The Potential Benefits of Dietary Changes in Psoriasis Patients

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The Potential Benefits of Dietary Changes in Psoriasis Patients

Psoriasis is a chronic inflammatory skin disease for which several lifestyle factors—smoking, alcohol use, and psychological stress—are associated with higher incidence and more severe disease.1-3 Diet also has been implicated as a factor that can affect psoriasis,4 and many patients have shown interest in possible dietary interventions to help their disease.5

In 2018, the National Psoriasis Foundation (NPF) presented dietary recommendations for patients based on results from a systematic review. From the available literature, only dietary weight reduction with hypocaloric diets in overweight or obese patients could be strongly recommended, and it has been proven that obesity is associated with worse psoriasis severity.6 Other more recent studies have shown that dietary modifications such as intermittent fasting and the ketogenic diet also led to weight loss and improved psoriasis severity in overweight patients; however, it is difficult to discern if the improvement was due to weight loss alone or if the dietary patterns themselves played a role.7,8 The paucity of well-designed studies evaluating the effects of other dietary changes has prevented further guidelines from being written. We propose that dietary patterns such as the Mediterranean diet (MeD) and vegan/vegetarian diets—even without strong data showing benefits in skin disease—may help to decrease systemic inflammation, improve gut dysbiosis, and help decrease the risk for cardiometabolic comorbidities that are associated with psoriasis.

Mediterranean Diet

The MeD is based on the dietary tendencies of inhabitants from the regions surrounding the Mediterranean Sea and is centered around nutrient-rich foods such as vegetables, olive oil, and legumes while limiting meat and dairy.9 The NPF recommended considering a trial of the MeD based on low-quality evidence.6 Observational studies have indicated that psoriasis patients are less likely to adhere to the MeD, but those who do have less severe disease.8 However, a search of PubMed articles indexed for MEDLINE using the terms Mediterranean diet and psoriasis yielded no prospective interventional studies. Given the association of the MeD with less severe disease, it is important to understand which specific foods in the MeD could be beneficial. Intake of omega-3 fatty acids, such as those found in fatty fish, are important for modulation of systemic inflammation.7 High intake of polyphenols—found in fruits and vegetables, extra-virgin olive oil, and wine—also have been implicated in improving inflammatory diseases due to potent antioxidant and anti-inflammatory properties. Individually, fruits, vegetables, whole grains, and sea fish have been associated with lowering C-reactive protein levels, which also is indicative of the benefits of these foods on systemic inflammation.7

Vegan/Vegetarian Diets

Although fruits, vegetables, legumes, and whole grains are a substantial component of the MeD, there are limited data on vegetarian or purely vegan plant-based diets. An observational study from the NPF found that only 48.4% (15/31) of patients on the MeD vs 69.0% (20/29) on a vegan diet reported a favorable skin response.5 Two case reports also have shown beneficial results of a strict vegan diet for psoriasis and psoriatic arthritis, where whole-food plant-based diets also improved joint symptoms.10-12 As with any diet, those who pursue a plant-based diet should strive to consume a variety of foods to avoid nutrient deficiencies. A recent systematic meta-analysis of 141 studies evaluated nutrient status of vegan and vegetarian diets compared to pescovegetarians and those who consume meat. All dietary patterns showed varying degrees of low levels of different nutrients.13 Of note, the researchers found that vitamin B12, vitamin D, iron, zinc, iodine, calcium, and docosahexaenoic acid were lower in plant-based diets. In contrast, folate; vitamins B1, B6, C, and E; polyunsaturated fatty acids; α-linolenic acid; and magnesium intake were higher. Those who consumed meat were at risk for inadequate intake of fiber, polyunsaturated fatty acids, α-linolenic acid, folate, vitamin E, calcium, magnesium, and vitamin D, though vitamin D intake was higher than in vegans/vegetarians.13 The results of this meta-analysis indicated the importance of educating patients on what constitutes a well-rounded, micronutrient-rich diet or appropriate supplementation for any diet.

Effects on Gut Microbiome

Any changes in diet can lead to alterations in the gut microbiome, which may impact skin disease, as evidence indicates a bidirectional relationship between gut and skin health.10 A metagenomic analysis of the gut microbiota in patients with untreated plaque psoriasis revealed a signature dysbiosis for which the researchers developed a psoriasis microbiota index, suggesting the gut microbiota may play a role in psoriasis pathophysiology.14 Research shows that both the MeD and vegan/vegetarian diets, which are relatively rich in fiber and omega-3 fatty acids and low in saturated fat and animal protein compared to many diets, cause increases in dietary fiber–metabolizing bacteria that produce short-chain fatty acids. These short-chain fatty acids improve gut epithelial integrity and alleviate both gut and systemic inflammation.10

The changes to the gut microbiome induced by a high-fat diet also are concerning. In contrast to the MeD or vegan/vegetarian diets, consumption of a high-fat diet induces alterations in the composition of the gut microbiota that in turn increase the release of proinflammatory cytokines and promote higher intestinal permeability.10 Similarly, high sugar consumption promotes increased intestinal permeability and shifts the gut microbiota to organisms that can rapidly utilize simple carbohydrates at the expense of other beneficial organisms, reducing bacterial diversity.15 The Western diet, which is notable for both high fat and high sugar content, is sometimes referred to as a proinflammatory diet and has been shown to worsen psoriasiformlike lesions in mice.16 Importantly, most research indicates that high fat and high sugar consumption appear to be more prevalent in psoriasis patients,8 but the type of fat consumed in the diet matters. The Western diet includes abundant saturated fat found in meat, dairy products, palm and coconut oils, and processed foods, as well as omega-6 fatty acids that are found in meat, poultry, and eggs. Saturated fat has been shown to promote helper T cell (TH17) accumulation in the skin, and omega-6 fatty acids serve as precursors to various inflammatory lipid mediators.4 This distinction of sources of fat between the Western diet and MeD is important in understanding the diets’ different effects on psoriasis and overall health. As previously discussed, the high intake of omega-3 acids in the MeD is one of the ways it may exert its anti-inflammatory benefits.7

Next Steps in Advising Psoriasis Patients

A major limitation of the data for MeD and vegan/vegetarian diets is limited randomized controlled trials evaluating the impact of these diets on psoriasis. Thus, dietary recommendations for psoriasis are not as strong as for other diseases for which more conclusive data exist.8 Although the data on diet and psoriasis are not definitive, perhaps dermatologists should shift the question from “Does this diet definitely improve psoriasis?” to “Does this diet definitely improve my patient’s health as a whole and maybe also their psoriasis?” For instance, the MeD has been shown to reduce the risk for type 2 diabetes mellitus and cardiovascular disease as well as to slow cognitive decline.17 Vegan/vegetarian diets focusing on whole vs processed foods have been shown to be highly effective in combatting obesity, type 2 diabetes mellitus, coronary artery disease including severe atherosclerosis, and hypertension.18 Psoriasis patients are at increased risk for many of the ailments that the MeD and plant-based diets protect against, making these diets potentially even more impactful than for someone without psoriasis.19 Dietary recommendations should still be made in conjunction with continuing traditional therapies for psoriasis and in consultation with the patient’s primary care physician and/or dietitian; however, rather than waiting for more randomized controlled trials before making health-promoting recommendations, what would be the downside of starting now? At worst, the dietary change decreases their risk for several metabolic conditions, and at best they may even see an improvement in their psoriasis.

References
  1. Naldi L, Chatenoud L, Linder D, et al. Cigarette smoking, body mass index, and stressful life events as risk factors for psoriasis: results from an Italian case–control study. J Invest Dermatol. 2005;125:61-67. doi:10.1111/j.0022-202X.2005.23681.x
  2. Armstrong AW, Harskamp CT, Dhillon JS, et al. Psoriasis and smoking: a systematic review and meta‐analysis. Br J Dermatol. 2014;170:304-314. doi:10.1111/bjd.12670
  3. Zhu K, Zhu C, Fan Y. Alcohol consumption and psoriatic risk: a meta‐analysis of case–control studies. J Dermatol. 2012;39:770-773. doi:10.1111/j.1346-8138.2012.01577.x
  4. Kanda N, Hoashi T, Saeki H. Nutrition and psoriasis. Int J Mol Sci. 2020;21:5405. doi:10.3390/ijms21155405
  5. Afifi L, Danesh MJ, Lee KM, et al. Dietary behaviors in psoriasis: patient-reported outcomes from a U.S. national survey. Dermatol Ther. 2017;7:227-242. doi:10.1007/s13555-017-0183-4
  6. Ford AR, Siegel M, Bagel J, et al. Dietary recommendations for adults with psoriasis or psoriatic arthritis from the medical board of the National Psoriasis Foundation: a systematic review. JAMA Dermatol. 2018;154:934. doi:10.1001/jamadermatol.2018.1412
  7. Duchnik E, Kruk J, Tuchowska A, et al. The impact of diet and physical activity on psoriasis: a narrative review of the current evidence. Nutrients. 2023;15:840. doi:10.3390/nu15040840
  8. Chung M, Bartholomew E, Yeroushalmi S, et al. Dietary intervention and supplements in the management of psoriasis: current perspectives. Psoriasis Targets Ther. 2022;12:151-176. doi:10.2147/PTT.S328581
  9. Mazza E, Ferro Y, Pujia R, et al. Mediterranean diet in healthy aging. J Nutr Health Aging. 2021;25:1076-1083. doi:10.1007/s12603-021-1675-6
  10. Flores-Balderas X, Peña-Peña M, Rada KM, et al. Beneficial effects of plant-based diets on skin health and inflammatory skin diseases. Nutrients. 2023;15:2842. doi:10.3390/nu15132842
  11. Bonjour M, Gabriel S, Valencia A, et al. Challenging case in clinical practice: prolonged water-only fasting followed by an exclusively whole-plant-food diet in the management of severe plaque psoriasis. Integr Complement Ther. 2022;28:85-87. doi:10.1089/ict.2022.29010.mbo
  12. Lewandowska M, Dunbar K, Kassam S. Managing psoriatic arthritis with a whole food plant-based diet: a case study. Am J Lifestyle Med. 2021;15:402-406. doi:10.1177/1559827621993435
  13. Neufingerl N, Eilander A. Nutrient intake and status in adults consuming plant-based diets compared to meat-eaters: a systematic review. Nutrients. 2021;14:29. doi:10.3390/nu14010029
  14. Dei-Cas I, Giliberto F, Luce L, et al. Metagenomic analysis of gut microbiota in non-treated plaque psoriasis patients stratified by disease severity: development of a new psoriasis-microbiome index. Sci Rep. 2020;10:12754. doi:10.1038/s41598-020-69537-3
  15. Satokari R. High intake of sugar and the balance between pro- and anti-inflammatory gut bacteria. Nutrients. 2020;12:1348. doi:10.3390/nu12051348
  16. Shi Z, Wu X, Santos Rocha C, et al. Short-term Western diet intake promotes IL-23–mediated skin and joint inflammation accompanied by changes to the gut microbiota in mice. J Invest Dermatol. 2021;141:1780-1791. doi:10.1016/j.jid.2020.11.032
  17. Romagnolo DF, Selmin OI. Mediterranean diet and prevention of chronic diseases. Nutr Today. 2017;52:208-222. doi:10.1097/NT.0000000000000228
  18. Tuso PJ, Ismail MH, Ha BP, et al. Nutritional update for physicians: plant-based diets. Perm J. 2013;17:61-66. doi:10.7812/TPP/12-085
  19. Parisi R, Symmons DPM, Griffiths CEM, et al. Global epidemiology of psoriasis: a systematic review of incidence and prevalence. J Invest Dermatol. 2013;133:377-385. doi:10.1038/jid.2012.339
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From the Department of Dermatology, University of California San Francisco. Dr. Liao also is from the Institute for Human Genetics, University of California San Francisco.

Drs. Kranyak and Bhutani, Kathryn Haran, Payton Smith, and Chandler Johnson report no conflict of interest. Dr. Liao has received research grants from Amgen, Janssen Pharmaceuticals, LEO Pharma, and Regeneron Pharmaceuticals.

Correspondence: Allison Kranyak, MD, UCSF Department of Dermatology, 1701 Divisadero St, San Francisco, CA 94115 ([email protected]).

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From the Department of Dermatology, University of California San Francisco. Dr. Liao also is from the Institute for Human Genetics, University of California San Francisco.

Drs. Kranyak and Bhutani, Kathryn Haran, Payton Smith, and Chandler Johnson report no conflict of interest. Dr. Liao has received research grants from Amgen, Janssen Pharmaceuticals, LEO Pharma, and Regeneron Pharmaceuticals.

Correspondence: Allison Kranyak, MD, UCSF Department of Dermatology, 1701 Divisadero St, San Francisco, CA 94115 ([email protected]).

Author and Disclosure Information

From the Department of Dermatology, University of California San Francisco. Dr. Liao also is from the Institute for Human Genetics, University of California San Francisco.

Drs. Kranyak and Bhutani, Kathryn Haran, Payton Smith, and Chandler Johnson report no conflict of interest. Dr. Liao has received research grants from Amgen, Janssen Pharmaceuticals, LEO Pharma, and Regeneron Pharmaceuticals.

Correspondence: Allison Kranyak, MD, UCSF Department of Dermatology, 1701 Divisadero St, San Francisco, CA 94115 ([email protected]).

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Psoriasis is a chronic inflammatory skin disease for which several lifestyle factors—smoking, alcohol use, and psychological stress—are associated with higher incidence and more severe disease.1-3 Diet also has been implicated as a factor that can affect psoriasis,4 and many patients have shown interest in possible dietary interventions to help their disease.5

In 2018, the National Psoriasis Foundation (NPF) presented dietary recommendations for patients based on results from a systematic review. From the available literature, only dietary weight reduction with hypocaloric diets in overweight or obese patients could be strongly recommended, and it has been proven that obesity is associated with worse psoriasis severity.6 Other more recent studies have shown that dietary modifications such as intermittent fasting and the ketogenic diet also led to weight loss and improved psoriasis severity in overweight patients; however, it is difficult to discern if the improvement was due to weight loss alone or if the dietary patterns themselves played a role.7,8 The paucity of well-designed studies evaluating the effects of other dietary changes has prevented further guidelines from being written. We propose that dietary patterns such as the Mediterranean diet (MeD) and vegan/vegetarian diets—even without strong data showing benefits in skin disease—may help to decrease systemic inflammation, improve gut dysbiosis, and help decrease the risk for cardiometabolic comorbidities that are associated with psoriasis.

Mediterranean Diet

The MeD is based on the dietary tendencies of inhabitants from the regions surrounding the Mediterranean Sea and is centered around nutrient-rich foods such as vegetables, olive oil, and legumes while limiting meat and dairy.9 The NPF recommended considering a trial of the MeD based on low-quality evidence.6 Observational studies have indicated that psoriasis patients are less likely to adhere to the MeD, but those who do have less severe disease.8 However, a search of PubMed articles indexed for MEDLINE using the terms Mediterranean diet and psoriasis yielded no prospective interventional studies. Given the association of the MeD with less severe disease, it is important to understand which specific foods in the MeD could be beneficial. Intake of omega-3 fatty acids, such as those found in fatty fish, are important for modulation of systemic inflammation.7 High intake of polyphenols—found in fruits and vegetables, extra-virgin olive oil, and wine—also have been implicated in improving inflammatory diseases due to potent antioxidant and anti-inflammatory properties. Individually, fruits, vegetables, whole grains, and sea fish have been associated with lowering C-reactive protein levels, which also is indicative of the benefits of these foods on systemic inflammation.7

Vegan/Vegetarian Diets

Although fruits, vegetables, legumes, and whole grains are a substantial component of the MeD, there are limited data on vegetarian or purely vegan plant-based diets. An observational study from the NPF found that only 48.4% (15/31) of patients on the MeD vs 69.0% (20/29) on a vegan diet reported a favorable skin response.5 Two case reports also have shown beneficial results of a strict vegan diet for psoriasis and psoriatic arthritis, where whole-food plant-based diets also improved joint symptoms.10-12 As with any diet, those who pursue a plant-based diet should strive to consume a variety of foods to avoid nutrient deficiencies. A recent systematic meta-analysis of 141 studies evaluated nutrient status of vegan and vegetarian diets compared to pescovegetarians and those who consume meat. All dietary patterns showed varying degrees of low levels of different nutrients.13 Of note, the researchers found that vitamin B12, vitamin D, iron, zinc, iodine, calcium, and docosahexaenoic acid were lower in plant-based diets. In contrast, folate; vitamins B1, B6, C, and E; polyunsaturated fatty acids; α-linolenic acid; and magnesium intake were higher. Those who consumed meat were at risk for inadequate intake of fiber, polyunsaturated fatty acids, α-linolenic acid, folate, vitamin E, calcium, magnesium, and vitamin D, though vitamin D intake was higher than in vegans/vegetarians.13 The results of this meta-analysis indicated the importance of educating patients on what constitutes a well-rounded, micronutrient-rich diet or appropriate supplementation for any diet.

Effects on Gut Microbiome

Any changes in diet can lead to alterations in the gut microbiome, which may impact skin disease, as evidence indicates a bidirectional relationship between gut and skin health.10 A metagenomic analysis of the gut microbiota in patients with untreated plaque psoriasis revealed a signature dysbiosis for which the researchers developed a psoriasis microbiota index, suggesting the gut microbiota may play a role in psoriasis pathophysiology.14 Research shows that both the MeD and vegan/vegetarian diets, which are relatively rich in fiber and omega-3 fatty acids and low in saturated fat and animal protein compared to many diets, cause increases in dietary fiber–metabolizing bacteria that produce short-chain fatty acids. These short-chain fatty acids improve gut epithelial integrity and alleviate both gut and systemic inflammation.10

The changes to the gut microbiome induced by a high-fat diet also are concerning. In contrast to the MeD or vegan/vegetarian diets, consumption of a high-fat diet induces alterations in the composition of the gut microbiota that in turn increase the release of proinflammatory cytokines and promote higher intestinal permeability.10 Similarly, high sugar consumption promotes increased intestinal permeability and shifts the gut microbiota to organisms that can rapidly utilize simple carbohydrates at the expense of other beneficial organisms, reducing bacterial diversity.15 The Western diet, which is notable for both high fat and high sugar content, is sometimes referred to as a proinflammatory diet and has been shown to worsen psoriasiformlike lesions in mice.16 Importantly, most research indicates that high fat and high sugar consumption appear to be more prevalent in psoriasis patients,8 but the type of fat consumed in the diet matters. The Western diet includes abundant saturated fat found in meat, dairy products, palm and coconut oils, and processed foods, as well as omega-6 fatty acids that are found in meat, poultry, and eggs. Saturated fat has been shown to promote helper T cell (TH17) accumulation in the skin, and omega-6 fatty acids serve as precursors to various inflammatory lipid mediators.4 This distinction of sources of fat between the Western diet and MeD is important in understanding the diets’ different effects on psoriasis and overall health. As previously discussed, the high intake of omega-3 acids in the MeD is one of the ways it may exert its anti-inflammatory benefits.7

Next Steps in Advising Psoriasis Patients

A major limitation of the data for MeD and vegan/vegetarian diets is limited randomized controlled trials evaluating the impact of these diets on psoriasis. Thus, dietary recommendations for psoriasis are not as strong as for other diseases for which more conclusive data exist.8 Although the data on diet and psoriasis are not definitive, perhaps dermatologists should shift the question from “Does this diet definitely improve psoriasis?” to “Does this diet definitely improve my patient’s health as a whole and maybe also their psoriasis?” For instance, the MeD has been shown to reduce the risk for type 2 diabetes mellitus and cardiovascular disease as well as to slow cognitive decline.17 Vegan/vegetarian diets focusing on whole vs processed foods have been shown to be highly effective in combatting obesity, type 2 diabetes mellitus, coronary artery disease including severe atherosclerosis, and hypertension.18 Psoriasis patients are at increased risk for many of the ailments that the MeD and plant-based diets protect against, making these diets potentially even more impactful than for someone without psoriasis.19 Dietary recommendations should still be made in conjunction with continuing traditional therapies for psoriasis and in consultation with the patient’s primary care physician and/or dietitian; however, rather than waiting for more randomized controlled trials before making health-promoting recommendations, what would be the downside of starting now? At worst, the dietary change decreases their risk for several metabolic conditions, and at best they may even see an improvement in their psoriasis.

Psoriasis is a chronic inflammatory skin disease for which several lifestyle factors—smoking, alcohol use, and psychological stress—are associated with higher incidence and more severe disease.1-3 Diet also has been implicated as a factor that can affect psoriasis,4 and many patients have shown interest in possible dietary interventions to help their disease.5

In 2018, the National Psoriasis Foundation (NPF) presented dietary recommendations for patients based on results from a systematic review. From the available literature, only dietary weight reduction with hypocaloric diets in overweight or obese patients could be strongly recommended, and it has been proven that obesity is associated with worse psoriasis severity.6 Other more recent studies have shown that dietary modifications such as intermittent fasting and the ketogenic diet also led to weight loss and improved psoriasis severity in overweight patients; however, it is difficult to discern if the improvement was due to weight loss alone or if the dietary patterns themselves played a role.7,8 The paucity of well-designed studies evaluating the effects of other dietary changes has prevented further guidelines from being written. We propose that dietary patterns such as the Mediterranean diet (MeD) and vegan/vegetarian diets—even without strong data showing benefits in skin disease—may help to decrease systemic inflammation, improve gut dysbiosis, and help decrease the risk for cardiometabolic comorbidities that are associated with psoriasis.

Mediterranean Diet

The MeD is based on the dietary tendencies of inhabitants from the regions surrounding the Mediterranean Sea and is centered around nutrient-rich foods such as vegetables, olive oil, and legumes while limiting meat and dairy.9 The NPF recommended considering a trial of the MeD based on low-quality evidence.6 Observational studies have indicated that psoriasis patients are less likely to adhere to the MeD, but those who do have less severe disease.8 However, a search of PubMed articles indexed for MEDLINE using the terms Mediterranean diet and psoriasis yielded no prospective interventional studies. Given the association of the MeD with less severe disease, it is important to understand which specific foods in the MeD could be beneficial. Intake of omega-3 fatty acids, such as those found in fatty fish, are important for modulation of systemic inflammation.7 High intake of polyphenols—found in fruits and vegetables, extra-virgin olive oil, and wine—also have been implicated in improving inflammatory diseases due to potent antioxidant and anti-inflammatory properties. Individually, fruits, vegetables, whole grains, and sea fish have been associated with lowering C-reactive protein levels, which also is indicative of the benefits of these foods on systemic inflammation.7

Vegan/Vegetarian Diets

Although fruits, vegetables, legumes, and whole grains are a substantial component of the MeD, there are limited data on vegetarian or purely vegan plant-based diets. An observational study from the NPF found that only 48.4% (15/31) of patients on the MeD vs 69.0% (20/29) on a vegan diet reported a favorable skin response.5 Two case reports also have shown beneficial results of a strict vegan diet for psoriasis and psoriatic arthritis, where whole-food plant-based diets also improved joint symptoms.10-12 As with any diet, those who pursue a plant-based diet should strive to consume a variety of foods to avoid nutrient deficiencies. A recent systematic meta-analysis of 141 studies evaluated nutrient status of vegan and vegetarian diets compared to pescovegetarians and those who consume meat. All dietary patterns showed varying degrees of low levels of different nutrients.13 Of note, the researchers found that vitamin B12, vitamin D, iron, zinc, iodine, calcium, and docosahexaenoic acid were lower in plant-based diets. In contrast, folate; vitamins B1, B6, C, and E; polyunsaturated fatty acids; α-linolenic acid; and magnesium intake were higher. Those who consumed meat were at risk for inadequate intake of fiber, polyunsaturated fatty acids, α-linolenic acid, folate, vitamin E, calcium, magnesium, and vitamin D, though vitamin D intake was higher than in vegans/vegetarians.13 The results of this meta-analysis indicated the importance of educating patients on what constitutes a well-rounded, micronutrient-rich diet or appropriate supplementation for any diet.

Effects on Gut Microbiome

Any changes in diet can lead to alterations in the gut microbiome, which may impact skin disease, as evidence indicates a bidirectional relationship between gut and skin health.10 A metagenomic analysis of the gut microbiota in patients with untreated plaque psoriasis revealed a signature dysbiosis for which the researchers developed a psoriasis microbiota index, suggesting the gut microbiota may play a role in psoriasis pathophysiology.14 Research shows that both the MeD and vegan/vegetarian diets, which are relatively rich in fiber and omega-3 fatty acids and low in saturated fat and animal protein compared to many diets, cause increases in dietary fiber–metabolizing bacteria that produce short-chain fatty acids. These short-chain fatty acids improve gut epithelial integrity and alleviate both gut and systemic inflammation.10

The changes to the gut microbiome induced by a high-fat diet also are concerning. In contrast to the MeD or vegan/vegetarian diets, consumption of a high-fat diet induces alterations in the composition of the gut microbiota that in turn increase the release of proinflammatory cytokines and promote higher intestinal permeability.10 Similarly, high sugar consumption promotes increased intestinal permeability and shifts the gut microbiota to organisms that can rapidly utilize simple carbohydrates at the expense of other beneficial organisms, reducing bacterial diversity.15 The Western diet, which is notable for both high fat and high sugar content, is sometimes referred to as a proinflammatory diet and has been shown to worsen psoriasiformlike lesions in mice.16 Importantly, most research indicates that high fat and high sugar consumption appear to be more prevalent in psoriasis patients,8 but the type of fat consumed in the diet matters. The Western diet includes abundant saturated fat found in meat, dairy products, palm and coconut oils, and processed foods, as well as omega-6 fatty acids that are found in meat, poultry, and eggs. Saturated fat has been shown to promote helper T cell (TH17) accumulation in the skin, and omega-6 fatty acids serve as precursors to various inflammatory lipid mediators.4 This distinction of sources of fat between the Western diet and MeD is important in understanding the diets’ different effects on psoriasis and overall health. As previously discussed, the high intake of omega-3 acids in the MeD is one of the ways it may exert its anti-inflammatory benefits.7

Next Steps in Advising Psoriasis Patients

A major limitation of the data for MeD and vegan/vegetarian diets is limited randomized controlled trials evaluating the impact of these diets on psoriasis. Thus, dietary recommendations for psoriasis are not as strong as for other diseases for which more conclusive data exist.8 Although the data on diet and psoriasis are not definitive, perhaps dermatologists should shift the question from “Does this diet definitely improve psoriasis?” to “Does this diet definitely improve my patient’s health as a whole and maybe also their psoriasis?” For instance, the MeD has been shown to reduce the risk for type 2 diabetes mellitus and cardiovascular disease as well as to slow cognitive decline.17 Vegan/vegetarian diets focusing on whole vs processed foods have been shown to be highly effective in combatting obesity, type 2 diabetes mellitus, coronary artery disease including severe atherosclerosis, and hypertension.18 Psoriasis patients are at increased risk for many of the ailments that the MeD and plant-based diets protect against, making these diets potentially even more impactful than for someone without psoriasis.19 Dietary recommendations should still be made in conjunction with continuing traditional therapies for psoriasis and in consultation with the patient’s primary care physician and/or dietitian; however, rather than waiting for more randomized controlled trials before making health-promoting recommendations, what would be the downside of starting now? At worst, the dietary change decreases their risk for several metabolic conditions, and at best they may even see an improvement in their psoriasis.

References
  1. Naldi L, Chatenoud L, Linder D, et al. Cigarette smoking, body mass index, and stressful life events as risk factors for psoriasis: results from an Italian case–control study. J Invest Dermatol. 2005;125:61-67. doi:10.1111/j.0022-202X.2005.23681.x
  2. Armstrong AW, Harskamp CT, Dhillon JS, et al. Psoriasis and smoking: a systematic review and meta‐analysis. Br J Dermatol. 2014;170:304-314. doi:10.1111/bjd.12670
  3. Zhu K, Zhu C, Fan Y. Alcohol consumption and psoriatic risk: a meta‐analysis of case–control studies. J Dermatol. 2012;39:770-773. doi:10.1111/j.1346-8138.2012.01577.x
  4. Kanda N, Hoashi T, Saeki H. Nutrition and psoriasis. Int J Mol Sci. 2020;21:5405. doi:10.3390/ijms21155405
  5. Afifi L, Danesh MJ, Lee KM, et al. Dietary behaviors in psoriasis: patient-reported outcomes from a U.S. national survey. Dermatol Ther. 2017;7:227-242. doi:10.1007/s13555-017-0183-4
  6. Ford AR, Siegel M, Bagel J, et al. Dietary recommendations for adults with psoriasis or psoriatic arthritis from the medical board of the National Psoriasis Foundation: a systematic review. JAMA Dermatol. 2018;154:934. doi:10.1001/jamadermatol.2018.1412
  7. Duchnik E, Kruk J, Tuchowska A, et al. The impact of diet and physical activity on psoriasis: a narrative review of the current evidence. Nutrients. 2023;15:840. doi:10.3390/nu15040840
  8. Chung M, Bartholomew E, Yeroushalmi S, et al. Dietary intervention and supplements in the management of psoriasis: current perspectives. Psoriasis Targets Ther. 2022;12:151-176. doi:10.2147/PTT.S328581
  9. Mazza E, Ferro Y, Pujia R, et al. Mediterranean diet in healthy aging. J Nutr Health Aging. 2021;25:1076-1083. doi:10.1007/s12603-021-1675-6
  10. Flores-Balderas X, Peña-Peña M, Rada KM, et al. Beneficial effects of plant-based diets on skin health and inflammatory skin diseases. Nutrients. 2023;15:2842. doi:10.3390/nu15132842
  11. Bonjour M, Gabriel S, Valencia A, et al. Challenging case in clinical practice: prolonged water-only fasting followed by an exclusively whole-plant-food diet in the management of severe plaque psoriasis. Integr Complement Ther. 2022;28:85-87. doi:10.1089/ict.2022.29010.mbo
  12. Lewandowska M, Dunbar K, Kassam S. Managing psoriatic arthritis with a whole food plant-based diet: a case study. Am J Lifestyle Med. 2021;15:402-406. doi:10.1177/1559827621993435
  13. Neufingerl N, Eilander A. Nutrient intake and status in adults consuming plant-based diets compared to meat-eaters: a systematic review. Nutrients. 2021;14:29. doi:10.3390/nu14010029
  14. Dei-Cas I, Giliberto F, Luce L, et al. Metagenomic analysis of gut microbiota in non-treated plaque psoriasis patients stratified by disease severity: development of a new psoriasis-microbiome index. Sci Rep. 2020;10:12754. doi:10.1038/s41598-020-69537-3
  15. Satokari R. High intake of sugar and the balance between pro- and anti-inflammatory gut bacteria. Nutrients. 2020;12:1348. doi:10.3390/nu12051348
  16. Shi Z, Wu X, Santos Rocha C, et al. Short-term Western diet intake promotes IL-23–mediated skin and joint inflammation accompanied by changes to the gut microbiota in mice. J Invest Dermatol. 2021;141:1780-1791. doi:10.1016/j.jid.2020.11.032
  17. Romagnolo DF, Selmin OI. Mediterranean diet and prevention of chronic diseases. Nutr Today. 2017;52:208-222. doi:10.1097/NT.0000000000000228
  18. Tuso PJ, Ismail MH, Ha BP, et al. Nutritional update for physicians: plant-based diets. Perm J. 2013;17:61-66. doi:10.7812/TPP/12-085
  19. Parisi R, Symmons DPM, Griffiths CEM, et al. Global epidemiology of psoriasis: a systematic review of incidence and prevalence. J Invest Dermatol. 2013;133:377-385. doi:10.1038/jid.2012.339
References
  1. Naldi L, Chatenoud L, Linder D, et al. Cigarette smoking, body mass index, and stressful life events as risk factors for psoriasis: results from an Italian case–control study. J Invest Dermatol. 2005;125:61-67. doi:10.1111/j.0022-202X.2005.23681.x
  2. Armstrong AW, Harskamp CT, Dhillon JS, et al. Psoriasis and smoking: a systematic review and meta‐analysis. Br J Dermatol. 2014;170:304-314. doi:10.1111/bjd.12670
  3. Zhu K, Zhu C, Fan Y. Alcohol consumption and psoriatic risk: a meta‐analysis of case–control studies. J Dermatol. 2012;39:770-773. doi:10.1111/j.1346-8138.2012.01577.x
  4. Kanda N, Hoashi T, Saeki H. Nutrition and psoriasis. Int J Mol Sci. 2020;21:5405. doi:10.3390/ijms21155405
  5. Afifi L, Danesh MJ, Lee KM, et al. Dietary behaviors in psoriasis: patient-reported outcomes from a U.S. national survey. Dermatol Ther. 2017;7:227-242. doi:10.1007/s13555-017-0183-4
  6. Ford AR, Siegel M, Bagel J, et al. Dietary recommendations for adults with psoriasis or psoriatic arthritis from the medical board of the National Psoriasis Foundation: a systematic review. JAMA Dermatol. 2018;154:934. doi:10.1001/jamadermatol.2018.1412
  7. Duchnik E, Kruk J, Tuchowska A, et al. The impact of diet and physical activity on psoriasis: a narrative review of the current evidence. Nutrients. 2023;15:840. doi:10.3390/nu15040840
  8. Chung M, Bartholomew E, Yeroushalmi S, et al. Dietary intervention and supplements in the management of psoriasis: current perspectives. Psoriasis Targets Ther. 2022;12:151-176. doi:10.2147/PTT.S328581
  9. Mazza E, Ferro Y, Pujia R, et al. Mediterranean diet in healthy aging. J Nutr Health Aging. 2021;25:1076-1083. doi:10.1007/s12603-021-1675-6
  10. Flores-Balderas X, Peña-Peña M, Rada KM, et al. Beneficial effects of plant-based diets on skin health and inflammatory skin diseases. Nutrients. 2023;15:2842. doi:10.3390/nu15132842
  11. Bonjour M, Gabriel S, Valencia A, et al. Challenging case in clinical practice: prolonged water-only fasting followed by an exclusively whole-plant-food diet in the management of severe plaque psoriasis. Integr Complement Ther. 2022;28:85-87. doi:10.1089/ict.2022.29010.mbo
  12. Lewandowska M, Dunbar K, Kassam S. Managing psoriatic arthritis with a whole food plant-based diet: a case study. Am J Lifestyle Med. 2021;15:402-406. doi:10.1177/1559827621993435
  13. Neufingerl N, Eilander A. Nutrient intake and status in adults consuming plant-based diets compared to meat-eaters: a systematic review. Nutrients. 2021;14:29. doi:10.3390/nu14010029
  14. Dei-Cas I, Giliberto F, Luce L, et al. Metagenomic analysis of gut microbiota in non-treated plaque psoriasis patients stratified by disease severity: development of a new psoriasis-microbiome index. Sci Rep. 2020;10:12754. doi:10.1038/s41598-020-69537-3
  15. Satokari R. High intake of sugar and the balance between pro- and anti-inflammatory gut bacteria. Nutrients. 2020;12:1348. doi:10.3390/nu12051348
  16. Shi Z, Wu X, Santos Rocha C, et al. Short-term Western diet intake promotes IL-23–mediated skin and joint inflammation accompanied by changes to the gut microbiota in mice. J Invest Dermatol. 2021;141:1780-1791. doi:10.1016/j.jid.2020.11.032
  17. Romagnolo DF, Selmin OI. Mediterranean diet and prevention of chronic diseases. Nutr Today. 2017;52:208-222. doi:10.1097/NT.0000000000000228
  18. Tuso PJ, Ismail MH, Ha BP, et al. Nutritional update for physicians: plant-based diets. Perm J. 2013;17:61-66. doi:10.7812/TPP/12-085
  19. Parisi R, Symmons DPM, Griffiths CEM, et al. Global epidemiology of psoriasis: a systematic review of incidence and prevalence. J Invest Dermatol. 2013;133:377-385. doi:10.1038/jid.2012.339
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  • Psoriasis is affected by lifestyle factors such as diet, which is an area of interest for many patients.
  • Low-calorie diets are strongly recommended for overweight/obese patients with psoriasis to improve their disease.
  • Changes in dietary patterns, such as adopting a Mediterranean diet or a plant-based diet, also have shown promise.
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Cutaneous Manifestations in Hereditary Alpha Tryptasemia

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Cutaneous Manifestations in Hereditary Alpha Tryptasemia

Hereditary alpha tryptasemia (HaT), an autosomal-dominant disorder of tryptase overproduction, was first described in 2014 by Lyons et al.1 It has been associated with multiple dermatologic, allergic, gastrointestinal (GI) tract, neuropsychiatric, respiratory, autonomic, and connective tissue abnormalities. These multisystem concerns may include cutaneous flushing, chronic pruritus, urticaria, GI tract symptoms, arthralgia, and autonomic dysfunction.2 The diverse symptoms and the recent discovery of HaT make recognition of this disorder challenging. Currently, it also is believed that HaT is associated with an elevated risk for anaphylaxis and is a biomarker for severe symptoms in disorders with increased mast cell burden such as mastocytosis.3-5

Given the potential cutaneous manifestations and the fact that dermatologic symptoms may be the initial presentation of HaT, awareness and recognition of this condition by dermatologists are essential for diagnosis and treatment. This review summarizes the cutaneous presentations consistent with HaT and discusses various conditions that share overlapping dermatologic symptoms with HaT.

Background on HaT

Mast cells are known to secrete several vasoactive mediators including tryptase and histamine when activated by foreign substances, similar to IgE-mediated hypersensitivity reactions. In their baseline state, mast cells continuously secrete immature forms of tryptases called protryptases.6 These protryptases come in 2 forms: α and β. Although mature tryptase is acutely elevatedin anaphylaxis, persistently elevated total serum tryptase levels frequently are regarded as indicative of a systemic mast cell disorder such as systemic mastocytosis (SM).3 Despite the wide-ranging phenotype of HaT, all individuals with the disorder have an elevated basal serum tryptase level (>8 ng/mL). Hereditary alpha tryptasemia has been identified as another possible cause of persistently elevated levels.2,6

Genetics and Epidemiology of HaT—The humantryptase locus at chromosome 16p13.3 is composed of 4 paralog genes: TPSG1, TPSB2, TPSAB1, and TPSD1.4 Only TPSAB1 encodes for α-tryptase, while both TPSB2 and TPSAB1 encode for β-tryptase.4 Hereditary alpha tryptasemia is an autosomal-dominant disorder resulting from a copy number increase in the α-tryptase encoding sequence within the TPSAB1 gene. Despite the wide-ranging phenotype of HaT, all individuals identified with the disorder have a basal serum tryptase level greater than 8 ng/mL, with mean (SD) levels of 15 (5) ng/mL and 24 (6) ng/mL with gene duplication and triplication, respectively (reference range, 0–11.4 ng/mL).2,6 Hereditary alpha tryptasemia likely is common and largely undiagnosed, with a recently estimated prevalence of 5% in the United Kingdom7 and 5.6% in a cohort of 125 individuals from Italy, Slovenia, and the United States.5

Implications of Increased α-tryptase Levels—After an inciting stimulus, the active portions of α-protryptase and β-protryptase are secreted as tetramers by activated mast cells via degranulation. In vitro, β-tryptase homotetramers have been found to play a role in anaphylaxis, while α-homotetramers are nearly inactive.8,9 Recently, however, it has been discovered that α2β2 tetramers also can form and do so in a higher ratio in individuals with increased α-tryptase–encoding gene copies, such as those with HaT.8 These heterotetramers exhibit unique properties compared with the homotetramers and may stimulate epidermal growth factor–like module-containing mucinlike hormone receptor 2 and protease-activated receptor 2 (PAR2). Epidermal growth factor–like module-containing mucinlike hormone receptor 2 activation likely contributes to vibratory urticaria in patients, while activation of PAR2 may have a range of clinical effects, including worsening asthma, inflammatory bowel disease, pruritus, and the exacerbation of dermal inflammation and hyperalgesia.8,10 Thus, α- and β-tryptase tetramers can be considered mediators that may influence the severity of disorders in which mast cells are naturally prevalent and likely contribute to the phenotype of those with HaT.7 Furthermore, these characteristics have been shown to potentially increase in severity with increasing tryptase levels and with increased TPSAB1 duplications.1,2 In contrast, more than 25% of the population is deficient in α-tryptase without known deleterious effects.5

Cutaneous Manifestations of HaT

A case series reported by Lyons et al1 in 2014 detailed persistent elevated basal serum tryptase levels in 9 families with an autosomal-dominant pattern of inheritance. In this cohort, 31 of 33 (94%) affected individuals had a history of atopic dermatitis (AD), and 26 of 33 (79%) affected individuals reported symptoms consistent with mast cell degranulation, including urticaria; flushing; and/or crampy abdominal pain unprovoked or triggered by heat, exercise, vibration, stress, certain foods, or minor physical stimulation.1 A later report by Lyons et al2 in 2016 identified the TPSAB1 α-tryptase–encoding sequence copy number increase as the causative entity for HaT by examining a group of 96 patients from 35 families with frequent recurrent cutaneous flushing and pruritus, sometimes associated with urticaria and sleep disruption. Flushing and pruritus were found in 45% (33/73) of those with a TPSAB1 duplication and 80% (12/15) of those with a triplication (P=.022), suggesting a gene dose effect regarding α-tryptase encoding sequence copy number and these symptoms.2

A 2019 study further explored the clinical finding of urticaria in patients with HaT by specifically examining if vibration-induced urticaria was affected by TPSAB1 gene dosage.8 A cohort of 56 volunteers—35 healthy and 21 with HaT—underwent tryptase genotyping and cutaneous vibratory challenge. The presence of TPSAB1 was significantly correlated with induction of vibration-induced urticaria (P<.01), as the severity and prevalence of the urticarial response increased along with α- and β-tryptase gene ratios.8

 

 

Urticaria and angioedema also were seen in 51% (36/70) of patients in a cohort of HaT patients in the United Kingdom, in which 41% (29/70) also had skin flushing. In contrast to prior studies, these manifestations were not more common in patients with gene triplications or quintuplications than those with duplications.7 In another recent retrospective evaluation conducted at Brigham and Women’s Hospital (Boston, Massachusetts)(N=101), 80% of patients aged 4 to 85 years with confirmed diagnoses of HaT had skin manifestations such as urticaria, flushing, and pruritus.4

HaT and Mast Cell Activation Syndrome—In 2019, a Mast Cell Disorders Committee Work Group Report outlined recommendations for diagnosing and treating primary mast cell activation syndrome (MCAS), a disorder in which mast cells seem to be more easily activated. Mast cell activation syndrome is defined as a primary clinical condition in which there are episodic signs and symptoms of systemic anaphylaxis (Table) concurrently affecting at least 2 organ systems, resulting from secreted mast cell mediators.9,11 The 2019 report also touched on clinical criteria that lack precision for diagnosing MCAS yet are in use, including dermographism and several types of rashes.9 Episode triggers frequent in MCAS include hot water, alcohol, stress, exercise, infection, hormonal changes, and physical stimuli.

Symptoms of MCAS vs HaT

Hereditary alpha tryptasemia has been suggested to be a risk factor for MCAS, which also can be associated with SM and clonal MCAS.9 Patients with MCAS should be tested for increased α-tryptase gene copy number given the overlap in symptoms, the likely predisposition of those with HaT to develop MCAS, and the fact that these patients could be at an increased risk for anaphylaxis.4,7,9,11 However, the clinical phenotype for HaT includes allergic disorders affecting the skin as well as neuropsychiatric and connective tissue abnormalities that are distinctive from MCAS. Although HaT may be considered a heritable risk factor for MCAS, MCAS is only 1 potential phenotype associated with HaT.9

Implications of HaT

Hereditary alpha tryptasemia should be considered in all patients with basal tryptase levels greater than 8 ng/mL. Cutaneous symptoms are among the most common presentations for individuals with HaT and can include AD, chronic or episodic urticaria, pruritus, flushing, and angioedema. However, HaT is unique because of the coupling of these common dermatologic findings with other abnormalities, including abdominal pain and diarrhea, hypermobile joints, and autonomic dysfunction. Patients with HaT also may manifest psychiatric concerns of anxiety, depression, and chronic pain, all of which have been linked to this disorder.

It is unclear in HaT if the presence of extra-allelic copies of tryptase in an individual is directly pathogenic. The effects of increased basal tryptase and α2β2 tetramers have been shown to likely be responsible for some of the clinical features in these individuals but also may magnify other individual underlying disease(s) or diathesis in which mast cells are naturally abundant.8 In the skin, this increased mast cell activation and subsequent histamine release frequently are visible as dermatographia and urticaria. However, mast cell numbers also are known to be increased in both psoriatic and AD skin lesions,12 thus severe presentation of these diseases in conjunction with the other symptoms associated with mast cell activation should prompt suspicion for HaT.

Effects of HaT on Other Cutaneous Disease—Given the increase of mast cells in AD skin lesions and fact that 94% of patients in the 2014 Lyons et al1 study cited a history of AD, HaT may be a risk factor in the development of AD. Interestingly, in addition to the increased mast cells in AD lesions, PAR2+ nerve fibers also are increased in AD lesions and have been implicated in the nonhistaminergic pruritus experienced by patients with AD.12 Thus, given the proposed propensity for α2β2 tetramers to activate PAR2, it is possible this mechanism may contribute to severe pruritus in individuals with AD and concurrent HaT, as those with HaT express increased α2β2 tetramers. However, no study to date has directly compared AD symptoms in patients with concurrent HaT vs patients without it. Further research is needed on how HaT impacts other allergic and inflammatory skin diseases such as AD and psoriasis, but one may reasonably consider HaT when treating chronic inflammatory skin diseases refractory to typical interventions and/or severe presentations. Although HaT is an autosomal-dominant disorder, it is not detected by standard whole exome sequencing or microarrays. A commercial test is available, utilizing a buccal swab to test for TPSAB1 copy number.

HaT and Mast Cell Disorders—When evaluating someone with suspected HaT, it is important to screen for other symptoms of mast cell activation. For instance, in the GI tract increased mast cell activation results in activation of motor neurons and nociceptors and increases secretion and peristalsis with consequent bloating, abdominal pain, and diarrhea.10 Likewise, tryptase also has neuromodulatory effects that amplify the perception of pain and are likely responsible for the feelings of hyperalgesia reported in patients with HaT.13

 

 

There is substantial overlap in the clinical pictures of HaT and MCAS, and HaT is considered a heritable risk factor for MCAS. Consequently, any patient undergoing workup for MCAS also should be tested for HaT. Although HaT is associated with consistently elevated tryptase, MCAS is episodic in nature, and an increase in tryptase levels of at least 20% plus 2 ng/mL from baseline only in the presence of other symptoms reflective of mast cell activation (Table) is a prerequisite for diagnosis.9 Chronic signs and symptoms of atopy, chronic urticaria, and severe asthma are not indicative of MCAS but are frequently seen in HaT.

Another cause of persistently elevated tryptase levels is SM. Systemic mastocytosis is defined by aberrant clonal mast cell expansion and systemic involvement11 and can cause persistent symptoms, unlike MCAS alone. However, SM also can be associated with MCAS.9 Notably, a baseline serum tryptase level greater than 20 ng/mL—much higher than the threshold of greater than 8 ng/mL for suspicion of HaT—is seen in 75% of SM cases and is part of the minor diagnostic criteria for the disease.9,11 However, the 2016 study identifying increased TPSAB1 α-tryptase–encoding sequences as the causative entity for HaT by Lyons et al2 found the average (SD) basal serum tryptase level in individuals with α-tryptase–encoding sequence duplications to be 15 (5) ng/mL and 24 (6) ng/mL in those with triplications. Thus, there likely is no threshold for elevated baseline tryptase levels that would indicate SM over HaT as a more likely diagnosis. However, SM will present with new persistently elevated tryptase levels, whereas the elevation in HaT is believed to be lifelong.5 Also in contrast to HaT, SM can present with liver, spleen, and lymph node involvement; bone sclerosis; and cytopenia.11,14

Mastocytosis is much rarer than HaT, with an estimated prevalence of 9 cases per 100,000 individuals in the United States.11 Although HaT diagnostic testing is noninvasive, SM requires a bone marrow biopsy for definitive diagnosis. Given the likely much higher prevalence of HaT than SM and the patient burden of a bone marrow biopsy, HaT should be considered before proceeding with a bone marrow biopsy to evaluate for SM when a patient presents with persistent systemic symptoms of mast cell activation and elevated baseline tryptase levels. Furthermore, it also would be prudent to test for HaT in patients with known SM, as a cohort study by Lyons et al5 indicated that HaT is likely more common in those with SM (12.2% [10/82] of cohort with known SM vs 5.3% of 398 controls), and patients with concurrent SM and HaT were at a higher risk for severe anaphylaxis (RR=9.5; P=.007).

Studies thus far surrounding HaT have not evaluated timing of initial symptom onset or age of initial presentation for HaT. Furthermore, there is no guarantee that those with increased TPSAB1 copy number will be symptomatic, as there have been reports of asymptomatic individuals with HaT who had basal serum levels greater than 8 ng/mL.7 As research into HaT continues and larger cohorts are evaluated, questions surrounding timing of symptom onset and various factors that may make someone more likely to display a particular phenotype will be answered.

Treatment—Long-term prognosis for individuals with HaT is largely unknown. Unfortunately, there are limited data to support a single effective treatment strategy for managing HaT, and treatment has varied based on predominant symptoms. For cutaneous and GI tract symptoms, trials of maximal H1 and H2 antihistamines twice daily have been recommended.4 Omalizumab was reported to improve chronic urticaria in 3 of 3 patients, showing potential promise as a treatment.4 Mast cell stabilizers, such as oral cromolyn, have been used for severe GI symptoms, while some patients also have reported improvement with oral ketotifen.6 Other medications, such as tricyclic antidepressants, clemastine fumarate, and gabapentin, have been beneficial anecdotally.6 Given the lack of harmful effects seen in individuals who are α-tryptase deficient, α-tryptase inhibition is an intriguing target for future therapies.

Conclusion

Patients who present with a constellation of dermatologic, allergic, GI tract, neuropsychiatric, respiratory, autonomic, and connective tissue abnormalities consistent with HaT may receive a prompt diagnosis if the association is recognized. The full relationship between HaT and other chronic dermatologic disorders is still unknown. Ultimately, heightened interest and research into HaT will lead to more treatment options available for affected patients.

References

1. Lyons JJ, Sun G, Stone KD, et al. Mendelian inheritance of elevated serum tryptase associated with atopy and connective tissue abnormalities. J Allergy Clin Immunol. 2014;133:1471-1474.

2. Lyons JJ, Yu X, Hughes JD, et al. Elevated basal serum tryptase identifies a multisystem disorder associated with increased TPSAB1 copy number. Nat Genet. 2016;48:1564-1569.

3. Schwartz L. Diagnostic value of tryptase in anaphylaxis and mastocytosis. Immunol Allergy Clin North Am. 2006;6:451-463.

4. Giannetti MP, Weller E, Bormans C, et al. Hereditary alpha-tryptasemia in 101 patients with mast cell activation–related symptomatology including anaphylaxis. Ann Allergy Asthma Immunol. 2021;126:655-660.

5. Lyons JJ, Chovanec J, O’Connell MP, et al. Heritable risk for severe anaphylaxis associated with increased α-tryptase–encoding germline copy number at TPSAB1. J Allergy Clin Immunol. 2020;147:622-632.

6. Lyons JJ. Hereditary alpha tryptasemia: genotyping and associated clinical features. Immunol Allergy Clin North Am. 2018;38:483-495.

7. Robey RC, Wilcock A, Bonin H, et al. Hereditary alpha-tryptasemia: UK prevalence and variability in disease expression. J Allergy Clin Immunol Pract. 2020;8:3549-3556.

8. Le QT, Lyons JJ, Naranjo AN, et al. Impact of naturally forming human α/β-tryptase heterotetramers in the pathogenesis of hereditary α-tryptasemia. J Exp Med. 2019;216:2348-2361.

9. Weiler CR, Austen KF, Akin C, et al. AAAAI Mast Cell Disorders Committee Work Group Report: mast cell activation syndrome (MCAS) diagnosis and management. J Allergy Clin Immunol. 2019;144:883-896.

10. Ramsay DB, Stephen S, Borum M, et al. Mast cells in gastrointestinal disease. Gastroenterol Hepatol (N Y). 2010;6:772-777.

11. Giannetti A, Filice E, Caffarelli C, et al. Mast cell activation disorders. Medicina (Kaunas). 2021;57:124.

12. Siiskonen H, Harvima I. Mast cells and sensory nerves contribute to neurogenic inflammation and pruritus in chronic skin inflammation. Front Cell Neurosci. 2019;13:422.

13. Varrassi G, Fusco M, Skaper SD, et al. A pharmacological rationale to reduce the incidence of opioid induced tolerance and hyperalgesia: a review. Pain Ther. 2018;7:59-75.

14. Núñez E, Moreno-Borque R, García-Montero A, et al. Serum tryptase monitoring in indolent systemic mastocytosis: association with disease features and patient outcome. PLoS One. 2013;8:E76116.

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Drs. Kranyak and Shuler are from the University of South Carolina School of Medicine, Greenville. Dr. Wine Lee is from the Departments of Dermatology and Pediatrics, Medical University of South Carolina, Charleston.

Dr. Kranyak reports no conflict of interest. Dr. Shuler is a speaker for AbbVie, Eli Lilly and Company, Janssen, Pfizer, and Sanofi-Regeneron. Dr. Wine Lee has received research support from AbbVie, Amgen, Amyrt, Arcutis, Avita, Castle Creek, Celgene, Eli Lilly and Company, Galderma, Incyte Corporation, Janssen, Kiniksa, Mayne Pharmaceuticals, Moonlake Pharmaceuticals, Novartis, Pfizer, Sanofi-Regeneron, Target Pharma, Timber Pharmaceuticals, Trevi Therapeutics, and UCB. She has received research fees from Amyrt, Castle Creek, Eli Lilly and Company, Novartis, Pfizer, and Regeneron, as well as consulting fees from AbbVie, Krystal Biotech, and Pyramid Bioscience.

Correspondence: Allison Kranyak, MD, 607 Grove Rd, Greenville, SC 29605 ([email protected]).

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Drs. Kranyak and Shuler are from the University of South Carolina School of Medicine, Greenville. Dr. Wine Lee is from the Departments of Dermatology and Pediatrics, Medical University of South Carolina, Charleston.

Dr. Kranyak reports no conflict of interest. Dr. Shuler is a speaker for AbbVie, Eli Lilly and Company, Janssen, Pfizer, and Sanofi-Regeneron. Dr. Wine Lee has received research support from AbbVie, Amgen, Amyrt, Arcutis, Avita, Castle Creek, Celgene, Eli Lilly and Company, Galderma, Incyte Corporation, Janssen, Kiniksa, Mayne Pharmaceuticals, Moonlake Pharmaceuticals, Novartis, Pfizer, Sanofi-Regeneron, Target Pharma, Timber Pharmaceuticals, Trevi Therapeutics, and UCB. She has received research fees from Amyrt, Castle Creek, Eli Lilly and Company, Novartis, Pfizer, and Regeneron, as well as consulting fees from AbbVie, Krystal Biotech, and Pyramid Bioscience.

Correspondence: Allison Kranyak, MD, 607 Grove Rd, Greenville, SC 29605 ([email protected]).

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Drs. Kranyak and Shuler are from the University of South Carolina School of Medicine, Greenville. Dr. Wine Lee is from the Departments of Dermatology and Pediatrics, Medical University of South Carolina, Charleston.

Dr. Kranyak reports no conflict of interest. Dr. Shuler is a speaker for AbbVie, Eli Lilly and Company, Janssen, Pfizer, and Sanofi-Regeneron. Dr. Wine Lee has received research support from AbbVie, Amgen, Amyrt, Arcutis, Avita, Castle Creek, Celgene, Eli Lilly and Company, Galderma, Incyte Corporation, Janssen, Kiniksa, Mayne Pharmaceuticals, Moonlake Pharmaceuticals, Novartis, Pfizer, Sanofi-Regeneron, Target Pharma, Timber Pharmaceuticals, Trevi Therapeutics, and UCB. She has received research fees from Amyrt, Castle Creek, Eli Lilly and Company, Novartis, Pfizer, and Regeneron, as well as consulting fees from AbbVie, Krystal Biotech, and Pyramid Bioscience.

Correspondence: Allison Kranyak, MD, 607 Grove Rd, Greenville, SC 29605 ([email protected]).

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Hereditary alpha tryptasemia (HaT), an autosomal-dominant disorder of tryptase overproduction, was first described in 2014 by Lyons et al.1 It has been associated with multiple dermatologic, allergic, gastrointestinal (GI) tract, neuropsychiatric, respiratory, autonomic, and connective tissue abnormalities. These multisystem concerns may include cutaneous flushing, chronic pruritus, urticaria, GI tract symptoms, arthralgia, and autonomic dysfunction.2 The diverse symptoms and the recent discovery of HaT make recognition of this disorder challenging. Currently, it also is believed that HaT is associated with an elevated risk for anaphylaxis and is a biomarker for severe symptoms in disorders with increased mast cell burden such as mastocytosis.3-5

Given the potential cutaneous manifestations and the fact that dermatologic symptoms may be the initial presentation of HaT, awareness and recognition of this condition by dermatologists are essential for diagnosis and treatment. This review summarizes the cutaneous presentations consistent with HaT and discusses various conditions that share overlapping dermatologic symptoms with HaT.

Background on HaT

Mast cells are known to secrete several vasoactive mediators including tryptase and histamine when activated by foreign substances, similar to IgE-mediated hypersensitivity reactions. In their baseline state, mast cells continuously secrete immature forms of tryptases called protryptases.6 These protryptases come in 2 forms: α and β. Although mature tryptase is acutely elevatedin anaphylaxis, persistently elevated total serum tryptase levels frequently are regarded as indicative of a systemic mast cell disorder such as systemic mastocytosis (SM).3 Despite the wide-ranging phenotype of HaT, all individuals with the disorder have an elevated basal serum tryptase level (>8 ng/mL). Hereditary alpha tryptasemia has been identified as another possible cause of persistently elevated levels.2,6

Genetics and Epidemiology of HaT—The humantryptase locus at chromosome 16p13.3 is composed of 4 paralog genes: TPSG1, TPSB2, TPSAB1, and TPSD1.4 Only TPSAB1 encodes for α-tryptase, while both TPSB2 and TPSAB1 encode for β-tryptase.4 Hereditary alpha tryptasemia is an autosomal-dominant disorder resulting from a copy number increase in the α-tryptase encoding sequence within the TPSAB1 gene. Despite the wide-ranging phenotype of HaT, all individuals identified with the disorder have a basal serum tryptase level greater than 8 ng/mL, with mean (SD) levels of 15 (5) ng/mL and 24 (6) ng/mL with gene duplication and triplication, respectively (reference range, 0–11.4 ng/mL).2,6 Hereditary alpha tryptasemia likely is common and largely undiagnosed, with a recently estimated prevalence of 5% in the United Kingdom7 and 5.6% in a cohort of 125 individuals from Italy, Slovenia, and the United States.5

Implications of Increased α-tryptase Levels—After an inciting stimulus, the active portions of α-protryptase and β-protryptase are secreted as tetramers by activated mast cells via degranulation. In vitro, β-tryptase homotetramers have been found to play a role in anaphylaxis, while α-homotetramers are nearly inactive.8,9 Recently, however, it has been discovered that α2β2 tetramers also can form and do so in a higher ratio in individuals with increased α-tryptase–encoding gene copies, such as those with HaT.8 These heterotetramers exhibit unique properties compared with the homotetramers and may stimulate epidermal growth factor–like module-containing mucinlike hormone receptor 2 and protease-activated receptor 2 (PAR2). Epidermal growth factor–like module-containing mucinlike hormone receptor 2 activation likely contributes to vibratory urticaria in patients, while activation of PAR2 may have a range of clinical effects, including worsening asthma, inflammatory bowel disease, pruritus, and the exacerbation of dermal inflammation and hyperalgesia.8,10 Thus, α- and β-tryptase tetramers can be considered mediators that may influence the severity of disorders in which mast cells are naturally prevalent and likely contribute to the phenotype of those with HaT.7 Furthermore, these characteristics have been shown to potentially increase in severity with increasing tryptase levels and with increased TPSAB1 duplications.1,2 In contrast, more than 25% of the population is deficient in α-tryptase without known deleterious effects.5

Cutaneous Manifestations of HaT

A case series reported by Lyons et al1 in 2014 detailed persistent elevated basal serum tryptase levels in 9 families with an autosomal-dominant pattern of inheritance. In this cohort, 31 of 33 (94%) affected individuals had a history of atopic dermatitis (AD), and 26 of 33 (79%) affected individuals reported symptoms consistent with mast cell degranulation, including urticaria; flushing; and/or crampy abdominal pain unprovoked or triggered by heat, exercise, vibration, stress, certain foods, or minor physical stimulation.1 A later report by Lyons et al2 in 2016 identified the TPSAB1 α-tryptase–encoding sequence copy number increase as the causative entity for HaT by examining a group of 96 patients from 35 families with frequent recurrent cutaneous flushing and pruritus, sometimes associated with urticaria and sleep disruption. Flushing and pruritus were found in 45% (33/73) of those with a TPSAB1 duplication and 80% (12/15) of those with a triplication (P=.022), suggesting a gene dose effect regarding α-tryptase encoding sequence copy number and these symptoms.2

A 2019 study further explored the clinical finding of urticaria in patients with HaT by specifically examining if vibration-induced urticaria was affected by TPSAB1 gene dosage.8 A cohort of 56 volunteers—35 healthy and 21 with HaT—underwent tryptase genotyping and cutaneous vibratory challenge. The presence of TPSAB1 was significantly correlated with induction of vibration-induced urticaria (P<.01), as the severity and prevalence of the urticarial response increased along with α- and β-tryptase gene ratios.8

 

 

Urticaria and angioedema also were seen in 51% (36/70) of patients in a cohort of HaT patients in the United Kingdom, in which 41% (29/70) also had skin flushing. In contrast to prior studies, these manifestations were not more common in patients with gene triplications or quintuplications than those with duplications.7 In another recent retrospective evaluation conducted at Brigham and Women’s Hospital (Boston, Massachusetts)(N=101), 80% of patients aged 4 to 85 years with confirmed diagnoses of HaT had skin manifestations such as urticaria, flushing, and pruritus.4

HaT and Mast Cell Activation Syndrome—In 2019, a Mast Cell Disorders Committee Work Group Report outlined recommendations for diagnosing and treating primary mast cell activation syndrome (MCAS), a disorder in which mast cells seem to be more easily activated. Mast cell activation syndrome is defined as a primary clinical condition in which there are episodic signs and symptoms of systemic anaphylaxis (Table) concurrently affecting at least 2 organ systems, resulting from secreted mast cell mediators.9,11 The 2019 report also touched on clinical criteria that lack precision for diagnosing MCAS yet are in use, including dermographism and several types of rashes.9 Episode triggers frequent in MCAS include hot water, alcohol, stress, exercise, infection, hormonal changes, and physical stimuli.

Symptoms of MCAS vs HaT

Hereditary alpha tryptasemia has been suggested to be a risk factor for MCAS, which also can be associated with SM and clonal MCAS.9 Patients with MCAS should be tested for increased α-tryptase gene copy number given the overlap in symptoms, the likely predisposition of those with HaT to develop MCAS, and the fact that these patients could be at an increased risk for anaphylaxis.4,7,9,11 However, the clinical phenotype for HaT includes allergic disorders affecting the skin as well as neuropsychiatric and connective tissue abnormalities that are distinctive from MCAS. Although HaT may be considered a heritable risk factor for MCAS, MCAS is only 1 potential phenotype associated with HaT.9

Implications of HaT

Hereditary alpha tryptasemia should be considered in all patients with basal tryptase levels greater than 8 ng/mL. Cutaneous symptoms are among the most common presentations for individuals with HaT and can include AD, chronic or episodic urticaria, pruritus, flushing, and angioedema. However, HaT is unique because of the coupling of these common dermatologic findings with other abnormalities, including abdominal pain and diarrhea, hypermobile joints, and autonomic dysfunction. Patients with HaT also may manifest psychiatric concerns of anxiety, depression, and chronic pain, all of which have been linked to this disorder.

It is unclear in HaT if the presence of extra-allelic copies of tryptase in an individual is directly pathogenic. The effects of increased basal tryptase and α2β2 tetramers have been shown to likely be responsible for some of the clinical features in these individuals but also may magnify other individual underlying disease(s) or diathesis in which mast cells are naturally abundant.8 In the skin, this increased mast cell activation and subsequent histamine release frequently are visible as dermatographia and urticaria. However, mast cell numbers also are known to be increased in both psoriatic and AD skin lesions,12 thus severe presentation of these diseases in conjunction with the other symptoms associated with mast cell activation should prompt suspicion for HaT.

Effects of HaT on Other Cutaneous Disease—Given the increase of mast cells in AD skin lesions and fact that 94% of patients in the 2014 Lyons et al1 study cited a history of AD, HaT may be a risk factor in the development of AD. Interestingly, in addition to the increased mast cells in AD lesions, PAR2+ nerve fibers also are increased in AD lesions and have been implicated in the nonhistaminergic pruritus experienced by patients with AD.12 Thus, given the proposed propensity for α2β2 tetramers to activate PAR2, it is possible this mechanism may contribute to severe pruritus in individuals with AD and concurrent HaT, as those with HaT express increased α2β2 tetramers. However, no study to date has directly compared AD symptoms in patients with concurrent HaT vs patients without it. Further research is needed on how HaT impacts other allergic and inflammatory skin diseases such as AD and psoriasis, but one may reasonably consider HaT when treating chronic inflammatory skin diseases refractory to typical interventions and/or severe presentations. Although HaT is an autosomal-dominant disorder, it is not detected by standard whole exome sequencing or microarrays. A commercial test is available, utilizing a buccal swab to test for TPSAB1 copy number.

HaT and Mast Cell Disorders—When evaluating someone with suspected HaT, it is important to screen for other symptoms of mast cell activation. For instance, in the GI tract increased mast cell activation results in activation of motor neurons and nociceptors and increases secretion and peristalsis with consequent bloating, abdominal pain, and diarrhea.10 Likewise, tryptase also has neuromodulatory effects that amplify the perception of pain and are likely responsible for the feelings of hyperalgesia reported in patients with HaT.13

 

 

There is substantial overlap in the clinical pictures of HaT and MCAS, and HaT is considered a heritable risk factor for MCAS. Consequently, any patient undergoing workup for MCAS also should be tested for HaT. Although HaT is associated with consistently elevated tryptase, MCAS is episodic in nature, and an increase in tryptase levels of at least 20% plus 2 ng/mL from baseline only in the presence of other symptoms reflective of mast cell activation (Table) is a prerequisite for diagnosis.9 Chronic signs and symptoms of atopy, chronic urticaria, and severe asthma are not indicative of MCAS but are frequently seen in HaT.

Another cause of persistently elevated tryptase levels is SM. Systemic mastocytosis is defined by aberrant clonal mast cell expansion and systemic involvement11 and can cause persistent symptoms, unlike MCAS alone. However, SM also can be associated with MCAS.9 Notably, a baseline serum tryptase level greater than 20 ng/mL—much higher than the threshold of greater than 8 ng/mL for suspicion of HaT—is seen in 75% of SM cases and is part of the minor diagnostic criteria for the disease.9,11 However, the 2016 study identifying increased TPSAB1 α-tryptase–encoding sequences as the causative entity for HaT by Lyons et al2 found the average (SD) basal serum tryptase level in individuals with α-tryptase–encoding sequence duplications to be 15 (5) ng/mL and 24 (6) ng/mL in those with triplications. Thus, there likely is no threshold for elevated baseline tryptase levels that would indicate SM over HaT as a more likely diagnosis. However, SM will present with new persistently elevated tryptase levels, whereas the elevation in HaT is believed to be lifelong.5 Also in contrast to HaT, SM can present with liver, spleen, and lymph node involvement; bone sclerosis; and cytopenia.11,14

Mastocytosis is much rarer than HaT, with an estimated prevalence of 9 cases per 100,000 individuals in the United States.11 Although HaT diagnostic testing is noninvasive, SM requires a bone marrow biopsy for definitive diagnosis. Given the likely much higher prevalence of HaT than SM and the patient burden of a bone marrow biopsy, HaT should be considered before proceeding with a bone marrow biopsy to evaluate for SM when a patient presents with persistent systemic symptoms of mast cell activation and elevated baseline tryptase levels. Furthermore, it also would be prudent to test for HaT in patients with known SM, as a cohort study by Lyons et al5 indicated that HaT is likely more common in those with SM (12.2% [10/82] of cohort with known SM vs 5.3% of 398 controls), and patients with concurrent SM and HaT were at a higher risk for severe anaphylaxis (RR=9.5; P=.007).

Studies thus far surrounding HaT have not evaluated timing of initial symptom onset or age of initial presentation for HaT. Furthermore, there is no guarantee that those with increased TPSAB1 copy number will be symptomatic, as there have been reports of asymptomatic individuals with HaT who had basal serum levels greater than 8 ng/mL.7 As research into HaT continues and larger cohorts are evaluated, questions surrounding timing of symptom onset and various factors that may make someone more likely to display a particular phenotype will be answered.

Treatment—Long-term prognosis for individuals with HaT is largely unknown. Unfortunately, there are limited data to support a single effective treatment strategy for managing HaT, and treatment has varied based on predominant symptoms. For cutaneous and GI tract symptoms, trials of maximal H1 and H2 antihistamines twice daily have been recommended.4 Omalizumab was reported to improve chronic urticaria in 3 of 3 patients, showing potential promise as a treatment.4 Mast cell stabilizers, such as oral cromolyn, have been used for severe GI symptoms, while some patients also have reported improvement with oral ketotifen.6 Other medications, such as tricyclic antidepressants, clemastine fumarate, and gabapentin, have been beneficial anecdotally.6 Given the lack of harmful effects seen in individuals who are α-tryptase deficient, α-tryptase inhibition is an intriguing target for future therapies.

Conclusion

Patients who present with a constellation of dermatologic, allergic, GI tract, neuropsychiatric, respiratory, autonomic, and connective tissue abnormalities consistent with HaT may receive a prompt diagnosis if the association is recognized. The full relationship between HaT and other chronic dermatologic disorders is still unknown. Ultimately, heightened interest and research into HaT will lead to more treatment options available for affected patients.

Hereditary alpha tryptasemia (HaT), an autosomal-dominant disorder of tryptase overproduction, was first described in 2014 by Lyons et al.1 It has been associated with multiple dermatologic, allergic, gastrointestinal (GI) tract, neuropsychiatric, respiratory, autonomic, and connective tissue abnormalities. These multisystem concerns may include cutaneous flushing, chronic pruritus, urticaria, GI tract symptoms, arthralgia, and autonomic dysfunction.2 The diverse symptoms and the recent discovery of HaT make recognition of this disorder challenging. Currently, it also is believed that HaT is associated with an elevated risk for anaphylaxis and is a biomarker for severe symptoms in disorders with increased mast cell burden such as mastocytosis.3-5

Given the potential cutaneous manifestations and the fact that dermatologic symptoms may be the initial presentation of HaT, awareness and recognition of this condition by dermatologists are essential for diagnosis and treatment. This review summarizes the cutaneous presentations consistent with HaT and discusses various conditions that share overlapping dermatologic symptoms with HaT.

Background on HaT

Mast cells are known to secrete several vasoactive mediators including tryptase and histamine when activated by foreign substances, similar to IgE-mediated hypersensitivity reactions. In their baseline state, mast cells continuously secrete immature forms of tryptases called protryptases.6 These protryptases come in 2 forms: α and β. Although mature tryptase is acutely elevatedin anaphylaxis, persistently elevated total serum tryptase levels frequently are regarded as indicative of a systemic mast cell disorder such as systemic mastocytosis (SM).3 Despite the wide-ranging phenotype of HaT, all individuals with the disorder have an elevated basal serum tryptase level (>8 ng/mL). Hereditary alpha tryptasemia has been identified as another possible cause of persistently elevated levels.2,6

Genetics and Epidemiology of HaT—The humantryptase locus at chromosome 16p13.3 is composed of 4 paralog genes: TPSG1, TPSB2, TPSAB1, and TPSD1.4 Only TPSAB1 encodes for α-tryptase, while both TPSB2 and TPSAB1 encode for β-tryptase.4 Hereditary alpha tryptasemia is an autosomal-dominant disorder resulting from a copy number increase in the α-tryptase encoding sequence within the TPSAB1 gene. Despite the wide-ranging phenotype of HaT, all individuals identified with the disorder have a basal serum tryptase level greater than 8 ng/mL, with mean (SD) levels of 15 (5) ng/mL and 24 (6) ng/mL with gene duplication and triplication, respectively (reference range, 0–11.4 ng/mL).2,6 Hereditary alpha tryptasemia likely is common and largely undiagnosed, with a recently estimated prevalence of 5% in the United Kingdom7 and 5.6% in a cohort of 125 individuals from Italy, Slovenia, and the United States.5

Implications of Increased α-tryptase Levels—After an inciting stimulus, the active portions of α-protryptase and β-protryptase are secreted as tetramers by activated mast cells via degranulation. In vitro, β-tryptase homotetramers have been found to play a role in anaphylaxis, while α-homotetramers are nearly inactive.8,9 Recently, however, it has been discovered that α2β2 tetramers also can form and do so in a higher ratio in individuals with increased α-tryptase–encoding gene copies, such as those with HaT.8 These heterotetramers exhibit unique properties compared with the homotetramers and may stimulate epidermal growth factor–like module-containing mucinlike hormone receptor 2 and protease-activated receptor 2 (PAR2). Epidermal growth factor–like module-containing mucinlike hormone receptor 2 activation likely contributes to vibratory urticaria in patients, while activation of PAR2 may have a range of clinical effects, including worsening asthma, inflammatory bowel disease, pruritus, and the exacerbation of dermal inflammation and hyperalgesia.8,10 Thus, α- and β-tryptase tetramers can be considered mediators that may influence the severity of disorders in which mast cells are naturally prevalent and likely contribute to the phenotype of those with HaT.7 Furthermore, these characteristics have been shown to potentially increase in severity with increasing tryptase levels and with increased TPSAB1 duplications.1,2 In contrast, more than 25% of the population is deficient in α-tryptase without known deleterious effects.5

Cutaneous Manifestations of HaT

A case series reported by Lyons et al1 in 2014 detailed persistent elevated basal serum tryptase levels in 9 families with an autosomal-dominant pattern of inheritance. In this cohort, 31 of 33 (94%) affected individuals had a history of atopic dermatitis (AD), and 26 of 33 (79%) affected individuals reported symptoms consistent with mast cell degranulation, including urticaria; flushing; and/or crampy abdominal pain unprovoked or triggered by heat, exercise, vibration, stress, certain foods, or minor physical stimulation.1 A later report by Lyons et al2 in 2016 identified the TPSAB1 α-tryptase–encoding sequence copy number increase as the causative entity for HaT by examining a group of 96 patients from 35 families with frequent recurrent cutaneous flushing and pruritus, sometimes associated with urticaria and sleep disruption. Flushing and pruritus were found in 45% (33/73) of those with a TPSAB1 duplication and 80% (12/15) of those with a triplication (P=.022), suggesting a gene dose effect regarding α-tryptase encoding sequence copy number and these symptoms.2

A 2019 study further explored the clinical finding of urticaria in patients with HaT by specifically examining if vibration-induced urticaria was affected by TPSAB1 gene dosage.8 A cohort of 56 volunteers—35 healthy and 21 with HaT—underwent tryptase genotyping and cutaneous vibratory challenge. The presence of TPSAB1 was significantly correlated with induction of vibration-induced urticaria (P<.01), as the severity and prevalence of the urticarial response increased along with α- and β-tryptase gene ratios.8

 

 

Urticaria and angioedema also were seen in 51% (36/70) of patients in a cohort of HaT patients in the United Kingdom, in which 41% (29/70) also had skin flushing. In contrast to prior studies, these manifestations were not more common in patients with gene triplications or quintuplications than those with duplications.7 In another recent retrospective evaluation conducted at Brigham and Women’s Hospital (Boston, Massachusetts)(N=101), 80% of patients aged 4 to 85 years with confirmed diagnoses of HaT had skin manifestations such as urticaria, flushing, and pruritus.4

HaT and Mast Cell Activation Syndrome—In 2019, a Mast Cell Disorders Committee Work Group Report outlined recommendations for diagnosing and treating primary mast cell activation syndrome (MCAS), a disorder in which mast cells seem to be more easily activated. Mast cell activation syndrome is defined as a primary clinical condition in which there are episodic signs and symptoms of systemic anaphylaxis (Table) concurrently affecting at least 2 organ systems, resulting from secreted mast cell mediators.9,11 The 2019 report also touched on clinical criteria that lack precision for diagnosing MCAS yet are in use, including dermographism and several types of rashes.9 Episode triggers frequent in MCAS include hot water, alcohol, stress, exercise, infection, hormonal changes, and physical stimuli.

Symptoms of MCAS vs HaT

Hereditary alpha tryptasemia has been suggested to be a risk factor for MCAS, which also can be associated with SM and clonal MCAS.9 Patients with MCAS should be tested for increased α-tryptase gene copy number given the overlap in symptoms, the likely predisposition of those with HaT to develop MCAS, and the fact that these patients could be at an increased risk for anaphylaxis.4,7,9,11 However, the clinical phenotype for HaT includes allergic disorders affecting the skin as well as neuropsychiatric and connective tissue abnormalities that are distinctive from MCAS. Although HaT may be considered a heritable risk factor for MCAS, MCAS is only 1 potential phenotype associated with HaT.9

Implications of HaT

Hereditary alpha tryptasemia should be considered in all patients with basal tryptase levels greater than 8 ng/mL. Cutaneous symptoms are among the most common presentations for individuals with HaT and can include AD, chronic or episodic urticaria, pruritus, flushing, and angioedema. However, HaT is unique because of the coupling of these common dermatologic findings with other abnormalities, including abdominal pain and diarrhea, hypermobile joints, and autonomic dysfunction. Patients with HaT also may manifest psychiatric concerns of anxiety, depression, and chronic pain, all of which have been linked to this disorder.

It is unclear in HaT if the presence of extra-allelic copies of tryptase in an individual is directly pathogenic. The effects of increased basal tryptase and α2β2 tetramers have been shown to likely be responsible for some of the clinical features in these individuals but also may magnify other individual underlying disease(s) or diathesis in which mast cells are naturally abundant.8 In the skin, this increased mast cell activation and subsequent histamine release frequently are visible as dermatographia and urticaria. However, mast cell numbers also are known to be increased in both psoriatic and AD skin lesions,12 thus severe presentation of these diseases in conjunction with the other symptoms associated with mast cell activation should prompt suspicion for HaT.

Effects of HaT on Other Cutaneous Disease—Given the increase of mast cells in AD skin lesions and fact that 94% of patients in the 2014 Lyons et al1 study cited a history of AD, HaT may be a risk factor in the development of AD. Interestingly, in addition to the increased mast cells in AD lesions, PAR2+ nerve fibers also are increased in AD lesions and have been implicated in the nonhistaminergic pruritus experienced by patients with AD.12 Thus, given the proposed propensity for α2β2 tetramers to activate PAR2, it is possible this mechanism may contribute to severe pruritus in individuals with AD and concurrent HaT, as those with HaT express increased α2β2 tetramers. However, no study to date has directly compared AD symptoms in patients with concurrent HaT vs patients without it. Further research is needed on how HaT impacts other allergic and inflammatory skin diseases such as AD and psoriasis, but one may reasonably consider HaT when treating chronic inflammatory skin diseases refractory to typical interventions and/or severe presentations. Although HaT is an autosomal-dominant disorder, it is not detected by standard whole exome sequencing or microarrays. A commercial test is available, utilizing a buccal swab to test for TPSAB1 copy number.

HaT and Mast Cell Disorders—When evaluating someone with suspected HaT, it is important to screen for other symptoms of mast cell activation. For instance, in the GI tract increased mast cell activation results in activation of motor neurons and nociceptors and increases secretion and peristalsis with consequent bloating, abdominal pain, and diarrhea.10 Likewise, tryptase also has neuromodulatory effects that amplify the perception of pain and are likely responsible for the feelings of hyperalgesia reported in patients with HaT.13

 

 

There is substantial overlap in the clinical pictures of HaT and MCAS, and HaT is considered a heritable risk factor for MCAS. Consequently, any patient undergoing workup for MCAS also should be tested for HaT. Although HaT is associated with consistently elevated tryptase, MCAS is episodic in nature, and an increase in tryptase levels of at least 20% plus 2 ng/mL from baseline only in the presence of other symptoms reflective of mast cell activation (Table) is a prerequisite for diagnosis.9 Chronic signs and symptoms of atopy, chronic urticaria, and severe asthma are not indicative of MCAS but are frequently seen in HaT.

Another cause of persistently elevated tryptase levels is SM. Systemic mastocytosis is defined by aberrant clonal mast cell expansion and systemic involvement11 and can cause persistent symptoms, unlike MCAS alone. However, SM also can be associated with MCAS.9 Notably, a baseline serum tryptase level greater than 20 ng/mL—much higher than the threshold of greater than 8 ng/mL for suspicion of HaT—is seen in 75% of SM cases and is part of the minor diagnostic criteria for the disease.9,11 However, the 2016 study identifying increased TPSAB1 α-tryptase–encoding sequences as the causative entity for HaT by Lyons et al2 found the average (SD) basal serum tryptase level in individuals with α-tryptase–encoding sequence duplications to be 15 (5) ng/mL and 24 (6) ng/mL in those with triplications. Thus, there likely is no threshold for elevated baseline tryptase levels that would indicate SM over HaT as a more likely diagnosis. However, SM will present with new persistently elevated tryptase levels, whereas the elevation in HaT is believed to be lifelong.5 Also in contrast to HaT, SM can present with liver, spleen, and lymph node involvement; bone sclerosis; and cytopenia.11,14

Mastocytosis is much rarer than HaT, with an estimated prevalence of 9 cases per 100,000 individuals in the United States.11 Although HaT diagnostic testing is noninvasive, SM requires a bone marrow biopsy for definitive diagnosis. Given the likely much higher prevalence of HaT than SM and the patient burden of a bone marrow biopsy, HaT should be considered before proceeding with a bone marrow biopsy to evaluate for SM when a patient presents with persistent systemic symptoms of mast cell activation and elevated baseline tryptase levels. Furthermore, it also would be prudent to test for HaT in patients with known SM, as a cohort study by Lyons et al5 indicated that HaT is likely more common in those with SM (12.2% [10/82] of cohort with known SM vs 5.3% of 398 controls), and patients with concurrent SM and HaT were at a higher risk for severe anaphylaxis (RR=9.5; P=.007).

Studies thus far surrounding HaT have not evaluated timing of initial symptom onset or age of initial presentation for HaT. Furthermore, there is no guarantee that those with increased TPSAB1 copy number will be symptomatic, as there have been reports of asymptomatic individuals with HaT who had basal serum levels greater than 8 ng/mL.7 As research into HaT continues and larger cohorts are evaluated, questions surrounding timing of symptom onset and various factors that may make someone more likely to display a particular phenotype will be answered.

Treatment—Long-term prognosis for individuals with HaT is largely unknown. Unfortunately, there are limited data to support a single effective treatment strategy for managing HaT, and treatment has varied based on predominant symptoms. For cutaneous and GI tract symptoms, trials of maximal H1 and H2 antihistamines twice daily have been recommended.4 Omalizumab was reported to improve chronic urticaria in 3 of 3 patients, showing potential promise as a treatment.4 Mast cell stabilizers, such as oral cromolyn, have been used for severe GI symptoms, while some patients also have reported improvement with oral ketotifen.6 Other medications, such as tricyclic antidepressants, clemastine fumarate, and gabapentin, have been beneficial anecdotally.6 Given the lack of harmful effects seen in individuals who are α-tryptase deficient, α-tryptase inhibition is an intriguing target for future therapies.

Conclusion

Patients who present with a constellation of dermatologic, allergic, GI tract, neuropsychiatric, respiratory, autonomic, and connective tissue abnormalities consistent with HaT may receive a prompt diagnosis if the association is recognized. The full relationship between HaT and other chronic dermatologic disorders is still unknown. Ultimately, heightened interest and research into HaT will lead to more treatment options available for affected patients.

References

1. Lyons JJ, Sun G, Stone KD, et al. Mendelian inheritance of elevated serum tryptase associated with atopy and connective tissue abnormalities. J Allergy Clin Immunol. 2014;133:1471-1474.

2. Lyons JJ, Yu X, Hughes JD, et al. Elevated basal serum tryptase identifies a multisystem disorder associated with increased TPSAB1 copy number. Nat Genet. 2016;48:1564-1569.

3. Schwartz L. Diagnostic value of tryptase in anaphylaxis and mastocytosis. Immunol Allergy Clin North Am. 2006;6:451-463.

4. Giannetti MP, Weller E, Bormans C, et al. Hereditary alpha-tryptasemia in 101 patients with mast cell activation–related symptomatology including anaphylaxis. Ann Allergy Asthma Immunol. 2021;126:655-660.

5. Lyons JJ, Chovanec J, O’Connell MP, et al. Heritable risk for severe anaphylaxis associated with increased α-tryptase–encoding germline copy number at TPSAB1. J Allergy Clin Immunol. 2020;147:622-632.

6. Lyons JJ. Hereditary alpha tryptasemia: genotyping and associated clinical features. Immunol Allergy Clin North Am. 2018;38:483-495.

7. Robey RC, Wilcock A, Bonin H, et al. Hereditary alpha-tryptasemia: UK prevalence and variability in disease expression. J Allergy Clin Immunol Pract. 2020;8:3549-3556.

8. Le QT, Lyons JJ, Naranjo AN, et al. Impact of naturally forming human α/β-tryptase heterotetramers in the pathogenesis of hereditary α-tryptasemia. J Exp Med. 2019;216:2348-2361.

9. Weiler CR, Austen KF, Akin C, et al. AAAAI Mast Cell Disorders Committee Work Group Report: mast cell activation syndrome (MCAS) diagnosis and management. J Allergy Clin Immunol. 2019;144:883-896.

10. Ramsay DB, Stephen S, Borum M, et al. Mast cells in gastrointestinal disease. Gastroenterol Hepatol (N Y). 2010;6:772-777.

11. Giannetti A, Filice E, Caffarelli C, et al. Mast cell activation disorders. Medicina (Kaunas). 2021;57:124.

12. Siiskonen H, Harvima I. Mast cells and sensory nerves contribute to neurogenic inflammation and pruritus in chronic skin inflammation. Front Cell Neurosci. 2019;13:422.

13. Varrassi G, Fusco M, Skaper SD, et al. A pharmacological rationale to reduce the incidence of opioid induced tolerance and hyperalgesia: a review. Pain Ther. 2018;7:59-75.

14. Núñez E, Moreno-Borque R, García-Montero A, et al. Serum tryptase monitoring in indolent systemic mastocytosis: association with disease features and patient outcome. PLoS One. 2013;8:E76116.

References

1. Lyons JJ, Sun G, Stone KD, et al. Mendelian inheritance of elevated serum tryptase associated with atopy and connective tissue abnormalities. J Allergy Clin Immunol. 2014;133:1471-1474.

2. Lyons JJ, Yu X, Hughes JD, et al. Elevated basal serum tryptase identifies a multisystem disorder associated with increased TPSAB1 copy number. Nat Genet. 2016;48:1564-1569.

3. Schwartz L. Diagnostic value of tryptase in anaphylaxis and mastocytosis. Immunol Allergy Clin North Am. 2006;6:451-463.

4. Giannetti MP, Weller E, Bormans C, et al. Hereditary alpha-tryptasemia in 101 patients with mast cell activation–related symptomatology including anaphylaxis. Ann Allergy Asthma Immunol. 2021;126:655-660.

5. Lyons JJ, Chovanec J, O’Connell MP, et al. Heritable risk for severe anaphylaxis associated with increased α-tryptase–encoding germline copy number at TPSAB1. J Allergy Clin Immunol. 2020;147:622-632.

6. Lyons JJ. Hereditary alpha tryptasemia: genotyping and associated clinical features. Immunol Allergy Clin North Am. 2018;38:483-495.

7. Robey RC, Wilcock A, Bonin H, et al. Hereditary alpha-tryptasemia: UK prevalence and variability in disease expression. J Allergy Clin Immunol Pract. 2020;8:3549-3556.

8. Le QT, Lyons JJ, Naranjo AN, et al. Impact of naturally forming human α/β-tryptase heterotetramers in the pathogenesis of hereditary α-tryptasemia. J Exp Med. 2019;216:2348-2361.

9. Weiler CR, Austen KF, Akin C, et al. AAAAI Mast Cell Disorders Committee Work Group Report: mast cell activation syndrome (MCAS) diagnosis and management. J Allergy Clin Immunol. 2019;144:883-896.

10. Ramsay DB, Stephen S, Borum M, et al. Mast cells in gastrointestinal disease. Gastroenterol Hepatol (N Y). 2010;6:772-777.

11. Giannetti A, Filice E, Caffarelli C, et al. Mast cell activation disorders. Medicina (Kaunas). 2021;57:124.

12. Siiskonen H, Harvima I. Mast cells and sensory nerves contribute to neurogenic inflammation and pruritus in chronic skin inflammation. Front Cell Neurosci. 2019;13:422.

13. Varrassi G, Fusco M, Skaper SD, et al. A pharmacological rationale to reduce the incidence of opioid induced tolerance and hyperalgesia: a review. Pain Ther. 2018;7:59-75.

14. Núñez E, Moreno-Borque R, García-Montero A, et al. Serum tryptase monitoring in indolent systemic mastocytosis: association with disease features and patient outcome. PLoS One. 2013;8:E76116.

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  • Chronic or episodic urticaria, flushing, and pruritus are the most consistent cutaneous abnormalities associated with hereditary alpha tryptasemia (HaT), but HaT also may augment symptoms of other underlying inflammatory skin disorders, such as atopic dermatitis and psoriasis.
  • Individuals with episodic dermatologic manifestations indicative of mast cell activation accompanied by symptoms affecting 1 or more organ systems should be evaluated for mast cell activation syndrome as well as HaT.
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