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Birt–Hogg–Dubé syndrome

January 08, 2023

Birt–Hogg–Dubé syndrome (BHD), also Hornstein–Birt–Hogg–Dubé syndrome, Hornstein–Knickenberg syndrome, and fibrofolliculomas with trichodiscomas and acrochordons[1] is a human autosomal dominant genetic disorder that can cause susceptibility to kidney cancer, renal and pulmonary cysts, and noncancerous tumors of the hair follicles, called fibrofolliculomas. The symptoms seen in each family are unique, and can include any combination of the three symptoms. Fibrofolliculomas are the most common manifestation, found on the face and upper trunk in over 80% of people with BHD over the age of 40. Pulmonary cysts are equally common (84%), but only 24% of people with BHD eventually experience a collapsed lung (spontaneous pneumothorax). Kidney tumors, both cancerous and benign, occur in 14–34% of people with BHD; the associated kidney cancers are often rare hybrid tumors.

Birt–Hogg–Dubé syndrome
The characteristic fibrofolliculomas of Birt–Hogg–Dubé syndrome seen on a person's face.
SpecialtyMedical genetics 

Any of these conditions that occurs in a family can indicate a diagnosis of Birt–Hogg–Dubé syndrome, though it is only confirmed by a genetic test for a mutation in the FLCN gene, which codes for the protein folliculin. Though its function is not fully understood, it appears to be a tumor suppressor gene that restricts cell growth and division. Versions of FLCN have been found in other animals, including fruit flies, German Shepherds, rats, and mice. The disease was discovered in 1977, but the connection with FLCN was not elucidated until 2002, after kidney cancer, collapsed lungs, and pulmonary cysts were all definitively connected to BHD.

Birt–Hogg–Dubé syndrome can manifest similarly to other diseases, which must be ruled out when making a diagnosis. These include tuberous sclerosis, which causes skin lesions similar to fibrofolliculomas, and Von Hippel–Lindau disease, which causes hereditary kidney cancers. Once diagnosed, people with BHD are treated preventatively, with monitoring of kidneys and lungs using medical imaging. Fibrofolliculomas can be removed surgically and pneumothorax and kidney cancer are treated according to the normal standard of care. Dermatologic examinations, neck ultrasounds and colonoscopies should be considered as well [1].

Signs and symptoms

Skin

 
 
Individual with Birt–Hogg–Dubé syndrome, showing the characteristic facial fibrofolliculomas

Birt–Hogg–Dubé syndrome affects the skin and increases the risk of tumors in the kidneys and lungs. The condition is characterized by multiple noncancerous, dome-shaped tumors of the hair follicles (fibrofolliculomas), particularly on the face, neck, and more rarely, the upper chest.[2] The fibrofolliculomas are generally described as having an opaque white color[3] or a yellowish tone[4] and have a waxy, smooth texture.[3] The tumors are always found on and around the nose and on and behind the outer ear. Typically, they first appear in a person's 20s or 30s, and are found in more than 80% of people with the syndrome above the age of 40.[2] The tumors become larger and more numerous over time.[5] Tumors differ between individuals; they may appear merged in plaques, look similar to a comedo with a plug of keratin, or include epidermoid cysts. A large number of tumors on the face can be associated with hyperseborrhea (abnormally elevated sebum production).[2] The presence of fibrofolliculomas on a person's face can cause significant psychological distress.[6]

Other tumors can include trichodiscomas (tumors of the hair disc, which may be identical to fibrofolliculomas), angiofibromas, and perifollicular fibromas.[5] However, angiofibromas are more common in tuberous sclerosis.[6] Along with the tumors, other skin conditions are seen in people with Birt–Hogg–Dubé syndrome. About 40% of people or families with the disease have papules in their mouths, which can be located on the cheeks (buccal mucosa), tongue, gums, or lips. Either white or mucosa-colored, they are discrete, small, and soft, and consist of fibrous tissue covered in thickened epithelium.[2] Collagenomas of the skin are also found in some families.[5] Many people with BHD have skin lesions that appear to be acrochordons (skin tags), but may instead be fibrofolliculomas. These lesions are usually found in the armpit, on the eyelids, and in folds of skin.[3] Not all individuals develop the facial tumors; some families with the mutation that causes BHD develop only kidney tumors or spontaneous pneumothorax.[5]

Kidneys

 
An H&E stain of tissue from a chromophobe renal cell carcinoma, the second-most common cancer associated with BHD

People over 20 years of age with BHD have an increased risk of developing slow-growing kidney tumors (chromophobe renal carcinoma and renal oncocytoma, respectively), kidney cysts, and possibly tumors in other organs and tissues.[2] These tumors often occur in both kidneys and in multiple locations in each kidney.[5] The average number of kidney tumors found in a person with BHD is 5.3, though up to 28 tumors have been found.[7] Hybrid oncocytoma/chromophobe carcinoma, found in 50% of cases,[8] is the most commonly found cancer, followed by chromophobe renal carcinoma, clear cell renal carcinoma, renal oncocytoma, and papillary renal cell carcinoma.[5][8] People over 40 years old and men are more likely to develop kidney tumors, which are diagnosed at a median age of 48.[2][5] Kidney cancer associated with BHD have been diagnosed in people at ages as young as 20.[6]

In general, people with this syndrome are at roughly at seven times the risk of kidney cancer compared to the unaffected population. Estimates of the incidence among people with the disease range from 14 to 34%.[2][8] Rarely, it is associated with clear cell renal cell carcinoma and papillary renal cell carcinoma.[5] If it develops in someone with BHD, renal cell carcinoma occurs later in life and has a poor prognosis.[9] Though the types of tumors typically associated with BHD are considered less aggressive, cases of advanced or metastatic kidney cancer have been observed in people with the syndrome. Both benign and cancerous tumors can reduce kidney function over time as they grow larger.[8]

Lungs

Along with fibrofolliculomas and kidney tumors, affected individuals frequently develop cysts (blebs or bullae) in the subpleural lung base or intraparenchymal space that may rupture and cause an abnormal collection of air in the chest cavity (pneumothorax), which could result in the collapse of a lung.[5][10] The cysts do not cause other symptoms[5] and lung function is usually normal.[6] More than 83% of people with BHD have cysts, but the syndrome does not cause conditions like progressive chronic obstructive pulmonary disease or generalized respiratory failure,[2] though it does cause emphysema.[4] Spontaneous, sometimes recurrent,[5] pneumothorax occurs far more often and at a younger age with BHD than in the unaffected population. Around 24% of people with the disease have at least one spontaneous pneumothorax, 30 times the occurrence in unaffected people. Though pneumothorax caused by BHD often occurs in middle age, at a median age of 38, 17% of affected people have a spontaneous pneumothorax before turning 40.[2] Pneumothoraces have been seen in people as young as 7 and 16 years of age.[6] Some families have a form of BHD that only affects the lungs.[11]

Other organs

Thyroid nodules[2] have been associated with the Birt–Hogg–Dubé phenotype, present in 65% of individuals and 90% of families with the syndrome.[2] However, a connection between BHD and thyroid cancer has not been substantiated.[3] Other conditions have been reported to be associated, but may not be caused by the mutation in FLCN or may not be related at all. These include multinodular goiter, medullary thyroid carcinoma, parotid oncocytoma, colonic polyposis,[12] connective tissue nevus, lipomas, angiolipomas, parathyroid adenomas, flecked chorioretinopathy, neurothekeoma, meningiomas, angiofibromas of the face,[3] trichoblastomas, cutaneous focal mucinosis, cutaneous leiomyoma, breast cancer, tonsillar cancer, colorectal cancer, sarcoma of the leg, lung cancer, melanoma, dermatofibrosarcoma protuberans, basal cell carcinoma, cutaneous leiomyosarcoma, and squamous cell carcinoma.[6]

Pathophysiology

Genetics

 
This diagram shows how autosomal dominant disorders like BHD are passed on. The unaffected parent produces all normal gametes (sperm and egg) and the affected parent produces half mutant gametes and half normal gametes. Because only one copy of the mutation is needed to have an autosomal dominant disease, each offspring has a 50% chance of having the mutation.

An association with the folliculin (FLCN) gene was first reported in 2002.[13] This 14-exon gene is located on the short arm of chromosome 17 (17p11.2) and has a cytosine-rich region in exon 11 particularly susceptible to mutation.[2][5] The most common mutation in this region is the insertion or deletion of a cytosine residue, found in 53% of BHD-affected families. No significant difference has been found in the symptoms experienced by families with an insertion at that location compared to those who have a deletion, but mutations in FLCN associated with BHD syndrome are heterogeneous, and are often nonsense mutations or frameshift mutations that cause early truncation of the protein product at the carboxy terminus.[14][3] Very rarely, missense mutations are observed.[6] The mutations in the FLCN gene that cause Birt–Hogg–Dubé syndrome are germline mutations, which means that they occur in every cell of the body and can be passed down to future generations.[15] These mutations are often passed from one generation to the next in an autosomal dominant fashion, but can occur as a new mutation in an individual with no prior family history (a de novo mutation).[16] The children of an affected parent each has a 50% chance of having the disease. BHD has very high penetrance.[5] A correlation between different FLCN genotypes and phenotypes has not been discovered.[16]

Function

FLCN creates a protein, folliculin, that has two isoforms.[3] It appears to act as a tumor suppressor, and is expressed strongly in the skin, distal nephrons, and type I pneumocytes.[5] It has also been found in the parotid gland, brain, breast, pancreas, prostate, and ovaries.[8][4] Tumor suppressors normally prevent cells from growing and dividing too rapidly or in an uncontrolled way. Mutations in the FLCN gene may interfere with the ability of folliculin to restrain cell growth and division, leading to the formation of noncancerous and cancerous tumors. Recent studies suggest that folliculin accomplishes this function through its involvement with cellular metabolism, possibly through modulation of the mTOR (mammalian target of rapamycin) pathway and/or oxidative phosphorylation in mitochondria.[17] Folliculin interacts with FNIP1 and FNIP2 (FLCN-interacting protein) to form a complex with AMP-activated protein kinase.[8][4] Folliculin's participation in the mTOR pathway may explain the similarity in phenotype between BHD syndrome, Cowden syndrome, tuberous sclerosis, and Peutz–Jeghers syndrome.[3]

Most of the cancer-causing mutations cause the protein to be truncated at the carboxy terminus.[8] The C-terminal end of folliculin has shown to be the domain through which it interacts with FNIP1, and thereby possibly the mTOR pathway.[14] FLCN is highly conserved in vertebrates—it is very similar between many vertebrate species.[5] The 508th amino acid, normally lysine, is affected by a missense mutation in some people with BHD. The lysine at this position is found to be conserved between invertebrate and vertebrate orthologs of folliculin, indicating that it is important to the protein's function.[14]

 
Folliculin is encoded by the FLCN gene, located on the p arm of human chromosome 17.

People with BHD are born with one mutated copy of the FLCN gene in each cell.[6] Haploinsufficiency—only having one functional copy of the FLCN gene—is enough to cause the fibrofolliculomas and pulmonary cysts, though one copy of the gene is enough to keep kidney cells in check.[1] During a person's lifetime, random mutations might inactivate the normal copy of the gene in a subset of cells. When this occurs, the result is that these cells have no functional copies of the FLCN gene, allowing the cells grow out of control. This loss of heterozygosity is a common mechanism in cancer, and it is frequently detected in the renal cancers associated with BHD. The molecular genetic defects in renal tumors of people with BHD are different from two other similar kidney tumors, chromophobe renal cell carcinoma and renal oncocytoma. BHD-associated tumorigenesis differs between the kidney, where loss of FLCN heterozygosity is responsible for cancers, and the skin, where FLCN is strongly expressed in heterozygotes.[6] FLCN has been found to be overexpressed in fibrofolliculoma tissue, and to have very low levels of expression in affected kidneys.[4] Furthermore, the mTOR pathway is shown to be activated in tumor tissue from both humans and mice.[7]

Renal cystogenesis and tumorigenesis in BHD have been shown to be driven by the constitutive activation of TFEB.[18]

Diagnosis

BHD can be suggested by clinical findings but is definitively diagnosed by molecular genetic testing to detect mutations in the FLCN gene. The classical clinical triad includes benign growths of the hair follicles, pulmonary cysts and spontaneous pneumothorax, and bilateral, multifocal renal tumors.[5]

Clinical triad

See also: List of cutaneous neoplasms associated with systemic syndromes

The cutaneous manifestations of BHD were originally described as fibrofolliculomas (abnormal growths of a hair follicle), trichodiscomas (hamartomatous lesions with a hair follicle at the periphery, often found on the face), and acrochordons (skin tags). Cutaneous manifestations are confirmed by histology. Most individuals (89%) with BHD are found to have multiple cysts in both lungs, and 24% have had one or more episodes of pneumothorax. The cysts can be detected by chest CT scan. Renal tumors can manifest as multiple types of renal cell carcinoma, but certain pathological subtypes (including chromophobe, oncocytoma, and oncocytic hybrid tumors) are more commonly seen. Although the original syndrome was discovered on the basis of cutaneous findings, individuals with BHD may only manifest the pulmonary and/or renal findings, without any skin lesions. Though these signs indicate BHD, it is only confirmed with a genetic test for FLCN mutations.[5]

Genetic testing

FLCN mutations are detected by sequencing in 88% of probands with this syndrome. This means that some people with the clinical diagnosis have mutations that are not detectable by current technology, or that mutations in another currently unknown gene could be responsible for a minority of cases. In addition, amplifications and deletions in exonic regions are also tested. Genetic testing can be useful to confirm the clinical diagnosis and to provide a means of determining other at-risk individuals in a family even if they have not yet developed BHD symptoms.[5][6]

Differential diagnosis

 
The person in this image has tuberous sclerosis. The skin lesions caused by tuberous sclerosis (angiofibromas) must be distinguished from the characteristic fibrofolliculomas of BHD, which also occur primarily on the face.

BHD can be difficult to diagnose from symptoms alone, because hereditary renal cancers, pneumothorax, and cutaneous tumors occur with other syndromes. Hereditary bilateral, multifocal kidney tumors similar to those seen in BHD can occur with von Hippel–Lindau disease (clear cell renal cell carcinoma), hereditary papillary renal cancer (papillary renal cell carcinoma), and hereditary leiomyomatosis and renal cell cancer syndrome. They are differentiated with examination of the tumors' histology.[5]

Hereditary recurrent pneumothorax or pulmonary cysts are associated with Marfan syndrome, Ehlers–Danlos syndrome, tuberous sclerosis complex, alpha1-antitrypsin deficiency, and cystic fibrosis. Nonhereditary recurrent pneumothorax and/or pulmonary cysts can occur with Langerhans cell histiocytosis and lymphangioleiomyomatosis. These conditions are differentiated from BHD through examining the patient history and performing a physical examination.[5] In women suspected to have the disease, ruling out pulmonary or thoracic endometriosis may be necessary.[9]

Though fibrofolliculomas are unique to BHD, they may present with an ambiguous appearance and must be confirmed histologically. Other diseases can mimic the dermatologic manifestations of BHD, including tuberous sclerosis complex, Cowden syndrome, familial trichoepitheliomas, and multiple endocrine neoplasia type 1.[5] Tuberous sclerosis must be distinguished because both disorders can present with angiofibromas on the face, though they are more common in tuberous sclerosis.[6]

Management

The different manifestations of BHD are controlled in different ways. The fibrofolliculomas can be removed surgically, through curettage, shave excision, skin resurfacing, or laser ablation; this is not a permanent solution, though, as the tumors often recur.[2][5] Dermatologic examination every 6-12 months due to risk of melanoma . Thyroid/parotid ultrasound should be considered annually. Colonoscopies should be considered. The renal and pulmonary symptoms are managed preventatively: CT scans, ultrasounds, or MRIs of the kidneys are recommended regularly, and family members are advised not to smoke.[2] MRIs are the preferred method for surveillance of the kidneys in people with BHD because they do not carry the same risk of radiation complications as CT scans, and are more sensitive than ultrasounds.[6] Smokers with Birt–Hogg–Dubé have more severe pulmonary symptoms than non-smokers.[19][6] Though nephrectomy is sometimes indicated, kidney tumors in cases of BHD are often removed without taking the whole kidney, in a partial nephrectomy.[5] Knockout mouse studies have shown that administration of rapamycin may mitigate the effects of FLCN mutations on kidneys and improve renal cancer prognoses because of folliculin's interaction with the mTOR pathway.[6]

Epidemiology

The disorder has been reported in more than 100 families worldwide,[14] though some sources cite up to 400 families,[1] and it is inherited in an autosomal dominant pattern. It is considered to be under-diagnosed[3][6] because of the variability in its expression.[20] The pattern of mutations and spectrum of symptoms are heterogeneous between individuals.[14] Less severe skin phenotypes are seen in women and people of both sexes who have a late onset of skin symptoms.[5]

Patient registry

Birt-Hogg-Dubé Syndrome patients, families, and caregivers are encouraged to join the . This is a privacy-protected site that provides up-to-date information for individuals interested in the latest scientific news, trials, and treatments related to rare lung diseases.

History

The syndrome was first well described in 1977,[21] by three Canadian physicians, Arthur R. Birt, Georgina R. Hogg, and William J. Dubé. The earliest case of possible BHD in the medical literature was published by Burnier and Rejsek in 1927,[22] who described a case of perifollicular fibromas on a 56-year-old woman's face. Trichodiscomas were first described in 1974 by H. S. Zackheim and H. Pinkus, but were not associated with BHD until Birt, Hogg, and Dubé.[3] The first case of BHD with the systemic symptoms was described by Hornstein and Knickenberg and found in two siblings and their father, all of whom exhibited colon polyps and the characteristic fibrofolliculomas.[23] Though the siblings did not have renal or pulmonary symptoms, their father had cysts in his lungs and kidneys.[3] Hornstein-Knickenberg syndrome is a now-deprecated name for the inherited fibrofolliculomas inherent to BHD.[5]

Birt, Hogg, and Dubé examined a family with a hereditary thyroid cancer, and discovered that many of the members had fibrofolliculomas, trichodiscomas, and acrochordons, which became defined as the classical symptoms of the eponymous disease. The first case of spontaneous pneumothorax associated with BHD was discovered in 1986;[3] the first case of renal cancer followed in 1993,[6] and the presence of lung cysts in people with BHD was confirmed in 1999.[4] People with BHD were once thought to be at higher risk for colorectal polyps and neoplasms, but this has been disproven.[2] The BHD Foundation supports research into the syndrome and holds regular symposia in BHD and related disorders for researchers, clinicians, and family members.[24][25][26]

Other animals

Genes related to FLCN and diseases similar to BHD have been found in dogs, fruit flies, rats, and mice. In German Shepherd dogs, missense mutations in the canine ortholog of FLCN cause a similar phenotype to human BHD—kidney cancers (in this case, multifocal renal cystadenocarcinoma) and skin tumors (nodular dermatofibrosis). They had a similar pattern of tumorigenesis to human BHD in that the skin lesions were heterozygous for the FLCN mutation, and the renal tumors were likely caused by loss of heterozygosity.[6] Female German Shepherds with a FLCN mutation are also prone to uterine leiomyomas.[3]

A homolog of FLCN called DBHD has been discovered in the common fruit fly, Drosophila melanogaster.[27][3] Decrease expression of the DBHD results in loss of male germline stem cells (GSC), which suggest that DBHD is required for male GSC maintenance in the fly testis.[28] Further, DBHD regulates GSC maintenance downstream or in parallel of the JAK/STAT and Dpp signal-transduction pathways, which suggest that BHD regulates tumorigenesis by controlling stem cells in human {[29] Singh et al. 2006}

A line of rats with hereditary kidney cancer were developed by Japanese researchers. They have a mutation in the FLCN homolog that produces a truncated protein, though they do not develop the cutaneous or pulmonary symptoms seen in humans. Heterozygotes have renal abnormalities seen very early in life that develop into clear-cell and hybrid tumors, significantly shortening the animals' lifespans; they also are prone to endometrial and salivary gland clear-cell hyperplasia as well as rhabdomyolysis. Homozygotes do not survive to birth.[3] When a wild-type FLCN gene was added, the phenotype was rescued.[6]

Knockout mice have been created for a kidney-cancer causing mutation of BHD; heterozygotes develop kidney cysts and tumors that lead to renal failure within three weeks of birth. In these mice, the mTOR pathway was inappropriately activated, indicating that the mouse homolog of FLCN plays a regulatory role in this pathway. Rapamycin partially rescued the phenotype by regulating mTOR. Homozygotes die in utero.[3]

References

Citations

  1. ^ a b c Genetics Home Reference.
  2. ^ a b c d e f g h i j k l m n o Andrews 2011.
  3. ^ a b c d e f g h i j k l m n o p Reese et al. 2009.
  4. ^ a b c d e f Palmirotta et al. 2010.
  5. ^ a b c d e f g h i j k l m n o p q r s t u v w x y Toro 2008.
  6. ^ a b c d e f g h i j k l m n o p q r Menko et al. 2009.
  7. ^ a b Chan-Smutko 2012, p. 345.
  8. ^ a b c d e f g Coleman & Russo 2009, p. 482.
  9. ^ a b Furuya & Nakatani 2012.
  10. ^ Grant, Babar & Griffin 2009, p. 442.
  11. ^ Devine & Garcia 2012, p. 4.
  12. ^ Coleman & Russo 2009, p. 481.
  13. ^ Nickerson et al. 2002.
  14. ^ a b c d e Toro et al. 2008.
  15. ^ "Rare Lung Diseases Disorder Definitions". www1.rarediseasesnetwork.org. Retrieved 13 November 2021.
  16. ^ a b Maher 2011.
  17. ^ Sudarshan et al. 2013.
  18. ^ Napolitano G, Di Malta C, Esposito A, de Araujo MEG, Pece S, Bertalot G, Matarese M, Benedetti V, Zampelli A, Stasyk T, Siciliano D, Venuta A, Cesana M, Vilardo C, Nusco E, Monfregola J, Calcagnì A, Di Fiore PP, Huber LA, Ballabio A (September 2020). "A substrate-specific mTORC1 pathway underlies Birt–Hogg–Dubé syndrome". Nature. 585 (7826): 597–602. Bibcode:2020Natur.585..597N. doi:10.1038/s41586-020-2444-0. PMC 7610377. PMID 32612235. S2CID 220289684.{{cite journal}}: CS1 maint: uses authors parameter (link)
  19. ^ Ayo et al. 2007.
  20. ^ Verine et al. 2010.
  21. ^ Birt, Hogg & Dubé 1977.
  22. ^ Riegert-Johnson.
  23. ^ Kniffin 2012.
  24. ^ BHD Foundation.
  25. ^ National Organization for Rare Disorders.
  26. ^ Genetics Home Reference: Educational Resources.
  27. ^ Liu et al. 2013.
  28. ^ Singh SR, Zhen W, Zheng Z, Wang H, Oh SW, Liu W, Zbar B, Schmidt LS, Hou SX. The Drosophila homolog of the human tumor suppressor gene BHD interacts with the JAK-STAT and Dpp signaling pathways in regulating male germline stem cell maintenance. Oncogene. 2006 Sep 28;25(44):5933-41.
  29. ^ Singh SR, Zhen W, Zheng Z, Wang H, Oh SW, Liu W, Zbar B, Schmidt LS, Hou SX. The Drosophila homolog of the human tumor suppressor gene BHD interacts with the JAK-STAT and Dpp signaling pathways in regulating male germline stem cell maintenance. Oncogene. 2006 Sep 28;25(44):5933-41

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External links

 
Wikimedia Commons has media related to Birt–Hogg–Dubé syndrome.
  • BHDSyndrome.org
  • Cancer.Net: Birt-Hogg-Dubé Syndrome

January 08, 2023
birt, hogg, dubé, syndrome, also, hornstein, hornstein, knickenberg, syndrome, fibrofolliculomas, with, trichodiscomas, acrochordons, human, autosomal, dominant, genetic, disorder, that, cause, susceptibility, kidney, cancer, renal, pulmonary, cysts, noncancer. Birt Hogg Dube syndrome BHD also Hornstein Birt Hogg Dube syndrome Hornstein Knickenberg syndrome and fibrofolliculomas with trichodiscomas and acrochordons 1 is a human autosomal dominant genetic disorder that can cause susceptibility to kidney cancer renal and pulmonary cysts and noncancerous tumors of the hair follicles called fibrofolliculomas The symptoms seen in each family are unique and can include any combination of the three symptoms Fibrofolliculomas are the most common manifestation found on the face and upper trunk in over 80 of people with BHD over the age of 40 Pulmonary cysts are equally common 84 but only 24 of people with BHD eventually experience a collapsed lung spontaneous pneumothorax Kidney tumors both cancerous and benign occur in 14 34 of people with BHD the associated kidney cancers are often rare hybrid tumors Birt Hogg Dube syndromeThe characteristic fibrofolliculomas of Birt Hogg Dube syndrome seen on a person s face SpecialtyMedical genetics Any of these conditions that occurs in a family can indicate a diagnosis of Birt Hogg Dube syndrome though it is only confirmed by a genetic test for a mutation in the FLCN gene which codes for the protein folliculin Though its function is not fully understood it appears to be a tumor suppressor gene that restricts cell growth and division Versions of FLCN have been found in other animals including fruit flies German Shepherds rats and mice The disease was discovered in 1977 but the connection with FLCN was not elucidated until 2002 after kidney cancer collapsed lungs and pulmonary cysts were all definitively connected to BHD Birt Hogg Dube syndrome can manifest similarly to other diseases which must be ruled out when making a diagnosis These include tuberous sclerosis which causes skin lesions similar to fibrofolliculomas and Von Hippel Lindau disease which causes hereditary kidney cancers Once diagnosed people with BHD are treated preventatively with monitoring of kidneys and lungs using medical imaging Fibrofolliculomas can be removed surgically and pneumothorax and kidney cancer are treated according to the normal standard of care Dermatologic examinations neck ultrasounds and colonoscopies should be considered as well 1 Contents 1 Signs and symptoms 1 1 Skin 1 2 Kidneys 1 3 Lungs 1 4 Other organs 2 Pathophysiology 2 1 Genetics 2 2 Function 3 Diagnosis 3 1 Clinical triad 3 2 Genetic testing 3 3 Differential diagnosis 4 Management 5 Epidemiology 6 Patient registry 7 History 8 Other animals 9 References 10 External linksSigns and symptoms EditSkin Edit Individual with Birt Hogg Dube syndrome showing the characteristic facial fibrofolliculomas Birt Hogg Dube syndrome affects the skin and increases the risk of tumors in the kidneys and lungs The condition is characterized by multiple noncancerous dome shaped tumors of the hair follicles fibrofolliculomas particularly on the face neck and more rarely the upper chest 2 The fibrofolliculomas are generally described as having an opaque white color 3 or a yellowish tone 4 and have a waxy smooth texture 3 The tumors are always found on and around the nose and on and behind the outer ear Typically they first appear in a person s 20s or 30s and are found in more than 80 of people with the syndrome above the age of 40 2 The tumors become larger and more numerous over time 5 Tumors differ between individuals they may appear merged in plaques look similar to a comedo with a plug of keratin or include epidermoid cysts A large number of tumors on the face can be associated with hyperseborrhea abnormally elevated sebum production 2 The presence of fibrofolliculomas on a person s face can cause significant psychological distress 6 Other tumors can include trichodiscomas tumors of the hair disc which may be identical to fibrofolliculomas angiofibromas and perifollicular fibromas 5 However angiofibromas are more common in tuberous sclerosis 6 Along with the tumors other skin conditions are seen in people with Birt Hogg Dube syndrome About 40 of people or families with the disease have papules in their mouths which can be located on the cheeks buccal mucosa tongue gums or lips Either white or mucosa colored they are discrete small and soft and consist of fibrous tissue covered in thickened epithelium 2 Collagenomas of the skin are also found in some families 5 Many people with BHD have skin lesions that appear to be acrochordons skin tags but may instead be fibrofolliculomas These lesions are usually found in the armpit on the eyelids and in folds of skin 3 Not all individuals develop the facial tumors some families with the mutation that causes BHD develop only kidney tumors or spontaneous pneumothorax 5 Kidneys Edit An H amp E stain of tissue from a chromophobe renal cell carcinoma the second most common cancer associated with BHD People over 20 years of age with BHD have an increased risk of developing slow growing kidney tumors chromophobe renal carcinoma and renal oncocytoma respectively kidney cysts and possibly tumors in other organs and tissues 2 These tumors often occur in both kidneys and in multiple locations in each kidney 5 The average number of kidney tumors found in a person with BHD is 5 3 though up to 28 tumors have been found 7 Hybrid oncocytoma chromophobe carcinoma found in 50 of cases 8 is the most commonly found cancer followed by chromophobe renal carcinoma clear cell renal carcinoma renal oncocytoma and papillary renal cell carcinoma 5 8 People over 40 years old and men are more likely to develop kidney tumors which are diagnosed at a median age of 48 2 5 Kidney cancer associated with BHD have been diagnosed in people at ages as young as 20 6 In general people with this syndrome are at roughly at seven times the risk of kidney cancer compared to the unaffected population Estimates of the incidence among people with the disease range from 14 to 34 2 8 Rarely it is associated with clear cell renal cell carcinoma and papillary renal cell carcinoma 5 If it develops in someone with BHD renal cell carcinoma occurs later in life and has a poor prognosis 9 Though the types of tumors typically associated with BHD are considered less aggressive cases of advanced or metastatic kidney cancer have been observed in people with the syndrome Both benign and cancerous tumors can reduce kidney function over time as they grow larger 8 Lungs Edit Along with fibrofolliculomas and kidney tumors affected individuals frequently develop cysts blebs or bullae in the subpleural lung base or intraparenchymal space that may rupture and cause an abnormal collection of air in the chest cavity pneumothorax which could result in the collapse of a lung 5 10 The cysts do not cause other symptoms 5 and lung function is usually normal 6 More than 83 of people with BHD have cysts but the syndrome does not cause conditions like progressive chronic obstructive pulmonary disease or generalized respiratory failure 2 though it does cause emphysema 4 Spontaneous sometimes recurrent 5 pneumothorax occurs far more often and at a younger age with BHD than in the unaffected population Around 24 of people with the disease have at least one spontaneous pneumothorax 30 times the occurrence in unaffected people Though pneumothorax caused by BHD often occurs in middle age at a median age of 38 17 of affected people have a spontaneous pneumothorax before turning 40 2 Pneumothoraces have been seen in people as young as 7 and 16 years of age 6 Some families have a form of BHD that only affects the lungs 11 Other organs Edit Thyroid nodules 2 have been associated with the Birt Hogg Dube phenotype present in 65 of individuals and 90 of families with the syndrome 2 However a connection between BHD and thyroid cancer has not been substantiated 3 Other conditions have been reported to be associated but may not be caused by the mutation in FLCN or may not be related at all These include multinodular goiter medullary thyroid carcinoma parotid oncocytoma colonic polyposis 12 connective tissue nevus lipomas angiolipomas parathyroid adenomas flecked chorioretinopathy neurothekeoma meningiomas angiofibromas of the face 3 trichoblastomas cutaneous focal mucinosis cutaneous leiomyoma breast cancer tonsillar cancer colorectal cancer sarcoma of the leg lung cancer melanoma dermatofibrosarcoma protuberans basal cell carcinoma cutaneous leiomyosarcoma and squamous cell carcinoma 6 Pathophysiology EditGenetics Edit This diagram shows how autosomal dominant disorders like BHD are passed on The unaffected parent produces all normal gametes sperm and egg and the affected parent produces half mutant gametes and half normal gametes Because only one copy of the mutation is needed to have an autosomal dominant disease each offspring has a 50 chance of having the mutation An association with the folliculin FLCN gene was first reported in 2002 13 This 14 exon gene is located on the short arm of chromosome 17 17p11 2 and has a cytosine rich region in exon 11 particularly susceptible to mutation 2 5 The most common mutation in this region is the insertion or deletion of a cytosine residue found in 53 of BHD affected families No significant difference has been found in the symptoms experienced by families with an insertion at that location compared to those who have a deletion but mutations in FLCN associated with BHD syndrome are heterogeneous and are often nonsense mutations or frameshift mutations that cause early truncation of the protein product at the carboxy terminus 14 3 Very rarely missense mutations are observed 6 The mutations in the FLCN gene that cause Birt Hogg Dube syndrome are germline mutations which means that they occur in every cell of the body and can be passed down to future generations 15 These mutations are often passed from one generation to the next in an autosomal dominant fashion but can occur as a new mutation in an individual with no prior family history a de novo mutation 16 The children of an affected parent each has a 50 chance of having the disease BHD has very high penetrance 5 A correlation between different FLCN genotypes and phenotypes has not been discovered 16 Function Edit FLCN creates a protein folliculin that has two isoforms 3 It appears to act as a tumor suppressor and is expressed strongly in the skin distal nephrons and type I pneumocytes 5 It has also been found in the parotid gland brain breast pancreas prostate and ovaries 8 4 Tumor suppressors normally prevent cells from growing and dividing too rapidly or in an uncontrolled way Mutations in the FLCN gene may interfere with the ability of folliculin to restrain cell growth and division leading to the formation of noncancerous and cancerous tumors Recent studies suggest that folliculin accomplishes this function through its involvement with cellular metabolism possibly through modulation of the mTOR mammalian target of rapamycin pathway and or oxidative phosphorylation in mitochondria 17 Folliculin interacts with FNIP1 and FNIP2 FLCN interacting protein to form a complex with AMP activated protein kinase 8 4 Folliculin s participation in the mTOR pathway may explain the similarity in phenotype between BHD syndrome Cowden syndrome tuberous sclerosis and Peutz Jeghers syndrome 3 Most of the cancer causing mutations cause the protein to be truncated at the carboxy terminus 8 The C terminal end of folliculin has shown to be the domain through which it interacts with FNIP1 and thereby possibly the mTOR pathway 14 FLCN is highly conserved in vertebrates it is very similar between many vertebrate species 5 The 508th amino acid normally lysine is affected by a missense mutation in some people with BHD The lysine at this position is found to be conserved between invertebrate and vertebrate orthologs of folliculin indicating that it is important to the protein s function 14 Folliculin is encoded by the FLCN gene located on the p arm of human chromosome 17 People with BHD are born with one mutated copy of the FLCN gene in each cell 6 Haploinsufficiency only having one functional copy of the FLCN gene is enough to cause the fibrofolliculomas and pulmonary cysts though one copy of the gene is enough to keep kidney cells in check 1 During a person s lifetime random mutations might inactivate the normal copy of the gene in a subset of cells When this occurs the result is that these cells have no functional copies of the FLCNgene allowing the cells grow out of control This loss of heterozygosity is a common mechanism in cancer and it is frequently detected in the renal cancers associated with BHD The molecular genetic defects in renal tumors of people with BHD are different from two other similar kidney tumors chromophobe renal cell carcinoma and renal oncocytoma BHD associated tumorigenesis differs between the kidney where loss of FLCN heterozygosity is responsible for cancers and the skin where FLCN is strongly expressed in heterozygotes 6 FLCN has been found to be overexpressed in fibrofolliculoma tissue and to have very low levels of expression in affected kidneys 4 Furthermore the mTOR pathway is shown to be activated in tumor tissue from both humans and mice 7 Renal cystogenesis and tumorigenesis in BHD have been shown to be driven by the constitutive activation of TFEB 18 Diagnosis EditBHD can be suggested by clinical findings but is definitively diagnosed by molecular genetic testing to detect mutations in the FLCN gene The classical clinical triad includes benign growths of the hair follicles pulmonary cysts and spontaneous pneumothorax and bilateral multifocal renal tumors 5 Clinical triad Edit See also List of cutaneous neoplasms associated with systemic syndromes The cutaneous manifestations of BHD were originally described as fibrofolliculomas abnormal growths of a hair follicle trichodiscomas hamartomatous lesions with a hair follicle at the periphery often found on the face and acrochordons skin tags Cutaneous manifestations are confirmed by histology Most individuals 89 with BHD are found to have multiple cysts in both lungs and 24 have had one or more episodes of pneumothorax The cysts can be detected by chest CT scan Renal tumors can manifest as multiple types of renal cell carcinoma but certain pathological subtypes including chromophobe oncocytoma and oncocytic hybrid tumors are more commonly seen Although the original syndrome was discovered on the basis of cutaneous findings individuals with BHD may only manifest the pulmonary and or renal findings without any skin lesions Though these signs indicate BHD it is only confirmed with a genetic test for FLCN mutations 5 Genetic testing Edit FLCN mutations are detected by sequencing in 88 of probands with this syndrome This means that some people with the clinical diagnosis have mutations that are not detectable by current technology or that mutations in another currently unknown gene could be responsible for a minority of cases In addition amplifications and deletions in exonic regions are also tested Genetic testing can be useful to confirm the clinical diagnosis and to provide a means of determining other at risk individuals in a family even if they have not yet developed BHD symptoms 5 6 Differential diagnosis Edit The person in this image has tuberous sclerosis The skin lesions caused by tuberous sclerosis angiofibromas must be distinguished from the characteristic fibrofolliculomas of BHD which also occur primarily on the face BHD can be difficult to diagnose from symptoms alone because hereditary renal cancers pneumothorax and cutaneous tumors occur with other syndromes Hereditary bilateral multifocal kidney tumors similar to those seen in BHD can occur with von Hippel Lindau disease clear cell renal cell carcinoma hereditary papillary renal cancer papillary renal cell carcinoma and hereditary leiomyomatosis and renal cell cancer syndrome They are differentiated with examination of the tumors histology 5 Hereditary recurrent pneumothorax or pulmonary cysts are associated with Marfan syndrome Ehlers Danlos syndrome tuberous sclerosis complex alpha1 antitrypsin deficiency and cystic fibrosis Nonhereditary recurrent pneumothorax and or pulmonary cysts can occur with Langerhans cell histiocytosis and lymphangioleiomyomatosis These conditions are differentiated from BHD through examining the patient history and performing a physical examination 5 In women suspected to have the disease ruling out pulmonary or thoracic endometriosis may be necessary 9 Though fibrofolliculomas are unique to BHD they may present with an ambiguous appearance and must be confirmed histologically Other diseases can mimic the dermatologic manifestations of BHD including tuberous sclerosis complex Cowden syndrome familial trichoepitheliomas and multiple endocrine neoplasia type 1 5 Tuberous sclerosis must be distinguished because both disorders can present with angiofibromas on the face though they are more common in tuberous sclerosis 6 Management EditThe different manifestations of BHD are controlled in different ways The fibrofolliculomas can be removed surgically through curettage shave excision skin resurfacing or laser ablation this is not a permanent solution though as the tumors often recur 2 5 Dermatologic examination every 6 12 months due to risk of melanoma Thyroid parotid ultrasound should be considered annually Colonoscopies should be considered The renal and pulmonary symptoms are managed preventatively CT scans ultrasounds or MRIs of the kidneys are recommended regularly and family members are advised not to smoke 2 MRIs are the preferred method for surveillance of the kidneys in people with BHD because they do not carry the same risk of radiation complications as CT scans and are more sensitive than ultrasounds 6 Smokers with Birt Hogg Dube have more severe pulmonary symptoms than non smokers 19 6 Though nephrectomy is sometimes indicated kidney tumors in cases of BHD are often removed without taking the whole kidney in a partial nephrectomy 5 Knockout mouse studies have shown that administration of rapamycin may mitigate the effects of FLCN mutations on kidneys and improve renal cancer prognoses because of folliculin s interaction with the mTOR pathway 6 Epidemiology EditThe disorder has been reported in more than 100 families worldwide 14 though some sources cite up to 400 families 1 and it is inherited in an autosomal dominant pattern It is considered to be under diagnosed 3 6 because of the variability in its expression 20 The pattern of mutations and spectrum of symptoms are heterogeneous between individuals 14 Less severe skin phenotypes are seen in women and people of both sexes who have a late onset of skin symptoms 5 Patient registry EditBirt Hogg Dube Syndrome patients families and caregivers are encouraged to join the NIH Rare Lung Diseases Consortium Contact Registry This is a privacy protected site that provides up to date information for individuals interested in the latest scientific news trials and treatments related to rare lung diseases History EditThe syndrome was first well described in 1977 21 by three Canadian physicians Arthur R Birt Georgina R Hogg and William J Dube The earliest case of possible BHD in the medical literature was published by Burnier and Rejsek in 1927 22 who described a case of perifollicular fibromas on a 56 year old woman s face Trichodiscomas were first described in 1974 by H S Zackheim and H Pinkus but were not associated with BHD until Birt Hogg and Dube 3 The first case of BHD with the systemic symptoms was described by Hornstein and Knickenberg and found in two siblings and their father all of whom exhibited colon polyps and the characteristic fibrofolliculomas 23 Though the siblings did not have renal or pulmonary symptoms their father had cysts in his lungs and kidneys 3 Hornstein Knickenberg syndrome is a now deprecated name for the inherited fibrofolliculomas inherent to BHD 5 Birt Hogg and Dube examined a family with a hereditary thyroid cancer and discovered that many of the members had fibrofolliculomas trichodiscomas and acrochordons which became defined as the classical symptoms of the eponymous disease The first case of spontaneous pneumothorax associated with BHD was discovered in 1986 3 the first case of renal cancer followed in 1993 6 and the presence of lung cysts in people with BHD was confirmed in 1999 4 People with BHD were once thought to be at higher risk for colorectal polyps and neoplasms but this has been disproven 2 The BHD Foundation supports research into the syndrome and holds regular symposia in BHD and related disorders for researchers clinicians and family members 24 25 26 Other animals EditGenes related to FLCN and diseases similar to BHD have been found in dogs fruit flies rats and mice In German Shepherd dogs missense mutations in the canine ortholog of FLCN cause a similar phenotype to human BHD kidney cancers in this case multifocal renal cystadenocarcinoma and skin tumors nodular dermatofibrosis They had a similar pattern of tumorigenesis to human BHD in that the skin lesions were heterozygous for theFLCNmutation and the renal tumors were likely caused by loss of heterozygosity 6 Female German Shepherds with a FLCN mutation are also prone to uterine leiomyomas 3 A homolog of FLCN calledDBHDhas been discovered in the common fruit fly Drosophila melanogaster 27 3 Decrease expression of the DBHD results in loss of male germline stem cells GSC which suggest that DBHD is required for male GSC maintenance in the fly testis 28 Further DBHD regulates GSC maintenance downstream or in parallel of the JAK STAT and Dpp signal transduction pathways which suggest that BHD regulates tumorigenesis by controlling stem cells in human 29 Singh et al 2006 A line of rats with hereditary kidney cancer were developed by Japanese researchers They have a mutation in the FLCN homolog that produces a truncated protein though they do not develop the cutaneous or pulmonary symptoms seen in humans Heterozygotes have renal abnormalities seen very early in life that develop into clear cell and hybrid tumors significantly shortening the animals lifespans they also are prone to endometrial and salivary gland clear cell hyperplasia as well as rhabdomyolysis Homozygotes do not survive to birth 3 When a wild type FLCN gene was added the phenotype was rescued 6 Knockout mice have been created for a kidney cancer causing mutation of BHD heterozygotes develop kidney cysts and tumors that lead to renal failure within three weeks of birth In these mice the mTOR pathway was inappropriately activated indicating that the mouse homolog of FLCN plays a regulatory role in this pathway Rapamycin partially rescued the phenotype by regulating mTOR Homozygotes die in utero 3 References EditCitations a b c Genetics Home Reference a b c d e f g h i j k l m n o Andrews 2011 a b c d e f g h i j k l m n o p Reese et al 2009 a b c d e f Palmirotta et al 2010 a b c d e f g h i j k l m n o p q r s t u v w x y Toro 2008 a b c d e f g h i j k l m n o p q r Menko et al 2009 a b Chan Smutko 2012 p 345 a b c d e f g Coleman amp Russo 2009 p 482 a b Furuya amp Nakatani 2012 Grant Babar amp Griffin 2009 p 442 Devine amp Garcia 2012 p 4 Coleman amp Russo 2009 p 481 Nickerson et al 2002 a b c d e Toro et al 2008 Rare Lung Diseases Disorder Definitions www1 rarediseasesnetwork org Retrieved 13 November 2021 a b Maher 2011 Sudarshan et al 2013 Napolitano G Di Malta C Esposito A de Araujo MEG Pece S Bertalot G Matarese M Benedetti V Zampelli A Stasyk T Siciliano D Venuta A Cesana M Vilardo C Nusco E Monfregola J Calcagni A Di Fiore PP Huber LA Ballabio A September 2020 A substrate specific mTORC1 pathway underlies Birt Hogg Dube syndrome Nature 585 7826 597 602 Bibcode 2020Natur 585 597N doi 10 1038 s41586 020 2444 0 PMC 7610377 PMID 32612235 S2CID 220289684 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint uses authors parameter link Ayo et al 2007 Verine et al 2010 Birt Hogg amp Dube 1977 Riegert Johnson Kniffin 2012 BHD Foundation National Organization for Rare Disorders Genetics Home Reference Educational Resources Liu et al 2013 Singh SR Zhen W Zheng Z Wang H Oh SW Liu W Zbar B Schmidt LS Hou SX The Drosophila homolog of the human tumor suppressor gene BHD interacts with the JAK STAT and Dpp signaling pathways in regulating male germline stem cell maintenance Oncogene 2006 Sep 28 25 44 5933 41 Singh SR Zhen W Zheng Z Wang H Oh SW Liu W Zbar B Schmidt LS Hou SX The Drosophila homolog of the human tumor suppressor gene BHD interacts with the JAK STAT and Dpp signaling pathways in regulating male germline stem cell maintenance Oncogene 2006 Sep 28 25 44 5933 41 BibliographyAyo Dereje S Aughenbaugh GL Yi ES Hand JL Ryu JH 2007 Cystic Lung Disease in Birt Hogg Dube Syndrome Chest 132 2 679 84 doi 10 1378 chest 07 0042 PMID 17505035 Birt A R Hogg GR Dube WJ 1977 Hereditary multiple fibrofolliculomas with trichodiscomas and acrochordons Archives of Dermatology 113 12 1674 7 doi 10 1001 archderm 113 12 1674 PMID 596896 BHD Foundation 2013 archived from the original on 11 June 2021 retrieved 17 July 2013 Chan Smutko Gayun 2012 Genetic Testing by Cancer Site The Cancer Journal 18 4 343 9 doi 10 1097 PPO 0b013e31826246ac PMID 22846736 Coleman Jonathan A Russo Paul 2009 Hereditary and familial kidney cancer Current Opinion in Urology 19 5 478 85 doi 10 1097 MOU 0b013e32832f0d40 PMID 19584731 Devine Megan Stuebner Garcia Christine Kim 2012 Genetic Interstitial Lung Disease Clinics in Chest Medicine 33 1 95 110 doi 10 1016 j ccm 2011 11 001 PMC 3292740 PMID 22365249 Furuya M Nakatani Y 2012 Birt Hogg Dube syndrome Clinicopathological features of the lung Journal of Clinical Pathology 66 3 178 86 doi 10 1136 jclinpath 2012 201200 PMC 3595143 PMID 23223565 Birt Hogg Dube syndrome Genetics Home Reference US National Library of Medicine January 2013 retrieved 13 July 2013 Birt Hogg Dube syndrome Educational resources Genetics Home Reference NIH 22 July 2013 archived from the original on 15 March 2016 retrieved 25 July 2013 Grant L A Babar J Griffin N 2009 Cysts cavities and honeycombing in multisystem disorders Differential diagnosis and findings on thin section CT Clinical Radiology 64 4 439 48 doi 10 1016 j crad 2008 09 015 PMID 19264190 James William D Berger Timothy Elston Dirk 2011 Andrew s Diseases of the Skin Clinical Dermatology 11th ed Elsevier Health Sciences ISBN 978 1 4377 3619 9 Kniffin Cassandra L 22 August 2012 Birt Hogg Dube syndrome BHD Online Mendelian Inheritance in Man Johns Hopkins University archived from the original on 10 March 2017 retrieved 13 July 2013 Liu Wei Chen Zhi Ma Yansen Wu Xiaochun Jin Yaping Hou Steven 2013 White Cooper Helen ed Genetic Characterization of the Drosophila Birt Hogg Dube Syndrome Gene PLOS ONE 8 6 e65869 Bibcode 2013PLoSO 865869L doi 10 1371 journal pone 0065869 PMC 3684598 PMID 23799055 Maher Eamonn R 2011 Genetics of Familial Renal Cancers Nephron Experimental Nephrology 118 1 e21 6 doi 10 1159 000320892 PMID 21071978 S2CID 23464317 Menko Fred H Van Steensel Maurice AM Giraud Sophie Friis Hansen Lennart Richard Stephane Ungari Silvana Nordenskjold Magnus Hansen Thomas vO Solly John Maher Eamonn R European Bhd Consortium 2009 Birt Hogg Dube syndrome Diagnosis and management The Lancet Oncology 10 12 1199 206 doi 10 1016 S1470 2045 09 70188 3 PMID 19959076 BHD Foundation National Organization for Rare Disorders 2013 archived from the original on 3 November 2013 retrieved 25 July 2013 Nickerson Michael L Warren Michelle B Toro Jorge R Matrosova Vera Glenn Gladys Turner Maria L Duray Paul Merino Maria Choyke Peter et al 2002 Mutations in a novel gene lead to kidney tumors lung wall defects and benign tumors of the hair follicle in patients with the Birt Hogg Dube syndrome Cancer Cell 2 2 157 64 doi 10 1016 S1535 6108 02 00104 6 PMID 12204536 Palmirotta Raffaele Savonarola Annalisa Ludovici Giorgia Donati Pietro Cavaliere Francesco De Marchis Maria Laura Ferroni Patrizia Guadagni Fiorella March 2010 Association between Birt Hogg Dube syndrome and cancer predisposition Anticancer Res 30 3 751 7 PMID 20392993 Reese Erin Sluzevich Jason Kluijt Irma Teertstra H Jelle De Jong Daphne Horenblas Simon Ryu Jay 5 October 2009 Birt Hogg Dube Syndrome in Riegert Johnson Douglas L Boardman Lisa A Hefferon Timothy Roberts Maegan eds Cancer Syndromes Bethesda MD National Center for Biotechnology Information PMID 21249760 Riegert Johnson DL Birt Hogg Dube Familial Cancer Syndromes NCBI retrieved 21 July 2009 Sudarshan Sunil Karam Jose A Brugarolas James Thompson R Houston Uzzo Robert Rini Brian Margulis Vitaly Patard Jean Jacques Escudier Bernard Linehan W Marston 2013 Metabolism of Kidney Cancer From the Lab to Clinical Practice European Urology 63 2 244 51 doi 10 1016 j eururo 2012 09 054 PMC 3709870 PMID 23063455 Toro Jorge R 9 September 2008 Birt Hogg Dube Syndrome in Pagon Roberta A Adam Margaret P Bird Thomas D Dolan Cynthia R Fong Chin To Smith Richard JH Stephens Karen eds GeneReviews University of Washington PMID 20301695 Toro J R Wei M H Glenn G M Weinreich M Toure O Vocke C Turner M Choyke P Merino M J et al 2008 BHD mutations clinical and molecular genetic investigations of Birt Hogg Dube syndrome A new series of 50 families and a review of published reports Journal of Medical Genetics 45 6 321 31 doi 10 1136 jmg 2007 054304 PMC 2564862 PMID 18234728 Verine Jerome Pluvinage Amelie Bousquet Guilhem Lehmann Che Jacqueline De Bazelaire Cedric Soufir Nadem Mongiat Artus Pierre 2010 Hereditary Renal Cancer Syndromes An Update of a Systematic Review European Urology 58 5 701 10 doi 10 1016 j eururo 2010 08 031 PMID 20817385External links Edit Wikimedia Commons has media related to Birt Hogg Dube syndrome BHDSyndrome org Cancer Net Birt Hogg Dube Syndrome Retrieved from https en wikipedia org w index php title Birt Hogg Dube syndrome amp oldid 1087894767, wikipedia, wiki, book, books, library,

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