Pten Hamartoma Tumor Syndrome
Summary
Clinical characteristics.
The PTEN hamartoma tumor syndrome (PHTS) includes Cowden syndrome (CS), Bannayan-Riley-Ruvalcaba syndrome (BRRS), PTEN-related Proteus syndrome (PS), and Proteus-like syndrome.
- CS is a multiple hamartoma syndrome with a high risk for benign and malignant tumors of the thyroid, breast, and endometrium. Affected individuals usually have macrocephaly, trichilemmomas, and papillomatous papules, and present by the late 20s. The lifetime risk of developing breast cancer is 85%, with an average age of diagnosis between 38 and 46 years. The lifetime risk for thyroid cancer (usually follicular, rarely papillary, but never medullary thyroid cancer) is approximately 35%. The risk for endometrial cancer may approach 28%.
- BRRS is a congenital disorder characterized by macrocephaly, intestinal hamartomatous polyposis, lipomas, and pigmented macules of the glans penis.
- PS is a complex, highly variable disorder involving congenital malformations and hamartomatous overgrowth of multiple tissues, as well as connective tissue nevi, epidermal nevi, and hyperostoses.
- Proteus-like syndrome is undefined but refers to individuals with significant clinical features of PS who do not meet the diagnostic criteria for PS.
Diagnosis/testing.
The diagnosis of PHTS is established in a proband by identification of a heterozygous germline PTEN pathogenic variant on molecular genetic testing.
Management.
Treatment of manifestations: Treatment for the benign and malignant manifestations of PHTS is the same as for their sporadic counterparts. Topical agents (e.g., 5-fluorouracil), curettage, cryosurgery, or laser ablation may alleviate the mucocutaneous manifestations of CS but are rarely utilized; cutaneous lesions should be excised only if malignancy is suspected or symptoms (e.g., pain, deformity, increased scarring) are significant.
Surveillance: To detect tumors at the earliest, most treatable stages:
- Children (age <18 years). Yearly thyroid ultrasound from the time of diagnosis and skin check with physical examination.
- Adults. Yearly thyroid ultrasound and dermatologic evaluation.
- Women beginning at age 30 years. Monthly breast self-examination; annual breast screening (at minimum mammogram; MRI may also be incorporated) and transvaginal ultrasound or endometrial biopsy.
- Men and women. Colonoscopy beginning at age 35 years with frequency dependent on degree of polyposis identified; biennial (every 2 years) renal imaging (CT or MRI preferred) beginning at age 40 years.
- Those with a family history of a particular cancer type at an early age. Consider initiating screening 5-10 years prior to the youngest age of diagnosis in the family.
Evaluation of relatives at risk: When a PTEN pathogenic variant has been identified in a proband, molecular genetic testing of asymptomatic at-risk relatives can identify those who have the family-specific pathogenic variant and warrant ongoing surveillance.
Genetic counseling.
PHTS is inherited in an autosomal dominant manner. Because CS is likely underdiagnosed, the actual proportion of simplex cases (defined as individuals with no obvious family history) and familial cases (defined as ≥2 related affected individuals) cannot be determined. The majority of CS cases are simplex. Perhaps 10%-50% of individuals with CS have an affected parent. Each child of an affected individual has a 50% chance of inheriting the pathogenic variant and developing PHTS. Once a PTEN pathogenic variant has been identified in an affected family member, prenatal testing for a pregnancy at increased risk is possible.
Diagnosis
Suggestive Findings
The PTEN hamartoma tumor syndrome (PHTS) includes Cowden syndrome (CS), Bannayan-Riley-Ruvalcaba syndrome (BRRS), PTEN-related Proteus syndrome (PS), and Proteus-like syndrome.
A PTEN hamartoma tumor syndrome (PHTS) should be suspected in individuals with the following clinical features.
Cowden Syndrome (CS)
Based on more than 3,000 prospectively accrued individuals with CS or a Cowden-like syndrome (CSL) from the community, a scoring system (which can be found online) that takes into account phenotype and age at diagnosis has been developed. The scoring system allows input of clinical information on an individual suspected of having CS/CSL and subsequently generates the prior probability of finding a PTEN pathogenic variant.
- In adults, a clinical threshold score of ≥10 leads to a recommendation for referral to a genetics professional to consider PHTS.
- In children, macrocephaly and ≥1 of the following leads to the consideration of PHTS:
- Autism or developmental delay
- Dermatologic features, including lipomas, trichilemmomas, oral papillomas, or penile freckling
- Vascular features, such as arteriovenous malformations or hemangiomas
- Gastrointestinal polyps
Additionally, consensus diagnostic criteria for CS have been developed [Eng 2000] and are updated each year by the National Comprehensive Cancer Network [NCCN 2015]. However, the CS scoring system discussed in this section has been shown to be more accurate than the NCCN diagnostic criteria [Tan et al 2011].
The NCCN consensus clinical diagnostic criteria have been divided into three categories: pathognomonic, major, and minor.
Pathognomonic criteria
- Adult Lhermitte-Duclos disease (LDD), defined as the presence of a cerebellar dysplastic gangliocytoma [Zhou et al 2003a]
- Mucocutaneous lesions:
- Trichilemmomas (facial) (see Figure 1)
- Acral keratoses
- Papillomatous lesions (see Figure 2)
- Mucosal lesions
Figure 1.
Figure 2.
Major criteria
- Breast cancer
- Epithelial thyroid cancer (non-medullary), especially follicular thyroid cancer
- Macrocephaly (occipital frontal circumference ≥97th percentile)
- Endometrial carcinoma
Minor criteria
- Other thyroid lesions (e.g., adenoma, multinodular goiter)
- Intellectual disability (IQ ≤75)
- Hamartomatous intestinal polyps
- Fibrocystic disease of the breast
- Lipomas
- Fibromas
- Genitourinary tumors (especially renal cell carcinoma)
- Genitourinary malformation
- Uterine fibroids
An operational diagnosis of CS is made if an individual meets any one of the following criteria:
- Pathognomonic mucocutaneous lesions combined with one of the following:
- Six or more facial papules, of which three or more must be trichilemmoma
- Cutaneous facial papules and oral mucosal papillomatosis
- Oral mucosal papillomatosis and acral keratoses
- Six or more palmoplantar keratoses
- Two or more major criteria
- One major and three or more minor criteria
- Four or more minor criteria
In a family in which one individual meets the diagnostic criteria for CS listed above, other relatives are considered to have a diagnosis of CS if they meet any one of the following criteria:
- The pathognomonic criteria
- Any one major criterion with or without minor criteria
- Two minor criteria
- History of Bannayan-Riley-Ruvalcaba syndrome
Bannayan-Riley-Ruvalcaba Syndrome (BRRS)
Diagnostic criteria for BRRS have not been set but are based heavily on the presence of the cardinal features of macrocephaly, hamartomatous intestinal polyposis, lipomas, and pigmented macules of the glans penis [Gorlin et al 1992].
Proteus Syndrome
Proteus syndrome (PS) is highly variable and appears to affect individuals in a mosaic distribution (i.e., only some organs/tissues are affected). Thus, it is frequently misdiagnosed despite the development of consensus diagnostic criteria [Biesecker et al 1999] (see Proteus Syndrome).
Proteus-Like Syndrome
Proteus-like syndrome is undefined but describes individuals with significant clinical features of PS but who do not meet the diagnostic criteria.
Establishing the Diagnosis
The diagnosis of PHTS is established in a proband by identification of a heterozygous germline pathogenic variant in PTEN on molecular genetic testing (see Table 1).
Molecular genetic testing approaches can include single-gene testing, use of a multigene panel, and more comprehensive genomic testing:
- Single-gene testing. Sequence analysis of PTEN is performed first and followed by gene-targeted deletion/duplication analysis if no pathogenic variant is found. If a pathogenic variant is not identified with deletion/duplication analysis, perform sequence analysis of the PTEN promoter region for variants that decrease gene expression.Note: In individuals with Cowden syndrome (CS) and Cowden-like syndrome also consider KLLN promoter methylation analysis (see Differential Diagnosis, Germline KLLN Epimutation), SDHB-D analysis (see Differential Diagnosis, New Susceptibility Genes in Individuals with Non-PHTS CS and a CS-Like Disorder) including PIK3CA, AKT1 [Orloff et al 2013], and SEC23B [Yehia et al 2015].
- A multigene panel that includes PTEN and other genes of interest (see Differential Diagnosis) may also be considered. Note: (1) The genes included in the panel and the diagnostic sensitivity of the testing used for each gene vary by laboratory and are likely to change over time. (2) Some multigene panels may include genes not associated with the condition discussed in this GeneReview; thus, clinicians need to determine which multigene panel is most likely to identify the genetic cause of the condition at the most reasonable cost while limiting identification of variants of uncertain significance and pathogenic variants in genes that do not explain the underlying phenotype. (3) In some laboratories, panel options may include a custom laboratory-designed panel and/or custom phenotype-focused exome analysis that includes genes specified by the clinician. (4) Methods used in a panel may include sequence analysis, deletion/duplication analysis, and/or other non-sequencing-based tests.For an introduction to multigene panels click here. More detailed information for clinicians ordering genetic tests can be found here.
- More comprehensive genomic testing (when available) including exome sequencing or genome sequencing may be considered if single-gene testing (and/or use of a multigene panel that includes PTEN) fails to confirm a diagnosis in an individual with features of PHTS. Such testing may provide or suggest a diagnosis not previously considered (e.g., mutation of a different gene or genes that results in a similar clinical presentation).For an introduction to comprehensive genomic testing click here. More detailed information for clinicians ordering genomic testing can be found here.
Table 1.
Gene 1 | Test Method | Proportion of Probands by Phenotype with a Pathogenic Variant Detectable by This Method | |||
---|---|---|---|---|---|
CS | BRRS | PLS | PS | ||
PTEN | Sequence analysis of coding region 2 | 25%-80% | 60% | 50% 3 | 20% |
Deletion/duplication analysis 4 | See footnote 5 | 11% 6 | Unknown | Unknown | |
Sequence analysis of promoter region 2 | 10% 7 | See footnote 5 | Unknown | Unknown |
CS = Cowden syndrome
BRRS = Bannayan-Riley-Ruvalcaba syndrome
PLS = Proteus-like syndrome
PS = PTEN-related Proteus syndrome
- 1.
See Table A. Genes and Databases for chromosome locus and protein. See Molecular Genetics for information on allelic variants.
- 2.
Sequence analysis detects variants that are benign, likely benign, of uncertain significance, likely pathogenic, or pathogenic. Pathogenic variants may include small intragenic deletions/insertions and missense, nonsense, and splice site variants; typically, exon or whole-gene deletions/duplications are not detected. For issues to consider in interpretation of sequence analysis results, click here.
- 3.
Data suggest that up to 50% of individuals with a Proteus-like syndrome and 20% of individuals who meet the clinical diagnostic criteria of Proteus syndrome have PTEN pathogenic variants [Zhou et al 2001, Smith et al 2002, Eng 2003, Loffeld et al 2006, Orloff & Eng 2008].
- 4.
Testing that identifies exon or whole-gene deletions/duplications not readily detectable by sequence analysis of the coding and flanking intronic regions of genomic DNA; included in the variety of methods that may be used are: quantitative PCR, long-range PCR, multiplex ligation-dependent probe amplification (MLPA), and chromosomal microarray (CMA) that includes this gene/chromosome segment.
- 5.
Finite but unknown; individuals with CS who have large deletions have been reported [Zbuk & Eng 2007, Orloff & Eng 2008, Tan et al 2011].
- 6.
Approximately 10% of individuals with BRRS who do not have a pathogenic variant detected in the PTEN coding sequence have large deletions within or encompassing PTEN [Zhou et al 2003b].
- 7.
10% of individuals with CS phenotype do not have an identifiable PTEN sequence variant in the coding/flanking intronic regions [Zhou et al 2003b].
Clinical Characteristics
Clinical Description
The PTEN hamartoma tumor syndrome (PHTS) is characterized by hamartomatous tumors and germline PTEN pathogenic variants. Clinically, PHTS includes Cowden syndrome (CS), Bannayan-Riley-Ruvalcaba syndrome (BRRS), PTEN-related Proteus syndrome (PS), and Proteus-like syndrome.
- CS is a multiple hamartoma syndrome with a high risk for benign and malignant tumors of the thyroid, breast, and endometrium. Renal cell carcinoma and colorectal carcinoma have recently been shown to be in the PHTS spectrum.
- BRRS is a congenital disorder characterized by macrocephaly, intestinal polyposis, lipomas, and pigmented macules of the glans penis.
- PS is a complex, highly variable disorder involving congenital malformations and overgrowth of multiple tissues.
- Proteus-like syndrome is undefined but refers to individuals with significant clinical features of PS who do not meet the diagnostic criteria for PS.
Cowden Syndrome (CS)
More than 90% of individuals with CS have some clinical manifestation of the disorder by the late 20s [Nelen et al 1996, Eng 2000]. By the third decade, 99% of affected individuals develop the mucocutaneous stigmata (primarily trichilemmomas and papillomatous papules) as well as acral and plantar keratoses. In addition, individuals with Cowden syndrome usually have macrocephaly and dolicocephaly.
Hamartomatous and mixed gastrointestinal polyps, seen frequently in the majority of people with PHTS, do confer an increased risk for colorectal cancers [Heald et al 2010].
Based on anecdotal observations, glycogenic acanthosis in the presence of features of CS appears to be associated with a high likelihood of finding a PTEN pathogenic variant [Eng 2003, McGarrity et al 2003].
Tumor risk. Individuals with CS are at high risk for breast, thyroid, and endometrial cancers. As with other hereditary cancer syndromes, the risk for multifocal and bilateral (in paired organs such as the breasts) cancer is increased:
- Breast disease
- Women with Cowden syndrome are at as high as a 67% risk for benign breast disease.
- An analysis of prospectively accrued and followed probands and family members with a PTEN pathogenic variant revealed an 85% lifetime risk for female breast cancer, with 50% penetrance by age 50 years [Tan et al 2012].
- Although breast cancer has been described in males with a PTEN pathogenic variant [Fackenthal et al 2001], it was not observed in a study of more than 3,000 probands [Tan et al 2011].
- Thyroid disease
- Benign multinodular goiter of the thyroid as well as adenomatous nodules and follicular adenomas are common, occurring in up to 75% of individuals with CS [Harach et al 1999].
- The lifetime risk for epithelial thyroid cancer is approximately 35% [Tan et al 2012]. Median age of onset was 37 years; seven years was the youngest age at diagnosis [Ngeow et al 2011].Note: (1) Follicular histology is overrepresented in adults compared to the general population in which papillary histology is overrepresented. (2) No medullary thyroid carcinoma was observed in the cohort with molecularly confirmed CS.
- Endometrial disease
- Benign uterine fibroids are common.
- Lifetime risk for endometrial cancer is estimated at 28%, with the starting age at risk in the late 30s to early 40s [Tan et al 2012].
- Gastrointestinal neoplasias
- More than 90% of individuals with a PTEN pathogenic variant who underwent at least one upper or lower endoscopy were found to have polyps [Heald et al 2010]. Histologic findings varied, ranging from ganglioneuromatous polyps, hamartomatous polyps, and juvenile polyps to adenomatous polyps.
- Lifetime risk for colorectal cancer is estimated at 9%, with the starting age at risk in the late 30s [Tan et al 2012].
- Renal cell carcinoma. Lifetime risk for renal cell carcinoma is estimated at 35%, with the starting age at risk in the 40s [Tan et al 2012]. The predominant histology is papillary renal cell carcinoma [Mester et al 2012].
- Other
- Lifetime risk for cutaneous melanoma is estimated at more than 5%.
- Brain tumors as well as vascular malformations affecting any organ are occasionally seen in individuals with CS.Note: Because meningioma is so common in the general population, it is not yet clear if meningioma is a true manifestation of CS.
- A rare central nervous system tumor, cerebellar dysplastic gangliocytoma (Lhermitte-Duclos disease), is also found in CS and may be pathognomonic.
Bannayan-Riley-Ruvalcaba Syndrome (BRRS)
Common features of BRRS, in addition to those mentioned above, include high birth weight, developmental delay, and intellectual disability (50% of affected individuals), a myopathic process in proximal muscles (60%), joint hyperextensibility, pectus excavatum, and scoliosis (50%) [Zbuk & Eng 2007].
Individuals with BRRS and a PTEN pathogenic variant are thought to have the same cancer risks as individuals with CS. Note: It is not clear whether these risks apply to individuals with BRRS who do not have a PTEN pathogenic variant.
The gastrointestinal hamartomatous polyps in BRRS (seen in 45% of affected individuals) may occasionally be associated with intussusception, but rectal bleeding and oozing of "serum" is more common. These polyps are not believed to increase the risk for colorectal cancer. PHTS hamartomatous polyps are different in histomorphology from the polyps seen in Peutz-Jeghers syndrome.
PTEN-Related Proteus Syndrome (PS)
PS is characterized by progressive segmental or patchy overgrowth of diverse tissues of all germ layers, most commonly affecting the skeleton, skin, and adipose and central nervous systems. In most individuals Proteus syndrome has minimal or no manifestations at birth, develops and progresses rapidly beginning in the toddler period, and relentlessly progresses through childhood, causing severe overgrowth and disfigurement. It is associated with a range of tumors, pulmonary complications, and a striking predisposition to deep vein thrombosis and pulmonary embolism. See Proteus Syndrome.
Proteus-Like Syndrome
Proteus-like syndrome is undefined but describes individuals with significant clinical features of PS who do not meet the diagnostic criteria.
Genotype-Phenotype Correlations
For purposes of PTEN genotype-phenotype analyses, a series of 37 unrelated probands with CS were ascertained by the operational diagnostic criteria of the International Cowden Consortium, 1995 version [Nelen et al 1996, Eng 2000]. Association analyses revealed that families with CS and a germline PTEN pathogenic variant are more likely to develop malignant breast disease than are families who do not have a PTEN pathogenic variant [Marsh et al 1998]. In addition, pathogenic missense variants and others 5' to or within the phosphatase core motif appeared to be associated with involvement of five or more organs, a surrogate phenotype for severity of disease [Marsh et al 1998].
More than 90% of families with CS-BRRS overlap were found to have a germline PTEN pathogenic variant. The mutational spectra of BRRS and CS have been shown to overlap, thus lending formal proof that CS and BRRS are allelic [Marsh et al 1999]. No difference in mutation frequencies was observed between BRRS occurring in a single individual in a family and BRRS occurring in multiple family members.
An individual presenting as a simplex case (i.e., one with no known family history) of Proteus-like syndrome comprising hemihypertrophy, macrocephaly, lipomas, connective tissue nevi, and multiple arteriovenous malformations was found to have a germline p.Arg335Ter PTEN pathogenic variant and the same somatic pathogenic variant (p.Arg130Ter) in three separate tissues, possibly representing germline mosaicism [Zhou et al 2000]. Both pathogenic variants have been previously described in classic CS and BRRS.
Two of nine individuals who met the clinical diagnostic criteria of Proteus syndrome and three of six with Proteus-like syndrome were found to have germline PTEN pathogenic variants [Zhou et al 2001]. Since then multiple single cases of germline PTEN pathogenic variants in individuals who met the clinical diagnostic criteria of Proteus and Proteus-like syndrome have been reported [Smith et al 2002, Loffeld et al 2006].
Penetrance
More than 90% of individuals with CS have some clinical manifestation of the disorder by the late 20s [Nelen et al 1996, Eng 2000, Zbuk & Eng 2007]. By the third decade, 99% of affected individuals develop the mucocutaneous stigmata, primarily trichilemmomas and papillomatous papules, as well as acral and plantar keratoses. (See also Clinical Description for age at which specific manifestations are likely to become evident.)
Nomenclature
Cowden syndrome, Cowden disease, and multiple hamartoma syndrome have been used interchangeably.
Bannayan-Riley-Ruvalcaba syndrome, Bannayan-Ruvalcaba-Riley syndrome, Bannayan-Zonana syndrome, and Myhre-Riley-Smith syndrome refer to a similar constellation of signs that comprise what the authors refer to as BRRS. When a PTEN pathogenic variant is found, the gene-related name, PHTS, should be used.
One form of Proteus-like syndrome, with a clinical presentation similar to that first described by Zhou et al [2000] and with a germline PTEN pathogenic variant, was termed SOLAMEN (segmental overgrowth, lipomatosis, arteriovenous malformation and epidermal nevus) syndrome [Caux et al 2007]. This is not useful, especially in the molecular era, as any phenotype associated with a PTEN pathogenic variant should be termed PHTS with all its implications for clinical management [Zbuk & Eng 2007, Orloff & Eng 2008].
Prevalence
Because the diagnosis of CS is difficult to establish, the true prevalence is unknown. The prevalence has been estimated at one in 200,000 [Nelen et al 1999], likely an underestimate. Because of the variable and often subtle external manifestations of CS/BRRS, many individuals remain undiagnosed [Zbuk & Eng 2007; Eng, unpublished].
Differential Diagnosis
Table 2.
Disorder | Gene(s) | MOI | Clinical Features of the Differential Diagnosis Disorder | |
---|---|---|---|---|
Overlapping w/PHTS | General | |||
Primary differential diagnoses to consider: other hamartoma syndromes incl JPS & PJS | ||||
JPS | BMPR1A SMAD4 | AD | Hamartomatous gastrointestinal polyps 1 | Characterized by predisposition to hamartomatous polyps in GI tract Most individuals have some polyps by age 20 yrs; some may have only 4-5 polyps over a lifetime; others in same family may have >100. Left untreated, polyps may cause bleeding & anemia. Most juvenile polyps are benign, but malignant transformation can occur. |
PJS | STK11 | AD | Hamartomatous gastrointestinal polyps 2 | Characterized by GI polyposis, mucocutaneous pigmentation, & cancer predisposition The pigmentation of perioral region is pathognomonic, particularly if it crosses the vermilion border. Hyperpigmented macules on the fingers are also common. |
Less likely differential diagnoses to consider | ||||
BHD | FLCN | AD | Cutaneous manifestations incl skin tags, fibromas, & trichiepitheliomas (can be mistaken for trichilemmomas) | Characterized by cutaneous findings 3, pulmonary cysts/history of pneumothorax, & various types of renal tumors 4 Lung cysts are mostly bilateral & multifocal; most individuals are asymptomatic but at high risk for spontaneous pneumothorax. |
NF1 | NF1 | AD | Café au lait macules & fibromatous tumors of the skin 5 | May be mistakenly diagnosed in persons w/CS/BRRS due to presence of ganglioneuromas in GI tract. |
Nevoid basal cell carcinoma (Gorlin) syndrome | PTCH1 SUFU | AD | Hamartomatous gastric polyps | Characterized by development of multiple jaw keratocysts &/or basal cell carcinomas Affected individuals can also develop other tumors & cancers incl fibromas, hamartomatous gastric polyps, & medulloblastomas. Dermatologic findings & developmental features in CS & Gorlin syndrome are quite different. |
AKT1-related Proteus syndrome | AKT1 | See footnote 6 | Proteus syndrome is a "PTEN-pathway-opathy" 7. Macrocephaly, overgrowth | Characterized by progressive segmental or patchy overgrowth of diverse tissues of all germ layers In most individuals: minimal or no manifestations at birth; progresses rapidly beginning in toddler period & relentlessly through childhood, causing severe overgrowth & disfigurement Associated w/a range of tumors, pulmonary complications, & striking predisposition to deep vein thrombosis & pulmonary embolism |
AD = autosomal dominant; AR = autosomal recessive; BHD = Birt-Hogg-Dubé syndrome; GI = gastrointestinal; JPS = juvenile polyposis syndrome; the term "juvenile" refers to the type of polyp rather than to the age of onset of polyps; MOI = mode of inheritance; NF1 = neurofibromatosis type 1; PJS = Peutz-Jeghers syndrome; XL = X-linked
- 1.
Juvenile polyps are hamartomas that show a normal epithelium with a dense stroma, an inflammatory infiltrate, and a smooth surface with dilated, mucus-filled cystic glands in the lamina propria. (See Juvenile Polyposis Syndrome.)
- 2.
The Peutz-Jeghers polyp has a diagnostic appearance and is quite different from the hamartomatous polyps seen in CS or JPS. Clinically, Peutz-Jeghers polyps are often symptomatic (intussusception, rectal bleeding), whereas CS polyps are rarely so. (See Peutz-Jeghers Syndrome.)
- 3.
Cutaneous findings characteristic of BHD: fibrofolliculomas, trichodiscomas/angiofibromas, perifollicular fibromas, and acrochordons. Skin lesions typically appear during the third or fourth decade of life and usually increase in size and number with age. (See Birt-Hogg-Dubé syndrome.)
- 4.
Individuals with BHDS are at increased risk for renal tumors that are typically bilateral and multifocal, and usually slow growing.
- 5.
The only two features seen in both NF1 and CS/BRRS are café au lait macules and fibromatous tumors of the skin. (See Neurofibromatosis type 1.)
- 6.
All individuals with clinically confirmed Proteus syndrome (known to authors of the Proteus Syndrome GeneReview) have been simplex cases caused by somatic mosaicism for the specific de novo AKT1 pathogenic variant c.49G>A (p.Glu17Lys).
- 7.
Since PTEN downregulates AKT1 by decreasing phosphorylation, the finding of an activating AKT1 pathogenic variant in Proteus syndrome confirms that Proteus syndrome is a ‘PTEN-pathway-opathy.’
Germline KLLN Epimutation
Bennett et al [2010] determined that approximately 30% of individuals with Cowden syndrome (CS) (OMIM 615107) and Cowden-like syndrome who do not have a PTEN germline pathogenic variant have a germline KLLN methylation epimutation, which resulted in downregulation of expression of KLLN, but not of PTEN. Of note, KLLN shares a bidirectional promoter with PTEN. Pilot data suggest that individuals with CS and Cowden-like syndrome with a germline KLLN epimutation have a greater prevalence of breast and renal cell carcinomas than do those with a germline PTEN pathogenic variant. Thus, individuals with Cowden-like syndrome (especially those with breast and/or renal carcinomas or a family history of such tumors) should be offered KLLN methylation analysis first because it accounts for 30% of such individuals, whereas PTEN germline pathogenic variants account for 5%-10%.
New Susceptibility Genes in Individuals with Non-PHTS CS and a CS-Like Disorder
A pilot study found that individuals with Cowden syndrome (CS) and a CS-like (CSL) disorder without germline PTEN pathogenic variants (but with increased levels of manganese superoxide dismutase) harbored germline variants in SDHB (OMIM 612359) and SDHD (OMIM 615106) [Ni et al 2008]. That germline variants in SDHB, SDHC, and SDHD occur in approximately 10% of persons with CS or CSL who do not have a PTEN pathogenic variant has been validated in an independent series of 608 research participants [Ni et al 2012]. These variants were associated with stabilization of HIF1a, destabilization of p53 secondary to decreased NQ01 interaction, and increased reactive oxygen species with consequent apoptosis resistance. Approximately 10% of individuals with CS/CSL disorder without germline PTEN or SDHx pathogenic variants have been found to harbor germline PIK3CA (see PIK3CA-Related Segmental Overgrowth) or AKT1 pathogenic variants [Orloff et al 2013]. Another 3%-6% of CS and CS-like individuals without pathogenic variants in the above known genes have germline heterozygous SEC23B pathogenic variants, which are particularly associated with thyroid carcinoma [Yehia et al 2015].
Management
Evaluations Following Initial Diagnosis
To establish the extent of disease and needs of an individual diagnosed with PTEN hamartoma tumor syndrome (PHTS), the following evaluations are recommended:
- Complete medical history and family history
- Physical examination with particular attention to skin, mucous membranes, thyroid, breasts
- In children: consideration of neurodevelopmental evaluation
- Urinalysis with cytospin
- Baseline thyroid ultrasound examination* (on identification of a PTEN pathogenic variant)
- For women age ≥30 years at diagnosis*:
- Breast screening (at minimum mammogram; MRI may also be incorporated)
- Transvaginal ultrasound or endometrial biopsy
- For men and women age ≥35 years at diagnosis*: colonoscopy
- For men and women age ≥40 years at diagnosis*: renal imaging (CT or MRI preferred)
- Consultation with a clinical geneticist and/or genetic counselor
* For individuals with a family history of a particular cancer type at an early age, screening may be considered five to ten years prior to the youngest diagnosis in the family.
Treatment of Manifestations
The mucocutaneous manifestations of Cowden syndrome are rarely life threatening:
- If asymptomatic, observation alone is prudent.
- Cutaneous lesions should be excised only if malignancy is suspected or symptoms (e.g., pain, deformity, increased