Mutyh Polyposis

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Summary

Clinical characteristics.

MUTYH polyposis (also referred to as MUTYH-associated polyposis, or MAP) is characterized by a greatly increased lifetime risk of colorectal cancer (CRC). Although typically associated with ten to a few hundred colonic adenomatous polyps, CRC develops in some individuals in the absence of polyposis. Serrated adenomas, hyperplastic/sessile serrated polyps, and mixed (hyperplastic and adenomatous) polyps can also occur. Duodenal adenomas are common, with an increased risk of duodenal cancer. The risk for malignancies of the ovary and bladder is also increased, and there is some evidence of an increased risk for breast and endometrial cancer. Additional reported features include thyroid nodules, benign adrenal lesions, jawbone cysts, and congenital hypertrophy of the retinal pigment epithelium.

Diagnosis/testing.

The diagnosis is established in a proband by identification of biallelic germline pathogenic variants in MUTYH on molecular genetic testing.

Management.

Treatment of manifestations: Suspicious polyps identified on colonoscopy should be removed until polypectomy alone cannot manage the large size and density of the polyps, at which point either subtotal colectomy or proctocolectomy is performed. Duodenal polyps showing dysplasia or villous changes should be excised during endoscopy. Abnormal findings on thyroid ultrasound examination should be evaluated by a thyroid specialist to determine what combination of monitoring, surgery, and/or fine needle aspiration is appropriate.

Surveillance: Colonoscopy with polypectomy every one to two years beginning at age 25-30 years; upper endoscopy and side viewing duodenoscopy every three months to four years beginning at age 30-35 years with subsequent follow up based on initial findings. Consider annual physical examination, thyroid ultrasound, and skin examination by a dermatologist.

Individuals with a heterozygous germline MUTYH pathogenic variant: offer average moderate-risk colorectal screening based on family history.

Evaluation of relatives at risk: It is appropriate to clarify the genetic status of apparently asymptomatic older and younger sibs of an individual with MAP by molecular genetic testing for the MUTYH pathogenic variants identified in the proband in order to reduce morbidity and mortality in those who would benefit from appropriate surveillance beginning at age 10-15 years and early identification and treatment of polyps.

Genetic counseling.

MAP is inherited in an autosomal recessive manner. At conception, each sib of an affected individual has a 25% chance of being affected, a 50% chance of being a carrier with a small increased risk for CRC, and a 25% chance of being unaffected and not a carrier. Carrier testing for at-risk family members and prenatal diagnosis for pregnancies at increased risk are possible if the pathogenic variants in the family have been identified.

Diagnosis

Suggestive Findings

MUTYH polyposis (MAP) should be suspected in an individual with the following clinical findings and family history [NCCN 2019].

Clinical findings

  • A personal cumulative lifetime history of ten or more colorectal adenomas in an individual age ≤60 years
  • A personal cumulative lifetime history of 20 or more colorectal adenomas in an individual of any age
  • A personal cumulative lifetime history of any combination of 20 or more colorectal adenomas, hyperplastic polyps, and/or sessile serrated polyps (excluding rectal and sigmoid hyperplastic polyps)
  • Sessile serrated polyposis syndrome:
    • At least five serrated polyps proximal to the sigmoid colon, of which two or more are >10 mm; OR
    • >20 serrated polyps of any size distributed throughout the colon (excluding hyperplastic polyps found in the rectum and sigmoid colon)
  • Duodenal polyp(s) and/or duodenal cancer
  • Colorectal cancer with or without a history of polyps and identification of a somatic KRAS pathogenic variant (c.34G>T in codon 12) or identification of specific mutational signature on tumor tissue testing due to a high percentage of somatic G>T transversions (e.g., COSMIC Signature 18; SigProfiler SBS18/SBS36; SignatureAnalyzer SBS18/SBS36) [Viel et al 2017].

Family history of colorectal cancer (± polyps) consistent with autosomal recessive inheritance.

Establishing the Diagnosis

The diagnosis of MAP is established in a proband by identification of germline biallelic pathogenic variants in MUTYH by molecular genetic testing (see Table 1 and Table 2).

Germline molecular genetic testing approaches can include gene-targeted testing (single-gene testing and/or multigene panel). Since the phenotype of MAP (as described in Suggestive Findings) overlaps with a number of other hereditary polyposis and colorectal cancer syndromes (see Differential Diagnosis), many individuals with MAP will likely be diagnosed using a multigene panel.

  • Single-gene testing. Sequence analysis of MUTYH detects small intragenic deletions/insertions and missense, nonsense, and splice site variants; typically, exon or whole-gene deletions/duplications are not detected. Perform sequence analysis first. If only one or no pathogenic variant is found, perform gene-targeted deletion/duplication analysis to detect intragenic deletions or duplications (Table 1).
  • A multigene panel that includes MUTYH and other genes of interest (see Differential Diagnosis) 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. 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. (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 this disorder a multigene panel that also includes deletion/duplication analysis is recommended (see Table 1).
    For an introduction to multigene panels click here. More detailed information for clinicians ordering genetic tests can be found here.

Table 1.

Germline Molecular Genetic Testing Used in MUTYH Polyposis

Gene 1MethodProportion of Pathogenic Variants 2 Detectable by Method
MUTYHSequence analysis 3~99% 4
Gene-targeted deletion/duplication analysis 5See footnote 6
1.

See Table A. Genes and Databases for chromosome locus and protein.

2.

See Molecular Genetics for information on allelic variants detected in this gene.

3.

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.

4.

Out et al [2010]

5.

Gene-targeted deletion/duplication analysis detects intragenic deletions or duplications. Methods used may include quantitative PCR, long-range PCR, multiplex ligation-dependent probe amplification (MLPA), and a gene-targeted microarray designed to detect single-exon deletions or duplications.

6.

A large (>4.2-kb) deletion encompassing exons 4-16 has been reported in three affected individuals from Spain, France, and Brazil, indicating a possible southern European founder variant [Rouleau et al 2011, Torrezan et al 2011, Castillejo et al 2014]. A deletion of exon 15 has also been reported [Ricci et al 2017].

Table 2.

Detection Frequency of Biallelic Germline MUTYH Pathogenic Variants by Number of Polyps in Individuals with APC Mutation-Negative Polyposis

Number of PolypsDetection Frequency of Biallelic Germline MUYTH Pathogenic Variants
1-192% (25/1,430)
10-192% (58/2,634)
20-4911% (60/540)
20-997% (306/4,425)
50-9921% (22/107)
100-99916% (133/809)
>1,0008% (2/24)

Based on Grover et al [2012], Stanich et al [2019], Terlouw et al [2020]

Tumor tissue testing prior to germline molecular genetic testing of a proband is generally not required; however, it may be required in certain circumstances (e.g., by third-party payer policy). In other instances, review of past tumor testing on a proband may help determine the preferred germline molecular genetic testing approach (i.e., single-gene testing vs use of a multigene panel).

  • Identification of a somatic KRAS pathogenic variant. The KRAS pathogenic variant (c.34G>T in codon 12), present in less than 5%-10% of sporadic colorectal cancers (CRCs), is found in 40%-100% of adenomas and 60%-90% of CRCs in persons with MAP [Nielsen et al 2011, Viel et al 2017]. Furthermore, 10%-25% of persons with CRCs with this somatic KRAS variant have biallelic germline MUTYH pathogenic variants.
    KRAS somatic molecular genetic testing is often routine in advanced CRCs to identify individuals who are eligible for MUTYH germline molecular genetic testing, including probands with atypical clinical findings (CRC and no or very few adenomas) [van Puijenbroek et al 2008, Guarinos et al 2014, Aimé et al 2015, Viel et al 2017].
  • Microsatellite instability (MSI)-low (For information on MSI testing including advantages and disadvantages, click here). Although the majority of CRCs in persons with MAP are microsatellite stable, the MSI-high phenotype is found in a minority (0%-18%, mean: 4%) (see review in Nielsen et al [2011], Castillejo et al [2014]).

Clinical Characteristics

Clinical Description

MUTYH polyposis (MUTYH-associated polyposis; MAP) is characterized by a greatly increased lifetime risk for colorectal cancer (CRC) (43%-63% at age 60 years and a lifetime risk of 80%-90% in the absence of timely surveillance). The risk for malignancies of the duodenum, ovary, and bladder is also increased, and there is some evidence of an increased risk for breast and endometrial cancer (Table 3).

Table 3.

Cancer Risks in Individuals with MUTYH Polyposis Compared to the General Population

Cancer TypeGeneral
Population Risk 1
Risk Associated with MAP 2Median Age
of Onset
Colorectal5.5%43%-63% by age 60 yrs; 80%-90% lifetime risk w/out surveillance48 yrs
Duodenal<0.3%4%61 yrs
Ovarian1.3%6%-14%51 yrs
Bladder1%-4%6%-8% in females; 6%-25% in males61 yrs
Breast12%12%-25%53 yrs
Endometrial2.9%~3%51 yrs
Gastric<0.7%-1%1%38 yrs
Pancreatic1.6%See footnote 3
Skin~20% 4See footnote 3
Thyroid0.6%-1.8%See footnote 3
1.

US National Cancer Institute's Surveillance Epidemiology and End Results (SEER) Database 2012-2014

2.

Nielsen et al [2006], Lubbe et al [2009], Vogt et al [2009], Win et al [2014], Walton et al [2016]

3.

Unclear if the risk for this type of cancer is increased in individuals with MAP

4.

Including basal cell carcinoma

Colon polyps and cancer. Most individuals with MAP have between ten and a few hundred colonic polyps with a mean age of presentation of approximately 50 years. Persons with MAP can have colonic adenomas as well as serrated adenomas, hyperplastic/sessile serrated polyps, and mixed (hyperplastic and adenomatous) polyps [Sieber et al 2003, Chow et al 2006, Boparai et al 2008, O'Shea et al 2008]. Of note, eight of 17 persons with MAP had one or more hyperplastic colonic polyps and/or sessile serrated adenomas; findings in three of these eight individuals met criteria for the serrated polyposis syndrome (see Differential Diagnosis) [Boparai et al 2008]. A rectal clustering (studding) of a large number (i.e., >20) of hyperplastic polyps was found in ten of 16 persons with MAP [Church & Kravochuck 2016].

Molecular genetic testing of individuals with CRC has revealed that up to one third of persons with biallelic germline MUTYH pathogenic variants develop CRC in the absence of colonic polyposis [Croitoru et al 2004, Farrington et al 2005, Balaguer et al 2007, Cleary et al 2009, Pearlman et al 2017]. In a minority (0%-3.7%) of affected individuals, biallelic germline MUTYH pathogenic variants have been found in the index case of a family with a phenotype suggestive of Lynch syndrome [Nielsen et al 2011, Castillejo et al 2014].

In the absence of timely surveillance, the lifetime risk for CRC in individuals with MAP was between 80% and 90% [Lubbe et al 2009, Win et al 2014]. Colon cancers were found to be right-sided in 29%-69% of individuals with MAP [Lipton et al 2003, O'Shea et al 2008, Nielsen et al 2009a]. Metachronous or synchronous colon cancers occurred in 23%-27% of individuals with MAP [Lipton et al 2003, Nielsen et al 2009a].

In one report, survival of individuals with MUTYH CRC on average was better than survival in individuals with colorectal adenocarcinoma and unknown family history who did not have microsatellite instability testing [Nielsen et al 2010]. Five-year survival for persons with MAP CRC was 78% (which, after adjustment for differences in age, stage, sex, subsite, country, and year of diagnosis, remained better than for controls).

Duodenal polyps and cancer. Duodenal polyps occur in 17%-34% of individuals with MAP. The lifetime risk for duodenal cancer is approximately 4% [Nielsen et al 2006, Vogt et al 2009, Walton et al 2016].

Ovarian cancer. The incidence of ovarian cancer was significantly increased in women with MAP, with a lifetime risk of 6%-14% and median age at diagnosis of 51 years [Vogt et al 2009, Win et al 2016]. Biallelic germline MUTYH pathogenic variants were uncommon in a large cohort of women with ovarian cancer (1/7,646) [LaDuca et al 2020].

Bladder cancer. The incidence of bladder cancer was significantly increased, with a lifetime risk of 6%-8% for females and 6%-25% for males with MAP and a median age at diagnosis of 61 years (range 45-67) [Vogt et al 2009, Win et al 2016].

Other cancers

  • Breast cancer. It is unclear if the risk for breast cancer is increased in women with MAP. The risk was found to be higher in one study, with median age at diagnosis 53 years (range 45-76) [Vogt et al 2009]. However, a second study did not find an increased breast cancer risk [Win et al 2016]. Although biallelic germline MUTYH pathogenic variants have not been reported in individuals from large breast cancer cohorts, one male with biallelic germline MUTYH pathogenic variants was reported in a cohort of 560 males with breast cancer [Rizzolo et al 2018].
  • Endometrial cancer was diagnosed in two of 118 women with MAP, with a median age at diagnosis of 51 years and a lifetime risk of approximately 3% [Vogt et al 2009]. Sutcliffe et al [2019] reported endometrial cancer in four of 45 women with MAP.
  • Gastric fundic gland polyps and gastric cancer. Among 150 individuals with MAP undergoing endoscopic surveillance, 17 (11%) had gastric fundic gland polyps. Although a higher risk for gastric cancer than in the general population was observed, the trend was not significant [Vogt et al 2009].
  • Pancreatic cancer. Two (2%) of 83 individuals with MAP were diagnosed with pancreatic cancer [Sutcliffe et al 2019]. Two additional studies including 276 individuals with MAP did not report any instances of pancreatic cancer [Vogt et al 2009, Win et al 2016].
  • Skin cancer. Thirteen of 276 individuals with MAP had a diagnosis of skin cancer including melanomas, squamous epithelial carcinomas, and basal cell cancers [Vogt et al 2009]. In this same cohort, five individuals also had sebaceous gland adenomas or sebaceous gland epitheliomas. Another study reported two melanomas and six other skin cancers in 81 individuals with MAP [Sutcliffe et al 2019].
  • Thyroid cancer. Three of 24 individuals with MAP evaluated by thyroid ultrasound had papillary thyroid cancer [LaGuardia et al 2011]; a high incidence of thyroid cancer was not reported in other studies and may have reflected selection bias. Vogt et al [2009] reported two instances of thyroid cancer in 276 individuals with MAP.

Other extraintestinal findings in persons with MAP

  • Thyroid nodules were identified in 16 of 24 individuals with MAP examined by ultrasound [LaGuardia et al 2011]. A second study reported thyroid nodules in two of 82 individuals with MAP [Sutcliffe et al 2019].
  • Adrenal lesions (all benign and not hyperfunctioning) were identified in five (18%) of 21 of individuals with MAP in a prospective study [Kallenberg et al 2017].
  • Dental abnormalities. Jawbone cysts were reported in 11 of 276 persons with MAP [Vogt et al 2009].
  • Congenital hypertrophy of retinal pigment epithelium (CHRPE). The estimate of CHRPE in individuals with MAP is about 5.5%; however, this figure may also include misdiagnoses since pigment anomalies of the retina are quite frequent in the general population [Vogt et al 2009].

Heterozygotes

The risk for CRC in individuals heterozygous for a germline MUTYH pathogenic variant was only marginally increased in large population-based and family-based studies [Jenkins et al 2006, Jones et al 2009, Win et al 2014]. In a prospective study of 62 MUTYH heterozygotes, the frequency of colonic and upper GI polyps was not increased [El Hachem et al 2019].

The risk of developing extraintestinal cancer in MUTYH heterozygotes is unclear. A slightly increased cumulative risk for MUTYH heterozygotes for gastric, hepatobiliary, endometrial, and breast cancer was reported by Win et al [2016]. Other case-control studies did not find an association between MUTYH heterozygosity and risk for breast cancer or hepatocellular carcinoma [Baudhuin et al 2006, Beiner et al 2009, Out et al 2012, Fulk et al 2019].

A heterozygous MUTYH pathogenic variant was identified in two of 45 individuals with neuroendocrine tumors (NET) of the pancreas and eight of 160 individuals with adrenocortical carcinomas (ACC) [Pilati et al 2017, Scarpa et al 2017]. Two of 15 probands with familial NET of the small intestine and four of 215 individuals with nonfamilial NET of the small intestine were heterozygous for MUTYH pathogenic variant p.Gly396Asp [Dumanski et al 2017]. It is unclear if a heterozygous MUTYH pathogenic variant is a risk factor for NET or ACC, as the risk of NET or ACC in individuals with biallelic MUTYH pathogenic variants appears to be quite low.

Genotype-Phenotype Correlations

Functional studies have shown differences in glycosylase activity between the c.536A>G pathogenic variant and the c.1187G>A pathogenic variant [Banda et al 2017]. Differences were also seen in clinical manifestations: homozygosity for c.536A>G was associated with a more severe phenotype and an approximately eight-year-earlier age of onset compared to homozygosity for c.1187G>A [Lubbe et al 2009, Nielsen et al 2009b, Terdiman 2009, Morak et al 2010].

For other common variants, such as p.Glu324His, which has up to a 50% minor allele frequency in some populations [Banda et al 2017], association with cancer risk has been reported; however, the reported risks are not consistent with mendelian inheritance and are not used to direct patient care.

Nomenclature

An outdated term for MUTYH polyposis is "autosomal recessive adenomatous polyposis."

The gene formerly designated MYH is now MUTYH.

Prevalence

It is estimated that 1%-2% of the general northern European, Australian, and US populations are heterozygous for a germline MUTYH pathogenic variant [Al-Tassan et al 2002, Cleary et al 2009, Win et al 2017]. The Genome Aggregation Database (gnomAD) reports a somewhat lower frequency of MUTYH pathogenic variants (~0.8%). Using these figures, the prevalence of 1:20,000 to 1:60,000 for persons with biallelic germline MUTYH pathogenic variants can be derived.

MAP is estimated to account for 0.7% of all CRC and between 0.5% and 6% of cohorts of familial or early-onset CRC in which affected individuals have a low number of adenomas (<15-20) [Sieber et al 2003, Cleary et al 2009, Lubbe et al 2009, Landon et al 2015, Pearlman et al 2017]. See also Table 4.

Table 4.

Percentage of Persons with MAP by Age at Diagnosis of CRC

Persons with Biallelic MUTYH Pathogenic VariantsAge at Diagnosis of CRC
% (n)Range
1.3% (52/3,976)0.5%-6.2%<50 years
0.3% (28/11,150)0.0%-0.6%>50 years

Review of literature, Nielsen et al [2011], Landon et al [2015], Pearlman et al [2017]

CRC = colorectal cancer

Differential Diagnosis

MUTYH polyposis (MAP) can be distinguished from other inherited polyposis and colon cancer conditions by clinical findings, pathologic findings, mode of inheritance, and molecular genetic testing. Conditions to consider in the differential diagnosis include the disorders summarized in Table 5.

Table 5.

Disorders to Consider in the Differential Diagnosis of MUTYH Polyposis

Cancer Susceptibility SyndromeGene(s) /
Genetic
Mechanism
MOIPolyps /
Colon Cancer
Associated
Malignancies
Other Features /
Comments
APC-associated polyposis conditionsAPCADAttenuated FAP:
  • 0-100 colonic polyps
  • CRC risk: 70%
FAP:
  • 100 colonic polyps
  • Upper GI polyps
  • CRC risk: 100%
  • Small bowel
  • Pancreatic
  • Thyroid
  • Liver
  • Brain
  • Bile duct
  • Gastric
  • CHRPE
  • Osteomas
  • Supernumerary or missing teeth
  • Cutaneous lesions
  • Desmoid tumors
NTHL1-associated polyposisNTHL1AR
  • 8-50 adenomatous colonic polyps
  • Duodenal adenomas
  • CRC in 16/29 individuals
Extracolonic cancer in 12/29 individuals:
  • Uterine
  • Duodenal
  • Breast
  • Premalignant endometrial lesions
  • 2nd most common AR form of colon cancer & polyps after MAP 1
Lynch syndrome
(hereditary non-polyposis colon cancer)
MLH1
MSH2
MSH6
PMS2
EPCAM
AD
  • 4% develop ≥10 polyps
  • Colon tumors often MSI+
  • CRC risk: 52%-82%
  • Uterine
  • Ovarian
  • Small bowel
  • Gastric
  • Urinary tract
  • Skin
  • Brain
  • Hepatobiliary tract
  • Pancreas
  • Prostate
Peutz-Jeghers syndromeSTK11AD
  • GI hamartomatous polyps
  • Polyps most often in small bowel
  • Adenomatous colonic polyps can occur.
  • CRC risk: 39%
  • Gastric
  • Breast
  • Ovarian
  • Small bowel
  • Pancreas
  • Cervix
  • Uterine
  • Lung
  • Testicular
  • Ovarian sex cord tumors w/annular tubules
  • Dk-brown to dk-blue melanocytic macules (fade w/age)
Juvenile polyposis syndromeBMPR1A
SMAD4
AD
  • Hamartomatous (juvenile) polyps in small bowel, stomach, colon, & rectum
  • CRC risk: 38.7%
  • Gastric
  • Upper GI tract
  • Pancreas
Hereditary hemorrhagic telangiectasia (SMAD4-related)
PTEN hamartoma tumor syndromePTENAD
  • Multiple hamartomatous & mixed polyps in GI tract
  • CRC risk: 9%
  • Breast
  • Thyroid
  • Uterine
  • Renal
  • Brain
  • Melanoma
  • Thyroid disease/nodules
  • Uterine fibroids
  • Macrocephaly
  • Lipomas
  • Mucocutaneous lesions
  • Pigmented macules of glans penis
  • Hamartomatous overgrowth of tissues
  • Connective tissue nevi
  • Epidermal nevi
  • Hyperostoses
Hereditary mixed polyposis syndrome (OMIM 610069, 601228)BMPR1A
GREM1
dup 15q13-q14 2
AD
  • Adenomatous polyps, juvenile polyps, hyperplastic polyps, & polyps containing mixed histology
  • ↑ CRC risk 3
Desmoid tumor, prostate cancer, & duodenal adenocarcinoma reported in 1 individual 4Rare condition (few families)
Sessile serrated polyposis syndrome
(OMIM