The Inherited and Familial Component of Early-Onset Colorectal Cancer.

Early-onset colorectal cancer (EOCRC), defined as that diagnosed before the age of 50, accounts for 10-12% of all new colorectal cancer (CRC) diagnoses. Epidemiological data indicate that EOCRC incidence is increasing, despite the observed heterogeneity among countries. Although the cause for such increase remains obscure, ≈13% (range: 9-26%) of EOCRC patients carry pathogenic germline variants in known cancer predisposition genes, including 2.5% of patients with germline pathogenic variants in hereditary cancer genes traditionally not associated with CRC predisposition. Approximately 28% of EOCRC patients have family history of the disease. This article recapitulates current evidence on the inherited syndromes that predispose to EOCRC and its familial component. The evidence gathered support that all patients diagnosed with an EOCRC should be referred to a specialized genetic counseling service and offered somatic and germline pancancer multigene panel testing. The identification of a germline pathogenic variant in a known hereditary cancer gene has relevant implications for the clinical management of the patient and his/her relatives, and it may guide surgical and therapeutic decisions. The relative high prevalence of hereditary cancer syndromes and familial component among EOCRC patients supports further research that helps understand the genetic background, either monogenic or polygenic, behind this increasingly common disease.

1. Introduction

Early-onset colorectal cancer (EOCRC), defined as that diagnosed before the age of 50, accounts for 10–12% of all new colorectal cancer (CRC) diagnoses [1,2]. Early-onset cancer, together with familial aggregation of cancer and diagnosis of multiple primary tumors, is one of the hallmarks of inherited cancer predisposition. The identification of a hereditary cancer syndrome, i.e., of a germline pathogenic variant in a hereditary cancer gene, has significant implications for the carriers and their families, as it helps risk assessment, directs clinical management, and guides preventive and therapeutic options [3,4].

The prevalence of hereditary cancer syndromes among EOCRC patients is ≈13% (prevalence range in different reports: 9–26%) [5,6,7,8,9,10,11,12]. The variability observed among studies may be due to (i) different patient inclusion criteria, such as different age cut-offs; (ii) different germline testing approaches, which range from the study of a few major CRC genes to the analysis of multigene hereditary cancer panels or whole exomes; (iii) population-specific founder effects; (iv) variant classification disparities. Table 1 shows the results of different studies assessing the hereditary component of EOCRC. In addition to the known hereditary cancer syndromes—including CRC predisposition syndromes and other cancer syndromes not traditionally associated with CRC—a relevant, still-to-be-determined proportion of EOCRC may be explained by the accumulation of low-risk CRC alleles [13].

Table 1

Prevalence of germline pathogenic variants in hereditary cancer genes among early-onset colorectal cancer (EOCRC) patients. Studies including >100 EOCRC patients and analyzing multiple (>10) hereditary cancer genes or whole exomes are listed in the table.

Study [Population]	EOCRC Age Cutoff	No. Patients Analyzed	Testing Approach	Hereditary Cancer	Gene/Mutation Spectrum in CRC Genes a% P or LP Variant Carriers (n)	Gene/Mutation Spectrum in Other Cancer Genes a,b% P or LP Variant Carriers (n)
Laduca 2020 [11][Different populations]	<50	Mean: 2672 (range: 986–4017)	Nine different multigene panels (5–49 genes evaluated)	362/4017 (9.0%)	5.3% MMR genes (213/3994)0.5% APC (20/3884)0.4% biallelic MUTYH (15/3953)0.1% SMAD4 (5/3881)0.1% BMPR1A (3/3881)0.0% STK11 (1/3954)0,0% PTEN (1/4014)0.0% GREM1 (1/2366)	1.5% BRCA1/2 (21/1387)1.1% CHEK2 (43/3954)1.0% ATM (14/,345)0.2% TP53 (9/4017)0.1% PALB2 (2/1350)0.1% BARD1 (1/1339)0.3% BRIP1 (4/1342)0.1% RAD51C (1/1342)0.2% CDKN2A (2/1228)0.1% SMARCA4 (1/986)0.1% NBN (2/1339)0.1% CDH1 (2/3965)0.1% NF1 (1/1298)
Chubb 2016 [9][UK]	≤55	1006	Exome sequencing	158/1006 (15.7%)	11% MMR genes (111)1.9% APC (19)0.9% biallelic MUTYH (9)0.4% POLE/POLD1 (4)0.1% biallelic NTHL1 (1)	0.9% BRCA1/2 (9)0.3% ATM (3)0.1% TP53 (1)0.1% PALB2 (1)
Pearlman 2017 [5][USA]	<50	450	25-gene panel	65/450 (14.4%)	8.2% MMR genes (37)1.1% APC (5)0.9% APC p.I1307K (4)0.9% biallelic MUTYH (4)0.2% SMAD4 (1)0.2% APC/PMS2 (1)	0.45% BRCA1 (2)0.9% BRCA2 (4)0.7% ATM (3)0.2% ATM/CHEK2 (1)0.45% PALB2 (2)0.2% CDKN2A (1)
DeRycke 2017 [10][USA, Canada, Australia]	<50	333	36-gene panel	88/333 (26.4%)	13.5% MMR genes (45)3.3% APC (11)1.5% biallelic MUTYH (5)0.9% SMAD4 (3)0.6% BMPR1A (2)0.3% PTEN (1)	1.8% CHEK2 (6)0.6% TP53 (2)0.9% CDH1 (3)2.1% RECQL5 (7)0.6% FLCN (2)0.3% biallelic BLM (1)
Stoffel 2018 [6][USA]	<50	315	124-gene panel67-gene panel	76/315 (24.1%)	17.8% MMR genes (56)2.5% APC (8)2.2% biallelic MUTYH (7)0.6% SMAD4 (2)	0.3% BRCA1 (1) 0.3% CHEK2 (1)0.3% TP53 (1)
Jiang 2020 [12] [China]	<50	261	14 genes analyzed by target sequencing	47/261 (18%)	15.7% MMR genes (41)1.5% APC (4)0.4% biallelic MUTYH (1)c0.4% STK11 (1)
Mork 2015 [8][USA]	<35	205	Variety of germline tests	41/193 (21.2%)	11.9 % MMR genes (23)6.7% APC (13)1% biallelic MUTYH (2)1% biallelic MSH6/PMS2 (2)	0.5% TP53 (1)
Total		6587		837/6587 (12.7%)	682/6587 (10.4%)	155/6587 (2.4%)

a Pathogenic and likely pathogenic variants, as reported by the authors, are considered in the calculations. b Carriers of disruptive variants (frameshift, stop-gain and start-loss variants) are considered for non-CRC cancer genes in the study by Chubb et al. c Considered biallelic, although there are no specific details in the original article.

In this article we review the inherited cancer syndromes associated with CRC predisposition and their prevalence among EOCRC patients according to the published data, the role of low-risk genetic variants, and the unexplained familial component of EOCRC, finishing with the recommendations for genetic testing and counseling in EOCRC.

2. Inherited Syndromes That Predispose to EOCRC

Known hereditary colorectal cancer syndromes and their contribution to EOCRC, based on the data recapitulated in this review, are represented in Figure 1.

Figure 1

Hereditary colorectal cancer (CRC) syndromes, associated phenotypes, causal genes, and contribution to EOCRC.

2.1. Lynch Syndrome and Constitutional Mismatch Repair Deficiency

2.1.1. Lynch Syndrome

Lynch syndrome is the most common form of hereditary CRC, accounting for 1–3% of all CRC cases [14]. It is an autosomal dominant disorder caused by the presence of a germline pathogenic variant in one of the alleles of the mismatch repair genes MLHI, MSH2, MSH6, or PMS2, by a 3′ deletion in the EPCAM gene that causes the epigenetic silencing of MSH2, or by the constitutional methylation of the MLH1 promoter [15]. The somatic inactivation of the wildtype allele of the corresponding MMR gene leads to abnormal DNA repair function which causes the accumulation of errors during DNA replication, especially in the repetitive sequences known as microsatellites. As a result, tumors of patients with Lynch syndrome characteristically show MMR deficiency, defined as the presence of microsatellite instability (MSI) and/or loss of MMR protein expression [16]. Individuals with Lynch syndrome have an increased lifetime risk of developing CRC and neoplasms in other organs, including endometrium, ovaries, stomach, small bowel, urinary tract (urothelial), biliary tract, prostate, brain (usually glioblastoma), skin (sebaceous adenomas, sebaceous carcinomas, and keratoacanthomas), and pancreas [14,17]. CRC develops through an accelerated adenoma-carcinoma sequence, and at a younger age compared to sporadic CRC [18]. Lynch syndrome patients have a risk of developing CRC by age 70 of 40–50% for MLH1 and MSH2 heterozygous carriers, 20% for MSH6 carriers and a significant lower risk for PMS2 carriers [14], according to the most recent findings of the international, multicenter Prospective Lynch Syndrome Database calculations (visit www.plsd.eu (accessed on January 2021) for cancer type, gene, and gender-specific risks). In the case of endometrial cancer, the risk by age 70 is 35–46% for MLH1, MSH2 and MSH6, and 13% for PMS2. The estimated risks largely vary among studies due to their prospective/retrospective nature, ascertainment biases, population analyzed, and statistical methods used [19,20,21,22,23].

Although MMR deficiency is the hallmark of Lynch syndrome, 10–15% of MMR-deficient CRCs are not Lynch syndrome, being this deficiency caused by (i) somatic methylation of the MLH1 promoter, usually associated with BRAF somatic mutations; or (ii) double somatic mutations in the MMR genes, which explains the majority of Lynch-like cases [24], i.e., patients with an MMR deficient tumor with no identified germline pathogenic variant in an MMR gene and no somatic MLH1 promoter methylation [25]. In line with their most likely sporadic nature, patients with double somatic MMR mutations are diagnosed with cancer at more advanced ages than Lynch syndrome patients, and display less frequently family history of Lynch syndrome tumors. In a small proportion of these cases, double somatic mutations are associated with germline pathogenic variants in other hereditary cancer DNA repair genes such as MUTYH, POLE or POLD1; i.e., due to the germline defect that alters DNA repair or polymerase proofreading and causes accumulation of mutations in the tumor, these may occur in MMR repair genes [26,27,28]. In the Ohio Colorectal Cancer Prevention Initiative, where 450 population-based EOCRC patients were studied, 2% of the CRCs analyzed (9/450), constituting 18.8% of all MMR-deficient EOCRCs, had double somatic mutations in the MMR genes [5]. The same group, by studying a total of 283 MMR-deficient, non-MLH1 methylated CRC patients not selected by age (populations: USA and Iceland), found that 55% had Lynch syndrome and 32.5% had double somatic MMR gene mutations [24]. Mismatch repair deficiency, whether caused by germline or somatic genetic or epigenetic alterations, leaves a particular mutation pattern in the tumors represented by specific mutational signatures of the Catalogue of Somatic Mutations in Cancer (COSMIC), such as SBS6 [29,30].

The prevalence of Lynch syndrome among EOCRC patients is ≈8% (range: 5–18%) (Table 1), being the distribution among the different MMR genes highly dependent on the population/ethnicity and its relative frequency of founder pathogenic variants [5,6,7,8,9,10,31,32].

The diagnosis of Lynch syndrome is a challenge due to the absence of pathognomonic clinical signs. The presence of a germline pathogenic variant is required to establish the definitive diagnosis. Current diagnostic strategies include the study of families or individuals with familial aggregation and/or early onset of Lynch syndrome-associated tumors; the so-called universal MMR deficiency testing, which implies that all patients with CRC undergo tumor IHC of MMR proteins and/or MSI testing. MMR-deficient cases (excluding those with somatic MLH1 promoter methylation) should be tested for germline mutations. However, current guidelines (NCCN) recommend performing germline panel testing in all EOCRC. In addition to germline testing, somatic panel testing is also recommended to identify double somatic MMR gene mutations.

2.1.2. Constitutional Mismatch Repair Deficiency (CMMRD)

CMMRD is an autosomal recessive condition associated with a high risk of cancer in children, adolescents and young adults that results from biallelic germline pathogenic variants in the MMR genes (MLH1, MSH2, MSH6, or PMS2). MMR deficiency in normal tissues is the hallmark of the syndrome. CMMRD-affected individuals are at high risk of developing hematologic, brain and colorectal cancers, among other tumors, at a remarkably early age. Most patients with CMMRD have non-neoplastic features, with multiple café-au-lait maculae (CALM) being the most prevalent, and also including colorectal and duodenal adenomas. Diagnostic criteria for the clinical suspicion of CMMRD were defined by the European Care for CMMRD Consortium (C4CMMRD) [33]. The CMMRD clinical phenotype includes hematological neoplasms (mainly non-Hodgkin’s lymphoma, lymphoid leukemia, acute myeloid leukemia); brain and central nervous system tumors (more frequently high-grade gliomas, sPNET-supratentorial primitive neuroectodermal tumors), and Lynch syndrome-associated cancers such CRC, small bowel and endometrial cancer.

CRC is diagnosed at very early ages (mean age at diagnosis: 16 years) and current guidelines recommend colonoscopy screening starting at 8 years of age, although adenomatous polyps have been detected even at earlier ages [33,34]. None of the genetic studies performed in ≤55 EOCRC patients shown in Table 1 identified biallelic pathogenic variants in the MMR genes (total number of ≤55 CRC patients where MMR genes were analyzed: 6359), suggesting that the prevalence of CMMRD among EOCRC is extremely low, and/or that the <50 or ≤55 age cutoff defined as inclusion criterium is too high to select for CMMRD cases. In fact, Mork et al. (2015) identified two CMMRD cases among 193 CRC patients diagnosed at age ≤35 years (prevalence 1%) [8], suggesting that the lower the age of CRC diagnosis, the higher the chances of identifying a CMMRD patient.

2.2. Nonpolyposis Mismatch Repair Proficient EOCRC: RPS20 and Other Candidate Genes

A large proportion of nonpolyposis familial and/or EOCRCs is not explained by germline alterations in the MMR genes, being their tumors MMR proficient. For years, researchers unsuccessfully looked for their genetic cause. The rapid development of sequencing-based techniques and genome-wide copy number techniques brought hope for the identification of new causal genes for nonpolyposis familial and EOCRC. However, despite the enormous efforts made, which led to the identification of over a hundred candidate genes (reviewed by Terradas et al. [35]), up to date only RPS20 has shown consistent association with hereditary nonpolyposis CRC. Among the other ≈100 candidate genes identified, nine currently show promising evidence to support their involvement in CRC predisposition: MRE11, BARD1, POT1, BUB1B, POLE2, BRF1, IL12RB1, and PTPN12, and the epigenetic alteration of PTPRJ [35]. Additional candidate genes are published on a regular basis that require validation in large cohorts and functional studies that support their involvement in colorectal carcinogenesis.

RPS20 was first identified as a hereditary CRC gene in 2014 by Nieminen et al. [36]. RPS20 c.147dupA (p.Val50Serfs*23) was found in eight CRC-affected members (ages at first CRC diagnosis: 24–75) of a Finnish four-generation family. Six of the eight affected carriers or obligate carriers had developed the first CRC before 55 years of age (24, 33, 43, 50, 52 and 54 years), and three of them had developed metachronous CRCs at age ≤60 years. All studied tumors were MMR proficient and although they did not show loss of the RPS20 wildtype allele, patients carrying the RPS20 c.147dupA variant showed a marked increase of 21S pre-rRNAs, supporting a late pre-rRNA processing defect consistent with haploinsufficiency; i.e., the two wild type copies of the gene are required for a normal phenotype. Subsequently, exome sequencing analyses performed on 863 EOCRC patients led to the identification of a disruptive RPS20 variant (p.Leu61Glufs*11) in a 39 year-old individual with metachronous CRC, and a predicted pathogenic missense variant (p.Val154Leu) in a patient diagnosed with CRC at age 41. In contrast, no rare missense or disruptive RPS20 variants were found among 1604 cancer-free controls [37]. While our group found no predicted pathogenic RPS20 variants among 473 familial/EOCRC cases [38], a recent study identified a splicing variant, c.177 + 1G>A, in a family with four CRC-affected members (ages at diagnosis: 38–61), all of them carriers or obligate carriers of the RPS20 variant [39]. Although information from additional carriers are required to estimate risks and recommend gene-specific surveillance measures, available data suggests low prevalence (allele frequency in familial/early onset CRC patients: 2/2724; 0.07%) and high penetrance (13/16 (81%) >35-year-old carriers of disruptive or canonical splice-site variants were affected with CRC) for RSP20 pathogenic variants, as well as absence of extracolonic manifestations [35].

2.3. APC-Associated Polyposis

Familial Adenomatous Polyposis (FAP) is an autosomal dominant syndrome responsible for less than 1% of all CRC cases [40]. It is characterized by the development of hundreds to thousands of adenomas in the colorectum, with a high risk of CRC at an early age. Extracolonic manifestations (duodenal polyps and cancer, desmoid tumor, osteomas, epidermoid cysts, papillary thyroid carcinoma, pancreatic carcinoma, gastric cancer, hepatobiliary, and CNS tumors) are also part of the phenotype [41].

FAP is caused by germline pathogenic variants in the APC gene. De novo APC mutations are responsible for approximately 25% of FAP cases. Moreover, approximately 20% of individuals with an apparent de novo APC mutation have somatic mosaicism (when two or more cell lines in the same individual differ genetically) [42].

FAP may be classified in two categories: (i) the classic form, that consists of the involvement of the entire colon with the development of >100 adenomas (sometimes >1000) during the second decade of life, with a 100% risk of CRC before age 40 years if untreated; (ii) the attenuated form, with 10–100 colorectal adenomas, usually diagnosed later in life and associated with a lower CRC risk (79–80% if untreated) [43].

FAP is the second most frequent hereditary cancer syndrome in EOCRC, being the prevalence among EOCRC (age <50 or ≤55) patients 1.1% (range: 0.5–3.3%) (Table 1). Mork et al. [8] detected APC pathogenic variants in 6.7% (13/63) of patients diagnosed with CRC at age ≤35, suggesting that the earlier the age at CRC diagnosis, the larger the probability of identifying carriers of APC pathogenic variants.

2.4. Polymerase Proofreading-Associated Polyposis (PPAP)

Germline pathogenic variants affecting the proofreading activity of polymerases ε (POLE) and δ (POLD1) cause an autosomal dominant cancer and polyposis predisposing syndrome called polymerase proofreading-associated polyposis (PPAP) [44]. The phenotypic spectrum of PPAP mostly includes colorectal adenomas and CRC, diagnosed in adulthood (mean age 35–50), followed by endometrial, ovarian and breast cancer. Other tumors associated with this syndrome are adenomas and malignant tumors of the upper gastrointestinal tract, brain tumors, cancer of the small intestine and pancreatic cancer [45]. Tumors are diagnosed in the adulthood, except for the rare cases that present a CMMRD-like phenotype, characterized by severe phenotypes, including cancer, in childhood or adolescence [46,47].

The major function of polymerases ε and δ is to replicate the genome, however, unlike other polymerases, ε and δ contain an active 3’-5’ exonuclease domain which proofreads newly synthesized DNA for replication errors. This proofreading is essential for replication fidelity, therefore, its disruption by pathogenic mutations leads to the accumulation of thousands of mutations in the tumors, often >100 mutations per Mb, which is called ultramutated phenotype. Moreover, they present a characteristic spectrum of nucleotide changes that largely differs from that observed in microsatellite stable (MSS) and MSI tumors. This mutation pattern consists of C > A transversions in the context of TCT and C > T transitions in the context of TCG, corresponding to the COSMIC tumor mutational signature SBS10 [29,30]. Heterozygous exonuclease domain mutations, causing 50% of proofreading activity, are enough to increase the mutation frequency, thus not requiring a second hit in the target tissue [44]. Most proofreading-defective tumors are MSS, nevertheless, MSI or somatic DNA MMR gene mutations have been detected in some instances [45], most probably produced by the deficient proofreading activity due to a secondary mutation in an MMR gene. Proofreading deficiency has been associated with good prognosis and excellent response to immune checkpoint inhibition [48].

We recently assessed the prevalence of PPAP among familial and patients by analyzing 2309 prospectively recruited patients assessed in a hereditary cancer clinical program. Our results indicated that PPAP constitutes 0.1–0.4% of familial cancer cases, reaching 0.3–0.7% when only familial/early-onset CRC and polyposis patients were considered [49]. POLE and POLD1 analyses were only covered by Stoffel et al., Laduca et al. and Chubb et al., identifying pathogenic variants affecting the proofreading activity of the polymerases in 0.1% (4/3687) of EOCRC patients (Table 1).

2.5. MUTYH-Associated Polyposis (MAP)

MAP is an autosomal recessive syndrome caused by biallelic pathogenic variants in the MUTYH gene. This gene is a component of the base excision repair system that protects genomic information from oxidative damage. Two common founder missense pathogenic variants, p.Tyr179Cys (rs34612342) and p.Gly396Asp (rs36053993), are present in up to 70% of Caucasian patients with this condition and have a carrier frequency of 0.75% in populations of (non-Finnish) European ancestry [50].

Individuals with MAP can exhibit a wide range of phenotypes including classic and attenuated adenomatous polyposis, seldom including cases where no polyps were identified at the time of the CRC diagnosis [51]. MAP-associated tumors and polyps are usually MMR proficient, however, MSI may also be detected due to somatic inactivation of the MMR genes, thus explaining some Lynch-like cases [27,52]. As occurs for other genes involved in DNA repair, a specific mutational signature has been associated with MUTYH deficiency, COSMIC signature SBS36, characterized by enrichment of C>A transversions in an NCA or NCT context [30,53,54].

Biallelic MUTYH pathogenic variants occur in 0.7% (range: 0.4–2.2%) of EOCRC patients (Table 1).

Several studies indicate that MUTYH monoallelic carriers are at slight increased CRC risk (1.5–2.5-fold relative to the general population), particularly in the presence of familial CRC history [55,56], although the evidence is still conflicting. MUTYH heterozygotes, who do not develop polyposis, would benefit from population screening measures but could also be offered average moderate-risk colorectal screening based on their family history [57].

2.6. NTHL1 Tumor Syndrome

Weren et al. described in 2015 the second recessive inheritable form of adenomatous polyposis caused by biallelic pathogenic variants in a DNA base excision repair gene, affecting, in this case, the Nth like DNA glycosylase 1 (NTHL1) [58]. Previously called NTHL1-associated polyposis, today, the preferred name for this syndrome is NTHL1 Tumor Syndrome, based on the high risk to different benign and malignant tumor types that biallelic variants in NTHL1 confer [59].

To date, 36 individuals from 23 different families carrying biallelic germline pathogenic variants in NTHL1 have been reported in specific publications [37,58,60,61,62,63,64,65,66]. Unlike other cancer predisposing syndromes, all variants reported in NTHL1 biallelic carriers are stop-gain, frameshift or canonical splice-site variants; no missense variants have been yet identified as cause of the disease (data obtained October 2020). Over 90% (21/23) of the reported NTHL1 biallelic carrier families carry the recurrent c.268C>T (p.Gln90Ter) stop-gain variant, being 60% of all (14/23), homozygous carriers.

Regarding the phenotypic expression of the syndrome, all 31 biallelic individuals that underwent a colonoscopy were found to have developed adenomatous polyps (range: 1 > 150) [37,58,60,61,62,63,64,65,66]. Four individuals have developed less than five polyps at ages ranging from 33 to 53, and >10 colorectal adenomas were found in 21/27 (77.8%) patients for which the exact number of polyps was provided. Up to the date of reporting, 20 of the 36 NTHL1 biallelic carriers (56%) were diagnosed with colorectal cancer, eight of whom diagnosed before the age of 50 years, and the median age at first CRC diagnosis was 53 years (age range: 33–73 years). Due to the ascertainment bias in the reported individuals, accurate cancer risk estimation, mostly for colorectal cancer, has not been possible to calculate; even though, available data suggest that the lifetime risk of CRC in the NTHL1 tumor syndrome is likely high.

Two thirds (24/36, 66.7%) of all reported biallelic carriers have developed extracolonic malignancies including 15 different tumor types, being breast cancer the most common extracolonic cancer (53% of female carriers were affected with breast cancer), followed by endometrial cancer. Other extracolonic malignancies identified include duodenal polyps and cancer, meningiomas, hematologic malignancies, squamous cell carcinoma, bladder cancer, basal cell carcinoma, cervical cancer, pancreatic cancer, prostate cancer, thyroid cancer, kidney cancer, and brain cancer. Among the 36 NTHL1 biallelic carriers, 29 (80.6%) were diagnosed with CRC and/or another type of cancer at a median age of 47 years (range: 24–67) at first diagnosis and 18 of them (62.1%) showed an early age of onset (<50 years).

The prevalence of NTHL1 biallelic germline carriers is rare and has been estimated to be around 1:114,770, five times lower than the estimated prevalence for MUTYH-associated polyposis (1:19,079) [67]. The prevalence of biallelic cases among polyposis patients has been estimated to be ≈2% [49,68]. Chubb et al. identified germline biallelic inactivation of NTHL1 in 0.1% of the EOCRC included in the study. No other studies listed in Table 1 included NTHL1 in their analyses.

Tumors developed by NTHL1 biallelic carriers, independently of the tissue of origin, accumulate specific somatic mutations characterized by an enrichment of C > T transitions at non-CpG sites, which translates into a distinct mutational signature, COSMIC signature SBS30 [66,69].

2.7. Hamartomatous Polyposis

2.7.1. Peutz–Jeghers Syndrome (PJS)

PJS is a rare autosomal dominant syndrome characterized by pigmentation of mucocutaneous melanin and multiple gastrointestinal polyposis. These polyps, with characteristic histological features (frond-like elongated epithelial component along with cystic gland dilatation and smooth muscle arborization), have a high risk of developing gastrointestinal cancers of the colorectal, pancreatic and gastric organs. In addition, PJS patients have an increased risk for a wide variety of non-gastrointestinal epithelial malignancies, such as cancers of the breast, uterus, cervix, ovary, testicles, and lung. A meta-analysis performed by Hearle et al. and aggregating 419 patients with PJS estimated a cumulative risk for any cancer by age 50 years of 30% and by age 70 of 85%, and a risk for gastrointestinal cancer of 15% and 57% at the respective ages [70]. Mucocutaneous pigmented lesions are seen in around 95% of patients and may be the first clue to an individual having PJS. Such lesions arise in the infancy, occurring around the mouth, but may be seen at other sites such as nostrils, perianal area, fingers and toes, etc. [71].

Germline mutations in STK11 (also called LKB1) are the only known cause of PJS. Between 80% and 94% of families with a PJS phenotype have an identifiable LKB1/STK11 mutation [72]. A clinical diagnosis of PJS can be made when an individual has two or more of the following features: two or more Peutz–Jeghers polyps of the small intestine; typical mucocutaneous hyperpigmentation; and a family history of PJS [73]. The prevalence PJS in the EOCRC population is expected to be low (0.03%, Table 1), and clinical manifestations of the syndrome should guide suspicion (i.e., intussusception or intestinal obstruction due to large polyps in the childhood or adulthood, mucocutaneous hyperpigmentation, etc.).

2.7.2. Juvenile Polyposis

Juvenile Polyposis (JP) is a rare autosomal dominant syndrome characterized by the presence of juvenile hamartomatous polyps in the gastrointestinal tract, with a lifetime risk of CRC of 20% [74]. JPS is caused by germline pathogenic variants in SMAD4 or BMPR1A, with a mutation in either one identified in 39% of patients with the clinical phenotype. Clinical diagnosis of JP includes the presence of more than five juvenile polyps in the colon and/or rectum; the presence of juvenile polyps along the digestive tract, including the stomach; or the presence of any number of juvenile polyps in association with a family history of JP [75,76].

Congenital defects occur in approximately 15% of JPS cases. A subset of patients with JPS also has hereditary hemorrhagic telangiectasia (HHT), more commonly seen in SMAD4 mutation carriers and characterized by mucocutaneous telangiectasias, gastrointestinal arteriovenous malformations and pulmonary arterio-venous malformations.

Germline pathogenic variants in either BMPR1A or SMAD4 are identified in 0.2% of EOCRC patients (Table 1).

2.7.3. PTEN Hamartoma Tumor Syndrome

PTEN hamartoma tumor syndrome (PHTS), comprising Cowden, Bannayan–Riley–Ruvalcaba, and Proteus-like syndromes, is a rare multisystem disorder associated with increased lifetime risks for several cancer types due to pathogenic germline variants in the tumor suppressor gene PTEN. In addition to the increased cancer risk, PHTS is associated with developmental delay, overgrowth phenotypes, including macrocephaly, benign tumors, and skin abnormalities [76]. The most frequent phenotype is called Cowden Syndrome, characterized by multiple hamartomas that can occur in any organ, macrocephaly, mucocutaneous lesions, and an increased risk of several tumors, including CRC. The estimated lifetime risk of cancer in individuals with PHTS range from 85% to 89% for any cancer, 67–85% for female breast cancer, 6–38% for thyroid cancer, 2–28% for endometrial cancer, 2–34% for renal cancer, 9–20% for colorectal cancer, and 0–6% for melanoma [77]. Patients usually present with colorectal polyps (typically hamartomas, but other types such as ganglioneuromas, hyperplastic, adenomatous and inflammatory polyps often occur), and CRC (age at diagnosis: 44–60 years) [78]. Accordingly, the prevalence of germline PTEN pathogenic variants among EOCRC patients is low (0.03%), almost negligible (Table 1).

2.8. RNF43-Associated Serrated Polyposis

Serrated polyposis syndrome (SPS) is characterized by the presence of numerous colorectal serrated polyps (SP), and it is associated with an increased personal and familial risk of CRC [79,80,81,82]. Although SPS is the most common polyposis syndrome [83,84], its etiology is the least understood. Overall, SPS behaves as a complex disorder consequence of the interaction of both genetic and environmental factors. Despite this complexity, the World Health Organization (WHO) has established specific clinical criteria, recently updated, to standardize the diagnosis and treatment in the clinical practice, as well as to prompt research in the field [85].

Until 2014, previous efforts to identify an inherited genetic cause for SPS had been unsuccessful. That year, Gala et al. provided the first evidence indicating that germline RNF43 pathogenic variants were associated with SPS [86]. Since then, three truncating and two missense germline pathogenic variants have been reported in 13 carriers from seven families [86,87,88,89,90]. In ClinVar, six different disruptive (stop-gain or frameshift variants) are listed in RNF43 (date of consultation: Oct 2020). Of the seven reported carrier families, five carry loss of function variants, being c.337C>T (p.Arg113Ter) and c.394C>T (p.Arg132Ter) found in two families each. Regarding the carriers’ phenotypes, 12 of the 13 carriers had been diagnosed with polyposis and/or CRC. The age at the polyposis diagnosis and the number of polyps detected are highly diverse, ranging from 18 to 65 years of age and from 2 to more than 100 polyps. Three carriers had developed colon or rectal cancers, diagnosed at ages 23, 49 and 55 years, suggesting a relevant role in EOCRC. According to the limited data available, the diagnosis of a CRC does not seem to be directly associated with the number of polyps developed. Extracolonic cancers or other clinical manifestations are highly uncommon. The colonic lesions developed by carriers of RNF43 pathogenic variants harbor somatic loss of heterozygosity or mutation in RNF43 (2nd hits were identified in 100% (23/23) of the tumors analyzed); 50% (9/18) had CpG island methylator phenotype (CIMP). RNF43 functions as a tumor suppressor by exerting a negative feedback in the Wnt/β-catenin signaling pathway. Pathogenic variants in RNF43 cause Wnt addiction, which makes RNF43-mutated tumors good responders to PORCN inhibitors [91], opening a window of opportunity for the treatment of tumors developed by RNF43 carriers.

The frequency of pathogenic variants in RNF43 among SPS patients, taking into account the two largest unselected serrated polyposis cohorts, is 1.76% (3/170) [89,90]; up to 2.63% (5/190) if all European cohorts are considered [86,89,90]. Due to the novelty and rarity of RNF43, reported studies using multigene panel testing in EOCRC did not include RNF43. Nevertheless, access to CanVar (https://canvar.icr.ac.uk/ (accessed on January 2021)), a public database that gathers whole-exome and -genome sequencing information of 1006 CRC patients diagnosed before age 60 years, showed that six patients carried rare germline missense variants, none of which was predicted pathogenic (REVEL > 0.5). No loss of function variants or variants affecting canonical splice sites were detected.

2.9. GREM1-Associated Mixed Polyposis

The term hereditary mixed polyposis syndrome originally referred to the presence of multiple polyps of different histological types (serrated lesions, conventional adenomas, and hamartomas) and/or the presence of individual polyps with various overlapping histological features (atypical juvenile and admixed histologic features) [92,93,94]. While the genetic cause remains elusive in most cases, germline variants in and upstream of GREM1 have been identified in some affected individuals. In 2012, Jaeger et al. identified a 40-Kb duplication upstream of GREM1 at chr15:30,752,231–30,792,051 (hg19), as the underlying cause of hereditary mixed polyposis in families of Ashkenazi Jewish origin [95]. The 40-kb duplication has been identified in 1:184 Ashkenazi Jewish individuals with personal or familial history of polyposis or CRC [96]. In addition to the founder Ashkenazi duplication, additional (non-Ashkenazi) variants identified include: a 16-Kb duplication affecting the GREM1 5′ regulatory region identified in a large family affected with polyposis of multiple polyp types, CRC, breast and gastric cancer [97]; a 24-Kb tandem duplication in the 5′ regulatory region identified in an Amsterdam-positive nonpolyposis CRC family, and a large duplication encompassing the whole GREM1 gene in a patient with a CRC diagnosed at age 35 [98].

The data gathered to date indicate that GREM1 duplications may occur in individuals with or without polyposis. The onset of the polyposis usually occurs in the adulthood (late 20s or older), although there are reports of polyps identified earlier in life. The phenotypes may overlap with familial adenomatous polyposis or Lynch syndrome (no polyps), and extracolonic tumors have been reported [96]. The nature of the alterations in this gene and the challenge of their detection by analyzing NGS data, as is the case of multigene panels, made the identification of GREM1 duplications in the studied EOCRC patients difficult, preventing their reporting. Laduca et al. identified one GREM1 pathogenic variant (nature not detailed in the original article) among 2366 EOCRC patients analyzed [11].

2.10. Clinical Consequences of having a Hereditary CRC Syndrome

Carrying a pathogenic variant in a cancer-predisposing syndrome has relevant consequences for the clinical management of the carrier. Consensus cancer surveillance guidelines and surgical recommendations, either prophylactic and/or therapeutic, for major colorectal cancer syndromes have been established and are periodically revised. For the rare syndromes that have been described more recently, such as those caused by pathogenic variants in NTHL1, POLE and POLD1, RNF43 or GREM1, assessment of the clinical information from reported carriers is helping refine the corresponding clinical guidelines [57,98,99,100,101,102]. Together with periodic colonoscopy screening, chemoprevention might complete the precision prevention approach recommended for hereditary colorectal cancer and/or polyposis syndromes [103,104]. In particular, aspirin is recommended for Lynch syndrome carriers by most clinical guidelines [57], showing the most recent, long-term data from the CAPP2 study a robust reduction in incident colorectal cancers in Lynch syndrome carriers taking aspirin 600 mg/day. These data also show that aspirin uptake for a finite duration (mean 25 months) had sustained reduction in colorectal cancer incidence persisting for 20 years [105]. Nevertheless, additional data are expected that will define optimal dose (CAPP3 study), duration, and patient selection for Lynch syndrome-associated aspirin chemoprevention [106].

On the other hand, the choice of tumor chemotherapy treatment is influenced by specific tumor features that are characteristic of some hereditary syndromes [107]. Immune checkpoint blockade has proven effective in hypermutated tumors, including MMR- and POLE/POLD1- proofreading-deficient tumors [108,109], and recent preliminary data from a single case indicate that this treatment might also be effective for MUTYH-deficient tumors [110]. Other potential treatments for tumors developed in the context of a hereditary CRC syndrome include PORCN inhibitors for RNF43-deficient tumors [91], and the potential use of agents that induce BER-dependent DNA damage (e.g., Oxaliplatin or Temozolomide) might be considered for NTHL1- or MUTYH-deficient tumors (to be considered in future clinical assays).

In summary, recognition of a hereditary CRC syndrome in an eoCRC patient is extremely relevant for his/her clinical management, entitling specific surgical and treatment options depending on the mutated gene, and conditioning future clinical surveillance of the carrier and his/her relatives. Recent best practice pieces of advice for eoCRC patients recommend clinicians to counsel patients on the benefit of germline genetic testing in the presurgical period to inform which surgical options may be available to the patient; to use germline and somatic testing results to inform chemotherapeutic strategies; to offer, to the patient and other carrier family members, specific screening for CRC and extra-colonic cancers depending on the risks associated with the mutated gene [107].

3. EOCRC in Non-CRC Cancer Syndromes

Data obtained from comprehensive multigene pan-cancer panels applied to familial and early-onset cancer, consistently demonstrate that many individuals who harbor pathogenic or likely pathogenic germline cancer susceptibility gene variants have clinical histories that fail to fulfill traditional, syndrome-specific guidelines, have atypical clinical phenotypes that a priori would not fit into the syndrome’s classical phenotype, or have germline pathogenic variants in more than one cancer-predisposing gene [111]. In this regard, EOCRC patients may also harbor pathogenic variants in genes not traditionally associated with CRC predisposition, such being the case for BRCA1, BRCA2, TP53, ATM, CHEK2, PALB2, CDKN2A, etc. (Table 1, [112,113]); these occurring in ≈2.5% of EOCRC cases.

4. Familial Aggregation of CRC in EOCRC

While ≈13% (range: 9–26%) of EOCRC carry germline pathogenic variants in known cancer predisposition genes, ≈28% (range: 13–33%) have family history of CRC [5,6,8,9,10,11,114,115,116,117]. On the one hand, the absence of family history of CRC among EOCRC patients with a hereditary cancer syndrome ranges from 16.5% [6] to up to 60% [114], therefore a significant proportion of hereditary cases would not be suspected based on family history of this disease. On the other hand, a variable but relevant proportion of EOCRC patients have family history of CRC but no pathogenic variants in known hereditary cancer genes.

Large variability in the prevalence of family history of CRC is observed among studies focused on EOCRC: Stoffel et al. reported that 26% (111/430) of the EOCRC included in their study had at least one first-degree relative affected with CRC [6]], while this figure dropped to 6.7% in the EOCRC series analyzed by Chen et al. Considering family history of CRC as the presence of one 1st-, 2nd-, or 3rd-degree relative affected with the disease, O’Connell et al. [117] and Chen et al. [116] reported that 23–25% of EOCRC patients had familial CRC history and Stoffel et al. [6] reported that 57.2% if any relative with CRC is taken into account. The latter observed that the earlier the age at cancer diagnosis, the higher the chances of having family aggregation of the disease. Mork et al. reported that 18.6% of patients diagnosed before 35 years had at least one 1st or 2nd degree relative affected with CRC [8].

Individuals with family history of CRC (excluding hereditary syndromes) are known to be at increased risk for CRC. This risk is considered to be relevant in individuals with a first degree-relative (FDR) diagnosed below the age of 50 and in cases with two or more FDR with CRC [118]. In these situations, current guidelines recommend colonoscopy starting at age 40 years and performed every 5 years [118]. Family history of adenomas has been also associated with an increased CRC risk, however, the evidence is scarce and there is no clear consensus: whereas the ESGE guidelines [118] do not recommend screening in individuals with a FDR with adenomas, the U.S. Multi-Society Task Force of Colorectal Cancer [119], recommend screening for individuals with a FDR affected with an advanced adenoma before age 60 (colonoscopy starting at age 40 or 10 years before the age of diagnosis of the advanced adenoma in the FDR).

Unfortunately, screening guidelines for familial CRC are usually not followed. A major obstacle is the incomplete patient family history in medical records. Gupta et al. [120] in a cohort of 614 patients with CRC diagnosed between the ages of 40 and 49 years, reported that 98.4% (604 patients) should have been recommended to start screening at a younger age that their age at CRC diagnosis based on family history. Likewise, Stanich et al. observed that 97 (13.6%) of 713 EOCRC had family history of CRC, estimating that 82.5% (80/97) could have been diagnosed early and that 67% (65/97) would have had a potentially preventable CRC if screening guidelines based on family history would have been followed [114].

In summary, it is essential to optimize screening for CRC with early initiation of colonoscopy in cases with familial CRC history. Encouraging pedigree evaluation and stricter adherence to early CRC screening in this population is key to reduce EOCRC incidence and mortality.

5. Low Risk Alleles and EOCRC

The fact that only ≈13% of EOCRC is explained by germline pathogenic variants in high penetrance genes suggests that another relevant fraction might be caused by the accumulation of genetic variants with low–moderate effect on cancer susceptibility.

Hundreds of common genetic variants associated with CRC susceptibility have been identified in the last years by means of genome-wide association studies (GWAS) (https://www.ebi.ac.uk/gwas (accessed on January 2021)). The use of a polygenic risk score (PRS) generated from 95 association signals could impact clinical decisions for CRC preventive screening in European populations [121]. Archambault et al. recently demonstrated that the 95 variant-based PRS correlated more strongly with EOCRC than with late-onset CRC, by testing 12,197 early-onset CRC patients (age < 50 years) and 95,865 CRC patients diagnosed at age ≥ 50 [13]. Patients in the highest PRS quartile had 3.7-fold increased risk for EOCRC (95% CI, 3.28–4.24) and a 2.9-fold increased risk for late-onset CRC (95% CI, 2.80–3.04), compared with the lowest quartile group. The association was stronger in patients without a first-degree family history of CRC, being the risk increased in this group 4.3-fold (95% CI, 3.61–5.01) vs. 2.9-fold (95% CI, 2.70–3.00) for early- and late-onset CRC, respectively, when the highest quartile was compared with the lowest.

It is expected that predictive models that implement a PRS in combination with environmental and lifestyle risk factors will, in the (near) future, be able to identify individuals at high risk of CRC that would benefit from preventive measures or other intervention strategies at earlier ages than the ones established in population-based screening programs or based on family history of CRC.

6. Genetic Counseling and Genetic Testing Recommendations for EOCRC

Patients with EOCRC should be referred to a specialist service that includes genetic counseling and access to somatic and germline testing. Current guidelines recommend tumor screening for MMR deficiency for all CRC regardless of age and family history for Lynch syndrome diagnosis [99,122]. Germline testing should be offered to patients with MMR deficiency (with no evidence of MLH1 promoter methylation) and those with polyposis. Since double somatic mutations in the MMR genes are presented in a meaningful proportion of patients with unexplained MMR deficiency, current guidelines already recommend paired germline and somatic MMR testing [122]. In this sense tumor MMR sequencing may be helpful for EOCRC showing MMR deficiency and no germline pathogenic variant detected [24]. The identification of double somatic mutations may be very helpful since these patients and their close relatives should be managed based on their family history as they are not Lynch syndrome.

The data presented in this review (Table 1) suggest that a comprehensive multigene pan-cancer panel should be analyzed in every EOCRC patients, regardless of tumor MMR deficiency status. This recommendation is based on the prevalence of known hereditary CRC syndromes (≈10%), and also on the fact that ≈2.5% of EOCRC patients carry a germline pathogenic variant in a gene not traditionally linked to hereditary CRC. EOCRC patients with hereditary cancer syndromes should be managed according to established gene-specific surveillance guidelines. If possible, testing should occur prior to surgery since its results can affect surgical decision-making and therapeutic selection.

7. Conclusions

Epidemiological data indicate that EOCRC incidence is increasing at a global level, showing variability among countries. Established lifestyle cancer drivers such as diet, sedentary style, smoking, and obesity have been linked to EOCRC. Still unknown, probably unsuspected, nongenetic factors remain to be discovered. Hereditary syndromes are behind the pathogenicity of ≈13% of patients with EOCRC. In addition, a meaningful proportion of cases display either family history of CRC with no known high-penetrance genetic cause, or a germline pathogenic variant in genes not traditionally associated with CRC predisposition.

Genetic testing using a multigene pan-cancer panel is recommended in all EOCRC patients, ideally in paired germline and tumor samples. On the other hand, preoperative and pretherapeutic testing is highly advisable, as it could give the best ability for informed surgical decision-making and for treatment selection, specifically when a pathogenic variant in an MMR gene, the exonuclease domain of POLE or POLD1, or a gene involved in homologous recombination (BRCA1/2, ATM, PALB2), is detected. In addition, the identification of a known hereditary cancer syndrome has relevant implications for cancer prevention in patients and relatives.

Considering the prevalence of family history of CRC in EOCRC patients, improving adherence to current screening guidelines for individuals with CRC family history, would clearly have a significant impact on decreasing EOCRC. The implementation in predictive risk assessment of polygenic risk scores, together with family history information and lifestyle risk factors, will help better identify individuals at high risk of CRC that may benefit from cancer screening strategies or other interventions at earlier ages, also helping decrease the incidence of EOCRC.