Abstract
Inherited thrombocytopenias (IT) are genetic diseases characterized by low platelet count, sometimes associated with congenital defects or a predisposition to develop additional conditions. Next-generation sequencing has substantially improved our knowledge of IT, with more than 40 genes identified so far, but obtaining a molecular diagnosis remains a challenge especially for patients with non-syndromic forms, having no clinical or functional phenotypes that raise suspicion about specific genes. We performed exome sequencing (ES) in a cohort of 116 IT patients (89 families), still undiagnosed after a previously validated phenotype-driven diagnostic algorithm including a targeted analysis of suspected genes. ES achieved a diagnostic yield of 36%, with a gain of 16% over the diagnostic algorithm. This can be explained by genetic heterogeneity and unspecific genotype-phenotype relationships that make the simultaneous analysis of all the genes, enabled by ES, the most reasonable strategy. Furthermore, ES disentangled situations that had been puzzling because of atypical inheritance, sex-related effects or false negative laboratory results. Finally, ES-based copy number variant analysis disclosed an unexpectedly high prevalence of RUNX1 deletions, predisposing to hematologic malignancies. Our findings demonstrate that ES, including copy number variant analysis, can substantially contribute to the diagnosis of IT and can solve diagnostic problems that would otherwise remain a challenge.
Introduction
Inherited thrombocytopenias (IT) are a heterogeneous group of disorders characterized by low platelet count that can result in a bleeding tendency of variable degree. In these disorders, thrombocytopenia can be isolated or associated with additional congenital defects; moreover, some cases of IT have a predisposition to develop additional diseases over time, such as hematologic malignancies, bone marrow aplasia and renal failure.1
Until recently, the diagnosis of IT was based on a complex process requiring a multi-step clinical and laboratory characterization of patients and subsequent resequencing of candidate genes.2 The introduction of next-generation sequencing revolutionized the diagnostic approach to these disorders, allowing the analysis of virtually all known genes at one time by exome sequencing (ES). Moreover, application of next-generation sequencing led to the identification of many novel genes underlying IT. These advances revealed a picture of wide genetic heterogeneity, with at least 40 genes implicated;1 it should, however, be noted that only a few genes account for most of the cases, while most genes explain less than 2% cases each.3 In spite of the recent progress, almost half of patients with familial IT still remain without a definite molecular diagnosis,3 which would be of key importance for clinical management and counseling.
ES of large numbers of patients, in association with clustering of results according to standardized clinical or functional phenotypes,4,5 has proven effective in the description of novel forms of IT and the identification of causative variants in known IT genes, thus achieving a molecular diagnosis for a substantial proportion of patients.6-9 However, phenotype-based approaches may be ineffective when thrombocytopenia is non-syndromic, with no additional phenotypes contributing to the patient’s clinical picture, or is not associated with detectable alterations in platelet function.
Here we report the analysis of 116 patients with non-syndromic IT who had remained without a definite molecular diagnosis after an extensive diagnostic workup. We show the power of the ES approach to improve the diagnostic yield over a phenotype-driven diagnostic algorithm and illustrate the reasons that make ES a strategy of choice in the molecular elucidation of these genetically heterogeneous disorders.
Methods
Patients
We recruited 116 patients among probands and available affected relatives from 89 families (Online Supplementary Table S1) with familial thrombocytopenia who remained without a molecular diagnosis after the application of a validated diagnostic algorithm2 including systematic phenotypic investigation and sequencing of candidate genes among the 21 IT genes defined before the beginning of the study (listed in Online Supplementary Table S2). By this approach, 54%of the probands did not have a definite diagnosis, and all those with the availability of DNA samples of suitable quality for ES analysis were enrolled in this study (Online Supplementary Figure S1). Details about the different forms of IT diagnosed through the application of the phenotype-driven diagnostic algorithm are reported in Online Supplementary Table S3. All the cases recruited into the ES analysis presented apparently non-syndromic forms, with no clinical features additional to thrombocytopenia and no specific platelet function alterations.
The study was approved by the Ethics Committee of the IRCCS Policlinico San Matteo Foundation. All investigated individuals or their legal guardians provided written informed consent to participation in the study, which was conducted in accordance with the Declaration of Helsinki. Individual data were completely de-identified.
Exome sequencing
ES was carried out on DNA from whole blood after enrichment and capture with different strategies (Online Supplementary Methods). Sequence data analysis was performed as already described.10
Analysis of known inherited thrombocytopenia genes
We evaluated each patient for small variants and copy number variants (CNV) in 43 genes associated with IT (Online Supplementary Table S2), including 21 genes prescreened as part of the diagnostic algorithm and 22 genes found to be associated with IT in recent years (Online Supplementary Table S2).
Single nucleotide variants (SNV) and small insertions/deletions (indels) were selected according to minor allele frequencies and variant consequences, as detailed in the Online Supplementary Methods, and confirmed by Sanger sequencing in probands and available relatives. Variant classification followed the American College of Medical Genetics (ACMG) guidelines11 and the ClinGen Expert curation panel guidelines for RUNX1 variants.12 We evaluated segregation data as recommended by Jarvik and Browning.13
Analysis of runs of homozygosity was carried out on Family.43 with H3M2 to identify large exomic homozygous regions.14 The genomic inbreeding coefficient was calculated as the percentage of the cumulative length of auto-somal runs of homozygosity >1.5 Mb over the overall length of the autosomal genome.
Exome alignments were used to call and genotype CNV with Excavator2.15 Deletions encompassing RUNX1 were confirmed by real-time polymerase chain reaction (RT-PCR) and chromosomal microarray analysis (CMA) on an Agilent 8x60K platform.
Gene-based rare variant enrichment analysis
With the aim of identifying possible major contributing IT genes, in terms of prevalence, we carried out exome-wide collapsing of rare variants by gene to identify those bearing an excess of qualifying variants in IT probands compared to population-matched, unrelated controls. These included subjects of our exome datasets who were healthy or had genetic disorders with no hematologic involvement.
Qualifying variants were defined as SNV affecting the canonical transcript of protein-coding sequences (non-synonymous and splice-site variants) with a minor allele frequency ≤0.0001 in the ExAC non-Finnish European subpopulation. All 20,345 Gencode v19 protein-coding genes that were well-covered in most samples were considered (see the Online Supplementary Methods for more details). To exclude population stratification among cases and controls, we removed from the analysis: (i) samples with non-European ancestry, based on self-reported information, and (ii) outlier samples from a principal component analysis carried out on genotypes of our samples together with 2,504 samples from the 1000genomes dataset (h ttps://www.internationalgenome.org/).
For each gene under analysis, we modeled the number of subjects with at least one variant as a binomial distribution. We performed a two-proportion pooled test to verify the null hypothesis of equality of proportions of subjects with at least one variant in patients and controls. Multiple testing control was done applying the false discovery rate criterion proposed by Benjamini and Hochberg choosing a false discovery rate of 0.2.16
Variant confirmation by Sanger sequencing was carried out for the top ranking genes with a non-corrected P≤0.0015. Segregation analysis was performed whenever possible.
Results
First, we wanted to identify variants in IT-associated genes that could be defined as disease-contributing following ACMG criteria for establishing variant pathogenicity.
All the 43 known IT-associated genes, except GP1BB, GP9 and MPIG6B, achieved adequate sequence representation with average coverage of 132X (range: 72X-289X) and coverage higher than 20X on an average of 96.2% of targeted bases (range: 83.3% -100%) (Online Supplementary Table S2).
A total of 104 variants fulfilling selection criteria were identified in 60/89 probands (67%). According to ACMG criteria, 32 variants were classified as benign (B) or likely benign (LB), 40 were variants of uncertain significance (VUS), and 32 were classified as pathogenic (P) or likely pathogenic (LP). Table 1 reports P/LP variants, while Online Supplementary Table S4 lists the VUS and B/LB variants. Online Supplementary Table S6 reports the ACMG criteria applied for the classification of each variant. P/LP variants affected 30 probands and involved 18 genes. Most (75%; 24/32) were heterozygous variants in genes associated with autosomal dominant or autosomal dominant/recessive forms, while the remaining ones were either heterozygous X-linked variants (6%; 2/32) or heterozygous, compound heterozygous and homozygous variants in autosomal recessive genes (19%; 6/32).
The majority of P/LP variants (62%; 20/32) were in genes that would not have been previously analyzed because they were not included in the diagnostic algorithm,2 and that were already described in our previous publications.10,17-24 Conversely, 9/31 P/LP variants (29%) were heterozygous variants in IT-associated genes which should have been considered for analysis (Table 1), but that were overlooked because of erroneous interpretation or execution of the diagnostic algorithm: five variants affected genes that should have been suspected according to the clinical and laboratory findings of the patients (Family.9, CYCS; Family.21, ITGB3 and GP1BA; Family.26 and Family.27, RUNX1) but sequencing analysis was not performed. In four additional cases, laboratory or genetic tests failed to identify the implicated gene (in Family.8 and Family.35 Sanger sequencing missed the variants in ANKRD26 and GP1BA, respectively; in Family.23 the presence of MYH9 protein aggregates in leukocytes was not recognized at the immunofluorescence assay;25 in Family.17 with a variant in ITGA2B, flow cytometry failed to detect decreased expression of glycoprotein complex IIb-IIIa on the platelet surface26. Moreover, in vitro platelet aggregation in response to collagen, ADP, and arachidonate resulted within the normal range in the proband of this family).
Finally, in three cases the identification of the pathogenic variants had been hindered by non-Mendelian inheritance patterns or gender-related effects and only the unbiased (with respect to suspected inheritance) evaluation of qualifying variants in IT-associated genes allowed their recognition.
In one case (Family.43) (Figure 1A) the unreported consanguinity between both parents (II-1 and II-2) and grandparents (I-1 and I-2) of the probands (III-1 and III-2) resulted in a pseudo-dominant inheritance pattern of the ABCG8 c.1234C>T, p.Arg412Ter variant, which was homozygous in II-1, III-1 and III-2 and heterozygous in II-2. In a second family (Family.41) (Figure 1B), the LP variant WAS c.134C>T, p.Thr45Met on chromosome X, was inherited by two male siblings (IV-1 and IV-3) from their affected mother (III-4). An X-linked inheritance was initially not suspected, due to a phenocopy in the grandfather (II-1), who was considered to be affected because of a platelet count slightly below the normal threshold (120x109/L). In this situation, the high variability of platelet counts between the two probands (19 and 22x109/L) and mother (80x109/L) was attributed to other non-genetic factors, while it is most likely associated with the hemizygous versus heterozygous status of the variant. The status of the grandfather, II-1, revised based on the age- and gender-adjusted reference intervals for platelet count,27 was then classified as non-affected. Unfortunately a DNA sample from II-1 was not available; however, the fact that the other daughter, III-3, does not carry the variant indicates that II-1 is not a variant carrier.
In a third case (Family.40) (Figure 1C) we identified the heterozygous c.146delC, p.Pro50Argfs86Ter variant in GATA1, on the X chromosome, in the female proband (II-1). In this pedigree, an X-linked inheritance was not suspected because of a female-to-female transmission (I-2 also affected, but not available for genetic testing). Moreover, mild isolated thrombocytopenia due to GATA1 pathogenic variants (OMIM #300367) has been rarely reported in heterozygous females.28,29
Details about these three last cases are reported in the Online Supplementary Results.
We then reasoned that not all actual disease-contributing variants may be classified as P/LP, either because they are present in IT-associated genes but not fulfilling ACMG guidelines, or because they are in “novel” genes. We thus needed a method to highlight genes that had a significant burden of disease-contributing variants regardless of their P/LP classification. To this end, we performed a genebased rare variant enrichment analysis focused on qualifying variants (defined as predicted protein-altering variants with minor allele frequency ≤0.0001 in ExAC non-Finnish Europeans) in 81 unrelated cases and 215 controls of homogeneous Italian ancestry according to principal component analysis. A total of 6,320 genes with at least one qualifying variant in either cases or controls and fulfilling thresholds for adequate coverage were left for statistical analysis. Only two of the 18 IT-associated genes mutated in this cohort, namely ACTN130 and ETV6,31,32 attained a study-wide significant excess of qualifying variants in probands (P=0.0001 and P=0.0004, respectively). ACTN1 had nine qualifying variants in cases and one in controls, while ETV6 had six and zero, respectively (Table 2). Almost all ACTN1 and ETV6 alleles, including VUS and B/LB variants, were characterized by Combined Annotation Dependent Depletion (CADD) and Genomic Evolutionary Rate Profiling (GERP) scores as suggestive of a deleterious effect (i.e., CADD >20, GERP RS>4) as well as an ultra-low frequency in the general population (Table 1, Online Supplementary Table S4) but not all variant alleles could be defined as causative. As supported by our previous work, seven ACTN1 and three ETV6 alleles were classified as P/LP,17,18,22 while the other alleles were VUS or B/LB. No novel genes attained statistical significance.
Table 1.Pathogenic and likely pathogenic variants identified in the 43 known inherited thrombocytopenia genes.
Figure 1.Pedigrees of families with inherited thrombocytopenia. (AC) Families with pathogenic variants in ABCG8 (A), WAS (B) and GATA1 (C). Double lines indicate consanguineous unions. Platelet count (x109/L) and genotype are reported when available. wt: wt allele; mut: mutated allele.
We also asked whether disease-contributing genes could have top-ranking P values although not reaching statistical significance. We chose the highest 25 genes, i.e. showing a non-corrected P value ≤0.0015 (Table 2), finding no additional IT-associated gene. To understand whether novel genes could be present in this list, we performed segregation analysis of the variants in all the available relatives and collected the genes in which we found variants that segregated according to the disease (Online Supplementary Table S5). In this context, we suggest PREX1 as a potentially promising candidate, having no variants in controls and three variants in cases, all with scores indicative of a deleterious effect and of an intolerance to missense variants (Residual Variation Intolerance Score, RVIS 22.30, ExAC constraint 4.11) (Table 2, Online Supplementary Table S5).33 In two families, relatives were available for the analysis and PREX1 variants were segregating with the disorder in two and three affected members, respectively (Online Supplementary Figure S2). This gene has a role in regulating aggregation and dense granule secretion of mouse platelets.34 However, further genetic and/or functional data are needed to prove that this is an IT-associated gene.
We then argued that different types of variation, namely CNV, could play a role in disease. By using Excavator2,15 we identified heterozygous deletions involving RUNX1 in three unrelated families (Table 3, Figure 2). All the deletions were confirmed by RT-PCR, and chromosomal microarray analysis was used to annotate the genomic boundaries of the alterations (Figure 2A). In all the cases, RUNX1 is completely included within the breakpoints and is therefore present in a single copy in the carriers. The deletions were confirmed in seven, two and five affected individuals in Family.44 (Figure 2B), Family.66 (Figure 2C) and Family.72 (Figure 2D) respectively, in which they spanned 1.9 Mb (18 genes), 2.7 Mb (29 genes) and 900 Kb (7 genes). RUNX1 haploinsufficiency causes an autosomal-dominant IT with predisposition to myeloid malignancies (FPD-AML, OMIM #601399). Of note, Sanger sequencing of the whole RUNX1 gene had been performed in all the three probands before enrollment in this study, in accordance with the diagnostic algorithm. Few instances of large RUNX1 intragenic deletions have been described.35 The main clinical and laboratory features of our patients with heterozygous deletions involving RUNX1 are detailed in the Online Supplementary Results. A history of myeloid neoplasms was reported in Family.72 and Family.44. Interestingly, if both small variants (SNV and indels) and CNV were included in the enrichment analysis, RUNX1 would be among the top-ranking positions (5 variants in cases, 1 variant in controls; uncorrected P=0.00125).
Table 2.Gene-based rare variant collapsing analysis.
Overall, ES on all 89 families followed by a targeted analysis of 43 IT-associated genes achieved a 36% diagnostic yield (29 and 3 families with disease-causative SNV and CNV, respectively, out of 89). Compared to the phenotypedriven diagnostic algorithm on the same target genes, we estimated the increase of the diagnostic yield attained by ES as 16% (14/89), including 11 families with SNV and 3 families with full RUNX1 deletions.
Discussion
Until a few years ago, the diagnosis of IT was based on a multi-step clinical and laboratory characterization of patients and screening of candidate genes. In our experience, this approach made it possible to identify the causative genetic defect in just under 50% of cases.2 More recently, several groups introduced the use of next-generation sequencing techniques for a single-step, parallel sequencing of all the known genes associated with IT as a more effective, easier, and faster diagnostic approach. The results in terms of proportion of cases for which causative variants have been identified vary greatly according to different investigations.9,36-39
Differently from previous studies, here we applied ES to a cohort of IT patients who had remained without a definite diagnosis after the application of a systematic, well-defined diagnostic workup based on phenotype characterization and screening of candidate genes.2 For this reason, our population is particularly informative to assess the advantages and issues of ES as a complement to the traditional approach in the diagnosis of these disorders.
We report a 36% diagnostic rate in a large cohort of patients with non-syndromic IT. If we consider the same target genes as those in the phenotype-based diagnostic approach, we observed a 16% increase in the diagnostic yield attained with ES. This increase can be explained by the unbiased approach of ES to the analysis of proteincoding variations that overcomes three major problems. First, the genetic heterogeneity of IT, with more than 40 associated genes, makes the gene-by-gene approach very laborious and complex, which may negatively affect the adherence of clinicians to the diagnostic algorithm. As an additional complexity, patients with non-syndromic IT lack straightforward phenotypic features that easily raise diagnostic suspicion about specific genes, making the simultaneous analysis of all the genes the most reasonable strategy. Finally, false negative results from laboratory assays exploited in the diagnosis of IT can confound the process, as we observed in our cohort. Genetic heterogeneity also partially reflects on ES, since the larger the set of genes the higher the chance that candidate regions are not adequately represented (as reported here for GP1BB, GP9 and MPIG6B) and that VUS are found.
Figure 2.RUNX1 deletions. (A) RUNX1 deletions identified by exome sequencing were confirmed by chromosomal microarray analysis. Profiles from probands of Families 44, 66 and 72 (top to bottom panels) are shown. Highlighting indicates deleted regions. The top panel was produced by the UCSC Genome Browser (https://genome.ucsc.edu/) and shows the genomic positions and all genes included in the region. Segregation of deletions was evaluated by real-time polymerase chain reaction in Family.44 (B), Family.66 (C) and Family.72 (D). Genotype is reported when available.
Table 3.Deletions involving RUNX1 identified through analysis of exome data with Excavator2. Annotation of breakpoints identified by chromosomal microarray analysis are reported.
Indeed, the interpretation of ES-identified variants was confirmed to be a major challenge. Here, we found that the proportion of cases carrying at least one VUS in known IT genes was as high as 29% (26/89). Previously reported data range from 13 to 50%, depending on criteria for selecting patients to be analyzed, sequencing techniques, and bioinformatic processing of data.9,36-39 In our analysis, the availability of previous phenotypic and laboratory characterizations of pedigrees and the prompt access to DNA samples from patients’ relatives was essential to define the pathogenic or non-pathogenic role of variants in many cases. In particular, segregation analysis was determinant for downgrading 14 variants from P/LP to VUS and 13 variants from VUS to B/LB, as well as for upgrading one VUS to LP.
This emphasizes the synergistic role of next-generation sequencing and accurate phenotype description of pedigrees for the improvement of the diagnostic process for IT. In particular, such an approach would significantly improve the interpretation of variants, thereby reducing the number of VUS, and overcome the pitfalls of the traditional diagnostic workup. In this framework, interaction between specialists and discussion of cases in multidisciplinary teams including geneticists, hematologists and laboratory experts appears to be the most proficient strategy.25 Moreover, a periodic review of next-generation sequencing data in the light of new discoveries could be useful to refine the classification of variants.
Second, we showed that ES discloses causes of disease that could be otherwise overlooked according to assumptions made on the genetic model prior to the analysis. Indeed, we observed how instances of pseudo-dominance (Family.43), presence of phenocopies (Family.41) and unexpected female-to-female X-linked transmission (Family.40) can hinder a diagnosis during a process in which the mode of inheritance is incorrectly assumed to drive the selection of the suspected genes. Of note, these events, although occurring rarely, collectively contributed for a non-negligible proportion of cases in our cohort (3.4%) and we therefore suggest that they should be taken into account in IT.
Finally, although ES is tailored to detect small variants (i.e., single nucleotide changes and indels), its data can be successfully used to identify CNV as well. Indeed, based on ES data we detected large deletions encompassing RUNX1 in three cases (3.4%). Notably, this specific gene was suspected during the application of the diagnostic algorithm and its analysis by PCR and Sanger sequencing was correctly requested, but this technology could not identify these whole gene deletions. This finding is important as, if we consider all the IT probands available to us for whom a molecular diagnosis of IT was achieved (>165 families), the relative frequency of FPD-AML due to alterations of RUNX1 was 4.2% and whole deletions accounted for 43% of FPD-AML cases. Thus, deletions involving RUNX1 appear to be a relatively common cause of FPD-AML that may have been overlooked so far.
The gene-based variant enrichment analysis allowed us to identify ACTN1 and ETV6 as main contributing genes in this cohort. No further IT-associated gene, nor any “novel” gene, reached the study-wise statistical significance, confirming a picture of vast genetic heterogeneity for the genetic landscape of IT. It clearly emerged that only the few most frequent genes, including ACTN1, ETV6 and some of the genes that were pre-screened here (MYH9, ANKRD26, GP1BA, GP1BB) are prevalent in IT. Conversely, a constellation of many other genes, each accountable for substantially less than 2% of cases, must be searched for variants in a diagnostic setting. Accordingly, we observed that apart from ACTN1 and ETV6, the only two genes attaining study-wise statistical significance in the enrichment analysis, clinically relevant variation was dispersed across five (GNE, PTPRJ, SLFN14, SRC and THPO) of the 22 genes not in the pre-screening (Online Supplementary Table S2), accounting collectively for seven cases and for a maximum of two cases each, thereby emphasizing once again the genetic heterogeneity of IT.
Similarly, ”novel” genes (e.g., PREX1) may be present among those with top-ranking P values in the enrichment analysis, but their prevalence was too low to provide convincing evidence for an association with IT in this study. It is worth noting, in this respect, that if CNV and SNV had been included in the variant enrichment study, RUNX1 would have ranked with a top P value (5 variants in cases, 1 variant in controls; uncorrected P=0.00125). This supports an important role for RUNX1 in terms of prevalence and further highlights the importance of a comprehensive analysis of CNV and SNV, especially for this gene. We emphasize the importance of recognizing FPD-AML among IT since this disorder associates with a strong predisposition to hematologic neoplasms. Therefore, once a pathogenic variant in RUNX1 has been identified, molecular analysis should be extended to all available family members: all individuals carrying the RUNX1 mutation, including possible subjects with normal blood counts,6 should receive proper genetic counseling and be offered an appropriate follow-up, with at least annual evaluations according to recent recommendations.40 We expect that the application of the gene-based variant enrichment method presented here to larger cohorts might lead to the identification of new IT genes. As a limitation, we note that, in our study, segregation data weakened the role of many top-ranking genes. The application of the method on datasets in which more samples from the same family undergo ES could benefit from prompt enrichment in properly segregating variants.
It should be mentioned that our study was focused on Mendelian forms of IT. We explored the possibility of multigenic or incomplete penetrance, but our data are not sufficient to demonstrate a significant role for these mechanisms.
In conclusion, our results show how the application of an unbiased genomic approach to IT, inclusive of CNV evaluation, substantially increased the diagnostic rate in patients who remained undiagnosed after a thorough phenotype-driven investigation. The combined execution of both ES and accurate clinical-laboratory characterization in all patients with IT is expected to be the initial diagnostic approach with the highest probability of success. However, systematic application of this combined approach in all patients would be expensive and time-consuming, also in view of the increasing number of disorders being discovered as associated with IT, therefore necessitating an increasingly complex diagnostic workup for phenotypic characterization. Moreover, the study of IT patients needs specialized skills that often are not available locally: given that phenotypic characterization requires fresh blood samples, this usually means that patients have to travel long distances to reach the nearest reference center for the study of these rare diseases. Therefore, we consider it reasonable to propose that ES, which is becoming more and more economically convenient and can be performed on shipped samples, represents the initial investigation. The diagnosis indicated by ES should be confirmed though the study of the patient's clinical and laboratory phenotype and family history, in order to provide a correct interpretation of genetic variants. If this approach does not culminate in a diagnosis, then a complete phenotypic characterization needs to be performed at a center with specific expertise in the diagnosis of IT, especially considering the disorders associated with genes not completely covered by ES. We also suggest that segregation of candidate variants is evaluated on all available family members to allow correct classification of variants.
Finally, our study disclosed that no novel genes make major contributions to IT, in terms of prevalence, thereby suggesting the need for larger, collaborative studies to identify the genes associated with the almost 50% cases with unknown molecular causes.
Footnotes
- Received March 4, 2022
- Accepted August 29, 2022
Correspondence
Disclosures
No conflicts of interest to disclose.
Contributions
CM, AP, AS, CLB, PN, TP, and MS conceived the study; FP and TP curated the data; CM, EN, and TP were responsible for the formal analysis; AP, AS, CLB, FM, PN and MS acquired funding; CM, AP, FM, FP, RB, EN, MF, SB, TG, VB, PM, PN, TP, and MS performed the investigations; EN and TP were responsible for the methodology; FP and TP were responsible for the software; AP, TP, and MS supervised the study; CM, AP, TP and MS wrote the original draft of the manuscript; and all the authors reviewed and edited the subsequent versions.
Data-sharing statement
Original sequencing data cannot be shared for reasons of privacy.
Funding
This work was supported by grants GGP13082 from Telethon Foundation (to MS, PN, and AS), by grant IG 2018-21974 from the Italian Association of Cancer Research (to AS), from the IRCCS Policlinico San Matteo Foundation (to AP) and from the Ministry of Health to IRCCS Burlo Garofolo (RC 2/18) and to FM (GR-2018-12367235).
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