To the Editor:
Accumulating evidence suggests shared susceptibility factors between colorectal and hematological malignancies, in line with observations of cross-cancer associations of multiple cancer predisposing genes [1]. Familial colorectal cancer type X (FCCTX) refers to colorectal cancer families that fulfill the diagnostic (Amsterdam) criteria for Lynch syndrome but lack DNA mismatch repair (MMR) defects. The underlying genes are mostly unknown. We recently linked inactivation of RPS20 (ribosomal protein S20) to FCCTX predisposition [2]. The phenotypic spectrum of RPS20 was later expanded to include Diamond Blackfan anemia [3] thus connecting colorectal and hematological carcinogenesis. Observations of inherited variants in DDX41, a DEAD box RNA helicase gene, causing susceptibility to myelodysplastic syndrome and myeloid leukemias, offer additional proof of the important regulatory roles of ribosome biosynthesis and RNA processing in cancer [4]. DDX41 variants are currently known to represent the most common germline alterations in adult myelodysplastic syndromes, accounting for 0.5–4% of all acute myeloid leukemia or myelodysplastic syndrome cases in adults [5].
We conducted exome sequencing (ES) on 28 unexplained FCCTX families to identify their predisposing genes (Supplementary Materials and Methods, Supplementary Table 1). The investigations described in this paper were approved by the Institutional Review Boards of the Helsinki University Hospital, Helsinki, Finland (approval nos. 466-46-2001, 206/13/03/03/2016 and 303/13/03/01/2011). Family F32 with myelodysplastic syndrome/acute leukemia coexisting with colorectal cancer caught our attention (Fig. 1A). All variants fulfilling our selection criteria (high quality, minor allele frequency <0.001, nonsynonymous, and predicted pathogenic with at least 5/6 in silico programs if missense) are listed for the index individual III.1 in Supplementary Table 2. His granddaughter V.1 presented with an unusual form of hematologic disorder at the age of 18 years. Initially, the investigations started due to pancytopenia which was treated with allo-hematopoietic stem cell transplantation (HSCT). The disease relapsed 2 years later with blood counts: hemoglobin 9.5, platelets 50, neutrophils 0.7. At that time, morphological examination of the bone marrow showed dysplasia in megakaryopoiesis and excess of blasts, and was subsequently diagnosed as myelodysplastic syndrome (MDS)/refractory anemia with excess blasts, type 2 (RAEB2) [6]. When variant sharing in the key affected members III.1, IV.3, and V.1 was set as a requirement, the only variant that remained was a heterozygous truncating variant affecting the DEAH-box RNA helicase gene DHX40 (NM_024612.4:c.710_713delTCAG, p.Val237GlufsX7) (Fig. 1A). The variant is predicted to lead to the deletion of the helicase domain and all downstream C-terminal portion of DHX40. Seven of eight cancer-affected members had this variant (the only one without was individual III.3 with adenocarcinoma of unknown origin).
To functionally characterize the DHX40 variant, we evaluated its expressional consequences on RNA and protein level, undertook tumor studies to analyze somatic variants, changes in gene methylation and DHX40 protein expression, and conducted siRNA analyses of cell lines (see Supplementary Materials and Methods). By a primer extension assay, the dosage ratios of mutant to wild-type alleles were reduced up to fivefold (Supplementary Fig 1A), likely reflecting nonsense-mediated RNA decay. In agreement, Western blot analysis with N-terminal DHX40 antibody showed no visible truncated protein (Supplementary Fig. 2A). However, a truncated product of expected size could be clearly visualized by transfecting HEK293 cells with eGFP-tagged DHX40 expression constructs (Supplementary Fig. 2B). To evaluate if Knudson’s two-hit mechanism applied to DHX40, available neoplastic tissues from individuals heterozygous for the DHX40 c.710_713delTCAG variant were examined for somatic variants, loss of the wild-type allele, and promoter methylation of DHX40. There was no unequivocal evidence of “second hits” (Supplementary Fig. 1B, Supplementary Table 3, Supplementary Table 4), supporting the idea that loss of function of the constitutionally mutant allele alone was sufficient for tumorigenesis, without a second hit (haploinsufficiency).
As no suitable RNA samples from the patients were available for investigations of the consequences of DHX40 inactivation on global transcriptomes, we undertook siRNA experiments on cell lines representing normal (CCD841) or cancer tissues (HEK293 and K562) of different cellular origins (Fig. 1B, Supplementary Materials and Methods), followed by RNA-sequencing. We observed 71 differentially expressed transcripts (q-value < 0.01) unique to DHX40-siRNA-treated cells and shared by all three cell lines (Fig. 1B, Supplementary Fig. 3). Genes functioning in RNA metabolism (RNA helicase, RNA binding, or transcription-related function) were enriched, comprising 31% of the unique transcripts. ASGAL (Alternative Splicing Graph ALigner) directly aligns RNA-seq data to a splicing graph, which results in a list of novel splice events in respect to gene annotation. By ASGAL analysis, DHX40-siRNA-treated cells exhibited a 13% increase in novel splice events, compared to GAPDH-siRNA-treated or non-target siRNA-treated cells (Fig. 1B). DHX40-siRNA treatment associated with elevation of all types of splice events, especially exon skipping.
No germline variants suspected pathogenic were detectable in DHX40 or other DEAD/H box genes (from here on, referred to as DDX/DHX genes) in the remaining 27 FCCTX families. However, one family displayed a heterozygous truncating variant in a related RNA helicase gene, TDRD9 (NM_153046.2:c.2261delC, p.Thr754IlefsX11) that co-segregated with colorectal cancer in two siblings. This finding further strengthens the importance of impaired RNA metabolism behind hereditary cancer susceptibility.
Next, we ascertained close to 400 patients with acute leukemia, myelodysplastic syndrome, or myeloma with germline and/or somatic exomic data available from a hospital-based repository and analyzed their samples for possibly pathogenic variants in DDX/DHX genes. Sixty-six skin fibroblast samples out of 367 (18%) revealed a possibly pathogenic germline variant in at least one DDX/DHX gene (Fig. 2A). Most variants were of the missense type (Fig. 2B). According to the FinnGen database (finngen.fi), of single nucleotide variants included in their genome-wide association study and located nearby our most frequently affected genes, DDX58, DDX54, DHX38, and DDX10 showed significant (p < 10−4) association to several hematological malignancies. Additionally, DDX10 showed significant (p < 10−4) association to colon adenocarcinomas, and DDX54 to benign colon tumors. While DHX40 was not affected with any such germline alterations that would fulfill our stringent selection criteria, the common p.M1I pathogenic loss of-function variant of DDX41 [5] was detected twice. One hundred and twenty-two neoplastic bone marrow samples out of 432 (28%) revealed at least one possibly pathogenic somatic DHX/DDX single-nucleotide variant or small indel variant (mostly of the missense type), including DHX40 variants in four (two with AML and two with myeloma) (Fig. 2C, D). The nonsense variant NM_024612.4:c.361G > T, p.E121* was particularly noteworthy being present in two consecutive specimens of CD138+ cells taken with a 15-month interval from a patient with multiple myeloma, and having a high variant allele frequency (37%) in both samples. This variant (together with p.S210* identified in an AML patient) affects the DEAD/H box helicase domain and is predicted to give rise to a severely truncated protein (Fig. 2E).
In summary, we describe a rare truncating germline variant of DHX40 in a multi-generation family with hematological and solid malignancies. Loss-of-function nature of the variant, co-segregation with neoplasia phenotypes, and functional evidence suggest a role in cancer predisposition. Our findings add DHX40 as a new candidate to the growing list of RNA metabolism-related genes that may underlie predisposition to FCCTX [2, 7] and myeloid disorders [4]. Moreover, our findings from a large hospital-based patient series suggest the involvement of the broader DDX/DHX gene family in hematological malignancies.
Our DHX40 findings resemble those earlier described for DDX41 in several respects. First, while DDX41 primarily associates with hematological neoplasia, solid malignancies, especially prostate cancer, colorectal cancer, and melanoma, have been reported in individuals with pathogenic germline variants of DDX41 [8]. Second, our patient V.1 from F32 responded well to combination therapy (clofarabin, plerixafor and lenalidomide) and had no need for additional therapy regimens after a second allo-HSCT following the combination therapy; the patient has remained in remission for over 10 years. Interestingly, sensitivity of DDX41-mutated patients to lenalidomide treatment has been described in the literature [4]. Third, although the frameshift nature of the DHX40 germline variant implied loss of function, no apparent “second hits” were detectable in neoplastic tissues from individuals from F32 (Supplementary Table 3), a situation compatible with dominant-negative mechanism or alternatively, haploinsufficiency. Experience from DDX41 suggests haploinsufficiency: although individuals with pathogenic germline variants often acquire somatic DDX41 variants as second hits, the latter occur at low (0–20%) frequencies in bone marrow cells because biallelic alterations are not compatible with proliferating hematopoietic cells [9, 10]. It is likewise possible that biallelic DHX40 defects are not tolerated. Interestingly, a duodenum adenoma from F32 showed a mosaic loss of DHX40 protein by immunohistochemical analysis (Supplementary Fig. 1C), suggesting that biallelic defects could be present, but in only a small proportion of tumor cells. Fourth, DDX41-deficient blast cells were shown to exhibit aberrant exon skipping and retention [4] resembling our findings from siRNA-mediated knockdown of DHX40 in cell lines (Fig. 1B).
At least 59 established DDX/DHX helicases are known [11]. In our hospital-based hematological series, DDX/DHX genes were fairly frequently affected by missense variants and occasionally (7–9%) by truncating variants (Fig. 2A–D) Although several DDX/DHX genes pinpointed in this series showed significant association to hematological and colorectal neoplasia according to public databases, the true significance of the finding remains to be determined by additional studies.
Apart from ATP-dependent RNA-duplex unwinding, DDX/DHX proteins participate in the regulation of long and short non-coding RNAs, pre-mRNA splicing, ribosome biogenesis, and many other cellular functions [11,12,13,14]. Besides shedding light to the basic biological mechanisms of neoplasia, our results are clinically relevant since DDX/DHX variant status may guide therapy options ([4] and this study); moreover, participation in translational control makes DDX/DHX helicases attractive targets for novel anti-cancer therapies [15]. Our findings encourage additional investigations on DHX40 as well as studies into other DHX/DDX genes as possible predisposing factors for colorectal and hematological neoplasia.
Data availability
Raw RNA-seq data and DTE analysis results from siRNA treated cell lines can be obtained from GSE228991. Our IRB approvals do not allow sharing of raw sequencing data from patients. All variants fulfilling our filtering criteria can be found in the Supplementary Files. Requests to access additional datasets should be directed to the corresponding authors.
References
Huang KL, Mashl RJ, Wu Y, Ritter DI, Wang J, Oh C, et al. Pathogenic germline variants in 10,389 adult cancers. Cell. 2018;173:355–70.e314.
Nieminen TT, O’Donohue M-F, Wu Y, Lohi H, Scherer SW, Paterson AD, et al. Germline mutation of rps20, encoding a ribosomal protein, causes predisposition to hereditary nonpolyposis colorectal carcinoma without dna mismatch repair deficiency. Gastroenterology. 2014;147:595–8.e595.
Bhar S, Zhou F, Reineke LC, Morris DK, Khincha PP, Giri N, et al. Expansion of germline RPS20 mutation phenotype to include Diamond-Blackfan anemia. Hum Mutat. 2020;41:1918–30.
Polprasert C, Schulze I, Sekeres MA, Makishima H, Przychodzen B, Hosono N, et al. Inherited and somatic defects in DDX41 in myeloid neoplasms. Cancer Cell. 2015;27:658–70.
Quesada AE, Routbort MJ, DiNardo CD, Bueso-Ramos CE, Kanagal-Shamanna R, Khoury JD, et al. DDX41 mutations in myeloid neoplasms are associated with male gender, TP53 mutations and high-risk disease. Am J Hematol. 2019;94:757–66.
Hong M, He G. The 2016 revision to the world health organization classification of myelodysplastic syndromes. J Transl Int Med. 2017;5:139–43.
Bellido F, Sowada N, Mur P, Lázaro C, Pons T, Valdés-Mas R, et al. Association between germline mutations in BRF1, a subunit of the RNA polymerase III transcription complex, and hereditary colorectal cancer. Gastroenterology. 2018;154:181–94.e120.
Churpek JE, Smith-Simmer K. DDX41-associated familial myelodysplastic syndrome and acute myeloid leukemia. In: Margaret P Adam, Ghayda M Mirzaa, Roberta A Pagon, Stephanie E Wallace, Lora JH Bean, Karen W Gripp, Anne Amemiya, editors. GeneReviews. University of Washington: Seattle; 2021.
Chlon TM, Stepanchick E, Hershberger CE, Daniels NJ, Hueneman KM, Kuenzi Davis A, et al. Germline DDX41 mutations cause ineffective hematopoiesis and myelodysplasia. Cell Stem Cell. 2021;28:1966–81.e1966.
Makishima H, Saiki R, Nannya Y, Korotev S, Gurnari C, Takeda J, et al. Germ line DDX41 mutations define a unique subtype of myeloid neoplasms. Blood. 2023;141:534–49.
Cai W, Xiong Chen Z, Rane G, Satendra Singh S, Choo Z, Wang C, et al. Wanted DEAD/H or alive: helicases winding up in cancers. J Natl Cancer Inst. 2017;109:djw278.
Rocak S, Linder P. DEAD-box proteins: the driving forces behind RNA metabolism. Nat Rev Mol Cell Biol. 2004;5:232–41.
Liu YC, Cheng SC. Functional roles of DExD/H-box RNA helicases in Pre-mRNA splicing. J Biomed Sci. 2015;22:54.
Russon MP, Westerhouse KM, Tran EJ. Transcription, translation, and DNA repair: new insights from emerging noncanonical substrates of RNA helicases. Biol Chem. 2021;402:637–44.
Heerma van Voss MR, van Diest PJ, Raman V. Targeting RNA helicases in cancer: the translation trap. Biochim Biophys Acta Rev Cancer. 2017;1868:510–20.
Acknowledgements
We thank Saila Saarinen for expert laboratory assistance and Henrikki Almusa and Samuli Eldfors for contributing to VarScan2 analyses. We are grateful to Kirsi Pylvänäinen, Tuula Lehtinen, Beatriz Alcala-Repo, and Maija Röntynen for collecting clinical data.
Funding
This work was supported by grants from Biomedicum Helsinki Foundation (to AO); the Jalmari and Rauha Ahokas Foundation (to TTN); the Maud Kuistila Memorial Foundation (to TTN); the Finnish Medical Foundation (to MKo); the Finska Läkaresällskapet (to AR); Medicinska Understödsföreningen Liv & Hälsa (to AR); the Jane and Aatos Erkko Foundation (to PP); the Academy of Finland (grant number 330606 to PP); Cancer Foundation Finland sr (to AO, MKo, AR, OK, and PP); and Helsinki University Central Hospital Research Funds (to MKo and AR); and the Sigrid Juselius Foundation (to AR, OK, and PP). The Doctoral Program in Biomedicine of Helsinki University offered a paid doctoral student position to AO. Open Access funding provided by University of Helsinki including Helsinki University Central Hospital.
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Conceptualization: AO, TTN, SD, OK, UW-K, KP, and PP. Data curation: JV and MKa. Formal analysis: AO, TTN, SD, AK, JV, and MKa. Funding acquisition: MKo, AR, MM, CH, J-PM, OK, UW-K, KP, and PP. Investigation: AO, TTN, SD, AK, MKa, JV, MKo, CAH, JS, MS, OK, UW-K, AR, AL, KP, and PP. Methodology: AO, TTN, SD, AK, and PL. Project administration: HJ, AR, MM, J-PM, OK, UW-K, KP, and PP. Resources: AR, MM, CAH, HJ, J-PM, AL, OK, UW-K, KP, and PP. Software: AO, JV, and MKa. Supervision: AO, TTN, AR, CAH, OK, UW-K, KP, and PP. Validation: AO, TTN, and SD. Visualization: AO and PP. Writing—original draft: AO, TTN, and PP. Writing—review & editing: AO, TTN, SD, AR, OK, UW-K, KP, PP. All authors approved the final version of the manuscript.
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Olkinuora, A., Nieminen, T.T., Douglas, S. et al. Identification of DHX40 as a candidate susceptibility gene for colorectal and hematological neoplasia. Leukemia 37, 2301–2305 (2023). https://doi.org/10.1038/s41375-023-02021-9
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DOI: https://doi.org/10.1038/s41375-023-02021-9