Introduction

Diffuse large B-cell lymphoma (DLBCL) is the most common lymphoma in adults, accounting for around 75% of aggressive lymphomas. The current standard treatment for DLBCL is immunochemotherapy, typically R-CHOP (rituximab plus cyclophosphamide, doxorubicin, vincristine and prednisone), with 60% of patients living 10 years or more [1]. Patients who fail R-CHOP treatment respond poorly to currently available alternative therapies, and mortality is highest within the first two years after diagnosis [1]. The ability to risk-stratify patients with a low probability of cure following R-CHOP at diagnosis, and to enter them into clinical trials investigating alternative therapies is a significant unmet clinical need. A number of biomarkers have been investigated, but only MYC translocation and to a lesser extent, cell of origin (COO), are used routinely or in a clinical trial [1].

MYC translocation occurs in ~10% of DLBCL, and is frequently (21–83%) accompanied by an additional BCL2 and/or BCL6 translocation, known as double-hit (DH) or triple-hit (TH) [2,3,4,5,6,7,8,9,10,11,12,13,14,15]. MYC/BCL2-DH DLBCL are generally aggressive and respond poorly to currently available therapies, with the majority of patients dying within two years of diagnosis, although a minority of cases experience a long term survival [15, 16]. The clinical outcomes for MYC/BCL6-DH DLBCL are less clear owing to the small number of cases investigated and their heterogeneous COO [14, 17, 18]. Patients with a single MYC translocation (MYC-SH) show variable clinical courses. A subset of these cases has TP53 mutations and displays a worse survival, similar to that of MYC/BCL2-DH [18, 19]. There remains a need to clarify the prognostic stratification of MYC translocation-bearing DLBCL.

Based on COO classification, DLBCL has been divided into two broad subgroups: activated B-cell like (ABC) and germinal centre B-cell like (GCB) subtypes, with the ABC-DLBCL showing enhanced NF-κB activation and generally a worse prognosis [20, 21]. Although the COO classification provides broad biologically distinct categories, there is an apparent heterogeneity in clinical outcome within each subtype. Further subclassification of these broad molecular subtypes has been investigated by several recent studies based on clustered genetic changes and/or gene expression signatures [22,23,24,25,26]. Among these recent advances, Sha et al. and Ennishi et al. have defined a clinically and biologically distinct high-risk subgroup within GCB-DLBCL using, respectively, a Burkitt lymphoma-like or MYC/BCL2-DH-founded gene expression signature [25,26,27]. This subgroup, termed molecular high-grade (MHG) in the study by Sha et al., is enriched in cases with MYC/BCL2-DH, and more importantly includes other poor prognosis cases without the double-hit, which are not readily identified by other methods [25, 28].

Intriguingly, although MHG-DLBCL is enriched in MYC/BCL2-DH, a proportion of cases with MYC/BCL2-DH do not have the MHG gene expression signature and these cases show no worse survival than that of conventional GCB-DLBCL (non-MHG) [25]. To understand the genetic basis underlying MHG-DLBCL and its aggressive clinical behaviour, we used targeted sequencing to investigate 697 cases of DLBCL, particularly enriched for those with MYC/BCL2-DH(TH) (n = 62).

Methods

Case selection and materials

Of the 697 DLBCL cases included, 400 were from the REMoDL-B trial (28 MYC translocation positive) and 297 (97 MYC translocation positive) from a UK population-based cohort [25, 28]. The vast majority of cases in the population-based cohort were from the Haematological Malignancy Research Network (HMRN) (www.hmrn.org), which tracks all haematological malignancies across 14 hospitals diagnosed by a centralised fully-integrated haematopathology laboratory [29]. Case selection in the present study was biased towards those with a MYC translocation, which, together with BCL2 and BCL6 translocations, was determined at the time of diagnosis (HMRN) or retrospectively collected from pathology records or by performing interphase fluorescent in situ hybridisation (FISH) on TMA (REMoDL-B) [18, 25]. Among the population-based cohort, five cases had a previous history of follicular lymphoma (FL), and a further 28 cases had a histological evidence of concurrent FL. For the REMoDL-B trial, patients with a previous history of low-grade lymphoma were excluded.

Formalin-fixed paraffin-embedded (FFPE) diagnostic tissue biopsy was available in each case and local ethical guidelines were followed for the use of these tissue materials for research with the approval of the ethics committees of the involved institutions (05-Q1604–10, 04-Q1205–125, 10-H0504–79).

DNA extraction and quality assessment

Haematoxylin and eosin stained FFPE tissue slides were reviewed and tumour rich areas (>40%) in consecutive sections were isolated by crude macrodissection in each specimen. DNA was extracted using the QIAamp DNA Micro Kit (QIAGEN, Crawley, UK) and quantified using a Qubit® Fluorometer (Life Technologies, UK). The quality of DNA samples was assessed by PCR of variably sized genomic fragments using a standardised protocol [30].

Targeted sequencing by HaloPlexHS enrichment and Illumina HiSeq sequencing

This was essentially carried out as described previously [31]. Briefly, 100 ng genomic DNA was subjected to targeted enrichment of 70 genes (Table S1), which are recurrently mutated in aggressive B-cell lymphomas using a customised HaloPlexHS probe library (Agilent Technologies). The HaloPlexHS probes incorporate molecular barcodes, hence allowing removal of PCR errors during data analysis. Library preparation was performed according to the manufacturer’s instructions for FFPE tissue samples. The pooled libraries were sequenced on an Illumina HiSeq4000 (2 × 150 bp end sequencing protocol) or HiSeq2500 (Rapid Run Mode 2 × 150 bp end sequencing protocol). As stipulated by our previous study, DNA samples amenable for PCR of ≥400 bp genomic fragments were investigated in a single replicate, while those amenable for PCR of 300 bp were analysed in duplicates, with reproducible variants being considered as a true change [31].

Variant calling and annotation

Sequence data analysis and variants calling were performed using a previously validated in-house protocol [31]. Briefly, SNV were called using UnifiedGenotyper with no downsampling [32]. As this was unable to call SNVs at <8% AAF reliably, MuTect2 was additionally employed for detection of hotspot mutations at low AAF values. Indel detection was separately carried out on the recalibrated bam files using Pindel v0.2.5 [33], which allowed detection of indels as low as 2% AAF. Variant calling files were concatenated to produce one library vcf each for the SNV and Indel pipelines, and then filtered using vcftools v0.1.15 and bedtools v2.25 for read depth, quality score and known PCR/sequence artefacts. Further filtering was carried out to remove variants in intronic regions outside essential splicing sites, SNPs with a minor allele frequency ≥0.1% (dbSNP database, 1000 Genomes Project, the ExAC exome sequencing database) and synonymous changes. In addition, missense variants predicted to be benign by at least seven out of nine functional prediction tools (SIFT, Polyphen2 HDIV, Polyphen2 HVAR, LRT, MutationTaster, MutationAssessor, FATHMM, SVM score and LR score) were excluded. The resulting variants were further scrutinised by reviewing the bam file to eliminate potential PCR and sequence artefacts. Only variants above the cut-off value (20 alternative allele depth for DNA samples amenable for PCR of ≥400 bp, 15 alternative allele depth in both replicates for DNA samples amenable for PCR of 300 bp) were considered to be a true change [31]. Finally, extensive search of COSMIC database and published literature was carried out to retain those known and confirmed to be somatic variants. The final mutation list can be found in Table S2.

Molecular subtyping by gene expression profiling

Whole-genome gene expression profiling was performed on mRNA extracted from FFPE diagnostic tissue specimens using the Illumina whole-genome DASL array [34]. Data analyses and COO classification were carried out using the “DLBCL automatic classifier” (DAC) [35]. The MHG group was identified based on a Burkitt lymphoma-like signature as defined in previous studies [25, 36].

Interphase fluorescence in situ hybridisation (FISH)

Chromosome translocation status was available from routine haematopathological diagnosis or previous studies for MYC, BCL2 and BCL6 in 550, 233 and 218 cases, respectively [18, 25]. In the REMoDL-B and HMRN cohort, MYC translocation was screened with Dako MYC break-apart probe, and those showing no evidence of MYC translocation but with MHG phenotype were further investigated with Abbott MYC break-apart and MYC/IGH dual fusion probe. In the remaining cases from other UK hospitals, MYC translocation was investigated with Abbott MYC break-apart probe.

Interphase FISH was performed for BCL2 and BCL6 translocation in 433 and 366 cases in the present study. In cases with MYC translocation, additional FISH was performed with MYC/IGH (Abbott) (if not yet done), then MYC/IGK and MYC/IGL (Cytocell) dual fusion probes in those without any evidence of MYC and IGH fusion. All FISH was carried out on tissue microarray or whole tissue section as described previously [18, 25].

MYC immunohistochemistry

Data on MYC protein expression by immunohistochemistry on tissue microarrays (TMA) slides were available from our previous study [25]. The immunostained slides were scanned and MYC protein expression was quantified and presented as percentage of positive nuclear staining in lymphoma cells using IHC Profiler Image-J software according to the instructions for nuclear protein targets (https://imagej.net/) [37].

Statistical analysis

The probability of MYC hotspot mutations occurring by chance was assessed by Poisson regression. Associations among chromosomal rearrangements, mutations and clinical variables were analysed using Fisher’s exact test. Survival analysis was carried out using Cox proportional hazards and likelihood ratio tests in R (https://cran.r-project.org). All quoted P values are two-sided.

Results

Among the 697 cases investigated by targeted sequencing, 553 were investigated for chromosomal translocations by interphase FISH; and MYC, BCL2 and BCL6 translocations were found in 125, 136 and 97 cases, respectively, with MYC/BCL2/BCL6-TH in 11, MYC/BCL2-DH in 51 (BCL6 translocation data unknown in 8) and MYC/BCL6-DH in 22 (Figs. 1 and 2).

Fig. 1: Summary of cases of DLBCL included in the study.
figure 1

A total of 697 cases were studied, including 400 from the REMoDL-B trial and 297 cases from population-based cohort, mainly from the Haematological Malignancy Research Network (HMRN). Laboratory data on chromosome translocations and molecular subtypes by gene expression profiling are indicated.

Fig. 2: DLBCL with BCL2 translocation harbour the cardinal mutation signature of follicular lymphoma.
figure 2

a Heatmap illustration of mutation distribution according to chromosome translocation status; Where data available, evidence of previous or concurrent follicular lymphoma is indicated. b DLBCL with BCL2 translocation, particularly those with MYC/BCL2-DH, harbour the cardinal mutation signature of FL, and also the mutation profile associated with its high-grade transformation [38,39,40,41]. Representative mutation data in FL and transformed FL are from the study by Kridel et al. [41], with EZH2 mutation considered as the core changes associated with FL [38,39,40,41]. c Comparison of BCL2 mutation profile between BCL2 translocation positive DLBCL in the present study and FL in the study by Huet et al. [42]. d DLBCL with BCL2 translocation often have a previous or concurrent follicular lymphoma. MYC/BCL2-DH MYC/BCL2 double-hit, TH MYC/BCL2/BCL6 triple-hit, SH single-hit, tr +ve/−ve translocation positive/negative, FL follicular lymphoma.

The mutation profile of DLBCL with MYC/BCL2-DH or BCL2-SH suggests their derivation from follicular lymphoma

In general, DLBCL with MYC/BCL2/BCL6-TH and MYC/BCL2-DH had a similar mutation profile, and were characterised by a higher mutation load and more frequent mutations in BCL2, KMT2D, CREBBP, EZH2 and TNFRSF14 than those with isolated MYC translocation (Figs. 2a,  S1 and S2). Interestingly, these mutations are the cardinal features of FL [38,39,40,41,42], and were similarly seen in DLBCL with BCL2-SH (Fig. 2b). The BCL2 mutation profile was almost identical between BCL2 translocation positive DLBCL and FL (Fig. 2c) [42]. These findings suggest that DLBCL with a BCL2 translocation may be derived from a FL or its precursor lesion. In support of this suggestion, DLBCL with MYC/BCL2-DH(TH) and those with BCL2-SH also harboured an additional mutation profile (MYC, GNA13, TP53, P2RY8, PIM1, CCND3, B2M, EBF1 and S1PR2), which was associated with high-grade transformation of FL as shown by several previous studies (Fig. 2b) [38,39,40,41]. Furthermore, both groups (28 and 50%, respectively) frequently presented with either a previous or concurrent FL (Fig. 2d). Intriguingly, DLBCL with MYC-BCL2-DH(TH) were more often associated with a previous, but not concurrent FL than those with BCL2-SH. Nonetheless, 65% of BCL2 translocation positive cases lacked documented evidence of FL at diagnosis (Fig. 2d). With the exception of MYC mutations, there was no significant difference in the mutation profile between BCL2 translocation positive cases with and without FL (Fig. S3). MYC mutation was more frequent in BCL2 translocation positive cases without FL, and this was primarily due to a high frequency of MYC translocation in this group.

As expected, DLBCLs with MYC/BCL2-DH(TH) were either MHG (56%) or GCB (38%), the remaining cases being unclassifiable (6%) (Fig. 3). Similarly, the majority of DLBCL with BCL2-SH were GCB (74%), with the remaining cases distributed among MHG (14%), ABC (4%) and unclassified (8%). It is worth noting that the three cases of ABC-DLBCL with BCL2-SH lacked both EZH2 and GNA13 mutations that were nearly exclusively seen in GCB (MHG)-DLBCL.

Fig. 3
figure 3

Molecular subtype of DLBCL according to translocation status. MHG molecular high-grade, GCB germinal centre B-cell like, ABC activated B-cell like, UNC unclassified.

MHG-DLBCL with MYC translocation are enriched with MYC mutations that enhance its stability and transforming capacity

Our previous study showed that among patients with a MYC translocation, MHG-DLBCL had a significantly worse survival than GCB-DLBCL (non-MHG) [25]. To understand the genetic basis underlying MHG-DLBCL and its aggressive clinical behaviour, we compared the mutation profile among MHG, GCB and ABC subtype, and also between MHG and GCB within MYC/BCL2 double-hit groups (Fig. 4). This revealed a significantly higher frequency of MYC mutations in the MHG group (Fig. 4b).

Fig. 4: Mutation profile of MHG in comparison with the other molecular subtypes.
figure 4

a Comparison of mutation profile among MHG, GCB and ABC subtypes. The panel includes only the genes (n = 57) that had a mutation frequency ≥5% in at least one molecular subtype to make the figure legible. b Mutation comparison between MHG and GCB within the MYC/BCL2-DH(TH) group. Only genes showing a significant or apparent difference are included in the figure panel, with BCL2 mutation included as a reference. Fisherʼs exact test was used to analyse the difference of mutation frequency between various groups with statistical significance indicated.

MYC is a known target of somatic hypermutation machinery, and as expected many of the MYC mutations were in the RCY-motif (R = A/G, Y = C/T), with their extent attenuating when further downstream from the promoter (Fig. 5a). In comparison with synonymous mutations, there was a significant enrichment of non-synonymous changes in codons 57, 58 and 59 (Fig. 5a). In addition, an in-frame deletion of codons 56–60 was seen in one case. These mutations are likely to be functional, pathogenic and selected during lymphoma development as they affect the phosphorylation site (T58) and its neighbouring amino acids, which are important for MYC protein degradation [43]. Several lymphoma derived MYC mutants, including P57S and T58A, have been previously shown to dramatically increase the half-life of MYC protein, and also confer increased transforming capacity [44, 45].

Fig. 5: MYC pathogenic mutations and their relationship to molecular subtype and genetic changes in DLBCL.
figure 5

a Distribution of MYC variants with hotspot mutations clustered at the phosphorylation site (T58) and its neighbouring amino acids that are important for MYC degradation. *One case shows an in-frame deletion of codons 56–60 and all other mutations are missense changes. The codons 57, 58 and 59 hotspot mutations and the in-frame deletion are likely pathogenic and selected during lymphoma development. MYC variants are annotated according to transcript ENST00000377970.6 in keeping with the literature. b MYC hotspot mutations in codons 57, 58 and 59 are seen in a subset of cases with MYC translocation, more frequent in those with MYC/BCL2-DH, but are significantly enriched in MHG-DLBCL. c MYC hotspot mutations are more commonly seen in MYC/BCL2-DH DLBCL with IG gene as the MYC translocation partner, with a considerable overlap with MHG phenotype. d DLBCL with MYC mutation in codons 57–59 show a significantly higher MYC protein expression than those with MYC translocation, but lacking these pathogenic mutations. The MYC protein expression was investigated by immunohistochemistry, quantified using IHC Profiler Image-J software and presented as percentage of positive nuclear staining in lymphoma cells. Unpaired t-test was used to compare the two groups. MHG molecular high-grade, GCB germinal centre B-cell like, ABC activated B-cell like UNC, unclassified.

These MYC hotspot mutations were seen in a subset of DLBCL with MYC translocation, more frequently in those with MYC/BCL2-DH, and the majority (74%) were MHG (Fig. 5b).  In contrast, cases with MYC non-synonymous mutations in other codons did not show any association with molecular subtype although occurred predominantly in those with MYC/IG translocation (Fig. 5b, c). MYC hotspot mutations were significantly more frequent in cases with MYC/IG (41%) than those with MYC/non-IG translocation (8%), and together had a considerable overlap with MHG phenotype (Fig. 5c). Cases with MYC hotspot mutations had a significantly higher MYC protein expression than those with other MYC mutations (Fig. 5d) as shown by immunohistochemistry and quantitative analysis of the scanned immunostained slides [25]. Finally, MYC pathogenic mutations had a potential adverse effect on patient survival (Fig. 6). Even within the MHG group, cases with MYC pathogenic mutations had significantly worse overall survival than those without these mutations in the REMoDL-B trial, and a similar trend was also seen in HMRN’s population-based cohort (Fig. 6a, b). In a separate analysis within cases with MYC/BCL2-DH irrespective of their MHG status, cases with MYC pathogenic mutations also had significantly worse overall survival than those without these mutations in the REMoDL-B trial, albeit not in HMRN’s population-based cohort (Fig. S4). In multivariable analysis adjusting for MHG and MYC/BCL2-DH, MYC pathogenic mutations retained statistical significance in the REMoDL-B group, albeit not in the HMRN cohort.

Fig. 6: Prognostic value of MYC codons 57–59 mutations in DLBCL.
figure 6

a Differential impact on survival between MYC mutations in codons 57–59, and others. b MHG-DLBCL with MYC mutations in codons 57–59 show the worst overall survival in comparison with GCB-DLBCL. c Single variable Cox proportional hazards regression analysis of progression-free survival in GCB-DLBCL. *In multivariable analysis adjusting for MHG and MYC/BCL2-DH, MYC pathogenic mutations in codons 57–59 retain statistical significance in the REMoDL-B cohort, albeit not in the HMRN cohort.

A low allelic frequency (4–5% AAF) of the above MYC pathogenic mutations was seen in three cases, likely representing a subclonal change. Among these three cases, two had molecular subtyping data and one was MHG.

DLBCL with MYC/BCL6-DH or BCL6-SH, or MYC-SH are heterogeneous in their mutation profile and molecular subtype

There was no apparent mutation signature, nor biased molecular subtype associated with BCL6 translocation with exception of BCL10 and NOTCH2 mutations which were significantly enriched in cases with MYC/BCL6-DH or BCL6-SH (Figs. 2a, 3 and S5). Similarly, there was no specific mutation signature in DLBCL with MYC-SH with the exception of high frequent MYC mutations. Cases with MYC-SH varied in their molecular subtype, nonetheless MHG (39%) and GCB (29%) accounted for the majority. Interestingly, 6 of the 11 MHG-DLBCL with MYC-SH had TP53 mutations.

Discussion

Using integrated analyses of chromosome translocation, somatic mutation profiling of a panel of 70 genes that are recurrently mutated in aggressive B-cell lymphoma, and molecular subtype in a large cohort of DLBCL, the present study made two novel observations.

First, we have provided several strands of evidence indicating that DLBCL with MYC/BCL2-DH and those with BCL2-SH are most likely derived from a low-grade FL or its precursor lesion. These include finding: (1) a cardinal mutation signature (BCL2, KMT2D, CREBBP, EZH2 and TNFRSF14) associated with FL development; (2) a mutation profile (MYC, GNA13, TP53, P2RY8, PIM1, CCND3, B2M, EBF1 and S1PR2) associated with FL high-grade transformation; and (3) frequent presence of a previous or concurrent FL in DLBCL with BCL2 translocation.

We acknowledge the limitation of the relatively small gene panel used in the present study, and the above speculation needs to be confirmed by more comprehensive genetic profiling. Nonetheless, the speculation is supported by the finding that transformed FLs also show frequent MYC hotspot mutation [41]. In support of our study, the mutation signature associated with FL was also the characteristic change in high-grade B-cell lymphoma with MYC and BCL2 translocations [46], and in the EZB or C3 genetic subgroup, which are enriched by BCL2 translocation [23, 24].

Intriguingly, DLBCL with MYC/BCL2-DH had strong mutation signatures associated with FL, but less frequent evidence of a concurrent FL than those with BCL2-SH (28% vs 50%). Given the highly proliferative nature of DLBCL with MYC/BCL2-DH, these high-grade lymphoma cells may frequently efface the low-grade FL lesion, potentially leading to its underdetection. In addition, a single lymph node is commonly biopsied for histological diagnosis, increasingly needle core rather than excision biopsies. This would underestimate the true incidence of FL in patients with DLBCL. Alternatively, DLBCL with MYC/BCL2-DH may be derived from a precursor lesion, such as a common mutated precursor cell population. In fact, transformed FLs are more commonly (66–83%) derived from a common mutated precursor cell (CPC) population, in a process of divergent evolution [38,39,40,41]. The tissue compartment containing the CPC population is likely to be in situ follicular neoplasia (ISFN), the precursor lesion of FL, albeit this remains to be confirmed in future investigations. It is pertinent to speculate that BCL2 translocation positive DLBCL could be similarly derived from an ISFN lesion, regardless of any evidence for parallel FL development.

Second, we have identified frequent MYC hotspot mutations that affect the phosphorylation site (T58) and its adjacent amino acids, which are critical for FBXW7 mediated proteasome degradation (Fig. 5a) [43]. Such lymphoma derived MYC mutants (T58A, P57S) have been shown to increase the half-life of MYC protein from 30 to 110 min, and also confer increased transforming capacity, but are defective in promoting apoptosis due to failure to activate BIM [44, 45, 47]. Thus, these hotspot mutations are likely to be pathogenic and selected during lymphoma development.

Although these MYC hotspot mutations were seen in a subset of cases with MYC translocation, they were predominantly in MHG.  This may explain, at least in part, the heterogeneous molecular subtype and clinical outcome of DLBCL with MYC translocation, including those with MYC/BCL2-DH. MYC hotspot mutations (pathogenic changes) were significantly more frequent in cases with MYC/IG than those with MYC/non-IG translocation (41% vs 8%, P = 0.005), potentially explaining in part why these cases showed a worse prognosis than those with non-IG gene as the MYC partner [48, 49]. Cases with MYC pathogenic mutations were significantly associated with higher MYC protein expression as assessed by immunohistochemistry and quantitative imaging analysis.  This could potentially explain in part the variability (20–100%) of MYC protein expression in tumour cells of MYC translocation positive DLBCL [50]. The above findings are also consistent with the observation that the adverse prognosis of the MYC/BCL2-DH group is primarily due to those with IG as MYC translocation partner [48, 51].

It is worth noting that the above MYC hotspot mutations were also seen at a subclonal level, albeit in only a few cases. This finding raises an interesting question about whether tumour cells carrying these mutations are more resistant to therapies, and could thus be enriched in resistant or relapsed disease. If this is the case, the clinical impact of these MYC mutations may be under-estimated in the present study, as the investigation was exclusively based on diagnostic tissue biopsies.

More recently, a second hotspot of tumour-associated MYC mutations was identified in codons 243–249 through meta-analysis of mutation data from Burkitt lymphoma [52]. These mutants (T244A, P245A) phenocopy the aforementioned mutations in their enhanced MYC protein stability, transforming capacity, and also defective BIM activation [52]. We did not observe any hotspot mutations in this region, but this could be due to the relatively small number of cases in the present study, or different mutation spectra between Burkitt and DLBCL. Mutation in codon 138 has also been suggested to enhance MYC protein stability and thus regarded as pathogenic change in DLBCL [53, 54]. Nonetheless, mutation in codon 138 was frequently accompanied by the change in codon 58, and its independent impact remains uncertain due to a very limited number of mutant cases identified [54].

In the 2017 WHO lymphoma classification, MYC/BCL6-DH DLBCL are included in the double-hit category, without any distinction from those with MYC/BCL2/BCL6-TH or MYC/BCL2-DH [55]. We show here that DLBCL with MYC/BCL6-DH are significantly different in their mutation profile and molecular subtype from those with MYC/BCL2/BCL6-TH or MYC/BCL2-DH. This observation is further supported by a recent study albeit based on a smaller cohort [46]. In fact, MYC/BCL6-DH DLBCL are highly heterogeneous in their molecular subtypes, indicating their diverse COO, notwithstanding the high prevalence of NOTCH2 mutations [23, 24]. BCL6 translocation is recurrently seen in both follicular and marginal zone lymphoma [56,57,58,59]. It would be interesting to explore whether MYC/BCL6-DH DLBCL also result from high-grade transformation of a low-grade lesion such as follicular or marginal zone B-cell lymphoma or their precursor lesions, and their heterogeneous molecular subtypes reflect their inherent features from their derived low-grade lesion. These heterogeneities, in addition to the small numbers of cases available for each study, may explain the disparate clinical outcomes reported for MYC/BCL6-DH DLBCL [14, 17, 18]. In light of this, MYC/BCL6-DH DLBCL should not be regarded as a single group, and their biology and clinical management need to be explored in the context of their respective molecular subtype, rather than within the double-hit category.

In summary, DLBCL with MYC/BCL2-DH harbour the characteristic mutation signatures that are associated with FL development and its high-grade transformation, suggesting their derivation from FL or its precursor lesion, probably following acquisition of a MYC translocation. Our study also identifies the novel association of MHG-DLBCL with MYC hotspot mutations that enhance its stability and transforming capacity, and further highlight the pathogenic role of these mutations and their clinical significance, beyond transcriptional deregulation as a result of translocation.