Evaluation of Hi-C sequencing for the detection of gene fusions in hematologic and solid pediatric cancer samples

HiC sequencing is a DNA-based next-generation sequencing method that preserves the 3D conformation of the genome and has shown promise in detecting genomic rearrangements in translational research studies. To evaluate HiC as a potential clinical diagnostic platform, analytical concordance with routine laboratory testing was assessed using primary pediatric leukemia and sarcoma specimens previously positive for clinically significant genomic rearrangements. Archived specimen types tested included viable and nonviable frozen leukemic cells, as well as formalin-fixed paraffin-embedded (FFPE) tumor tissues. Initially, pediatric acute myeloid leukemia (AML) and alveolar rhabdomyosarcoma (A-RMS) specimens with known genomic rearrangements were subjected to HiC analysis to assess analytical concordance. Subsequently, a discovery cohort consisting of AML and acute lymphoblastic leukemia (ALL) cases with no known genomic rearrangements based on prior clinical diagnostic testing were evaluated to determine whether HiC could detect rearrangements. Using a standard sequencing depth of 50 million raw read-pairs per sample, or approximately 5X raw genomic coverage, 100% concordance was observed between HiC and previous clinical cytogenetic and molecular testing. In the discovery cohort, a clinically relevant gene fusion was detected in 45% of leukemia cases (5/11). This study demonstrates the value of HiC sequencing to medical diagnostic testing as it identified several clinically significant rearrangements, including those that might have been missed by current clinical testing workflows.

Key points

HiC sequencing is a DNA-based next-generation sequencing method that preserves the 3D conformation of the genome, facilitating detection of genomic rearrangements.HiC was 100% concordant with clinical diagnostic testing workflows for detecting clinically significant genomic rearrangements in pediatric leukemia and rhabdomyosarcoma specimens.HiC detected clinically significant genomic rearrangements not previously detected by prior clinical cytogenetic and molecular testing.HiC performed well with archived non-viable and viable frozen leukemic cell samples, as well as archived formalin-fixed paraffin-embedded tumor tissue specimens.

Severus: accurate detection and characterization of somatic structural variation in tumor genomes using long reads

Most current studies rely on short-read sequencing to detect somatic structural variation (SV) in cancer genomes. Long-read sequencing offers the advantage of better mappability and long-range phasing, which results in substantial improvements in germline SV detection. However, current long-read SV detection methods do not generalize well to the analysis of somatic SVs in tumor genomes with complex rearrangements, heterogeneity, and aneuploidy. Here, we present Severus: a method for the accurate detection of different types of somatic SVs using a phased breakpoint graph approach. To benchmark various short- and long-read SV detection methods, we sequenced five tumor/normal cell line pairs with Illumina, Nanopore, and PacBio sequencing platforms; on this benchmark Severus showed the highest F1 scores (harmonic mean of the precision and recall) as compared to long-read and short-read methods. We then applied Severus to three clinical cases of pediatric cancer, demonstrating concordance with known genetic findings as well as revealing clinically relevant cryptic rearrangements missed by standard genomic panels.

Abstract 243: Long-read sequencing of pediatric cancer genomes identifies multiple clinically relevant variants

Genetic characterization of pediatric cancer samples clinically for diagnostic, prognostic, or therapeutic information currently relies on an assortment of methods that complement and partially overlap one another, such as fluorescence in situ hybridization (FISH), karyotyping, microarray, and sequencing. This need for multiple tests results in longer analysis time, increased total costs, and higher consumption of sometimes limited tumor material. Long-read sequencing (lrSeq) using HiFi technology, i.e., circular consensus sequencing of reads 12-16kb in length, is able to provide sequence level changes with highly accurate base quality (>99%), as well as information on copy number variants, structural variants, and methylation status, all fully phased. Here, we assess the ability of lrSeq to detect clinically relevant genetic alterations (CRGAs) in pediatric cancer samples. We selected 10 patient cases of solid and liquid tumors with known CRGAs from prior clinical testing. These included 3 cases of T-cell acute lymphoblastic leukemia (T-ALL): one with t(9;17) involving NOTCH1, one with t(7;7) involving TRB, and one with biallelic CDKN2A deletion; 2 high-grade glioma (HGG) cases: one with t(2;9) causing a WDCP-NTRK2 fusion, and one with a TP53 mutation; 2 cases of acute myeloid leukemia (AML): one with biallelic mutations in CEPBA and one with a KMT2A-rearrangement (KMT2A-r; t(v;11q23.3)); 1 case of B-cell ALL with KMT2A-r, t(v;11q23.3); 1 neuroblastoma (NBL) case with regional amplifications of chromosome 12 including MDM2; and 1 case of anaplastic large cell lymphoma (ALCL) with an NPM1-ALK fusion (t(2;5)). DNA from these samples was sequenced on the PacBio Sequel II System to a target depth of 25x. HiFi reads were processed using the PacBio Human WGS Workflow. Methylation prediction was made from Primrose and 5mC modification probability of CpG sites were computed by pb-CpG-tools. We then assessed phased CpG methylation in known imprinted genes.We found that lrSeq detected translocations in 6 out of 6 cases, providing precise break ends and often clarifying unclear cytogenetic findings (such as partner genes). HiFi sequencing also detected 3 of 3 sequence alterations in CEBPA and TP53; biallelic deletion of CDKN2A; and known regions with loss of heterozygosity (LOH) in 2 out of 2 cases. However, it had difficulty detecting all amplified regions of chromosome 12 in the case of NBL, such as the one containing MDM2. Finally, we were able to detect methylation differences in a phased manner by parental haplotype in known imprinting regions across the genome. The difference in 5mC modification probability between the two alleles of the known imprinted genes was 81.5. Our results demonstrate that lrSeq can detect multiple CRGAs across several different types of genetic variants and pediatric cancers, bringing us closer to the promise of an all-in-one genetic test for cancer characterization.

Citation Format: Byunggil Yoo, Warren Cheung, Irina Pushel, Lisa Lansdon, Chengpeng Bi, Erin Guest, Tomi Pastinen, Midhat Farooqi. Long-read sequencing of pediatric cancer genomes identifies multiple clinically relevant variants [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 243.

Abstract 2498: Prognostically significant molecular pathways in infants diagnosed with acute lymphoblastic leukemia with KMT2A gene rearrangement

Two-thirds of infants diagnosed with acute lymphoblastic leukemia (ALL) with KMT2A gene rearrangement (KMT2A-r) relapse; however, the biological mechanisms underlying this relapse are unknown. Relapsed infant ALL carries a particularly poor prognosis and is often resistant to further attempts at re-induction. Here, we use single-cell RNA sequencing (scRNAseq) data on samples collected at diagnosis from KMT2A-r infant ALL patients to identify genes differentially expressed between cases known to later relapse versus those known to stay in remission. We subsequently describe potential molecular pathways that may explain the predisposition for the majority of these patients to relapse.

We performed 10x Genomics Chromium single-cell sequencing (Multiome v1 chemistry) to obtain gene expression data on blood or bone marrow samples collected at diagnosis from a total of 25 infants with KMT2A-r ALL; 19 of these cases later went on to relapse (the Rel group) while 6 did not (non-Rel). Differential expression analysis (DEA) was performed using the Seurat package (v4.0.2) in R 4.0.3, selecting positive (upregulated) genes only with a log fold change cutoff of 0.25. QIAGEN Ingenuity Pathway Analysis (IPA) software (v1.20.04) was then used to generate a list of molecular pathways described by these differentially upregulated genes (p<.05), one for each group: Rel as compared to non-Rel and vice versa. We then compared the two lists to identify potentially biologically significant markers with possible prognostic value.

We sequenced an average of 1191 cells total per patient over six captures. Following DEA, we found a total of 1168 genes that were enriched in the Rel group relative to the non-Rel group. Conversely, a total of 1240 genes were enriched in the non-Rel group relative to the Rel group. These genes were cross referenced to the KEGG database’s “Pathways in Cancer” list (hsa05200). The top 3 genes in the Rel group were ZBTB16, IL6ST, BCL2L11. The top 3 genes in the non-Rel group were MSH6, LEF1, and CDK6. Following IPA analysis, a total of 160 canonical pathways were described in the Rel group, and a total of 70 canonical pathways were described in the non-Rel group. Three intracellular signal transduction pathways present in the KEGG list above that were disproportionately present in the Rel group at diagnosis with statistical significance and potential prognostic value were PI3K, AKT, and mTOR signaling.

Since increased activation of the PI3K/AKT/mTOR pathway is specifically associated with chemoresistance in ALL, our findings suggest that this pathway could potentially be used as an indicator of potential relapse in infant ALL patients. Future studies, currently in progress, will compare the above data to scRNAseq data from infant KMT2A-r ALL samples collected at relapse to further investigate signaling pathway activation and clonal evolution in infant ALL.

Citation Format: Sidharth Ramesh, Irina Pushel, Byunggil Yoo, Midhat S. Farooqi, Tomi Pastinen, Patrick Brown, Erin Guest. Prognostically significant molecular pathways in infants diagnosed with acute lymphoblastic leukemia with KMT2A gene rearrangement [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2498.

Analysis of lamprey meis genes reveals that conserved inputs from Hox, Meis and Pbx proteins control their expression in the hindbrain and neural tube

Meis genes are known to play important roles in the hindbrain and neural crest cells of jawed vertebrates. To explore the roles of Meis genes in head development during evolution of vertebrates, we have identified four meis genes in the sea lamprey genome and characterized their patterns of expression and regulation, with a focus on the hindbrain and pharynx. Each of the lamprey meis genes displays temporally and spatially dynamic patterns of expression, some of which are coupled to rhombomeric domains in the developing hindbrain and select pharyngeal arches. Studies of Meis loci in mouse and zebrafish have identified enhancers that are bound by Hox and TALE (Meis and Pbx) proteins, implicating these factors in the direct regulation of Meis expression. We examined the lamprey meis loci and identified a series of cis-elements conserved between lamprey and jawed vertebrate meis genes. In transgenic reporter assays we demonstrated that these elements act as neural enhancers in lamprey embryos, directing reporter expression in appropriate domains when compared to expression of their associated endogenous meis gene. Sequence alignments reveal that these conserved elements are in similar relative positions of the meis loci and contain a series of consensus binding motifs for Hox and TALE proteins. This suggests that ancient Hox and TALE-responsive enhancers regulated expression of ancestral vertebrate meis genes in segmental domains in the hindbrain and have been retained in the meis loci during vertebrate evolution. The presence of conserved Meis, Pbx and Hox binding sites in these lamprey enhancers links Hox and TALE factors to regulation of lamprey meis genes in the developing hindbrain, indicating a deep ancestry for these regulatory interactions prior to the divergence of jawed and jawless vertebrates.

Predicting neuroblastoma using developmental signals and a logic-based model

Genomic information from human patient samples of pediatric neuroblastoma cancers and known outcomes have led to specific gene lists put forward as high risk for disease progression. However, the reliance on gene expression correlations rather than mechanistic insight has shown limited potential and suggests a critical need for molecular network models that better predict neuroblastoma progression. In this study, we construct and simulate a molecular network of developmental genes and downstream signals in a 6-gene input logic model that predicts a favorable/unfavorable outcome based on the outcome of the four cell states including cell differentiation, proliferation, apoptosis, and angiogenesis. We simulate the mis-expression of the tyrosine receptor kinases, trkA and trkB, two prognostic indicators of neuroblastoma, and find differences in the number and probability distribution of steady state outcomes. We validate the mechanistic model assumptions using RNAseq of the SHSY5Y human neuroblastoma cell line to define the input states and confirm the predicted outcome with antibody staining. Lastly, we apply input gene signatures from 77 published human patient samples and show that our model makes more accurate disease outcome predictions for early stage disease than any current neuroblastoma gene list. These findings highlight the predictive strength of a logic-based model based on developmental genes and offer a better understanding of the molecular network interactions during neuroblastoma disease progression.

HOXA1 and TALE proteins display cross-regulatory interactions and form a combinatorial binding code on HOXA1 targets

Hoxa1 has diverse functional roles in differentiation and development. We identify and characterize properties of regions bound by HOXA1 on a genome-wide basis in differentiating mouse ES cells. HOXA1-bound regions are enriched for clusters of consensus binding motifs for HOX, PBX, and MEIS, and many display co-occupancy of PBX and MEIS. PBX and MEIS are members of the TALE family and genome-wide analysis of multiple TALE members (PBX, MEIS, TGIF, PREP1, and PREP2) shows that nearly all HOXA1 targets display occupancy of one or more TALE members. The combinatorial binding patterns of TALE proteins define distinct classes of HOXA1 targets, which may create functional diversity. Transgenic reporter assays in zebrafish confirm enhancer activities for many HOXA1-bound regions and the importance of HOX-PBX and TGIF motifs for their regulation. Proteomic analyses show that HOXA1 physically interacts on chromatin with PBX, MEIS, and PREP family members, but not with TGIF, suggesting that TGIF may have an independent input into HOXA1-bound regions. Therefore, TALE proteins appear to represent a wide repertoire of HOX cofactors, which may coregulate enhancers through distinct mechanisms. We also discover extensive auto- and cross-regulatory interactions among the Hoxa1 and TALE genes, indicating that the specificity of HOXA1 during development may be regulated though a complex cross-regulatory network of HOXA1 and TALE proteins. This study provides new insight into a regulatory network involving combinatorial interactions between HOXA1 and TALE proteins.

Quantitative perturbation-based analysis of gene expression predicts enhancer activity in early Drosophila embryo

Enhancers constitute one of the major components of regulatory machinery of metazoans. Although several genome-wide studies have focused on finding and locating enhancers in the genomes, the fundamental principles governing their internal architecture and cis-regulatory grammar remain elusive. Here, we describe an extensive, quantitative perturbation analysis targeting the dorsal-ventral patterning gene regulatory network (GRN) controlled by Drosophila NF-κB homolog Dorsal. To understand transcription factor interactions on enhancers, we employed an ensemble of mathematical models, testing effects of cooperativity, repression, and factor potency. Models trained on the dataset correctly predict activity of evolutionarily divergent regulatory regions, providing insights into spatial relationships between repressor and activator binding sites. Importantly, the collective predictions of sets of models were effective at novel enhancer identification and characterization. Our study demonstrates how experimental dataset and modeling can be effectively combined to provide quantitative insights into cis-regulatory information on a genome-wide scale.

DOI:http://dx.doi.org/10.7554/eLife.08445.001

DNA contains regions known as genes, which may be “transcribed” to produce the RNA molecules that act as templates for building proteins and regulate cell activity. Proteins called transcription factors can bind to specific sequences of DNA to influence whether nearby genes are transcribed. For example, so-called enhancer regions of DNA contain several binding sites for transcription factors, and this binding activates gene transcription. Little is known about how the transcription factor binding sites are organized in enhancer regions, which makes it difficult to use DNA sequence information alone to predict the regulation of genes.

A transcription factor called Dorsal controls the activity of a network of genes that plays a crucial role in the development of fruit fly embryos. Dorsal binds to the enhancer region of a gene called rhomboid, which has been well studied and is known to be a fairly typical example of an enhancer region.

To understand the regulatory information encoded in the DNA sequences of enhancers, Sayal, Dresch et al. have now used a technique called perturbation analysis to investigate the interactions that are likely to occur between Dorsal and other transcription factors as they bind to the rhomboid enhancer. This technique involves systematically mutating the enhancer to remove different combinations of transcription factor binding sites and quantitatively investigating the effect this has on gene activity. A large set of mathematical models were then trained using this data and shown to correctly predict the activity of a range of other gene regulatory regions. The collective predictions of the models identified new enhancer regions and revealed details about how different types of transcription factor binding sites are arranged within enhancers.

As we enter an era where the DNA sequences of entire human populations are increasingly accessible, we would like to know the functional significance of changes in gene regulatory regions. Sayal, Dresch et al. show that the regulatory properties of specific control proteins are accessible by employing quantitative experiments and mathematical models. Similar studies will be required to learn how mutations found across the genome may alter gene expression, leading to better diagnosis and treatment of disease.

DOI:http://dx.doi.org/10.7554/eLife.08445.002

Integrated stability and activity control of the Drosophila Rbf1 retinoblastoma protein

The retinoblastoma (RB) family transcriptional corepressors regulate diverse cellular events including cell cycle, senescence, and differentiation. The activity and stability of these proteins are mediated by post-translational modifications; however, we lack a general understanding of how distinct modifications coordinately impact both of these properties. Previously, we showed that protein turnover and activity are tightly linked through an evolutionarily conserved C-terminal instability element (IE) in the Drosophila RB-related protein Rbf1; surprisingly, mutant proteins with enhanced stability were less, not more active. To better understand how activity and turnover are controlled in this model RB protein, we assessed the impact of Cyclin-Cdk kinase regulation on Rbf1. An evolutionarily conserved N-terminal threonine residue is required for Cyclin-Cdk response and showed a dominant impact on turnover and activity; however, specific residues in the C-terminal IE differentially impacted Rbf1 activity and turnover, indicating an additional level of regulation. Strikingly, specific IE mutations that impaired turnover but not activity induced dramatic developmental phenotypes in the Drosophila eye. Mutation of the highly conserved Lys-774 residue induced hypermorphic phenotypes that mimicked the loss of phosphorylation control; mutation of the corresponding codon of the human RBL2 gene has been reported in lung tumors. Our data support a model in which closely intermingled residues within the conserved IE govern protein turnover, presumably through interactions with E3 ligases, and protein activity via contacts with E2F transcription partners. Such functional relationships are likely to similarly impact mammalian RB family proteins, with important implications for development and disease.