Abstract
BackgroundChronic lymphocytic leukemia (CLL) is an indolent heme malignancy characterized by the accumulation of CD5+ CD19+ B cells and episodes of relapse. The biological signaling that influence episodes of relapse in CLL are not fully described. Here, we identify gene networks associated with CLL relapse and survival risk.MethodsNetworks were investigated by using a novel weighted gene network co-expression analysis method and examining overrepresentation of upstream regulators and signaling pathways within co-expressed transcriptome modules across clinically annotated transcriptomes from CLL patients (N = 203). Gene Ontology analysis was used to identify biological functions overrepresented in each module. Differential Expression of modules and individual genes was assessed using an ANOVA (Binet Stage A and B relapsed patients) or T-test (SF3B1 mutations). The clinical relevance of biomarker candidates was evaluated using log-rank Kaplan Meier (survival and relapse interval) and ROC tests.ResultsEight distinct modules (M2, M3, M4, M7, M9, M10, M11, M13) were significantly correlated with relapse and differentially expressed between relapsed and non-relapsed Binet Stage A CLL patients. The biological functions of modules positively correlated with relapse were carbohydrate and mRNA metabolism, whereas negatively correlated modules to relapse were protein translation associated. Additionally, M1, M3, M7, and M13 modules negatively correlated with overall survival. CLL biomarkers BTK, BCL2, and TP53 were co-expressed, while unmutated IGHV biomarker ZAP70 and cell survival-associated NOTCH1 were co-expressed in modules positively correlated with relapse and negatively correlated with survival days.ConclusionsThis study provides novel insights into CLL relapse biology and pathways associated with known and novel biomarkers for relapse and overall survival. The modules associated with relapse and overall survival represented both known and novel pathways associated with CLL pathogenesis and can be a resource for the CLL research community. The hub genes of these modules, e.g., ARHGAP27P2, C1S, CASC2, CLEC3B, CRY1, CXCR5, FUT5, MID1IP1, and URAHP, can be studied further as new therapeutic targets or clinical markers to predict CLL patient outcomes.
Highlights
Chronic lymphocytic leukemia (CLL) is an indolent heme malignancy characterized by the accumulation of C D5+ CD19+ B cells and episodes of relapse
The aggregation of B cells in the bone marrow and lymphoid organs interferes with the production of new blood, resulting in anemia, thrombocytopenia and neutropenia as well as impairing immune system integrity negatively impacting the quality of life of CLL patients
Systems biology defines a network of CLL co‐expression modules To assess the systems biology of CLL, the transcriptome comprising 24,658 genes across 201 CLL case samples (Table 1) were examined for co-expression modules of gene transcripts
Summary
Chronic lymphocytic leukemia (CLL) is an indolent heme malignancy characterized by the accumulation of C D5+ CD19+ B cells and episodes of relapse. Chronic lymphocytic leukemia (CLL) is a heme malignancy characterized by the presence of C D5+ CD19+ B cells in the blood, bone marrow, and lymph node organs [1]. The aggregation of B cells in the bone marrow and lymphoid organs interferes with the production of new blood, resulting in anemia, thrombocytopenia and neutropenia as well as impairing immune system integrity negatively impacting the quality of life of CLL patients. To effectively cure CLL and improve the quality of life of CLL patients, we need a better understanding of the cellular and molecular mechanisms that follow CLL initiation and lead to disease progression
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