Genetic Subtypes of Smoldering Multiple Myeloma are associated with Distinct Pathogenic Phenotypes and Clinical Outcomes

Smoldering multiple myeloma (SMM) is a precursor condition of multiple myeloma (MM) with significant heterogeneity in disease progression. Existing clinical models of progression risk do not fully capture this heterogeneity. Here we integrated 42 genetic alterations from 214 SMM patients using unsupervised binary matrix factorization (BMF) clustering and identified six distinct genetic subtypes. These subtypes were differentially associated with established MM-related RNA signatures, oncogenic and immune transcriptional profiles, and evolving clinical biomarkers. Three subtypes were associated with increased risk of progression to active MM in both the primary and validation cohorts, indicating they can be used to better predict high and low-risk patients within the currently used clinical risk stratification model.

Caveolar Dysfunction and Lipodystrophies

Congenital generalized lipodystrophy (CGL) is a rare, heterogeneous, autosomal recessive disorder characterized by near total absence of body fat with increased muscularity noticed at birth or in early infancy. Four distinct genetic subtypes of CGL have been reported to date. Types 1 and 2 are caused by biallelic variants in the 1-acylglycerol-3-phosphate-O-acyltransferase 2 (AGPAT2) and Berardinelli-Seip Congenital Lipodystrophy 2 (BSCL2) genes, respectively, and are the most common subtypes (1). Types 3 and 4 are extremely rare and are caused by biallelic variants in the caveolin 1 (CAV1) (2), and Caveolae Associated Protein-1 (CAVIN1; also known as polymerase I and transcript release factor (PTRF)]) genes (3), respectively. Patients with all CGL subtypes are predisposed to metabolic complications of insulin resistance, such as diabetes mellitus, hypertriglyceridemia and hepatic steatosis; however, each subtype presents with some unique clinical features.

Current ideas about molecular genetic subtypes of ovarian cancer: a personalized approach and a new platform for further research

Highly malignant ovarian cancers are a histopathological diagnosis, but can be multiple diseases at the molecular level. Research aimed at identifying molecular genetic subtypes of ovarian cancer is being conducted to find an answer to the question: can different molecular subgroups influence the choice of treatment? One of the achievements of this direction is the recognition of the dualistic theory of the origin of ovarian carcinomas with their division into High-grade and Low-grade subtypes. However, the data of sequencing of the tumor genome suggest the existence of 6 subtypes of carcinoma, including two LG and four HG subtypes. Patients of subtype C1 are characterized by a high stromal response and have the lowest survival, tumors of C2 and C4 subtypes have a higher rate of intratumoral CD3 + cells, lower stroma gene expression and better survival than C1. The mesenchymal subtype C5 is widely represented by mesenchymal cells, characterized by overexpression of N-cadherins and P-cadherins, low expression of differentiation markers and lower survival than C2 and C4. The use of a consensus algorithm to determine the subtype allows the identification of only a minority of ovarian cancers (approximately 25%). In this regard, the practical significance of this classification still requires additional research, and today it is permissible to talk about the existence of only 2-3 reproducible subtypes. It is thought that it makes sense to randomize tumors into groups with altered expression of angiogenic genes and with overexpression of immune response genes, as in the angiogenic group there is a comparison of the advantage in survival (prescribing bevacizumab improves it, and in the immune group even increases bevacizumab). Molecular subtypes with poorer survival rates (proliferative and mesenchymal) also benefit most from bevacizumab treatment. The review focuses on some advances in understanding molecular, cellular, and genetic changes related to ovarian cancers with the results achieved so far in describing molecular subtypes of ovarian cancer. The available information is the basis for planning further research.

Abrogation of a Histone Chaperone Pathway Mitigates Inflammation-Driven AML Progression

Background: Genetic heterogeneity makes clinical interventions challenging for acute myeloid leukemia (AML) patients. Identifying and targeting microenvironment-driven pathways that are active across AML genetic subtypes should allow the development of more broadly effective therapies. Previously, we have shown that AML microenvironment is rich in proinflammatory cytokine interleukin-1β (IL-1β) and significantly promotes the growth of AML progenitors while suppressing healthy progenitors. To elucidate this paradoxical effect, we performed transcriptome (RNA-seq) analysis from IL-1β-stimulated CD34+ AML and normal progenitors and found that ASF1B (anti-silencing function-1B) is one of the most differentially expressed genes. ASF1B is a histone chaperone, which recruits H3-H4 histones onto the replication fork during S-phase. This process is regulated by tousled-like kinase 1 and 2 (TLKs). TLKs and ASF1B are overexpressed in multiple solid tumors and associated with poor prognosis. However, their functional roles in hematopoiesis and inflammation-driven leukemia are unexplored. Here, we reveal a novel molecular mechanism that IL-1β promotes leukemia progression by activating the TLK-ASF1B pathway. Methods and Results: We first confirmed that IL-1β stimulation upregulates ASF1B expression at both mRNA and protein levels in FLT3-ITD, MLL-ENL, and NPM1 positive primary AML samples. ASF1B upregulation is abolished upon treatment with a p38MAPK inhibitor, further suggesting that ASF1B is downstream of IL-1β/p38 signaling. Next, we stably knocked down ASF1B in an AML cell line MOLM-14 using doxycycline-inducible shRNA. ASF1B-depleted AML cells exhibited reduced cell viability, inhibited growth, blocked cell cycle progression, and impaired colony formation ability. We xenografted shASF1B expressing AML cells into NSG mice and induced knockdown in vivo. Flow cytometry analysis of bone marrow cells 3 weeks post-engraftment showed 80 percent reduction in leukemia burden following ASF1B silencing compared to controls. To determine whether upregulation of ASF1B contributes to IL-1β-driven leukemic growth, we overexpressed ASF1B with MLL-ENL oncogene in a murine bone marrow transplantation model. We found that daily IL-1β exposure accelerated leukemia progression compared to vehicle-treated group (median survival = 64 vs. 85 days, p<0.05), and this effect was phenocopied by overexpression of ASF1B (median survival = 62 vs. 85 days, p<0.05). Conversely, heterozygous and complete Asf1b deletion in the MLL-ENL AML model delayed the leukemia progression compared to wildtype mice. Furthermore, Asf1b deletion attenuated IL-1β-mediated AML progression compared to wildtype controls (median survival = 63 vs. 47 days, p <0.01). Immunophenotyping of Asf1b-deficient mice using flow cytometry suggested that ASF1B is dispensable for normal hematopoiesis. Together, these data suggested that targeting of the ASF1B pathway may spare healthy cells. Additionally, we found that TLK2 which regulates ASF1B activation, is also upregulated in AML progenitors compared to healthy cells at the baseline levels and upon IL-1β stimulation. We next knocked down TLKs in human AML cells and observed a similar pattern with growth arrest, higher replication stress and DNA damage response. Finally, we generated Vav-Cre+ Tlk2 mice allowing Tlk2 deletion only in hematopoietic cells and found that Tlk2 deletion prolongs survival of leukemic mice in a dose dependent manner with and without IL-1β stimulation. Conclusions: We demonstrate that increased TLK-ASF1B expression promotes survival of AML cells. We also provide the first in vitro and in vivo evidence that the TLK-ASF1B pathway plays a critical role in potentiating IL-1β-dependent AML growth. Therefore, we establish TLK-ASF1B pathway as a novel route for therapeutic strategy to suppress inflammation-driven growth in various AML genetic subtypes. Disclosures No relevant conflicts of interest to declare.

Genetic pathogenesis, diagnosis, and treatment of short-chain 3-hydroxyacyl-coenzyme A dehydrogenase hyperinsulinism

Congenital hyperinsulinism (CHI), a major cause of persistent and recurrent hypoglycemia in infancy and childhood. Numerous pathogenic genes have been associated with 14 known genetic subtypes of CHI. Adenosine triphosphate-sensitive potassium channel hyperinsulinism (KATP-HI) is the most common and most severe subtype, accounting for 40–50% of CHI cases. Short-chain 3-hydroxyacyl-coenzyme A dehydrogenase hyperinsulinism (SCHAD-HI) is a rare subtype that accounts for less than 1% of all CHI cases that are caused by homozygous mutations in the hydroxyacyl-coenzyme A dehydrogenase (HADH) gene. This review provided a systematic description of the genetic pathogenesis and current progress in the diagnosis and treatment of SCHAD-HI to improve our understanding of this disease.

Genetic Subtypes and Natural Resistance Mutations in HCV Genotype 4 Infected Saudi Arabian Patients

This study aimed to characterize the HCV genetic subtypes variability and the presence of natural occurring resistance-associated substitutions (RASs) in Saudi Arabia patients. A total of 17 GT patients were analyzed. Sequence analysis of NS3, NS5A, and NS5B regions was performed by direct sequencing, and phylogenetic analyses were used to determine genetic subtypes, RAS, and polymorphisms. Nine patients were infected by GT 4a, two with GT 4o and three with GT 4d. Two patients were infected with apparent recombinant virus (4a/4o/4a in NS3/NS5A/NS5B), and one patient was infected with a previously unknown, unclassifiable, virus of GT 4. Natural RASs were found in six patients (35%), including three infected by GT 4a, two by GT 4a/GT 4o/GT 4a, and one patient infected by an unknown, unclassifiable, virus of GT 4. In particular, NS3-RAS V170I was demonstrated in three patients, while NS5A-RASs (L28M, L30R, L28M + M31L) were detected in the remaining three patients. All patients were treated with sofosbuvir plus daclatasvir; three patients were lost to follow-up, whereas 14 patients completed the treatment. A sustained virological response (SVR) was obtained in all but one patient carrying NS3-RAS V170I who later relapsed. GT 4a is the most common subtype in this small cohort of Saudi Arabia patients infected with hepatitis C infection. Natural RASs were observed in about one-third of patients, but only one of them showed a treatment failure.

Genetic Alterations in Childhood Acute Lymphoblastic Leukemia: Interactions with Clinical Features and Treatment Response

Acute lymphoblastic leukemia (ALL) is the most common cancer among children. This aggressive cancer comprises multiple molecular subtypes, each harboring a distinct constellation of somatic, and to a lesser extent, inherited genetic alterations. With recent advances in genomic analyses such as next-generation sequencing techniques, we can now clearly identify >20 different genetic subtypes in ALL. Clinically, identifying these genetic subtypes will better refine risk stratification and determine the optimal intensity of therapy for each patient. Underpinning each genetic subtype are unique clinical and therapeutic characteristics, such as age and presenting white blood cell (WBC) count. More importantly, within each genetic subtype, there is much less variability in treatment response and survival outcomes compared with current risk factors such as National Cancer Institute (NCI) criteria. We review how this new taxonomy of genetic subtypes in childhood ALL interacts with clinical risk factors used widely, i.e., age, presenting WBC, IKZF1del, treatment response, and outcomes.

Genetic Subtypes and Natural Resistance Mutations in HCV Genotype 4 Infected Saudi Arabian Patients

This study aimed to characterize the genetic subtypes of HCV-GT4 and identify the presence of natural occurring resistance-associated substitutions (RASs) in Saudi Arabia patients. A total of 17 GT4 patients was analyzed. Sequence analysis of NS3, NS5A and NS5B regions was performed by direct sequencing. In addition, phylogenetic analysis was used to determine genetic subtypes, RAS and polymorphisms. Nine patients were infected by a GT4a, one with GT4o, 3 with GT4d. The remaining four patients were infected with a recombinant virus (GT4a+GT4o in three patients, GT4c+GT4d in a patient). Natural RASs were found in six patients (35%), including three infected by GT4a, two by GT4a+GT4o and one patient infected by GT4c+GT4d. In particular, NS3-RAS V170I was demonstrated in three patients, while NS5A-RASs (L28M, L30R, L28M+M31L) were detected in the remaining three patients. All patients were treated with sofosbuvir plus daclatasvir; three patients were lost to follow-up whereas 14 patients completed the treatment. A sustained virological response (SVR) was obtained in all but one patient carrying NS3-RAS V170I who later relapsed. GT4a is the most common subtype in this small cohort of Saudi Arabia patients infected with hepatitis C infection. Natural RASs were observed in about a third of patients, but only one of them showed a treatment failure.