Your search keyword '"Rivas HG"' showing total 5 results

1. BPDCN MYB fusions regulate cell cycle genes, impair differentiation and induce myeloid-dendritic cell leukemia.

Author

Booth CA, Bouyssou JM, Togami K, Armand O, Rivas HG, Yan K, Rice S, Cheng S, Lachtara EM, Bourquin JP, Kentsis A, Rheinbay E, DeCaprio JA, and Lane AA

Abstract

MYB fusions are recurrently found in select cancers, including blastic plasmacytoid dendritic cell neoplasm (BPDCN), an acute leukemia with poor prognosis. They are markedly enriched in BPDCN compared to other blood cancers, and in some patients are the only obvious somatic mutation detected. This suggests they may alone be sufficient to drive dendritic cell transformation. MYB fusions are hypothesized to alter the normal transcription factor activity of MYB, but mechanistically how they promote leukemogenesis is poorly understood. Using CUT&RUN chromatin profiling, we found that in BPDCN leukemogenesis, MYB switches from being a regulator of dendritic cell lineage genes to aberrantly regulating G2/M cell cycle control genes. MYB fusions found in BPDCN patients increased the magnitude of DNA binding at these locations, and this was linked to BPDCN-associated gene expression changes. Furthermore, expression of MYB fusions in vivo impaired dendritic cell differentiation and induced transformation to generate a mouse model of myeloid-dendritic acute leukemia. Therapeutically, we present evidence that all-trans retinoic acid (ATRA) may cause loss of MYB protein and cell death in BPDCN.

Published

2024

2. Distinct Radiation Responses in Virus-Positive and Virus-Negative Merkel Cell Carcinoma.

Author

Ahmed MM, Rivas HG, Frost TC, and DeCaprio JA

Subjects

Humans, Carcinoma, Merkel Cell pathology, Merkel cell polyomavirus, Tumor Virus Infections pathology, Skin Neoplasms pathology, Polyomavirus Infections pathology

Published

2023

3. Disrupting the DREAM complex enables proliferation of adult human pancreatic β cells.

Author

Wang P, Karakose E, Argmann C, Wang H, Balev M, Brody RI, Rivas HG, Liu X, Wood O, Liu H, Choleva L, Hasson D, Bernstein E, Paulo JA, Scott DK, Lambertini L, DeCaprio JA, and Stewart AF

Subjects

Adult, Cell Proliferation, Humans, Protein Serine-Threonine Kinases genetics, Protein-Tyrosine Kinases metabolism, Diabetes Mellitus, Type 2, Insulin-Secreting Cells metabolism, Insulinoma genetics, Pancreatic Neoplasms

Abstract

Resistance to regeneration of insulin-producing pancreatic β cells is a fundamental challenge for type 1 and type 2 diabetes. Recently, small molecule inhibitors of the kinase DYRK1A have proven effective in inducing adult human β cells to proliferate, but their detailed mechanism of action is incompletely understood. We interrogated our human insulinoma and β cell transcriptomic databases seeking to understand why β cells in insulinomas proliferate, while normal β cells do not. This search reveals the DREAM complex as a central regulator of quiescence in human β cells. The DREAM complex consists of a module of transcriptionally repressive proteins that assemble in response to DYRK1A kinase activity, thereby inducing and maintaining cellular quiescence. In the absence of DYRK1A, DREAM subunits reassemble into the pro-proliferative MMB complex. Here, we demonstrate that small molecule DYRK1A inhibitors induce human β cells to replicate by converting the repressive DREAM complex to its pro-proliferative MMB conformation.

Published

2022

4. MMB-FOXM1-driven premature mitosis is required for CHK1 inhibitor sensitivity.

Author

Branigan TB, Kozono D, Schade AE, Deraska P, Rivas HG, Sambel L, Reavis HD, Shapiro GI, D'Andrea AD, and DeCaprio JA

Subjects

A549 Cells, Carcinoma, Non-Small-Cell Lung enzymology, Carcinoma, Non-Small-Cell Lung genetics, Carcinoma, Non-Small-Cell Lung pathology, Cell Cycle Checkpoints drug effects, Cell Cycle Proteins genetics, Checkpoint Kinase 1 genetics, Checkpoint Kinase 1 metabolism, Forkhead Box Protein M1 genetics, Gene Expression Regulation, Neoplastic, Humans, Lung Neoplasms enzymology, Lung Neoplasms genetics, Lung Neoplasms pathology, Multiprotein Complexes, Signal Transduction, Trans-Activators genetics, Antineoplastic Agents pharmacology, Carcinoma, Non-Small-Cell Lung drug therapy, Cell Cycle Proteins metabolism, Checkpoint Kinase 1 antagonists & inhibitors, Forkhead Box Protein M1 metabolism, Lung Neoplasms drug therapy, Mitosis drug effects, Protein Kinase Inhibitors pharmacology, Pyrazines pharmacology, Pyrazoles pharmacology, Trans-Activators metabolism

Abstract

To identify genes whose loss confers resistance to CHK1 inhibitors, we perform genome-wide CRISPR-Cas9 screens in non-small-cell lung cancer (NSCLC) cell lines treated with the CHK1 inhibitor prexasertib (CHK1i). Five of the top six hits of the screens, MYBL2 (B-MYB), LIN54, FOXM1, cyclin A2 (CCNA2), and CDC25B, are cell-cycle-regulated genes that contribute to entry into mitosis. Knockout of MMB-FOXM1 complex components LIN54 and FOXM1 reduce CHK1i-induced DNA replication stress markers and premature mitosis during Late S phase. Activation of a feedback loop between the MMB-FOXM1 complex and CDK1 is required for CHK1i-induced premature mitosis in Late S phase and subsequent replication catastrophe, indicating that dysregulation of the S to M transition is necessary for CHK1 inhibitor sensitivity. These findings provide mechanistic insights into small molecule inhibitors currently studied in clinical trials and provide rationale for combination therapies., Competing Interests: Declaration of interests D.K. has served as a consultant to Vertex. G.I.S. is a consultant/advisory board member for Lilly, Sierra Oncology, Merck-EMD Serono, Pfizer, Astex, Almac, Roche, Bicycle Therapeutics, Fusion Pharmaceuticals, G1 Therapeutics, Bayer, Ipsen, Cybrexa Therapeutics, Angiex, Daiichi Sankyo, and Seattle Genetics and reports receiving commercial research grants from Lilly, Sierra Oncology, Merck-EMD Serono, and Merck & Co. A.D.D. is a consultant/advisory board member for Lilly Oncology, Merck-EMD Serono, Intellia Therapeutics, Sierra Oncology, Cyteir Therapeutics, Third Rock Ventures, AstraZeneca, Ideaya Inc., and Cedilla Therapeutics Inc.; a stockholder in Ideaya Inc., Cedilla Therapeutics Inc., and Cyteir; and received research support from Lilly Oncology and Merck-EMD Serono. J.A.D. is a consultant to Merck & Co. and EMD Serono and received research support from Constellation Pharmaceuticals., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

5. Shutoff of Host Gene Expression in Influenza A Virus and Herpesviruses: Similar Mechanisms and Common Themes.

Author

Rivas HG, Schmaling SK, and Gaglia MM

Subjects

Animals, Herpesviridae Infections metabolism, Humans, Influenza, Human metabolism, Proteolysis, RNA Splicing, RNA Stability, RNA, Messenger genetics, RNA, Messenger metabolism, Transcription, Genetic, Virus Replication, Gene Expression Regulation, Herpesviridae physiology, Herpesviridae Infections genetics, Herpesviridae Infections virology, Host-Pathogen Interactions genetics, Influenza A virus physiology, Influenza, Human genetics, Influenza, Human virology

Abstract

The ability to shut off host gene expression is a shared feature of many viral infections, and it is thought to promote viral replication by freeing host cell machinery and blocking immune responses. Despite the molecular differences between viruses, an emerging theme in the study of host shutoff is that divergent viruses use similar mechanisms to enact host shutoff. Moreover, even viruses that encode few proteins often have multiple mechanisms to affect host gene expression, and we are only starting to understand how these mechanisms are integrated. In this review we discuss the multiplicity of host shutoff mechanisms used by the orthomyxovirus influenza A virus and members of the alpha- and gamma-herpesvirus subfamilies. We highlight the surprising similarities in their mechanisms of host shutoff and discuss how the different mechanisms they use may play a coordinated role in gene regulation.

Published

2016