Your search keyword '"El-Hachem, Nehme"' showing total 5 results

1. Recent Advances in Cancer Drug Discovery Through the Use of Phenotypic Reporter Systems, Connectivity Mapping, and Pooled CRISPR Screening.

Author

Salame, Natasha, Fooks, Katharine, El-Hachem, Nehme, Bikorimana, Jean-Pierre, Mercier, François E., and Rafei, Moutih

Subjects

DRUG discovery, MEDICAL screening, COMPUTATIONAL biology, HIGH throughput screening (Drug development), ANTINEOPLASTIC agents, CRISPRS

Abstract

Multi-omic approaches offer an unprecedented overview of the development, plasticity, and resistance of cancer. However, the translation from anti-cancer compounds identified in vitro to clinically active drugs have a notoriously low success rate. Here, we review how technical advances in cell culture, robotics, computational biology, and development of reporter systems have transformed drug discovery, enabling screening approaches tailored to clinically relevant functional readouts (e.g., bypassing drug resistance). Illustrating with selected examples of "success stories," we describe the process of phenotype-based high-throughput drug screening to target malignant cells or the immune system. Second, we describe computational approaches that link transcriptomic profiling of cancers with existing pharmaceutical compounds to accelerate drug repurposing. Finally, we review how CRISPR-based screening can be applied for the discovery of mechanisms of drug resistance and sensitization. Overall, we explore how the complementary strengths of each of these approaches allow them to transform the paradigm of pre-clinical drug development. [ABSTRACT FROM AUTHOR]

Published

2022

2. Thymoproteasome-Expressing Mesenchymal Stromal Cells Confer Protective Anti-Tumor Immunity via Cross-Priming of Endogenous Dendritic Cells.

Author

Bikorimana, Jean-Pierre, El-Hachem, Nehme, El-Kadiry, Abed El-Hakim, Abusarah, Jamilah, Salame, Natasha, Shammaa, Riam, and Rafei, Moutih

Subjects

STROMAL cells, DENDRITIC cells, IMMUNITY, PROTEASOMES, T cells, PSYCHONEUROIMMUNOLOGY, BCG vaccines, BACTERIAL vaccines, DYSTHYMIC disorder

Abstract

Proteasomes are complex macromolecular structures existing in various forms to regulate a myriad of cellular processes. Besides degrading unwanted or misfolded proteins (proteostasis), distinct immune functions were ascribed for the immunoproteasome and thymoproteasome (TPr) complexes. For instance, antigen degradation during ongoing immune responses mainly relies on immunoproteasome activity, whereas intrathymic CD8 T-cell development requires peptide generation by the TPr complex. Despite these substantial differences, the functional contribution of the TPr to peripheral T-cell immunity remains ill-defined. We herein explored whether the use of mesenchymal stromal cells (MSCs) engineered to exhibit altered proteasomal activity through de novo expression of the TPr complex can be exploited as a novel anti-cancer vaccine capable of triggering potent CD8 T-cell activation. Phenotypic and molecular characterization of MSC-TPr revealed a substantial decrease in MHCI (H2-Kb and H2-Dd) expression along with elevated secretion of various chemokines (CCL2, CCL9, CXCL1, LIX, and CX3CL1). In parallel, transcriptomic analysis pinpointed the limited ability of MSC-TPr to present endogenous antigens, which is consistent with their low expression levels of the peptide-loading proteins TAP, CALR, and PDAI3. Nevertheless, MSC-TPr cross-presented peptides derived from captured soluble proteins. When tested for their protective capacity, MSC-TPr triggered modest anti-tumoral responses despite efficient generation of effector memory CD4 and CD8 T cells. In contrast, clodronate administration prior to vaccination dramatically enhanced the MSC-TPr-induced anti-tumoral immunity clearly highlighting a refractory role mediated by phagocytic cells. Thus, our data elute to a DC cross-priming-dependant pathway in mediating the therapeutic effect of MSC-TPr. [ABSTRACT FROM AUTHOR]

Published

2021

3. A Novel Sulfonyl-Based Small Molecule Exhibiting Anti-cancer Properties.

Author

El-Kadiry, Abed El-Hakim, Abusarah, Jamilah, Cui, Yun Emma, El-Hachem, Nehme, Hammond-Martel, Ian, Wurtele, Hugo, Thomas, Sini, Ahmadi, Maryam, Balood, Mohammad, Talbot, Sébastien, and Rafei, Moutih

Subjects

SMALL molecules, T cell receptors, CELL death, CANCER cells, T cells

Abstract

Phenotypic screening is an ideal strategy for the discovery of novel bioactive molecules. Using a customized high-throughput screening (HTS) assay employing primary T lymphocytes, we screened a small library of 4,398 compounds with unknown biological function/target to identify compounds eliciting immunomodulatory properties and discovered a sulfonyl-containing hit, we named InhiTinib. This compound inhibited interferon (IFN)-gamma production and proliferation of primary CD3+ T cells without inducing cell death. In contrast, InhiTinib triggered apoptosis in several murine and human cancer cell lines. Besides, the compound was well tolerated by immunocompetent mice, triggered tumor regression in animals with pre-established EL4 T-cell lymphomas, and prolonged the overall survival of mice harboring advanced tumors. Altogether, our data demonstrate the anti-cancer properties of InhiTinib, which can henceforth bridge to wider-scale biochemical and clinical tests following further in-depth pharmacodynamic studies. Using a high-throughput screening (HTS) assay employing transgenic T cells which fluoresce upon T cell receptor (TCR) activation, we screened a small library of compounds with unknown biological function/target to identify compounds with potential immunomodulatory properties. Among the screened library, we discovered a sulfonyl-containing hit, we named. This compound inhibited interferon (IFN)-gamma production and proliferation of primary CD3+ T-cells without inducing cell death. In contrast, InhiTinib triggered apoptosis in several murine and human cancer cell lines. Further in vivo studies showed the compound is well tolerated by immunocompetent mice, triggers tumor regression in animals with pre-established EL4 T-cell lymphomas, and prolongs the overall survival of mice harboring advanced tumors. [ABSTRACT FROM AUTHOR]

Published

2020

4. Transcriptomic Alterations in Lung Adenocarcinoma Unveil New Mechanisms Targeted by the TBX2 Subfamily of Tumor Suppressor Genes.

Author

Khalil, Athar, Dekmak, Batoul, Boulos, Fouad, Kantrowitz, Jake, Spira, Avrum, Junya Fujimoto, Kadara, Humam, El-Hachem, Nehme, and Nemer, Georges

Published

2018

5. A Novel Role for CSRP1 in a Lebanese Family with Congenital Cardiac Defects.

Author

Kamar, Amina, Fahed, Akl C., Shibbani, Kamel, El-Hachem, Nehme, Bou-Slaiman, Salim, Arabi, Mariam, Kurban, Mazen, Seidman, Jonathan G., Seidman, Christine E., Haidar, Rachid, Baydoun, Elias, Nemer, Georges, and Bitar, Fadi

Subjects

CONGENITAL heart disease, LEBANESE, GENETIC mutation, HEALTH

Abstract

Despite an obvious role for consanguinity in congenital heart disease (CHD), most studies fail to document a monogenic model of inheritance except for few cases. We hereby describe a first-degree cousins consanguineous Lebanese family with 7 conceived children: 2 died in utero of unknown causes, 3 have CHD, and 4 have polydactyly. The aim of the study is to unveil the genetic variant(s) causing these phenotypes using next generation sequencing (NGS) technology. Targeted exome sequencing identified a heterozygous duplication in CSRP1 which leads to a potential frameshift mutation at position 154 of the protein. This mutation is inherited from the father, and segregates only with the CHD phenotype. The in vitro characterization demonstrates that the mutation dramatically abrogates its transcriptional activity over cardiac promoters like NPPA. In addition, it differentially inhibits the physical association of CSRP1 with SRF, GATA4, and with the newly described partner herein TBX5. Whole exome sequencing failed to show any potential variant linked to polydactyly, but revealed a novel missense mutation in TRPS1. This mutation is inherited from the healthy mother, and segregating only with the cardiac phenotype. Both TRPS1 and CSRP1 physically interact, and the mutations in each abrogate their partnership. Our findings add fundamental knowledge into the molecular basis of CHD, and propose the di-genicmodel of inheritance as responsible for such malformations. [ABSTRACT FROM AUTHOR]

Published

2017