Institution
Cancer Research Institute
Nonprofit•New York, New York, United States•
About: Cancer Research Institute is a nonprofit organization based out in New York, New York, United States. It is known for research contribution in the topics: Cancer & Population. The organization has 1061 authors who have published 754 publications receiving 26712 citations.
Topics: Cancer, Population, Breast cancer, Cell cycle, Gene
Papers published on a yearly basis
Papers
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TL;DR: Comparative studies of wild-type and mutants will be helpful in understanding the basic role of BARD1BRCT in DNA damage repair and loss in structural compactness on the Ile738Val mutant.
Abstract: BARD1-BRCA1 complex plays an important role in DNA damage repair, apoptosis, chromatin remodeling, and other important processes required for cell survival. BRCA1 and BARD1 heterodimer possess E3 ligase activity and is involved in genome maintenance, by functioning in surveillance for DNA damage, thereby regulating multiple pathways including tumor suppression. BRCT domains are evolutionary conserved domains present in different proteins such as BRCA1, BARD1, XRCC, and MDC1 regulating damage response and cell-cycle control through protein-protein interactions. Nonetheless, the role of BARD1BRCT in the recruitment of DNA repair mechanism and structural integrity with BRCA1 complex is still implicit. To explicate the role of BARD1BRCT in the DNA repair mechanism, in silico, in vitro, and biophysical approach were applied to characterize BARD1 BRCT wild-type and Arg658Cys and Ile738Val mutants. However, no drastic secondary and tertiary structural changes in the mutant proteins were observed. Thermal and chemical denaturation studies revealed that mutants Arg658Cys and Ile738Val have a decrease in Tm and ∆G than the wild type. In silico studies of BARD1 BRCT (568-777) and mutant protein indicate loss in structural compactness on the Ile738Val mutant. Comparative studies of wild-type and mutants will thus be helpful in understanding the basic role of BARD1BRCT in DNA damage repair.
6 citations
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6 citations
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TL;DR: In this paper, the authors investigated the role of EGR1 (Early Growth Response1) in upregulation of SRSF10 in head and neck cancer (HNC) patients.
Abstract: Aberrant alternative splicing is recognized to promote cancer pathogenesis, but the underlying mechanism is yet to be clear. Here, in this study, we report the frequent upregulation of SRSF10 (serine and arginine-rich splicing factor 10), a member of an expanded family of SR splicing factors, in the head and neck cancer (HNC) patients sample in comparison to paired normal tissues. We observed that SRSF10 plays a crucial role in HNC tumorigenesis by affecting the pro-death, pro-survical splice variants of BCL2L1 (BCL2 Like 1: BCLx: Apoptosis Regulator) and the two splice variants of PKM (Pyruvate kinase M), PKM1 normal isoform to PKM2 cancer-specific isoform. SRSF10 is a unique splicing factor with a similar domain organization to that of SR proteins but functions differently as it acts as a sequence-specific splicing activator in its phosphorylated form. Although a body of research studied the role of SRSF10 in the splicing process, the regulatory mechanisms underlying SRSF10 upregulation in the tumor are not very clear. In this study, we aim to dissect the pathway that regulates the SRSF10 upregulation in HNC. Our results uncover the role of transcription factor EGR1 (Early Growth Response1) in elevating the SRSF10 expression; EGR1 binds to the promoter of SRSF10 and promotes TET1 binding leading to the CpG demethylation (hydroxymethylation) in the adjacent position of the EGR1 binding motif, which thereby instigate SRSF10 expression in HNC. Interestingly we also observed that the EGR1 level is in the sink with the ERK1/2 pathway, and therefore, inhibition of the ERK1/2 pathway leads to the decreased EGR1 and SRSF10 expression level. Together, this is the first report to the best of our knowledge where we characterize the ERK 1/2-EGR1-SRSF10 axis regulating the cancer-specific splicing, which plays a critical role in HNC and could be a therapeutic target for better management of HNC patients.
6 citations
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TL;DR: The overall results of the study strongly suggest that all-trans retinoic acid enhances the effect of Fra-1 on inhibiting cervical cancer proliferation and metabolism in vitro, and also influences the expression of MDM2/P53/P21 and LDHA.
Abstract: This study on all-trans retinoic acid was designed to explore its effect on the ability of Fra-1 to cervical cancer cell development. The results show that all-trans retinoic acid enhances the effect of Fra-1 on inhibiting cervical cancer proliferation and the glucose consumption, its effect on the loss of mitochondrial membrane potential, on the decreasing of lactic acid as well as ATP, and also influences the expression of MDM2/P53/P21 and LDHA. The results show that the expression of Fra-1 is higher in all-trans retinoic acid-treated cervical cancer. Flow cytometry and kit detection show that all-trans retinoic acid can enhance the ability of Fra-1 to lose the mitochondrial membrane potential, inhibit the glucose consumption and the production of lactic acid as well as ATP. CCK8 and colony formation assays indicate that all-trans retinoic acid enhances the ability of Fra-1 to inhibit cell proliferation. In addition, through Western blot analysis, it was determined that P53 and P21 were up-regulated, and MDM2 and LDHA were down-regulated. The overall results of the study strongly suggest that all-trans retinoic acid enhances the effect of Fra-1 on inhibiting cervical cancer proliferation and metabolism in vitro, and also influences the expression of MDM2/P53/P21 and LDHA.
6 citations
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TL;DR: The finding that different domain of FANCI, FANCD2 and BRCA2 are playing important role in PPIs, and mutations cause the impairment in the PPIs which in turn may disrupt the DNA ICL repair mechanism is investigated.
6 citations
Authors
Showing all 1079 results
Name | H-index | Papers | Citations |
---|---|---|---|
Lewis L. Lanier | 159 | 554 | 86677 |
Xavier Estivill | 110 | 673 | 59568 |
Richard D. Kolodner | 105 | 307 | 40928 |
Jay A. Levy | 104 | 451 | 37920 |
Zbigniew Darzynkiewicz | 101 | 689 | 42625 |
Vikas P. Sukhatme | 100 | 317 | 39027 |
Israel Vlodavsky | 98 | 494 | 34150 |
Yung-Jue Bang | 94 | 664 | 46313 |
Naofumi Mukaida | 93 | 368 | 29652 |
Tetsuo Noda | 90 | 318 | 33195 |
George R. Pettit | 89 | 848 | 31759 |
Jo Vandesompele | 88 | 383 | 59368 |
Denis Gospodarowicz | 84 | 208 | 28915 |
Rolf Kiessling | 82 | 299 | 24617 |
Bruce R. Bistrian | 77 | 590 | 25634 |