Project description:The testis-specific BET protein BRDT structurally resembles the ubiquitous BRD4 and is ectopically expressed in various solid tumors, most notably lung cancer. Our analysis of patient samples indicates that BRDT expression may impact lung cancer progression. BRDT knockdown in lung cancer cells slowed tumor growth and prolonged survival in a xenograft model. Comparative characterization of PTEFb complex participation and chromatin binding indicates BRD4-redundant and -distinct BRDT functions. Unlike dual depletion, individual BRD4 or BRDT knockdown did not impair transcriptional responses to hypoxia in BRDT-expressing cells, consistent with redundant function. Acute BRD4 depletion and BRDT complementation revealed that BRDT can also release paused RNA Polymerase II independently of its bromodomains. These results underscore the functional importance of the C-terminal domains present in both BRD4 and BRDT and their potential as therapeutic targets in cancer, particularly in solid tumors. Future investigation will explore BRD4-distinct BRDT functions and BRDT misexpression driving cancer pathogenesis.

Project description:The BET family protein BRD4, which forms the CDK9-containing BRD4-PTEFb complex, is considered to be a master regulator of RNA polymerase II (Pol II) pause release. Because its tandem bromodomains interact with acetylated histone lysine residues, it has long been thought that BRD4 requires these bromodomains for its recruitment to chromatin and transcriptional regulatory function. Here, using rapid depletion and genetic complementation with domain deletion mutants, we demonstrate that BRD4 bromodomains are dispensable for Pol II pause release. A minimal, bromodomain-less C-terminal BRD4 fragment containing the PTEFb-interacting C-terminal motif (CTM) is instead both necessary and sufficient to mediate Pol II pause release in the absence of full-length BRD4. Although BRD4-PTEFb can associate with chromatin through acetyl recognition, our results indicate that a distinct, active BRD4-PTEFb population functions to regulate transcription independently of bromodomain-mediated chromatin association. These findings may enable more effective pharmaceutical modulation of BRD4-PTEFb activity.

Project description:Microarray analysis of gene expression changes in human A549 lung cancer cells upon siRNA knockdown of FAM60A and SDS3

Project description:During the post-meiotic phase of spermatogenesis, transcription is progressively repressed as the nuclei of haploid spermatids are compacted through a dramatic chromatin reorganization involving hyper-acetylation and replacement of most histones with sperm-specific protamines. Although BRDT has been shown to function in transcription as well as histone removal in post-meiotic spermatids, it is unknown whether other BET family proteins play a role. Immunofluorescence of mouse testes revealed BRD4 in a complete ring around the nuclei of spermatids containing hyper-acetylated histones. The BRD4 ring lies directly adjacent to the acroplaxome, or the cytoskeletal base of the acrosome, and does not form in acrosomal mutant mice. ChIP sequencing in round spermatids revealed enrichment of BRD4 and acetylated histone H3 and H4 at the promoters of active genes. GO Term analysis showed that BRD4 and BRDT bind to distinct subsets of spermatogenesis-specific genes. Association of BRD4 with Cyclin T1 decreases as spermatogenesis progresses despite a persistence of association with acetylated H4. Moreover, acetylated histones are removed from the condensing spermatid nucleus in a wave following the progressing acrosome. These data provide evidence for an interesting mechanism in which BRD4 and perhaps acetylated histones are removed from the spermatid genome via the progressing acrosome as transcription is repressed. Single replicates each of Brd4, H3K9me3, H3K9ac, H4K5ac, H4K8ac, H4K12ac, H4K16ac, H4Kac (pan-acetyl antibody), and input in mouse round spermatid cells; input is used to control for local sonication efficiency bias.

Project description:The RUNX1 transcription factor is strongly influenced by post-translational modifications. Here, we investigate a post-translational modification hotspot within a short peptide region in the evolutionarily conserved DNA-binding Runt domain. Cancer-specific mutations have been found clustered in this region, which also partially resembled the N-terminal tail of histone H4. We found that lysine acetylation of this histone-like motif promoted RUNX1 interaction with the BET-domain transcription co-activator BRD4,resulting in enhanced RUNX1 phosphorylation and transcriptional activity. Flanking post-translational modifications, such as arginine methylation and threonine phosphorylation, strongly inhibited the RUNX1-BRD4 complex formation. RNA sequencing revealed that knockdown of RUNX1 and BRD4 resulted in downregulation of genes associated with cell proliferation, suggesting that RUNX1 and BRD4 cooperated in driving cell cycle progression in gastric cancer. We identified AMIGO2 – known for its roles in invasion, proliferation and survival in cancer – as a common transcriptional target of RUNX1 and BRD4. Depletion of RUNX1 and BRD4 impaired cell proliferation and invasion in gastric cancer cells. Our work therefore indicates an oncogenic function for RUNX1-BRD4 interaction. Post-translational modification is reversible and can be pharmacologically targeted. We provide a basis for future design of drugs to specifically target the RUNX1-BRD4 interaction.

Project description:Comparison of Lung Cancer Proteome Profiles 3: DIA

Project description:RNA profiling of non-small cell lung cancer

Project description:Cancer-Associated Fibroblasts Support Lung Cancer Stemness through Paracrine IGF-II/IGF1R/Nanog Signaling

Project description:Gene expression in hypoxic non-small cell lung cancer

Project description:Knockdown of the oncogene, BRD4-NUT, in a rare cancer, termed NUTmidline carcinoma (NMC), results in morphologic features consistent with squamous differentiation. Treatment with the HDAC-inhibitor, TSA, appears to cause the same phenotype. Here, we use gene expression profiling to compare the changes in gene expression following BRD4-NUT knockdown and TSA treatment. RNA was extracted from two BRD4-NUT-expressing NMC cell lines, PER-403 and TC-797, 24h following siRNA knockdown versus control in duplicate. RNA was extracted from two BRD4-NUT-expressing NMC cell lines, PER-403 and TC-797, 24h following treatment with TSA versus etoh control in triplicate