Project description:NMNAT-1 and PARP-1, two key enzymes in the NAD+ metabolic pathway, localize to the nucleus where integration of their enzymatic activities has the potential to control a variety of nuclear processes. Using a variety of biochemical, molecular, cell-based, and genomic assays, we show that NMNAT-1 and PARP-1 physically and functionally interact at target gene promoters in MCF-7 cells. Specifically, we show that PARP-1 recruits NMNAT-1 to promoters, where it produces NAD+ to support PARP-1 catalytic activity, but also enhances the enzymatic activity of PARP-1 independent of NAD+ production. Furthermore, using two-photon excitation microscopy, we show that NMNAT-1 catalyzes the production of NAD+ in a nuclear pool that may be distinct from other cellular compartments. In expression microarray experiments, depletion of NMNAT-1 or PARP-1 alters the expression of about 200 protein-coding genes each, with about 10% overlap between the two gene sets. NMNAT-1 enzymatic activity is required for PARP-1-dependent PARylation at the promoters of commonly regulated target genes, as well as the expression of those target genes. Collectively, our studies link the enzymatic activities of NMNAT-1 and PARP-1 to the regulation of a set of common target genes through functional interactions at target gene promoters. We examined the co-localization of NMNAT-1 and PARP-1 at RefSeq promoters in MCF-7 cells using ChIP-chip Five samples:(1) two FLAG-NMNAT-1 IP'd with FLAG antibody from MCF-7 cells ectopically expressig FLAG-NMNAT-1 and (2) three native PARP-1 IP'd from parental MCF-7 cells with PARP-1 antibody

Project description:In mammals, nicotinamide phosphoribosyltransferase (NAMPT) and nicotinamide mononucleotide adenylyltransferase 1 (NMNAT-1) constitute a nuclear NAD+ salvage pathway, regulating cellular functions of the NAD+-dependent deacetylase SIRT1. However, little is known about the molecular mechanisms by which NAD+ biosynthesis controls gene transcription in the nucleus. In this study, we show that stable knockdown of NAMPT or NMNAT-1 in MCF-7 breast cancer cells significantly reduced total cellular NAD+ levels. Expression microarray analyses demonstrate that both enzymes have broad and overlapping functions in gene regulation. SIRT1 is a key mediator of NAMPT- and NMNAT-1-dependent gene regulation, and is found at promoters of many of the target genes. Furthermore, SIRT1 deacetylase activity at these promoters is regulated by NAMPT and NMNAT-1. Most significantly, NMNAT-1 interacts with SIRT1 and is recruited to target gene promoters by SIRT1. Our results reveal an unexpected mechanism for the direct control of SIRT1 deacetylase activity at target gene promoters by NMNAT-1. Interactions between NMNAT-1 and SIRT1 at gene promoters may provide a platform for integration of multiple signaling pathways that regulate transcription. This SuperSeries is composed of the SubSeries listed below.

Project description:Global protein synthesis is upregulated in cancers, and thus cancer cells are prone to errors in translation, which may lead to protein misfolding and proteotoxic stress. The pathways that maintain protein homeostasis support the transformation and growth of cancer cells. Here, we show that the cytosolic NAD+ synthesis pathway (controlled by NMNAT-2) plays an essential role in ovarian cancer by maintaining protein homeostasis by regulating the activity of PARP-16, that MARylates the ribosomal proteins. Using polysome-RNA Seq analysis, we found that inhibiting ribosomal protein MARylation by knocking down NMNAT-2 or PARP-16 leads to increased association of specific mRNAs with polysomes and enhanced translation of a set of mRNAs that contain specific secondary structures in their 3’UTRs, which leads to protein aggregation. Collectively, our study demonstrates that NMNAT-2 regulates PARP-16 activity and ribosomal protein MARylation, which control protein homeostasis by fine-tuning the levels of protein synthesis in ovarian cancers.

Project description:Although ADP-ribosylation of histones by PARP-1 has been linked to genotoxic stress responses, its role in physiological processes has remained elusive. We found that ADPribosylation of histone H2B-Glu35 inhibits the differentiation of adipocyte precursors, leading to a reduction of newly formed adipocytes in white adipose tissue. ADP-ribosylation of Glu35 by PARP-1 inhibits phosphorylation of adjacent H2B-Ser36, which is required for the proadipogenic gene expression program. It also inhibits adipogenesis in cultured cells and a mouse lineage tracing genetic model. The activity of PARP-1 on H2B requires NMNAT-1, a nuclear NAD+ synthase, which serves as a specificity factor to direct PARP-1 catalytic activity to Glu and Asp residues. Collectively, our results demonstrate a functional interplay between H2B-Glu35 ADP-ribosylation and H2B-Ser36 phosphorylation that controls adipogenesis and cancer cell proliferation.

Project description:The PARP family of proteins comprises 17 members, about two thirds of which are active mono- or poly(ADP-ribosyl)transferase enzymes that transfer the ADP-ribose moiety of NAD+ onto target proteins. In many cases, ADP-ribosylation, which plays critical roles in human diseases (e.g., cancer, heart disease, and neuropathies) is associated with abrogation of the molecular functions of the target. Discerning ADP-ribosylation events mediated by a specific PARP is challenging, since all PARPs use the same substrate (i.e., NAD+) and the available inhibitors lack the specificity needed to make such conclusions. In order to identify the direct and specific targets of individual PARP family members, we have developed a chemical and genetic approach known as analog sensitivity, in which alteration of a single conserved amino acid in the active site of the PARP protein creates a pocket that allows use of an unnatural NAD+ analog containing a steric moiety. We have functionalized the steric moiety with alkyne for use in click chemistry reactions. This approach, which is transferable to other PARP family members, creates substrate specificity where none previously existed, allowing PARP-specific post-translational modification followed by target visualization, or isolation of ADP-ribosylated targets using click chemistry techniques. We have used this technology in conjunction with mass spectrometry to identify hundreds of targets both unique to, as well as shared among, the nuclear PARP proteins, PARP-1, PARP-2, and PARP-3. We have also determined the genome-wide distribution of PARP-1-specific ADP-ribosylation by coupling this analog-sensitive PARP approach with chromatin cross-linking in method that we call “Click-ChIP-seq”. We observed that PARP-1-specific ADP-ribosylation is enriched at transcriptionally active promoters in proximity to sites of PARP-1 enrichment. In addition, we observed that NELF, an important regulator of RNA Polymerase II (Pol II) pausing, is not only a target of ADP-ribosylation by PARP-1 but also spatially correlated with chromatin-associated ADP-ribose and PARP-1 in Click-ChIP-seq and ChIP-seq assays, respectively. Given these observations, we hypothesized that ADP-ribosylation might modulate NELF function and result altered Pol II pausing. We have explored this possibility using global run-on coupled with deep sequencing (GRO-seq) in MCF-7 cells in which PARP-1 was depleted by RNAi-mediated knockdown. PARP-1 depletion caused an increase in Pol II pausing genome-wide. Taken together, these results suggest the intriguing possibility that ADP-ribosylation of NELF by PARP-1 may be an important and heretofore unknown step in the release of Pol II into productive elongation.

Project description:The PARP family of proteins comprises 17 members, about two thirds of which are active mono- or poly(ADP-ribosyl)transferase enzymes that transfer the ADP-ribose moiety of NAD+ onto target proteins. In many cases, ADP-ribosylation, which plays critical roles in human diseases (e.g., cancer, heart disease, and neuropathies) is associated with abrogation of the molecular functions of the target. Discerning ADP-ribosylation events mediated by a specific PARP is challenging, since all PARPs use the same substrate (i.e., NAD+) and the available inhibitors lack the specificity needed to make such conclusions. In order to identify the direct and specific targets of individual PARP family members, we have developed a chemical and genetic approach known as analog sensitivity, in which alteration of a single conserved amino acid in the active site of the PARP protein creates a pocket that allows use of an unnatural NAD+ analog containing a steric moiety. We have functionalized the steric moiety with alkyne for use in click chemistry reactions. This approach, which is transferable to other PARP family members, creates substrate specificity where none previously existed, allowing PARP-specific post-translational modification followed by target visualization, or isolation of ADP-ribosylated targets using click chemistry techniques. We have used this technology in conjunction with mass spectrometry to identify hundreds of targets both unique to, as well as shared among, the nuclear PARP proteins, PARP-1, PARP-2, and PARP-3. We have also determined the genome-wide distribution of PARP-1-specific ADP-ribosylation by coupling this analog-sensitive PARP approach with chromatin cross-linking in method that we call “Click-ChIP-seq”. We observed that PARP-1-specific ADP-ribosylation is enriched at transcriptionally active promoters in proximity to sites of PARP-1 enrichment. In addition, we observed that NELF, an important regulator of RNA Polymerase II (Pol II) pausing, is not only a target of ADP-ribosylation by PARP-1 but also spatially correlated with chromatin-associated ADP-ribose and PARP-1 in Click-ChIP-seq and ChIP-seq assays, respectively. Given these observations, we hypothesized that ADP-ribosylation might modulate NELF function and result altered Pol II pausing. We have explored this possibility using global run-on coupled with deep sequencing (GRO-seq) in MCF-7 cells in which PARP-1 was depleted by RNAi-mediated knockdown. PARP-1 depletion caused an increase in Pol II pausing genome-wide. Taken together, these results suggest the intriguing possibility that ADP-ribosylation of NELF by PARP-1 may be an important and heretofore unknown step in the release of Pol II into productive elongation.

Project description:ADP-ribosylation (ADPRylation) is a regulatory posttranslational modification of proteins that results in the covalent attachment of ADP-ribose (ADPR) moieties on target proteins. PARP-7 (TiPARP) is a monoADPR transferase whose proteins substrates and biological activities are poorly understood. Here, we describe a chemical genetics approach that has allowed us to identify substrates of PARP-7 and explore their biological functions. We observed reduced levels of PARP7 mRNA in ovarian cancer patient samples versus normal tissue, but found nonetheless that PARP-7 is required for a number of cancer-related biological endpoints in ovarian cancer cells, including growth, migration, and invasion. Global gene expression and gene ontology analyses in ovarian cancer cells subjected to siRNA-mediated knockdown of PARP7 revealed an enrichment of genes encoding proteins with roles in cell-cell adhesion, cell cycle arrest, apoptosis, and gene regulation. To identify the ADPRylated substrates that underlie PARP-7-mediated ovarian cancer cell phenotypes, we developed an NAD+ analog-sensitive approach for PARP-7 comprising a PARP-7 NAD+ binding pocket mutant (S563G) paired with the NAD+ analog 8-Bu(3-yne)T-NAD+. When coupled with mass spectrometry, this approach allowed us to identify the PARP-7 ADP-ribosylated proteome in ovarian cancer cells, including components of the cell-cell adhesion and cytoskeleton organization machinery. Specifically, we found that PARP-7 monoADPRylates α-tubulin to promote microtubule instability, which may play a key role in the regulating ovarian cancer cell growth and motility. Collectively, our results point to an extensive PARP-7 ADP-ribosylated proteome with important roles in cancer-related cellular phenotypes.

Project description:Poly ADP-ribose (PAR) polymerases (PARPs) play fundamental roles in multiple DNA damage recognition and repair pathways. Persistent nuclear PARP activation causes cellular NAD+ depletion and exacerbates cellular aging. However, very little is known about mitochondrial PARP (mtPARP) and PARylation. The existence of mtPARP is controversial, and the biological roles for mtPARP induced mitochondrial PARylation are unclear. Here, we demonstrate the presence of PARP1 and PARylation in purified mitochondria. The addition of the PARP1 substrate NAD+ to isolated mitochondria induces PARylation which is suppressed by PARP inhibitor olaparib treatment. Mitochondrial PARylation was also evaluated by enzymatic labeling of terminal ADP-ribose (ELTA) labeling. To further confirm the presence of mtPARP1, we evaluated mitochondrial nucleoid PARylation by ADP ribose-chromatin affinity purification (ADPr-ChAP) . We observed that NAD+ stimulated PARylation and TFAM occupancy on the mtDNA regulatory region D-loop, inducing mtDNA transcription. These findings suggest that PARP1 is integrally involved in mitochondrial PARylation and NAD+ dependent mtPARP1 activity contributes to mtDNA transcription regulation.

Project description:To identify the ADPRylated substrates that underlie PARP-7-mediated ovarian cancer cell phenotypes, we developed an NAD+ analog-sensitive approach for PARP-7 comprising a PARP-7 NAD+ binding pocket mutant (S563G) paired with the NAD+ analog 8-Bu(3-yne)T-NAD+. When coupled with mass spectrometry, this approach allowed us to identify the PARP-7 ADP-ribosylated proteome in ovarian cancer cells, including components of the cell-cell adhesion and cytoskeleton organization machinery. Specifically, we found that PARP-7 monoADPRylates alpha-tubulin to promote microtubule instability, which may play a key role in the regulating ovarian cancer cell growth and motility. Collectively, our results point to an extensive PARP-7 ADP-ribosylated proteome with important roles in cancer-related cellular phenotypes.

Project description:Eukaryotic gene regulation implies that transcription factors gain access to genomic information via poorly understood processes involving activation and targeting of kinases, histone-modifying enzymes, and chromatin remodelers to chromatin. Here we report that progestin gene regulation in breast cancer cells requires a rapid and transient increase in poly-(ADP)-ribose (PAR), accompanied by a dramatic decrease of cellular NAD that could have broad implications in cell physiology. This rapid increase in nuclear PARylation is mediated by activation of PAR polymerase PARP-1 as a result of phosphorylation by cyclin-dependent kinase CDK2. Hormone-dependent phosphorylation of PARP-1 by CDK2, within the catalytic domain, enhances its enzymatic capabilities. Activated PARP-1 contributes to the displacement of histone H1 and is essential for regulation of the majority of hormone-responsive genes and for the effect of progestins on cell cycle progression. Both global chromatin immunoprecipitation (ChIP) coupled with deep sequencing (ChIP-seq) and gene expression analysis show a strong overlap between PARP-1 and CDK2. Thus, progestin gene regulation involves a novel signaling pathway that connects CDK2-dependent activation of PARP-1 with histone H1 displacement. Given the multiplicity of PARP targets, this new pathway could be used for the pharmacological management of breast cancer. PARP-1 activation mechanism by CDK2 in response of progestin in breast cancer cells