The SIN3 Deacetylase Complex Represses Genes Encoding Mitochondrial Proteins

Pile, Lori A.; Spellman, Paul T.; Katzenberger, Rebeccah J.; Wassarman, David A.

doi:10.1074/jbc.m305996200

Cited by 77 publications

(102 citation statements)

References 48 publications

(32 reference statements)

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“…Consistent with findings in Drosophila, mSin3A deletion resulted in the up-regulation of genes involved in cytosolic and mitochondrial energy-generating pathways (Pdk1,Mrsp23,Oghd,Adac9,Bdh,Got2,Hadh2,Cs,Fxc1,Prdx3), strengthening the provocative role for mSin3A in the regulation of mitochondrial respiratory activity (Pile et al 2003; see below). Finally, mSin3A regulates the expression of several genes involved in DNA replication (Rpa1,Lig1,Mcm4,Mcm5,Mcm7,Nap1l1) providing a basis for the observed defects in DNA replication upon deletion of mSin3A, and strengthening the case for a direct role for mSin3A in the DNA replication process.…”

Section: Genetic Analysis Of Msin3a Genes and Development 1585supporting

confidence: 65%

mSin3A corepressor regulates diverse transcriptional networks governing normal and neoplastic growth and survival

Dannenberg

Gourichon²,

Zhong³

et al. 2005

Genes Dev.

210

249

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mSin3A is a core component of a large multiprotein corepressor complex with associated histone deacetylase (HDAC) enzymatic activity. Physical interactions of mSin3A with many sequence-specific transcription factors has linked the mSin3A corepressor complex to the regulation of diverse signaling pathways and associated biological processes. To dissect the complex nature of mSin3A's actions, we monitored the impact of conditional mSin3A deletion on the developmental, cell biological, and transcriptional levels. mSin3A was shown to play an essential role in early embryonic development and in the proliferation and survival of primary, immortalized, and transformed cells. Genetic and biochemical analyses established a role for mSin3A/HDAC in p53 deacetylation and activation, although genetic deletion of p53 was not sufficient to attenuate the mSin3A null cell lethal phenotype. Consistent with mSin3A's broad biological activities beyond regulation of the p53 pathway, time-course gene expression profiling following mSin3A deletion revealed deregulation of genes involved in cell cycle regulation, DNA replication, DNA repair, apoptosis, chromatin modifications, and mitochondrial metabolism. Computational analysis of the mSin3A transcriptome using a knowledge-based database revealed several nodal points through which mSin3A influences gene expression, including the Myc-Mad, E2F, and p53 transcriptional networks. Further validation of these nodes derived from in silico promoter analysis showing enrichment for Myc-Mad, E2F, and p53 cis-regulatory elements in regulatory regions of up-regulated genes following mSin3A depletion. Significantly, in silico promoter analyses also revealed specific cis-regulatory elements binding the transcriptional activator Stat and the ISWI ATP-dependent nucleosome remodeling factor Falz, thereby expanding further the mSin3A network of regulatory factors. Together, these integrated genetic, biochemical, and computational studies demonstrate the involvement of mSin3A in the regulation of diverse pathways governing many aspects of normal and neoplastic growth and survival and provide an experimental framework for the analysis of essential genes with diverse biological functions.[Keywords: Histone modifications; knock-out; mSin3 complex; mSin3A; transcriptional regulation; tumorigenesis] Supplemental material is available at http://www.genesdev.org.

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Section: Genetic Analysis Of Msin3a Genes and Development 1585supporting

confidence: 65%

mSin3A corepressor regulates diverse transcriptional networks governing normal and neoplastic growth and survival

Dannenberg

Gourichon²,

Zhong³

et al. 2005

Genes Dev.

210

249

View full text Add to dashboard Cite

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“…In the absence of this hormone, the ecdysone receptor complex interacts with transcriptional repressors Rpd3 and Sin3 [41]. What is interesting about this, from our point of view, is that reduction of Rpd3 extends life span in flies [42] and reduction in Sin3 causes upregulation of genes involved in the oxidative metabolism of fatty acid to acetyl-CoA and genes involved in mitochondrial oxidative phosphorylation [43]. The similarity between the ecdysone receptor complex and the nuclear hormone complexes in mammalian systems has led to speculation that the mammalian counterparts may also participate in the regulation of aging [44].…”

Section: Spanmentioning

confidence: 85%

Metabolic Reprogramming in Dietary Restriction

Anderson

Weindruch²

2006

Interdisciplinary Topics in Gerontology

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It is widely accepted that energy intake restriction without essential nutrient deficiency delays the onset of aging and extends life span. The mechanism underlying this phenomenon is still unknown though a number of different, nonmutually exclusive explanations have been proposed. In each of these, different facets of physiology play the more significant role in the mechanism of aging retardation. Some examples include the altered lipid composition model, the immune response model and models describing changes in endocrine function. In this paper we propose the hypothesis that metabolic reprogramming is the key event in the mechanism of dietary restriction, and the physiological effects at the cellular, tissue and organismal level may be understood in terms of this initial event.Dietary restriction (DR) is the most successful intervention tested to date in mammals which greatly extends maximum life span and keeps animals 'younger longer' [1][2][3]. Consequently, any hypothesis about the etiology of aging must reconcile the effects of DR on aging. With increased knowledge of the mechanism of DR, we stand to gain a considerable insight into the process of aging.We propose that a change in the regulation of energy metabolism in response to DR is the primary step in the retardation of aging ( fig. 1). First we describe the evidence in support of metabolic reprogramming, a switch to an altered metabolic state, by DR in mice. Next we consider evidence for metabolic shifts in other model organisms where life span is extended by DR or by genetic manipulation. Then we focus on changes in mitochondrial energy metabolism with age and DR in mammals. Next we will explore the effects of altered mitochondrial function in the context of reactive oxygen species (ROS) generation and oxidative stress. Finally we describe the metabolic and morphological changes in white adipose tissue that we believe are a result of altered mitochondrial function. We propose that the activation of adipose tissue through metabolic reprogramming is critical to the mechanism of DR and that it leads to the changes in the animal physiology that are described in the models indicated above. Metabolic Reprogramming in Tissues from Dietary-Restricted AnimalsThe inverse linear relationship between calorie intake and life span in mice [4] suggests that genes central to energy metabolism may be critical in the underlying mechanism of DR in

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“…The decrease of string, which encodes the Drosophila homolog of the CDC25 phosphatase, may be particularly relevant as its elimination was shown to be sufficient to cause G 2 arrest in S2 cells. In addition, downregulation of string and G 2 arrest was also observed by others upon RNAi of the HDAC1-recruiting SIN3 co-repressor (39,40) (also see below).…”

Section: Resultsmentioning

confidence: 99%

“…This similarity is not unexpected because DHDAC1 is thought to be involved in the transcriptional repressor functions of SIN3. We therefore compared the published microarray profile of SIN3 RNAi (40) with our TSA or DHDAC1 RNAi data. Significant overlaps were detected between the published SIN3 and our DHDAC1 and TSA signatures (Fig.…”

Section: Resultsmentioning

confidence: 99%

Dissecting the Biological Functions of Drosophila Histone Deacetylases by RNA Interference and Transcriptional Profiling

Foglietti

Filocamo

Cundari

et al. 2006

Journal of Biological Chemistry

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Chromatin modifications such as acetylation, methylation, phosphorylation, ubiquitination, and sumoylation of histones play an important role in the regulation of transcription (1-5). Together with DNA methylation, these modifications are part of a broad and multifaceted strategy whereby eukaryotes regulate gene expression at the epigenetic level (6 -8).Acetylation of histones is tightly controlled by the activity of histone acetyltransferases and histone deacetylases (HDACs) 2 (9, 10). Histone deacetylation may repress transcription by different mechanisms. On the one hand, this process increases the charge density on the N termini of the core histones thereby strengthening histone tail-DNA interactions and blocking access of the transcriptional machinery to the DNA template. In addition, histone modifications are specifically recognized by chromatin-interacting proteins thus favoring the formation of higher order chromatin structures (heterochromatin).There is ample evidence that aberrations in the epigenetic regulation of gene expression at the levels of DNA methylation and histone acetylation or histone methylation are an important component in the process of malignant transformation of human cells (11). A number of histone acetyltransferase mutations were identified in cancer, and HDACs were found to be overexpressed or aberrantly recruited in several human malignancies (12). Small molecule HDAC inhibitors induce cell cycle arrest, differentiation, and apoptosis in cancer cells with a significant window over normal cells, and some molecules have already entered clinical trials and show promising results (13).Higher organisms have evolved a considerable complexity in the histone deacetylase family; thus, in mammals, 17 different HDAC subtypes were identified, which were grouped into three classes according to their sequence homologies with the yeast proteins Rpd3 (class I), HDA1 (class II), and Sir (class III) (14 -16). Class I and class II proteins are evolutionarily related and share a common enzymatic mechanism, the Zn-catalyzed hydrolysis of the acetyl-lysine amide bond. The HDAC inhibitors that are presently in clinical trials are rather nonselective and are thought to inhibit most or many of the class I and II proteins. Class III proteins are evolutionarily unrelated to class I or class II and catalyze the transfer of the acetyl group onto the sugar moiety of NAD (16

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The SIN3 Deacetylase Complex Represses Genes Encoding Mitochondrial Proteins

Cited by 77 publications

References 48 publications

mSin3A corepressor regulates diverse transcriptional networks governing normal and neoplastic growth and survival

mSin3A corepressor regulates diverse transcriptional networks governing normal and neoplastic growth and survival

Metabolic Reprogramming in Dietary Restriction

Dissecting the Biological Functions of Drosophila Histone Deacetylases by RNA Interference and Transcriptional Profiling

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