Matthew F. Barber scite author profile

Sirtuin proteins regulate diverse cellular pathways that influence genomic stability, metabolism, and ageing1,2. SIRT7 is a mammalian sirtuin whose biochemical activity, molecular targets, and physiologic functions have been unclear. Here we show that SIRT7 is an NAD+-dependent H3K18Ac (acetylated lysine 18 of histone H3) deacetylase that stabilizes the transformed state of cancer cells. Genome-wide binding studies reveal that SIRT7 binds to promoters of a specific set of gene targets, where it deacetylates H3K18Ac and promotes transcriptional repression. The spectrum of SIRT7 target genes is defined in part by its interaction with the cancer-associated ETS transcription factor ELK4, and comprises numerous genes with links to tumour suppression. Notably, selective hypoacetylation of H3K18Ac has been linked to oncogenic transformation, and in patients is associated with aggressive tumour phenotypes and poor prognosis3–6. We find that deacetylation of H3K18Ac by SIRT7 is necessary for maintaining essential features of human cancer cells, including anchorage-independent growth and escape from contact inhibition. Moreover, SIRT7 is necessary for a global hypoacetylation of H3K18Ac associated with cellular transformation by the viral oncoprotein E1A. Finally, SIRT7 depletion markedly reduces the tumourigenicity of human cancer cell xenografts in mice. Together, our work establishes SIRT7 as a highly selective H3K18Ac deacetylase and demonstrates a pivotal role for SIRT7 in chromatin regulation, cellular transformation programs, and tumour formation in vivo.

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Cell cycle-dependent deacetylation of telomeric histone H3 lysine K56 by human SIRT6

Michishita¹,

McCord²,

Boxer³

et al. 2009

Cell Cycle

343

259

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Interferon-Inducible GTPases in Host Resistance, Inflammation and Disease

Pilla-Moffett

Barber

Taylor

et al. 2016

Journal of Molecular Biology

192

221

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Cell-autonomous immunity is essential for host organisms to defend themselves against invasive microbes. In vertebrates, both the adaptive and the innate branches of the immune system operate cell-autonomous defenses as key effector mechanisms that are induced by pro-inflammatory interferons. Interferons can activate cell-intrinsic host defenses in virtually any cell type ranging from professional phagocytes to mucosal epithelial cells. Much of this interferon-induced host resistance program is dependent on four families of interferon-inducible GTPases: the myxovirus resistance proteins (Mx), the immunity related GTPases (IRGs), the guanylate binding proteins (GBPs) and the very large interferon-inducible GTPases (VLIGs). These GTPase families provide host resistance to a variety of viral, bacterial and protozoan pathogens through the sequestration of microbial proteins, manipulation of vesicle trafficking, regulation of antimicrobial autophagy (xenophagy), execution of intracellular membranolytic pathways, and the activation of inflammasomes. This review discusses our current knowledge of the molecular function of interferon-inducible GTPases in providing host resistance as well as their role in the pathogenesis of autoinflammatory Crohn's disease. While substantial advances were made in the recent past, few of the known functions of interferon-inducible GTPases have been explored in any depth and new functions await discovery. This review will therefore highlight key areas of future exploration that promise to advance our understanding of the role of interferon-inducible GTPases in human diseases. Graphical abstract1 corresponding authors:

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Escape from bacterial iron piracy through rapid evolution of transferrin

Barber

Elde

2014

Science

171

150

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Iron sequestration provides an innate defense termed nutritional immunity, leading pathogens to scavenge iron from hosts. Although the molecular basis of this battle for iron is established, its potential as a force for evolution at host-pathogen interfaces is unknown. We show that the iron transport protein transferrin is engaged in ancient and ongoing evolutionary conflicts with TbpA, a transferrin surface receptor from bacteria. Single substitutions in transferrin at rapidly evolving sites reverse TbpA binding, providing a mechanism to counteract bacterial iron piracy among great apes. Furthermore, the C2 transferrin polymorphism in humans evades TbpA variants from Haemophilus influenzae, revealing a functional basis for standing genetic variation. These findings identify a central role for nutritional immunity in the persistent evolutionary conflicts between primates and bacterial pathogens.

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Buried Treasure: Evolutionary Perspectives on Microbial Iron Piracy

2015

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Host-pathogen interactions provide valuable systems for the study of evolutionary genetics and natural selection. The sequestration of essential iron has emerged as a critical innate defense system termed nutritional immunity, leading pathogens to evolve mechanisms of `iron piracy' to scavenge this metal from host proteins. This battle for iron carries numerous consequences not only for host-pathogen evolution, but also microbial community interactions. Here we highlight recent and potential future areas of investigation on the evolutionary implications of microbial iron piracy in relation to molecular arms races, host range, competition, and virulence. Applying evolutionary genetic approaches to the study of microbial iron acquisition could also provide new inroads for understanding and combating infectious disease.

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Matthew F. Barber

SIRT7 links H3K18 deacetylation to maintenance of oncogenic transformation

Cell cycle-dependent deacetylation of telomeric histone H3 lysine K56 by human SIRT6

Interferon-Inducible GTPases in Host Resistance, Inflammation and Disease

Escape from bacterial iron piracy through rapid evolution of transferrin

Buried Treasure: Evolutionary Perspectives on Microbial Iron Piracy

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