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Journal Club June 2018

by

Oliver Medvedik

June 25, 2018

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For the June edition of Journal Club, we discussed the recent paper entitled “Changes at the nuclear lamina alter binding of pioneer factor Foxa2 in aged liver“. We had also summarized the research in an article earlier this month.

Summary
Increasing evidence suggests that regulation of heterochromatin at the nuclear envelope underlies metabolic disease susceptibility and age‐dependent metabolic changes, but the mechanism is unknown. Here, we profile lamina‐associated domains (LADs) using lamin B1 ChIP‐Seq in young and old hepatocytes and find that, although lamin B1 resides at a large fraction of domains at both ages, a third of lamin B1‐associated regions are bound exclusively at each age in vivo. Regions occupied by lamin B1 solely in young livers are enriched for the forkhead motif, bound by Foxa pioneer factors. We also show that Foxa2 binds more sites in Zmpste24 mutant mice, a progeroid laminopathy model, similar to increased Foxa2 occupancy in old livers. Aged and Zmpste24‐deficient livers share several features, including nuclear lamina abnormalities, increased Foxa2 binding, de‐repression of PPAR‐ and LXR‐dependent gene expression, and fatty liver. In old livers, additional Foxa2 binding is correlated to loss of lamin B1 and heterochromatin (H3K9me3 occupancy) at these loci. Our observations suggest that changes at the nuclear lamina are linked to altered Foxa2 binding, enabling opening of chromatin and de‐repression of genes encoding lipid synthesis and storage targets that contribute to etiology of hepatic steatosis.

Whitton, H., Singh, L. N., Patrick, M. A., Price, A. J., Osorio, F. G., López‐Otín, C., & Bochkis, I. M. (2018). Changes at the nuclear lamina alter binding of pioneer factor Foxa2 in aged liver. Aging cell, 17(3), e12742.

CategoryJournal club

Tags: Foxa2, Journal Club, Nuclear lamina

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About the author

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Oliver Medvedik

Oliver Medvedik, Co-founder of Genspace citizen science laboratory in Brooklyn NY, earned his Ph.D. at Harvard Medical School in the Biomedical and Biological Sciences program. As part of his doctoral work he has used single-celled budding yeast as a model system to map the genetic pathways that underlie the processes of aging in more complex organisms, such as humans. Prior to arriving in Boston for his doctoral studies, he has lived most of his life in New York City. He obtained his bachelor’s degree in biology from Hunter College, City University of New York. Since graduating from Harvard, he has worked as a biotechnology consultant, taught molecular biology to numerous undergraduates at Harvard University and mentored two of Harvard’s teams for the international genetically engineered machines competition (IGEM) held annually at M.I.T. Oliver is also the Director of The Maurice Kanbar Center for Biomedical Engineering at the Cooper Union, New York City. The Maurice Kanbar Center for Biomedical Engineering is open to all Cooper Union faculty and students working on bioengineering projects requiring equipment and space for tissue culture, genetic engineering, biomechanics, and related research. Faculty that is currently using the facility are pursuing groundbreaking biomedical research in such fields as biomedical devices, tissue engineering, obstructive sleep apnea biomechanics also collaborating with several major New York City-based hospitals. The Kanbar Center continues to provide space for undergraduate teams participating in the international genetically engineered competition (iGEM) during the summer, as well as space for courses that offer a biological laboratory component.

1 Comment

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Tam Hunt

July 2, 2018

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Excellent work, guys! I really appreciate this service and hope to get involved with future journal club efforts.

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