Paul D Kaufman PHD
Title Professor
Institution University of Massachusetts Medical School
Department Program in Molecular Medicine
Address University of Massachusetts Medical School
 364 Plantation Street, LRB-506
 Worcester MA 01605
Telephone 508-856-5016
Email
Other Positions
Institution UMMS - Graduate School of Biomedical Sciences
Department Interdisciplinary Graduate Program

Institution UMMS - Graduate School of Biomedical Sciences
Department MD/PhD Program

Institution UMMS - Programs, Centers and Institutes
Department Program in Gene Function & Expression
Narrative
 

Academic Background

Paul Kaufman received his A.B. in Biochemistry from the University of California, Berkeley and his Ph.D. in Biology from MIT. He was a postdoctoral fellow at Cold Spring Harbor Laboratory, where he was supported by the Life Sciences Research Foundation. He went on to become a Career Staff Scientist at the Lawrence Berkeley National Laboratory and Associate Adjunct Professor of Biochemistry and Molecular Biology at the University of California, Berkeley. Dr. Kaufman joined the Program in Gene Function and Expression at the University of Massachusetts Medical School as an Associate Professor in 2005 and was promoted to Full Professor in 2011.



Assembly and Function of Eukaryotic Chromosomes

Photo: Paul D. Kaufman, Ph.D.We study several different classes of chromatin proteins used by eukaryotic cells to regulate gene expression and chromosome structure. We study these processes in the pathogenic yeast Candida albicans and in human cells, using biochemical, genetic, genomic, and cell biological techniques.

Current Projects

Introduction

In eukaryotes, DNA is assembled into a nucleoprotein complex called chromatin. The fundamental repeating unit of chromatin is the nucleosome, which consists of 146 bp of DNA wrapped around an octamer of core histone proteins, comprised of two H2A/H2B dimers flanking an inner (H3/H4)2 tetramer. In addition to their role in compacting the genome and occluding access to trans-acting proteins, core histone proteins affect all aspects of chromosome function via a wide variety of post-translational modifications.

We are investigating several aspects of chromatin biology. First, we are using our expertise with a fungal histone acetyltransferase enzyme to search for novel candidate antifungal compounds. Second, we are exploring how the transcriptional and spatial regulation of repetitive DNA in human cells is regulated.

Histone H3-K56 acetylation by the fungal-specific enzyme Rtt109 is required for fungal pathogenesis

In fungal cells, histone H3 lysine 56 is quantitatively acetylated on newly synthesized molecules by an enzyme termed Rtt109. H3-K56 acetylation promotes subsequent deposition onto DNA and is required for normal rates of histone turnover. Notably, cells lacking H3-K56 acetylation are very sensitive to genotoxic agents, including DNA alkylating chemicals and hydrogen peroxide. An important feature of this pathway is that it is fungal-specific; in other eukaryotes, H3-K56 acetylation is much less abundant than in fungal cells, and its biological role is not clear. Further, there is no close mammalian homolog of Rtt109; although the p300 enzyme is a distant relative, it is distinct in its active site properties and in its mechanism.

An important way that mammals fight off fungal pathogens is via phaogcytic engulfment and attack with reactive oxygen species. We therefore reasoned that fungal cells that lack H3-K56 acetylation would be poor pathogens because they would be killed more easily by phagocytic cells such as macrophages. We tested this idea in Candida albicans, the most prevalent fungal pathogen of humans (Lopes da Rosa et al., PNAS 2010). Indeed, C. albicans cells lacking Rtt109 are much less lethal to mice upon systemic infection of the bloodstream. Further, these cells are more easily killed by macrophages, in a manner that depends on generation of reactive oxygen species. Because Rtt109 lacks close mammalian homologs, we concluded that Rtt109 is a good candidate target for novel antifungal therapeutics.

In collaboration with the Broad Institute as part of the NIH Molecular Libraries Program, we have screened over 300,000 small molecules in an in vitro assay for histone acetylation by Rtt109. Characterization of candidate inhibitors is in progress.

Regulation of human repetitive DNA by chromatin proteins and remodeling enzymes

We are exploring how human nucleosome remodeling enzymes and other chromatin proteins regulate the transcriptional output and three-dimensional organization of repetitive elements in the genome. These studies are facilitated by our development of a versatile family of retroviral and lentiviral vectors for protein overexpression and depletion, and by the microscopy, high throughput sequencing and bioinformatics resources at UMMS.

 
Publications
1. Lopes da Rosa J, Bajaj V, Spoonamore J, Kaufman PD. A small molecule inhibitor of fungal histone acetyltransferase Rtt109. Bioorg Med Chem Lett. 2013 May 15; 23(10):2853-9.
  View in: PubMed
 
2. Lopes da Rosa J, Kaufman PD. Chromatin-mediated Candida albicans virulence. Biochim Biophys Acta. 2012 Mar; 1819(3-4):349-55.
  View in: PubMed
 
3. Kaufman PD. New Partners for HP1 in Transcriptional Gene Silencing. Mol Cell. 2011 Jan 7; 41(1):1-2.
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4. Kaufman PD. Toxicity and lifespan extension: complex outcomes of histone overexpression in budding yeast. Cell Cycle. 2010 Dec 1; 9(23):4611-2.
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5. Kolonko EM, Albaugh BN, Lindner SE, Chen Y, Satyshur KA, Arnold KM, Kaufman PD, Keck JL, Denu JM. Catalytic activation of histone acetyltransferase Rtt109 by a histone chaperone. Proc Natl Acad Sci U S A. 2010 Nov 23; 107(47):20275-80.
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6. Rosa JL, Holik J, Green EM, Rando OJ, Kaufman PD. Overlapping Regulation of CenH3 Localization and Histone H3 Turnover by CAF-1 and HIR Proteins in Saccharomyces cerevisiae. Genetics. 2011 Jan; 187(1):9-19.
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7. Miller A, Chen J, Takasuka TE, Jacobi JL, Kaufman PD, Irudayaraj JM, Kirchmaier AL. Proliferating cell nuclear antigen (PCNA) is required for cell cycle-regulated silent chromatin on replicated and nonreplicated genes. J Biol Chem. 2010 Nov 5; 285(45):35142-54.
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8. Kaufman PD, Rando OJ. Chromatin as a potential carrier of heritable information. Curr Opin Cell Biol. 2010 Jun; 22(3):284-90.
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9. Lopes da Rosa J, Boyartchuk VL, Zhu LJ, Kaufman PD. Histone acetyltransferase Rtt109 is required for Candida albicans pathogenesis. Proc Natl Acad Sci U S A. 2010 Jan 26; 107(4):1594-9.
  View in: PubMed
 
10. Erkmann JA, Kaufman PD. A negatively charged residue in place of histone H3K56 supports chromatin assembly factor association but not genotoxic stress resistance. DNA Repair (Amst). 2009 Dec 3; 8(12):1371-9.
  View in: PubMed
 
11. Campeau E, Ruhl VE, Rodier F, Smith CL, Rahmberg BL, Fuss JO, Campisi J, Yaswen P, Cooper PK, Kaufman PD. A versatile viral system for expression and depletion of proteins in mammalian cells. PLoS One. 2009; 4(8):e6529.
  View in: PubMed
 
12. Kaplan T, Liu CL, Erkmann JA, Holik J, Grunstein M, Kaufman PD, Friedman N, Rando OJ. Cell cycle- and chaperone-mediated regulation of H3K56ac incorporation in yeast. PLoS Genet. 2008 Nov; 4(11):e1000270.
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13. Berndsen CE, Tsubota T, Lindner SE, Lee S, Holton JM, Kaufman PD, Keck JL, Denu JM. Molecular functions of the histone acetyltransferase chaperone complex Rtt109-Vps75. Nat Struct Mol Biol. 2008 Sep; 15(9):948-56.
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14. Tsubota T, Berndsen CE, Erkmann JA, Smith CL, Yang L, Freitas MA, Denu JM, Kaufman PD. Histone H3-K56 acetylation is catalyzed by histone chaperone-dependent complexes. Mol Cell. 2007 Mar 9; 25(5):703-12.
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15. Antczak AJ, Tsubota T, Kaufman PD, Berger JM. Structure of the yeast histone H3-ASF1 interaction: implications for chaperone mechanism, species-specific interactions, and epigenetics. BMC Struct Biol. 2006; 6:26.
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16. Recht J, Tsubota T, Tanny JC, Diaz RL, Berger JM, Zhang X, Garcia BA, Shabanowitz J, Burlingame AL, Hunt DF, Kaufman PD, Allis CD. Histone chaperone Asf1 is required for histone H3 lysine 56 acetylation, a modification associated with S phase in mitosis and meiosis. Proc Natl Acad Sci U S A. 2006 May 2; 103(18):6988-93.
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17. Green EM, Antczak AJ, Bailey AO, Franco AA, Wu KJ, Yates JR, Kaufman PD. Replication-independent histone deposition by the HIR complex and Asf1. Curr Biol. 2005 Nov 22; 15(22):2044-9.
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18. Sharp JA, Rizki G, Kaufman PD. Regulation of histone deposition proteins Asf1/Hir1 by multiple DNA damage checkpoint kinases in Saccharomyces cerevisiae. Genetics. 2005 Nov; 171(3):885-99.
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19. Franco AA, Lam WM, Burgers PM, Kaufman PD. Histone deposition protein Asf1 maintains DNA replisome integrity and interacts with replication factor C. Genes Dev. 2005 Jun 1; 19(11):1365-75.
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20. Zhang R, Poustovoitov MV, Ye X, Santos HA, Chen W, Daganzo SM, Erzberger JP, Serebriiskii IG, Canutescu AA, Dunbrack RL, Pehrson JR, Berger JM, Kaufman PD, Adams PD. Formation of MacroH2A-containing senescence-associated heterochromatin foci and senescence driven by ASF1a and HIRA. Dev Cell. 2005 Jan; 8(1):19-30.
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21. Franco AA, Kaufman PD. Histone deposition proteins: links between the DNA replication machinery and epigenetic gene silencing. Cold Spring Harb Symp Quant Biol. 2004; 69:201-8.
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22. Daganzo SM, Erzberger JP, Lam WM, Skordalakes E, Zhang R, Franco AA, Brill SJ, Adams PD, Berger JM, Kaufman PD. Structure and function of the conserved core of histone deposition protein Asf1. Curr Biol. 2003 Dec 16; 13(24):2148-58.
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23. Sharp JA, Krawitz DC, Gardner KA, Fox CA, Kaufman PD. The budding yeast silencing protein Sir1 is a functional component of centromeric chromatin. Genes Dev. 2003 Oct 1; 17(19):2356-61.
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24. Sutton A, Shia WJ, Band D, Kaufman PD, Osada S, Workman JL, Sternglanz R. Sas4 and Sas5 are required for the histone acetyltransferase activity of Sas2 in the SAS complex. J Biol Chem. 2003 May 9; 278(19):16887-92.
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25. Ye X, Franco AA, Santos H, Nelson DM, Kaufman PD, Adams PD. Defective S phase chromatin assembly causes DNA damage, activation of the S phase checkpoint, and S phase arrest. Mol Cell. 2003 Feb; 11(2):341-51.
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26. Sharp JA, Kaufman PD. Chromatin proteins are determinants of centromere function. Curr Top Microbiol Immunol. 2003; 274:23-52.
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27. Formosa T, Ruone S, Adams MD, Olsen AE, Eriksson P, Yu Y, Rhoades AR, Kaufman PD, Stillman DJ. Defects in SPT16 or POB3 (yFACT) in Saccharomyces cerevisiae cause dependence on the Hir/Hpc pathway: polymerase passage may degrade chromatin structure. Genetics. 2002 Dec; 162(4):1557-71.
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28. Krawitz DC, Kama T, Kaufman PD. Chromatin assembly factor I mutants defective for PCNA binding require Asf1/Hir proteins for silencing. Mol Cell Biol. 2002 Jan; 22(2):614-25.
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29. Sharp JA, Franco AA, Osley MA, Kaufman PD. Chromatin assembly factor I and Hir proteins contribute to building functional kinetochores in S. cerevisiae. Genes Dev. 2002 Jan 1; 16(1):85-100.
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30. Sharp JA, Fouts ET, Krawitz DC, Kaufman PD. Yeast histone deposition protein Asf1p requires Hir proteins and PCNA for heterochromatic silencing. Curr Biol. 2001 Apr 3; 11(7):463-73.
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31. Game JC, Kaufman PD. Role of Saccharomyces cerevisiae chromatin assembly factor-I in repair of ultraviolet radiation damage in vivo. Genetics. 1999 Feb; 151(2):485-97.
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32. Kaufman PD, Cohen JL, Osley MA. Hir proteins are required for position-dependent gene silencing in Saccharomyces cerevisiae in the absence of chromatin assembly factor I. Mol Cell Biol. 1998 Aug; 18(8):4793-806.
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33. Verreault A, Kaufman PD, Kobayashi R, Stillman B. Nucleosomal DNA regulates the core-histone-binding subunit of the human Hat1 acetyltransferase. Curr Biol. 1998 Jan 15; 8(2):96-108.
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34. Kaufman PD, Kobayashi R, Stillman B. Ultraviolet radiation sensitivity and reduction of telomeric silencing in Saccharomyces cerevisiae cells lacking chromatin assembly factor-I. Genes Dev. 1997 Feb 1; 11(3):345-57.
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35. Verreault A, Kaufman PD, Kobayashi R, Stillman B. Nucleosome assembly by a complex of CAF-1 and acetylated histones H3/H4. Cell. 1996 Oct 4; 87(1):95-104.
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36. Gaillard PH, Martini EM, Kaufman PD, Stillman B, Moustacchi E, Almouzni G. Chromatin assembly coupled to DNA repair: a new role for chromatin assembly factor I. Cell. 1996 Sep 20; 86(6):887-96.
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37. Kaufman PD. Nucleosome assembly: the CAF and the HAT. Curr Opin Cell Biol. 1996 Jun; 8(3):369-73.
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38. Kamakaka RT, Bulger M, Kaufman PD, Stillman B, Kadonaga JT. Postreplicative chromatin assembly by Drosophila and human chromatin assembly factor 1. Mol Cell Biol. 1996 Mar; 16(3):810-7.
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39. Kaufman PD, Kobayashi R, Kessler N, Stillman B. The p150 and p60 subunits of chromatin assembly factor I: a molecular link between newly synthesized histones and DNA replication. Cell. 1995 Jun 30; 81(7):1105-14.
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40. Kamakaka RT, Kaufman PD, Stillman B, Mitsis PG, Kadonaga JT. Simian virus 40 origin- and T-antigen-dependent DNA replication with Drosophila factors in vitro. Mol Cell Biol. 1994 Aug; 14(8):5114-22.
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41. Kaufman PD, Rio DC. Drosophila P-element transposase is a transcriptional repressor in vitro. Proc Natl Acad Sci U S A. 1991 Apr 1; 88(7):2613-7.
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42. Kaufman PD, Doll RF, Rio DC. Drosophila P element transposase recognizes internal P element DNA sequences. Cell. 1989 Oct 20; 59(2):359-71.
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