UASOM Faculty Profiles


Name	JOHN L. HARTMAN, IV Associate Professor
Campus Address	KAUL 702 Zip 0024
Phone	(205) 996-4195
E-mail	jhartman@uab.edu
Other websites	Research Gate

Undergraduate

Duke University

1989

B.S.

Medical School

University of Alabama at Birmingham

1995

M.D.

Residency

University of Washington

1997

Internal Medicine

Fellowship

University of Washington

2001

Hematology

Fellowship

Fred Hutchinson Cancer Research Center

2004

Yeast Genetics

Internal Medicine

2001

Appointment Type

Department

Division

Rank

Primary

Genetics Research Div

Associate Professor

Secondary

Biochemistry & Molecular Genetics

Associate Professor

Secondary

Med - Hematology & Oncology

Associate Professor

Secondary

Pharmacology/Toxicology Chair's Office

Associate Professor

Center

Comp Arthritis, MSK, Bone & Autoimmunity Ctr

Associate Professor

Center

Comprehensive Cancer Center

Associate Professor

Center

Comprehensive Diabetes Center

Associate Professor

Center

Ctr for Clinical & Translational Sci

Associate Professor

Center

Ctr Neurodegeneration & Exp Ther (CNET)

Associate Professor

Center

Cystic Fibrosis Research Center

Associate Professor

Center

GL Ctr for Craniofacial, Oral, & Dental Disorders

Associate Professor

Center

Integrative Center for Aging Research

Associate Professor

Center

Nutrition Sciences Research

Nutrition Obesity Res Ctr (NORC)

Associate Professor

Biochemistry and Structural Biology

Cancer Biology

Cell, Molecular, & Developmental Biology

Cellular and Molecular Biology Program

Genetics, Genomics and Bioinformatics

Medical Scientist Training Program

Microbiology

Neuroscience

Pathobiology and Molecular Medicine

John Hartman received a B.S. from Duke University in 1989, and an M.D. from UAB in 1995. He completed Internal Medicine Residency and Hematology Fellowship at the University of Washington and Fred Hutchinson Cancer Research Center in Seattle, WA from 1995-2001, where he also conducted postdoctoral research in yeast genetics with Lee Hartwell at the Fred Hutchinson Cancer Research Center. Hartman became a faculty member in the UAB Department of Genetics in 2004, where he has developed yeast genetic approaches for phenomic modeling of human disease and disease complexity. Other prior research experiences as an undergraduate and medical student included working with Max Cooper (UAB, Immunology), George Philips (Duke, Hematology), Eric Sorshcer (UAB, Cystic Fibrosis), and John Northup (NIH, G-protein Signaling). Past awards include Howard Hughes Medical Institute (HHMI) Research Fellowship for Medical Students, HHMI Postdoctoral Fellowship, and HHMI Early Career Award for Physician-Scientists. Hartman has also received support through a K08 Career Development Award from NCI, American Cancer Society Research Scholar Grant, Cystic Fibrosis Foundation Research Grants, and R01 funding from NIA and NHLBI.

Organization Name

Position Held

Org Link

American Assoc. for the Advancement of Science (AAAS)

Member

http://www.aaas.org/

Cancer Molecular Therapeutics Research Association (CMTRA)

Member

http://www.cancermoleculartherapeutics.org/

Genetics Society of America (GSA)

Member

http://www.genetics-gsa.org/

Title
Experimental models of gene interaction networks that buffer human disease using cell array phenotyping of yeast gene knockout libraries
Description
Biological systems are robust, having the capacity to maintain relatively stable phenotypic outputs over a range of perturbing genetic and environmental inputs. Genetic buffering refers to gene activities within a cell that confer phenotypic stability in a particular context. Genetic interactions, defined whenever the phenotype resulting from a chemical or genetic perturbation is dependent upon a particular gene, underlie buffering. Buffering networks are manifest, for example, by chemical sensitivity or synthetic lethality revealed through high throughput phenotyping of yeast gene knockout library . Research in our laboratory is focused on understanding genotype-phenotype complexity through global, quantitative analysis of genetic interactions. Using the powerful model system, S. cerevisiae, we aim to understand the various structures of gene interaction networks that influence different of human diseases. To measure gene interaction globally, we perturb an array of ~5000 isogenic yeast deletion strains, and use cell proliferation as a phenotypic readout to quantify the interacting effects between the perturbation and deletion at each locus. By varying the type and intensity of perturbation, the resulting selectivity and strengths of interaction are determined, revealing the relative buffering specificity of each gene. Using gene annotation and other bioinformatics resources to analyze the quantitative patterns of gene interaction, testable hypotheses are generated to further understand the molecular basis of the observed interaction networks. Genes that interact (exacerbate or compensate) with a known genetic or environmental disease-susceptibility factor can act as disease modifiers, contributing to complex disease traits. Systematic, comprehensive, quantitative understanding of how genetic buffering and cellular robustness are achieved in the highly tractable yeast model system is a strategy for understanding complex genotype-phenotype relationships that may exist generally for eukaryotic cells. The Hartman laboratory has developed novel methodology to globally and quantitatively analyze genetic interactions and is applying them to model genetic buffering networks that modulate disease expression. The yeast homolog of CFTR, YOR1, is used as a model protein to understand different gene modifier networks relevant to cystic fibrosis. The chronological lifespan model is used to characterize factors regulating cell cycle exit and quiescence. The approach is also employed to gain a deeper understanding of the genetic factors that potentially influence the response of cancer to cytotoxic chemotherapy.

Publication	PUBMEDID
Enriquez-Hesles E, Smith, DL, Maqani N, Wierman MB, Sutcliffe MD, Fine RD, Kalita A, Santos SM, Muehlbauer MJ, Bain JR, Janes KA, Hartman 4th JL, Hirschey MD, Smith JS. A cell non-autonomous mechanism of yeast chronological aging regulated by caloric restriction and one-carbon metabolism. J Biol Chem 2021;Jan-Jun;296:100125. doi: 10.1074/jbc.RA120.015402.	33243834
Santos SM, Laflin S, Broadway A, Burnet C, Hartheimer J, Rodgers J, Smith DL Jr, Hartman JL 4th. High-resolution yeast quiescence profiling in human-like media reveals complex influences of auxotrophy and nutrient availability. Geroscience 2021 Apr;43(2):941-964. doi: 10.1007/s11357-020-00265-2.	33015753
Spurlock B, Tullet J, Hartman JL 4th, Mitra K. Interplay of mitochondrial fission-fusion with cell cycle regulation: Possible impacts on stem cell and organismal aging. Exp Gerontol. 2020 Jul 1;135:110919. doi: 10.1016/j.exger.2020.110919.	32220593
Slowing ribosome velocity restores folding and function of mutant CFTR. Oliver KE, Rauscher R, Mijnders M, Wang W, Wolpert MJ, Maya J, Sabusap CM, Kesterson RA, Kirk KL, Rab A, Braakman I, Hong JS, Hartman JL 4th, Ignatova Z, Sorscher EJ. J Clin Invest. 2019 Dec 2;129(12):5236-5253. doi: 10.1172/JCI124282.	31657788
Santos SM, Icyuz M, Pound I, William D, Guo J, McKinney BA, Niederweis M, Rodgers J, Hartman JL IV. A Humanized Yeast Phenomic Model of Deoxycytidine Kinase to Predict Genetic Buffering of Nucleoside Analog Cytotoxicity. Genes (Basel). 2019 Sep 30;10(10):770. doi: 10.3390/genes10100770	31575041
A yeast phenomic model for the influence of Warburg metabolism on genetic buffering of doxorubicin. Santos SM, Hartman JL 4th. Cancer Metab. 2019 Oct 23;7:9. doi: 10.1186/s40170-019-0201-3. eCollection 2019.	31660150
Smith DL Jr, Maharrey CH, Carey CR, White RA, Hartman JL 4th. Gene-nutrient interaction markedly influences yeast chronological lifespan. Exp Gerontol. 2016 Dec 15;86:113-123.	27125759
Veit G, Oliver K, Apaja PM, Perdomo D, Bidaud-Meynard A, Lin ST, Guo J, Icyuz M, Sorscher EJ, Hartman IV JL, Lukacs GL. Ribosomal Stalk Protein Silencing Partially Corrects the DeltaF508-CFTR Functional Expression Defect. PLoS Biol 2016, 14:e1002462. doi: 10.1371/journal.pbio.1002462.	27168400
Wei S, Roessler BC, Icyuz M, Chauvet S, Tao B, Hartman JL 4th, Kirk KL. Long-range coupling between the extracellular gates and the intracellular ATP binding domains of multidrug resistance protein pumps and cystic fibrosis transmembrane conductance regulator channels. FASEB J. 2016 Mar;30(3):1247-62.	26606940
Hartman JL 4th, Stisher C, Outlaw DA, Guo J, Shah NA, Tian D, Santos SM, Rodgers JW, White RA. Yeast Phenomics: An Experimental Approach for Modeling Gene Interaction Networks that Buffer Disease. Genes (Basel). 2015 Feb 6;6(1):24-45.	25668739
Rodgers J, Guo J, Hartman IV JL. Phenomic assessment of genetic buffering by kinetic analysis of cell arrays. Methods Mol Biol 2014;1205:187-208.	25213246
Allison DB, Antoine LH, Ballinger SW, Bamman MM, Biga P, Darley-Usmar VM, Fisher G, Gohlke JM, Halade GV, Hartman IV JL, Hunter GR, Messina JL, Nagy TR, Plaisance EP, Powell ML, Roth KA, Sandel MW, Schwartz TS, Smith DL, Sweatt JD, Tollefsbol TO, Watts SA, Yang Y, Zhang J, Austad SN. Aging and energetics' 'Top 40' future research opportunities 2010-2013. F1000Research 2014;3:219.	25324965
Wei S, Roessler BC, Chauvet S, Guo J, Hartman IV JL, Kirk KL. Conserved Allosteric Hot Spots in the Transmembrane Domains of Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) Channels and Multidrug Resistance Protein (MRP) Pumps. J Biol Chem 2014;289:19942-57.	24876383
Zhang Y, Anderson SJ, French SL, Sikes ML, Viktorovskaya OV, Huband J, Holcomb K, Hartman IV JL, Beyer AL, Schneider DA. The SWI/SNF Chromatin Remodeling Complex Influences Transcription by RNA Polymerase I in Saccharomyces cerevisiae. PloS one 2013;8:e56793.	23437238
Louie RJ, Guo J, Rodgers JW, White R, Shah N, Pagant S, Kim P, Livstone M, Dolinski K, McKinney BA, Hong J, Sorscher EJ, Bryan J, Miller EA, Hartman IV JL. A yeast phenomic model for the gene interaction network modulating F508del-CFTR protein biogenesis. Genome Med 2012;4:103.	23270647
Guo J, Tian D, McKinney BA, Hartman IV JL. Recursive expectation-maximization clustering: a method for identifying buffering mechanisms composed of phenomic modules. Chaos 2010;20:026103.	20590332
Copic A, Dorrington M, Pagant S, Barry J, Lee MC, Singh I, Hartman IV JL, Miller EA. Genomewide analysis reveals novel pathways affecting endoplasmic reticulum homeostasis, protein modification and quality control. Genetics 2009;182:757-69.	19433630
Singh I, Pass R, Togay SO, Rodgers JW, Hartman IV JL. Stringent Mating-Type-Regulated Auxotrophy Increases the Accuracy of Systematic Genetic Interaction Screens with Saccharomyces cerevisiae Mutant Arrays. Genetics 2009;181:289-300.	18957706
Mani R, St Onge RP, Hartman IV JL, Giaever G, Roth FP. Defining genetic interaction. Proc Natl Acad Sci U S A 2008;105:3461-6.	18305163
Shah NA, Laws RJ, Wardman B, Zhao LP, Hartman IV JL. Accurate, precise modeling of cell proliferation kinetics from time-lapse imaging and automated image analysis of agar yeast culture arrays. BMC Syst Biol 2007;1:3.	17408510
Hartman IV JL. Buffering of deoxyribonucleotide pool homeostasis by threonine metabolism. Proc Natl Acad Sci U S A 2007;104:11700-5.	17606896
Hartman IV JL, Tippery NP. Systematic quantification of gene interactions by phenotypic array analysis. Genome Biol 2004;5:R49.	15239834
Hartman IV JL, Garvik B, Hartwell L. Principles for the buffering of genetic variation. Science 2001;291:1001-4.	11232561

yeast genetics, quantitative high throughput cell array phenotyping (Q-HTCP), gene interaction networks, cellular quiescence, aging, cystic fibrosis, chemotherapy response, systems biology, drug discovery, lab automation