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Diane Barber

From Wikipedia, the free encyclopedia
Diane L. Barber
Born
California, U.S.
EducationB.S., M.S., University of California, Davis
Ph.D., University of California, Los Angeles
SpouseA. Richard Ellis (1984-present)
Scientific career
FieldsCell Biology
InstitutionsUniversity of California, San Francisco
Websitedbarberlab.ucsf.edu

Diane L. Barber (born 1952) is an American cell biologist. She is an Endowed Professor and Chair of the Department of Cell and Tissue Biology at University of California, San Francisco (UCSF) and an elected American Association for the Advancement of Science fellow in recognition of her "distinguished contributions on cell signaling by plasma membrane ion transport proteins and on the design and function of proteins regulated by intracellular pH dynamics."[1][2] In addition to teaching graduate and professional students and her administrative service, she directs a research laboratory funded by grants from the National Institutes of Health (NIH) and the National Science Foundation (NSF).

Early life and education

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Barber was born and raised in Bakersfield, California. Her father, Leo Barber (Berberian), and mother, Helen Barber (nee Garabedian), were first-generation Armenian Americans whose families emigrated from the Anatolia region of Eastern Turkey; Karput and Diyarbakir, respectively.[3] She earned a BS in Biological Sciences in 1975 and MS in Physiology in 1977 from the University of California, Davis, followed by a PhD in Anatomy under Andrew Soll and John Walsh in 1985 in the Centre for Ulcer Research and Education at the University of California, Los Angeles. Supported by a National Research Service Award fellowship from the NIH, she completed her postdoctoral work under Susan Leeman in the Department of Physiology at the University of Massachusetts Medical Center in Worcester, MA. Her first faculty appointment was as an Assistant Professor at Yale University in the Department of Surgery, Section of Anatomy between 1987-1991. She joined the faculty in the Department of Stomatology and Surgery at the University of California, San Francisco in 1992. She is currently a Professor and former Chair of the Department of Cell and Tissue Biology at the University of California, San Francisco.[4]

Research

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A major aspect of Barber's research is determining in molecular detail how intracellular pH (pHi) dynamics regulate cell behaviors, with a focus on epithelial plasticity, including transformed cancer cells, and stem cell differentiation. Barber addresses questions on how signaling networks[5] and the actin cytoskeleton[6] control normal and pathological cell behavior, particularly the post-translational modifications of proteins by protonation[7] and by phosphorylation.[8] Her research bridges protein structure and electrostatics with cell biology to reveal how pHi dynamics regulate cell behaviors though protonation of titrating amino acids as a post-translational modification to affect protein structure and function. Her group revealed design principles and functions of "pH sensors" described as endogenous proteins regulated within the cellular pH range, which they showed have critical roles in cell division, migration, and tumorigenesis. Additionally work from her group showed how increased pHi is necessary for adult and embryonic stem cell differentiation. Through their work, Barber's research group developed new genetically-encoded biosensors to quantitatively measure cytoplasmic and lysosome pH dynamics in clonal cells and animals. Collectively, Barber's work is highlighted by an h-index of 46 for her group's publications and her election as a fellow for the American Association for the Advancement of Science (AAAS), and being the plenary or keynote speaker at multiple international and national scientific conferences.

Cancer cell biology

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One focus of her research is on cancer cell biology, specifically in regards to the pHi (intracellular pH) of cancer cells., which is increased in comparison to normal cells. The research focuses on the relationship between the increased pHi and their ability to perform necessary functions. The laboratory group showed in molecular detail how it is necessary for the directed cell migration for metastasis. This was accomplished through the use of selective pH sensors that defined how proteins were regulated by cellular changes in pH. The group subsequently worked on the effect of increased pHi on the glycolytic enzymes necessary for metabolic programming, somatic mutation biology, and tumorigenic behaviors. The research uses optogenetic tools to control the pHi of the cells, biosensors that are genetically encoded to quantify the pHi of single cancer cells as well as cells in vivo, and computational programming to identify ionizable residues in proteins and amino acid mutation signatures that are present in numerous cancer databases.[9][10]

Stem cell differentiation

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The second focus of Barber's laboratory is in stem cell differentiation, in collaboration with the laboratory of Todd Nystul. The group studies how intracellular pH and actin filament dynamics regulate stem cell differentiation. Through their work, the group has been able to show that daughter cells have a higher pHi than naive adult and embryonic stem cells that is necessary for their differentiation. Additionally, the laboratory studies how actin filament remodeling is necessary for the differentiation of naive embryonic stem cells. The current focus is on the transcriptional events linked to these actin dynamics.[9][10]

Neurodegeneration

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The final main focus of her research is on neurodegeneration, as part of a 4-lab collaboration with the groups of Aimee Kao, Matt Jacobson, and Torsten Wittman. The main focus of this area is to identify the dysregulated cellular pH dynamics that results in the pathology associated Alzheimer's disease. The laboratory is focused on reversing the decreased intracellular pH and increased lysosomal pH that is commonly associated with neurodegeneration.[9][10][11] This team recently received one of five Allen Distinguished Investigator (ADI) grants of $1.32 million.[12][13]

Leadership and mentoring

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Barber has been a long-standing member of the Women in Cell Biology (WICB)[6] committee within the American Society for Cell Biology (ASCB) and served as chair of the committee from 2016-2019.[14] She was also co-chair and chair of Gordon Research Conferences on Molecular Pharmacology, and currently serves on the Scientific Advisory Board of the Max Planck Institute for Experimental Medicine[7] as well as on editorial boards for several journals, including Molecular Biology of the Cell, the American Journal of Physiology – Cell Physiology, and BMC Biology. She has supervised more than 35 PhD students and postdoctoral fellows, and her mentoring and research excellence has been recognized by her receipt of the Annual Faculty Mentoring Award in 2013 from the UCSF Postdoctoral Scholars Association, of the Annual Faculty Research and Mentoring Award in 2020 from the UCSF John Greene Society of Dental Students,[15] and the Annual Faculty Lecture in Translational Science from the UCSF Academic Senate.[16] For the past several years, Barber has traveled to Yerevan, Armenia to co-teach a week-long cell biology course at the Institute of Molecular Biology.[17]

Personal life

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Barber lives in Mill Valley, CA with her husband Richard Ellis, who is a criminal defense attorney specializing in capital habeas. They have two daughters, Claire Ellis Olson, an industry bioinformatics analyst in Seattle, WA, and Lauren Ellis, an attorney in the Los Angeles County Public Defender's Office, as well as two grandchildren. With her husband, she has been a coach for Special Olympics Swimming in Marin County for 16 years.

Selected publications

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Research articles

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  • Denker, SP. Huang, DC, Orlowski, J, Furthmayr, H and Barber, DL. 2000 Direct binding the Na-H exchanger NHE1 to ERM proteins regulates the cortical cytoskeleton and cell shape independently of H+ translocation. Mol Cell 6:1425-1436. (Cited in > 350 publications). PMID 11163215
  • Denker, SP and Barber, DL.  2002 Cell migration requires both ion translocation and cytoskeletal anchoring by the Na-H exchanger NHE1. J Cell Biol. 159:1087-1096. (Highlighted in Journal [Using acid to find direction. J Cell Biol. 2002 159:911]) (Cited in > 340 publications) PMID 12486114
  • Frantz, C, Barreiro, G, Dominguez, L, Chen, X, Eddy, R, Condeelis, J, Kelly, M, Jacobson, MP and Barber, DL. 2008 Cofilin is a pH sensor for actin free barbed end formation. J Cell Biol. 183:865-879 (Highlighted in Journal and cited in > 150 publications) PMID 19029335
  • Srivastava, J, Barreiro, G, Groscurth, S, Gringas, AR, Goult, BT Critchley, DR, Kelly, MJS, Jacobson. MP and Barber, DL. 2008 Structural model and functional significance of pH-dependent talin-actin binding for focal adhesion remodeling. Proc Natl Acad Sci. 105:14436-14441. (Cited in > 90 publications) PMID 18780792
  • LeClaire, LL III, Baumgartner, M, Iwasa, JH, Mullins, RD and Barber, DL. 2008 Phosphorylation of the Arp2/3 complex is necessary to nucleate actin filaments. J Cell Biol. 182:647-654. (Highlighted commentary in Journal 182:617) (Cited in > 55 publications) PMID 22125478
  • Webb, BE, Chimenti, M, Jacobson, MP, Barber, D.L. 2011 Dysregulated pH: a perfect storm for cancer progression. Nature Cancer Rev. 11:671-677. (Cited in > 1200 publications)
  • Choi, CC, Webb, BA, Chimenti, MS, Jacobson, MP and Barber, DL. 2013 pH sensing by FAK-His58 regulates focal adhesion remodeling. J Cell Biol. 202:849-59. (Commentaries:  C. Lawson and D. D. Schlaepfer, "pHocal adhesion kinase regulation is on a FERM foundation", J Cell Biol. 202:833-836 and K. Legg, "Factoring pH into FAK phosphorylation", Cell Migration Gateway) (Cited in > 70 publications). PMID 24043700
  • Schönichen, A., Webb, B.E., Jacobson, M.P., and Barber, D.L. 2013 Considering protonation as a post-translational modification regulating protein structure and function. Ann Rev Biophys. 2013 42:289-314. (Cited in > 100 publications) PMID 23451893
  • LeClaire, LL, Rana, MK, Baumgartner, M and Barber, DL. 2015 The Nck-interacting kinase NIK increases Arp2/3 complex activity by phosphorylating the Arp2 subunit. J Cell Biol. 208:161-170. (Highlighted commentary in Journal 208:138) PMID 25601402
  • Webb BA, Forouhar F, Szu FE, Seetharaman J, Tong L, Barber DL. 2015 Structures of human   phosphofructokinase-1 and atomic basis of cancer-associated mutations. Nature 523:111-114. (Cited in > 60 publications) PMID 25985179
  • Ulmschneider, B., Grillo-Hill, B.K., Benitez, M., Azimova, D., Barber. D.L., Nystul, T.G. 2016 Increased intracellular pH is necessary for adult epithelial and embryonic stem cell differentiation. J. Cell Biol. 215:345-355 (featured focus article in journal) (Cited in > 60 publications) PMID 27821494
  • Webb BA, Dosey AM, Wittmann T, Kollman J, Barber DL 2017 Filament assembly by the glycolytic enzyme phosphofructokinase-1. J Cell Biol 216:2305-2313. (Spotlight article in Journal “Strength in numbers: Phosphofructokinase polymerization prevails in the liver” J Cell Biol. 216:2239-2241). (Republished in a special J Cell Biol. edition on noteworthy work on cell biophysics) (cited in > 60 publications) PMID 28646105
  • White KA, Grillo-Hill BK, Barber DL. 2017 Cancer cell behaviors mediated by dysregulated pH dynamics at a glance. J Cell Sci. 130(4):663-669. (Cited by > 150 publications) PMID 28202602
  • White, KA, Garrido Ruiz, G, Szpiech, ZA, Strauli, NB, Hernandez, RD, Jacobson, JP and Barber, DL. 2017 Cancer-associated arginine to histidine mutations confer a gain in pH sensing to mutant proteins. Sci. Signaling 10(495). pii: eaam9931. PMID 28874603
  • White, KA, Grillo-Hill, BK, Esquivel, M, Peralta, J, Bui, VN, Chire, I, Barber, DL. 2018. β-catenin is a pH sensor with decreased stability at higher intracellular pH. J Cell Biol. 217:3965-3976. Also included in JCB Special Collection of published outstanding articles on the cell biology of adhesion. PMID 30315137
  • Webb BA, Aloisio FM, Charafeddine RA, Cook J, Wittmann T, and Barber DL. 2021 pHLARE: a new biosensor reveals decreased lysosome pH in cancer cells. Mol Biol Cell. 32:131-142. PMID 33237838
  • Aloisio FM, Barber DL. 2022 Arp2/3 complex activity is necessary for mouse ESC differentiation, times formative pluripotency, and enables lineage specification. Stem Cell Reports. 17(6):1318-1333. PMID 35658973

Awards and memberships

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From 1995 to 2000, Barber was named an Established Investigator by the American Heart Association. From 1998 and continuing into the present day, Barber has been on the editorial board of the American Journal of Physiology. Cell Physiology. From 1998 to 1999, Barber served on the National Review Committee for Transport and Metabolism of the American Heart Association. In 1998, Barber was awarded the Innovation in Basic Sciences Award at the University of California, San Francisco. From 2000 to 2002, Barber was the co-chair of the National Review Committee for Transport and Metabolism for the American Heart Association. In 2001, Barber became the vice-chair of the Gordon Conference on Molecular Pharmacology, and in 2003, she became the chair. Barber was a member of the NIH CDF3 Study Section from 2001 to 2003. In 2005, Barber received the Sandler Program Integrative Award.[18]

In 2012, Barber was selected as a fellow of the American Association for the Advancement of Science (AAAS).[19]

In 2016, Barber was appointed as the chair of Women in Cell Biology (WICB) for the American Society for Cell Biology (ASCB).[20] Her term began on January 1, 2016. She succeeded the last chair, Sandra K. Masur.[21]

Awards and honors

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  1. Excellence in Research and Mentoring, John Greene Society of UCSF Dental Students (2021)[22]
  2. Faculty Lecture in Translational Science, UCSF Academic Senate (2022)[23]

References

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  1. ^ "AAAS fellow". Archived from the original on 2013-03-23. Retrieved 2013-04-22.
  2. ^ UCSF Cancer Center news
  3. ^ "Young Scientists School". molbiol.sci.am. Retrieved 2018-11-27.
  4. ^ Aloisio, Francesca (2016-03-21). "Diversity Spotlight: One on One with Diane Barber". synapse.ucsf.edu. Retrieved 2022-07-19.
  5. ^ "Using acid to find direction".
  6. ^ "Cofilin activity is a total coincidence".
  7. ^ "A polarity/proton loop".
  8. ^ "Arp2/3 phosphorylation kickstarts cells".
  9. ^ a b c "Diane Barber, PhD". Biomedical Sciences Graduate Program. Retrieved 2018-11-26.
  10. ^ a b c "Diane Barber Lab". Diane Barber Laboratory. Retrieved 2018-11-26.
  11. ^ "2020 Catalyst Awardees". Innovation Ventures. Retrieved 2022-07-19.
  12. ^ "ADI Alzheimers Disease Research - Paul G. Allen Philanthropies". www.pgaphilanthropies.org. Retrieved 2018-11-27.
  13. ^ "Researchers Receive Nearly $3M from Allen Family Foundation to Study Alzheimer's Disease | UC San Francisco". www.ucsf.edu. 16 July 2015. Retrieved 2022-07-19.
  14. ^ "Meet UCSF's Women in Discovery Science". Women in Science @UCSF. Retrieved 2022-07-19.
  15. ^ "Student Groups Salute Faculty". dentistry.ucsf.edu. Retrieved 2022-07-19.
  16. ^ "Faculty Research Lecture in Tranlational Science 11th | UCSF Academic Senate". senate.ucsf.edu. Retrieved 2022-07-19.
  17. ^ "Young Scientists School". molbiol.sci.am. Retrieved 2022-07-19.
  18. ^ "Diane L. Barber, PhD | UCSF Helen Diller Family Comprehensive Cancer Center". cancer.ucsf.edu. Retrieved 2018-11-26.
  19. ^ Bole, Kristine (November 29, 2012). "Six UCSF Researchers Named Fellows of National Scientific Society". University of California, San Francisco Helen Diller Family Comprehensive Cancer Center.
  20. ^ "Diane Barber, PhD | UCSF School of Dentistry". dentistry.ucsf.edu. Retrieved 2018-11-26.
  21. ^ "Barber Named Chair of Women in Cell Biology Committee - ASCB". ASCB. 2015-10-30. Retrieved 2018-11-27.
  22. ^ "Student Groups Salute Faculty".
  23. ^ "Faculty Research Lecture in Tranlational Science 11th | UCSF Academic Senate".
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