University of California San Francisco

Koh, James - 144
James Koh, PhD

Professor of Surgery
Division of Surgical Oncology
Director, Endocrine Neoplasia Research Lab

Address

513 Parnassus Avenue, HSE, #563
San Francisco, CA 94143
United States

Email: [email protected]
Phone: 415-514-9648
Fax: 415-476-8694

Biography

James Koh, Ph.D., is an Associate Professor of Surgery at UCSF and Director of the newly established Endocrine Neoplasia Research Lab. He earned his doctorate under the direction of Dr. Francis S. Collins at the University of Michigan, Ann Arbor, and then completed a post-doctoral fellowship in Dr. Ed Harlow's laboratory at Harvard University. Dr. Koh joined the UCSF faculty in December 2018.

Building upon his background in cellular signaling, cell cycle regulation, and tumor suppressor function, Dr. Koh's laboratory has developed a combination of molecular, murine modeling, and live-cell imaging approaches to examine the underlying mechanisms of disrupted biochemical signaling behavior in human endocrine tumors.

Recently, Dr. Koh and his research team utilized live tumor tissue functional analysis of calcium responsiveness to reveal two discrete classes of human parathyroid adenomas associated with differing patterns of clinical presentation and outcome. Towards the goal of establishing a novel dynamic functional axis of diagnostic criteria to supplement conventional tumor classification metrics, Dr. Koh will focus on the development of live-cell imaging methods for direct ex vivo provocative testing of endocrine tumor reactivity to physiological agonist engagement at single cell resolution.

 

Education

Institution Degree Dept or School End Date
University of California Diversity, Equity, and Inclusion Champion Training 2019
Harvard University Postdoctoral Fellowship 1997
University of Michigan Ph.D. Human Genetics 1994
University of Michigan M.S. Human Genetics 1988
University of North Carolina BA Zoology/Classics 1983
Phillips Exeter Academy 1979

Grants and Funding

  • Understanding MEN4: Improved screening and functional assessment | Mental Insight Foundation | 2024-01-01 - 2026-12-31 | Role: Principal Investigator
  • Vitamin D and beta-amyloid signaling in hyperparathyroidism | NIH | 2023-04-15 - 2026-03-31 | Role: Principal Investigator
  • Pancreatic islet and parathyroid co-transplantation for treatment of diabetes in intramuscular sites | California Institute of Regenerative Medicine | 2019-07-01 - 2023-06-30 | Role: Co-Investigator
  • Regulation of parathyroid function by the amyloid precursor protein | NIH | 2021-05-01 - 2023-01-31 | Role: Principal Investigator
  • Spatial profiling of scRNAseq signatures in human parathyroid glands | Hypopara Foundation | 2021-04-01 - 2022-03-31 | Role: Co-PI
  • Single cell analysis of intratumoral heterogeneity in parathyroid neoplasia | NIH | 2015-01-16 - 2017-02-28 | Role: Principal Investigator
  • Molecular Mechanisms of Altered Calcium Sensing in Human Parathyroid Disease | NIH | 2010-06-01 - 2016-05-31 | Role: Co-Principal Investigator

Research Narrative

The Endocrine Neoplasia Research Lab employs a combination of molecular, murine modeling, and live-cell imaging approaches to examine the underlying mechanisms of disrupted biochemical sensing behaviors in human endocrine tumors. Recently, in contrast to the prevailing clonal origin model, our group has shown that parathyroid adenomas driving primary hyperparathyroidism are comprised of functionally discrete and separable cellular subpopulations that respond differentially to extracellular calcium stimulation and which arise in many cases following polyclonal expansion of multiple independent progenitor cells within the parathyroid gland.

We are employing dynamic calcium response imaging at both the single cell and intact tissue level, in combination with transgenic mouse modeling to study how these newly identified cellular subpopulations drive the failure of appropriate calcium sensing in parathyroid disease. To examine cell-signaling behaviors in the native context of viable tumor tissue, we have developed a novel ex vivo imaging system that enables direct provocative testing of tumor reactivity to physiological agonist engagement at single-cell resolution. These methods form the foundation for our laboratory’s ongoing efforts to understand how perturbed biochemical signaling can contribute to the development of preneoplastic lesions in human endocrine neoplasia.

Research Interests

Parathyroid tumors

Neoplastic transformation

Live-cell imaging

Primary hyperparathyroidism

Endocrine cell signaling, differentiation, and development

Single cell functional and genomic analysis

 

 

Research Pathways

Basic Biomedical & Translational Research

Publications

MOST RECENT PUBLICATIONS FROM A TOTAL OF 15
  1. Digital spatial profiling of human parathyroid tumors reveals cellular and molecular alterations linked to vitamin D deficiency.
    Tu CL, Chang W, Sosa JA, Koh J| | PubMed
  2. Effects of Multi-stage Procurement on the Viability and Function of Human Donor Parathyroid Glands.
    Kelly YM, Ward C, Zhang R, Syed S, Stock PG, Duh QY, Sosa JA, Koh J| | PubMed
  3. Ex Vivo Intact Tissue Analysis Reveals Alternative Calcium-sensing Behaviors in Parathyroid Adenomas.
    Koh J, Zhang R, Roman S, Duh QY, Gosnell J, Shen W, Suh I, Sosa JA| | PubMed
  4. Parathyroid-Targeted Overexpression of Regulator of G-Protein Signaling 5 (RGS5) Causes Hyperparathyroidism in Transgenic Mice.
    Balenga N, Koh J, Azimzadeh P, Hogue J, Gabr M, Stains JP, Olson JA| | PubMed
  5. Transcriptional profiling reveals distinct classes of parathyroid tumors in PHPT.
    Koh J, Hogue JA, Roman SA, Scheri RP, Fradin H, Corcoran DL, Sosa JA| | PubMed
  6. Polyclonal origin of parathyroid tumors is common and is associated with multiple gland disease in primary hyperparathyroidism.
    Shi Y, Azimzadeh P, Jamingal S, Wentworth S, Ferlitch J, Koh J, Balenga N, Olson JA| | PubMed
  7. Live-Cell Visualization of Calcium Flux in Vibratome-Cut Thick Sections of Viable Tumor Tissue.
    Koh J, Hogue JA, Sosa JA| | PubMed
  8. Impaired calcium sensing distinguishes primary hyperparathyroidism (PHPT) patients with low bone mineral density.
    Weber TJ, Koh J, Thomas SM, Hogue JA, Scheri RP, Roman SA, Sosa JA| | PubMed
  9. Orphan Adhesion GPCR GPR64/ADGRG2 Is Overexpressed in Parathyroid Tumors and Attenuates Calcium-Sensing Receptor-Mediated Signaling.
    Balenga N, Azimzadeh P, Hogue JA, Staats PN, Shi Y, Koh J, Dressman H, Olson JA| | PubMed
  10. A Novel Ex Vivo Method for Visualizing Live-Cell Calcium Response Behavior in Intact Human Tumors.
    Koh J, Hogue JA, Sosa JA| | PubMed
  11. Single-cell approaches for molecular classification of endocrine tumors.
    Koh J, Allbritton NL, Sosa JA| | PubMed
  12. Single-cell functional analysis of parathyroid adenomas reveals distinct classes of calcium sensing behaviour in primary hyperparathyroidism.
    Koh J, Hogue JA, Wang Y, DiSalvo M, Allbritton NL, Shi Y, Olson JA, Sosa JA| | PubMed
  13. Functional and genetic studies of isolated cells from parathyroid tumors reveal the complex pathogenesis of parathyroid neoplasia.
    Shi Y, Hogue J, Dixit D, Koh J, Olson JA| | PubMed
  14. Regulator of G protein signaling 5 is highly expressed in parathyroid tumors and inhibits signaling by the calcium-sensing receptor.
    Koh J, Dar M, Untch BR, Dixit D, Shi Y, Yang Z, Adam MA, Dressman H, Wang X, Gesty-Palmer D, Marks JR, Spurney R, Druey KM, Olson JA| | PubMed
  15. Severe obesity is associated with symptomatic presentation, higher parathyroid hormone levels, and increased gland weight in primary hyperparathyroidism.
    Adam MA, Untch BR, Danko ME, Stinnett S, Dixit D, Koh J, Marks JR, Olson JA| | PubMed