- B.S., University of California at Berkeley, 1992
- Ph.D., University of California at San Francisco, 1997
- National Institutes of Health
- Searle Scholar and Whitehall Foundation Fellow
All cells and organisms must monitor and maintain their energy levels for survival. One particular protein kinase, AMP-activated protein kinase (AMPK) plays a central role in energy balance. AMPK consists of a protein complex encoded by three subunits, a serine-threonine kinase catalytic subunit (α) and two regulatory subunits (ß, γ). When AMPK signaling is disrupted cells undergo cell death and organisms can not survive limited starvation.
AMPK has many potential biomedically-relevant functions. AMPK is proposed to be a therapeutic target for Type 2 diabetes and Metabolic syndrome (obesity, insulin resistance, cardiovascular disease). In addition, since cancer cells have larger energetic requirements than non-dividing cells, targeting AMPK might be an attractive approach for attacking cancer.
We identified mutations in the AMPK kinase domain (AMPKα) during a genetic screen looking for "neurodegeneration mutants" in Drosophila. Inactivation of AMPK leads to neurodegeneration-like phenotypes in neurons and abnormal metabolism in other cells. Our lab uses combinations of genetics, biochemistry/proteomics and cell culture models to try to further identify new molecules involved in AMPK signaling. We are particularly interested in how AMPK signaling and molecules it regulates are relevant to:
- Metabolism (Type 2 Diabetes/Cardiac Disease)
- and Cancer
Many of our studies use Drosophila melanogaster (the fruit fly) due to the powerful genetics of this assay system and conserved molecules in AMPK signaling. However, we also use mouse genetics to explore AMPK function in two contexts: 1) In brains of knockout mice to explore the role of AMPK in normal nervous system function; 2) In brain tumor cancer models (in collaboration with Dr. R. Miller).
Other studies use differential proteomics (in collaboration with Dr. O. Alzate) in combination with AMPK knockout cells and tissues to elaborate new AMPK signaling targets/components.
Finally, human mutations in the gamma subunit of AMPK cause the fatal cardiac syndrome, Wolf-Parkinson-White. We are trying to use Drosophila to develop an animal model with these mutations to allow us to use powerful genetic analyses to better understand this disease and regulation of AMPK signaling.
A joint project (with Dr. J. Sexton, NCCU) involves developing new cell based assays for new compounds that could become thereapeutics for metabolic disease (particularly Type 2 Diabetes and fatty liver).
- Braco JT, Gillespie EL, Alberto GE, Brenman JE, Johnson EC. Energy-dependent Modulation of Glucagon-like Signaling in Drosophila via the AMP-activated Protein Kinase. Genetics 2012 (Epub ahead of print)
- Onyenwoke RU, Forsberg LJ, Liu L, Williams T, Alzate O, Brenman JE. AMPK directly inhibits NDPK through a phosphoserine switch to maintain cellular homeostasis. Molecular Biology of the Cell. 2012; 23(2)381-9
- Williams T, Courchet J, Viollet B, Brenman JE, Polleux F. AMP-activated protein kinase (AMPK) activity is not required for neuronal development but regulates axogenesis during metabolic stress. PNAS. 2011; 108(14)5849-54
- Kazgan N, Williams T, Forsberg LJ, Brenman JE. Identification of a nuclear export signal in the catalytic subunit of AMP-activated protein kinase. Molecular Biology of the Cell. 2010 (19)3433-42
- Johnson EC, Kazgan N, Bretz CA, Forsberg LJ, Hector CE, Worthen RJ, Onyenwoke R, Brenman JE. Altered metabolism and persistent starvation behaviors caused by reduced AMPK function. PLoS One. 2010; 5 (9) e12799
- Sexton JZ, He Q, Forsberg JL, Brenman JE. High content screening for non-classical peroxisome proliferators. Int Journal of High Throughput Screening. 2010(1)127-140
- Williams, T., Forsberg, F., Viollet, B., and Brenman J. E. Basal autophagy induction without AMP-activated protein kinase under low glucose conditions. Autophagy (2009) 5(8)1155-65
- Amin, N., Khan, A., Tomlinson, I., St Johnston D., Martin S., Brenman J., McNeill, H. LKB1 regulates polarity remodeling and adherens junction formation in the Drosophila eye. PNAS (2009 Jun 2;106(22):8941-6.)
- Brenman JE., Fragile X Mental Retardation Protein in the Driver's Seat. Cereb Cortex. (2009 Jul;19(7):1490-2.)
- Williams, T., and Brenman, J.E. (2008) LKB1 and AMPK in Cell Polarity and Division. Trends in Cell Biology 18(4):193-8.
- Medina, P.M.B., Worthen, R., Forsberg, J., and Brenman, J.E.. The Actin-Binding Protein Capulet Genetically Interacts with the Microtubule Motor Kinesin to Maintain Dendrite Homeostasis (2008) PLoS One Aug 25;3(8):e3054
- Mirouse, Swick, Kazgan and Brenman. (2007) LKB1 and AMPK maintain epithelial polarity under energetic stress. 177(3)387-92 The Journal of Cell Biology.
- Temple, B. and Brenman, J.E. (2007). Alternative Views of AMP-activated protein kinase. Cell Biochemistry and Biophysics 47(3):321-31.
- Crews, S.T., and Brenman, J.E. (2006) Spineless Provides a Little Backbone for Dendritic Morphogenesis. Genes & Development 2006 Oct 15;20(20):2773-8.
- Medina PM, Swick LL, Andersen R, Blalock Z, Brenman JE. A novel forward genetic screen for identifying mutations affecting larval neuronal dendrite development in Drosophila melanogaster. Genetics. 2006 Apr;172(4):2325-35. Epub 2006 Jan 16.
- Sweeney NT, Brenman JE, Jan YN, Gao FB. The coiled-coil protein shrub controls neuronal morphogenesis in Drosophila. Current Biology. 2006 May 23;16(10):1006-11.