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Publications (Pubmed)

Leon Bromberg Professor of Medicine, Dept. of Internal Medicine, Scientist, Sealy Center for Molecular Science, Sealy Center for Cancer Cell Biology
Tel: (409) 772-2824
Fax: (409) 772-8709
Route: 1060
8.138 Medical Research Bldg.


Allan R. Brasier, M.D.

A central problem in cellular biology is to understand how cells transduce signals in the extracellular environment to produce changes in the expression of homeostatic genes. Extracellular signals, taking the form of hormones or environmental signals (such as viral infection, heat, uv-light) alter signal transduction pathways that ultimately result in the activation of a limited set of DNA-binding proteins. These transcription factors, in turn, activate expression of genetic networks plays a dominant role in cellular response to stress and the pathobiology of numerous human disease states including inflammation, hypertension, wound repair, and malignancy.

Work in my laboratory has concentrated on cellular mechanisms of genetic responses to inflammatory hormones in the liver (the hepatic acute-phase response) and the respiratory epithelium (the pulmonary cytokine cascade).

Our lab has defined mechanism for activation of a key signal transduction molecule that mediate the transcriptional activation of the acute phase reactants.

The hepatic acute-phase response is seen following acute viral or drug-induced hepatitis, heavy metal poisoning, or systemic bacterial infection.

Inflammatory hormones, such as tumor necrosis factor-a (TNFa), initiates de novo transcription of genetic networks through activating nuclear translocation of the latent cytoplasmic nuclear factor-kB (NF-kB) transcription factor. NF-kB is sequestered in the cytoplasm by association with inhibitory proteins termed IkBs. After TNFa stimulation IkB is rapidly proteolyzed, releasing NF-kB to enter the nucleus and stimulate transcription of acute-phase reactants. Our lab was the first to show the inducible degradation of the IkB protein is mediated by cytosolic calcium-activated neutral endoproteases (calpains).

A separate model under study in my laboratory is the mechanisms for the pulmonary cytokine cascade activated by Respiratory syncytial virus (RSV) infection. RSV is a ubiquitous pathogen that infects virtually 100% of the US population before the age of three and is responsible for 100,000 hospitalizations annually. Apart from its acute effects, RSV infection is etiologically linked to airway hyper-reactivity (asthma) in children. RSV produces a pronounced inflammatory response in airways of children with active infection; this is a consequence of inflammatory mediators (cytokines) produced by airway epithelial cells. These cytokines recruit and activate various populations of immune cells into the respiratory mucosa. We have demonstrated that RSV-infected alveolar epithelial cells inducibly transcribe and secrete IL-8. IL-8 gene expression is mediated and absolutely dependent on the nuclear translocation of the NF-kB subunit, Rel A. We are presently investigating the mechanisms for NF-kB activation of IL-8 through studies on promoter assembly and characterization of NF-kB dependent gene networks using microarray technology. These studies are also part of a NIAID sponsored Asthma and Allergic Diseases Research Center grant.