George Khoury Lecture
Organized by NIH scientists to honor the memory of Dr. George Khoury, who was highly regarded as a superb scientist and caring mentor of the postdoctoral fellows in his laboratory. This annual lecture is part of the Wednesday Afternoon Lecture Series. Speakers are selected by a committee led by Dr. Eric Freed.
Human Oncogenic Viruses: Nature and Discovery
Our laboratory performs basic and applied research on viral oncogenesis with efforts focused in the following three areas.
Merkel cell carcinoma and Merkel cell polyomavirus. We recently discovered a new human polyomavirus, that we call Merkel cell polyomavirus (MCV). This virus is etiologically associated with a rare, but one of the most clinically aggressive skin cancers in humans. We are currently involved in the primary characteristics of this virus including transcript mapping, transforming properties, origin replication, transmission, and seroepidemiologic studies.
RNA antics in viral drug resistance and host immunosuppression
The Kirkegaard laboratory deciphers the genetics of RNA viruses and their mammalian hosts, with the goal of suppressing drug resistance and excessive inflammation during viral infections.
Getting by with a little help from their friends: how bacteria aid virus infection
Dr. Pfeiffer studies RNA virus evolution, dissemination, pathogenesis, and transmission. Her recent interests include examining the impact of intestinal microbiota on enteric virus infections. Her lab has determined that intestinal bacteria promote replication of several enteric viruses and ongoing work is examining mechanisms and consequences of bacteria-virus interactions.
Sounding the alarm and putting out the fire: new mechanistic insights into inflammation triggered by invasive infection
The Lieberman laboratory has been in the forefront of developing RNAi-based therapeutics and using RNAi for genome-wide screening. They were the first to demonstrate that siRNAs could protect mice from disease. They developed methods to harness RNAi to inhibit herpes and HIV transmission in animal models. They have developed strategies for cell-targeted RNAi to treat viral infection, immune disease, and cancer. They are currently investigating tumor-targeted siRNAs for immunotherapy to activate tumor expression of neoantigens and avoid autoimmune side effects of checkpoint inhibitors.
Thinking about cancer as an infectious disease
Infection causes 1 in 5 cancers worldwide. Many tumor suppressors, such as p53, have dual functions to prevent tumor cell growth and to inhibit viral replication. These molecules may have evolved from a primordial unicellular eukaryotic antiviral defense system that inhibited DNA synthesis and initiated programmed cell death in response to viral infection. Two cancer viruses found by our lab, Kaposi’s sarcoma herpesvirus and Merkel cell polyomavirus, provide examples of how virus targeting in a cell can be used to understand important circuits controlling tumor cell growth.
Hepatitis C and beyond: Never a dull moment
The Rice lab focuses on RNA viruses and is well known for its work on hepatitis C. Besides studies aimed at understanding basic viral replicative processes the lab also probes the interface between viruses and host intrinsic and innate immunity and small non-coding RNAs.
Intrinsic host defenses against HIV-1
The investigation of impeded viral replication in animal cells of particular types or species has uncovered great complexity in the interaction between retroviruses and their hosts. These studies have revealed that cells are equipped with a diverse set of proteins that can directly inhibit the replication of retroviruses, including HIV-1. Genes encoding antiretroviral proteins exhibit unusually high sequence variation, presumably because selection pressures exerted by ancient viral infections have caused them to evolve at an unusually rapid pace.
Chromatin structure and the control of gene expression
The Wu laboratory investigates the biochemical basis for histone H2A.Z exchange using the budding yeast model organism. They have identified the yeast SWR1 ATP-dependent chromatin remodeling complex as the responsible enzyme. In a purified system, SWR1 removes H2A-H2B dimers from nucleosomes and deposits free H2A.Z-H2B dimers in an ATP-dependent manner. Homologous enzymes have since been characterized in mammalian systems. How does SWR1 recognize promoters and enhancers genome-wide?
The page was last updated on Thursday, January 29, 2015 - 2:30pm