Chromatin
Structure and In Vivo Footprinting Studies on Murine and Human iNOS
Nitric
oxide (NO) has been implicated in a variety of normal and pathological
situations, including vasodilation, neurotransmission, sepsis, as well as
ischemia-reperfusion injury. There are currently three nitric oxide synthases
(NOS) capable of generating NO, a neuronal form (nNOS) and an endothelial form
(eNOS), which are constituitively expressed under most circumstances as well as
an inducible form (iNOS).
iNOS
has been strongly associated with the anti-bacterial and viral activity of
monocytes in rodent cells, a phenomenon not yet documented in human cells.
Although the exact physiological role of iNOS is not clearly been defined in
for example pulmonary or hepatic cells, we have been attempting to understand
the regulation of the human gene in these tissues.
Our studies
on the murine and human iNOS genes in murine macrophages and astrocytes and
human pulmonary and biliary epithelial cells have employed a strategy similar
to that for MnSOD. In vivo footprinting studies of the murine iNOS
promoter have identified the location of basal factor binding sites within the
proximal promoter as well as inducible protein contacts. The studies in the
murine system include a comparison of iNOS expression in macrophages with that
in neuronal astrocyte cultures, which we have shown to have similar regulatory
responses. Coupled with our gene regulation studies we have also begun an
investigation of iNOS mRNA stability in murine astrocytes, based on the
extensive evidence implicating this molecular mechanism in regulation of iNOS mRNA
levels.
Our
studies on the human iNOS gene were performed in collaboration with Dr. Sarah
Chesrown at the University of Florida and Drs. Tim Billiar and David Gellar at
the University of Pittsburgh. Transcription
of the human iNOS gene is regulated by cellular stimulation with inflammatory
cytokines in a tissue and species specific manner. To determine if differences in cytokine induced mRNA levels in
human pulmonary epithelial cells (A549) or hepatic biliary epithelial cells
(AKN-1) are the result of different protein/DNA regulatory mechanisms, we
identified cytokine induced changes in chromatin structure by mapping DNase I
hypersensitive (HS) sites in 13 kb of
the 5’ flanking region. Our analysis
revealed both constitutive and inducible HS sites in an overlapping yet cell-type
specific pattern.
We then
examined one region of chromatin that contained both constitutive and cytokine
induced HS sites for potential DNA/protein interactions using dimethyl sulfate
(DMS) in vivo footprinting and
ligation-mediated PCR. We identified
four potential protein binding sites at this location in the human iNOS
promoter in both liver and lung cells.
The in vivo footprinting
autoradiogram below depicts sopme of this data and the figure on the left
summarizes our results for this region of the humn iNOS promoter.
Three
of these in vivo footprints are
present in both control and cytokine-treated cells and map within a
constitutive HS site. The remaining footprint
appears only in response to cytokine treatment and maps to an inducible HS site. These
studies illustrate a portion of the molecular mechanisms controlling the
transcriptional regulation of the human iNOS gene at single nucleotide
resolution in a cell/tissue specific manner. In vivo footprinting
studies at -5 kb have revealed the interaction of numerous basal factors in
both cell types. As part of our collaborative efforts we will pursue in vivo
footprinting studies on the remainder of the chromatin hypersensitive sites and
intiate the cloning of any novel factors.
