The bacteriophage T4 inhibitor and coactivator AsiA inhibits Escherichia coli RNA Polymerase more rapidly in the absence of sigma70 region 1.1: evidence that region 1.1 stabilizes the interaction between sigma70 and core.

The N-terminal region (region 1.1) of sigma70, the primary sigma subunit of Escherichia coli RNA polymerase, is a negatively charged domain that affects the DNA binding properties of sigma70 regions 2 and 4. Region 1.1 prevents the interaction of free sigma70 with DNA and modulates the formation of stable (open) polymerase/promoter complexes at certain promoters. The bacteriophage T4 AsiA protein is an inhibitor of sigma70-dependent transcription from promoters that require an interaction between sigma70 region 4 and the -35 DNA element and is the coactivator of transcription at T4 MotA-dependent promoters. Like AsiA, the T4 activator MotA also interacts with sigma70 region 4. We have investigated the effect of region 1.1 on AsiA inhibition and MotA/AsiA activation. We show that sigma70 region 1.1 is not required for MotA/AsiA activation at the T4 middle promoter P(uvsX). However, the rate of AsiA inhibition and of MotA/AsiA activation of polymerase is significantly increased when region 1.1 is missing. We also find that RNA polymerase reconstituted with sigma70 that lacks region 1.1 is less stable than polymerase with full-length sigma70. Our previous work has demonstrated that the AsiA-inhibited polymerase is formed when AsiA binds to region 4 of free sigma70 and then the AsiA/sigma70 complex binds to core. Our results suggest that in the absence of region 1.1, there is a shift in the dynamic equilibrium between polymerase holoenzyme and free sigma70 plus core, yielding more free sigma70 at any given time. Thus, the rate of AsiA inhibition and AsiA/MotA activation increases when RNA polymerase lacks region 1.1 because of the increased availability of free sigma70. Previous work has argued both for and against a direct interaction between regions 1.1 and 4. Using an E. coli two-hybrid assay, we do not detect an interaction between these regions. This result supports the idea that the ability of region 1.1 to prevent DNA binding by free sigma70 arises through an indirect effect.

Conditional macrophage ablation demonstrates that resident macrophages initiate acute peritoneal inflammation.

The role played by resident macrophages (Mphi) in the initiation of peritoneal inflammation is currently unclear. We have used a conditional Mphi ablation strategy to determine the role of resident peritoneal Mphi in the regulation of neutrophil (PMN) recruitment in experimental peritonitis. We developed a novel conditional Mphi ablation transgenic mouse (designated CD11bDTR) based upon CD11b promoter-mediated expression of the human diphtheria toxin (DT) receptor. The murine DT receptor binds DT poorly such that expression of the human receptor confers toxin sensitivity. Intraperitoneal injection of minute (nanogram) doses of DT results in rapid and marked ablation of F4/80-positive Mphi populations in the peritoneum as well as the kidney, and ovary. In experimental peritonitis, resident Mphi ablation resulted in a dramatic attenuation of PMN infiltration that was rescued by the adoptive transfer of resident nontransgenic Mphi. Attenuation of PMN infiltration was associated with diminished CXC chemokine production at 1 h. These studies indicate a key role for resident peritoneal Mphi in sensing perturbation to the peritoneal microenvironment and regulating PMN infiltration.

Selective depletion of macrophages reveals distinct, opposing roles during liver injury and repair.

Macrophages perform both injury-inducing and repair-promoting tasks in different models of inflammation, leading to a model of macrophage function in which distinct patterns of activation have been proposed. We investigated macrophage function mechanistically in a reversible model of liver injury in which the injury and recovery phases are distinct. Carbon tetrachloride---induced liver fibrosis revealed scar-associated macrophages that persisted throughout recovery. A transgenic mouse (CD11b-DTR) was generated in which macrophages could be selectively depleted. Macrophage depletion when liver fibrosis was advanced resulted in reduced scarring and fewer myofibroblasts. Macrophage depletion during recovery, by contrast, led to a failure of matrix degradation. These data provide the first clear evidence that functionally distinct subpopulations of macrophages exist in the same tissue and that these macrophages play critical roles in both the injury and recovery phases of inflammatory scarring.