Proteus mirabilis is a facultative anaerobic, Gram-negative bacterium and a member of the Enterobacteriaceae family. It is a normal flora in human intestine. It usually causes, however, urinary tract infection (UTI), and leads to kidney disease, pneumonia and septicemia in individuals with long-term catheterization or with structural or functional abnormalities in the urinary tract. Hfq is a bacterial RNA chaperone protein. Its regulation is mediated through small RNAs (sRNAs), which belong to post-transcriptional regulation. Hfq can help sRNA function, as to increase or decrease target proteins translation. The sequence of Hfq is highly conserved in several Gram negative pathogens, including Proteus mirabilis. In almost all of the Gram negative bacteria, hfq gene is located in a miaA-hfq-hflX cascade, and there’s no exception for P. mirabilis. Recently, ever-increasing studies of Hfq have been reported, focusing on its impact on bacterial physiology and virulence. To understand the role of Hfq in P. mirabilis, in our study we constructed an hfq mutant by knockout assay. In the following experiments we found that hfq mutation caused massive effects on P. mirabilis, leading to growth defect, changes in motility, decreased flagellin expression, impaired biofilm formation, delayed haemolysin cycle and decreased activity, decreased NTUB1 cell invasion ability, increased macrophage clearance, changes in outer membrane protein profile, increased outer membrane permeability, increased sensitivity to antibiotics, lowered heat, oxidative and hyperosmotic stress resistance, and attenuated rat burn wound skin infection ability. According to the aboved-mentaioned results we concluded that Hfq played a vital role in P. mirabilis, affecting its physiology and virulence. Since there’s a ten-fold increase in polymyxin B sensentivity in hfq mutant, we used LPS quantification, PB binding assay, and rppA reporter assay to study the underlying mechanisms involved. So far, none of the results have been found desirable to explain our findings. Thus, the effect of Hfq on polymyxin B sensentivity in P. mirabilis remained unclear. It has been proved that Hfq can function as an RNA chaperone protein to stabilize rpoS mRNA. Furthermore, it can up-regulate RpoS translation via DsrA, RprA, ArcZ, RyhA-sRNAs. In our study, using real-time PCR we found that rpoS mRNA was significantly decreased in hfq mutant. This indicated that Hfq has a similar effect on rpoS mRNA stability in P. mirabilis. Also, we constructed rpoS mutant and found that it showed some coomon phenotypes with the hfq mutant, including decreased NTUB1 cell invasion ability as well as lowered resistance to oxidative and hyperosmotic stresses. Studies have revealed that Hfq can act in concert with sRNAs to influence targets on bacterial outer membrane. When hfq is mutated, loss of these actions can change the outer membrane protein composition, and thus dirupt the outer membrane intergrity. Changes in outer membrane intergrity can then activate the rpoE-envelop stress sigma factor. In our data, we showed that hfq mutant possessed stronger rpoE activity than wild type, indicating that there’s a similar role of Hfq in P. mirabilis. Using SDS-PAGE outer membrane protein profiling we further iderntified five outer membrane proteins that accumulated in the hfq mutant. These are PMI0044, PMI0540, PMI1017, OmpA, and OmpF. Subsequent real-time PCR quantification revealed that PMI0540 is the most significantly increased one. After constructing the PMI0540 overexpression strain and assaying its phenotypes, we observed that rpoE reporter acitivity was increased. The result indicated that PMI0540 overexpression alone can activiate rpoE response. In other phenotypic assays we found that SDS and Cm sensitivity was increased and PMI0540 overexpression strain showed lowered hyperosmotic stress resistance and biofilm formation ability. After searching for PMI0540 homologue in other bacteria, we found that PMI0540 was closely related to YbfM. They both belong to OprD family outer membrane protein. The specific function of YbfM have been published in E. coli and Salmonella. There are three important genes involved in YbfM regulation, hfq, MicM, and chbBC intergenic region. In P. mirabilis, all of the three genes do exist and their functionally important binding sites are also conserved. In this study we found that similar roles of these regulators applied to P. mirabilis. When Proteus encountered chitobiose, PMI0540 was then induced and synthesized for transportation of these sugars. And chb operon, MicM, Hfq were all involved in this kind of regulation, which was called an mRNA-mediated antisense regulation of the antisense RNA. To sum up, we found that Hfq played an important role in P. mirabilis, affecting its growth, motility, stress resistance, antibiotics sensitivity, and virulence factors. We also observed that RpoS did attribute to some of the hfq mutant phenotypes, but not all. In the regulation of outer membrane proteins part we found that MicM and Hfq can repress PMI0540 translation unless the signal molecule, chitobiose, occurred.