Overexpression of an outer membrane protein associated with decreased susceptibility to carbapenems in Proteus mirabilis.

Proteus mirabilis isolates commonly have decreased susceptibility to imipenem. Previously, we found P. mirabilis hfq mutant was more resistant to imipenem and an outer membrane protein (OMP) could be involved. Therefore, we investigated the role of this OMP in carbapenem susceptibility. By SDS-PAGE we found this OMP (named ImpR) was increased in hfq mutant and LC-MS/MS revealed it to be the homologue of Salmonella YbfM, which is a porin for chitobiose and subject to MicM (a small RNA) regulation. We demonstrated that ImpR overexpression resulted in increased carbapenem MICs in the laboratory strain and clinical isolates. Chitobiose induced expression of chb (a chitobiose utilization operon). Real-time RT-PCR and SDS-PAGE were performed to elucidate the relationship of hfq, impR, chb and MicM in P. mirabilis. We found MicM RNA was decreased in hfq mutant and chbBC-intergenic region (chbBC-IGR) overexpression strain (chbIGRov), while impR mRNA was increased in hfq mutant, micM mutant and chbIGRov strain. In addition, mutation of hfq or micM and overexpression of chbBC-IGR increased ImpR protein level. Accordingly, chitobiose made wild-type have higher levels of ImpR protein and are more resistant to carbapenems. Hfq- and MicM-complemented strains restored wild-type MICs. Mutation of both impR and hfq eliminated the increase in carbapenem MICs observed in hfq mutant and ImpR-complementation of hfq/impR double mutant resulted in MICs as hfq mutant, indicating that the ImpR-dependent decreased carbapenem susceptibility of hfq mutant. These indicate MicM was antisense to impR mRNA and was negatively-regulated by chbBC-IGR. Together, overexpression of ImpR contributed to the decreased carbapenem susceptibility in P. mirabilis.

The RNA chaperone Hfq is involved in stress tolerance and virulence in uropathogenic Proteus mirabilis.

Hfq is a bacterial RNA chaperone involved in the riboregulation of diverse genes via small noncoding RNAs. Here, we show that Hfq is critical for the uropathogenic Proteus mirabilis to effectively colonize the bladder and kidneys in a murine urinary tract infection (UTI) model and to establish burned wound infection of the rats. In this regard, we found the hfq mutant induced higher IL-8 and MIF levels of uroepithelial cells and displayed reduced intra-macrophage survival. The loss of hfq affected bacterial abilities to handle H2O2 and osmotic pressures and to grow at 50 °C. Relative to wild-type, the hfq mutant had reduced motility, fewer flagella and less hemolysin expression and was less prone to form biofilm and to adhere to and invade uroepithelial cells. The MR/P fimbrial operon was almost switched to the off phase in the hfq mutant. In addition, we found the hfq mutant exhibited an altered outer membrane profile and had higher RpoE expression, which indicates the hfq mutant may encounter increased envelope stress. With the notion of envelope disturbance in the hfq mutant, we found increased membrane permeability and antibiotic susceptibilities in the hfq mutant. Finally, we showed that Hfq positively regulated the RpoS level and tolerance to H2O2 in the stationary phase seemed largely mediated through the Hfq-dependent RpoS expression. Together, our data indicate that Hfq plays a critical role in P. mirabilis to establish UTIs by modulating stress responses, surface structures and virulence factors. This study suggests Hfq may serve as a scaffold molecule for development of novel anti-P. mirabilis drugs and P. mirabilis hfq mutant is a vaccine candidate for preventing UTIs.

[Establishing an organic model of SMC proliferation with cultured aorta of rats and exploring the underlying mechanism].

To study the mechanism of proliferous vascular disease as well as its prevention and treatment, an organic model was established with cultured aortas of rats, and the mechanism there-in invloved was probed. Immunostaining histology showed that smooth muscle cell (SMC) proliferation was observed in the aorta segments of rats, after their endothelia being injured and cultured in vitro with 20% fetal bovine serum. After being cultured for 5 days, various degrees of proliferation of SMC on cultured artery segments were observed by HE staining, and conspicuous plaques were developed after being cultured for 13 days. The proliferous SMC was also observed by Brdu labeling. RT-PCR examination showed that the mRNA expression of hypertension-related gene-1 (Hrg-1) and smooth muscle 22 alpha (SM22a) in the aortas decreased with the prolongation of culture time, and completely disappeared after being cultured for 13 days . But when cultured in vitro for ten days, the ET-1 content of supernatant and the proliferous SMC labeled by Brdu increased obviously and the expressions of Hrg-1 and SM22a decreased after the endothelium was destroyed. Compared with the injured endothelium groups, the proliferous SMC of injured endothelium plus BQ123 groups decreased visibly. The same significant differences between serum groups and serum-free groups were also observed. These results suggest that the culturing of rat aorta segments in vitro can induce the proliferation of SMC and the transform of phenotype from contractile type to synthetic type. The ET-1 and serum are the main factors in the proliferation of SMC and in the transform of phenotype. This organic model could serve as a good experimental platform for the researches into the mechanism of proliferous vascular disease as well as its prevention and treatment.

A novel cultured tissue model of rat aorta: VSMC proliferation mechanism in relationship to atherosclerosis.

Development of a cultured tissue experimental model of rat aorta was explored in order to study mechanism of vascular smooth muscle (VSMC) proliferation. This particular model has potential with regard to amelioration of atherosclerosis and other vascular diseases in comparison to whole animal and cell culture models. The aorta segments of rats were divided into 4 experimental groups: the injured endothelium, injured endothelium plus BQ123, without injured endothelium and without injured endothelium plus BQ123. Each of group was subdivided into a further 2 subgroups and cultured with 20% serum and with serum-free DMEM. Each group cultured in vitro for 5, 8 and 13 days respectively. The control group was not cultured in vitro. Bromodeoxyuridine (BrDU 8x10(-4) mol/l) was added into the cultured medium of all groups, 24 h prior to harvesting. These segments were fixed in 4% paraformaldehyde for paraffin slice used to HE and immunocytochemical staining and other aorta segments were used to detect the expressions of hypertension-related gene-1 (HRG-1) and smooth muscle 22 alpha (SM22alpha) by RT-PCR. ET-1 content in the supernatant was detected with radioimmunology. Proliferous VSMC can be observed on artery segments cultured in vitro, and conspicuous plaques were developed on model vascular wall cultured for 13 days. Labeled cells increased with an increase in culture time but were not seen in the control group. A greater number of labeled cells were observed in injured endothelium group cultured in 20% serum DMEM. Hyperplasia was inhibited after BQ123 was added into the medium, suggesting that serum and ET-1 are important factors that lead to VSMC proliferation. Expressions of HRG-1 and SM22alpha were decreased while the aorta segments were cultured in vitro, minimum or even absent mRNA expressions of HRG-1 and SM22alpha were detected in injured endothelium cultured in 20% serum DMEM and increased in injured endothelium plus BQ123 group cultured. ET-1 content in the supernatant increased in injured endothelium cultured in 20% serum DMEM. These results show that the phenotypic transform and VSMC proliferation on cultured artery segments were related not only to serum culture, but also to ET-1 secreting. ET-1 and serum may be the main factors of contributing to the proliferation and phenotypic transform. This model provides a favorable experimental platform for research into the mechanism of vascular proliferous diseases as well as its prevention and treatment.

Fibronectin and culture temperature modulate the efficacy of an avidin-biotin binding system for chondrocyte adhesion and growth on biodegradable polymers.

Cell adhesion to a scaffold is a prerequisite for tissue engineering. Many studies have been focused on enhancing cell adhesion to synthetic materials that are used for scaffold fabrication. Previously, we showed that immobilization of biotin molecules to chondrocyte surfaces enhanced cell adhesion to avidin-coated biodegradable polymers such as poly-L-lactic acid, poly-D,L-lactic acid and polycaprolactone. However, the endocytosis of cell membrane biotin molecules decreases binding strength between biotinylated-chondrocytes (B-chondrocytes) and avidin-coated substrata, and therefore decreases cell spreading and discourages long-term chondrocytes culture. In this study, we proposed two strategies to solve the shortcoming of the avidin-biotin binding system. First, the avidin-biotin binding system is combined with the intrinsic integrin-dependent adhesion systems in order to enhance long-term cell culture. Second, the incubation temperature is lowered in order to slow down the endocytosis process. We found that the avidin-biotin binding system in combination with FN-integrin binding system enhanced cell adhesion, cell spreading and cell growth. Decrease of cell culture temperature to 4 degrees C enhanced the adhesion of B-chondrocytes to the avidin-coated surfaces, but decreased cell viability and proliferation, compared to culture temperature of 37 degrees C. Whether there is an optimal seeding temperature between 4 and 37 degrees C for both adhesion and proliferation of B-chondrocytes needs further investigation. Our results indicated that modulation of the adhesion conditions could further enhance the efficacy of the avidin-biotin binding system in mediating cell adhesion, and subsequent tissue culture.

Effects of an avidin-biotin binding system on chondrocyte adhesion and growth on biodegradable polymers.

Cell adhesion to a scaffold is a prerequisite for tissue engineering. Many studies have been focused on enhancing cell adhesion to synthetic materials that are used for scaffold fabrication. In this study, we applied an avidin-biotin binding system to enhance chondrocyte adhesion to biodegradable polymers. Biotin molecules were conjugated to the cell membrane of chondrocytes, and mediated cell adhesion to avidin-coated surfaces. We demonstrated that immobilization of biotin molecules to chondrocyte surfaces enhanced cell adhesion to avidin-coated biodegradable polymers such as poly(L-lactic acid), poly(D,L-lactic acid), and polycaprolactone, compared to the adhesion of normal chondrocytes to the same type of biodegradable polymer. The biotinylated chondrocytes still maintained their proliferation ability. This study showed the promise of applying the avidin-biotin system in cartilage tissue engineering. [diagram in text].

Effect of an avidin-biotin binding system on chondrocyte adhesion, growth and gene expression.

Cell adhesion to synthetic biomaterials is a prerequisite for anchorage cell culture and tissue engineering. The current study investigated utilization of an avidin-biotin binding system in enhancing chondrocyte adhesion to tissue culture polystyrene (TCPS). Biotinylated chondrocytes adhered to avidin-coated TCPS more quickly than untreated chondrocytes to bare TCPS. Also the avidin-biotin binding system enhanced cell initial spreading. However, the effects were only transient. The growth of biotinylated chondrocytes was first decreased during the first 3 days but increased afterwards. The progeny of biotinylated chondrocytes still maintained the ability in expressing cartilage extracellular matrix proteins such as type II collagen, type IX collagen and aggrecan. These results show potential for the application of the avidin-biotin binding system to cell culture and tissue engineering.