Moraxella catarrhalis AcrAB-OprM efflux pump contributes to antimicrobial resistance and is enhanced during cold shock response

Moraxella catarrhalis is a common pathogen of the human respiratory tract. Multidrug efflux pumps play a major role in antibiotic resistance and virulence in many Gram-negative organisms. In the present study, the role of the AcrAB-OprM efflux pump in antibiotic resistance was investigated by constructing mutants that lack the acrA, acrB, and oprM genes in M. catarrhalis strain O35E. We observed a moderate (1.5-fold) decrease in the MICs of amoxicillin and cefotaxime and a marked (4.7-fold) decrease in the MICs of clarithromycin for acrA, acrB, and oprM mutants in comparison with the wild-type O35E strain. Exposure of the M. catarrhalis strains O35E and 300 to amoxicillin triggered an increased transcription of all AcrAB-OprM pump genes, and exposure of strains O35E, 300, and 415 to clarithromycin enhanced the expression of acrA and oprM mRNA. Inactivation of the AcrAB-OprM efflux pump genes demonstrated a decreased ability to invade epithelial cells compared to the parental strain, suggesting that acrA, acrB, and oprM are required for efficient invasion of human pharyngeal epithelial cells. Cold shock increases the expression of AcrAB-OprM efflux pump genes in all three M. catarrhalis strains tested. Increased expression of AcrAB-OprM pump genes after cold shock leads to a lower accumulation of Hoechst 33342 (H33342), a substrate of AcrAB-OprM efflux pumps, indicating that cold shock results in increased efflux activity. In conclusion, the AcrAB-OprM efflux pump appears to play a role in the antibiotic resistance and virulence of M. catarrhalis and is involved in the cold shock response.

Cleavage and activation of calpain and its substrate caspase-7 in prostate cancer cells: Evidence for a role in apoptotic sensitization

Changes in the levels of intracellular calcium mediate multiple biological effects, including apoptosis, in some tumor cells. Early studies demonstrated that prostate cancer cells are highly sensitive to alterations in the levels of their intracellular calcium pools. Furthermore, it has been established that apoptosis in prostate cancer could be initiated through calcium-selective ionophores, or inhibitors of intracellular calcium pumps. High sensitivity to changes in intracellular calcium levels may therefore be exploited as a novel mechanism for controlling prostate cancer apoptotic thresholds; however, the mechanisms associated with this process are poorly understood. To investigate the role of calcium as a mediator of prostate cancer cell death and its effects on caspase activation, LNCaP and PC-3 cell response to the calcium ionophore A23187, were examined. LNCaP cells were highly sensitive to changes in intracellular calcium, and subtoxic concentrations of A23187 facilitated apoptosis initiated by cytokines (TNF or TRAIL). In contrast, PC-3 cell death was not affected by A23187 or cytokines. A23187 caused rapid and concentration-dependent activation of calpain in LNCaP (but not PC-3 cells) which correlated with cleavage of calpain substrates caspase-7 and PTP1B. Cleavage of PTP1B from a 50 kDa to 42 kDa protein correlated with its translocation from the endoplasmic reticulum to the cytosol and with inhibition of tyrosine phosphorylation. Caspase-7 was cleaved from a 35 kDa to 30 kDa protein in response to A23187 in LNCaP (but not PC-3) cells and correlated with activation of both upstream and downstream caspases. Extracts from A23187-treated LNCaP cells, or PC-3 cells transiently transfected with calpain, mediated similar processing of in vitro transcribed and translated (TNT) caspase-7. In vitro processing of caspase-7 correlated with its proteolytic activation, which was inhibited by calpain inhibitor (calpeptin) and to some degree, by caspase inhibitors (zVAD, DEVD). Together, these results suggest that calpain is directly involved in calcium-mediated apoptosis of prostate cancer cells through activation and cleavage of caspase-7 and other substrates. Loss of calpain activation may therefore play a critical role in apoptotic resistance of some prostate cancer cells. ^

Intrinsic characteristics of the proton pump in the luminal membrane of a tight urinary epithelium. The relation between transport rate and delta mu H.

A number of tight urinary epithelia, as exemplified by the turtle bladder, acidify the luminal solution by active transport of H+ across the luminal cell membrane. The rate of active H+ transport (JH) decreases as the electrochemical potential difference for H+ [delta mu H = mu H(lumen) - mu H(serosa)] across the epithelium is increased. The luminal cell membrane has a low permeability for H+ equivalents and a high electrical resistance compared with the basolateral cell membrane. Changes in JH thus reflect changes in active H+ transport across the luminal membrane. To examine the control of JH by delta mu H in the turtle bladder, transepithelial electrical potential differences (delta psi) were imposed at constant acid-base conditions or the luminal pH was varied at delta psi = 0 and constant serosal PCO2 and pH. When the luminal compartment was acidified from pH 7 to 4 or was made electrically positive, JH decreased as a linear function of delta mu H as previously described. When the luminal compartment was made alkaline from pH 7 to 9 or was made electrically negative, JH reached a maximal value, which was the same whether the delta mu H was imposed as a delta pH or a delta psi. The nonlinear JH vs. delta mu H relation does not result from changes in the number of pumps in the luminal membrane or from changes in the intracellular pH, but is a characteristic of the H+ pumps themselves. We propose a general scheme, which, because of its structural features, can account for the nonlinearity of the JH vs. delta mu H relations and, more specifically, for the kinetic equivalence of the effects of the chemical and electrical components of delta mu H. According to this model, the pump complex consists of two components: a catalytic unit at the cytoplasmic side of the luminal membrane, which mediates the ATP-driven H+ translocation, and a transmembrane channel, which mediates the transfer of H+ from the catalytic unit to the luminal solution. These two components may be linked through a buffer compartment for H+ (an antechamber).