AcrAB efflux pump impacts on the survival of adherent-invasive Escherichia coli strain LF82 inside macrophages.

The tripartite complex AcrAB-TolC is the major RND pump in Escherichia coli and other Enterobacteriaceae. It consists of the AcrB transporter, which is embedded in the inner membrane, the AcrA adapter located in the periplasm, and the channel protein TolC responsible for the transport of substrates towards the extracellular environment. Besides conferring resistance to many classes of antibiotics, AcrAB plays a role in the pathogenesis and virulence of several bacterial pathogens. Here we report that the AcrAB pump heavily affects the infection process of the LF82 strain, the prototype of Adherent-Invasive Escherichia coli (AIEC) which are highly abundant in the ileal mucosa of Chron disease patients. We found that the deletion of genes encoding AcrA and/or AcrB leads to decreased survival of LF82 within macrophages. Ectopic AcrAB expression in a acrAB defective mutant restores the wild type condition. Furthermore, we demonstrate that inhibition of AcrB and replacement of the transporter with an unfunctional AcrB also interfere with bacterial viability inside macrophages. Overall, these data suggest a pivotal role of the AcrAB efflux pump in bacteria-host cell interactions also in AIEC.

The MFS efflux pump EmrKY contributes to the survival of Shigella within macrophages.

Efflux pumps are membrane protein complexes conserved in all living organisms. Beyond being involved in antibiotic extrusion in several bacteria, efflux pumps are emerging as relevant players in pathogen-host interactions. We have investigated on the possible role of the efflux pump network in Shigella flexneri, the etiological agent of bacillary dysentery. We have found that S. flexneri has retained 14 of the 20 pumps characterized in Escherichia coli and that their expression is differentially modulated during the intracellular life of Shigella. In particular, the emrKY operon, encoding an efflux pump of the Major Facilitator Superfamily, is specifically and highly induced in Shigella-infected U937 macrophage-like cells and is activated in response to a combination of high K+ and acidic pH, which are sensed by the EvgS/EvgA two-component system. Notably, we show that following S. flexneri infection, macrophage cytosol undergoes a mild reduction of intracellular pH, permitting EvgA to trigger the emrKY activation. Finally, we present data suggesting that EmrKY is required for the survival of Shigella in the harsh macrophage environment, highlighting for the first time the key role of an efflux pump during the Shigella invasive process.

Cyclin D1 is a major target of miR-206 in cell differentiation and transformation.

miR-206, a member of the so-called myomiR family, is largely acknowledged as a specific, positive regulator of skeletal muscle differentiation. A growing body of evidence also suggests a tumor suppressor function for miR-206, as it is frequently downregulated in various types of cancers. In this study, we show that miR-206 directly targets cyclin D1 and contributes to the regulation of CCND1 gene expression in both myogenic and non-muscle, transformed cells. We demonstrate that miR-206, either exogenous or endogenous, reduces cyclin D1 levels and proliferation rate in C2C12 cells without promoting differentiation, and that miR-206 knockdown in terminally differentiated C2C12 cells leads to cyclin D1 accumulation in myotubes, indicating that miR-206 might be involved in the maintenance of the post-mitotic state. Targeting of cyclin D1 might also account, at least in part, for the tumor-suppressor activity suggested for miR-206 in previous studies. Accordingly, the analysis of neoplastic and matched normal lung tissues reveals that miR-206 downregulation in lung tumors correlates, in most cases, with higher cyclin D1 levels. Moreover, gain-of-function experiments with cancer-derived cell lines and with in vitro transformed cells indicate that miR-206-mediated cyclin D1 repression is directly coupled to growth inhibition. Altogether, our data highlight a novel activity for miR-206 in skeletal muscle differentiation and identify cyclin D1 as a major target that further strengthens the tumor suppressor function proposed for miR-206.

E1B55K-deleted adenovirus (ONYX-015) overrides G1/S and G2/M checkpoints and causes mitotic catastrophe and endoreduplication in p53-proficient normal cells.

In order to take advantage of cell replication machinery, viruses have evolved complex strategies to override cell cycle checkpoints and force host cells into S phase. To do so, virus products must interfere not only with the basal cell cycle regulators, such as pRb or Mad2, but also with the main surveillance pathways such as those controlled by p53 and ATM. Recently, a number of defective viruses has been produced which, lacking the latter ability, are incapable of replicating in normal cells but should be able to grow and finally lyse those cells that, such as the tumor cells, have lost their surveillance mechanisms. A prototype of these oncolytic viruses is the E1B55K-defective Adenovirus ONYX-015, which was predicted to selectively replicate and kill p53-deficient cancer cells. We found that, despite wt p53 and notwithstanding the activation of the checkpoint regulators p53, ATM and Mad2, ONYX-015 actively replicated in HUVEC cells. Furthermore, ONYX-015 replication induced a specific phenotype, which is distinct from that of the E4-deleted adenovirus dlE4 Ad5, although both viruses express the main regulatory region E1A. This phenotype includes overriding of the G(1)/S and G(2)/M checkpoints, over-expression of MAD2 and retardation of mitosis and accumulation of polyploid cells, suggesting the occurrence of alterations at the mitotic-spindle checkpoint and impairment of the post-mitotic checkpoint. Our data suggest that viral E1A and E4 region products can override all host cell-checkpoint response even at the presence of a full activation of the ATM/p53 pathway. Furthermore, the E4 region alone seems to act independently of the E1B55K virus product in impairing the ATM-dependent, p53-independent G(2)/M checkpoint since dlE4 Ad5-infected cells arrested in G(2) while ONYX-015-infected cells did enter mitosis.

p27Kip1 acts downstream of N-cadherin-mediated cell adhesion to promote myogenesis beyond cell cycle regulation.

It is widely acknowledged that cultured myoblasts can not differentiate at very low density. Here we analyzed the mechanism through which cell density influences myogenic differentiation in vitro. By comparing the behavior of C2C12 myoblasts at opposite cell densities, we found that, when cells are sparse, failure to undergo terminal differentiation is independent from cell cycle control and reflects the lack of p27Kip1 and MyoD in proliferating myoblasts. We show that inhibition of p27Kip1 expression impairs C2C12 cell differentiation at high density, while exogenous p27Kip1 allows low-density cultured C2C12 cells to enter the differentiative program by regulating MyoD levels in undifferentiated myoblasts. We also demonstrate that the early induction of p27Kip1 is a critical step of the N-cadherin-dependent signaling involved in myogenesis. Overall, our data support an active role of p27Kip1 in the decision of myoblasts to commit to terminal differentiation, distinct from the regulation of cell proliferation, and identify a pathway that, reasonably, operates in vivo during myogenesis and might be part of the phenomenon known as "community effect".

Selective repression of myoD transcription by v-Myc prevents terminal differentiation of quail embryo myoblasts transformed by the MC29 strain of avian myelocytomatosis virus.

We have investigated the mechanism by which expression of the v-myc oncogene interferes with the competence of primary quail myoblasts to undergo terminal differentiation. Previous studies have established that quail myoblasts transformed by myc oncogenes are severely impaired in the accumulation of mRNAs encoding the myogenic transcription factors Myf-5, MyoD and Myogenin. However, the mechanism responsible for such a repression remains largely unknown. Here we present evidence that v-Myc selectively interferes with quail myoD expression at the transcriptional level. Cis-regulatory elements involved in the auto-activation of qmyoD are specifically targeted in this unique example of transrepression by v-Myc, without the apparent participation of Myc-specific E-boxes or InR sequences. Transiently expressed v-Myc efficiently interfered with MyoD-dependent transactivation of the qmyoD regulatory elements, while the myogenin promoter was unaffected. Finally, we show that forced expression of MyoD in v-myc-transformed quail myoblasts restored myogenin expression and promoted extensive terminal differentiation. These data suggest that transcriptional repression of qmyoD is a major and rate-limiting step in the molecular pathway by which v-Myc severely inhibits terminal differentiation in myogenic cells.