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Moreover, given the recently discovered interplay between FadR and the chromosome structuring protein Coalescin, FadR phosphorylation could also influence local chromosome conformation under specific cellular conditions.Development of integrin-targeted cancer therapies is hindered by incomplete understanding of integrin function in tumor cells and the tumor microenvironment. Previous studies showed that mice with epidermis-specific deletion of the α3 integrin subunit fail to form skin tumors during two-step chemical tumorigenesis, indicating a pro-tumorigenic role for integrin α3β1. Here we generated mice with tamoxifen-inducible, epidermis-specific α3 knockout to determine the role of α3β1 in the maintenance of established tumor cells and/or the associated stroma. Genetic ablation of α3 in established skin tumors caused their rapid regression, indicating that α3β1 is essential to maintain tumor growth. Interestingly, while reduced proliferation and increased apoptosis were observed in α3β1-deficient tumor cells, these changes followed a robust increase in stromal apoptosis. Furthermore, macrophages and fibulin-2 levels were reduced in stroma following α3 deletion from tumor cells. click here Mass spectrometric analysis of conditioned medium from immortalized keratinocytes showed that α3β1 regulates a substantial fraction of the keratinocyte secretome, including fibulin-2 and macrophage colony-stimulating factor 1; RNA in situ hybridization showed that expression of these two genes was reduced in tumor keratinocytes in vivo. Our findings identify α3β1 as a regulator of the keratinocyte secretome and skin tumor microenvironment, and as a potential therapeutic target.Glycogen synthase kinase-3 (GSK-3) is a serine/threonine kinase implicated in numerous physiological processes and cellular functions through its ability to regulate the function of many proteins, including transcription factors and structural proteins. GSK-3β has been demonstrated to function as a regulator of multiple behavioral processes induced by drugs of abuse, particularly psychostimulant drugs. In this review, we provide an overview of the regulation of GSK-3β activity produced by psychostimulants, and the role of GSK-3β signaling in psychostimulant-induced behaviors including drug reward, associative learning and memory which play a role in the maintenance of drug-seeking. Evidence supports the conclusion that GSK-3β is an important component of the actions of psychostimulant drugs and that GSK-3β is a valid target for developing novel therapeutics. Additional studies are required to examine the role of GSK-3β in distinct cell types within the mesolimbic and memory circuits to further elucidate the mechanisms related to the acquisition, consolidation, and recall of drug-related memories, and potentially countering neuroadaptations that reinforce drug-seeking behaviors that maintain drug dependence.Developmental pathways for B cell lymphogenesis are sufficiently known only in mice and humans. However, both of these species rearrange immunoglobulin heavy chains (IgH) before light chains (IgL) while IgL precedes IgH rearrangement in swine. We demonstrate here that this reversed order of rearrangements have some concealed consequences (1) we confirmed that although IgLκ rearrangement is initial, most IgLλ+ B cells are generated earlier and before IgH rearrangements, while most IgLκ+ B cells later and after IgH rearrangements, (2) the second IgLκ rearrangement can occur after IgLλ rearrangement, (3) early formed B cells bear only single in-frame IgH rearrangements, (4) many IgLκ+ B cells carry IgLλ rearrangements that can be productive and occurring on both alleles in one cell, and (5) although VpreB and λ5 genes are present in swine, they are preferentially expressed in non-B cells. In summary, our findings reveal that swine use an alternative B cell developmental pathway as compared to mice and humans.The adenosine nucleotide translocase (ANT) family of proteins are inner mitochondrial membrane proteins involved in energy homeostasis and cell death. The primary function of ANT proteins is to exchange cytosolic ADP with matrix ATP, facilitating the export of newly synthesized ATP to the cell while providing new ADP substrate to the mitochondria. As such, the ANT proteins are central to maintaining energy homeostasis in all eukaryotic cells. Evidence also suggests that the ANTs constitute a pore-forming component of the mitochondrial permeability transition pore (MPTP), a structure that forms in the inner mitochondrial membrane that is thought to underlie regulated necrotic cell death. Additionally, emerging studies suggest that ANT proteins are also critical for mitochondrial uncoupling and for promoting mitophagy. Thus, the ANTs are multifunctional proteins that are poised to participate in several aspects of mitochondrial biology and the greater regulation of cell death, which will be discussed here.The mitochondrial permeability transition, an established mechanism for heart diseases, is a long-standing mystery of mitochondrial biology and a prime drug target for cardioprotection. Several hypotheses about its molecular nature have been put forward over the years, and the prevailing view is that permeabilization of the inner mitochondrial membrane follows opening of a high-conductance channel, the permeability transition pore, which is also called mitochondrial megachannel or multiconductance channel. The permeability transition strictly requires matrix Ca2+ and is favored by the matrix protein cyclophilin D, which mediates the inhibitory effects of cyclosporin A. Here we provide a review of the field, with specific emphasis on the possible role of the adenine nucleotide translocator and of the F-ATP synthase in channel formation, and on currently available small molecule inhibitors. While the possible mechanisms through which the adenine nucleotide translocator and the F-ATP synthase might form high-conductance channels remain unknown, reconstitution experiments and site-directed mutagenesis combined to electrophysiology have provided important clues. The hypothesis that more than one protein may act as a permeability transition pore provides a reasonable explanation for current controversies in the field, and holds great promise for the solution of the mystery of the permeability transition.