Cancer is fueled by deregulation of signaling pathways in control of cellular growth and proliferation. These pathways are also targeted by infectious pathogens en route to establishing infection. Gallbladder carcinoma (GBC) is frequent in the Indian subcontinent, with chronic Salmonella enterica serovar Typhi infection reported as a significant risk factor. However, direct association and causal mechanisms between Salmonella Typhi infection and GBC have not been established. Deconstructing the epidemiological association between GBC and Salmonella Typhi infection, we show that Salmonella enterica induces malignant transformation in predisposed mice, murine gallbladder organoids, and fibroblasts, with TP53 mutations and c-MYC amplification. Mechanistically, activation of MAPK and AKT pathways, mediated by Salmonella enterica effectors secreted during infection, is critical to both ignite and sustain transformation, consistent with observations in GBC patients from India. Collectively, our findings indicate that Salmonella enterica can promote transformation of genetically predisposed cells and is a causative agent of GBC.
Newly synthesized proteins exit the endoplasmic reticulum (ER) via coat protein complex II (COPII) vesicles. Procollagen (PC), however, forms prefibrils that are too large to fit into typical COPII vesicles; PC thus needs large transport carriers, which we term megacarriers. TANGO1 assists PC packing, but its role in promoting the growth of megacarriers is not known. We found that TANGO1 recruited Sedlin, a TRAPP component that is defective in spondyloepiphyseal dysplasia tarda (SEDT), and that Sedlin was required for the ER export of PC. Sedlin bound and promoted efficient cycling of Sar1, a guanosine triphosphatase that can constrict membranes, and thus allowed nascent carriers to grow and incorporate PC prefibrils. This joint action of TANGO1 and Sedlin sustained the ER export of PC, and its derangement may explain the defective chondrogenesis underlying SEDT.
Every
year three million people die as a result of bacterial infections,
and this number may further increase due to resistance to current
antibiotics. These antibiotics target almost all essential bacterial
processes, leaving only a few new targets for manipulation. The host
proteome has many more potential targets for manipulation in order
to control bacterial infection, as exemplified by the observation
that inhibiting the host kinase Akt supports the elimination of different
intracellular bacteria including Salmonella and M. tuberculosis. If host kinases are involved in the control
of bacterial infections, phosphatases could be as well. Here we present
an integrated small interference RNA and small molecule screen to
identify host phosphatase-inhibitor combinations that control bacterial
infection. We define host phosphatases inhibiting intracellular growth
of Salmonella and identify corresponding inhibitors
for the dual specificity phosphatases DUSP11 and 27. Pathway analysis
places many kinases and phosphatases controlling bacterial infection
in an integrated pathway centered around Akt. This network controls
host cell metabolism, survival, and growth and bacterial survival
and reflect a natural host cell response to bacterial infection. Inhibiting
two enzyme classes with opposite activities–kinases and phosphatases–may
be a new strategy to overcome infections by antibiotic-resistant bacteria.
A cDNA encoding for a copper containing amine oxidase has been isolated and sequenced from young leaves of Euphorbia characias, a perennial mediterranean shrub. A single long open reading frame of 2068 pb encodes a protein composed of 653 amino acids with a molecular mass of about 74 kDa. A putative 24-aminoacid signal peptide precedes the sequence of the mature protein, with characteristics of a secretion signal peptide. Alignments of Euphorbia amine oxidase cDNA nucleotide sequence with that of amine oxidase from the seedlings of the pulses lentil, pea, and chickpea reveal several conserved regions, especially in the C-terminus, with a homology 90%-97%. The near 5' region shows several insertions, deletions, and different nucleotide sequence with ca. 60% homology. The enzyme contains 1%-2% carbohydrate deduced by deglycosylation experiments. Five cysteine residues are present in the deduced aminoacid sequence with a single disulfide bridge as judged by titration with cysteine reagents.
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