TDP-43 is a multifunctional DNA/RNA-binding factor that has been implicated in the regulation of neuronal plasticity. TDP-43 has also been identified as the major constituent of the neuronal cytoplasmic inclusions (NCIs) that are characteristic of a range of neurodegenerative diseases, including the frontotemporal lobar degeneration with ubiquitin+ inclusions (FTLD-U) and amyotrophic lateral sclerosis (ALS). We have generated a FTLD-U mouse model (CaMKII-TDP-43 Tg) in which TDP-43 is transgenically overexpressed in the forebrain resulting in phenotypic characteristics mimicking those of FTLD-U. In particular, the transgenic (Tg) mice exhibit impaired learning/memory, progressive motor dysfunction, and hippocampal atrophy. The cognitive and motor impairments are accompanied by reduced levels of the neuronal regulators phospho–extracellular signal-regulated kinase and phosphorylated cAMP response element-binding protein and increased levels of gliosis in the brains of the Tg mice. Moreover, cells with TDP-43+, ubiquitin+ NCIs and TDP-43–deleted nuclei appear in the Tg mouse brains in an age-dependent manner. Our data provide direct evidence that increased levels of TDP-43 protein in the forebrain is sufficient to lead to the formation of TDP-43+, ubiquitin+ NCIs and neurodegeneration. This FTLD-U mouse model should be valuable for the mechanistic analysis of the role of TDP-43 in the pathogenesis of FTLD-U and for the design of effective therapeutic approaches of the disease.
Serratia marcescens has long been recognized as an important opportunistic pathogen, but the underlying pathogenesis mechanism is not completely clear. Here, we report a key pathogenesis pathway in S. marcescens comprising the RssAB two-component system and its downstream elements, FlhDC and the dominant virulence factor hemolysin ShlBA. Expression of shlBA is under the positive control of FlhDC, which is repressed by RssAB signaling. At 37°C, functional RssAB inhibits swarming, represses hemolysin production, and promotes S. marcescens biofilm formation. In comparison, when rssBA is deleted, S. marcescens displays aberrant multicellularity favoring motile swarming with unbridled hemolysin production. Cellular and animal infection models further demonstrate that loss of rssBA transforms this opportunistic pathogen into hypervirulent phenotypes, leading to extensive inflammatory responses coupled with destructive and systemic infection. Hemolysin production is essential in this context. Collectively, a major virulence regulatory pathway is identified in S. marcescens.The Gram-negative bacterium Serratia marcescens is an important opportunistic pathogen that causes a wide range of diseases and clinical presentations with high morbidity (25). S. marcescens frequently causes outbreaks in intensive and neonatal care units, and the occurrence of multiple-antibioticresistant strains has further exacerbated clinical treatment difficulties (3, 39). Despite years of study, the mechanism of pathogenesis of S. marcescens and why it behaves as an opportunistic pathogen remain poorly understood. Unraveling the underlying mechanism of pathogenesis is thus very important for developing strategies to prevent and treat S. marcescens infection.The hemolysin ShlA was shown to be a dominant virulence factor in S. marcescens pathogenesis using a murine lung infection model (35). ShlA is responsible for the hemolytic and cytotoxic effects on erythrocytes and cultured cells, with the aid of an outer membrane protein, ShlB (28,29,47,53,54). ShlA also contributes to the release of inflammatory mediators, increases uropathogenicity, and triggers microtubule-dependent invasion of S. marcescens into epithelial cells (27,30,34,40). However, the mechanism by which the expression of shlA is regulated, especially in response to any bacterial signaling system control, remains uncharacterized. Only one reported study has indicated that iron is involved in the regulation of shlBA expression in S. marcescens (46). S. marcescens exhibits swarming, which is recognized as a highly coordinated multicellular surface migration behavior (24,51,62) that is correlated with virulence capability, antibiotic resistance, and hemolysin production in other bacteria (1,17,44). S. marcescens swarms on Luria-Bertani (LB) agar surfaces at 30°C, but not at 37°C (36). Our previous studies showed that activation of a bacterial two-component system, RssAB, comprising a sensor kinase, RssA, and a response regulator, RssB, inhibited swarming and reduced hemolysin productio...
Metal-mediated base pairs have been extensively utilized in many research fields, including genetic-code extension, novel therapeutics development, and nanodevice design. Compared to other cations, Ag is more flexible in pairing with natural base pairs. Herein, we present a DNA structure containing two C-Ag -C pairs and the first reported G-Ag -G pair in a short 8mer DNA strand. This structure not only provides detailed insight into these Ag -mediated base-pairing patterns in DNA, but also represents the first nonhelical DNA structure driven by heavy-metal ions, thus further contributing to the structural diversity of DNA. This unique complex structure is highly sequence-dependent, thus implying functional potentials as a new DNA aptamer that can bind and recognize silver ions. These results not only advance our understanding of the interactions between Ag and nucleobases, but also provide a unique structural component for the rational design of new DNA nanodevices.
These data suggest that miR-592 may promote the progression and metastasis, in part, by targeting FoxO3A in CRC. miR-592 may be a novel target for CRC treatment and antagomir-592 may inhibit the proliferation and metastasis of CRC cells.
Mitochondrial nucleases play important roles in accurate maintenance and correct metabolism of mtDNA, the own genetic materials of mitochondria that are passed exclusively from mother to child. MGME1 is a highly conserved DNase that was discovered recently. Mutations in MGME1-coding gene lead to severe mitochondrial syndromes characterized by external ophthalmoplegia, emaciation, and respiratory failure in humans. Unlike many other nucleases that are distributed in multiple cellular organelles, human MGME1 is a mitochondria-specific nuclease; therefore, it can serve as an ideal target for treating related syndromes. Here, we report one HsMGME1-Mn2+ complex and three different HsMGME1-DNA complex structures. In combination with in vitro cleavage assays, our structures reveal the detailed molecular basis for substrate DNA binding and/or unwinding by HsMGME1. Besides the conserved two-cation-assisted catalytic mechanism, structural analysis of HsMGME1 and comparison with homologous proteins also clarified substrate binding and cleavage directionalities of the DNA double-strand break repair complexes RecBCD and AddAB.
Initiation of Myxococcus xanthus multicellular development requires integration of information concerning the cells' nutrient status and density. A gain-of-function mutation, sasB7, that bypasses both the starvation and high cell density requirements for developmental expression of the 4521 reporter gene, maps to the sasS gene. The wild-type sasS gene was cloned and sequenced. This gene is predicted to encode a sensor histidine protein kinase that appears to be a key element in the transduction of starvation and cell density inputs. The sasS null mutants express 4521 at a basal level, form defective fruiting bodies, and exhibit reduced sporulation efficiencies. These data indicate that the wild-type sasS gene product functions as a positive regulator of 4521 expression and participates in M. xanthus development. The N terminus of SasS is predicted to contain two transmembrane domains that would locate the protein to the cytoplasmic membrane. The sasB7 mutation, an E139K missense mutation, maps to the predicted N-terminal periplasmic region. The C terminus of SasS contains all of the conserved residues typical of the sensor histidine protein kinases. SasS is predicted to be the sensor protein in a two-component system that integrates information required for M. xanthus developmental gene expression. Multicellular development of Myxococcus xanthus is initiatedby nutrient limitation and proceeds only if these gram-negative soil bacteria are at high density. More than 10 5 cells aggregate to form an organized mound, termed a fruiting body, inside of which the rod-shaped cells differentiate into environmentally resistant ovoid myxospores. This developmental program ensures the survival of the organism until nutrients are available and the spores can germinate (10, 11).M. xanthus cells sense their nutrient status and density by using two different signals. Nutrient limitation is sensed, at least in part, by a rise in intracellular guanosine penta-and tetraphosphate ([p]ppGpp) levels (55). Cell density is sensed through A signal, a specific subset of amino acids at an extracellular concentration greater than 10 M (36). The A signal is presumably generated when extracellular proteinases degrade the surface proteins of developing cells (35,49). If the cells are at a density greater than about 3 ϫ 10 8 /ml, apparently the concentration of extracellular amino acids and peptides exceeds the critical A-signal threshold concentration (36). The transduction of the starvation and A signals and integration of this information within the first 1 to 2 h of development allow the cells to determine if conditions are appropriate to proceed through the early stages of fruiting body development (15,26).The expression of one class of genes expressed during early development requires independent input from both starvation and A signals (4, 25). The best characterized member of this class is the gene 4521, whose expression is monitored by a Tn5 lac transcriptional fusion, ⍀4521 (31). In wild-type cells 1 to 2 h after starvation at high de...
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