Poly(ADP-ribose) polymerase-1 (PARP-1) is an abundant nuclear enzyme that modifies substrates by poly(ADP-ribose)-ylation. PARP-1 has well-described functions in DNA damage repair, and also functions as a context-specific regulator of transcription factors. Using multiple models, data demonstrate that PARP-1 elicits pro-tumorigenic effects in androgen receptor (AR)-positive prostate cancer (PCa) cells, both in the presence and absence of genotoxic insult. Mechanistically, PARP-1 is recruited to sites of AR function, therein promoting AR occupancy and AR function. It was further confirmed in genetically-defined systems that PARP-1 supports AR transcriptional function, and that in models of advanced PCa, PARP-1 enzymatic activity is enhanced, further linking PARP-1 to AR activity and disease progression. In vivo analyses demonstrate that PARP-1 activity is required for AR function in xenograft tumors, as well as tumor cell growth in vivo and generation and maintenance of castration-resistance. Finally, in a novel explant system of primary human tumors, targeting PARP-1 potently suppresses tumor cell proliferation. Collectively, these studies identify novel functions of PARP-1 in promoting disease progression, and ultimately suggest that the dual functions of PARP-1 can be targeted in human PCa to suppress tumor growth and progression to castration-resistance.
Yersinia pestis, the causative agent of plague, expresses the Psa fimbriae (pH 6 antigen) in vitro and in vivo. To evaluate the potential virulence properties of Psa for pneumonic plague, an Escherichia coli strain expressing Psa was engineered and shown to adhere to three types of human respiratory tract epithelial cells. Psa binding specificity was confirmed with Psa-coated polystyrene beads and by inhibition assays. Individual Y. pestis cells were found to be able to express the capsular antigen fraction 1 (F1) concomitantly with Psa on their surface when analyzed by flow cytometry. To better evaluate the separate effects of F1 and Psa on the adhesive and invasive properties of Y. pestis, isogenic ⌬caf (F1 genes), ⌬psa, and ⌬caf ⌬psa mutants were constructed and studied with the three respiratory tract epithelial cells. The ⌬psa mutant bound significantly less to all three epithelial cells compared to the parental wild-type strain and the ⌬caf and ⌬caf ⌬psa mutants, indicating that Psa acts as an adhesin for respiratory tract epithelial cells. An antiadhesive effect of F1 was clearly detectable only in the absence of Psa, underlining the dominance of the Psa ؉ phenotype. Both F1 and Psa inhibited the intracellular uptake of Y. pestis. Thus, F1 inhibits bacterial uptake by inhibiting bacterial adhesion to epithelial cells, whereas Psa seems to block bacterial uptake by interacting with a host receptor that doesn't direct internalization. The ⌬caf ⌬psa double mutant bound and invaded all three epithelial cell types well, revealing the presence of an undefined adhesin(s) and invasin(s).Since the last plague pandemic at the end of the 19th century, its bacterial agent, Yersinia pestis, has been maintained in rodents in several Asian, African, and American countries, including the United States (17, 40). Bubonic plague results from the transmission of Y. pestis by flea bites. In contrast, primary pneumonic plague is acquired when a mammalian host inhales particles or aerosols carrying Y. pestis. Although plague is currently not a major public health problem in developed countries and has been suggested to be less contagious than commonly believed (32), the spread of Y. pestis by aerosols could cause a cluster of human cases of primary pneumonic plague with potential amplification of the outbreak (27).The major adhesins and invasins of enteropathogenic Yersinia pseudotuberculosis and Yersinia enterocolitica (YadA, Ail, and Inv) are not expressed by Y. pestis strains (15,45,51). Thus, how Y. pestis attaches to and translocates through the epithelial layer of the respiratory tract to reach deeper tissues and the bloodstream following airborne transmission remains unknown. Interestingly, Y. pestis exhibits an extensive extracellular lifestyle due to the intracellular delivery of several antiphagocytic effector proteins by its type III secretion system (T3SS-1 or Yops regulon) (5-7, 14, 54, 56). Moreover, two antigenic surface structures exported by usher-chaperone proteins characteristic of fimbrial biogenesis systems...
Background We previously showed that pirfenidone, an anti-fibrotic agent, reduces lung allograft injury/rejection. In this study, we tested the hypothesis that pirfenidone has immune modulating activities and evaluated its effects on the function of T cell subsets, which play important roles in allograft rejection. Method We first evaluated whether pirfenidone alters T cell proliferation and cytokine release in response to T cell receptor (TCR) activation, and whether pirfenidone alters regulatory T cells (CD4+CD25+) suppressive effects using an in vitro assay. Additionally, pirfenidone effects on alloantigen-induced T cell proliferation in vivo were assessed by adoptive transfer of CFSE-labeled T cells across a parent->F1 MHC mismatch, as well as using a murine heterotopic cardiac allograft model (BALB/c->C57BL/6). Results Pirfenidone was found to inhibit the responder frequency of TCR-stimulated CD4+ cell total proliferation in vitro and in vivo, whereas both CD4 and CD8 proliferation index were reduced by pirfenidone. Additionally, pirfenidone inhibited TCR-induced production of multiple pro-inflammatory cytokines and chemokines. Interestingly, there was no change on TGF-β production by purified T cells, and pirfenidone had no effect on the suppressive properties of naturally occurring regulatory T cells. Pirfenidone alone showed a small but significant (p < 0.05) effect on the in vivo allogeneic response while the combination of pirfenidone and low dose rapamycin had more remarkable effect in reducing the alloantigen response with prolonged graft survival. Conclusion Pirfenidone may be an important new agent in transplantation, with particular relevance to combating chronic rejection by inhibiting both fibroproliferative and alloimmune responses.
Pathogenic infections lead to activation of innate immunity followed by induction of a type 1 T cell subset and, therefore, provide a good model to evaluate when T cells commit to type 1 T cells. Here we show a two-step mechanism of T cell subset commitment during pathogenic infection. The first step is mediated by the basal function of macrophage/dendritic cells and is antigen independent. This step modulates the committed precursor frequency of T cell subsets and influences the expression of T-box expressed in T cells (T-bet) and GATA-3 genes. IL-12 and NK cells are not required for this step. The second step requires antigenic stimulation of T cells together with IL-12 or IL-4, and influences on the expression of T-bet and GATA-3. We propose a two-step T cell subset commitment pathway based on these observations. Therefore, pathogenic infections influence functional T cell commitment before T cells encounter nominal antigen.
Eight genomic SSR markers with a M13 tail attached were used to assess the genetic diversity of 72 Ussurian Pear accessions (Pyrus ussuriensis Maxim.) in China. The M13-tailed method was effective in discriminating all the 32 wild accessions. All the 40 Ussurian Pear cultivars could be successfully discriminated with the exception of 4 sets of synonymies or spots. A total of 108 alleles were obtained with an average of 13.5 per locus. The expected heterozygosity, observed heterozygosity, and power of discrimination were 0.78, 0.63, and 0.86 respectively.
Single-dose of intranasal dexmedetomidine was an effective agent for patients under the age of 3 years requiring sedation for transthoracic echocardiography. The 50% effective dose of intranasal dexmedetomidine for transthoracic echocardiography sedation in children aged 13-36 months was higher than in children <13 months.
The morbidity and mortality rates of ischemic stroke (IS) are very high, and IS constitutes one of the main causes of disability and death worldwide. The pathogenesis of ischemic stroke includes excitotoxicity, calcium overload, oxygen radical injury, inflammatory reactions, necrosis/apoptosis, destruction of the blood-brain barrier (BBB), and other pathologic processes. Recent studies have shown that exosomes are critical to the pathogenesis, diagnosis, and treatment of cerebral infarctions resulting from ischemic stroke; and there is growing interest in the role of exosomes and exosomal miRNAs in the diagnosis and treatment of IS. Exosomes from central nervous system cells can be found in cerebrospinal fluid and peripheral bodily fluids, and exosomal contents have been reported to change with disease occurrence. Exosomes are small membranous extracellular vesicles (EVs), 30–150 nm in diameter, that are released from the cell membrane into the depressions that arise from the membranes of multivesicular bodies. Exosomes carry lipids, proteins, mRNAs, and microRNAs (miRNAs) and transport information to target cells. This exosomal transfer of functional mRNAs/miRNAs and proteins ultimately affects transcription and translation within recipient cells. Exosomes are EVs with a double-membrane structure that protects them from ribonucleases in the blood, allowing exosomal miRNAs to be more stable and to avoid degradation. New evidence shows that exosomes derived from neural cells, endothelial cells, and various stem cells create a fertile environment that supports the proliferation and growth of neural cells and endothelial cells, inhibits apoptosis and inflammatory responses, and promotes angiogenesis. In the present review, we discuss how circulating exosomes—and exosomal miRNAs in particular—may provide novel strategies for the early diagnosis and treatment of ischemic stroke via their potential as non-invasive biomarkers and drug carriers.
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