Manuka honey (MH) is currently used as a wound treatment and suggested to be effective in Methicillin-resistant Staphylococcus aureus (MRSA) elimination. We sought to optimize the synthesis of MH microneedles (MHMs) while maintaining the MH therapeutic effects. MHMs were synthesized using multiple methods and evaluated with in vitro assays. MHMs demonstrated excellent bactericidal activity against MRSA at concentrations ≥ 10% of honey, with vacuum-prepared honey appearing to be the most bactericidal, killing bacterial concentrations as high as 8 × 10 7 CFU/mL. The woundhealing assay demonstrated that, at concentrations of 0.1%, while the cooked honey had incomplete wound closure, the vacuum-treated honey trended towards faster wound closure. In this study, we demonstrate that the method of MHM synthesis is crucial to maintaining MH properties. We optimized the synthesis of MHMs and demonstrated their potential utility in the treatment of MRSA infections as well as in wound healing. This is the first report of using MH as a substrate for the formation of dissolvable microneedles. this data supports the need for further exploration of this new approach in a wound-healing model and opens the door for the future use of MH as a component of microneedle scaffolds. Surgical site infections (SSIs) have historically been associated with increased morbidity and mortality but remain an issue in modern day healthcare. As of 2017, the Centers for Disease Control and Prevention (CDC) estimated that SSIs occurred in at least 1.9% of all surgical patients; however, this number is most likely not representative of the total number of SSI cases since about 50% of SSIs occur after hospital discharge 1,2. MRSA is the most common cause of SSIs leading in an increased morbidity in patients and increased hospital charges 3,4. In a study evaluating the 90-day mortality rate in patients with SSI, it was discovered that patients with a methicillin-resistant Staphylococcus aureus (MRSA) SSI had a 3.40 times increased mortality rate (95% CI, 1.5-7.2) than patients infected with a methicillin-susceptible S. aureus strain 5. Given the health and economic burden attributable,
Prostaglandin F2α (PGF2α) is a potent inhibitor of adipocyte differentiation in vitro, that has also recently been implicated in the regulation of the adipogenic process in vivo, by opposing adipose tissue accretion and the subsequent development of obesity and its attendant metabolic consequences. In previous studies, we have demonstrated that PGF2α inhibits adipocyte differentiation by means of a calcium-dependent signaling pathway that is critically dependent upon the activity of the calcineurin phosphatase. In the current study, we have now extended these findings to further elucidate the mechanism by which the PGF2α/calcineurin-pathway inhibits the adipogenic process. We now report that the IL-11 cytokine, a member of the gp130 cytokine co-receptor-related family, is a downstream transcriptional target of this pathway in 3T3-L1 preadipocytes and is actively secreted in differentiating cells in response to PGF2α stimulation. Using a combined shRNA and dominant-negative receptor mutant approach, we provide evidence that IL-11/gp130-signaling is required to mediate the inhibitory effects of PGF2α on adipogenesis. Moreover, by taking advantage of a well-characterized panel of chimeric gp130 mutant receptors, we demonstrate that gp130 signaling is sufficient to inhibit adipocyte differentiation and specifically requires the activation of the STAT1 transcription factor. Conversely, we find that depleting endogenous STAT1 levels rescues adipogenesis in the presence of both IL-11/gp130 signaling and PGF2α. Collectively, our findings support a model in which PGF2α inhibits adipocyte differentiation by means of an IL-11 mediated autocrine negative feedback loop, that acts via gp130 to block adipogenesis through the essential actions of the STAT1 transcription factor.
Inclusion body nephropathy (IBN) and kidney fibrosis in aged immunodeficient mice and, to lesser extent, in immunocompetent mice have been recently linked to infection of mouse kidney parvovirus (MKPV), also known as murine chapparvovirus (MuCPV). Knowledge about its prevalence and the complete genome sequence of more MKPV strains is essential for understanding phylogenetic relationships and pathogenicity among MKPV strains. In the present study using PCR and genome walking, we determined the complete 4440-nucleotide genome of a new MKPV strain, namely MIT-WI1, which was identified in IBN-affected Il2rg −/-Rag2 −/c-Kit W-sh/W-sh mice housed in the vivarium at Whitehead Institute for Biomedical Research (WI). The overall nucleotide (>94%) and deduced amino acid sequences (>98%) of p10, p15, NS1 (replicase), NS2 and VP1 (capsid protein) within the MIT-WI1 genome, are closely related to MKPV/MuCPV strains described in laboratory and wild Mus musculus mice. In addition, PCR and qPCR assays using newly designed primers conserved among the known MKPV/MuCPV genomes were developed and utilized to assess MKPV status in selected laboratory mice. MKPV was also detected in immunodeficient (NSG) and immunocompetent (Crl:CD1(ICR), UTX flox) mouse strains/stocks. The abundance of the MKPV genome copies was significantly correlated with the severity of IBN. Our data indicate that MKPV is present in selected mouse strains/stocks, and provides new insights into the genome evolution of MKPV.
Klebsiella pneumoniae (Kp) is a gram-negative opportunistic pathogen that causes severe pneumonia, pyelonephritis, and sepsis in immunocompromised hosts. During a 4-mo interval, several NOD.Cg-PrkdcscidIl2rgtm1Wjl/SzJ (NSG) breeders and pups in our facilities were diagnosed with Kp infections. An initial 6 adult and 1 juvenile NSG mice were submitted for necropsy and histologic examination because of acute onset of diarrhea and death. The evaluation revealed typhlocolitis in 2 of the mice and tritrichomoniasis in all 7. Escherichia coli positive for polyketide synthase (pks+) and Kp were isolated from the intestines. Given a history of sepsis due to pks+ E. coli in NSG mice in our facilities and determination of its antimicrobial susceptibility, trimethoprim–sulfamethoxazole (TMP–SMX) was administered to the colony in the drinking water for 4 wk. After this intervention, an additional 21 mice became ill or died; 11 of these mice had suppurative pneumonia, meningoencephalitis, hepatitis, metritis, pyelonephritis, or sepsis. Kp was cultured from pulmonary abscesses or blood of 10 of the mice. Whole-genome sequencing (WGS) indicated that the Kp isolates contained genes associated with phenotypes found in pore-forming Kp isolates cultured from humans with ulcerative colitis and primary sclerosing cholangitis. None of the Kp isolates exhibited a hyperviscous phenotype, but 13 of 14 were resistant to TMP–SMX. Antimicrobial susceptibility testing indicated sensitivity of the Kp to enrofloxacin, which was administered in the drinking water. Antibiotic sensitivity profiles were confirmed by WGS of the Kp strains; key virulence and resistance genes to quaternary ammonia compounds were also identified. Enrofloxacin treatment resulted in a marked reduction in mortality, and the study using the NSG mice was completed successfully. Our findings implicate intestinal translocation of Kp as the cause of pneumonia and systemic infections in NSG mice and highlight the importance of identification of enteric microbial pathogens and targeted antibiotic selection when treating bacterial infections in immunocompromised mice.
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