Temporal and spatial characterization of HIV/SIV infection at anorectal mucosa using rhesus macaque rectal challenge model

The study described herein is a continuation of our work in which we developed a methodology to identify small foci of transduced cells following rectal challenge of rhesus macaques with a non-replicative luciferase reporter virus. In the current study, the wild-type virus was added to the inoculation mix and twelve rhesus macaques were necropsied 2-4 days after the rectal challenge to study the changes in infected cell phenotype as the infection progressed. Relying on luciferase reporter we noted that both anus and rectum tissues are susceptible to the virus as early as 48h after the challenge. Small regions of the tissue containing luciferase-positive foci were further analyzed microscopically and were found to also contain cells infected by wild-type virus. Phenotypic analysis of the Env and Gag positive cells in these tissues revealed the virus can infect diverse cell populations, including but not limited to Th17 T cells, non Th17 T cells, immature dendritic cells, and myeloid-like cells. The proportions of the infected cell types, however, did not vary much during the first four days of infection when anus and rectum tissues were examined together. Nonetheless, when the same data was analyzed on a tissue-specific basis, we found significant changes in infected cell phenotypes over the course of infection. For anal tissue, a statistically significant increase in infection was observed for Th17 T cells and myeloid-like cells, while in the rectum, the non-Th17 T cells showed the biggest temporal increase, also of statistical significance.

BM-MSCs-derived microvesicles promote allogeneic kidney graft survival through enhancing micro-146a expression of dendritic cells

OBJECTIVE

Microvesicles (MVs) are plasmalemmal vesicles that are released from various cells and regarded as a mediator of intermolecular communication. In present study, we aimed to evaluate the therapeutic efficacy of the bone marrow mesenchymal stem cells (BM-MSCs)-derived MVs in the mice kidney transplant model and explored the underlying mechanism.

METHODS

BM-MSCs were isolated from C57BL/6 mice and identified using flow cytometry. In vivo allogenic kidney transplantation model of mice was performed between C57BL/6 mice (recipient) and BALB/c mice (donor). Recipient-type BM-MSC (0.1ml) or equal volume of medium as a control was injected i.v. 24h after kidney transplantation. Serum was collected for creatinine concentration detection at 14 d after transplantation. Dendritic cells (DCs) phenotype and miR-146a expression level in plant was identified. Immature DCs (iDCs) and mature DCs (mDCs) were derived from monocytes. MVs were separated from BM-MSCs.

RESULTS

BM-MSCs positive for CD29 (95.8%) and CD44 (94.7%) were cultured and confirmed to prolong the allogenic kidney graft survival in mice. Importantly, the expression of miR-146a increased significantly in DCs of BM-MSCs-treated allogenic kidney. Moreover, both BM-MSCs and MVs derived from BM-MSCs enhanced miR-146a expression in iDCs and mDCs in vitro. Furthermore, MVs substantially reduced IL-12 mRNA expression and IL-12 production of mDCs whereas this action was reversed by miR-146a silencing. MiR-146a silencing also abrogated the MVs-induced decrease in serum creatinine, reduction of immature DCs phenotype in transplant and increase in miR-146a expression level.

CONCLUSION

In summary, our data suggested that the BM-MSCs-derived MVs improved allogenic kidney transplantation survival through inhibiting DCs maturity by miR-146a.

Particulate formulations for the delivery of poly(I:C) as vaccine adjuvant

Current research and development of antigens for vaccination often center on purified recombinant proteins, viral subunits, synthetic oligopeptides or oligosaccharides, most of them suffering from being poorly immunogenic and subject to degradation. Hence, they call for efficient delivery systems and potent immunostimulants, jointly denoted as adjuvants. Particulate delivery systems like emulsions, liposomes, nanoparticles and microspheres may provide protection from degradation and facilitate the co-formulation of both the antigen and the immunostimulant. Synthetic double-stranded (ds) RNA, such as polyriboinosinic acid-polyribocytidylic acid, poly(I:C), is a mimic of viral dsRNA and, as such, a promising immunostimulant candidate for vaccines directed against intracellular pathogens. Poly(I:C) signaling is primarily dependent on Toll-like receptor 3 (TLR3), and on melanoma differentiation-associated gene-5 (MDA-5), and strongly drives cell-mediated immunity and a potent type I interferon response. However, stability and toxicity issues so far prevented the clinical application of dsRNAs as they undergo rapid enzymatic degradation and bear the potential to trigger undue immune stimulation as well as autoimmune disorders. This review addresses these concerns and suggests strategies to improve the safety and efficacy of immunostimulatory dsRNA formulations. The focus is on technological means required to lower the necessary dosage of poly(I:C), to target surface-modified microspheres passively or actively to antigen-presenting cells (APCs), to control their interaction with non-professional phagocytes and to modulate the resulting cytokine secretion profile.