Preclinical safety evaluation of human platelets treated with antimicrobial peptides in severe combined immunodeficient mice.

BACKGROUND: Bacterial sepsis is a complication attributed to room temperature (RT)-stored platelets (PLTs) in transfusion medicine. Antimicrobial peptides (AMPs) are emerging as new therapeutic agents against microbes. We had previously demonstrated bactericidal activity of select synthetic AMPs against six types of bacteria in stored PLTs. In this report, we tested these AMPs for their potential antibody response and interference with the recovery and survival of human PLTs in an animal model. STUDY DESIGN AND METHODS: Two separate studies were conducted to evaluate the safety of the synthetic AMPs. 1) Two AMPs (PD3 and PD4), derived from thrombin-induced human PLT microbicidal protein, and four repeats of arginine-tryptophan (RW), containing two to five repeats (RW2-RW5), were tested in rabbits for potential antibody response. 2) RT-stored human PLTs treated for 2 hours with each of the six AMPs individually or with phosphate-buffered saline (PBS) alone were infused into severe combined immunodeficient (SCID) mice to evaluate their in vivo recovery and survival by flow cytometry. RESULTS: Except for PD3, which showed a weak immune response, all other peptides did not induce any detectable antibodies in rabbits. Furthermore, all six AMPs tested did not significantly affect the in vivo recovery and survival of human PLTs in SCID mice compared to PBS alone-treated PLTs. CONCLUSION: Preclinical evaluation studies reported here demonstrate that the selected AMPs used in the study did not adversely affect the human PLT recovery and survival in the SCID mouse model, suggesting further study of AMPs toward addressing the bacterial contamination of PLTs.

Evidence against a human cell-specific role for LRP6 in anthrax toxin entry.

The role of the cellular protein LRP6 in anthrax toxin entry is controversial. Previous studies showed that LRP6 was important for efficient intoxication of human M2182 prostate carcinoma cells but other studies performed with cells from gene-knockout mice demonstrated no role for either LRP6 or the related LRP5 protein in anthrax toxin entry. One possible explanation for this discrepancy is that LRP6 may be important for anthrax toxin entry into human, but not mouse, cells. To test this idea we have investigated the effect of knocking down LRP6 or LRP5 expression with siRNAs in human HeLa cells. We show here that efficient knockdown of either LRP6, LRP5, or both proteins has no influence on the kinetics of anthrax lethal toxin entry or MEK1 substrate cleavage in these cells. These data argue against a human-specific role for LRP6 in anthrax toxin entry and suggest instead that involvement of this protein may be restricted to certain cell types independently of their species of origin.

Receptor-specific requirements for anthrax toxin delivery into cells.

The three proteins that constitute anthrax toxin self-assemble into toxic complexes after one of these proteins, protective antigen (PA), binds to tumor endothelial marker 8 (TEM8) or capillary morphogenesis protein 2 (CMG2) cellular receptors. The toxin receptor complexes are internalized, and acidic endosomal pH triggers pore formation by PA and translocation of the catalytic subunits into the cytosol. In this study we show that the pH threshold for conversion of the PA prepore to the pore and for translocation differs by approximately a pH unit, depending on whether the TEM8 or CMG2 receptor is used. For TEM8-associated toxin, these events can occur at close to neutral pH values, and they show relatively low sensitivity to ammonium chloride treatment in cells. In contrast, with CMG2-associated toxin, these events require more acidic conditions and are highly sensitive to ammonium chloride. We show, furthermore, that PA dissociates from TEM8 and CMG2 upon pore formation. Our results are consistent with a model in which translocation depends on pore formation and pore formation, in turn, depends on release of PA from its receptor. We propose that because PA binds to CMG2 with much higher affinity than it does to TEM8, a lower pH is needed to attenuate CMG2 binding to allow pore formation. Our results suggest that toxin can form pores at different points in the endocytic pathway, depending on which receptor is used for entry.

Overexpression of murine TSLP impairs lymphopoiesis and myelopoiesis.

The role of thymic stromal cell-derived lymphopoietin (TSLP) in regulating hematopoiesis is poorly characterized, so we investigated its regulatory effects in vivo using TSLP transgenic mice. Overexpression of TSLP disrupted hematopoietic homeostasis by causing imbalances in lymphopoiesis and myelopoiesis. Mice harboring a TSLP transgene had 5- to 700-fold fewer B and T precursors and no detectable pre-B lymphocyte colonyforming activity in the marrow or spleen. Conversely, TSLP transgenic mice possessed 15 to 20 times more splenic myeloid precursors than their littermates, and progenitor activity of the granulocyteerythrocyte-macrophage-megakaryocyte colony-forming units was significantly elevated. The arrest in lymphopoiesis and the expansion of myeloid progenitor cells in TSLP transgenic mice suggest that TSLP has negative and positive regulatory effects on lymphoid and myeloid development, respectively.