Characterization of primitive marrow CD34+ cells that persist after a sublethal dose of total body irradiation

Preclinical IV busulfan dose-finding study to induce reversible myeloablation in a non-human primate model

In this study we utilized a large animal model to identify a dose of intravenous busulfan that can cause reversible myelosuppression. Nine baboons (Papio anubis) were treated with IV busulfan at 6.4 (Group A), 8 (Group B), or 9.6 mg/kg (Group C). Peripheral blood counts were measured up to 90 days after treatment and serial bone marrow samples were obtained to analyze CD34+ cell content and colony forming units. Overall, the highest grade of peripheral blood cytopenia was observed 15 days after treatment in all three groups (n = 3/group). In particular, we observed a notable reduction of neutrophil and platelet counts in the blood and the number of marrow CD34+ cells and colony forming units. In contrast, the effect of busulfan on hemoglobin levels was mild. Baboons who received the highest dose of busulfan showed only a 25-35% recovery of marrow CD34+ cells and colony forming units after 90 days of busulfan administration. However, all three groups of animals showed a full recovery of peripheral blood counts and normal marrow cellularity and tri-lineage hematopoiesis after treatment. Notably, all three doses of busulfan were tolerated well without significant extra-medullary toxicity. These results validate the hierarchy of blood cells likely targeted by busulfan, and based on these findings, clinical trials using myelotoxic but not myeloablative doses of intravenous busulfan will be designed for patients with myeloid malignancies.

miR-363-5p regulates endothelial cell properties and their communication with hematopoietic precursor cells

Recent findings have shown that the blood vessels of different organs exert an active role in regulating organ function. In detail, the endothelium that aligns the vasculature of most organs is fundamental in maintaining organ homeostasis and in promoting organ recovery following injury. Mechanistically, endothelial cells (EC) of tissues such as the liver, lungs or the bone marrow (BM) have been shown to produce “angiocrine” factors that promote organ recovery and restore normal organ function. Controlled production of angiocrine factors following organ injury is therefore essential to promote organ regeneration and to restore organ function. However, the molecular mechanisms underlying the coordinated production and function of such “angiocrine” factors are largely undisclosed and were the subject of the present study. In detail, we identified for the first time a microRNA (miRNA) expressed by BM EC that regulates the expression of angiocrine genes involved in BM recovery following irradiation. Using a microarray-based approach, we identified several miRNA expressed by irradiated BMEC. After validating the variations in miRNA expression by semi-quantitative PCR, we chose to study further the ones showing consistent variations between experiments, and those predicted to regulate (directly or indirectly) angiogenic and angiocrine factors. Of the mi-RNA that were chosen, miR-363-5p (previously termed miR-363*) was subsequently shown to modulate the expression of numerous EC-specific genes including some angiocrine factors. By luciferase reporter assays, miR-363-5p is shown to regulate the expression of angiocrine factors tissue inhibitor of metalloproteinases-1 (Timp-1) and thrombospondin 3 (THBS3) at post-transcriptional level. Moreover, miR-363-5p reduction using anti-miR is shown to affect EC angiogenic properties (such as the response to angiogenic factors stimulation) and the interaction between EC and hematopoietic precursors (particularly relevant in a BM setting). miR-363-5p reduction resulted in a significant decrease in EC tube formation on matrigel, but increased hematopoietic precursor cells adhesion onto EC, a mechanism that is shown to involve kit ligand-mediated cell adhesion. Taken together, we have identified a miRNA induced by irradiation that regulates angiocrine factors expression on EC and as such modulates EC properties. Further studies on the importance of miR-363-5p on normal BM function and in disease are warranted.

Quantitation of peripheral blood markers of rat experimental autoimmune encephalomyelitis

Identification and quantitation of peripheral blood non-invasive, cell-surface markers of EAE disease activity and drug response would facilitate the preclinical development of potential therapeutics. Towards this end, we characterized the influx of immune mediators into spinal cords of diseased rats to establish the kinetics of T cell and monocyte-mediated inflammation. We then examined the periphery for regulation of T cell and monocyte activation. We report increased CD80 and VLA-4 expression on peripheral blood monocytes (PBM) during the onset and peak of experimental disease scores. Increased CD4+, CD62L - and CD4+, CD134+ T cells were detected only at disease peak, not during disease onset. PBM CD80 expression was significantly inhibited in CSA-treated animals, but increased in Dex-treated animals. PBM VLA-4 expression was unaffected by drug treatment. Both CSA and Dex inhibited CD62L shedding and CD134 expression on peripheral CD4+ T cells. These results identify quantitative, peripheral markers of disease activity and drug response.

Chromatin-modifying agents permit human hematopoietic stem cells to undergo multiple cell divisions while retaining their repopulating potential

Human hematopoietic stem cells (HSCs) exposed to cytokines in vitro rapidly divide and lose their characteristic functional properties presumably due to the alteration of a genetic program that determines the properties of an HSC. We have attempted to reverse the silencing of this HSC genetic program by the sequential treatment of human cord blood CD34+ cells with the chromatin-modifying agents, 5-aza-2′-deoxycytidine (5azaD) and trichostatin A (TSA). We determined that all CD34+CD90+ cells treated with 5azaD/TSA and cytokines after 9 days of incubation divide, but to a lesser degree than cells exposed to only cytokines. When CD34+CD90+ cells that have undergone extensive number of cell divisions (5-10) in the presence of cytokines alone were transplanted into immunodeficient mice, donor cell chimerism was not detectable. By contrast, 5azaD/TSA-treated cells that have undergone similar numbers of cell divisions retained their marrow repopulating potential. The expression of several genes and their products previously implicated in HSC self-renewal were up-regulated in the cells treated with 5azaD/TSA as compared to cells exposed to cytokines alone. These data indicate that HSC treated with chromatin-modifying agents are capable of undergoing repeated cell divisions in vitro while retaining their marrow-repopulating potential.

PKC-theta-deficient mice are protected from Th1-dependent antigen-induced arthritis

T cell effector functions contribute to the pathogenesis of rheumatoid arthritis. PKC-theta transduces the signal from the TCR through activation of transcription factors NF-kappaB, AP-1, and NFAT. We examined the effects of PKC-theta deficiency on two Th1-dependent models of Ag-induced arthritis and found that PKC-theta-deficient mice develop disease, but at a significantly diminished severity compared with wild-type mice. In the methylated BSA model, cellular infiltrates and articular cartilage damage were mild in the PKC-theta-deficient mice as compared with wild-type mice. Quantitation of histopathology reveals 63 and 77% reduction in overall joint destruction in two independent experiments. In the type II collagen-induced arthritis model, we observed a significant reduction in clinical scores (p < 0.01) in three independent experiments and diminished joint pathology (p < 0.005) in PKC-theta-deficient compared with wild-type littermates. Microcomputerized tomographic imaging revealed that PKC-theta deficiency also protects from bone destruction. PKC-theta-deficient CD4(+) T cells show an impaired proliferative response, decreased intracellular levels of the cytokines IFN-gamma, IL-2, and IL-4, and significantly diminished cell surface expression of the activation markers CD25, CD69, and CD134/OX40 on memory T cells. We demonstrate decreased T-bet expression and significantly reduced IgG1 and IgG2a anti-collagen II Ab levels in PKC-theta-deficient mice. Collectively, our results demonstrate that PKC-theta deficiency results in an attenuated response to Ag-induced arthritis, which is likely mediated by the reduced T cell proliferation, Th1/Th2 cell differentiation and T cell activation before and during disease peak.