HemaMax™, a recombinant human interleukin-12, is a potent mitigator of acute radiation injury in mice and non-human primates.

HemaMax, a recombinant human interleukin-12 (IL-12), is under development to address an unmet medical need for effective treatments against acute radiation syndrome due to radiological terrorism or accident when administered at least 24 hours after radiation exposure. This study investigated pharmacokinetics, pharmacodynamics, and efficacy of m-HemaMax (recombinant murine IL-12), and HemaMax to increase survival after total body irradiation (TBI) in mice and rhesus monkeys, respectively, with no supportive care. In mice, m-HemaMax at an optimal 20 ng/mouse dose significantly increased percent survival and survival time when administered 24 hours after TBI between 8-9 Gy (p<0.05 Pearson's chi-square test). This survival benefit was accompanied by increases in plasma interferon-γ (IFN-γ) and erythropoietin levels, recovery of femoral bone hematopoiesis characterized with the presence of IL-12 receptor ß2 subunit-expressing myeloid progenitors, megakaryocytes, and osteoblasts. Mitigation of jejunal radiation damage was also examined. At allometrically equivalent doses, HemaMax showed similar pharmacokinetics in rhesus monkeys compared to m-HemaMax in mice, but more robustly increased plasma IFN-γ levels. HemaMax also increased plasma erythropoietin, IL-15, IL-18, and neopterin levels. At non-human primate doses pharmacologically equivalent to murine doses, HemaMax (100 ng/Kg and 250 ng/Kg) administered at 24 hours after TBI (6.7 Gy/LD(50/30)) significantly increased percent survival of HemaMax groups compared to vehicle (p<0.05 Pearson's chi-square test). This survival benefit was accompanied by a significantly higher leukocyte (neutrophils and lymphocytes), thrombocyte, and reticulocyte counts during nadir (days 12-14) and significantly less weight loss at day 12 compared to vehicle. These findings indicate successful interspecies dose conversion and provide proof of concept that HemaMax increases survival in irradiated rhesus monkeys by promoting hematopoiesis and recovery of immune functions and possibly gastrointestinal functions, likely through a network of interactions involving dendritic cells, osteoblasts, and soluble factors such as IL-12, IFN-γ, and cytoprotectant erythropoietin.

Expression of intracellular filament, collagen, and collagenase genes in diabetic and normal skin after injury.

Reports have shown differences in gene expression in the skin of diabetic and normal mice both at baseline and after injury. Cluster analysis identified distinct expression patterns within intermediate filaments and extracellular proteins. This report addresses the effect of diabetes and injury on the expression of keratin-associated proteins, keratin complexes, procollagen, and collagenase (matrix metalloproteinase; MMP) genes. At baseline keratin-associated proteins and keratin complexes gene expression was increased in diabetic mice. After surgery, the level of expression for keratin-associated proteins and keratin complexes genes decreased in diabetic mice, but did not change in normal mice. If the expression of a procollagen gene differed between diabetic and normal mice, the expression was lower in diabetic mice. Procollagen gene expression was elevated after skin excision compared with noninjured skin. At baseline, the level of MMP and tissue inhibitor of metalloproteinase gene expression was comparable between mouse strains. With injury, the expression of several MMP genes was increased in both mouse strains, but to higher levels in diabetic mice. At day 7, the level of MMP-9 activity in granulation tissue was elevated. This alteration may contribute to delayed healing in diabetic mice. Therefore, differences in gene expression exist between mouse strains and can assist in understanding of physiological manifestations, including delayed healing, in diabetic mice.

Effect of NorLeu3-A(1-7) on scar formation over time after full-thickness incision injury in the rat.

Previous studies have shown that the angiotensin peptide NorLeu3-A(1-7) accelerates dermal healing and reduces scar formation. In this report, the effect of this peptide on scar formation is more fully delineated. The effect of surgical day, time after injury, and observer on the clinical appearance of the incision were determined. Clinical observations of incision site, including inflammation, opening of the injury, and appearance of scar, were conducted by two observers blinded to treatment (two observations per time point) twice weekly. Opening of the incision occurred in 35-40% of incisions early (days 4 and 7) after injury. Administration of NorLeu3-A(1-7) at the time of injury reduced the incidence of opening at day 7 to approximately 20%. Further, the length of the wound opening was significantly reduced in the peptide-treated incisions at day 7. Starting on day 14 after injury, scar formation was evaluated. Up to 80-90% of control animals had observable scars starting on day 14. Thereafter, the scar remodeled with fewer incisions having visible scar on day 28. With administration of NorLeu3-A(1-7), significantly fewer incisions had observable scars starting on day 14 and throughout the study. As few as 20% of the incisions had observable scars on day 28. The histological appearance of the healing wound was also evaluated at weekly intervals starting on day 7 and continued until day 42. At day 7, the maximal number of fibroblasts at the wound site was observed. Thereafter, the number gradually reduced, reaching a plateau at day 28. The administration of peptide had no effect on fibroblast number at the incision site. A similar pattern was observed in the thickness of the epidermis with the resolution of the hyperplastic phase at day 21. Administration of the peptide significantly increased epidermal height at day 7. Blood vessel formation peaked on day 21 and 28 in control wounds and was further enhanced by peptide administration during the neovascularization phase. After day 28, blood vessel number was comparable between control and treated incisions. Collagen deposition and remodeling were increased by the administration of NorLeu3-A(1-7) at the time of injury.

Synergistic effects of co-administration of angiotensin 1-7 and Neupogen on hematopoietic recovery in mice.

PURPOSE: Angiotensin 1-7 [A(1-7)] is a seven amino acid peptide that has been shown to increase the proliferation of epidermal stem cells after dermal injury and the number of hematopoietic progenitors in the bone marrow of myelosuppressed mice. In this study, the effect of combining A(1-7) with Neupogen on hematopoietic recovery and bone marrow progenitors was evaluated. MATERIALS AND METHODS: Intravenous 5-fluorouracil (5FU) was administered to induce myelosuppression. Administration of A(1-7) and/or Neupogen was initiated 2 days after chemotherapy. Angiotensin II (AII) and A(1-7) binding were assessed by flow cytometric analysis. Hematopoietic progenitors were counted by colony forming assays. Recovery of formed elements in the blood was evaluated by hemocytometer. RESULTS: Flow cytometric analysis indicated that the number of early hematopoietic progenitors (Lin(-)Sca1(+)cKit(+)) that bind AII or A(1-7) increased 5-7 days after intravenous injection of 150 mg/kg 5FU. Further, administration of A(1-7) led to a slight increase in the number of circulating leukocytes and platelets after this chemotherapeutic regimen. When given in combination with a subclinical dose of Neupogen, a synergistic effect on the number of circulating leukocytes was observed, but there was no further effect on the number of circulating platelets. In myelosuppressed mice, A(1-7) had its most profound effect on the number of hematopoietic progenitors in the bone marrow. The progenitors evaluated in the study included BFU-E, CFU-Meg, CFU-GM and CFU-GEMM. There was an increase in the number of these progenitors in the bone marrow, indicating an effect on all hematopoietic lineages. When given in combination with Neupogen, these effects were synergistic for the numbers of BFU-E and CFU-Meg (Neupogen by itself had no effect) and for the myeloid progenitors at lower doses of A(1-7). CONCLUSIONS: These results suggest that these hematopoietic agents act at different sites within the hematopoietic cascade and that combining these two agents may be of benefit in the treatment of hematopoietic disorders.