Treatment with halofuginone results in marked growth inhibition of a von Hippel-Lindau pheochromocytoma in vivo.

Halofuginone has recently been shown to inhibit tumor progression of various types of cancers. The antitumoral effect was associated with decreased tumor angiogenesis rather than a direct cytostatic effect on the tumor cells. The antiangiogenic action of the drug could be related to its inhibition of collagen type I synthesis, inhibition of matrix metalloproteinases (MMPs), or via both mechanisms because both collagen synthesis and MMP activity have been shown to be involved in angiogenesis. Vascular endothelial growth factor (VEGF), in addition to its effect on endothelial cell proliferation, has been shown to be a potent inducer of MMP expression. Because von Hippel-Lindau (VHL)-associated tumors express high levels of VEGF, it was of interest to ascertain the potential usefulness of halofuginone for treatment of these tumors. Pheochromocytoma tissue fragments obtained at surgery from a VHL type 2a patient were propagated s.c. in male BALB/c nu/nu (nude) mice. For experiments, 2-3-mm tumor fragments were transplanted secondarily s.c. to nude mice. Two treatment groups received halofuginone in standard lab chow at 3 and 5 ppm; control animals received regular chow. All groups were followed for 6 weeks after transplantation. A marked and significant diminution of tumor size and weight was observed in the drug-treated animals (>90% reduction of mean tumor volume for both the 3 and 5 ppm groups). In vivo magnetic resonance imaging analysis of tumors in halofuginone-treated animals showed a significant reduction of vascular functionality. Immunohistochemical studies revealed decreased collagen type I levels and vascular density in treated tumors and gelatinase assays of tumor extracts revealed a reduction of MMP-2 and MMP-9 activity in halofuginone-treated cells. Taken together, our data indicate that therapy directed at blocking MMP activity (presumably related to excessive VEGF expression in VHL) and reduction of type I collagen deposition curtails angiogenesis and thereby presumably tumor growth in this model system.

Preimplantation factor (PIF*) reverses neuroinflammation while promoting neural repair in EAE model.

INTRODUCTION: Embryo-derived PIF modulates systemic maternal immunity without suppression. Synthetic analog (sPIF) prevents juvenile diabetes, preserves islet function, reducing oxidative stress/protein misfolding. We investigate sPIF effectiveness in controlling neuroinflammation/MS. METHODS: Examine sPIF-induced protection against harsh, clinical-relevant murine EAE-PLP acute and chronic models. Evaluate clinical indices: circulating cytokines, spinal cord histology, genome, canonical global proteome, cultured PLP-activated splenocytes cytokines, and immunophenotype. RESULTS: Short-term, low-dose sPIF prevented paralysis development and lowered mortality (P<0.05). Episodic sPIF reversed chronic paralysis (P<0.0001) completely in >50%, by day 82. Prevention model: 12days post-therapy, sPIF reduced circulating IL12 ten-fold and inflammatory cells access to spinal cord. Regression model: sPIF blocked PLP-induced IL17 and IL6 secretions. Long-term chronic model: sPIF reduced spinal cord pro-inflammatory cytokines/chemokines, (ALCAM, CF1, CCL8), apoptosis-promoters, inflammatory cells access (JAM3, OPA1), solute channels (ATPases), aberrant coagulation factors (Serpins), and pro-antigenic MOG. Canonical proteomic analysis demonstrated reduced oxidative phosphorylation, vesicle traffic, cytoskeleton remodeling involved in neuro-cytoskeleton breakdown (tubulins), associated with axon re-assembly by (MTAPs)/improved synaptic transmission. CONCLUSION: sPIF--through coordinated central and systemic multi-targeted action--reverses neuroinflammation/MS and imparts significant neuroprotective effects up to total paralysis resolution. Clinical testing is warranted and planned.

Preimplantation factor (PIF) analog prevents type I diabetes mellitus (TIDM) development by preserving pancreatic function in NOD mice.

Preimplantation factor (PIF) is a novel embryo-secreted immunomodulatory peptide. Its synthetic analog (sPIF) modulates maternal immunity without suppression. There is an urgent need to develop agents that could prevent the development of type 1 diabetes mellitus (TIDM). Herein, we examine sPIF's preventive effect on TIDM development by using acute adoptive-transfer (ATDM) and spontaneously developing (SDM) in non-obese diabetic (NOD) murine models. Diabetes was evaluated by urinary and plasma glucose, intraperitoneal glucose tolerance test (IPGTT), pancreatic islets insulin staining by immunohistochemistry and by pancreatic proteome evaluation using mass spectrometry, followed by signal pathway analysis. Continuous administration of sPIF for 4-weeks prevents diabetes development in ATDM model in >90% of recipients demonstrated by normal IPGTT, preserved islets architecture, number, and insulin staining. (P < 0.01). sPIF effect was specific; its protective effects are not replicated by scrambled PIF (χ(2) = 0.009) control. sPIF led also to increased circulating Th2 and Th1 cytokines. In SDM model, 4-week continuous sPIF administration prevented onset of diabetes for 21 weeks post-therapy (P < 0.01). Low-dose sPIF administration for 16 weeks prevented diabetes development up to 14 weeks post-therapy, evidenced by preserved islets architecture and insulin staining. In SDM model, pancreatic proteome pathway analysis demonstrated that sPIF regulates protein traffic, prevents protein misfolding and aggregation, and reduces oxidative stress and islets apoptosis, leading to preserved insulin staining. sPIF further increased insulin receptor expression and reduced actin and tubulin proteins, thereby blocking neutrophil invasion and inflammation. Exocrine pancreatic function was also preserved. sPIF administration results in marked prevention of spontaneous and induced adoptive-transfer diabetes suggesting its potential effectiveness in treating early-stage TIDM.

Heparanase upregulates Th2 cytokines, ameliorating experimental autoimmune encephalitis.

Heparanase is an endo-beta-d-glucuronidase that cleaves heparan sulfate (HS) saccharide chains. The enzyme promotes cell adhesion, migration and invasion and plays a significant role in cancer metastasis, angiogenesis and inflammation. The present study focuses on the involvement of heparanase in autoimmunity, applying the murine experimental autoimmune encephalitis (EAE) model, a T-cell dependent disease often used to investigate the pathophysiology of multiple sclerosis (MS). Intraperitoneal administration of recombinant heparanase ameliorated, in a dose dependent manner, the clinical signs of the disease. In vitro and in vivo studies revealed that heparanase inhibited mitogen induced splenocyte proliferation and mixed lymphocyte reaction (MLR) through modulation of their repertoire of cytokines indicated by a marked increase in the levels of IL-4, IL-6 and IL-10, and a parallel decrease in IL-12 and TNF-alpha. Similar results were obtained with active, latent, or point mutated inactive heparanase, indicating that the observed inhibitory effect is attributed to a non-enzymatic activity of the heparanase protein. We suggest that heparanase induces upregulation of Th2 cytokines, resulting in inhibition of the inflammatory lesion of EAE.