Protected graft copolymer excipient leads to a higher acute maximum tolerated dose and extends residence time of vasoactive intestinal Peptide significantly better than sterically stabilized micelles.

PURPOSE: To determine and compare pharmacokinetics and toxicity of two nanoformulations of Vasoactive Intestinal Peptide (VIP). METHODS: VIP was formulated using a micellar (Sterically Stabilized Micelles, SSM) and a polymer-based (Protected Graft Copolymer, PGC) nanocarrier at various loading percentages. VIP binding to the nanocarriers, pharmacokinetics, blood pressure, blood chemistry, and acute maximum tolerated dose (MTD) of the formulations after injection into BALB/c mice were determined. RESULTS: Both formulations significantly extend in vivo residence time compared to unformulated VIP. Formulation toxicity is dependent on loading percentage, showing major differences between the two carrier types. Both formulations increase in vivo potency of unformulated VIP and show acute MTDs at least 140 times lower than unformulated VIP, but still at least 100 times higher than the anticipated highest human dose, 1-5 µg/kg. These nanocarriers prevented a significant drop in arterial blood pressure compared to unformulated VIP. CONCLUSIONS: While both carriers enhance in vivo residence time compared to unformulated VIP and reduce the drop in blood pressure immediately after injection, PGC is the excipient of choice to extend residence time and improve the safety of potent therapeutic peptides such as VIP.

Extending residence time and stability of peptides by protected graft copolymer (PGC) excipient: GLP-1 example.

PURPOSE: To determine whether a Protected Graft Copolymer (PGC) containing fatty acid can be used as a stabilizing excipient for GLP-1 and whether PGC/GLP-1 given once a week can be an effective treatment for diabetes. METHODS: To create a PGC excipient, polylysine was grafted with methoxypolyethyleneglycol and fatty acid at the epsilon amino groups. We performed evaluation of the binding of excipient to GLP-1, the DPP IV sensitivity of GLP-1 formulated with PGC as the excipient, the in vitro bio-activity of excipient-formulated GLP-1, the in vivo pharmacokinetics of excipient-formulated GLP-1, and the efficacy of the excipient-formulated GLP-1 in diabetic rats. RESULTS: We showed reproducible synthesis of PGC excipient, high affinity binding of PGC to GLP-1, slowed protease degradation of excipient-formulated GLP-1, and that excipient-formulated GLP-1 induced calcium influx in INS cells. Excipient-formulated GLP-1 stays in the blood for at least 4 days. When excipient-formulated GLP-1 was given subcutaneously once a week to diabetic ZDF rats, a significant reduction of HbA1c compared to control was observed. The reduction is similar to diabetic ZDF rats given exendin twice a day. CONCLUSIONS: PGC can be an ideal in vivo stabilizing excipient for biologically labile peptides.

Protected graft copolymer (PGC) basal formulation of insulin as potentially safer alternative to Lantus® (insulin-glargine): a streptozotocin-induced, diabetic Sprague Dawley rats study.

PURPOSE: To develop a long-acting formulation of native human insulin with a similar pharmacodynamics (PD) profile as the insulin analogue insulin glargine (Lantus®, Sanofi-Aventis) with the expectation of retaining native human insulin's superior safety profile as insulin glargine is able to activate the insulin-like growth factor 1 (IGF-1) receptor and is linked to a number of malignancies at a higher rate than regular human insulin. METHODS: Development of protected graft copolymer (PGC) excipients that bind native human insulin non-covalently and testing blood glucose control obtained with these formulations in streptozotocin-induced diabetic Sprague Dawley rats compared to equally dosed insulin glargine. RESULTS: PGC-formulations of native human insulin are able to control blood glucose to the same extent and for the same amount of time after s.c. injection as the insulin analogue insulin glargine. No biochemical changes were made to the insulin that would change receptor binding and activation with their possible negative effects on the safety of the insulin. CONCLUSION: Formulation with the PGC excipient offers a viable alternative to biochemically changing insulin or other receptor binding peptides to improve PD properties.

Cytotoxic herpes simplex type 2-specific, DQ0602-restricted CD4 T+-cell clones show alloreactivity to DQ0601.

Alloreactivity is one of the most serious problems in organ transplantation. It has been hypothesized that pre-existing alloreactive T cells are actually cross-reacting cells that have been primed by the autologous major histocompatibility complex (MHC) and a specific peptide. CD8+ cytotoxic T lymphocytes that are alloreactive and recognize a virus-peptide that is presented by the autologous MHC have been reported. Here we demonstrate a cross-reactivity that exists between DQ0602 restricted, herpes simplex type 2 VP16 40-50 specific CD4+ T-cell clones, which can be alloreactive to DQ0601. Though most of the DQ0602 restricted T-cell clones we isolated from two different donors were not alloreactive, weakly cross-reacting T-cell clones could be isolated from both donors. Two strongly cross-reacting T-cell clones with high affinity interaction of their T-cell receptor (TCR) with both DQ0602/VP16 40-50 and DQ0601 could be isolated from one donor. DNA sequencing of the a fragment of the Vbeta gene used in their TCR confirmed that these two T cells indeed are two independent clones. These clones are cytotoxic and produce cytokines of a T helper 2-like pattern. Possible implications in a DR-matched transplantation setting are discussed.

Islet-specific glucose-6-phosphatase catalytic subunit-related protein-reactive CD4+ T cells in human subjects.

Islet-specific glucose-6-phosphatase catalytic subunit-related protein (IGRP) is recognized as a major autoantigen for autoimmune type 1 diabetes (T1D) in the NOD mouse model. This study was undertaken to examine CD4+ T cell responses toward IGRP in human subjects. The tetramer-guided epitope mapping approach was used to identify IGRP-specific CD4+ T cell epitopes. IGRP(23-35) and IGRP(247-259) were identified as DRA1*0101/DRB1*0401-restricted epitopes. IGRP(13-25) and IGRP(226-238) were identified as DRA1*0101/DRB1*0301-restricted epitopes. IGRP-specific tetramers were used to evaluate the prevalence of IGRP-reactive T cells in healthy and T1D subjects. More than 80% of subjects with either DRB1*0401 or DRB1*0301 haplotype have IGRP-specific CD4+ T cell responses for at least one IGRP epitope. IGRP-specific T cells from both healthy and T1D groups produce both gamma-IFN and IL-10. DRA1*0101/DRB1*0401 IGRP(247-259)-restricted T cells also show cross-reactivity to an epitope derived from liver/kidney glucose-6-phosphatase. The detection of IGRP-reactive T cells in both type 1 diabetic subjects and healthy subjects and recent reports of other autoreactive T cells detected in healthy subjects underscore the prevalence of potentially autoreactive T cells in the peripheral immune system of the general population.

Mutational analysis of critical residues determining antigen presentation and activation of HLA-DQ0602 restricted T-cell clones.

Three different HLA-DQ0602 restricted T-lymphocyte clones (clones 5, 44, and 48) specific for two different Herpes simplex virus type 2 (HSV-2) VP16 peptides were used in a series of proliferation assays with BLS-1 cell lines expressing mutated HLA-DQ0604 molecules as APC. Up to four residues in the peptide-binding region of DQ0604 were replaced by the respective DQ0602 residue. For all three clones, residue beta70 played a crucial role in TCR recognition; beta30 and beta57 were important, although beta86 was less significant. Clone 5 and 48, specific to the HSV-2 VP16 369--379 peptide, responded to the same mutated DQ0604 molecules. Both clones could be stimulated only when the antigen presenting DQ molecule contained the DQ0602-like Gly at position beta70. Stimulation of clone 44, which recognized a different HSV-2 VP16 epitope (VP16 40-50), was less restricted. Molecular homology modeling showed that the beta70Arg of DQ0604 partially covered the peptide around P5/P6. Interactions of beta70 with residues from the antigen-peptide and polymorphic residues at positions beta30 and beta57 can modulate this effect. Supported by molecular modeling data, we conclude that the distinct molecular topography of DQ0602 is not contributed by a single residue, but rather the interactions of various polymorphic DQ residues with particular antigenic peptides.

HLA class II tetramers: tools for direct analysis of antigen-specific CD4+ T cells.

Immunotherapies for human autoimmune and immune-mediated diseases are proliferating rapidly, and with these changes comes the opportunity to monitor patients for immune responses to therapy based on early surrogate markers for clinical responses. Class II tetramers have the potential to serve as these sorts of markers for immune monitoring, and thereby assist with patient management, therapy selection, and improved outcomes. However, important issues of TCR avidity require resolution, because much is still unknown regarding location, quantitation, and characterization of the human T cell response. Opportunities for application of tetramer technologies in the near future will enable both clinical progress and the development of new insights into human CD4+ T cell biology in vivo.