A comparative study of matrix metalloproteinase and aggrecanase mediated release of latent cytokines at arthritic joints.

BACKGROUND: Latent cytokines are engineered by fusing the latency associated peptide (LAP) derived from transforming growth factor-ß (TGF-ß) with the therapeutic cytokine, in this case interferon-ß (IFN-ß), via an inflammation-specific matrix metalloproteinase (MMP) cleavage site. OBJECTIVES: To demonstrate latency and specific delivery in vivo and to compare therapeutic efficacy of aggrecanase-mediated release of latent IFN-ß in arthritic joints to the original MMP-specific release. METHODS: Recombinant fusion proteins with MMP, aggrecanase or devoid of cleavage site were expressed in CHO cells, purified and characterised in vitro by Western blotting and anti-viral protection assays. Therapeutic efficacy and half-life were assessed in vivo using the mouse collagen-induced arthritis model (CIA) of rheumatoid arthritis and a model of acute paw inflammation, respectively. Transgenic mice with an IFN-regulated luciferase gene were used to assess latency in vivo and targeted delivery to sites of disease. RESULTS: Efficient localised delivery of IFN-ß to inflamed paws, with low levels of systemic delivery, was demonstrated in transgenic mice using latent IFN-ß. Engineering of latent IFN-ß with an aggrecanase-sensitive cleavage site resulted in efficient cleavage by ADAMTS-4, ADAMTS-5 and synovial fluid from arthritic patients, with an extended half-life similar to the MMP-specific molecule and greater therapeutic efficacy in the CIA model. CONCLUSIONS: Latent cytokines require cleavage in vivo for therapeutic efficacy, and they are delivered in a dose dependent fashion only to arthritic joints. The aggrecanase-specific cleavage site is a viable alternative to the MMP cleavage site for the targeting of latent cytokines to arthritic joints.

Molecular engineering of short half-life small peptides (VIP, αMSH and γ3MSH) fused to latency-associated peptide results in improved anti-inflammatory therapeutics.

OBJECTIVE: To facilitate the targeting to inflammation sites of small anti-inflammatory peptides, with short half-lives, by fusion with the latency-associated peptide (LAP) of transforming growth factor ß1 through a cleavable matrix metalloproteinase (MMP) linker. This design improves efficacy, overcoming the limitations to their clinical use. METHODS: We generated latent forms of vasoactive intestinal peptide (VIP), α-melanocyte-stimulating hormone (MSH) and γ(3)MSH by fusion to LAP through an MMP cleavage site using recombinant DNA technology. The biological activities of these latent therapeutics were studied in vivo using monosodium urate (MSU)-induced peritonitis and collagen-induced arthritis (CIA) models. We assessed gene therapy and purified protein therapy. RESULTS: The recruitment of the polymorphonuclear cells induced by MSU injection into mouse peritoneal cavity was reduced by 35% with γ(3)MSH (1 nmol), whereas administration of a much lower dose of purified latent LAP-MMP-γ(3)MSH (0.03 nmol) attenuated leucocyte influx by 50%. Intramuscular gene delivery of plasmids coding LAP-MMP-VIP and LAP-MMP-αMSH at disease onset reduced the development of CIA compared with LAP-MMP, which does not contain any therapeutic moiety. Histological analysis confirmed a significantly lower degree of inflammation, bone and cartilage erosion in groups treated with LAP-MMP-VIP or LAP-MMP-αMSH. Antibody titres to collagen type II and inflammatory cytokine production were also reduced in these two groups. CONCLUSION: Incorporation of small anti-inflammatory peptides within the LAP shell and delivered as recombinant protein or through gene therapy can control inflammatory and arthritic disease. This platform delivery can be developed to control human arthritides and other autoimmune diseases.