Mutations in the catalytic domain of human matrix metalloproteinase-1 (MMP-1) that allow for regulated activity through the use of Ca2+.

Conditionally active proteins regulated by a physiological parameter represent a potential new class of protein therapeutics. By systematically creating point mutations in the catalytic and linker domains of human MMP-1, we generated a protein library amenable to physiological parameter-based screening. Mutants screened for temperature-sensitive activity had mutations clustered at or near amino acids critical for metal binding. One mutant, GVSK (Gly(159) to Val, Ser(208) to Lys), contains mutations in regions of the catalytic domain involved in calcium and zinc binding. The in vitro activity of GVSK at 37 °C in high Ca(2+) (10 mm) was comparable with MMP-1 (wild type), but in low Ca(2+) (1 mm), there was an over 10-fold loss in activity despite having similar kinetic parameters. Activity decreased over 50% within 15 min and correlated with the degradation of the activated protein, suggesting that GVSK was unstable in low Ca(2+). Varying the concentration of Zn(2+) had no effect on GVSK activity in vitro. As compared with MMP-1, GVSK degraded soluble collagen I at the high but not the low Ca(2+) concentration. In vivo, MMP-1 and GVSK degraded collagen I when perfused in Zucker rat ventral skin and formed higher molecular weight complexes with α2-macroglobulin, an inhibitor of MMPs. In vitro and in vivo complex formation and subsequent enzyme inactivation occurred faster with GVSK, especially at the low Ca(2+) concentration. These data suggest that the activity of the human MMP-1 mutant GVSK can be regulated by Ca(2+) both in vitro and in vivo and may represent a novel approach to engineering matrix-remodeling enzymes for therapeutic applications.

Hyaluronan accumulates with high-fat feeding and contributes to insulin resistance.

Increased deposition of specific extracellular matrix (ECM) components is a characteristic of insulin-resistant skeletal muscle. Hyaluronan (HA) is a major constituent of the ECM. The hypotheses that 1) HA content is increased in the ECM of insulin-resistant skeletal muscle and 2) reduction of HA in the muscle ECM by long-acting pegylated human recombinant PH20 hyaluronidase (PEGPH20) reverses high-fat (HF) diet-induced muscle insulin resistance were tested. We show that muscle HA was increased in HF diet-induced obese (DIO) mice and that treatment of PEGPH20, which dose-dependently reduced HA in muscle ECM, decreased fat mass, adipocyte size, and hepatic and muscle insulin resistance in DIO mice at 10 mg/kg. Reduced muscle insulin resistance was associated with increased insulin signaling, muscle vascularization, and percent cardiac output to muscle rather than insulin sensitization of muscle per se. Dose-response studies revealed that PEGPH20 dose-dependently increased insulin sensitivity in DIO mice with a minimally effective dose of 0.01 mg/kg. PEGPH20 at doses of 0.1 and 1 mg/kg reduced muscle HA to levels seen in chow-fed mice, decreased fat mass, and increased muscle glucose uptake. These findings suggest that ECM HA is a target for treatment of insulin resistance.

A comprehensive model of hyaluronan turnover in the mouse.

The metabolism of hyaluronan (HA), especially its catabolism, is still far from being elucidated. Although several studies suggest that HA is degraded locally in tissues and through the lymphatic or circulatory systems, much needs to be learned about the enzymes, receptors and cell types that support this dynamic process. In the current work, the clearance of exogenously administered HA was examined in a C57BL/6 mouse model. Hyaluronidase-sensitive fluorescein-labeled 1.2MDa hyaluronan (flHA) was administered either intravenously (i.v.) or subcutaneously (s.c.) into wild type C57BL/6 mice. Plasma was sampled for pharmacokinetic analysis and tissues were harvested for histological examination of the cell types responsible for uptake using immunofluorescent localization and for size exclusion chromatography analysis. We observed that flHA could be degraded locally in the skin or be taken up by sinusoidal cells in lymph nodes, liver and spleen. I.v. administration of flHA revealed non-linear Michaelis-Menten pharmacokinetics compatible with a saturable, receptor-mediated clearance system (K(m)=11.6µg/ml±46.0%, V(max)=1.69µg/ml/min±59.7%). Through a combination of immunofluorescence microscopy, pharmacokinetic, and chromatographic analyses of labeled substrate in vivo, our results shed additional light on the mechanisms by which HA is catabolized in mammals, and serve as a basis for future studies.

Enzymatic depletion of tumor hyaluronan induces antitumor responses in preclinical animal models.

Hyaluronan (HA) is a glycosaminoglycan polymer that often accumulates in malignancy. Megadalton complexes of HA with proteoglycans create a hydrated connective tissue matrix, which may play an important role in tumor stroma formation. Through its colloid osmotic effects, HA complexes contribute to tumor interstitial fluid pressure, limiting the effect of therapeutic molecules on malignant cells. The therapeutic potential of enzymatic remodeling of the tumor microenvironment through HA depletion was initially investigated using a recombinant human HA-degrading enzyme, rHuPH20, which removed HA-dependent tumor cell extracellular matrices in vitro. However, rHuPH20 showed a short serum half-life (t(1/2) < 3 minutes), making depletion of tumor HA in vivo impractical. A pegylated variant of rHuPH20, PEGPH20, was therefore evaluated. Pegylation improved serum half-life (t(1/2) = 10.3 hours), making it feasible to probe the effects of sustained HA depletion on tumor physiology. In high-HA prostate PC3 tumors, i.v. administration of PEGPH20 depleted tumor HA, decreased tumor interstitial fluid pressure by 84%, decreased water content by 7%, decompressed tumor vessels, and increased tumor vascular area >3-fold. Following repeat PEGPH20 administration, tumor growth was significantly inhibited (tumor growth inhibition, 70%). Furthermore, PEGPH20 enhanced both docetaxel and liposomal doxorubicin activity in PC3 tumors (P < 0.05) but did not significantly improve the activity of docetaxel in low-HA prostate DU145 tumors. The ability of PEGPH20 to enhance chemotherapy efficacy is likely due to increased drug perfusion combined with other tumor structural changes. These results support enzymatic remodeling of the tumor stroma with PEGPH20 to treat tumors characterized by the accumulation of HA.