Membrane-Type 5 Matrix Metalloproteinase Is Expressed in Differentiated Neurons and Regulates Axonal Growth 1

Expression of membrane-type (MT) 5 matrix metalloproteinase (MMP) in the mouse brain was examined. MT5-MMP was expressed in the cerebrum in embryos, but it declined after birth. In contrast, expression in the cerebellum started to increase postnatally and continued thereafter. The cells expressing MT5-MMP were postmitotic neurons that showed gelatinolytic activities. Specific expression of MT5-MMP was observed in the neurons but not in the glial cells when embryonal mouse carcinoma P19 cells were differentiated in vitro by retinoic acid treatment. Neurons isolated from dorsal root ganglia also expressed MT5-MMP, and it was localized at the edge of growth cone. Proteoglycans inhibit neurite extension and regulate synaptogenesis. The inhibitory effect of the proteoglycans on neurite extension of dorsal root ganglia neurons was effectively eliminated by recombinant MT5-MMP. Thus, MT5-MMP expressed in neurons may play a role in axonal growth that contributes to the regulation of neural network formation

Robust Long-term Transduction of Common Marmoset Neuromuscular Tissue With rAAV1 and rAAV9

Profiles of recombinant adeno-associated virus (rAAV)-mediated transduction show interspecies differences for each AAV serotype. Robust long-term transgene expression is generally observed in rodents, whereas insufficient transduction is seen in animals with more advanced immune systems. Non-human primates, including the common marmoset, could provide appropriate models for neuromuscular diseases because of their higher brain functions and physiological resemblance to humans. Strategies to induce pathologies in the neuromuscular tissues of non-human primates by rAAV-mediated transduction are promising; however, transgene expression patterns with rAAV transduction have not been elucidated in marmosets. In this study, transduction of adult marmoset skeletal muscle with rAAV9 led to robust and persistent enhanced green fluorescent protein (EGFP) expression that was independent of the muscle fiber type, although lymphocyte infiltration was recognized. Systemic rAAV injection into pregnant marmosets led to transplacental fetal transduction. Surprisingly, the intraperitoneal injection of rAAV1 and rAAV9 into the neonatal marmoset resulted in systemic transduction and persistent transgene expression without lymphocyte infiltration. Skeletal and cardiac muscle were effectively transduced with rAAV1 and rAAV9, respectively. Interestingly, rAAV9 transduction led to intense EGFP signaling in the axons of the corpus callosum. These transduction protocols with rAAV will be useful for investigating gene functions in the neuromuscular tissues and developing gene therapy strategies

Osteopontin Undergoes Polymerization in Vivo and Gains Chemotactic Activity for Neutrophils Mediated by Integrin α9β1*

Osteopontin (OPN) is an integrin-binding inflammatory cytokine that undergoes polymerization catalyzed by transglutaminase 2. We have previously reported that polymeric OPN (polyOPN), but not unpolymerized OPN (OPN*), attracts neutrophils in vitro by presenting an acquired binding site for integrin α9β1. Among many in vitro substrates for transglutaminase 2, only a few have evidence for in vivo polymerization and concomitant function. Although polyOPN has been identified in bone and aorta, the in vivo functional significance of polyOPN is unknown. To determine whether OPN polymerization contributes to neutrophil recruitment in vivo, we injected OPN* into the peritoneal space of mice. Polymeric OPN was detected by immunoblotting in the peritoneal wash of mice injected with OPN*, and both intraperitoneal and plasma OPN* levels were higher in mice injected with a polymerization-incompetent mutant, confirming that OPN* polymerizes in vivo. OPN* injection induced neutrophil accumulation, which was significantly less following injection of a mutant OPN that was incapable of polymerization. The importance of in vivo polymerization was further confirmed with cystamine, a transglutaminase inhibitor, which blocked the polymerization and attenuated OPN*-mediated neutrophil recruitment. The thrombin-cleaved N-terminal fragment of OPN, another ligand for α9β1, was not responsible for neutrophil accumulation because a thrombin cleavage-incompetent mutant recruited similar numbers of neutrophils as wild type OPN*. Neutrophil accumulation in response to both wild type and thrombin cleavage-incompetent OPN* was reduced in mice lacking the integrin α9 subunit in leukocytes, indicating that α9β1 is required for polymerization-induced recruitment. We have illustrated a physiological role of molecular polymerization by demonstrating acquired chemotactic properties for OPN