Mice Lacking the Extracellular Matrix Protein WARP Develop Normally but Have Compromised Peripheral Nerve Structure and Function-
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- Categories : General motor functions , Motor control , Publications - ID: 222

Authors
J. M. Allen, L. Zamurs, B. Brachvogel, U. Schlötzer-Schrehardt, U. Hansen et al.


Lab
University of Melbourne, Royal Children's Hospital, Murdoch Children's Research Institute and Department of Paediatrics, Parkville, Victoria, Australia.

Journal
The Journal of Biological Chemistry

Abstract
WARP is a recently identified extracellular matrix molecule with restricted expression in permanent cartilages and a distinct subset of basement membranes in peripheral nerves, muscle, and the central nervous system vasculature. WARP interacts with perlecan, and we also demonstrate here that WARP binds type VI collagen, suggesting a function in bridging connective tissue structures. To understand the in vivo function of WARP, we generated a WARP-deficient mouse strain. WARP- mice were healthy, viable, and fertile with no overt abnormalities. Motor function and behavioral testing demonstrated that WARP- mice exhibited a significantly delayed response to acute painful stimulus and impaired fine motor coordination, although general motor function was not affected, suggesting compromised peripheral nerve function. Immunostaining of WARP-interacting ligands demonstrated that the collagen VI microfibrillar matrix was severely reduced and mislocalized in peripheral nerves of WARP- mice. Further ultrastructural analysis revealed reduced fibrillar collagen deposition within the peripheral nerve extracellular matrix and abnormal partial fusing of adjacent Schwann cell basement membranes, suggesting an important function for WARP in stabilizing the association of the collagenous interstitial matrix with the Schwann cell basement membrane. In contrast, other WARP-deficient tissues such as articular cartilage, intervertebral discs, and skeletal muscle showed no detectable abnormalities, and basement membranes formed normally. Our data demonstrate that although WARP is not essential for basement membrane formation or musculoskeletal development, it has critical roles in the structure and function of peripheral nerves.

BIOSEB Instruments Used:
Grip strength test (BIO-GS3)

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