Identification and localization of wound hyaluronidase

Modulation of human fibroblast gap junction intercellular communication by hyaluronan

The composition of the extracellular matrix changes during dermal repair. Initially, hyaluronan (HA) concentration is high, however, by day 3, HA is eliminated. HA optimizes collagen organization within granulation tissue. One possible mechanism of HA modulation of collagen packing is through the promotion of gap junction intercellular communication (GJIC). Gap junctions are gated channels that allow rapid intercellular communication and synchronization of coupled cell activities. The gap junction channel is composed of connexin (Cx) proteins that form a gated channel between coupled cells. HA is reported to enhance Cx43 expression in transformed fibroblasts. GJIC was quantified by the scrape loading technique and reported as a coupling index. The coupling index for human dermal fibroblasts was 4.6 +/- 0.2, while the coupling index for fibroblasts treated with HA more than doubled to 10.6 +/- 0.7. By Western blot analysis no differences were appreciated in the protein levels of Cx43 or beta-catenin, a protein involved in the translocation of Cx to the cell surface. By immuno-histology Cx43 and beta-catenin were evenly distributed throughout the cell in controls, but in cells treated with HA these proteins were co-localized to the cell surface. Coupled fibroblasts are reported to enhance the organization of collagen fibrils. It is proposed that HA increases the accumulation of Cx43 and beta-catenin on the cell surface, leading to greater GJIC and enhanced collagen organization.

Inhibiting the differentiation of myocardiocytes by hyaluronic acid

BACKGROUND

In vitro experimentation found that wounded midgestation fetal mouse hearts heal scarlessly. Scarless repair occurs in an environment enriched in hyaluronic acid (HA), while in the absence of HA and the inclusion of hyaluronidase (HAdase), repair by scarring occurs. Excess HA downregulates the expression of the specific HA receptor, RHAMM (receptor for HA-mediated motility). The expression of RHAMM and the migration of cardiac cells from fetal heart explants were investigated in the presence of excess HA and added HAdase.

METHOD

Hearts from Gestational Day 15 fetal mice (term = 20) were cut into four fragments, established as explant cultures, and assigned to one of three treatment groups: 400 micrograms/ml HA, 50 U/ml HAdase, or saline. Cellular outgrow was recorded at Day 7. The character of the migrating cells (fibroblast-like or myocardiocyte) was determined by immunostaining for filamentous actin (f-actin, microfilaments) or desmin (intermediate filaments). The expression of RHAMM was documented also.

RESULTS

The inclusions of HA stimulated cell migration and proliferation, perpetuated cells as immature myocardiocytes, and blocked the expression of RHAMM. The inclusion of HAdase limited cell migration and proliferation, promoted the differentiation of cells into myocardiocytes, and increased the number of cells expressing RHAMM.

CONCLUSION

Increased concentrations of HA promoted the proliferation and migration of an immature population of myocardiocytes. On the other hand the inclusion of HAdase inhibits the migration and proliferation of cells and promotes the appearance of myocardiocytes with a fibroblast-like morphology. The speculation is that excess HA may promote proliferation and migration of immature myocardiocytes into a heart defect, leading to replacement of lost myocardium with contractile tissue rather than dysfunctional scar.

Separation and properties of rabbit buccal mucosal wound hyaluronidase

This study establishes the existence of a mammalian buccal mucosal wound hyaluronidase (hyaluronate 4-glycohydrolase; EC 3.2.1.35) having properties distinct from those of the endogenous lysosomal hyaluronidase of normal (uninjured) buccal mucosa. A time-dependent change in hyaluronidase activity was measured, with the highest specific activity occurring on post-wound day 4 (7.7 +/- 1.3 units/mg protein), followed by consecutive decreases until activity was no longer discernible by day 21. Mucosal wound hyaluronidase closely resembled a previously described integumentary wound endoglycosidase in terms of a high pH optimum (5.0-6.0), distinct (but non-exclusive) substrate preference for hyaluronic acid, and ability to generate saturated depolymerization products by an endoglycosidic hydrolysis.

A model for the role of hyaluronic acid and fibrin in the early events during the inflammatory response and wound healing

A model is presented outlining the molecular and cellular events that occur during the early stages of the wound healing process. The underlying theme is that there is a specific binding interaction between fibrin, the major clot protein, and hyaluronic acid (HA), a constituent of the wound extracellular matrix. This binding interaction, which could also be stabilized by other cross-linking components, provides the driving force to organize a three-dimensional HA matrix attached to and interdigitated with the initial fibrin matrix. The HA-fibrin matrix plays a major role in the subsequent tissue reconstruction processes. We suggest that HA and fibrin have both structural and regulatory functions at different times during the wound healing process. The concentration of HA in blood and in the initial clot is very low. This is consistent with the proposed interaction between HA and fibrin(ogen), which could interfere with either fibrinogen activation or fibrin assembly and cross-linking. We propose that an activator (e.g. derived from a plasma precursor, platelets or surrounding cells) is produced during the clotting reaction and then stimulates one or more blood cell types to synthesize and secrete HA into the fibrin matrix of the clot. We predict that HA controls the stability of the matrix by regulating the degradation of fibrin. The new HA-fibrin matrix increases or stabilizes the volume and porosity of the clot and then serves as a physical support, a scaffold through which cells trapped in the clot or cells infiltrating from the peripheral edge of the wound can migrate. The HA-fibrin matrix also actively stimulates or induces cell motility and activates and regulates many functions of blood cells, which are involved in the inflammatory response, including phagocytosis and chemotaxis. The secondary HA-fibrin matrix itself is then modified as cells continue to migrate into the wound, secreting hyaluronidase and plasminogen activator to degrade the HA and fibrin. At the same time these cells secrete collagen and glycosaminoglycans to make a more differentiated matrix. The degradation products derived from both fibrin and HA are, in turn, important regulatory molecules which control cellular functions involved in the inflammatory response and new blood vessel formation in the healing wound. The proposed model generates a number of testable experimental predictions.

Dental pulp mucopolysaccharidase: identification and role in tooth resorption

The presence of mucopolysaccharidase activity within the pulps of resorbing deciduous teeth was investigated using histochemical techniques. The loss of toluidine blue metachromasia within glycosaminoglycan film subtrates indicated the presence of enzyme activity. This was related to physiologic resorption.