Lymphocyte entry into inflammatory tissues in vivo. Qualitative differences of high endothelial venule-like vessels in sponge matrix allografts vs isografts.

Sponge matrix allografts and isografts become extensively encapsulated and neovascularized after s.c. implantation. Sponge allografts acquire alloantigen-reactive T lymphocytes, whereas sponge isografts fail to do so, even though these T cells are continuously circulating in the peripheral blood. We have investigated the possibility that the vascular endothelia regulates lymphocytic accumulation in sponge matrix implants. In normal lymph nodes, specialized high endothelial venules (HEV) regulate lymphocyte extravasation from the blood. We have now identified HEV-like vessels in sponge matrix allografts. These vessels are operationally defined as "HEV-like" in that they react with mAb MECA 325 which identifies murine HEV, and bind lymphocytes in ex vivo adhesion assays. In contrast, sponge isografts contain MECA 325 reactive vessels that are significantly smaller than those found in allografts. Further, vessels of sponge isografts do not readily bind lymphocytes in ex vivo adhesion assays. Immunohistologic analysis also revealed that the small MECA 325+ vessels present in sponge isografts are consistently found in close proximity to nerve bundles. Although this MECA 325 reactive vessel-nerve bundle association is also observed in sponge allografts, large MECA 325 reactive vessels are widely distributed in allografts. Our data suggest that small, poorly adhesive MECA 325 reactive vessels develop in sponge isografts and allografts, possibly under the influence of local nerve tissue. These vessels respond to regional alloimmune responses by developing into the larger HEV-like vessels capable of binding lymphocytes in sponge allografts. The value of this experimental system as an in vivo model to evaluate mechanisms involved in neovascularization and endothelial differentiation is discussed.