92K-GL (MMP-9) and 72K-GL (MMP-2) are produced in vivo by human oral squamous cell carcinomas and can enhance FIB-CL (MMP-1) activity in vitro.

Previous studies have shown a correlation between the production of certain matrix metalloproteinases (MMPs), especially the gelatinases, by malignant tumors and the progression of these cancers as they invade and metastasize through the extracellular matrix and basement membranes. However, very few of these studies examined this relationship in human oral cancer in vivo, and none addressed the issue of how combinations of the MMPs may further enhance tumor progression. To determine which MMPs are produced in vivo by human oral cancers, we used specific anti-human-MMP antibodies and immunocytochemistry (ICC) methods to examine oral cancer tissue specimens from 20 surgery patients. The ICC data indicated that 72-kDa (72K-GL) and 92-kDa gelatinases (92K-GL) were produced in vivo by discreet clusters of tumor cells and by stromal fibroblasts, vascular endothelial cells (72K-GL), and PMNs (92K-GL). Some stromal fibroblasts near the tumors also appeared to produce fibroblast-type collagenase (FIB-CL), a finding confirmed by Western blot analysis of media conditioned by oral tumor explant cultures. ICC results indicated that 5 of the 20 tumors coincidentally produced all three MMPs. To examine how the two gelatinases and FIB-CL may interact in vitro to degrade fibrillar type I collagen, a major structural component of the extracellular matrix, we used a modified FIB-CL activity assay. Combinations of the gelatinases and FIB-CL were incubated with a 3H-collagen substrate, with the results compared with the combination of stromelysin-1 (SL-1, a superactivator of FIB-CL) and FIB-CL. 92K-GL caused a nine-fold increase in collagenase activity, equivalent to SL-1, while 72K-GL produced a four-fold increase. These results indicate that human oral cancers produce 92K-GL, 72K-GL, and FIB-CL in vivo and that the gelatinases and FIB-CL cooperate to enhance collagen degradation greatly in vitro.

Peripheral blood chimerism in renal allograft recipients transfused with donor bone marrow.

Experimental studies have shown that administration of antilymphocyte serum combined with donor bone marrow cells can induce tolerance to allograft tissue. We have initially reported application of these protocols in clinical studies of cadaveric renal allograft recipients who were treated with MALG and donor-specific bone marrow cells. To evaluate the effectiveness of the donor marrow cells in the production of chimerism, a detection method based on 32P-incorporated PCR was established. The 32P PCR was utilized with primers specific for the HLA class II, VNTR (D17S5 and D1S111), and/or Y-chromosome genes to detect the presence of allogeneic chimerism in the recipients. Immediately posttransplant, 26.4% of marrow recipients demonstrated the presence of allogeneic chimerism prior to the marrow transfusion as did 18% in the untransfused controls. In transfused patients, chimerism was detected most frequently during the 1-3-month interval after marrow transfusion (65%), and then diminished to 50-56% at 3-12 months posttransfusion. In the control group the frequency of allogeneic chimerism was gradually decreased and was undetectable in the majority of the patients beyond 3 months posttransplant while marrow-transfused recipients were more likely to have chimeric cells detected consistently beyond 3 months. Rejection episodes were significantly effected by the presence of chimerism in the recipients. Of the transfused patients, 91.3% who demonstrated allogeneic chimerism were rejection-free as compared with 8.7% who experienced at least one rejection episode (P = 0.01). While the presence of allogeneic chimerism in the control group was correlated with rejection-free graft survival, this difference did not reach statistical significance.