Qa-2 antigen encoded by Q7b is biochemically indistinguishable from Qa-2 expressed on the surface of C57BL/10 mouse spleen cells

Qa-2 was immunoprecipitated from the surface of 125I-labeled C57BL/10 (B10) mouse spleen cells and compared with Qa-2 immunoprecipitated from the surface of R1.1 thymoma cells transfected with Q7b. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that Qa-2 glycoproteins from both of these sources have a relative molecular mass of approximately 37 kDa. After treatment with endoglycosidase F, the Qa-2 polypeptide chains derived from C57BL/10 spleen and Q7b-transfected R1.1 cells displayed identical mobilities in sodium dodecyl sulfate-polyacrylamide gel electrophoresis because of removal of N-linked oligosaccharide residues. Furthermore, treatment of Qa-2 proteins from both sources with cyanogen bromide or alpha-chymotrypsin resulted in identical peptide fragmentation patterns. These results therefore provide a biochemical correlation between a cloned Qa-region gene produce expressed on the surface of transfected cells, and the Qa-2 glycoprotein on spleen cells that was described a decade ago by serologic methods.     

New method for visualization of vascular networks in nonperfused fixed tissues

A new method of visualizing the angioarchitecture of tissues has been developed that uses blood components in nonperfused materials. Tissue blocks are fixed in 4% paraformaldehyde and cut with a vibratome into 50-60 micron sections. Endogenous peroxidase in red blood cells is then reduced in the presence of hydrogen peroxide with the resultant oxidation of the chromogen 3,3'-diaminobenzidine (DAB). This generates a dark, highly insoluble reaction product throughout the vascular system. The visualization of vascular components can be further enhanced by exposing the sections to peroxidase-conjugated IgG to increase the background staining of the blood plasma. The technique minimizes preparation artifact and permits the application of morphometric analytical methods, thus allowing parameters such as the volume density of the vascular bed to be quantified.     

New Method for Visualization of Vascular Networks in Nonperfused Fixed Tissues

A new method of visualizing the angioarchitecture of tissues has been developed that uses blood components in nonperfused materials. Tissue blocks are fixed in 4% paraformaldehyde and cut with a vibratome into 50-60 μm sections. Endogenous peroxidase in red blood cells is then reduced in the presence of hydrogen peroxide with the resultant oxidation of the chromogen 3,3'-diaminobenzidine (DAB). This generates a dark, highly insoluble reaction product throughout the vascular system. The visualization of vascular components can be further enhanced by exposing the sections to peroxidase-conjugated IgG to increase the background staining of the blood plasma. The technique minimizes preparation artifact and permits the application of morphometric analytical methods, thus allowing parameters such as the volume density of the vascular bed to be quantified.     

HLA-JY328: Mapping studies and expression of a polymorphic HLA class I gene

The JY328 clone was identified in a human genomic library using cDNA corresponding to mRNA for HLA-B7 as a probe. The L/328 cell line was established by cotransformation of mouse Ltk^– cells with the herpes thymidine kinase gene and clone JY328. On Northern blots, RNA from,L/328 strongly hybridized to an HLA class I probe, and an antigen was recognized by an anti-HLA class I framework antibody on the cell surface. A DNA probe corresponding to a segment of intron 7 was developed by comparing the nucleotide sequence of clone JY328 with that of other HLA class I-type genes. Using the radiolabeled probe to screen Southern blots of DNA from families with siblings exhibiting intra-HLA recombinations, a restriction fragment length polymorphism was revealed —a 1.4 kb BstE II band not present in all individuals. A corresponding fragment was apparent in the base sequence of clone JY328. The occurrence of this band on Southern blots established that JY328 maps distinct from and centromeric to the HLA-C locus and near to the HLA-B locus. Antibody absorption studies and cytotoxicity tests indicated that the JY328 gene product was not an HLA-B antigen but that it did specifically absorb CW7-specific antibody. In sum, these results suggest a novel, polymorphic HLA class I gene which expresses a product serologically similar to HLA-Cw7 but which does not map within the corresponding locus.     

Glutathione S-transferase in human organs

Glutathione S-transferase (GSH-T) distribution has been investigated in human tissues. The relative contribution of each species to total enzyme activity of the various tissues has been compared. "Cationic" (pI greater than 7.5) "neutral" (pI 6-6.5) and "anionic" (pI less than 5.4) species of GSH-T were separated by isoelectric focusing. "Cationic" GSH-Ts (ligandin) quantitated by radioimmunoassay were present in all tissues studied. Highest concentrations were in liver, kidney, duodenum, testis and adrenal. "Neutral" and "anionic" GSH-Ts were not present in every tissue or in every specimen of some tissues studied. Marked inter-organ and inter-individual variation in the relative concentration of the 3 GSH-T species may explain individual and organ susceptibility to drugs and toxins and underlines the need for future studies to examine individual enzymes rather than total activity.