Characterization and application of monoclonal antibodies directed to separate epitopes of glutathione-insulin transhydrogenase

Five monoclonal antibodies specific for glutathione-insulin transhydrogenase were characterized. None of the monoclonal antibodies cross-reacted with another insulin-degrading enzyme, neutral thiopeptidase. The isotype of four antibodies was IgG1 and of the fifth IgG2b. Affinity studies, competitive binding studies and immunoblot analysis of CNBr and trypsin cleavage products of glutathione-insulin transhydrogenase demonstrated that the four IgG1 antibodies were directed to an epitope of the enzyme which was distinct from the epitope recognized by the IgG2b antibody. Inhibition studies indicated that each monoclonal antibody, when added singly to glutathione-insulin transhydrogenase, was unable to inhibit the insulin-degrading activity of the enzyme. However, when monoclonal antibodies directed against separate epitopes of glutathione-insulin transhydrogenase were presented together (i.e., the IgG2b with any one of the four IgG1 antibodies), a loss in enzymatic activity was noted. Immunoblot analysis of rat organ extracts with the IgG1 antibodies demonstrated one immunoreactive protein band of Mr 56,000 in all tissues examined (liver, fat, pancreas and kidney) except the spleen, which demonstrated two immunoreactive protein bands of Mr 56,000 and 51,000. The same immunoblots, when probed with the IgG2b antibody, demonstrated the same immunoreactive protein banding pattern as above plus an additional immunoreactive protein band of Mr 67,000 in all tissues. Studies with spleen extracts from steptozotocin-induced diabetic rats demonstrated that there was a loss of the 51,000 immunoreactive band in diabetes. This 51,000 protein was restored upon insulin treatment of the diabetic rats and nullified upon concomitant administration of cycloheximide or actinomycin D with insulin. Immunoblots of human liver, adipose and skeletal muscle extracts indicated that each monoclonal antibody cross-reacted with the human form of the enzyme which had a molecular weight of Mr 63,000; a second minor immunoreactive band of 67,000 was detected with the IgG2b antibody. The physiological significance of additional molecular forms of the enzyme (i.e., 67,000 and 51,000) remains to be determined.     

Structural characterization of cardiac protein phosphatase with a monoclonal antibody. Evidence that the Mr = 38,000 phosphatase is the catalytic subunit of the native enzyme(s)

The native structures of protein phosphatases have not been clearly established. Several tissues contain high molecular weight enzymes which are converted to active species of Mr approximately 35,000 by denaturing treatments or partial proteolysis. We have used a monoclonal antibody directed against purified bovine cardiac Mr = 38,000 protein phosphatase to determine whether this species is the native catalytic subunit or a proteolytic product of a larger polypeptide. Monoclonal antibody was obtained from a cloned hybrid cell line produced by the fusion of Sp2 myeloma cells with spleen cells from a mouse immunized with phosphatase coupled to hemocyanin. This antibody was specific for the Mr = 38,000 phosphatase as determined by immunoblot analysis of purified enzyme or cardiac tissue extracts after native or sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A single immunoreactive protein of Mr = 38,000 was present in cardiac tissue extracts including extracts prepared from freeze-clamped rat heart rapidly denatured in hot sodium dodecyl sulfate buffer. Precipitation of cardiac extract with 80% ethanol did not alter the Mr of the phosphatase nor did it liberate new immunoreactive material not observed in the extract. Ethanol precipitation caused the dissociation of both phosphatase activity and immunoreactivity from a high Mr form to a form of Mr between 30,000 and 40,000. An immunoreactive protein of Mr = 38,000 was identified in several bovine and rat tissues as well as tissues from rabbits, mice and chickens and human HT-29 cells. From these data we conclude that the Mr = 38,000 cardiac phosphatase is a native catalytic subunit of higher molecular complexes which are dissociated by ethanol precipitation. A very similar, or identical, protein is present in several tissues and species suggesting that this catalytic subunit is a ubiquitous enzyme important in many dephosphorylation reactions.     

Insulin degradation in insulinoma: evidence for the occurrence of an inactive form of glutathione-insulin transhydrogenase and for the absence of insulin A and B chains degrading protease(s)

Islet cell tumors (insulinomas) have been found to contain insulin-degrading activity. Apparent K_m values for insulin obtained with tumor extracts were similar to those found for other tissues and for purified glutatione-insulin transhydrogenase (GIT). In Ouchterlony double diffusion experiments with antibody to purified human liver GIT, each tumor extract gave a single precipitation band of identity with purified human liver GIT. Examination by chromatography on Sephadex G-75 of the products formed from ¹²⁵I-insulin upon incubation with tumor extracts showed the same products (A chain, and B chain rich-A chain aggregate) as previously found with purified GIT; however, there was no further degradation (i.e., proteolysis) of A chain to low molecular weight components. These results indicate that the insulin-degrading activity present in the islet tumor is, in fact, GIT and that the protease(s) that further catabolizes the insulin A and B chains is apparently missing in the insulinoma. These data could be interpreted to indicate that the function of GIT in this tissue is to promote the biosynthesis of proinsulin and insulin rather than their degradation. Data are also presented which indicate that in insulinoma GIT is present in an inactive state as a divalent metal ion complex since it could be activated with EDTA and/or GSH.     

Localization of glutathione-insulin transhydrogenase (protein-disulfide interchange enzyme) in pancreas using immunocytochemistry, immunodiffusion, and enzymatic activity assay techniques

The localization of the protein-disulfide interchange enzyme, glutathione-insulin transhydrogenase (GIT), in rat and mouse pancreas was studied by protein A-gold immunocytochemistry, immunodiffusion, and assay of enzymatic activity. Immunocytochemistry on tissue sections using antibody to GIT and protein A-gold complex indicated the presence of GIT in alpha and beta cells in islets as well as acinar cells. The beta cells in obese (ob/ob) hyperinsulinemic mice showed increased GIT immunoreactivity. In both alpha and beta cells, GIT immunoreactive sites were associated predominantly with secretory granules. In pancreas from rats injected with glibenclamide, the degranulated beta cells contained GIT immunoreactive sites on the cisternal surface of the rough endoplasmic reticulum (RER). In acinar cells, the RER, Golgi elements, condensing vacuoles, and zymogen granules possessed GIT immunoreactive sites as did mitochondria. Immunocytochemistry on sections of isolated subcellular fractions showed that GIT was associated with different membranes. The enzymatic activity of GIT was found in the following order: Golgi elements greater than mitochondria greater than microsomes greater than zymogen granules greater than cytosol. In Ouchterlony immunodiffusion tests, each subcellular fraction showed a precipitin band which was continuous with that of purified GIT, a result indicating the presence of immunologically identical GIT in all fractions.     

Characterization of a cDNA for human glutathione-insulin transhydrogenase (protein-disulfide isomerase/oxidoreductase)

A human liver cDNA expression library in lambda-phage gt11 was screened with monoclonal antibodies to rat liver protein-disulfide isomerase/oxidoreductase (EC 5.3.4.1/1.8.4.2), also known as glutathione-insulin transhydrogenase (GIT). The nucleotide sequence of the largest cDNA insert (hgit-1) was determined. It contained approx. 1500 basepairs, representing an estimated 65% of the glutathione-insulin transhydrogenase message. The amino-acid sequence deduced from this cDNA insert contains a 7-amino-acid long polypeptide determined by sequencing the active-site fragment isolated from the rat GIT protein. A comparison of the nucleotide sequence of hgit-1 and a previously reported nucleotide sequence of rat glutathione-insulin transhydrogenase cDNA shows that the human hgit-1 clone corresponds to the middle of the transhydrogenase message at amino-acid residue number 275 of the rat protein, and codes for 206 amino-acid residues, including one of the two active-site regions of glutathione-insulin transhydrogenase, a stop codon (TAA), a long 3'-noncoding region of over 800 bases, a polyadenylation signal (AATAA), and a 29 base poly(A) tail. There exists high homology between the human and rat enzymes (94% in the overall amino-acid sequence, with 100% in the active site region and 81% in the nucleotide sequence within the coding portion of hgit-1). As with the rat enzyme, the human enzyme shows some identity with another dithiol-disulfide-exchange protein, Escherichia coli thioredoxin. Like rat cDNA, the human hgit-1 cDNA hybridized to rat mRNA of 2500 bases on a Northern blot. The relative quantitative abundance of GIT mRNA in nine rat tissues studied using hgit-1 as a hybridization probe was found to be in the same order as previously found with the rat cDNA. Thus, the above studies indicate that glutathione-insulin transhydrogenase is a highly conserved protein and that the human hgit-1 cDNA is suitable for use as a probe for further studies on gene regulation of this enzyme.     

Characterization of a cDNA for human glutathione-insulin transhydrogenase (protein-disulfide isomerase / oxidoreductase)

A human liver cDNA expression library in λ-phage gt11 was screened with monoclonal antibodies to rat liver protein-disulfide isomerase / oxidoreductase (EC 5.3.4.1 / 1.8.4.2), also known as glutathione-insulin transhydrogenase (GIT). The nucleotide sequence of the largest cDNA insert (hgit-1) was determined. It contained approx. 1500 basepairs, representing an estimated 65% of the glutathione-insulin transhydrogenase message. The amino-acid sequence deduced from this cDNA insert contains a 7-amino-acid long polypeptide determined by sequencing the active-site fragment isolated from the rat GIT protein. A comparison of the nucleotide sequence of hgit-1 and a previously reported nucleotide sequence of rat glutathione-insulin transhydrogenase cDNA shows that the human hgit-1 clone corresponds to the middle of the transhydrogenase message at amino-acid residue number 275 of the rat protein, and codes for 206 amino-acid residues, including one of the two active-site regions of glutathione-insulin transhydrogenase, a stop codon (TAA), a long 3′-noncoding region of over 800 bases, a polyadenylation signal (AATAA), and a 29 base poly(A) tail. There exists high homology between the human and rat enzymes (94% in the overall amino-acid sequence, with 100% in the active site region and 81% in the nucleotide sequence within the coding portion of hgit-1). As with the rat enzyme, the human enzyme shows some identity with another dithiol-disulfide-exchange protein, Escherichia coli thioredoxin. Like rat cDNA, the human hgit-1 cDNA hybridized to rat mRNA of 2500 bases on a Northern blot. The relative quantitative abundance of GIT mRNA in nine rat tissues studied using hgit-1 as a hybridization probe was found to be in the same order as previously found with the rat cDNA. Thus, the above studies indicate that glutathione-insulin transhydrogenase is a highly conserved protein and that the human hgit-1 cDNA is suitable for use as a probe for further studies on gene regulation of this enzyme.     

Electrophoretic and immunochemical characterization of 3 alpha-hydroxysteroid/dihydrodiol dehydrogenases of rat tissues.

The properties of 3 alpha-hydroxysteroid/dihydrodiol dehydrogenase from Sprague-Dawley rat liver cytosol have been re-examined in light of several reports which suggest that multiple forms of the enzyme may exist in this tissue. During enzyme purification, chromatography on DE-52 cellulose and chromatofocusing columns indicated the existence of only one form of the protein. Re-chromatography of the purified enzyme by either of these techniques failed to resolve the protein into additional forms. When the purified enzyme was subjected to SDS/polyacrylamide-gel electrophoresis a single band corresponding to Mr 34,000 was detected. Two-dimensional gels showed one predominant protein with a pI of 5.9. Using the homogeneous enzyme as antigen, high-titre polyclonal antibody was raised in rabbits. Western-blot analysis of cytosolic proteins prepared from male and female Sprague-Dawley rat liver indicated the presence of a single immunoreactive band with an Mr of 34,000 in both sexes. All of the 3 alpha-hydroxysteroid dehydrogenase activity present in rat liver cytosol could be immunotitrated with the antibody and the resulting titration curve was superimposable on the titration curve obtained with the purified enzyme. Western-blot analysis of cytosolic proteins prepared from livers of male Wistar and Fischer rats also revealed the presence of a single immunoreactive protein with an Mr of 34,000. These data indicate that, contrary to previous reports, only one form of the dehydrogenase may exist in liver cytosols prepared from a variety of rat strains. Although 3 alpha-hydroxysteroid dehydrogenase activity is known to be widely distributed in male Sprague-Dawley rat tissues, Western blots indicate that only the liver, lung, testis and small intestine contain immunoreactive protein with an Mr of 34,000. The levels of immunoreactive protein in these tissues follow the distribution of dihydrodiol dehydrogenase.     

Insulin degradation. XVIII. On the regulation of glutathione-insulin transhydrogenase in the hyperglycemic obese (ob/ob) mouse.

The occurrence of insulin-degrading activity in the liver of the obese hyperglycemic mouse (ob/ob) and its litter mate has been studied. The trichloroacetic acid-soluble product formed from insulin upon incubation with liver homogenate was identified as the A chain of insulin. In Ouchterlony double-diffusion experiments with antibody to purified rat liver glutathione-insulin transhydrogenase, mouse liver homogenate and the microsomal fraction each gave a single precipitation band of identity with the purified rat liver enzyme. These results indicate that the insulin-degrading activity present in the mouse liver is, in fact, glutathione-insulin transhydrogenase. Subcellular distribution studies of glutathione-insulin transhydrogenase and marker enzymes indicate that the transhydrogenase is located primarily in the microsomal fraction of mouse liver homogenate. The ob/ob mouse, which is a genetic mutant characterized by obesity, hyperinsulinism and resistance to the hypoglycemic action of insulin, contains hepatic glutathione-insulin transhydrogenase activity (per mg microsomal protein) markedly higher (40--60%) than its lean litter mates. However, a major portion of the increased hepatic enzyme in the ob/ob mouse occurs in a latent state; the increased amount of enzyme either is unavailable or is nonfunctional, although the ob/ob mouse still contains more of the functional form than the lean mouse. Thus, the results are consistent with the suggestion that the hepatic glutathione-insulin transhydrogenase is probably under a feedback control by circulating insulin.     

Deoxyuridine triphosphate nucleotidohydrolase: distribution of the enzyme in various rat tissues

The distribution of deoxyuridine triphosphate nucleotidohydrolase (dUTPase) [EC 3.6.1.23] in the cytosol of various rat tissues was investigated by measuring the enzyme activity and by immunochemical analyses. Among nine rat tissues, thymus, and spleen showed the highest activities of the enzyme per gram of tissue, while intestine, stomach, lung and liver showed very low levels. Rabbit antibodies directed against purified dUTPase of anemic rat spleen showed reactivity with partially purified dUTPases from other rat tissues such as thymus, testis, or regenerating liver. Immunotitration and immunoblot experiments also indicated that the dUTPases in various rat tissues had very similar antigenicity and apparently the same subunit molecular size (Mr = 19,500), suggesting that the enzyme lacks organ-specificity. Immunoblot analysis of dUTPase protein with crude extracts from various rat tissues showed a similar distribution to that of the enzyme activity. No immuno-reactive band corresponding to the dUTPase was detected in intestine, although intestinal mucosa has been recognized as an actively proliferating tissue.     

Production and characterization of a monoclonal antibody to rat liver thiol: protein-disulfide oxidoreductase/glutathione-insulin transhydrogenase

Rat liver thiol:protein-disulfide oxidoreductase/glutathione-insulin transhydrogenase (glutathione:protein disulfide oxidoreductase, EC 1.8.4.2) was purified and found to give two bands on sodium dodecyl sulfate polyacrylamide gel electrophoresis. A monoclonal antibody was produced against this enzyme preparation and found to remove all the insulin degrading activity of purified preparations of the enzyme. This monoclonal antibody was also found to react with the two different forms of the enzyme observed on gel electrophoresis. These results suggest that glutathione-insulin transhydrogenase can exist in more than one state.     

Insulin degradation XVIII. On the regulation of glutathione-insulin transhydrogenase in the hyperglycemic obese (ob/ob) mouse

The occureence of insulin-degrading activity in the liver of the obese hyperglycemic mouse (ob/ob) and its litter mate has been studied. The trichloroacetic acid-soluble product formed from insulin upon incubation with liver homogenate was identified as the A chain of insulin. In Ouchterlony double-diffusion experiments with antibody to purified rat liver glutathione-insulin transhydrogenase, mouse liver homogenate and the microsomal fraction each gave a single precipitation band of identity with the purified rat liver enzyme. These results indicate that the insulin-degrading activity preseny in the mouse liver is, in fact, glutathione-insulin transhydrogenase. Subcellular distribution studies of glutathione-insulin transhydrogenase and marker enzymes indicate that the transhydrogenase is located primarily in the microsomal fraction of mouse liver homogenate.The ob/ob mouse, which is a genetic mutant characterized by obesity, hyper-insulinism and resistance to the hypoglycemic action of insulin, contains hepatic glutathione-insulin transhydrogenase activity (per mg microsomal protein) markedly higher (40–60%) than its lean litter mates. However, a major portion of the increased hepatic enzyme in the ob/ob mouse occurs in a latent state; the increased amount of enzyme either is unavailable or is nonfunctional, although the ob/ob mouse still contains more of the functional form than the lean mouse. Thus, the results are consistent with the suggestion that the hepatic glutathione-insulin transhydrogenase is probably under a feedback control by circulating insulin.     

Stimulation by insulin of cyclic AMP phosphodiesterase. Role of glutathione-insulin transhydrogenase.

In agreement with other workers, exposure of isolated rat fat cells to insulin shows a dose dependent increase in cyclic AMP phosphodiesterase (PDE) activity. However, when fat cells are pre-exposed to either guinea pig antiserum against insulin, rabbit antiserum against glutathione-insulin transhydrogenase (GIT), or immunogamma globulin against GIT, each antibody preparation totally or almost totally abolished the insulin-dependent increase in PDE activity. In control experiments, appropriate normal (non-immune) sera, normal gamma globulin, or the GIT-antiserum or the GIT-immunogamma globulin which had been previously neutralized with purified rat liver GIT were found to be completely ineffective in abolishing the insulin-dependent PDE activity of fat cells. These results suggest that the GIT-catalyzed sulfhydryl-disulfide inter-change reaction with insulin might be part of the mechanism by which insulin regulates the intracellular cyclic AMP concentration.     

Insulin degradation. X. Identification of insulin degrading activity of rat liver plasma membrane as glutathione-insulin transhydrogenase

The liver plasma membrane preparation devised by Neville (Biochim. Biophys. Acta, $\text{154}$, 540 (1968) contains insulin-degrading activity. Examination by chromatography on Sephadex G-75 of the products formed from ¹²⁵I-insulin upon incubation with plasma membrane showed the same products (A chain and B chain rich-A chain aggregate) as previously found with purified GSH-insulin transhydrogenase (GIT). In Ouchterlony double-diffusion experiments with antibody to purified rat liver GIT, plasma membrane gave a single precipitation band of identity with purified rat liver GIT. Thus, the insulin-degrading activity present in the plasma membrane preparation is indeed GIT.     

The orientation of transhydrogenase in the inner mitochondrial membrane of rat liver

The orientation of the transmembranous enzyme, pyridine dinucleotide transhydrogenase, in the inner mitochondrial membrane of rat liver has been determined by evaluating effects of proteases on the integrity of the enzyme in mitoplasts and submitochondrial particles. Following treatment of these membranes with the nonspecific protease, proteinase K, antigenic proteolytic products were detected by immunoblot analysis using polyclonal antibody prepared against purified bovine heart enzyme. Proteinase K treatment of mitoplasts converted the 110,000 transhydrogenase monomer into a single immunoreactive species having Mr 75,000. This proteolytic product is stable to further incubation with the protease. Treatment of submitochondrial particles with proteinase K resulted in the disappearance of the 110,000 monomer and the transient formation of an intermediate product with Mr 52,000. Information from these proteolysis studies was used to construct a model of the orientation of transhydrogenase in the inner mitochondrial membrane. This model indicates that transhydrogenase (Mr 110,000) contains a core of proteolytically inaccessible proteins within the membrane (Mr 23,000) bounded by extramembranous domains on the matrix (Mr 52,000) and cytoplasmic (Mr 35,000) face of the inner mitochondrial membrane.     

Identification of a novel serum protein secreted by lung carcinoma cells

The murine anti-human lung tumor monoclonal antibody L3 recognizes antigens found both in the medium of cultured carcinoma cells and in normal human serum. Sequential immunoprecipitation experiments indicate that the L3 antigen is also recognized by a previously described monoclonal antibody directed against a melanoma-associated antigen [Natali, P. G., Wilson, B. S., Imai, K., Bigotti, A., & Ferrone, S. (1982) Cancer Res. 42, 583-589]. This antibody precipitated a Mr 76000 glycoprotein from metabolically labeled extracts of the lung carcinoma cell line Calu-1 and a Mr 94 000 glycoprotein from labeled culture medium. Pulse-chase experiments suggested a precursor-product relationship between these molecules. Analysis of glycosidase sensitivities of the two forms indicated that maturation of carbohydrate side chains correlated with the apparent increase in molecular weights. L3 antigenic activity, measured in a competitive radiometric cell binding assay, was purified more than 90-fold from serum-free medium of Calu-1 cells and more than 3000-fold from normal human serum. The major immunoreactive components purified from culture medium and serum were identical with respect to apparent molecular weight, electrophoretic mobility, pI, glycosidase sensitivity, and V8 protease fingerprints. In addition, the sequence of the amino-terminal 16 N-terminal amino acid residues of the major immunoreactive species from both sources was identical. The properties of the L3 antigen did not correspond to those of any known protein, suggesting that this serum protein has not been previously characterized.     

Nonlatent and latent hepatic glutathione-insulin transhydrogenase activity during perinatal development and liver regeneration in rats and in rat placenta

We have studied glutathione-insulin transhydrogenase (GIT) activity in differentiating rat liver during parturition and neonatal growth and during compensatory liver growth. Parturition is characterized by a rapid but transient increase in total (i.e., nonlatent plus latent) hepatic GIT activity resulting from changes in the quantity (Vm) of the enzyme while neonatal growth is characterized by an increase in the nonlatent (active) form which persists until just prior to weaning. During liver regeneration following partial hepatectomy, GIT activity/mg protein is lowest after 12 h of regeneration and then progressively increases exceeding the control levels after 72 h of regeneration. Placenta from near-term rats contain a significant concentration of GIT which is immunologically similar to hepatic GIT.     

Stabilization of insulin receptor subunit structure by glutathione-insulin transhydrogenase

A partially purified insulin receptor preparation from rat liver was incubated at 37 degrees C with and without the protein-disulfide interchange enzyme, glutathione-insulin transhydrogenase (thiol: protein-disulfide oxidoreductase/isomerase, EC 1.8.4.2/5.3.4.1). Insulin-binding activity was then assessed by crosslinking receptor-125I-insulin complexes and subjecting them to electrophoresis on SDS-polyacrylamide gels in the absence and presence of reductant followed by autoradiography. Prior incubation of the receptor at 37 degrees C in the absence of the enzyme markedly decreased the subsequent binding of 125I-insulin to the holoreceptor (Mr 350 000) and to its subunits (Mr 180 000 and 130 000), while addition of the enzyme to the preincubation medium served to substantially prevent this decrease. The loss in binding at 37 degrees C was not restored by subsequent addition of the enzyme, nor was the loss prevented by any of the several known inhibitors of proteolysis. The apparent stabilization of receptor by transhydrogenase, as evidenced by the increase in binding above control levels, was proportional to both the enzyme concentration and the duration of incubation. These effects seem to be specific for transhydrogenase, since several other disulfide-containing proteins were found to be ineffective. These data suggest that the stabilization of the subunit structure of the insulin receptor at physiological temperatures may take place via a disulfide interchange reaction catalyzed by glutathione-insulin transhydrogenase.     

Mammalian-heart adenylate deaminase: Cross-species immunoanalysis of tissue distribution with a cardiac-directed antibody

A sheep antiserum against purified rabbit-heart adenylate deaminase (EC 3.5.4.6) (AMPD) was developed and validated as an immunologic probe to assess the cross-species tissue distribution of the mammalian cardiac AMPD isoform. The antiserum and the antibodies purified therefrom recognized both native and denatured rabbit-heart AMPD in immunoprecipitation and immunoblot experiments, respectively, and antibody binding did not affect native enzyme activity. The immunoprecipitation experiments further demonstrated a high antiserum titer. Immunoblot analysis of either crude rabbit-heart extracts or purified rabbit-heart AMPD revealed a major immunoreactive band with the molecular mass (81 kDa) of the soluble rabbit-heart AMPD subunit. AMPD in heart extracts from mammalian species other than rabbit (including human) was equally immunoreactive with this antiserum by quantitative immunoblot criteria. Although generally held to be in the same isoform class as heart AMPD, erythrocyte AMPD was not immunoreactive either within or across species. Nor was AMPD from most other tissues [e.g., white (gastrocnemius) muscle, lung, kidney] immunoreactive with the cardiac-directed antibody. Limited immunoreactivity was evidenced by mammalian liver, red (soleus) muscle, and brain extracts across species, indicating the presence of a minor cardiac(-like) AMPD isoform in these tissues. The results of this study characterize the tissue distribution of the cardiac AMPD isoform using a molecular approach with the first polyclonal antibodies prepared against homogeneous cardiac AMPD. This immunologic probe should prove useful at the tissue level for AMPD immunohistochemistry.     

The major source of endogenous prostaglandin D2 production is likely antigen-presenting cells. Localization of glutathione-requiring prostaglandin D synthetase in histiocytes, dendritic, and Kupffer cells in various rat tissues

The cellular localization of glutathione-requiring PGD synthetase, which catalyzes the predominant formation of PGD2 in various peripheral tissues, was investigated in adult rats by immunoperoxidase-staining with a polyclonal antibody specific for this enzyme. Although the 25 N-terminal amino acid residues of synthetase are 56% identical and 76% similar to those of several rat glutathione S-transferase subunits, the antibody cross-reacted only with synthetase in dot blotting and was nearly completely inactive with all transferase isozymes thus far purified. In Western blotting after SDS-PAGE of crude extracts of rat spleen, the antibody showed a single positive band at the same position as that of the purified enzyme (Mr = 26,000). The positive immunocytochemical stain was found in a number of histiocytes and/or dendritic cells in spleen, thymus, and Peyer's patch of intestine. The immunostain was also observed in such cells in lamina propria of the villus in small intestine and colon, in submucosal layer of stomach, and in Kupffer cells in liver. Immunoelectron microscopy confirmed that immunoreactivity of this enzyme was distributed in cytoplasm of those cells. Such immunoreactive cells were not observed in brain, spinal cord, kidney, heart, testis, and skeletal muscle. These observations suggest that PGD2 is produced by glutathione-requiring PGD synthetase localized in these types of APC in various tissues and may play a critical role in dictating the progression of immune responses.