Rat plasma murinoglobulin: isolation, characterization, and comparison with rat alpha-1- and alpha-2-macroglobulins

Murinoglobulin, a newly identified mouse plasma protein with trypsin-protein esterase activity (Saito, A. & Sinohara, H. (1985) J. Biol. Chem. 260, 775-781), was also found in rat plasma and purified to apparent homogeneity. The serum level of rat murinoglobulin was 14.1 mg/ml, amounting to 1/3 of the total serum globulin fraction. Rat murinoglobulin was a monomeric glycoprotein (Mr = 210,000) containing 12% carbohydrate. Rat plasma contained two isoforms of murinoglobulin, termed I and II, which showed complete immunological identity on double diffusion analysis using rabbit antiserum raised against isoform I or II. These antisera also showed partial cross-reactivity towards mouse murinoglobulin and rat alpha-1-macroglobulin but not towards rat or human alpha-2-macroglobulin. The chemical compositions, peptide mapping patterns and electrophoretic mobilities of the two isoforms resembled each other but clearly differed from those of rat alpha-1- or alpha-2-macroglobulin. Rat murinoglobulin inhibited the proteolytic activity of trypsin towards casein and remazol brilliant blue hide powder. The inhibition as to the latter substrate was greater than that as to the former. When molar ratios of inhibitor to trypsin were low, murinoglobulin and the two alpha-macroglobulins stimulated the amidolytic activity of trypsin towards a synthetic substrate. At higher ratios, however, murinoglobulin, but not the alpha-macroglobulins, inhibited the same activity. The trypsin-protein esterase activity of murinoglobulin and the two alpha-macroglobulins was impaired by a molar excess of soybean trypsin inhibitor. Murinoglobulin and the two alpha-macroglobulins were inactivated by methylamine with a concomitant unmasking of the thiol group. Murinoglobulin was much more sensitive to soybean trypsin inhibitor and methylamine than the two alpha-macroglobulins.     

Trypsin inhibitors in guinea pig plasma: isolation and characterization of contrapsin and two isoforms of alpha-1-antiproteinase and acute phase response of four major trypsin inhibitors

Contrapsin and two isoforms, F (fast) and S (slow), of alpha-1-antiproteinase (also called alpha-1-proteinase inhibitor) were isolated in an apparently homogeneous state from plasma of inflamed guinea pigs. Contrapsin inactivated trypsin, but did not significantly affect chymotrypsin, pancreatic elastase, or pancreatic kallikrein. On the other hand, both isoforms of alpha-1-antiproteinase inhibited trypsin, chymotrypsin, and elastase, but not plasma or pancreatic kallikrein. The S isoform of alpha-1-antiproteinase was present in barely detectable amounts in healthy animals, but increased markedly when the acute-phase reaction was induced by subcutaneous injection of turpentine. On the other hand, the plasma levels of the F isoform, contrapsin, and alpha-macroglobulin showed moderate (1.5 to 2.3-fold) elevation during the acute-phase reaction. In contrast to the previous findings that rats and rabbits contain two different alpha-macroglobulins, one of which is an acute-phase reactant while the other is not, inflamed guinea pigs contained only one species of alpha-macroglobulin. Murinoglobulin, the most prominent acute-phase negative protein in both mice and rats, showed no significant change in guinea pigs. These results indicate that guinea pig plasma contains four major trypsin inhibitors, i.e., contrapsin, alpha-1-antiproteinase, alpha-macroglobulin, and murinoglobulin, the properties of which are very similar to those of the respective mouse homologues, but that the acute-phase response of these inhibitors differs greatly from that of the homologous proteins in rats or mice.     

Isolation and characterization of alpha-macroglobulin from guinea pig plasma

Guinea pig alpha-macroglobulin was purified to apparent homogeneity by sequential chromatography on Sephacryl S-300, DEAE-cellulose, and hydroxyapatite. A molecular weight of 780,000 was obtained by equilibrium sedimentation. The preparation migrated as a single band of Mr = 180,000 in sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Rabbit antiserum raised against the final preparation partially cross-reacted with human and rat alpha-2-macroglobulins but not with rat alpha-1-macroglobulin. Guinea pig alpha-macroglobulin stimulated the amidolytic activity of trypsin towards a small substrate, but inhibited the proteolytic activity of trypsin towards remazol brilliant blue hide powder. When treated with trypsin or methylamine, four thiol groups per molecule were newly generated. The reaction with trypsin proceeded with at least at two different rates: half of the thiol groups were generated in a fast reaction and the remaining half in a slower reaction. On the other hand, such a two-step reaction was not detected in the reaction with methylamine. The methylamine-treated alpha-macroglobulin retained half the capacity to bind trypsin and its mobility in polyacrylamide gel under nondenaturing conditions remained virtually unchanged. These properties are in marked contrast to those reported for human alpha-2-macroglobulin, but resemble those of rat alpha-2- and mouse alpha-macroglobulins. The amidase activity of trypsin bound to guinea pig alpha-macroglobulin was impaired by soybean trypsin inhibitor to a much greater degree than that of trypsin bound to human or rat alpha-2-macroglobulin.     

Guinea pig plasma trypsin inhibitors. Purification and characterization of two functionally distinct proteinase inhibitors.

Two trypsin inhibitors (TI-1, TI-2) were isolated from guinea pig plasma and purified to homogeneity. In amino-acid composition as well as molecular masses, TI-1 (Mr 58,000) and TI-2 (Mr 57,000) are similar to each other and to human and mouse alpha 1-proteinase inhibitors, and mouse con-trapsin. The two inhibitors form equimolar complexes with proteinases. The effectiveness of the inhibitors was characterized by association rate constants under second-order rate conditions. The inhibitory action of TI-1 was rapid for bovine trypsin, porcine pancreatic elastase and guinea pig plasma kallikrein, but slow for bovine thrombin and guinea pig plasmin and not detectable for bovine chymotrypsin and porcine pancreatic kallikrein. The inhibitory action of TI-2 was rapid for trypsin and chymotrypsin, but slow for guinea pig plasma kallikrein and not detectable for other proteinases. These results show that TI-1 and TI-2 are physicochemically similar but functionally distinct from each other and from human alpha 1-proteinase inhibitor that inhibits trypsin, chymotrypsin and elastase.     

Trypsin/acrosin inhibitor activity of rat and guinea pig caltrin proteins. Structural and functional studies

Dramatic inhibition of trypsin activity by rat caltrin and guinea pig caltrin I was spectrophotometrically demonstrated using the artificial substrate benzoylarginyl ethyl ester. Approximately 6% and 21% of residual proteolytic activity was recorded after preincubating the enzyme with 0.22 and 0.27 microM rat caltrin and guinea pig caltrin I, respectively. Reduction and carboxymethylation of the cysteine residues abolished the inhibitor activity of both caltrin proteins. Rat caltrin and guinea pig caltrin I show structural homology with secretory trypsin/acrosin inhibitor proteins isolated from boar and human seminal plasma and mouse seminal vesicle secretion and share a fragment of 13 amino acids of almost identical sequence (DPVCGTDGH/K/ITYG/AN), which is also present in the structure of Kazal-type trypsin inhibitor proteins from different mammalian tissues. Bovine, mouse, and guinea pig caltrin II, three caltrin proteins that have no structural homology with rat caltrin or guinea pig caltrin I, lack trypsin inhibitor activity. Rat caltrin, guinea pig caltrin I, and the mouse seminal vesicle trypsin inhibitor protein P12, which also inhibits Ca(2+) uptake into epididymal spermatozoa (mouse caltrin I), bound specifically to the sperm head, on the acrosomal region, as detected by indirect immunofluorescence. They also inhibited the acrosin activity in the gelatin film assay. Caltrin I may play an important role in the control of sperm functions such as Ca(2+) influx in the acrosome reaction and activation of acrosin and other serine-proteases at the proper site and proper time to ensure successful fertilization.     

Proteinase inhibitory spectrum of mouse murinoglobulin and alpha-macroglobulin

The interactions of mouse murinoglobulin and alpha-macroglobulin with several proteinases were investigated by filtration and by assays of amidolytic activity towards synthetic substrates in the presence of proteinaceous enzyme inhibitors as well as assays of the inhibition of proteolytic activity. Mouse alpha-macroglobulin formed complexes with thrombin, clotting factor Xa, plasmin, pancreatic kallikrein, plasma kallikrein, submaxillary gland trypsin-like proteinase, neutrophil elastase, and pancreatic elastase. These complexes lost the proteolytic activities against high-molecular-weight substrates, but protected the active sites of the enzymes from inactivation by their proteinaceous inhibitors. Mouse murinoglobulin showed essentially the same properties except (i) that it did not form a complex with the clotting factor Xa, and (ii) that it did not protect plasma kallikrein, neutrophil elastase or submaxillary proteinase from inactivation by their proteinaceous inhibitors, although it formed complexes with these proteinases. No interaction was detected between Clostridium histolyticum collagenase and murinoglobulin or alpha-macroglobulin. These results indicate (i) that murinoglobulin has a proteinase-binding spectrum similar to that of alpha-macroglobulin, but is weaker in the ability to protect the bound proteinases from inactivation by the proteinaceous inhibitors than alpha-macroglobulin and (ii) that mouse alpha-macroglobulin has essentially the same inhibitory spectrum as the human homologue.     

Murinoglobulin, a novel protease inhibitor from murine plasma. Isolation, characterization, and comparison with murine alpha-macroglobulin and human alpha-2-macroglobulin

Two glycoproteins having trypsin-protein esterase activity were purified to apparent homogeneity from murine plasma. One was alpha-macroglobulin, a homologue of human alpha-2-macroglobulin, while the other, tentatively named murinoglobulin, did not correspond to any of the known plasma protease inhibitors that have been well characterized in men or other mammals. Murinoglobulin contained about 7.6% carbohydrate and was composed of a single-polypeptide chain of Mr = 180,000 as judged by the equilibrium sedimentation analysis and sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Murinoglobulin did not cross-react immunologically with mouse alpha-macroglobulin nor with human alpha-2-macroglobulin. Protease-inhibiting properties of murinoglobulin were compared with those of mouse alpha-macroglobulin and human alpha-2-macroglobulin. All the three proteins inhibited trypsin, papain, and thermolysin, although they differed considerably in both the degree of inhibition and the binding stoichiometry of protease-inhibitor complexes. The two macroglobulins inhibited pepsin at pH 5.5, whereas murinoglobulin was inactivated at this pH. Murinoglobulin was more sensitive to methylamine than the two macroglobulins. No protein corresponding to murinoglobulin was detected in human plasma.     

Amidolytic activity of porcine trypsin bound to human plasma alpha-1-antiproteinase

Human plasma alpha-1-antiproteinase interacted with porcine trypsin in two different manners. One was a well known interaction, which resulted in inhibition of the proteolytic activity of the trypsin. The other has not been described to date, and resulted in retention of the amidolytic activity of the trypsin towards benzoyl-L-arginine p-nitroanilide in the presence of soybean trypsin inhibitor. The latter, so-called trypsin-protein amidase, activity is essentially the same as that observed with vertebrate alpha-macroglobulin and rodent murinoglobulin under similar conditions. All attempts to separate the two different activities as well as to abolish either activity by means of chemical or physical modifications were unsuccessful. The proteolysis-inhibiting interaction, which was virtually completed within 5 min, was predominant over the amidolysis-retaining interaction, when the inhibitor/trypsin molar ratio was less than 1. On the other hand, the amidolysis-retaining interaction, which proceeded much more slowly, became evident when the molar ratio was greater than 1.     

The major plasma kallikrein inhibitor of guinea pig plasma.

A plasma kallikrein inhibitor in guinea pig plasma (KIP) was purified to homogeneity. KIP is a single chain protein and the apparent molecular weight is estimated to be 59,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In amino acid composition, KIP is similar to human and mouse alpha 1-proteinase inhibitors and mouse contrapsin. KIP forms an equimolar complex with plasma kallikrein in a dose- and time-dependent fashion. The association rate constants for the inhibition of guinea pig plasma kallikrein by KIP, alpha 2-macroglobulin, C1-inactivator and antithrombin III were 2.5 +/- 0.3.10(4), 2.4 +/- 0.4.10(4), 6.6 +/- 0.5.10(4) and 9.1 +/- 0.6.10(2), respectively. Comparison of the association rate constants and the normal plasma concentrations of the four inhibitors demonstrates that KIP is ten-times as effective as alpha 2-MG and other two inhibitors are marginally effective in the inhibition of kallikrein. KIP inhibits trypsin and elastase rapidly, and thrombin and plasmin slowly, but is inactive for chymotrypsin and gland kallikrein. These results suggest that KIP is the major kallikrein inhibitor in guinea pig plasma and the proteinase inhibitory spectrum is unique to KIP in spite of the molecular similarity to alpha 1-proteinase inhibitor.     

Variations in induction of drug-metabolizing enzymes by trans-Stilbene oxide in rodent species

trans-Stilbene oxide (400 mg/kg) produced a 500% increase in the microsomal in the microsomal epoxide hydratase activity in rat and mouse with little change in the soluble enzyme activity. However, in guinea pig, the soluble epoxide hydratase activity increased by about 33% with only a small increase (47.6%) in the microsomal enzyme activity. The soluble glutathione S-transferase activities were also induced in both rat and mouse, with little change in that of the guinea pig. Increasing dosage of trans-stilbene oxide from 400 mg/kg to 1000 mg/kg had little effect on the above enzyme activities. That the guinea pig was not relatively refractory to all inducing agents was shown by the fact phenobarbital (100 mg/kg) and 3-methylcholanthrene (25 mg/kg) produced relatively similar increases in the activities of aniline hydroxylase and P-aminopyrineP-demethylase in rat, mouse and guinea pig. However, these inducers produced only a 15–20% stimulation in the soluble glutathione S-transferase and microsomal epoxide hydratase activities in guinea pig, when compared to a 50–80% increase in rat and mouse, suggesting a general resistance to induction by the phase II enzymes in guinea liver. In all animal models, the inducer markedly increased th emicrosomal total phospholipid content, although the sphingomyelin content itself was decreased. In both rat and mouse, the microsomal cholesterol content was significantly decreased while that in guinea pig was unaffected. Possible factors responsible for the observed species differences are discussed.     

Inhibition of macrophage migration by virus-induced interferon preparations.

It was found that a preparation of mouse L cell interferon induced by Newcastle disease virus (NDV) possessed not only interferon activity but also inhibitory activity upon migration of guinea pig peritoneal macrophages (MIF activity). These activities were also observed in a preparation of human leukocyte interferon induced by NDV. The interferon and MIF activities shared common characteristics in the dose response, time course of in vitro production, thermal stability, sensitivity to trypsin and periodate, and elution pattern in CM-Sephadex column chromatography. However, gel filtration pattern with Sephadex G-100 showed two separate peaks. Fractions collected from the first peak, corresponding to a molecular weight of about 45 000, had only the MIF activity, while those collected from the second peak, corresponding to a molecular weight of about 30 000, had both the interferon and MIF activities. A preparation of mouse brain interferon induced by Japanese encephalitis virus had a much weaker MIF activity than the L cell interferon, although these preparations were equal in interferon activity (5000 units/ml).     

Comparison of the sex and subcellular distributions, catalytic and immunochemical reactivities of hepatic epoxide hydrolases in seven mammalian species

Sex and species differences in hepatic epoxide hydrolase activities towards cis- and trans-stilbene oxide were examined in common laboratory animals, as well as in monkey and man. In general trans-stilbene oxide was found to be a good substrate for epoxide hydrolase activity in cytosolic fractions, whereas the cis isomer was selectively hydrated by the microsomal fraction (with the exception of man, where the cytosol also hydrated this isomer efficiently). The specific cytosolic epoxide hydrolase activity was highest in mouse, followed by hamster and rabbit. Epoxide hydrolase activity in the crude 'mitochondrial' fraction towards trans-stilbene oxide was also highest in mouse and low in all other species examined. Microsomal epoxide hydrolase activity was highest in monkey, followed by guinea pig, human and rabbit, which all had similar activities. Sex differences were generally small, but where significant, male animals had higher catalytic activities than females of the same species in most cases. Antibodies raised against microsomal epoxide hydrolase purified from rat liver reacted with microsomes from all species investigated, indicating structural conservation of this protein. Antibodies directed towards cytosolic epoxide hydrolase purified from mouse liver reacted only with liver cytosol from mouse and hamster and with the 'mitochondrial' fraction from mouse in immunodiffusion experiments. Immunoblotting also revealed reaction with rat liver cytosol. The cytosolic and 'mitochondrial' epoxide hydrolases in all three mouse strains and in both sexes for each strain were immunochemically identical. The anomalies in human liver epoxide hydrolase activities observed here indicate that no single common laboratory animal is a good model for man with regard to these activities.     

Synaptic and extra-synaptic distribution of histamine H1-receptors in rat and guinea pig brains

Localization of histamine H1-receptors in subcellular fractions from rat and guinea pig brains was examined in a [3H]mepyramine binding study. Major [3H]mepyramine binding sites with increased specific activities [( 3H]mepyramine binding vs. protein amount) were recovered from P2 fractions from both rat and guinea pig brains by differential centrifugation. Further subfractionation of both rat and guinea pig P2 fractions by a discontinuous sucrose density gradient centrifugation showed the highest recovery of [3H]mepyramine binding with further increased specific activities found in synaptic plasma membrane (SPM) fractions. Minor [3H]mepyramine binding sites with increased specific activities were detected in both rat and guinea pig P3 fractions. [3H]Mepyramine binding sites in SPM and P3 fractions showed identical Kd values in each species. These results indicate that histamine H1-receptors are located not only in synaptic but also in extra-synaptic membranes of both rat and guinea pig brains.     

Heterogeneity of hepatic microsomal UDP-glucuronosyltransferase(s) activities: comparison between human and mammalian species activities

The first comparative profiles of UDP-glucuronosyltransferase(s) (UDPGT) activities obtained under standard conditions in vitro in mammals (man, rat [Wistar and Gunn], mouse, monkey [Papio papio and Cynomolgus], pig, guinea pig, rabbit, dog) are presented for 16 aglycones. A decreasing scale of these activities was obtained from planar to bulky molecules. The scale was identical for each of the mammals studied, including man. Statistical analysis of the results revealed a division of the aglycones into three groups, one being correlated with the molecular form called GT1 the two others with the GT2 form. The profile of activities in the Gunn rat revealed very weak activity towards planar molecules (GT1). These results provide evidence that under standard conditions, human UDPGT activities are comparable to those from other animals.     

Inhibition of Macrophage Migration by Virus-Induced Interferon Preparations1

It was found that a preparation of mouse L cell interferon induced by Newcastle disease virus (NDV) possessed not only interferon activity but also inhibitory activity upon migration of guinea pig peritoneal macrophages (MIF activity). These activities were also observed in a preparation of human leukocyte interferon induced by NDV. The interferon and MIF activities shared common characteristics in the dose response, time course of in vitro production, thermal stability, sensitivity to trypsin and periodate, and elution pattern in CM-Sephadex column chromatography. However, gel filtration pattern with Sephadex G-100 showed two separate peaks. Fractions collected from the first peak, corresponding to a molecular weight of about 45 000, had only the MIF activity, while those collected from the second peak, corresponding to a molecular weight of about 30 000, had both the interferon and MIF activities. A preparation of mouse brain interferon induced by Japanese encephalitis virus had a much weaker MIF activity than the L cell interferon, although these preparations were equal in interferon activity (5000 units/ml).     

Interaction of S-activated enkephalin analogs with opiate receptors

Enkephalin analogs containing a thiol activated by a thiomethyl (SCH3)*** or 3-nitro-2-pyridinesulfenyl (Npys) group were synthesized. Incubation of such S-activated enkephalin analogs as [D-Ala2, Leu(CH2S)SCH(3)5]enkephalin or [D-Ala2,Leu(CH2S)Npys5]enkephalin with guinea pig ileum (GPI) resulted in the continuous stimulation of the mu opiate receptors. This sustained GPI-activity was completely reversed with the antagonist naloxone, while subsequent washings elicited again the full enkephalin activity. When GPI showing full enkephalin activity was incubated with 1 mM dithiothreitol, about 70% of the activity was eliminated. Examination of enkephalin analogs containing Cys(Npys) at position 1, 5, or 6 suggested that no other thiols occur near the enkephalin binding site of the mu receptor. From these results, it is considered that only one thiol group exists near the binding site of the mu receptor in GPI. Similar results were also obtained for the mu receptors in mouse vas deferens.     

Effect of an extract of nereis virens on mammalian spermatozoa

Epididymal sperm of the mouse, rat, and guinea pig and ejaculated sperm of rabbits are cleaved at the head-tail junction by an extract of Nereis virens. Annelids are extracted with water and the extract is purified by ion exchange chromatography. Electron microscopy shows that the extract acts on the filaments connecting the capitulum of the tail with the basal plate lining the nuclear envelope. Following detachment, the basal plate remains with the head. The extract contains proteases as indicated by hydrolysis of tosyl arginine methyl ester (TAME), benzoyl arginine ethyl ester (BAEE), and Azocoll, a general protease substrate. The hydrolysis of TAME is inhibited by tosyl lysine chloromethyl ketone (TLCK), a trypsin inhibitor, but TLCK does not prevent head-tail separation by the Nereis extract. Similarly tosyl phenylalanine chloromethyl ketone (TPCK), a chymotrypsin inhibitor, and phosphoramidon and leucyltryptophan, both thermolysin and acrolysin inhibitors — singly or in combination — do not prevent hydrolysis of Azocoll. Head-tail separation activity of the extract was inhibited by dithiothreitol, which reduces disulfide bonds, and phenylmethyl sulfonyl fluoride, an inhibitor of serine proteases. These results indicate that the extract is a mixture of proteases, one being a serine protease similar to trypsin. Digestion of the connecting filaments with the pure proteases, trypsin and Staphylococcus aureus V8 protease, has yielded the following information on the proteins of the filaments. The accessibility of arginine and/or lysine peptide bonds to enzyme action is highest in rat sperm filaments, whereas those in the filaments of mouse, rabbit, and guinea pig sperm are less accessible than in the rat. Another possibility is that the total content of arginine and/or lysine varies between the species. The most dramatic difference is the enzymatic action on glutamyl peptide bonds of the filaments, the order being: mouse 〉 rat 〉 rabbit, with guinea pig sperm filaments completely resistant over the time course of the experiment.     

Purification, structure, and characterization of caltrin proteins from seminal vesicle of the rat and mouse.

Caltrins, small basic proteins that inhibit calcium uptake by epididymal spermatozoa, have been purified from seminal vesicle content of the mouse and rat. Mouse caltrin (M(r) 8,476) contains 75 amino acid residues, 14 basic, 5 acidic, and 7 cysteines while rat caltrin (M(r) 6,217) has 56 residues, 10 basic, 5 acidic, and 6 cysteines; their pI values are 10.2 and 9.3, respectively. The proteins did not react with Ellman's reagent unless the cystine residues were previously reduced. The primary structures were determined by sequencing fragments generated by trypsin, clostripain, and endoproteinase Lys-C digestion. The sequences were ordered to give the total structural formula. The two molecules have no sequence similarity and are different from those of the bull and guinea pig previously reported. Only rat caltrin has a sequence of 13 residues nearly identical to that in guinea pig caltrin I. Both rat and mouse caltrin react with antibodies against bovine and guinea pig caltrins. Reduction and alkylation of cysteine residues suppressed the immunologic response of mouse caltrin; however, modified rat caltrin retained partially its immunoreactivity with the antiserum against guinea pig caltrin I. The same treatment abolished the calcium transport inhibitory activity of mouse caltrin and greatly reduced that of rat caltrin. It is likely that rat and mouse caltrins have the same physiological function as proposed for bovine caltrin; namely, to regulate the development of the Ca(2+)-dependent processes that "capacitate" sperm for fertilization.     

Vascular permeability enhancement by Vibrio mimicus protease and the mechanisms of action.

Vibrio mimicus, a causative agent of gastroenteritis, has also been reported to attribute to extraintestinal infections. Recently we have purified a metalloprotease produced by the pathogen: however, the role of the protease in V. mimicus infection has not been documented. The V. mimicus protease (VMP) was found to enhance vascular permeability and form edema when injected into the dorsal skin of guinea pig and rat. The permeability enhancement by VMP was observed in a dose-dependent manner in both guinea pig and rat skin. In guinea pig, an inhibitor of the angiotensin-converting enzyme was found to augment the permeability enhancement reaction. The permeability enhancement was significantly blocked by soybean trypsin inhibitor (SBTI), an inhibitor of plasma kallikrein reaction. In vitro conversion of plasma prekallikrein to kallikrein by VMP was also noted. In rat skin, the permeability enhancement reaction was not blocked by antihistamine or SBTI. However, the reaction was partially blocked when a mixture of antihistamine and SBTI was administered with VMP. It is apparent from the study that in guinea pig skin, VMP enhances vascular permeability through activation of plasma kallikrein-kinin system which generates bradykinin, whereas in addition to the activation of plasma kallikrein-kinin cascade in the case of rat, stimulation of histamine release from mast cells and other unknown mechanism seem to be also a cause of the permeability enhancement reaction. These results suggest that VMP may play a role in extraintestinal infections with edema caused by the pathogen.     

Histochemistry of the tongue epithelium in four mammals with respect to keratinization

The tongue epithelium was examined in the laboratory rat, guinea pig, rabbit and Domestic cat, using light microscopical, histological fluorescent and histochemical methods. The distributions of the enzymes, acid and alkaline phosphatase were examined. Protein-bound phospholipid and calcium were investigated, together with thiol sulphydryl groups and cysteine disulphide bonds of proteins. A variety of different types of keratinization were shown in the various species, as well as in the same species in different regions of the tongue. The most strongly keratinized structures were the filiform and conical papillae which varied widely from species to species. Those of the rat dorsum were similar to papillae described previously in the House mouse and have strongly keratinized spines. The guinea pig showed some differences but also had keratinized spines. In contrast the rabbit papillae did not have spines but the horny layer over the posterior sides was hardened instead to form pointed edges. Human filiform papillae are similar to the rabbit without spines but the horny layer is less strongly keratinized. In the Domestic cat the conical papillae were also without spines but the horny layer on the anterior and posterior surface was hardened to form claw-like structures.