Conversion of leukotriene C4 to leukotriene D4 by a cell-surface enzyme of rat macrophages

Leukotriene (LT) C4-metabolizing enzyme was studied using rat leukocytes. Neutrophils and lymphocytes hardly metabolized LTC4, whereas macrophages rapidly converted LTC4 to LTD4. The LTC4-metabolizing enzyme of macrophages was present in the membrane fraction but not in the nuclear, granular and cytosol fractions. When macrophages were modified chemically with diazotized sulfanilic acid, a poorly permeant reagent which inactivates cell-surface enzymes selectively, the LTC4-metabolizing activity of macrophages decreased significantly (greater than 90%). These findings suggest that rat macrophages possess the LTC4-metabolizing enzyme which converts LTC4 to LTD4, on the cell surface membrane.     

Studies on the leukotriene D4-metabolizing enzyme of rat leukocytes, which catalyzes the conversion of leukotriene D4 to leukotriene E4

Leukotriene D4-metabolizing enzyme was studied using rat neutrophils, lymphocytes and macrophages. These leukocyte sonicates converted leukotriene D4 to leukotriene E4. However, the leukotriene D4-metabolizing activity varied with cell type, and macrophages showed the highest activity among these leukocytes. The subcellular localization of the leukotriene D4-metabolizing enzyme of macrophages was examined, and the leukotriene D4-metabolizing activity was found to be present in the membrane fraction, but not in the nuclear, granular and cytosol fractions. When macrophages were modified chemically with diazotized sulfanilic acid, a poorly permeant reagent which inactivates cell-surface enzymes selectively, the leukotriene D4-metabolizing activity of macrophages decreased significantly (about 95%) without any inhibition of marker enzymes of microsome, cytosol, lysosome and mitochondria. When neutrophils and lymphocytes were modified with diazotized sulfanilic acid, the leukotriene D4-metabolizing activity was also inhibited about 90% by the modification. Among various enzyme inhibitors used, o-phenanthroline, a metal chelator, remarkably inhibited the leukotriene D4-metabolizing activity of leukocytes, and the o-phenanthroline-inactivated enzyme activity was fully reactivated by Co2+ and Zn2+. These findings seem to indicate that rat neutrophils, lymphocytes and macrophages possess the leukotriene D4-metabolizing metalloenzyme which converts leukotriene D4 to leukotriene E4, on the cell surface, although macrophages have a higher enzyme activity than the other two.     

Localization of leukotriene D4-metabolizing metalloenzyme on the cell surface of human neutrophils

The localization of leukotriene D4-metabolizing enzyme on the cell surface was examined using human neutrophils. Intact neutrophils rapidly converted leukotriene D4 to leukotriene E4. However, when neutrophils were modified chemically by diazotized sulfanilic acid, a poorly permeant reagent which inactivates cell surface enzymes selectively, the leukotriene D4-metabolizing activity of neutrophils decreased significantly without any inhibition of the cell viability or marker enzymes of cytosol, granules, microsome and mitochondria. The leukotriene D4-metabolizing enzyme activity of the membrane fraction was inhibited by modification to the same extent as that of Mg2+-dependent ATPase, a cell-surface marker enzyme. Among various enzyme inhibitors examined, a metal chelator, o-phenanthroline, strongly suppressed the leukotriene D4-metabolizing activity of intact neutrophils and the o-phenanthroline-inactivated enzyme activity was fully reactivated by Co2+, Mn2+ and Zn2+. These results would suggest that some metalloenzyme located on the cell surface is involved in the conversion of leukotriene D4 to leukotriene E4 by neutrophils.     

Metabolism of leukotriene D4 by rat peritoneal mast cells

Metabolism of sulfidopeptide leukotrienes, leukotrienes (LT) C4 and D4 by rat peritoneal mast cells was studied. Rat peritoneal mast cells converted LTD4 to LTE4 but not LTC4 to LTD4. The LTD4-metabolizing activity was equally distributed on the cell surface and inside cells, but not released to the extracellular milieu even when a considerable portion of histamine and the secretory granule enzymes were released. Among various enzyme inhibitors examined, o-phenanthroline, a metal chelator, and dithiothreitol significantly suppressed the LTD4-metabolizing activity of mast cell. These results would suggest that some metalloenzyme located on the cell surface is involved in the conversion of LTD4 to LTE4 by rat peritoneal mast cells.     

Desulphation of heparin by mice and guinea pig leukocytes

Leukocytes from mice and guinea pigs were tested for their sulphate-splitting activity on heparin. Mouse macrophages showed the highest degrading activity while mouse neutrophils and lymphocytes were less active. In comparison, guinea pig spleen cells and leukocytes showed only a weak degrading activity. Mouse macrophages maintained in tissue culture were also found to degrade heparin, the amount of sulphate released increasing with time up to 96 h. Spleen extracts were found to neutralize the anticoagulatory activity of heparin.     

Indole-3-acetic acid increases glutamine utilization by high peroxidase activity-presenting leukocytes

Indole-3-acetic acid (IAA) is toxic for human tumor cells and in association with horseradish peroxidase (HRP) can be used as a new prodrug/enzyme combination for targeted cancer therapy. The toxic effect of IAA on neutrophils, macrophages and lymphocytes is associated with cell peroxidase activity, which is high in neutrophils and low in lymphocytes. The effect of IAA on glucose and glutamine metabolism in leukocytes presenting different peroxidase activities: neutrophils, thioglycollate-elicited macrophages and lymphocytes was investigated. A time-course effect (from 6 to 48 h in culture) of IAA on glucose and glutamine metabolism of neutrophils, thioglycollate-elicited macrophages, and lymphocytes was then carried out. Addition of IAA (0.25 mM) did not have a marked effect on glucose utilization and lactate formation by the three cell types but it raised glutamine consumption and glutamate production by neutrophils and macrophages. IAA had no effect on glutamine consumption and glutamate production by lymphocytes. A strong relationship was found between glutamine utilization (0.999) and glutamate production (0.999) and peroxidase activity. IAA did not change the activities of hexokinase, glucose-6-phosphate dehydrogenase, citrate synthase, lactate dehydrogenase, and phosphate-dependent glutaminase of 24 h cultured neutrophils and lymphocytes. The effect of IAA (1 mM) on glucose and glutamine metabolism was also investigated by 1 h incubated leukocytes in PBS. IAA did not affect glucose and glutamine metabolism of lymphocytes but enhanced glucose and glutamine metabolism by 1 h incubated neutrophils and thioglycollate-elicited macrophages. IAA caused a marked increase on oxygen consumption by neutrophils, which was more pronounced in the presence of the glutamine as compared to glucose. The stimulation of oxygen consumption leads to a reduction in NADH/NAD+ ratio that activates the flux of substrates through the Krebs cycle. Since glutamine is mainly metabolized through the left hand side of the Krebs cycle, a reduction in the redox state of the cells may accelerate the flux of substrates through glutaminolysis. The toxic results presented here show that the affect of IAA in association with peroxidase involves activation of glutamine metabolism.     

Dependence of histochemical staining of leukocyte aminopeptidase upon its biochemical enzyme activity

The relationship between histochemical staining and biochemical activity of the enzyme was investigated using leukocytes with different aminopeptidase activities. In guinea-pig neutrophils and macrophages which have a relatively high enzyme activity, the histochemical staining correlated with the biochemical enzyme activity. On the other hand, guinea-pig lymphocytes and mouse neutrophils whose enzyme activities were 8.25 +/- 0.27 mU/10(7) cells and 6.18 +/- 0.87 mU/10(7) cells, respectively, were not stained by histochemical techniques. When guinea-pig neutrophils were modified chemically by diazotized sulfanilic acid at different concentrations, the histochemical staining of neutrophils decreased in proportion to the degree of inhibition of their biochemical enzyme activity and hardly became detectable below 10 mU/10(7) cells. However, guinea-pig neutrophils contained the soluble enzyme, corresponding to 5 mU/10(7) cells, which leaked out rapidly from cells during staining procedure, suggesting that the limit of visualization of the membrane-bound aminopeptidase activity by the histochemical techniques is about 5 mU/10(7) cells. The membrane-bound enzyme activities in guinea-pig lymphocytes and mouse neutrophils were 5 mU and 3 mU per 10(7) cells, respectively, and so it is possible that these leukocytes hardly stained histochemically.     

Enhancement of lysophospholipase activity with Trichinella spiralis antigen: evidence for cell cooperation

Murine lymphocytes, neutrophils, macrophages and eosinophils were assayed for lysophospholipase in order to determine the cellular source of the enzyme. The eosinophil was the only cell that demonstrated a positive reaction for the enzyme. The role of other cells and/or antigen in production of the enzyme by the eosinophil was also investigated. Results demonstrated that eosinophils cultured with both Trichinella spiralis antigen and other leukocytes (lymphocytes and/or macrophages) yielded enzyme activities significantly greater than did eosinophils cultured alone or with only antigen. More specific experiments showed that T-lymphocytes were the cells responsible for influencing the eosinophils' production of lysophospholipase in the presence of antigen, and that their influence was enhanced by the presence of macrophages. These results suggest that increased lysophospholipase activity present in parasitized tissue is not only due to an increased number of eosinophils infiltrating parasitized tissues, but is also due to each eosinophil synthesizing more of the enzyme for release. The necessity for antigen and other cells suggests a need for cell cooperation in the production of the enzyme, specifically T-lymphocytes and macrophage interaction with the eosinophil.     

Characteristics of two lines of guinea pigs (BHS and BHR) differing in bronchial sensitivity to acetylcholine and histamine exposure.

In a previous study, we reported that as model animals to be used in the study of bronchial asthma in humans, two lines of guinea pigs were developed by ourselves: bronchial hypersensitive line (BHS) and bronchial hyposensitive line (BHR) as a control. Studies on biological characteristics in guinea pigs of two lines were undertaken, and the following results were obtained. 1) Airway resistance of guinea pigs of the two lines to intravenously administered acetylcholine, histamine and leukotriene D4 was found to be different between BHS and BHR. Airway resistance of BHS to the chemicals was increased compared with those of BHR. 2) The number of muscarinic acetylcholine receptors in lung membrane preparation and its affinity increased significantly in BHS compared with those of BHR. In beta-adrenergic and histamine H1 receptors, there was observed no difference between BHS and BHR. 3) No difference in IgE antibody production to ovalbumin was observed between BHS and BHR. 4) When total leukocytes and differential leukocyte count (percentage, %) in peripheral blood of BHS and BHR were examined, relative percentage of lymphocytes and eosinophils was significantly higher in BHS than in BHR, while percentage of neutrophils was significantly lower in the former than in the latter.     

Further Studies on Guinea Pig Z-1 Antigen That Is Involved in Phagocytosis of Zymosan by Macrophages: Cell Type Distribution of the Antigen and Cross-Reactivity of Anti-Z-1 with Human CR3

We have previously identified a heterodimer molecule, Z-1, on guinea pig peritoneal macrophages (Møs) by the newly prepared monoclonal antibody, anti-Z-1, and Z-1 has been assumed to be the complement receptor type three (CR3) in this species. To clarify this assumption, the cell type distribution of the antigen in guinea pig and the cross-reactivity of anti-Z-1 with other species were analyzed. It was demonstrated that Z-1 was expressed on peritoneal Møs, pulmonary Møs, peritoneal polymorphonuclear leukocytes (PMN), peripheral neutrophils, and some subpopulations of spleen cells and of bone marrow cells, but not on erythrocytes, circulating lymphocytes, and lymphocytes in both spleen and bone marrow in detectable amounts. Thus the expression of Z-1 seems to be restricted to phagocytes as is CR3 of other species. Furthermore, it was found that anti-Z-1 bound with peripheral neutrophils from human, horse and goat and HL-60 cells differentiated into monocytes. Any cross-reactivity of the antibody was not detected with neutrophils from rabbit, cow, sheep and dog and nondifferentiated HL-60 cells. Human Z-1 was indistinguishable from human CR3, since both were the heterodimer consisting of α chain of 170 kDa (pI = 6.6-7.2) noncovalently associated with β chain of 100 kDa (pI = 5.6-6.7). In addition, human CR3 in detergent-lysate of neutrophils was completely adsorbed with anti-Z-1 F(ab')2-Sepharose. These findings indicate that guinea pig Z-1 shares an antigenic determinant with human CR3. It thus seems to be possible that Z-1 may function as CR3 in guinea pigs.     

Macrophage-T cell interaction mediated by immunogenic and non-immunogenic forms of a monofunctional antigen

Summary As an approach to the elucidation of the essential steps in the immune pathway, the uptake and retention of immunogenic and non-immunogenic analogs of a monofunctional antigen by guinea pig macrophages and the efficiency of macrophages pulsed with the compounds to present antigen to sensitized T lymphocytes were compared. L-Tyrosine-azobenzene-p-arsonate (RAT) and its non-immunogenic analog, 4-hydroxyphenyl-n-propane-3-azobenzene-p-arsonate (RAN), react similarly with antiarsonate antibody, but RAN, unlike RAT, is unable to induce cellular immunity in guinea pigs. The uptake and retention patterns of the two compounds by macrophages differed in that, at a given time, more RAN than RAT was retained and detectable on cell surfaces by anti-arsonate antibody. Equivalent numbers of T lymphocytes from guinea pigs sensitized to RAT formed antigen-dependent clusters with macrophages pulsed with either RAT or RAN after 24 hr in culture, but not with macrophages pulsed with an azobenzenoid compound of unrelated specificity. On the other hand, T lymphocytes from guinea pigs immunized with RAN showed no significant capacity to bind to macrophages which had been pulsed with any of the compounds. The number of lymphocytes from RAT-sensitized animals which bound to RAT-pulsed macrophages remained relatively stable over a 48 hr period, whereas clusters of the same lymphocytes with RAN-pulsed macrophages dissocitated to background levels within that time. Early cluster formation mediated by RAN, as well as its ability to induce transient specific T cell unresponsiveness to RAT in vivo, indicate that T cells are capable of recognizing (binding) the non-immunogen. However, such early, and perhaps weak, interaction with RAN-pulsed macrophages did not induce DNA synthesis by T cells. Anti-Ia serum completely blocked cluster formation mediated by either RAT or RAN. Thus, the only significant distinction disclosed by these studies between the immunogenic and non-immunogenic compounds was the stability of macrophage-T cell interaction as determined by the persistence of antigen mediated cell clusters in culture, suggesting that this may be a factor in immunogenic discrimination.Abbreviations ABA azobenzenearsonate - BSA bovine serum albumin - CFA complete Freund's adjuvant - IFA incomplete Freund's adjuvant - KLH keyhole limpet hemocyanin - LNC Lymph node cells - MHC major histocompatibility complex - PEC peritoneal exudate cells - PEL peritoneal exudate lymphocytes - RAN 4-hydroxyphenyl-n-propane-3-azobenzene-p-arsonate - RAT L-tyrosine-azobenzene-p-arsonate - TAT L-tyrosine-azobenzene-p-trimethylammonium chloride Aided by USPHS Grant AI 05664.     

Dependence of histochemical staining of leukocyte aminopeptidase upon its biochemical enzyme activity

Summary The relationship between histochemical staining and biochemical activity of the enzyme was investigated using leukocytes with different aminopeptidase activities. In guinea-pig neutrophils and macrophages which have a relatively high enzyme activity, the histochemical staining correlated with the biochemical enzyme activity. On the other hand, guinea-pig lymphocytes and mouse neutrophils whose enzyme activities were 8.25±0.27 mU/10⁷ cells and 6.18±0.87 mU/10⁷ cells, respectively, were not stained by histochemical techniques. When guinea-pig neutrophils were modified chemically by diazotized sulfanilic acid at different concentrations, the histochemical staining of neutrophils decreased in proportion to the degree of inhibition of their biochemical enzyme activity and hardly became detectable below 10 mU/10⁷ cells. However, guinea-pig neutrophils contained the soluble enzyme, corresponding to 5 mU/10⁷ cells, which leaked out rapidly from cells during staining procedure, suggesting that the limit of visualization of the membrane-bound aminopeptidase activity by the histochemical techniques is about 5 mU/10⁷ cells. The membrane-bound enzyme activities in guinea-pig lymphocytes and mouse neutrophils were 5 mU and 3 mU per 10⁷ cells, respectively, and so it is possible that these leukocytes hardly stained histochemically.     

Leukocyte differential analysis in multiple laboratory species by a laser multi-angle polarized light scattering separation method.

Leukocyte differential analysis was performed in various species, particularly laboratory animals, by the laser multi-angle polarized light scattering separation method. Venous blood specimens were drawn from the following subjects: healthy adult men and women ("humans"); cynomolgus monkeys ("monkeys"); common marmosets ("marmosets"); beagle dogs ("dogs"); miniature potbelly pigs ("swine"); Japanese white rabbits ("rabbits"); Hartley guinea pigs ("guinea pigs"); and Sprague-Dawley rats ("rats"). 90 degrees/10 degrees scatter plot: Basophils and mononuclear-polymorphonuclear cells were separated in all subjects, but individual 10 degrees and 90 degrees scatter plots overlapped in dogs and guinea pigs, respectively. 90 degrees depolarized /90 degrees scatter plot: Neutrophils and eosinophils were clearly separated in human, monkey, guinea pig, swine and rat subjects. The eosinophil cluster was not clearly plotted in marmoset, dog, or rabbit. 0 degree/10 degrees scatter plot: Regarding this plot for monocytes and lymphocytes, cells were plotted in the following order in all subjects: lymphocytes < basophils < or = monocytes in the 0 degree (size) scatter; and lymphocytes [symbol: see text] monocytes < or = basophils in the 10 degrees (complexity) scatter. Compared to other species, the rat scatter showed a tendency to overlapping plots in both the 0 degree and 10 degrees scatters in the monocyte and lymphocyte clusters. In both dog and guinea pig, the monocyte and neutrophil plots overlapped in the 0 degree and 10 degrees scatters. Basobox: In the human and rabbit subjects, the basophil cluster was plotted within the established basobox, but no clear cell cluster was plotted in the other subjects. As a result of comparing the percentage values for leukocytes in various species obtained by using the CD3500 apparatus versus the corresponding values obtained manually, good correspondence was found in the monkey, and eosinophils in the marmoset were lower with CD3500 than manually. In the rabbit, the mean measured value for basophils matched in the manual and CD3500 findings. In the guinea pig, the CD3500 values were lower than the manual values for lymphocytes, but higher for monocytes and neutrophils. The above findings suggest that the laser multi-angle polarized light scattering separation method is indeed capable of analyzing leukocytes from various species based on cell size and cell complexity, i.e., the presence or absence of nuclei, granules and cell enclosures.     

Light and electron microscopic demonstration of phospholipase B activity in the mouse eosinophil

Phospholipase B (EC 3.1.1.5) which hydrolyzes phospholipids in the alpha and beta positions was demonstrated in murine leukocytes using light and electron microscopic histochemical techniques. Leukocytes (neutrophils, lymphocytes, macrophages, eosinophils) were harvested from peritoneal exudates of mice. Cells were fixed in 4% calcium-formol fixative for 10 min at 4 degrees C for light microscopy and 30 min at room temperature for electron microscopy, after which they were incubated at 37 degrees C in medium at pH 6.6 containing 2 microM lysolecithin and CaCl2. The fatty acids released during the hydrolytic reaction were trapped as a calcium precipitate and were converted to a cobalt precipitate for light microscopy by treatment with cobalt acetate or to a lead precipitate for electron microscopy by treatment with lead nitrate. The reaction products were observed to be present in eosinophils and absent in neutrophils, lymphocytes and macrophages. It is concluded that the eosinophilic leukocyte is the carrier cell for phospholipase B in inflammatory reactions.     

Identification of the principal cell type yielding immune RNA capable of transferring tumor-specific cellular cytotoxicity

A search was made for the lymphoid cell type(s) which are the source of immune RNA (I-RNA) capable of transferring tumor-specific cell-mediated cytotoxicity (CMC). Hartley guinea pigs were immunized with syngeneic murine fibrosarcomas (BP-10 or BP-11) induced by 3,4-benzo(a)pyrene in C3H/HeJ mice, and the I-RNA was extracted individually from their spleens, lymph nodes, and peritoneal exudate (PE) cells. All three I-RNA preparations were able to convert normal C3H/HeJ mouse lymphocytes to effector cells significantly cytolytic to the specific syngeneic mouse tumor in vitro. Furthermore, lymphocytes and macrophages were purified from the spleens, lymph nodes, and PE cells of tumor-immunized guinea pigs. I-RNA was extracted from these purified cell populations and also from the pooled guinea pig lymphoid tissues. Normal C3H/HeJ lymphocytes were incubated with each type of I-RNA and tested in vitro for CMC against the specific tumor cells. Significant CMC against BP-10 targets was observed with mouse lymphocytes incubated with I-RNA extracted from pooled lymphoid tissues of BP-10 tumor-immunized guinea pigs. There was a reduced but still significant CMC when mouse lymphocytes were incubated with I-RNA extracted from purified guinea pig lymphocytes, whereas there was a markedly increased CMC when the I-RNA was extracted from purified guinea pig macrophages. As indicated by sucrose density gradient analysis, the lesser effectiveness of lymphocyte I-RNA was not due to RNA degradation resulting from lymphocyte purification or I-RNA extraction. Treatment of all types of I-RNA with RNase abrogated the transfer of CMC, whereas treatment of I-RNA with DNase or pronase did not. RNA extracted from the lymphoid tissues of guinea pigs immunized with complete Freund's adjuvant without tumor was ineffective. Mouse lymphocytes incubated with BP-10 macrophage I-RNA destroyed BP-10 but not BP-11 tumor cells, whereas lymphocytes incubated with BP-11 macrophage I-RNA killed BP-11 but not BP-10 tumor cells, thus indicating tumor specificity of the immunity transferred by macrophage I-RNA. Our results suggest that macrophages are the principal source of I-RNA capable of transferring tumor-specific CMC.     

Relations between number and volume of erythrocytes and leukocytes in the human blood

Total concentration of erythrocytes and leukocytes, a relative contents of neutrophils, lymphocytes, monocytes, average volume of these types of cells, were determined in humans. Changes in the cell indices seem to be correlated and sex-dependent. Thus, erythrocytes and leukocytes are correlated in their contents and volume characteristics. A control mechanism seems to exist in humans, involving microcirculation in capillaries.     

Pathogenesis of experimental allergic orchitis. III. T lymphocyte requirement in local adoptive transfer by peritoneal exudate cells.

In experimental allergic orchitis (EAO), a lesion characterized by mononuclear invasion of seminiferous tubules can be adoptively transferred within 1 to 4 days by testicular injection of peritoneal exudate cells (PEC) from syngeneic strain 13 guinea pigs (GP) immunized with homologous testicular antigens in complete Freund's adjuvant (CFA). This study examined the role of T lymphocytes, macrophages, and polymorphonuclear neutrophils (PMN) in the adoptive transfer. Guinea pig PEC contained 7% T lymphocytes, rare B lymphocytes, and over 90% of macrophages and PMN. After T lymphocytes were depleted by rabbit erythrocyte (E) rosette and Hypaque-Ficoll gradient centrifugation, cell preparations that contained 73% of original macrophages and 15% original T lymphocytes were obtained, and these cells did not transfer EAO (0 of 18 testes). In contrast, cell preparations enriched in T lymphocytes by nylon wool column or E rosette contained 1.5% of the original macrophages and 59% of the original T lymphocytes transferred EAO to 70% of the testes, starting at 1.5 x 10(6) T lymphocytes per testis. The number of T lymphocytes correlated with the incidence of adoptive transfer; the correlation existed regardless of the number of macrophages or PMN present. Finally, EAO was adoptively transferred to recipients that had total-body irradiation. The results indicate that (a) T lymphocytes are capable of transferring lesions of EAO, (b) in the transfer, the T lymphocytes did not function as helper T cells, since the transfer need not involve participation of host lymphoid cells, and (c) by inference, testis antigen-reactive T lymphocytes exist.     

Cytochemical study of macrophage lysosomal inorganic trimetaphosphatase and acid phosphatase

Cytochemical investigations have associated acid inorganic trimetaphosphatase (TMPase) activity with the lysosomes of certain cell types. We have used the modified staining technique of Berg to show that this enzyme activity is present in normal mononuclear phagocytes and macrophage cell lines. We have found this enzyme activity to be present in murine RAW264 macrophages, in human U937 macrophages, in normal human blood monocytes, and in guinea pig peritoneal macrophages. All of the RAW264 and U937 macrophages showed intense TMPase activity. Many of the human monocytes and most of the guinea pig macrophages were labeled by this method. The reaction product was associated with the lysosomes of these cell types. The lysosomal staining-pattern was similar to that of acid phosphatase. Differences with regard to Golgi staining were noted. This indicates that TMPase is a lysosomal enzyme of mammalian macrophages. The distinction between TMPase and acid phosphatase activity has been demonstrated by measuring the pH optimum of each enzyme. Using substrates identical to those of the ultrastructural cytochemistry, we show that the pH optimum of TMPase is 4.0 and that of acid phosphatase is 5.0. The enzymatic activities are therefore ultrastructurally and biochemically distinct. Following phagocytosis of latex, yeast (Saccharomyces cerevisiae), or Corynebacterium parvum, TMPase has been found to be associated with phagosomes. This enzyme may take part in the degradation of phagocytosed materials, particularly microorganisms which contain inorganic polyphosphates and metaphosphates.     

Species-specific distribution of cathepsin E in mammalian blood cells

The distribution of cathepsins D and E in leukocytes and erythrocyte ghosts of several mammalian species, and in HL-60 and K-562 cells was examined by means of a combined application of electrophoretic and immunochemical methods. Cathepsin D was found in leukocytes of all species examined, but the distribution of cathepsin E was found to be species-specific: pigs, cows and goats had no cathepsin E activity in leukocytes or erythrocytes at all. In humans, cathepsin E occurred in erythrocytes but not in leukocytes, which contrasted with the guinea pig pattern of its presence in leukocytes and its absence in erythrocytes. No cathepsin E-related enzymes were found in HL-60 or K-562 cells, but these human leukemic cells contained cathepsin D-related enzyme forms that are electrophoretically distinct from normal leukocyte cathepsin D. The present results are inconsistent with the view that cathepsin E may be involved as an essential factor in the biological functions of leukocytes or erythrocytes.