Modification of lymphocyte migration by mannans and phosphomannans. Different carbohydrate structures control entry of lymphocytes into spleen and lymph nodes

Previous in vitro studies suggest that recognition of phosphomannosyl structures by lymphocytes plays a central role in the binding of lymphocytes to high endothelial venules. However, the physiologic relevance of phosphomannosyl recognition in in vivo lymphocyte migration has not been established. This paper describes experiments that examined this question. It was demonstrated that the phosphomannan monoester core (PPME) from Pichia holstii, a potent inhibitor of peripheral node high endothelial venule interactions in vitro, was a very effective inhibitor of in vivo lymphocyte migration, as little as 39 micrograms/mouse significantly inhibiting popliteal lymph node entry. Furthermore, PPME exhibited a similar hierarchy of inhibition in vivo as previously reported in vitro, most effectively inhibiting entry of lymphocytes into popliteal lymph node, somewhat less effectively inhibiting mesenteric lymph node entry and being a relatively poor inhibitor of Peyer's patch entry. Additionally, PPME inhibited splenic entry of lymphocytes, and inhibition of lymphoid organ entry was accompanied by a substantial leukocytosis. Two additional mannose-containing compounds were found to modify lymphocyte migration, namely a well defined mannose containing pentasaccharide (PENT) with terminal mannose-6-phosphate (M6P) and an unphosphorylated yeast mannan. Both PENT and mannan induced leukocytosis and were particularly effective at inhibiting splenic entry of lymphocytes. In fact, detailed dose-response curves indicated that mannan was a much more potent inhibitor of splenic entry than PPME or PENT, whereas in lymph nodes PPME was the most effective inhibitor. Pretreatment of lymphocytes before injection with either PPME or mannan demonstrated that PPME could act at the lymphocyte level, whereas mannan probably acted at some other site. Collectively, these data suggest that different carbohydrate structures are involved in the entry of lymphocytes into different lymphoid organs, with mannose recognition playing an important role in splenic entry and recognition of M6P-like structures controlling lymph node entry. In contrast, it was found that mannose-and M6P-containing structures, unlike sulfated polysaccharides such as fucoidan, did not affect the subsequent positioning of lymphocytes within lymphoid organs.     

Leukocyte-endothelial cell recognition: evidence of a common molecular mechanism shared by neutrophils, lymphocytes, and other leukocytes

The interaction of leukocytes with endothelial cells is intrinsic to the process of leukocyte extravasation, whether during the entry of blood polymorphonuclear leukocytes and monocytes into sites of acute and chronic inflammation, or during the homing of lymphocytes to lymphoid organs. A lymphocyte surface glycoprotein, defined by monoclonal antibody MEL-14, has been described that appears to mediate lymphocyte recognition of postcapillary venules in peripheral lymph nodes, and to control the migration of lymphocytes from the blood into these lymphoid organs. We now report that the antigenic determinant recognized by MEL-14 is present at high levels on other leukocytes as well, including neutrophils, monocytes, and eosinophils; and we demonstrate involvement of the MEL-14 antigen in neutrophil-endothelial cell interactions. MEL-14 immunoprecipitates a neutrophil surface protein of Mr approximately 100,000, similar in m.w. to the 80,000 to 90,000 dalton lymphocyte surface MEL-14 antigen, and it blocks the interaction of neutrophils with endothelial cells in an in vitro model of adhesion to postcapillary venules in lymph node frozen sections. Neutrophil binding to lymph node venules is also inhibited by PPME, a mannose-6-phosphate-rich yeast polysaccharide that is thought to mimic the endothelial cell ligand for the MEL-14-defined lymphocyte receptor. Interestingly, neither MEL-14 nor PPME exhibit a major effect on neutrophil binding to postcapillary venules in Peyer's patches, suggesting that as for lymphocytes, the neutrophil MEL-14 antigen is involved in recognition of tissue-specific endothelial determinants. Finally, we show that MEL-14 inhibits the capacity of neutrophils to migrate from the blood into sites of acute inflammation in the skin. These observations lead us to propose that receptors for tissue-specific endothelial determinants are utilized by neutrophils and lymphocytes and probably other leukocytes during the physiologic process of leukocyte extravasation in vivo.     

Possible role for cell-surface carbohydrate-binding molecules in lymphocyte recirculation

We are investigating the hypothesis that carbohydrate-binding molecules on the cell surface are involved in the recirculation of lymphocytes from the bloodstream into lymphoid organs. This phenomenon requires the specific attachment of circulating lymphocytes to the endothelial cells of postcapillary venules. Using an in vitro assay to measure the adhesive interaction between lymphocytes and postcapillary venules, we have found that L-fucose, D mannose, and the L-fucose-rich, sulfated polysaccharide fucoidin specifically inhibit this binding interaction. L-fucose shows stereo-selective inhibitory activity at concentrations greater than 18 mM while fucoidin produces 50% inhibition at approximately 1-5 X 10(-8) M. Fucoidin appears to interact with the lymphocyte, and not the postcapillary venule, to inhibit binding. These data suggest that cell surface carbohydrates (fucoselike) and carbohydrate-binding molecules (cell surface lectins) may contribute to the specific attachment of lymphocytes to postcapillary venules.     

Phosphomannosyl-derivatized beads detect a receptor involved in lymphocyte homing

Recirculating lymphocytes initiate extravasation from the blood stream by binding to specialized high endothelial venules (HEV) within peripheral lymph nodes (PN) and other secondary lymphoid organs. We have previously reported that lymphocyte attachment to PN HEV is selectively inhibited by mannose-6-phosphate (M6P) and related carbohydrates (Stoolman, L. M., T. S. Tenforde, and S. D. Rosen, 1984, J. Cell Biol., 99:1535-1540). In the present study, we employ a novel cell-surface probe consisting of fluorescent beads derivatized with PPME, a M6P-rich polysaccharide. PPME beads directly identify a carbohydrate-binding receptor on the surface of mouse lymphocytes. In every way examined, lymphocyte attachment to PPME beads (measured by flow cytofluorometry) mimics the interaction of lymphocytes with PN HEV (measured in the Stamper-Woodruff in vitro assay): both interactions are selectively inhibited by the same panel of structurally related carbohydrates, are calcium-dependent, and are sensitive to mild treatment of the lymphocytes with trypsin. In addition, thymocytes and a thymic lymphoma, S49, bind poorly to PPME beads in correspondence to their weak ability to bind to HEV. When the S49 cell line was subjected to a selection procedure with PPME beads, the ability of the cells to bind PPME beads, as well as their ability to bind to PN HEV, increased six- to eightfold. We conclude that a carbohydrate-binding receptor on mouse lymphocytes, detected by PPME beads, is involved in lymphocyte attachment to PN HEV.     

Hexose phosphates as regulators of hepatic glycogen synthase phosphatases

The activity of glycogen synthase phosphatase from smooth endoplasmic reticulum of liver was stimulated markedly by galactose-6- and fructose-6-phosphates and to a lesser extent by glucose-1- and 2-deoxyglucose-6-phosphates. The synthase phosphatase of liver cytosol showed strong activation by glucose-1-, glucose-6- and fructose-6-phosphates and smaller activation by galactose-6- and 2-deoxyglucose-6-phosphates. Kinetic analysis showed that the activators did not affect the Km for glycogen synthase D, for either enzyme. The mechanism of activation of the two phosphatases by hexose phosphates appears to be by combination of the activator at a specific activator site on the enzyme rather than by substrate modulation. It is concluded that certain hexose phosphates, particularly fructose-6-phosphate and glucose-1-phosphate, can function as regulators of hepatic synthase phosphatase activity, and that this may explain the ability of elevated blood glucose to increase both glycogen synthase I activity and glycogen synthesis in the liver.     

Receptors involved in lymphocyte homing: relationship between a carbohydrate-binding receptor and the MEL-14 antigen

Blood-borne lymphocytes extravasate in large numbers within peripheral lymph nodes (PN) and other secondary lymphoid organs. It has been proposed that the initiation of extravasation is based upon a family of cell adhesion molecules (homing receptors) that mediate lymphocyte attachment to specialized high endothelial venules (HEV) within the lymphoid tissues. A putative homing receptor has been identified by the monoclonal antibody, MEL-14, which recognizes an 80-90-kD glycoprotein on the surface of mouse lymphocytes and blocks the attachment of lymphocytes to PN HEV. In a companion study we characterize a carbohydrate-binding receptor on the surface of mouse lymphocytes that also appears to be involved in the interaction of lymphocytes with PN HEV. This receptor selectively binds to fluorescent beads derivatized with PPME, a polysaccharide rich in mannose-6-phosphate. In this report we examine the relationship between this carbohydrate-binding receptor and the putative homing receptor identified by the MEL-14 antibody. We found that: MEL-14 completely and selectively blocks the activity of the carbohydrate-binding receptor on mouse lymphocytes; the ability of six lymphoma cell lines to bind PPME beads correlates with cell-surface expression of the MEL-14 antigen, as well as PN HEV-binding activity; selection of lymphoma cell line variants for PPME-bead binding by fluorescence-activated cell sorting (FACS) produces highly correlated (r = 0.974, P less than 0.001) and selective changes in MEL-14 antigen expression. These results show that the carbohydrate-binding receptor on lymphocytes and the MEL-14 antigen, which have been independently implicated as receptors involved in PN-specific HEV attachment, are very closely related, if not identical, molecules.     

Multiple carbohydrate receptors on lymphocytes revealed by adhesion to immobilized polysaccharides

Phosphomannan polysaccharides and fucoidan, a polymer of fucose 4-sulfate, have been demonstrated to inhibit adhesion of lymphocytes to tissue sections that contain high endothelial venules (Stoolman, L. M., T. S. Tenforde, and S. D. Rosen, 1984, J. Cell Biol., 99:1535-1540). We have investigated the potential cell surface carbohydrate receptors involved by quantitating adhesion of rat cervical lymph node lymphocytes to purified polysaccharides immobilized on otherwise inert polyacrylamide gels. One-sixth of the lymphocytes adhered specifically to surfaces derivatized with PPME (a phosphomannan polysaccharide prepared from Hansenula holstii yeast), whereas up to half of the cells adhered to surfaces derivatized with fucoidan. Several lines of evidence demonstrated that two distinct receptors were involved. Adhesion to PPME-derivatized gels was labile at 37 degrees C (decreasing to background levels within 120 min) whereas adhesion to fucoidan-derivatized gels was stable. Soluble PPME and other phosphomannans blocked adhesion only to PPME-derivatized gels; fucoidan and a structurally related fucan blocked adhesion to fucoidan-derivatized gels. Other highly charged anionic polysaccharides, such as heparin, did not block adhesion to either polysaccharide-derivatized gel. Adhesion to PPME-derivatized gels was dependent on divalent cations, whereas that to fucoidan-derivatized gels was not. The PPME-adherent lymphocytes were shown to be a subpopulation of the fucoidan-adhesive lymphocytes which contained both saccharide receptors. These data reveal that at least two distinct carbohydrate receptors can be found on peripheral lymphocytes.     

The synthesis of mannose 1-phosphate in brain

The interconversion of mannose-6-P and mannose-1-P in brain has been shown to be catalyzed by a distinct enzyme. The enzyme has been separated from most of the phosphoglucomutase activity of the brain. The residual phosphoglucomutase activity (less than 1%) may be associated with phosphomannomutase itself. Mannose-1,6-P2 or glucose-1,6-P2 is required for the reaction as well as a divalent cation (Mg2+ greater than Co2+ greater than Ni2+ greater than Mn2+). Glucose-1-P, glucose-6-P, and 2-deoxyglucose-6-P are also substrates or inhibitors. Other phosphorylated sugars tested, glucosamine-6-P, N-acetylglucosamine-6-P, galactose-6-P, fructose-6-P, ribose-5-P, and arabinose-5-P, do not affect the rate of the reaction when assayed in the presence of mannose-6-32P.     

Fructose-2,6-bisphosphate in rat mesenteric lymph nodes

1. The fructose-2,6-bisphosphate (Fru-2,6-P2) content of mesenteric lymph nodes was measured in rats. 2. The effects of Fru-2,6-P2 on the activity of 6-phosphofructo-1-kinase (PFK-1) from rat mesenteric lymph nodes were also studied. 3. The affinity of the enzyme for fructose-6-phosphate was increased by Fru-2,6-P2 whereas the inhibition of the enzyme with high concentrations of ATP was released by Fru-2,6-P2. 4. The activity of lymphocyte PFK-1 was highly stimulated in a simultaneous presence of low concentrations of AMP and Fru-2,6-P2. 5. These results show that rat lymphocyte PFK-1 is highly regulated with Fru-2,6-P2 which means that glycolysis in rat lymphocytes is controlled by Fru-2,6-P2.     

Function and evolutionary conservation of distinct epitopes on the leukocyte adhesion molecule-1 (TQ-1, Leu-8) that regulate leukocyte migration.

The leukocyte adhesion molecule-1 (LAM-1, TQ=1, Leu-8) in humans, like its murine homologue, MEL-14, is the principal receptor that mediates the binding of leukocytes to high endothelial venules (HEV) of peripheral lymph nodes. In this study, several regions of the protein which mediate receptor function were identified by using a large panel of murine mAb reactive with LAM-1. Individual mAb reacted with LAM-1+ cells with characteristic intensities of immunofluorescence staining, and each bound both lymphocytes and neutrophils. Lymphocyte attachment to HEV was significantly inhibited by the binding of five mAb. In contrast, only two of these mAb were able to completely block the binding of phosphomannan monoester core complex from the yeast Hansenula holstii cell wall (PPME), a phosphomannan monoester core polysaccharide that serves as a soluble model of the natural ligand of LAM-1. Interestingly, the binding of two anti-LAM-1 mAb to cells induced a significant increase in PPME binding, reminiscent of the increase in receptor affinity observed after leukocyte activation. Antibody cross-blocking studies indicated that many of the functionally important epitopes were spatially distinct, and domain mapping indicated that they recognized distinct domains of LAM-1. The expression and function of these epitopes were further assessed by using a variety of animal species to further characterize the functionally relevant epitopes defined in these studies. At least some anti-LAM-1 mAb reacted with leukocytes from monkey, cow, rabbit, sheep, dog, cat, pig, and goat, but not from chicken, rat, or mouse. The reactivity of anti-LAM-1 mAb in several animal species correlated with the ability of leukocytes to bind PPME, and mAb that inhibited lymphocyte binding to HEV in man could also inhibit this function in rhesus monkey and dog. Thus, several LAM-1 epitopes are structurally and functionally well conserved throughout recent mammalian evolution, emphasizing an important role for LAM-1 in the regulation of leukocyte traffic.     

Catalytic properties of glucose-6-phosphate dehydrogenase from pea leaves.

A homogeneous preparation of glucose-6-phosphate dehydrogenase (G6PDH, EC 1.1.1.49) with a specific activity of 3.88 U/mg protein was isolated from pea (Pisum sativum L.) leaves. The molecular mass of the G6PDH is 79 +/- 2 kD. According to SDS-PAGE, the molecular mass of the enzyme subunit is 40 +/- 3 kD. The Km values for glucose-6-phosphate and NADP are 2 and 0.5 mM, respectively. The enzyme has a pH optimum of 8.0. Mg2+, Mn2+, and Ca2+ activate the enzyme at concentrations above 1 mM. Galactose-6-phosphate and fructose-6-phosphate inhibit the G6PDH from pea leaves. Fructose-1, 6-bisphosphate and galactose-1-phosphate are enzyme activators. NADPH is a competitive inhibitor of the G6PDH with respect to glucose-6-phosphate (Ki = 0.027 mM). ATP, ADP, AMP, UTP, NAD, and NADH have no effect on the activity of the enzyme.     

Direct demonstration of the lectin activity of gp90MEL, a lymphocyte homing receptor

Considerable evidence implicates gp90MEL as a lymphocyte homing receptor mediating lymphocyte attachment to high endothelial venules of lymph nodes in mouse. The protein appears to function as a calcium-dependent, lectin-like receptor as inferred primarily by the ability of specific carbohydrates to block its function and by the presence of a calcium-type lectin domain in its primary sequence. An ELISA assay is described which provides the first demonstration that the isolated protein has lectin activity and allows a further definition of its carbohydrate specificity. In addition to the monosaccharides mannose-6-phosphate and fructose-1-phosphate, ligand activity is shown for the sulfated glycolipid, sulfatide, and for two sulfated fucose-containing polysaccharides (fucoidin and egg jelly coat) from nonmammalian sources.     

Galactose-1-Phosphatase in Rat Brain

A prominent galactose-1-phosphatase was isolated from rat brain and partially purified by chromatography on diethylaminoethyl-Sephacel, hydroxylapatite, and Sephacryl S-300 columns. The galactose-1-phosphatase was separated from alkaline phosphatase, and from two forms of glucose-1-phosphatase. The three columns gave a 10-fold increase in specific activity to 290 mol/min/mg of protein, with a yield of 15%. Of the eight sugar phosphates tested, galactose-1-phosphate was the best substrate for the purified enzyme, followed by glucose-1-phosphate, which was hydrolyzed 40% as rapidly as galactose-1-phosphate. Galactose-1-phosphatase had an optimum pH of 8.5 and a Km value of 2.5 mM for galactose-1-phosphate hydrolysis. Mg2+ was required for activity, and supported half-maximal activity at a concentration of 1.25 mM. Phosphate was the only potent inhibitor found ATP, arsenate, and vanadate caused moderate inhibition of 10 mM levels, whereas AMP, L-homoarginine, and L-phenylalanine stimulated enzyme activity. Galactose-1-phosphatase was determined to have a Stokes radius of 30 A and a sedimentation coefficient of 4.1S. These values were used to calculate a molecular weight of 50,200 and a frictional ratio showing the enzyme to be a globular protein. It is hypothesized that a similar phosphatase may play a role in reducing brain galactose-1-phosphate concentrations in patients with galactosemia.     

Isomerase activity of the C-terminal fructose-6-phosphate binding domain of glucosamine-6-phosphate synthase from Escherichia coli

The isomerase activity of the C-terminal fructose-6P binding domain (residues 241-608) of glucosamine-6-phosphate synthase from Escherichia coli has been studied. The equilibrium constant of the C-terminal domain k(eq) ([glucose-6P]/[fructose-6-P]) = 5.0. A non-competitive product inhibition of the isomerase activity by the reaction product glucose-6-P has been detected. The existence of more than one binding and reaction sites for the substrate fructose-6P on the molecule of glucosamine-6-phosphate synthase can be expected. The fructose-6P binding domain possibly includes a regulatory site, different from the catalytic center of the enzyme.     

Galactose inhibition of auxin-induced growth of mono- and dicotyledonous plants

Galactose inhibited auxin-induced cell elongation of oat coleoptiles but not that of azuki bean stems. Galactose decreased the level of UDP-glucose in oat coleoptiles but not in azuki bean hypocotyls. Glucose-1-phosphate uridyltransferase activity (EC 2.7.7.9), in a crude extract from oat coleoptiles, was competitively inhibited by galactose-1-phosphate, but that enzyme from azuki bean was not. A correlation was found between inhibition of growth by galactose and inhibition of glucose-1-phosphate uridyltransferase activity by galactose-1-phosphate using oat, wheat, maize, barley, azuki bean, pea, mung bean, and cucumber plants. Thus, it is concluded that galactose is converted into galactose-1-phosphate, which interferes with UDP-glucose formation as an analog of glucose-1-phosphate.     

Studies on the metabolism of galactose-6-phosphate in rat heart and brain.

The subcellular distribution of NADP⁺ and NAD⁺-dependent glucose-6-phosphate and galactose-6-phosphate dehydrogenases were studied in rat liver, heart, brain, and chick brain. Only liver particulate fractions oxidized glucose-6-phosphate and galactose-6-phosphate with either NADP⁺ or NAD⁺ as cofactor. While all of the tissues examined had NADP⁺-dependent glucose-6-phosphate dehydrogenase activity, only rat liver and rat brain soluble fractions had NADP⁺-dependent galactose-6-phosphate dehydrogenase activity. Rat liver microsomal and rat brain soluble galactose-6-phosphate dehydrogenase activities were kinetically different (K_m's 0.5 mm and 10 mm, respectively, for galactose-6-phosphate), although their reaction products were both 6-phosphogalactonate. Rat brain subcellular fractions did not oxidize 6-phosphogalactonate with either NADP⁺ or NAD⁺ cofactors but phosphatase activities hydrolyzing 6-phosphogalactonate, galactose-6-phosphate and galactose-1-phosphate were found in crude brain homogenates. In addition, galactose-6-phosphate and 6-phosphogalactonate were tested as inhibitors of various enzymes, with largely negative results, except that 6-phosphogalactonate was a competitive inhibitor (K_i = 0.5 mM) of rat brain 6-phosphogluconate dehydrogenase.     

Catalytic properties of phosphoglucomutase from pea chloroplasts.

Electrophoretically homogeneous phosphoglucomutase (PGM) with specific activity of 3.6 units/mg protein was isolated from pea (Pisum sativum L.) chloroplasts. The molecular mass of this PGM determined by gel-filtration is 125 +/- 4 kD. According to SDS-PAGE, the molecular mass of subunits is 65 +/- 3 kD. The Km for glucose-1-phosphate is 18.0 +/- 0.5 microM, and for glucose-1, 6-diphosphate it is 33 +/- 0.7 microM. At glucose-1-phosphate and glucose-1,6-diphosphate concentrations above 0.5 and 0.2 mM, respectively, substrate inhibition is observed. The enzyme has optimum activity at pH 7.9 and 35 degrees C. Mg2+ activates the PGM. Mn2+ activates the enzyme at concentrations below 0.2 mM, while higher concentrations have an inhibitory effect. The activity of the PGM is affected by 6-phosphogluconate, fructose-6-phosphate, NAD+, ATP, ADP, citrate, and isocitrate.     

Human serum amyloid P is a multispecific adhesive protein whose ligands include 6-phosphorylated mannose and the 3-sulphated saccharides galactose, N-acetylgalactosamine and glucuronic acid.

Carbohydrate recognition by amyloid P component from human serum has been investigated by binding experiments using several glycosaminoglycans, polysaccharides and a series of structurally defined neoglycolipids and natural glycolipids. Two novel classes of carbohydrate ligands have been identified. The first is 6-phosphorylated mannose as found on lysosomal hydrolases, and the second is the 3-sulphated saccharides galactose, N-acetyl-galactosamine and glucuronic acid as found on sulphatide and other acidic glycolipids that occur in neural or kidney tissues or on subpopulations of lymphocytes. Binding to mannose-6-phosphate containing molecules and inhibition of binding by free mannose-6-phosphate and fructose-1-phosphate are features shared with mannose-6-phosphate receptors involved in trafficking of lysosomal enzymes. However, only amyloid P binding is inhibited by galactose-6-phosphate, mannose-1-phosphate and glucose-6-phosphate. These findings strengthen the possibility that amyloid P protein has a central role in amyloidogenic processes: first in formation of focal concentrations of lysosomal enzymes including proteases that generate fibril-forming peptides from amyloidogenic proteins, and second in formation of multicomponent complexes that include sulphoglycolipids as well as glycosaminoglycans. The evidence that binding to all of the acidic ligands involves the same polypeptide domain on amyloid P protein, and inhibition data using diffusible, phosphorylated monosaccharides, is potentially important leads to novel drug designs aimed at preventing or even reversing amyloid deposition processes without interference with essential lysosomal trafficking pathways.     

Histochemical studies of fructose-1,6-diphosphatase in various tissues of the rat

Summary Two methods to determine fructose-1,6-diphosphatase activity histochemically were tested on liver, intestine, skeletal muscle and heart of rats. Using lead ions to precipitate inorganic phosphate, according to Wachstein and Meisel, the addition of the specific inhibitor adenosine monophosphate caused an increase of phosphate precipitation. Therefore this method is often not suitable. A coupled assay, used to detect fructose-6-phosphate formed after conversion to glucose-6-phosphate (which in its turn may reduce tetrazolium dyes in the glucose-6-phosphate dehydrogenase reaction), was found to be satisfactory in liver to demonstrate specific fructose-1,6-diphosphatase activity, since adenosine monophosphate was strongly inhibitory. In intestine acid- and alkaline phosphatases, however, were found to interfere. In the latter organ, added adenosine monophosphate itself strongly stimulates formazan formation, which is probably due to high xanthine oxidase activity.In muscle, where a high aldolase activity is present, monoiodoacetate must be included in the incubation medium. Since fructose-1,6-diphosphatase activity in muscle is low compared with that of liver, the results obtained with muscle are often difficult to interpret.     

Kinetic properties of human placental glucose-6-phosphate dehydrogenase

The kinetic properties of placental glucose-6-phosphate dehydrogenase were studied, since this enzyme is expected to be an important component of the placental protection system. In this capacity it is also very important for the health of the fetus. The placental enzyme obeyed "Rapid Equilibrium Ordered Bi Bi" sequential kinetics with K(m) values of 40+/-8 microM for glucose-6-phosphate and 20+/-10 microM for NADP. Glucose-6-phosphate, 2-deoxyglucose-6-phosphate and galactose-6-phosphate were used with catalytic efficiencies (k(cat)/K(m)) of 7.4 x 10(6), 4.89 x 10(4) and 1.57 x 10(4) M(-1).s(-1), respectively. The K(m)app values for galactose-6-phosphate and for 2-deoxyglucose-6-phosphate were 10+/-2 and 0.87+/-0.06 mM. With galactose-6-phosphate as substrate, the same K(m) value for NADP as glucose-6-phosphate was obtained and it was independent of galactose-6-phosphate concentration. On the other hand, when 2-deoxyglucose-6-phosphate used as substrate, the K(m) for NADP decreased from 30+/-6 to 10+/-2 microM as the substrate concentration was increased from 0.3 to 1.5 mM. Deamino-NADP, but not NAD, was a coenzyme for placental glucose-6-phosphate dehydrogenase. The catalytic efficiencies of NADP and deamino-NADP (glucose-6-phosphate as substrate) were 1.48 x 10(7) and 4.80 x 10(6) M(-1)s(-1), respectively. With both coenzymes, a hyperbolic saturation and an inhibition above 300 microM coenzyme concentration, was observed. Human placental glucose-6-phosphate dehydrogenase was inhibited competitively by 2,3-diphosphoglycerate (K(i)=15+/-3 mM) and NADPH (K(i)=17.1+/-3.2 microM). The small dissociation constant for the G6PD:NADPH complex pointed to tight enzyme:NADPH binding and the important role of NADPH in the regulation of the pentose phosphate pathway.