Immunohistochemical localization of facilitated-diffusion glucose transporters in rat pancreatic islets

The subcellular localization of five isoforms of facillitated-diffusion glucose transporters (GLUTs), from GLUT1 to GLUT5, in rat pancreatic islets was studied by immunohistochemistry using rabbit polyclonal antisera against mouse or rat GLUT peptides. Animals were perfusion-fixed with phosphate-buffered 4% paraformaldehyde and the pancreases were removed. Some specimens were embedded in paraffin, serially sectioned, and immunostained for glucagon, insulin, somatostatin, and the GLUTs for light microscopic observation. Others were prepared for immunoelectron microscopy by the post-embedding method. By these methods, GLUT2 immunostaining was observed on the lateral membranes of pancreatic β-cells, whereas GLUT3 immunoreaction was predominatly localized in the cytoplasm to β-cells and was not found in α-cells. In contrast, GLUT5 immunostaining was preferentially localized in the cytoplasm of α-cells compared to that of β-cells. However, GLUT1 and GLUT4 were either barely or not at all detectable in any cells. These results suggest that rat islets take up glucose by at least three different processes and that blood glucose levels could be modulated differentially by: a high Km glucose transporter, GLUT2, in β-cells; by a low Km glucose transporter, GLUT3, in β-cells; and by a low Km glucose transporter, GLUT5, in α-cells.     

Over-expression of human type I (placental) 3β-hydroxy-5-ene-steroid dehydrogenase/isomerase in insect cells infected with recombinant baculovirus

Human type I placental 3β-hydroxy-5-ene-steroid dehydrogenase/steroid 5→4-ene-isomerase (3β-HSD/isomerase) synthesizes androstenedione from fetal dehydroepiandrosterone and progesterone from pregnenolone. The full length cDNA that encodes type I 3β-HSD/isomerase was inserted into the baculovirus, Autographa californica multiple nucleocapsid polyhedrosis virus, and expressed in Spodoptera fungiperda (Sf-9) insect cells. Western blots showed that the baculovirus-infected Sf-9 cells produced an immunoreactive protein that co-migrated with purified placental 3β-HSD/isomerase. Ultracentrifugation localized the expressed enzyme activities in all the membrane-associated organelles of the Sf-9 cell (nuclear, mitochondrial and microsomal). Kinetic studies showed that the expressed enzyme has 3β-HSD and isomerase activities. The Michaelis-Menton constant is very similar for the 3β-HSD substrate, 5-androstan-3β-o1-17-one, in the Sf-9 cell homogenate (K_m = 17.9 μM) and placental microsomes (K_m = 16.7 μM). The 3β-HSD activity (V_max = 14.5 nmol/min/mg) is 1.6-fold higher in the Sf-9 cell homogenate compared to placental microsomes (V_max = 9.1 nmol/min/mg). The K_m values are almost identical for the isomerase substrate, 5-androstene-3,17-dione, in the Sf-9 cell homogenate (K_m = 14.7 μM) and placental microsomes (K_m = 14.4 μM). The specific isomerase activity is 1.5-fold higher in the Sf-9 cells (V_max = 25.7 nmol/min/mg) relative to placenta (V_max = 17.2 nmol/min/mg). These studies show that our recombinant baculovirus system over-expresses fully active enzyme that is kinetically identical to native 3β-HSD/isomerase in human placenta.     

Kinetic properties of microsomal 3beta hydroxysteroid dehydrogenase-isomerase from the testis of Bufo arenarum H

3β-hydroxysteroid dehydrogenase 5-ene isomerase (3βHSD/I) activity is necessary for the biosynthesis of hormonally active steroids. A dual distribution of the enzyme was described in toad testes. The present study demonstrates that in testicular tissue of Bufo arenarum H., microsomal 3βHSD/I has more affinity for dehydroepiandrosterone (DHEA) than for pregnenolone (K_m=0.17±0.03 and 1.02 μM, respectively). The Hill coefficient for the conversion of DHEA and pregnenolone were 1.04 and 1.01, respectively. The inclusion of DHEA in the kinetic analysis of pregnenolone conversion affected V_max while K_m was not modified, suggesting a non-competitive inhibition of the conversion of pregnenolone. K_i was calculated from replot of Dixon's slope for each substrate concentration. K_i from the intercept and the slope of this replot were similar (0.276±0.01 and 0.263±0.02 μM) and higher than the K_m for DHEA. The K_m and K_i values suggest the presence of two different binding sites. When pregnenolone was present in the assays with DHEA as substrate, no effect was observed on the V_max while K_m values slightly increased with pregnenolone concentration. Consequently, pregnenolone inhibited the transformation of DHEA in a competitive fashion. These studies suggest that, in this species, the microsomal biosyntheses of androgens and progesterone are catalysed by different active sites.     

Enzymic properties of β-mannanase from Polyporus versicolor

Substrate specificities and the kinetic parameters, K_m and V_max, of the four multiple enzyme forms of extracellular β-mannanase activity purified from Polyporus versicolor were determined. Although K_m values were significantly greater than those encountered in other β-mannanase systems V_max values were equivalent or much greater, rendering the physiological efficiencies of the β-mannanase comparable to those of other β-mannanases. All enzymes preferred glucomannan as substrate, were highly refractory at low concentrations to n-octylglucopyranoside, sodium deoxylcholate, and sodium dodecylsulfate, and were largely insensitive to methanol, ethanol, acetonitrile, and dimethylsulfoxide.     

Tight Coupling between Glucose and Mitochondrial Metabolism in Clonal ��-Cells Is Required for Robust Insulin Secretion

The biochemical mechanisms underlying glucose-stimulated insulin secretion from pancreatic β-cells are not completely understood. To identify metabolic disturbances in β-cells that impair glucose-stimulated insulin secretion, we compared two INS-1-derived clonal β-cell lines, which are glucose-responsive (832/13 cells) or glucose-unresponsive (832/2 cells). To this end, we analyzed a number of parameters in glycolytic and mitochondrial metabolism, including mRNA expression of genes involved in cellular energy metabolism. We found that despite a marked impairment of glucose-stimulated insulin secretion, 832/2 cells exhibited a higher rate of glycolysis. Still, no glucose-induced increases in respiratory rate, ATP production, or respiratory chain complex I, III, and IV activities were seen in the 832/2 cells. Instead, 832/2 cells, which expressed lactate dehydrogenase A, released lactate regardless of ambient glucose concentrations. In contrast, the glucose-responsive 832/13 line lacked lactate dehydrogenase and did not produce lactate. Accordingly, in 832/2 cells mRNA expression of genes for glycolytic enzymes were up-regulated, whereas mitochondria-related genes were down-regulated. This could account for a Warburg-like effect in the 832/2 cell clone, lacking in 832/13 cells as well as primary β-cells. In human islets, mRNA expression of genes such as lactate dehydrogenase A and hexokinase I correlated positively with HbA_1c levels, reflecting perturbed long term glucose homeostasis, whereas that of Slc2a2 (glucose transporter 2) correlated negatively with HbA_1c and thus better metabolic control. We conclude that tight metabolic regulation enhancing mitochondrial metabolism and restricting glycolysis in 832/13 cells is required for clonal β-cells to secrete insulin robustly in response to glucose. Moreover, a similar expression pattern of genes controlling glycolytic and mitochondrial metabolism in clonal β-cells and human islets was observed, suggesting that a similar prioritization of mitochondrial metabolism is required in healthy human β-cells. The 832 β-cell lines may be helpful tools to resolve metabolic perturbations occurring in Type 2 diabetes.     

Expression of the glucose transporter isoform GLUT 4 is insufficient to confer insulin-regulatable hexose uptake to cultured muscle cells.

Glucose transporter isoform expression was studied in the skeletal muscle-like cell line, C2C12. Northern and Western blot analysis showed that the insulin-responsive muscle/fat glucose transporter isoform, GLUT 4, was expressed in these cells at very low levels, whereas the erythrocyte isoform, GLUT 1, was expressed at readily detectable levels. Insulin did not stimulate glucose transport in this cultured muscle cell line. The C2C12 cells were then transfected separately with either GLUT 1 or GLUT 4, and stable cell lines expressing high levels of mRNA and protein were isolated. GLUT 1-transfected cells exhibited a 3-fold increase in the amount of the GLUT 1 transporter protein which was accompanied by a 2- to 3-fold increase in the glucose uptake rate. However, despite at least a 10-fold increase in GLUT 4 mRNA and protein detected after GLUT 4 cDNA transfection, the glucose uptake of these cells was unchanged and remained insulin-insensitive. By laser confocal immunofluorescence imaging, it was established that the transfected GLUT 4 protein was localized almost entirely in cytoplasmic compartments. In contrast, the GLUT 1 isoform was detected both at the plasma membrane as well as in intracellular compartments. These results suggest that acute insulin stimulation of glucose transport is not solely dependent on the presence of the insulin receptor and the GLUT 4 protein, and that the presence of some additional protein(s) must be required.     

A kinetic study of almond-β-glucosidase catalysed synthesis of hexyl-glycosides in low aqueous media: Influence of glycosyl donor and water activity

A variety of alkyl and aryl glycosides were investigated as substrates for almond β-glucosidase catalysed synthesis of hexyl-β- -glycosides in low aqueous hexanol media. The rate-limiting step in the organic media was determined to be the glycosylation of the enzyme. The kinetic constants V_max, K_m (glycosyl donor) and V_max/K_m were all influenced by the water activity and they all increased in value with increasing water activity. The increase in V_max/K_m was mainly determined by the increase in V_max and a plot of log(V_max/K_m) versus water activity resulted in a straight line with similar slopes for all glycosides but with different absolute values and thus the most reactive substrate p-nitrophenyl glucoside was the best one in the entire water activity range studied (0.53–0.96). The preference for the two competing acceptors, hexanol and water, was not affected by the aglycon part of the glucoside. Surprisingly, the ratio between trans glycosylation and hydrolysis increased with increasing water activity. A decrease in water activity caused an increase in equilibrium yield of hexyl glycoside, as expected, but was not beneficial for the kinetically controlled yield.     

Xenobiotic acyl-CoA formation: evidence of kinetically distinct hepatic microsomal long-chain fatty acid and nafenopin-CoA ligases

Multiplicity of hepatic microsomal coenzyme A ligases catalyzing acyl-CoA thioester formation is an important factor for consideration in relation to the metabolism of xenobiotic carboxylic acids. In this study the kinetic characteristics of rat hepatic microsomal nafenopin-CoA ligase were studied and compared with those of long-chain fatty acid (palmitoyl) CoA ligase. The high affinity component of palmitoyl-CoA formation was inhibited by nafenopin (K_i 53 μM) and ciprofibrate (K_i 1000 μM). Analagous to palmitoyl-CoA, nafenopin-CoA formation was catalyzed by an apparent high affinity low capacity isoform (K_m 6 ± 2.5 μM, (V_max 0.33 ± 0.12 nmol/mg per min) which was inhibited competitively by palmitic acid (mean K_i 1.7 μM, n = 5) and R-ibuprofen (mean K_i 10.8 μM, n = 5) whilst ciprofibrate and clofibric acid were ineffective as inhibitors. The intrinsic metabolic clearance of nafenopin to nafenopin-CoA (V_max/K_m 0.057 ± 0.011 nmol/mg/min ± M) was similar to that reported recently for the formation of ibuprofenyl-CoA by rat liver microsomes. Evidence of both a substantial difference between the K_m and K_i for nafenopin and lack of commonality with regard to xenobiotic inhibitors suggests that the high affinity microsomal nafenopin-CoA and long-chain fatty acid-CoA ligases are kinetically distinct. Thus until the current ‘long-chain like’ xenobiotic-CoA ligases are fully characterised in terms of substrate specificity, inhibitor profile, etc, it will be impossible to rationalize (and possibly predict) the metabolism and hence toxicity of xenobiotic carboxylic acids forming acyl-CoA thioester intermediates.     

Glucose-stimulated insulin secretion of insulinoma INS-1E cells is associated with elevation of both respiration and mitochondrial membrane potential

Increased ATP/ADP ratio resulting from enhanced glycolysis and oxidative phosphorylation represents a plausible mechanism controlling the glucose-stimulated insulin secretion (GSIS) in pancreatic β-cells. Although specific bioenergetics might be involved, parallel studies of cell respiration and mitochondrial membrane potential (ΔΨ_m) during GSIS are lacking. Using high resolution respirometry and parallel ΔΨ_m monitoring by two distinct fluorescence probes we have quantified bioenergetics in rat insulinoma INS-1E cells representing a suitable model to study in vitro insulin secretion. Upon glucose addition to glucose-depleted cells we demonstrated a simultaneous increase in respiration and ΔΨ_m during GSIS and showed that the endogenous state 3/state 4 respiratory ratio hyperbolically increased with glucose, approaching the maximum oxidative phosphorylation rate at maximum GSIS. Attempting to assess the basis of the “toxic” effect of fatty acids on insulin secretion, GSIS was studied after linoleic acid addition, which diminished respiration increase, ΔΨ_m jump, and magnitude of insulin release, and reduced state 3/state 4 dependencies on glucose. Its effects were due to protonophoric function, i.e. uncoupling, since without glucose, linoleic acid accelerated both state 3 and state 4 respiration by similar extent. In turn, state 3 respiration increased marginally with linoleic acid at 10–20 mM glucose. We conclude that upon glucose addition in physiological range, the INS-1E cells are able to regulate the oxidative phosphorylation rate from nearly zero to maximum and that the impairment of GSIS by linoleic acid is caused by mitochondrial uncoupling. These findings may be relevant to the pathogenesis of type 2 diabetes.     

Glucose transporter isotypes switch in T-antigen-transformed pancreatic beta cells growing in culture and in mice.

High-level expression of the low-Km glucose transporter isoform GLUT-1 is characteristic of many cultured tumor and oncogene-transformed cells. In this study, we tested whether induction of GLUT-1 occurs in tumors in vivo. Normal mouse beta islet cells express the high-Km (approximately 20 mM) glucose transporter isoform GLUT-2 but not the low-Km (1 to 3 mM) GLUT-1. In contrast, a beta cell line derived from an insulinoma arising in a transgenic mouse harboring an insulin-promoted simian virus 40 T-antigen oncogene (beta TC3) expressed very low levels of GLUT-2 but high levels of GLUT-1. GLUT-1 protein was not detectable on the plasma membrane of islets or tumors of the transgenic mice but was induced in high amounts when the tumor-derived beta TC3 cells were grown in tissue culture. GLUT-1 expression in secondary tumors formed after injection of beta TC3 cells into mice was reduced. Thus, high-level expression of GLUT-1 in these tumor cells is characteristic of culture conditions and is not induced by the oncogenic transformation; indeed, overnight culture of normal pancreatic islets causes induction of GLUT-1. We also investigated the relationship between expression of the different glucose transporter isoforms by islet and tumor cells and induction of insulin secretion by glucose. Prehyperplastic transgenic islet cells that expressed normal levels of GLUT-2 and no detectable GLUT-1 exhibited an increased sensitivity to glucose, as evidenced by maximal insulin secretion at lower glucose concentrations, compared with that exhibited by normal islets. Further, hyperplastic islets and primary and secondary tumors expressed low levels of GLUT-2 and no detectable GLUT-1 on the plasma membrane; these cells exhibited high basal insulin secretion and responded poorly to an increase in extracellular glucose. Thus, abnormal glucose-induced secretion of insulin in prehyperplastic islets in mice was independent of changes in GLUT-2 expression and did not require induction of GLUT-1 expression.     

Induction of glyoxylate cycle enzymes in rat liver upon food starvation

The key enzymes of the glyoxylate cycle, isocitrate lyase and malate synthase, have been detected in liver of foodstarved rats. Activities became measurable 3 days and peaked 5 days after the beginning of starvation. Both enzymes were found in the peroxisomal cell fraction after organelle fractionation by isopycnic centrifugation. Isocitrate lyase was purified 112-fold by ammonium sulfate precipitation, and chromotography on DEAE-cellulose and Toyopearl HW-65. The specific activity of the purified enzyme was 9.0 units per mg protein. The K_m(isocitrate) was 68 μM and the pH optimum was at pH 7.4. Malate synthase was enriched 4-fold by ammonium sulfate precipitation. The enzyme had a K_m(acetyl-CoA) of 0.2 μM, a K_m(glyoxylate) of 3 mM and a pH optimum of 7.6.     

Molecular characterization of calcitonin gene-related peptide (CGRP) in a rat medullary thyroid carcinoma cell line

The rat medullary thyroid carcinoma cell line, CA-77, is known to express the calcitonin gene and the cell line has been used for characterization of procalcitonin. The present investigations concentrate on a molecular characterization of the calcitonin gene-related peptide (CGRP) expressed by a subclone of this cell line. The investigations demonstrate that this subclone produces significantly more CGRP compared to calcitonin. Gel chromatography of cell extracts demonstrates heterogeneity for both CGRP and calcitonin, but a significant amount of immunoreactivity elutes corresponding to the elution position for synthetic CGRP and calcitonin, respectively. The gel chromatogram for CGRP demonstrates four immunoreactive peaks with K_d of 0.42, 0.53, 0.68, and 0.85. The immunoreactive peak with K_d 0.42 elutes corresponding to synthetic rat CGRP. The four immunoreactive peaks were characterized by high pressure liquid chromatography followed by sequence analysis and mass spectrometry. The immunoreactive peak with K_d 0.42 was identified as rat -CGRP as was the peak with K_d 0.53. The peak with K_d 0.68 was identified as 19–37 rat -CGRP and the peak with K_d 0.85 as 28–37 rat -CGRP. In summary, we find that the CA-77 cell line expresses large quantities of normally processed amidated -CGRP and specific fragments thereof. However, the cell line does not express detectable levels of rat β-CGRP. The findings indicate that the CA-77 cell line can be useful for studies of calcitonin/CGRP gene expression.     

Kinetic characterization of sulphur-containing excitatory amino acid uptake in primary cultures of neurons and astrocytes

The uptake of the neuroactive sulphur amino acids -cysteine sulphinate, -cysteate, -homocysteine sulphinate and -homocysteate was investigated in astrocytes cultured from the prefrontal cortex; in neurons, cultured from cerebral cortex; and, in granule cells, cultured from cerebellum. It was shown that each amino acid acted as a substrate for a plasma membrane transporter in both neurons and astrocytes. Astrocytes and neurons exhibited a high-affinity uptake for -cysteine sulphinate and -cysteate with K_m values ranging from 14–100 μM, and a low-affinity uptake for -homocysteine sulphinate and -homocysteate, with K_m values ranging from 225–1210 μM. The uptake of all transmitter candidates studied was partially sodium-dependent. This sodium-dependency was most evident at low (< 100 μM) concentrations of each substrate. The apparent uptake measured in the absence of sodium was included as a component in corrections made for non-saturable influx. With the exception of -cysteine sulphinate, uptake of each sulphur amino acid was greatest in astrocytes, with V_max values ranging between 15–32 nmol min⁻¹ mg⁻¹ cell protein. Moreover, the uptake of each sulphur amino acid in cerebellar granule cells (V_max values ranging between 10–25 nmol min⁻¹ mg⁻¹ cell protein) was consistently greater than that in cerebral cortex neurons (V_max values ranging between 1.5–6 nmol min⁻¹ mg⁻¹ cell protein).     

Properties of endogenous β-glucosidase of a Saccharomyces cerevisiae strain isolated from Sicilian musts and wines

Three hundred sixty-one yeast strains (80 of which ascribable to Saccharomyces cerevisiae) were isolated from Sicilian musts and wines with the purpose of looking for β-glucosidase (βG, EC 3.2.1.21) activity. Of these, the AL 41 strain had highest endogenous βG activity and was identified as belonging to the species S. cerevisiae by biochemical and molecular methods. This enzyme was subsequently characterized. It had optimum effect at pH 3.5–4.0, whilst optimum temperature was 20 °C, compatible with typical wine-cellar conditions; it was not inhibited by ethanol, at concentrations of 12–14%, or fructose and glucose. The βG was also characterised in terms of the kinetic parameters K_m (2.55 mM) and V_max (1.71 U mg⁻¹ of protein). Finally, it remained stable for at least 35 days in model solutions of must and wine.     

Potential activities of androgen metabolizing enzymes in human prostate

The entire androgen metabolism of the human prostate is an integral part of the DHT mediated cellular processes, which eventually give rise to the androgen responsiveness of the prostate. Therefore, the potential activities of various androgen metabolizing enzymes were studied. Moreover, the impact of aging on the androgen metabolism and the inhibition of 5-reductase by finasteride were studied. In epithelium (E) and stroma (S) of normal (NPR) and hyperplastic human prostate (BPH), for each enzyme being involved in the conversion either of testosterone via DHT, 3- and 3β-diol to the C₁₉O₃-triols or from testosterone to androstenedione and vice versa, the amount (V_max) and Michaelis constant (K_m) were determined by Lineweaver-Burk plots. Furthermore, V_max/K_m quotients were calculated, which served as an index for the potential enzyme activity. 17 enzymes showed a mean V_max/K_m ≥ 0.10. The top four were the 5-reductases in E and S of NPR and BPH. Among those, the highest activity was found in E of NPR (1.6 ± 0.2). Moreover, in E a significant age-dependent decrease of 5-reductase activity occurred, whereas in stroma rather constant activities were found over the whole age range. Similar age-dependent alterations were found for the cellular DHT levels. Finally, the finasteride inhibition of 5-reductase (IC₅₀;nM) was stronger in E (35 ± 17) than in S (126 ± 15). In conclusion, 5-reductase is: (a) the outstanding androgen metabolizing enzyme in NPR and BPH; (b) dictating the DHT enrichment in the prostate; (c) under the impact of aging; and (d) preferentially inhibited by finasteride in E.     

Biochemical and catalytic properties of two intracellular β-glucosidases from the fungus Penicillium decumbens active on flavonoid glucosides

In the presence of rutin as sole carbon source, Penicillium decumbens produces two intracellular β-glucosidases named G_I and G_II, with molecular masses of 56,000 and 460,000 Da, respectively. The two proteins have been purified to homogeneity. G_I and G_II composed of two and four equal sub-units, respectively and displayed optimal activity at pH 7.0 and temperature 65–75 °C. Both β-glucosidases were competitively inhibited by glucose and glucono-δ-lactone. G_I and G_II exhibited broad substrate specificity, since they hydrolyzed a range of (1,3)-, (1,4)- and (1,6)-β-glucosides as well as aryl β-glucosides. Determination of k_cat/K_m revealed that G_II hydrolyzed 3–8 times more efficiently the above-mentioned substrates. The ability of G_I and G_II to deglycosylate various flavonoid glycosides was also investigated. Both enzymes were active against flavonoids glycosylated at the 7 position but G_II hydrolyzed them 5 times more efficiently than G_I. Of the flavanols tested, both enzymes were incapable of hydrolyzing quercetrin and kaempferol-3-glucoside. The main difference between G_I and G_II as far as the hydrolysis of flavanols is concerned, was the ability of G_II to hydrolyze the quercetin-3-glucoside.     

Characterization of cocaine-sensitive dopamine uptake in PC12 cells

Dopamine uptake in rat pheochromocytoma (PC12) cells is a carrier-mediated process which follows Michaelis Menten kinetics. Uptake was saturable with an apparent K_m of 0.71 μM for dopamine and a V_max of 3.2 pmol/2 × 10⁵ cells/min. The rank order of potency for various amines was norepinephrine copamine > epinephrine. Uptake increased with increasing temperature and showed a sharp break in the Arrhenius plot at 27.5 C. The Q₁₀ was 1.39 above and 2.95 below 27.5 C. Cocaine inhibited uptake in a dose-dependent manner with a K₁ of 0.97 μM. The presence of cocaine lowered the apparent K_m but did not affect the V_max, indicating competitive inhibition. Tunicamycin inhibited [³H]dopamine accumulation in a dose- and time-dependent fashion suggesting the dopamine uptake site in PC12 cells is an asparagine-linked glycoprotein. Kinetic analysis showed a decrease in V_max but not in the apparent K_m after tunicamycin treatment, consistent with the notion that tunicamycin treatment results in the loss of a substantial amount of active carrier molecules.     

Evidence for modulation of cell-to-cell electrical coupling by cAMP in mouse islets of Langerhans

The effects of forskolin on electrical coupling among pancreatic β-cells were studied. Two microelectrodes were used to measure membrane potentials simultaneously in pairs of islet β-cells. Intracellular injection of a current pulse (ΔI) elicited a membrane response ΔV₁ in the injected cell and also a response ΔV₂ in a nearby β-cell confirming the existence of cell-to-cell electrical coupling among islet β-cells. In the presence of glucose (7 mM), application of forskolin evoked a transient depolarization of the membrane and electrical activity suggesting that the drug induced a partial inhibition of the β-cell membrane K⁺ conductance. Concomitant with this depolarization of the membrane there was a marked decrease in β-cell input resistance (ΔV₂/ΔI) suggesting that exposure to forskolin enhanced intercellular coupling. Direct measurements of the coupling ratio ΔV₂/ΔV₁ provided further support to the idea that forskolin enhances electrical coupling among islet cells. Indeed, application of forskolin reversibly increased the coupling ratio. These results suggest that cAMP might be involved in the modulation of electrical coupling among islet β-cells.     

Octapamine N-acetyltransferase activity from the cattle tick, Boophilus microplus

The metabolism of octopamine in the tick, Boophilus microplus, was studied by incubating synganglia, excised from adult females, with [³H]octopamine. The major metabolite co-chromatographed with N-acetyloctopamine and was predominantly found outside the nervous tissue in the surrounding saline. The N-acetyltransferase (NAT) activity was measured in enzyme preparations from adult synganglia using [³H]octopamine as the substrate and acetyl CoA as a co-factor. Under the assay conditions employed, the V_max was 7 nmol/h/mg of protein and the apparent K_m for octopamine was 4 μM. The N-acetylation of octopamine was inhibited by divalent cations (Zn²⁺ and Cu²⁺), β-carbolines, imipramine and a number of biogenic amines.

NAT activity towards octopamine was also found in enzyme preparations from larvae of B. microplus and this enzyme had similar K_m and V_max values (4 μM and 10 nmol/h/mg of protein, respectively) to the neural enzyme and was inhibited both by β-carbolines and biogenic amines. These results suggest that N-acetylation is a key reaction in the metabolism of octopamine in the nervous system of the tick and may also play an important role in the metabolism of octopamine and other biogenic amines in larval stages of this acarine.     

A substitutive substrate for measurements of beta-ketoacyl reductases in two fatty acid synthase systems

Bacterial β-ketoacyl-ACP reductase (FabG) and the β-ketoacyl reductase domain in mammalian fatty acid synthase (FAS) have the same function and both are rendered as the novel targets for drugs. Herein we developed a convenient method, using an available compound ethyl acetoacetate (EAA) as the substitutive substrate, to measure their activities by monitoring decrease of NADPH absorbance at 340 nm. In addition to the result, ethyl 3-hydroxybutyrate (EHB) was detected by HPLC analysis in the reaction system, indicating that EAA worked effectively as the substrate of FabG and FAS since its β-keto group was reduced. Then, the detailed kinetic characteristics, such as optimal ionic strength, pH value and temperature, and kinetic parameters, for FabG and FAS with this substitutive substrate were determined. The K_m and k_cat values of FabG obtained for EAA were 127 mM and 0.30 s^− 1, while those of this enzyme for NADPH were 10.0 μM and 0.59 s^− 1, respectively. The corresponding K_m and k_cat values of FAS were 126 mM and 4.63 s^− 1 for EAA; 8.7 μM and 4.09 s^− 1 for NADPH. Additionally, the inhibitory kinetics of FabG and FAS, by a known inhibitor EGCG, was also studied.