Determination of several sugars in serum by high-performance anion-exchange chromatography with pulsed amperometric detection

In this paper, a sensitive, simple and direct method for simultaneous determination of glucose, ribose, isomaltose and maltose in serum sample by high-performance anion-exchange chromatography coupled with integrated pulsed amperometric detection was developed. The four target analytes were easily and completely separated on an anion-exchange column at a flow-rate of 0.25 mL/min by binary step gradient elution in about 16 min and the two eluents were deionized water and 500 mM sodium hydroxide, respectively. The separated four analytes were detected directly by using a gold electrode and quadruple-potential waveform integrated pulsed amperometry without derivatization. Under the optimized conditions, when the injection volume was 25 microL, the detection limits (signal-to-noise ratio equal to 3) for glucose, ribose, isomaltose and maltose were 0.92, 7.50, 12.9 and 10.3 ng/mL, respectively. The calibration graphs of peak area for the four analytes were linear over two to three orders of magnitude with correlation coefficients greater than 0.998. R.S.D. of peak areas of the four analytes for five determinations were no more than 5.6%. The analytical method had been applied to the determination of glucose, ribose, isomaltose and maltose in real serum samples and good results with low relative standard deviation not more than 5.3% were obtained. The accuracy of the proposed method was tested by recovery measurements on spiked samples and good recovery results (98.1-107.9%) were obtained.

Desensitization of platelets to iloprost. Loss of specific binding sites and heterologous desensitization of adenylate cyclase

The binding characteristics of [3H]prostacyclin and [3H]iloprost ([3H]5-[(E)-(1S,5S,6R,7R)-7-hydroxy-6-[(E)-(3S,4RS) -3-hydroxy-4-methyl-1-octen-6-inyl]-bicyclo[3.3.0]octan-3-yl idene] -pentanoic acid) and platelet adenylate cyclase activities were investigated in platelet-rich plasma preincubated with iloprost. The exposure of platelets to 0.1 microM iloprost (12 h, 20 degrees C) caused a significant loss of iloprost binding sites (P less than 0.01) without causing changes in binding affinity. This loss of specific [3H]iloprost binding was time- and dose-dependent. The reduction of iloprost receptor density was accompanied by an impaired responsiveness of platelet adenylate cyclase to iloprost, prostaglandin D2 and forskolin. In contrast, basal adenylate cyclase activity was not affected by iloprost pretreatment. The diminished response of the enzyme to GTP and NaF pointed to an involvement of the stimulatory guanyl nucleotide-binding protein (Gs) in iloprost-induced heterologous desensitization. Consequently, [32P]NAD+ and cholera toxin were used for the direct labelling of Gs. Platelet membranes desensitized to iloprost incorporated less label into the 45 kD subunit of Gs. These data suggest that the site of action of iloprost for heterologous desensitization of human platelet adenylate cyclase is located on Gs.

d-Ribose as a Contributor to Glycated Haemoglobin

Glycated haemoglobin (HbA1c) is the most important marker of hyperglycaemia in diabetes mellitus. We show that d-ribose reacts with haemoglobin, thus yielding HbA1c. Using mass spectrometry, we detected glycation of haemoglobin with d-ribose produces 10 carboxylmethyllysines (CMLs). The first-order rate constant of fructosamine formation for d-ribose was approximately 60 times higher than that for d-glucose at the initial stage. Zucker Diabetic Fatty (ZDF) rat, a common model for type 2 diabetes mellitus (T2DM), had high levels of d-ribose and HbA1c, accompanied by a decrease of transketolase (TK) in the liver. The administration of benfotiamine, an activator of TK, significantly decreased d-ribose followed by a decline in HbA1c. In clinical investigation, T2DM patients with high HbA1c had a high level of urine d-ribose, though the level of their urine d-glucose was low. That is, d-ribose contributes to HbA1c, which prompts future studies to further explore whether d-ribose plays a role in the pathophysiological mechanism of T2DM.

Nucleosides and glutamine are primary energy substrates for embryonic and adult chicken red cells

It has been assumed that glucose is a major energy yielding substrate for chicken red blood cells. In this report we show that glucose fails to maintain cellular ATP levels in embryonic and mature chicken erythrocytes during overnight incubation. Of over a dozen metabolites tested, inosine, guanosine, and glutamine were the most efficacious ATP-sustaining substrates. Of seven potential citric acid cycle substrates, only glutamine significantly sustained ATP levels. Incubation with inosine plus glutamine sustained the ATP level at over 70% of the initial value found in embryonic chicken red cells. Uridine, cytidine, xanthosine, glutamate, and pyruvate were ineffective substrates. Similar results were obtained with adult erythrocytes, except that glutamine plus inosine fully sustained ATP levels during long-term incubation. Adenosine did not sustain ATP levels. Below 1 mM, the adenosine level was rapidly exhausted and above 1 mM its presence led to cell lysis. The ability of some nucleosides to maintain ATP levels is consistent with the high numbers of nitrobenzylthioinosine binding sites (nucleoside transporter sites) both in mature chicken red cells (approximately 10,000 sites/cell) and in embryonic red cells (approximately 30,000 sites/cell). Unlike pig red cells which switch from glucose to nucleosides at the erythrocyte stage, chicken cells show primary dependence on nucleoside metabolism at the embryonic stage.

Studies on the energy metabolism of opossum (Didelphis Virginiana) erythrocytes. I. Utilization of carbohydrates and purine nucleosides

Opossum erythrocytes filtered through cellulose columns were used to estimate their permeability to D-glucose and optimum inorganic phosphate requirement for D-glucose utilization at pH 7.4 and 8.1. D-Glucose readily penetrated opossum red cells; there was no measurable difference whether plasma or electrolyte solution served as the suspending medium. Optimum extracellular inorganic phosphate concentration for glucose utilization as indicated by red cell lactate production was pH-dependent, with a sharp optimum of 30 mmol/liter at pH 8.1. Whereas glucose, fructose, mannose, dihydroxyacetone, adenosine, and inosine were readily utilized at pH 7.4 and Pi 30 mmol/liter as shown by net lactate and ATP production by the red cells, galactose and ribose as substrates were not metabolized. In electrolyte, Pi 30 mmol/liter, and pH 7.4 glucose utilization by opossum red cells averaged 3.5 mumol, at pH 8.1, 9.5 mumol/ml cells/hr were utilized. Red cells suspended in leukocyte-free plasma utilized D-glucose at a rate of 3.0 mumol/ml/hr at pH 7.5. Seven percent of D-glucose flowed through the pentose phosphate pathway; this rate increased 11-fold by methylene blue stimulation. The amount of D-glucose recycled through the pentose phosphate pathway increased 300-fold in the presence of the redox dye.

Proliferation of peripheral blood mononuclear cells increases riboflavin influx

Previously we demonstrated that proliferation of peripheral blood mononuclear cells (PBMC) causes a five-fold increase in cellular uptake of biotin; this increase is mediated by an increased number of biotin transporters on the PBMC surface. In the present study, we investigated the specificity of this phenomenon by determining whether the cellular uptake of riboflavin also increases in proliferating PBMC and whether the increase is also mediated by an increased number of transporters per cell. We characterized [3H]riboflavin uptake in both quiescent and proliferating PBMC. In quiescent PBMC, [3H]riboflavin uptake exhibited saturation kinetics and was reduced by addition of unlabeled riboflavin (P < 0.05) or lumichrome (P < 0.01). These observations are consistent with transporter-mediated uptake. [3H]Riboflavin uptake was reduced at 4 degrees C compared with 37 degrees C (P < 0.01) and by 2, 4-dinitrophenol (P < 0.05) but not by ouabain or incubation in sodium-free medium. These data provide evidence for an energy-dependent but sodium-independent transporter. Proliferating PBMC accumulated approximately four times more [3H]riboflavin than quiescent PBMC (P < 0.05). Because both transporter affinity and transporter number per cell (as judged by maximal transport rate) were similar in quiescent and proliferating PBMC, we hypothesize that the increased riboflavin uptake by proliferating PBMC reflects only increased cellular volume. To test this hypothesis, PBMC volume was reduced using hyperosmolar medium; [3H]riboflavin uptake decreased to about 50% of isotonic controls (P < 0.01). Thus we conclude that proliferating PBMC increase cellular content of riboflavin and biotin by two different mechanisms.

Cow red blood cells. III. Postnatal adaptation of energy metabolism in the calf red blood cells

1. The change in energy metabolism of red blood cells from the newborn calf to adult cow was examined utilizing a number of metabolic substrates including glyceraldehyde, dihydroxyacetone, ribose, glucose, adenosine and inosine. 2. All of these substrates are utilizes by the newborn calf cells to a varying degree. With glyceraldehyde, dihydroxyacetone or glucose as a substrate, lactate is formed at a rate of 2-3 mumol/ml cells per h. As in other species, ribose utilization depends on substrate concentration, with an optimum of 3 mM ribose yielding lactate 1-1.5 mumol/ml cells per h in the calf cells. 3. In sharp contrast, adult cow red blood cells lost the bulk of the postnatal metabolic substrate affinities except for glyceraldehyde and glucose which are consumed at less than half of the rate at birth. 4. While the transition of the metabolic properties from the newborn to the adult state takes place within 2 to 3 months after birth, the red blood cells produced shortly after birth have already assumed the metabolic machinery characteristic to the adult cells. 5. Even though adenosine in itself is a poor substrate in producing lactate, a net synthesis of ATP from adenosine can take place in both calf and cow cells provided that an alternate carbon source such as glyceraldehyde, dihydroxyacetone or glucose is given. 6. Of the test substrates, glucose is the only substrate for the adult cow cells exhibiting a greater than 50% increase in utilization by exogenously added adenine. By contrast, the calf cell is affected to a much lesser extent. The possible in vivo regulatory metabolic role of certain purine and pyrimidine compounds unique to the adult stage of this species is discussed.

Effects of therapeutic ribose levels on human lymphocyte proliferation in vitro

Ribose has been used successfully in the treatment of ischemic heart disease and muscular enzyme deficiencies, and its administration also facilitates the diagnosis of coronary artery disease by influencing thallium-201 scintigraphy. Concerns about the safety of ribose therapy have been triggered by reports about inhibitory effects of ribose on cell proliferation in vitro. This study examines possible side effects of ribose on human lymphocytes. Unstimulated and mitogen-stimulated human lymphocytes were incubated with ribose concentrations associated with high-dose oral administration, i.e., 3.5 mM, and with two- (7 mM) and tenfold (35 mM) higher concentrations. Cell cultures with matching glucose concentrations served as controls. Incorporation of [3H]thymidine into cells was used to measure cell proliferation. No significant inhibition of human lymphocyte proliferation in vitro was observed in mitogen-stimulated cells. Unstimulated cultures showed significant inhibition only at 35 mM ribose. It is concluded that ribose plasma levels associated with high-dose oral administration do not inhibit human lymphocyte proliferation in vitro. No evidence was found that short-term ribose therapy is harmful to human lymphocytes.