Genetic regulation of plasma and red blood cell magnesium concentrations in man. I. Univariate and bivariate path analyses.

This paper concerns an analysis of family resemblance for magnesium concentrations, based on data from nuclear families and twins. Neither red blood cell magnesium nor plasma magnesium varies with age in children (under 20 years of age). Whereas adult plasma magnesium varies linearly with age, the red cell magnesium clearly showed a nonlinear trend: quadratic for males and a fifth-degree polynomial for females. Transformed magnesium concentrations generated six correlations in nuclear families and twins for each of the two traits. Separate univariate analyses, using a simple linear model with four parameters, strongly suggested that genetic factors are primarily responsible for the observed family resemblance. Both traits were then analyzed simultaneously using a simple bivariate model. We found that one common genetic factor alone could not explain all the 24 correlations generated for the bivariate analysis. The most parsimonious model involved only three parameters: genetic heritability for red blood cell magnesium (.922 +/- .014), genetic heritability for plasma magnesium (.721 +/- .040), and the genetic correlation between the two traits (.233 +/- .040).     

Is there a genetic control in man of red blood cell magnesium levels?

Three groups of human subjects underwent successive monthly examinations to determine red blood cell magnesium levels and plasma magnesium, potassium and sodium levels. From these data, a comparison between intra- and inter individual variances showed that red blood cell magnesium had a characteristically high intra individual stability and a wide inter individual variability. This characteristic, which was much more marked than for plasma cholesterol or serum gamma globulin levels, whose high coefficient of heritability has been demonstrated elsewhere, is in good keeping with the hypothesis of genetic control of red blood cell Mg content.     

Genetic systems of red cell blood groups in goats.

Evidence is presented for six genetic systems of goat red cell blood groups. The A system presently consists of one specificity, two alleles, two phenotypes (A1 and no-A1) and appears to be homologous to the A system of sheep. The B system, like its homologue in sheep, is very complex. Fourteen of 21 specificities detected in the present study, i.e. B2, B3, B4, B5, B7, B8, B9, B10, B11, B14, B15, B16, B17 and B20, belong to the B system which involves a large number of phenogroups (31 different B phenogroups identified in 26 sires). Because of their homology with sheep C and R systems, two other genetic systems of goat blood groups are named C and R respectively. Each of the two goat systems is presently a one blood group specificity, two phenotype (C12 and no-C12; R and no-R detectable on the red cells) two allele system. Two specificities, namely E6 and E18, belong to a genetic system called E in which four phenotypes are under the control of two alleles codominant and one recessive at a single locus. The F system involves but a single pair of alleles and two phenotypes (F19 and no-F19). Because of its low frequency in the goats tested, the X13 specificity remains unassigned.     

MAPKinase and regulation of the sodium-proton exchanger in human red blood cell

The sodium-proton exchanger is activated by various agonists, including insulin, even in human red blood cell. MAPKinase, a family of ubiquitous serine/threonine kinases, plays an important role in the signal transduction pathways which lead to sodium-proton exchanger activation. The aim of our study was to establish the existence of MAPKinase in human red blood cell and to investigate the effects of its activation by insulin and okadaic acid on the sodium-proton exchanger. Immunoblot with antiMAPK antibody revealed the presence of two isoforms, p44(ERK1) and p42(ERK2). Insulin stimulated MAPKinase activity and increased the phosphorylation of MAPK tyrosine residues, with a peak time between 3 and 5 min. Okadaic acid, an inhibitor of serine/threonine phosphatases, stimulated MAPKinase activity. In the presence of PD98059, an inhibitor of MEK, the upstream activator of MAPKinase, insulin and okadaic acid failed to stimulate MAPKinase. Insulin and okadaic acid increased the activity of the sodium-proton exchanger and this effect was abolished by PD98059. In conclusion, we first describe the presence and activity of MAPKinase in human red blood cell. Furthermore, we demonstrate that in human red blood cell, insulin modulates the sodium-proton exchanger through MAPKinase activation.     

Microfluidic analysis of red blood cell deformability

A common indicator of rheological dysfunction is a measurable decrease in the deformability of red blood cells (RBCs). Decreased RBC deformability is associated with cellular stress or pathology and can impede the transit of these cells through the microvasculature, where RBCs play a central role in the oxygenation of tissues. Therefore, RBC deformability has been recognized as a sensitive biomarker for rheological disease. In the current study, we present a strategy to measure RBC cortical tension as an indicator of RBC deformability based on the critical pressure required for RBC transit through microscale funnel constrictions. By modeling RBCs as a Newtonian liquid drop, we were able to discriminate cells fixed with glutaraldehyde concentrations that vary as little as 0.001%. When RBCs were sampled from healthy donors on different days, the RBC cortical tension was found to be highly reproducible. Inter-individual variability was similarly reproducible, showing only slightly greater variability, which might reflect biological differences between normal individuals. Both the sensitivity and reproducibility of cortical tension, as an indicator of RBC deformability, make it well-suited for biological and clinical analysis of RBC microrheology.     

Genetic regulation of the expression of catalase activity in murine red blood cells

The specific activity (k′₁) and concentration of red blood cell catalase from four inbred strains of mice (BALB/c, C57BL, C57BL/6, and NBL) were measured to determine the mechanisms responsible for interstrain variations in enzyme activity. The specific activities of RBC catalase in NBL and the C57BL sublines are equal (2.5×10⁷ m ^?1 sec^?1), while that of BALB/c (4.0×10⁷ m ^?1 sec^?1) is 67% greater. The relative concentration of catalase is approximately 30% lower in NBL erythrocytes compared to the other three strains. The activity of BALB/c RBC catalase is due to a high k′₁ coupled with a high intracellular concentration; RBC catalase activity in the C57BL sublines is the result of a low k′₁ and high concentration. A low k′₁ and a low concentration are responsible for the low catalase activity levels found in NBL erythrocytes.     

Content of red blood-cell sialic acid in BW 35 blood donors. Relation to magnesium concentration and pyruvate kinase activity

Previous studies have shown that the concentration of red blood cell (RBC) magnesium is significantly lower in subjects carrying an HLA-BW 35 antigen (p less than 0.001) than in non-carriers. As this finding might be related to modifications of the RBC membrane sialoglycoconjugates, RBC sialic acid was comparatively determined in BW 35+ and BW 35- subjects. Pyruvate-kinase activity mean RBC volume, and reticulocyte count have also been determined in order to estimate whether some significant variations in the level of these age markers could be detected between the HLA BW 35+ and BW 35- subjects. A significant negative correlation between sialic acid and RBC magnesium concentrations was observed for the whole population tested (n 57, p less than 0.005), 61% of the BW 35+ and only 25% of the BW 35- individuals having sialic acid values above, and magnesium values below the overall mean (p less than 0.01). The variance of mean RBC volume was also larger for the BW 35+ group. Other determinations did not show any significant variations, suggesting that the results are not related to RBC age.     

The concentration of red blood cell UDPglucose and UDPgalactose determined by high-performance liquid chromatography.

We have developed a sensitive method that employs high-performance liquid chromatography to separate and quantitate uridine diphosphogalactose (UDPGal) and uridine diphosphoglucose (UDPGlu) in human red blood cells. The trichloracetic acid extracts of red blood cells were chromatographed using a Dionex CarboPac anion-exchange resin and a 20-40% potassium phosphate buffer, pH 4.5, in a gradient-elution program. UDPGal and UDPGlu were detected spectrophotometrically at 254 nm. Recoveries of UDPGal and UDPGlu ranged from 96 to 106%. Under these conditions, there was exceptionally good reproducibility in stored specimens, and the method was sensitive in the low picamole range. The mean values and standard deviations in adults were 2.9 +/- 0.4 and 7.8 +/- 0.8 mumol/100 g Hgb for UDPGal and UDPGlu, respectively. The values in children were 4.5 +/- 1.2 and 10.2 +/- 1.7 mumol/100 g Hgb for UDPGal and UDPGlu, respectively. Values determined by the HPLC method are in excellent agreement with those obtained by enzyme analysis.     

The human blood platelet: its derivation from the red blood cell. II. Instantaneous changes in form in the platelet and red cell. A morphologic study

The human blood platelet arises from the interior of the red cell instantaneously as blood is either damaged or disturbed. The platelet starts out as a fine granular structure that rather suddenly changes in form and function with the passage of a very small amount of time.     

Acid-base balance and plasma glutamine concentration in man

Plasma glutamine concentrations were measured in chronic metabolic acidosis and alkalosis in healthy male volunteers. Metabolic acidosis resulted in a significant drop in glutamine concentration while metabolic alkalosis significantly elevated glutamine levels. These changes in glutamine concentration correlated with both the bicarbonate and PCO2 levels. To determine whether bicarbonate or PCO2 levels influence the glutamine concentrations, respectively acidosis was induced by respiring 5% CO2. This resulted in a significant elevation in both PCO2 and glutamine while bicarbonate levels remained unchanged. The results demonstrate an effect of acid-base alterations upon plasma glutamine concentration mediated by PCO2.     

Filipin as a cholesterol probe. II. Filipin-cholesterol interaction in red blood cell membranes

Filipin, a mixture of polyene antibiotics which form complexes with cholesterol, perturbs membrane lipid organization, and causes hemolysis of erythrocytes, is increasingly used as a cytochemical probe for the distribution of cholesterol in cell membranes. We used light (phase-contrast, dark-field and fluorescence) and electron microscopical techniques (whole-mount shadowing, negative staining, and freeze-fracture) to study the interaction of filipin with unfixed and glutaraldehyde-fixed human red blood cell (RBC) membranes. Lysis time and extent depended upon the cholesterol:filipin (C:F) ratio. Lysis was prevented by osmotic protection with high MW dextran. Filipin treated cells fluoresced, but variation in fluorescence intensity among unfixed as well as among fixed cells was evident both at low and high C:F ratios. Negatively stained preparations of unfixed cells lysed on grids or in suspension revealed ring- or C-shaped filipin-induced lesions (FIL) equipped with a veil-like appendage; single FIL, and FIL fused by their veils into aggregates, were shed from membranes. FIL at the surface proper of shadowed whole-mounts and of freeze-etched preparations of prefixed cells appeared as single, dispersed or aggregated cylinders protruding to variable heights above the membrane's plane; aggregated FIL were shed from cells. The freeze-fracture appearance of FIL differed in membranes fixed before or after filipin treatment. E- and P-faces of post-fixed membranes exhibited cylindrical protrusions and depressions, respectively; in essence, the reverse was found in pre-fixed RBC. Both pre- and post-fixed membranes showed considerable variation in the number of FIL on individual cells whether incubated at high (1:1) or low (1:5) C:F ratios, or for a short (10 min) or a long (80-180 min) time. Aggregation and shedding of FIL was evident in all preparations. Thin layer chromatography of the incubation fluid after sedimentation of cells showed that membrane cholesterol was shed from incubated cells. The presented data question the feasibility of filipin as a probe for the topographical distribution of cholesterol in cell membranes.     

Network-level analysis of metabolic regulation in the human red blood cell using random sampling and singular value decomposition

Background  

Extreme pathways (ExPas) have been shown to be valuable for studying the functions and capabilities of metabolic networks through characterization of the null space of the stoichiometric matrix (S). Singular value decomposition (SVD) of the ExPa matrix P has previously been used to characterize the metabolic regulatory problem in the human red blood cell (hRBC) from a network perspective. The calculation of ExPas is NP-hard, and for genome-scale networks the computation of ExPas has proven to be infeasible. Therefore an alternative approach is needed to reveal regulatory properties of steady state solution spaces of genome-scale stoichiometric matrices.