Influence of the Ionic Composition of Fluid Medium on Red Cell Aggregation

The effects of ionic strength and cationic valency of the fluid medium on the surface potential and dextran-induced aggregation of red blood cells (RBC's) were investigated. The zeta potential was calculated from cell mobility in a microelectrophoresis apparatus; the degree of aggregation of normal and neuraminidase-treated RBC's in dextrans (Dx 40 and Dx 80) was quantified by microscopic observation, measurement of erythrocyte sedimentation rate, and determination of low-shear viscosity. A decrease in ionic strength caused a reduction in aggregation of normal RBC's in dextrans, but had no effect on the aggregation of neuraminidase-treated RBC's. These findings reflect an increase in electrostatic repulsive force between normal RBC's by the reduction in ionic strength due to (a) a decrease in the screening of surface charge by counter-ions and (b) an increase in the thickness of the electric double layer. Divalent cations (Ca⁺⁺, Mg⁺⁺, and Ba⁺⁺) increased aggregation of normal RBC's in dextrans, but had no effect on the aggregation of neuraminidase-treated RBC's. These effects of the divalent cations are attributable to a decrease in surface potential of normal RBC's and a shrinkage of the electric double layer. It is concluded that the surface charge of RBC's plays a significant role in cell-to-cell interactions.     

Dextran protection of erythrocytes from low-pH-induced hemolysis

Low-pH-induced hemolysis of erythrocytes is inhibited by dextrans. The protective effect was observed with dextrans larger than 40 kDa. Electron microscopy showed dextrans of 150 kDa in a tight association with the erythrocyte membrane. These results indicate that dextrans stop the low-pH-induced hemolysis by interacting with the acid-induced defects in the erythrocyte membrane [(1989) Biochim. Biophys. Acta, in press.     

Role of Surface Electric Charge in Red Blood Cell Interactions

The role of the surface charge of human red blood cells (RBC's) in affecting RBC aggregation by macromolecules was studied by comparing the behavior of normal RBC's with that of RBC's treated with neuraminidase, which removes the sialic acids from the cell membrane and reduces the zeta potential. RBC aggregation in dextrans with different molecular weights (Dx 20, Dx 40, and Dx 80) was quantified by microscopic observation, measurement of erythrocyte sedimentation rate, and determination of low-shear viscosity. Dx 20 did not cause aggregation of normal RBC's, but caused considerable aggregation of neuraminidase-treated RBC's. Neuraminidase-treated RBC's also showed stronger aggregation than normal RBC's in Dx 40 and 80. Together with the electron microscopic findings that the intercellular distance in the RBC rouleaux varies with the molecular size of dextrans used, the present study indicates that the surface charge of RBC's inhibits their aggregation by dextrans and that the electrostatic repulsive force between cell surfaces may operate over a distance of 20 nm.     

The α-d-glucopyranosidic linkages of dextrans: comparison of percentages from structural analysis by periodate oxidation and by methylation

The analyses of 25 dextrans by g.l.c.-m.s., methylation-fragmentation, and periodate-oxidation techniques have been compared. Although in general agreement for slightly branched dextrans, the two techniques yield divergent analyses for highly branched dextrans. Employing the methylation-fragmentation data as the standard, the periodate-oxidation data were examined to establish the extent of deviation for the types of α-d-glucopyranosidic linkages that occur in dextrans, that is, the (1→6)-like, the (1→4)-like, and the (1→3)-like. The unexpected behavior of the dextrans was correlated with whether branching occurs through either C-2 or C-4, or C-3 or both of these types. Possible causes for the effects observed are discussed.     

In vitro fermentation of linear and alpha-1,2-branched dextrans by the human fecal microbiota

The role of structure and molecular weight in fermentation selectivity in linear α-1,6 dextrans and dextrans with α-1,2 branching was investigated. Fermentation by gut bacteria was determined in anaerobic, pH-controlled fecal batch cultures after 36 h. Inulin (1%, wt/vol), which is a known prebiotic, was used as a control. Samples were obtained at 0, 10, 24, and 36 h of fermentation for bacterial enumeration by fluorescent in situ hybridization and short-chain fatty acid analyses. The gas production of the substrate fermentation was investigated in non-pH-controlled, fecal batch culture tubes after 36 h. Linear and branched 1-kDa dextrans produced significant increases in Bifidobacterium populations. The degree of α-1,2 branching did not influence the Bifidobacterium populations; however, α-1,2 branching increased the dietary fiber content, implying a decrease in digestibility. Other measured bacteria were unaffected by the test substrates except for the Bacteroides-Prevotella group, the growth levels of which were increased on inulin and 6- and 70-kDa dextrans, and the Faecalibacterium prausnitzii group, the growth levels of which were decreased on inulin and 1-kDa dextrans. A considerable increase in short-chain fatty acid concentration was measured following the fermentation of all dextrans and inulin. Gas production rates were similar among all dextrans tested but were significantly slower than that for inulin. The linear 1-kDa dextran produced lower total gas and shorter time to attain maximal gas production compared to those of the 70-kDa dextran (branched) and inulin. These findings indicate that dextrans induce a selective effect on the gut flora, short-chain fatty acids, and gas production depending on their length.     

The macromolecular environment and the electrophoretic mobility of microorganisms: example of Leuconostoc mesenteroïdes - Dextran concentration and molecular weight increase the electrophoretic mobility

The electrophoretic mobility of Leuconostoc mesenteroides is twice higher in the presence of 10g dextrans/1 than without dextrans. The electrophoretic mobilities are slightly higher during the early stationary phase than during the exponential phase. The osmotic force and the degree of space-occupancy are able to explain the evolution of electrophoretic mobilities in the presence of dextrans.     

Neutral and DEAE dextrans as tracers for assessing lung microvascular barrier permeability and integrity.

Steady-state lymph-to-plasma concentration ratios (L/Ps) of neutral dextrans, cationic DEAE dextrans, and endogenous proteins were determined under normal and increased permeability conditions in six unanesthetized yearling sheep prepared with chronic lung lymph fistulas. Fluorescent dextrans with radii ranging from 1 to 30 nm were intravenously infused, and after 24 h, perilla ketone (PK) was given to alter permeability while the dextran infusion was maintained. Plasma and lymph samples were collected before and after PK administration and analyzed for dextran and protein concentrations after high-performance liquid chromatography size separation. Under both baseline and increased permeability conditions, DEAE dextrans had higher L/Ps than neutral dextrans of similar size but lower L/Ps than proteins of similar size. Comparison of L/Ps before and after PK revealed that the percentage change in permeability for neutral and DEAE dextrans was significantly larger than that for proteins. These results suggest that 1) the pulmonary microvascular barrier behaves as a net negative barrier, 2) some transport mechanisms for proteins and dextrans are different, and 3) neutral and cationic dextrans are more sensitive markers than proteins of the same size for assessing changes in pulmonary capillary permeability.     

Effect of crowding by dextrans and Ficolls on the rate of alkaline phosphatase-catalyzed hydrolysis: a size-dependent investigation

The cell cytosol is crowded with macromolecules such as proteins, nucleic acids, and membranes. The consequences of such crowding remain unclear. How is the rate of a typical enzymatic reaction, involving a freely diffusing enzyme and substrate, affected by the presence of macromolecules of different sizes, shapes, and concentrations? Here, we mimic the cytosolic crowding in vitro, using dextrans and Ficolls, for the first time in a variety of sizes ranging from 15 to 500 kDa, in a concentration range 0–30% w/w. Alkaline phosphatase–catalyzed hydrolysis of p‐nitrophenyl phosphate (PNPP) was chosen as the model reaction. A pronounced decrease in the rate with increase in fractional volume occupancy of dextran is observed for larger dextrans (200 and 500 kDa) in contrast to smaller dextrans (15–70 kDa). Our results indicate that, at 20% w/w, smaller dextrans (15–70 kDa) reduce the initial rate moderately (1.4‐ to 2.4‐fold slowing), while larger dextrans (>200 kDa) slow the reaction considerably (>5‐fold). Ficolls (70 and 400 kDa) slow the reaction moderately (1.3‐ to 2.3‐fold). The influence of smaller dextrans was accounted by a combination of increase in viscosity as sensed by PNPP and a minor offsetting increase in enzyme activity due to crowding. Larger dextrans apparently reduce the frequency of enzyme substrate encounter. The reduced influence of Ficolls is attributed to their compact and quasispherical shape, much unlike the dextrans. © 2006 Wiley Periodicals, Inc. Biopolymers 83: 477–486, 2006 This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Search for a dextransucrase minimal motif involved in dextran binding

Fourteen truncated forms of Leuconostoc mesenteroides NRRL B512-F dextransucrase, involving N-, C- or N- plus C-terminal domain truncations were tested for their ability to bind dextrans. The shortest fragment (14kDa molecular weight) that still exhibited a strong interaction with dextran was localized between amino acids N1397 and A1527 of the C-terminal domain (GBD-7) and consists of six YG repeats. With a dissociation constant K(d) of 2.8x10(-9)M, this motif shows a very high affinity for isomaltohexaose and longer dextrans, supporting the proposed role of GBD in polymer formation. The potential application of GBD-7 as an affinity tag onto cheap resins like Sephacryl S300HR for rapid purification was evaluated and is discussed.     

Methylation structural analysis of unusual dextrans by combined gas-liquid chromatography-mass spectrometry

Eight bacterial dextrans from NRRL strainsLeuconostoc mesenteroides B-742, B-1299, B-1355, B-1399, and B-1402, and from Streptobacterium dextranicum B-1254 were examined by methylation structural analysis. Methyl ethers of d-glucose that were present in hydrolyzates of permethylated dextrans were analyzed by combined g.l.c.?m.s. as the peracetylated aldononitriles. The various dextrans differed significantly in frequency and type of chain branching.     

Rheology of native dextrans in relation to their primary structure

High molecular weight dextrans were synthesized at five temperatures (3, 10, 20, 25 and 30°C) using an in-vitro enzymatic method. The rheological properties of these dextrans in aqueous solution were assessed through their flow behaviour and their viscoelastic characteristics. The results were interpreted in relation to their primary structure and particularly to their branching.

It was shown that the relatively expanded conformation of the dextrans synthesized at 3, 10 and 20°C gives to these dextrans comparable properties which are not too different from those described in literature for random-coil linear polysaccharides. Dextran synthesized at 30°C exhibited flow properties which are typical of particle suspensions in dilute and semi-dilute solution. In the concentrated domain, this dextran yielded structured systems with properties typical of weak gels. This unexpected behaviour could be related to the highly-ramified structure of this dextran in comparison with the dextrans synthesized between 3 and 20°C. On the other hand, the dextran synthesized at 25°C displayed rheological behaviour which could also be related to an intermediate primary structure between those of dextran synthesized at 20°C and dextran synthesized at 30°C.     

Quantitative intravital microscopy using a Generalized Polarity concept for kidney studies

In this article, we describe a ratiometric intravital two-photon microscopy technique for studying glomerular permeability and differences in proximal tubule cell reabsorption. This quantitative approach is based on the Generalized Polarity (GP) concept, in which the intensity difference between two fluorescent molecules is normalized to the total intensity produced by the two dyes. After an initial intravenous injection of a mixture of 3-, 40-, and 70-kDa fluorescently labeled dextrans into live Munich-Wistar-Frömter (MWF) rats, we were able to monitor changes in the GP values between any two dyes within local regions of the kidney, including the glomerulus, Bowman's capsule, proximal tubule lumens and proximal tubule cells, and individual capillary vessels. We were able to quantify accumulations of different dextrans in the Bowman's space and in tubular lumens as well as reabsorption by proximal tubular cells at different time points in the same rat. We found that for 6- to 8-wk-old MWF rats that developed spontaneous albuminuria, the 40- and 70-kDa dextrans, with hydrodynamic radii larger than albumin, were differentially filtered, but both were able to pass the glomerular filtration barrier and enter into the urinary space of the Bowman's capsule within a few seconds after intravenous infusion. Using GP image analysis, we found that negatively charged dextrans of both 40 and 70 kDa were better reabsorbed by the proximal tubule cells than the neutrally charged 40-kDa dextran. These results demonstrate the potential power of the GP imaging technique for quantitative studies of glomerular filtration and tubular reabsorption. glomerular permeability; tubular reabsorption; charge selectivity; two-photon excitation; multiphoton     

Hydrolysis of fourteen native dextrans by arthrobacter isomaltodextranase and correlation with dextran structure

The isomaltodextranase (EC 3.2.1.94) from Arthrobacter globiformis T6 hydrolysed thirteen dextrans to various extents (11?64% after 13 days) at initially large but gradually decreasing rates. Dextran B-1355 fraction S was, unlike the other dextrans, hydrolysed by the dextranase initially at the lowest rate among the dextrans used, but the rate was maintained for a long period with little decrease, so that the hydrolysis reached as high as 85% after 13 days. Paper chromatography of these dextran digests revealed that this dextranase produces in addition to isomaltose, one or two trisaccharides [isomaltose residues substituted by (1 →2)-, (1→3)-, or (1→4)-α-D-glucopyranosyl groups at the non-reducing D-glucopyranosyl residues] from every dextran used. It is evident that the non-(1→6)-linkages of these trisaccharide products constitute the “anomalous” linkages of the corresponding dextrans. The relative amounts of these trisaccharide products appear to indicate the approxima te relative amounts of a particular linkage among the dextrans, or the relative amounts of two kinds of linkages of each dextran. The kinds and the relative amounts of “anomalous” linkages of some dextrans were established on the basis of the trisaccharides produced by isomaltodextranase.     

Assessment of red blood cell aggregation with dextran by ultrasonic interferometry.

Aggregation of human red blood cells (RBCs) induced by dextrans of various molecular weight has been studied by using a new ultrasonic interferometry method. This method, based on A-mode echography, allowed for the measurement of the accumulation rate of particles on a solid plate which is related to their sedimentation rate (i.e., to their mean size). The initial aggregation process, the mean and the maximum sedimentation rate of aggregates and the packing of the sedimented RBCs have been investigated. Effects of hematocrit, molecular weight of dextrans and inhibition by dextran 40 on the RBC aggregation induced by dextran of higher molecular weight have been determined by analysing variations of the aggregate size. Results obtained confirm the aggregation effect of dextrans of molecular weights equal or higher than 70,000 dalton and disaggregation effect of dextran 40,000 dalton on aggregation by dextrans of higher molecular weight.     

Synthesis of ultrasmall superparamagnetic iron oxides using reduced polysaccharides

Investigation into the effect of the reducing sugar of dextran on formation and stability of dextran-coated ultrasmall superparamagnetic iron oxides (USPIO) has demonstrated that reduction of the terminal reducing sugar can have a significant effect on particle size, coating stability, and magnetic properties. Four aspects of polysaccharide-coated USPIO particle synthesis were investigated: (i) the effect reduction of the terminal polysaccharide sugar has upon polysaccharide usage, particle size, stability, and magnetic susceptibility; (ii) the effect an exogenous reducing sugar can have upon particle synthesis; (iii) the effect the molecular weight of the reduced polysaccharide has on particle synthesis; and (iv) the effectiveness of reduced and native dextrans in stabilizing a preformed magnetic sol. For low molecular weight dextrans (MW 20,000 x 10(-6) cgs). Similar results were obtained with a 12 kDa pullulan. The effect of polysaccharide molecular weight on particle size was studied, wherein higher molecular weight reduced dextrans produced larger particles. The effectiveness of the reduced and native dextrans in stabilizing a preformed magnetic sol was compared. Reduced dextrans were found to be superior for stabilizing the magnetic sol. The observed effects of reduction of the terminal sugar in dextran compared with the native dextran were modeled using the Langmuir adsorption isotherm. A good fit of experimental data with this model was found.     

Viscosity dependence of O2 escape from respiratory proteins as a function of cosolvent molecular weight.

Laser photodissociation of respiratory proteins is followed by fast geminate recombination competing with escape of the oxygen molecule into the solvent. The escape rate from myoglobin or hemerythrin has been shown previously to exhibit a reciprocal power-law dependence on viscosity. We have reinvestigated oxygen escape from hemerythrin using a number of viscous cosolvents of varying molecular weight, from glycerol to dextrans up to 500 kDa. In isoviscous solutions, the strong viscosity dependence observed with small cosolvents is progressively reduced upon increasing the cosolvent's molecular weight and disappears at molecular weights greater than about 100 kDa. Thus, viscosity is not a suitable independent parameter to describe the data. The power of the viscosity dependence of the rate coefficient is shown here to be a function of the cosolvent's molecular weight, suggesting that local protein-solvent interactions rather than bulky viscosity are affecting protein dynamics.     

Dextran and 5-aminosalicylic acid (5-ASA) conjugates: synthesis, characterisation and enzymic hydrolysis

Mesalamine (5-aminosalicylic acid) is the drug of choice for the treatment of Crohn's disease. A scheme for the synthesis of 5-aminosalicylic acid (5-ASA) conjugates of dextrans was developed with a focus on Crohn's disease applications. Dextrans were oxidised using sodium periodate (NaIO(4)), where the aldehyde groups formed were coupled with the alpha-amino (-NH(2)) group of 5-ASA. The resulting imine bonds were unstable in water and were consequently reduced to secondary amine groups. The effects of different aspects of the conjugation reaction were studied. These included the following: the molecular weight of the dextrans, the molar proportion of NaIO(4) to the dextrans (for periodate oxidation), the pH of the conjugation solutions, the ratio 5-ASA to oxidised polysaccharide and the relationship between the degree of conjugation and the amount of enzyme hydrolysis. Conjugates incubated in HCl were stable in 0.5 and 1.0M HCl, but they underwent degradation in 2.0 and 4.0M HCl. Dextrans (MW 20,000) with various degrees of oxidation (12%, 26%, 46%, 65%, 90% and 93%) were also prepared. Each oxidised dextran sample was conjugated with 5-ASA, and the product was quantified by high-performance liquid chromatography (HPLC). Dextrans with a maximum degree of oxidation (93%) unsurprisingly gave maximum conjugation of 5-ASA (49.1mg per 100mg of product) but were resistant to dextranase hydrolysis. Less oxidised dextrans (12%) conjugated proportionally less 5-ASA (15.1mg per 100mg of product) but were successfully hydrolysed by dextranase, suggesting their potential applications for the treatment of Crohn's disease in the distal ileum and proximal colon.     

The solubility of fibrinogen in solutions containing dextrans of various molecular weights (Short Communication)

The effect of dextrans of various molecular weights on the solubility of fibrinogen was investigated. The results indicate that the prime effect responsible for the observed changes of solubility was steric exclusion. This applies over the whole molecular-weight range of dextrans used, i.e. from 5700 to 76000.     

Effect of 100% O2 on passage of uncharged dextrans from blood to lung lymph

Since charge as well as size may influence the passage of plasma proteins from blood to lung lymph, we used uncharged dextrans as tracers to study the effects of hyperoxic lung injury on the molecular sieving properties of the pulmonary microcirculation in unanesthetized sheep. Polydisperse [3H]dextran was infused intravenously into five sheep before and after the animals breathed 100% O2 until lymph flow increased threefold (66-84 h). Lymph-to-plasma concentration ratios (L/P) were determined for [3H]dextran fractions of graded molecular sizes (1.6-8.4 nm effective radius) from samples obtained during the infusions. Before hyperoxia the blood-lymph barrier was highly restrictive to transport of [3H]dextrans above 5.0 nm in radius; steady-state L/P for these molecules averaged 0.03 or less. After the sheep breathed 100% O2, [3H]dextrans as large as 8.4 nm radius appeared in the lymph. Posthyperoxia, the L/P were significantly increased relative to prehyperoxia base-line values for every [3H]dextran fraction larger than 2.0 nm radius (P less than 0.05). In contrast, neither the L/P for albumin or total protein changed significantly. At autopsy, electron microscopy showed widespread damage to the endothelium of the alveolar capillaries with infrequent gaps between endothelial cells. In two control sheep, inhalation of compressed air for 96 h had no effect on lymph flow or L/P for the [3H]dextrans. We conclude that O2 poisoning reduced the selective sieving of uncharged dextrans across the blood-lymph barrier of the lungs and allowed larger dextrans to enter the lymph. These larger molecules may have leaked from the pulmonary microcirculation via disruptions in the continuity of the endothelial lining.     

The mechanism of dextransucrase action: Activation of dextransucrase from Streptococcus mutans OMZ 176 by dextran and modified dextran and the nonexistence of the primer requirement for the synthesis of dextran

Streptococcus mutans OMZ 176 was grown in a sucrose-free medium containing fructose as a carbohydrate source. Dextransucrase was precipitated from the culture supernatant with 40% saturated ammonium sulfate. The activity of dextransucrase was shown to be stimulated by exogenous dextran. Maximum activity was reached when the concentration of exogenous dextran was 2 mg/ml. Dextrans modified at the nonreducing ends by reaction with tripsyl chloride and/or by hydrolysis with an exodextranase also activated dextransucrase four to six times over that of a control. The exodextranasemodified dextrans have nonreducing chains that are very short in comparison with unmodified dextran and the tripsyl-modified dextrans have chains that are blocked at the nonreducing ends with a triisopropylbenzenesulfonyl group on the C₆ hydroxyl group. Because the nonreducing ends of the modified dextrans are not available for reaction, the activation of dextransucrase by these modified dextrans cannot be due to primer reactions with the nonreducing ends. The activation of dextransucrase, thus, must be by an alternate mechanism. Two alternative mechanisms discussed are an allosteric effect and nucleophilic displacement reactions by the added dextran. It was also found that the addition of increasing amounts of dextran shifted the synthesis from an insoluble dextran to a soluble dextran.