Physicochemical properties of isocitrate dehydrogenase from lactating bovine mammary gland: effect of substrates and cofactors

The influence of substrates and cofactors on the oligomeric structure of the cytosolic form of NADP+-specific isocitrate dehydrogenase (IDH) from lactating bovine mammary gland was investigated using analytical ultracentrifugation and kinetic methods. In guanidine-HCl, the monomer molecular weight for reduced and carboxymethylated IDH was found to be 50,000 to 52,000. In nondenaturing solvents IDH behaves as a homogeneous solute with a molecular weight of 97,200. When added separately, manganous isocitrate, isocitrate, manganous citrate (substrate analog), and a mixture of the substrate analog and NADP+ do not significantly alter the sedimentation coefficient or the molecular weight of IDH as judged by direct observation of the enzyme at 0.1 to 3 microM using sedimentation velocity and equilibrium. Active enzyme sedimentation (AES) was used to assess the degree of dissociation of IDH at lower concentrations, and Kd for the dimer-monomer equilibrium was estimated to be 2 nM. In enzymatic studies, the specific activity at several levels of substrate does not vary as the subunit concentration of enzyme is reduced from 10 to 0.3 nM. Estimates for Kd by AES indicate the presence of a significant fraction of monomer at assay concentrations of 1 nM and below, where the weight fraction of monomer is predicted to be 0.6. If the monomer has a lower activity than the dimer, a drop in specific activity is expected below 1 nM. Significant decreases occur only when the IDH is not protected from denaturation. The concentration of cytoplasmic IDH in bovine mammary tissue is estimated to be 5.7 microM, at least 100-fold greater than our estimates of Kd. Since over 90% of the enzyme is present in the dimeric form, ligand-induced changes in aggregation state cannot play a significant role in the regulation of the cytosolic form of IDH in situ in this tissue.     

Physicochemical properties of the matrix proteins of three main culture vehicles

The protein components of three industrial recombinant expression systems: Escherichia coli, Saccharomyces cerevisiae, and a mammalian cell culture supernatant of CHO cells were characterized in terms of their molecular weight, isoelectric point, and relative surface hydrophobicity. Identification of individual proteins was done by reference to their position in protein band profiles by polyacrylamide gel electrophoresis (PAGE) of the crude material. This permitted a rapid and facile assignment of quantitative values for these three parameters to all the major protein components in these materials. Because it is the indigenous proteins in expression systems that will form the bulk of any impurities in the product, once the values of these parameters are known for any target recombinant protein, the data obtained will enable appropriate expression systems to be chosen for minimizing amounts of potential contaminants and reducing downstream processing requirements and costs. The data will also indicate which fractionation steps (i.e., charge, size or hydrophobicity-based) are likely to be best for distinguishing between target and contaminant proteins, thus aiding and early removal of the maximum quantities of undesired protein to bring subsequent bioseparation steps down in scale and cost and up in terms of efficiency. (c) 1994 John Wiley & Sons, Inc.     

Synthesis of graft copolymer (CgOH-g-AGA): Physicochemical properties, characterization and application

A graft copolymer of κ-carrageenan and 2-acrylamidoglycolic acid (CgOH-g-AGA) was synthesized via free radical polymerization initiated by potassium peroxymonosulphate/malonic acid redox pair. For affording maximum percentage of grafting, optimum conditions were determined by varying the concentrations of κ-carrageenan, 2-acrylamidoglycolic acid, potassium peroxymonosulphate, malonic acid, hydrogen ion, time and temperature. The swelling, metal ion uptake and flocculation studies were investigated with water, three metals (Ni(2+), Pb(2+) and Zn(2+)) solutions, coal (coking and non-coking) suspensions, respectively. Both, polymer backbone and its corresponding graft copolymer samples were characterized by Fourier transform infrared spectroscopy and thermogravimetric analysis.     

Physicochemical properties of the microbial exopolysaccharide ethapolan synthesized on a mixture of growth substrates

Some physicochemical properties of the microbial exopolysaccharide (EPS) ethapolan synthesized by Acinetobacter sp. 12S depended on whether the producer was grown on a mixture of ethanol and glucose or on single substrates. Irrespective of the carbon source in the nutrient medium, the contents of carbohydrates, pyruvic acid, uronic acids, and mineral components in the EPS remained unchanged. The EPS were also identical in their monosaccharide composition: the molar ratio of glucose, mannose, galactose, and rhamnose was 3:2:1:1. EPS with a higher proportion of fatty acids was synthesized during growth on the mixture of ethanol and glucose. Average molecular weight and the proportion of high-molecular (over two million) fractions were greater in ethapolan produced on the substrate mixture. In the presence of 0.1 M KCl, after transformation into the H+ form, and in the Cu(2+)-glycine system, solutions of these EPS showed higher viscosity than solutions of EPS synthesized on single substrates. The reasons for the improved rheological properties of the EPS produced on the substrate mixture are discussed.     

Growth properties and cholesterol removal ability of electroporated Lactobacillus acidophilus BT 1088

This study aimed to evaluate the effects of electroporation on the cell growth, cholesterol removal, and adherence abilities of L. acidophilus BT 1088 and their subsequent passages. The growth of electroporated parent cells increased (P<0.05) by 4.49-21.25% compared with that of the control. This may be attributed to the alteration of cellular membrane. However, growth of first, second, and third passages of treated cells was comparable with that of the control, which may be attributed to the resealing of transient pores on the cellular membrane. Electroporation also increased (P<0.05) assimilation of cholesterol by treated parent cells (>185.40%) and first passage (>21.72%) compared with that of the control. Meanwhile, incorporation of cholesterol into the cellular membrane was also increased (P<0.05) in the treated parent cells (>108.33%) and first passage (>26.67%), accompanied by increased ratio of cholesterol:phospholipids (C:P) in these passages. Such increased ratio was also supported by increased enrichment of cholesterol in the hydrophilic heads, hydrophobic tails, and the interface regions of the membrane phospholipids of both parent and first passage cells compared with that of the control. However, such traits were not inherited by the subsequent second and third passages. Parent cells also showed decreased intestinal adherence ability (P<0.05; decreased by 1.45%) compared with that of the control, without inheritance by subsequent passages of treated cells. Our data suggest that electoporation could be a potential physical treatment to enhance the cholesterol removal ability of lactobacilli that was inherited by the first passage of treated cells without affecting their intestinal adherence ability.     

Production of poly(3-hydroxybutyrate) from inexpensive substrates

Two inexpensive substrates, starch and whey were used to produce poly(3-hydroxybutyrate) (PHB) in fed-batch cultures of Azotobacter chroococcum and recombinant Escherichia coli, respectively. Oxygen limitation increased PHB contents in both fermentations. In fed-batch culture of A. chroococcum, cell concentration of 54 g l⁻¹ with 46% PHB was obtained with oxygen limitation, whereas 71 g l⁻¹ of cell with 20% PHB was obtained without oxygen limitation. The timing of PHB biosynthesis in recombinant E. coli was controlled using the agitation speed of a stirred tank fermentor. A PHB content of 80% could be obtained with oxygen limitation by increasing the agitation speed up to only 500 rpm.     

Rhamnolipid-induced removal of lipopolysaccharide from Pseudomonas aeruginosa: effect on cell surface properties and interaction with hydrophobic substrates

Little is known about the interaction of biosurfactants with bacterial cells. Recent work in the area of biodegradation suggests that there are two mechanisms by which biosurfactants enhance the biodegradation of slightly soluble organic compounds. First, biosurfactants can solubilize hydrophobic compounds within micelle structures, effectively increasing the apparent aqueous solubility of the organic compound and its availability for uptake by a cell. Second, biosurfactants can cause the cell surface to become more hydrophobic, thereby increasing the association of the cell with the slightly soluble substrate. Since the second mechanism requires very low levels of added biosurfactant, it is the more intriguing of the two mechanisms from the perspective of enhancing the biodegradation process. This is because, in practical terms, addition of low levels of biosurfactants will be more cost-effective for bioremediation. To successfully optimize the use of biosurfactants in the bioremediation process, their effect on cell surfaces must be understood. We report here that rhamnolipid biosurfactant causes the cell surface of Pseudomonas spp. to become hydrophobic through release of lipopolysaccharide (LPS). In this study, two Pseudomonas aeruginosa strains were grown on glucose and hexadecane to investigate the chemical and structural changes that occur in the presence of a rhamnolipid biosurfactant. Results showed that rhamnolipids caused an overall loss in cellular fatty acid content. Loss of fatty acids was due to release of LPS from the outer membrane, as demonstrated by 2-keto-3-deoxyoctonic acid and sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis and further confirmed by scanning electron microscopy. The amount of LPS loss was found to be dependent on rhamnolipid concentration, but significant loss occurred even at concentrations less than the critical micelle concentration. We conclude that rhamnolipid-induced LPS release is the probable mechanism of enhanced cell surface hydrophobicity.     

三个不同产地香菇多糖的理化性质及生物活性研究

本研究分析了浙江、湖北和新疆香菇多糖的结构、抗氧化及抗肿瘤活性。采用水提醇沉法,制备3个产地香菇多糖,分别利用Sevag法及透析法对其进行初步纯化,获得浙江香菇多糖（ZLP）、新疆香菇多糖（XLP）、湖北香菇多糖（HLP）。进一步通过高效阴离子交换色谱（HPAEC）测定其单糖组成,傅里叶变换红外光谱（FTIR）分析其结构。检测了3个多糖的自由基清除能力和抑制肿瘤细胞增殖能力。结果表明,3个多糖均主要由葡萄糖、半乳糖及甘露糖组成。3个多糖红外光谱的特征吸收峰相似,均含有β糖苷键。HLP、ZLP、XLP均可有效清除1,1-二苯基-2-苦基肼（DPPH）、2,2-联氮基双-3-乙基苯并噻唑啉-6-磺酸（ABTS）和羟基自由基。此外,HLP和XLP对人肝癌细胞（HpG2）、人肺癌细胞（NCI-H460）、人胃腺癌细胞（SGC-7901）的抑制增殖能力高于ZLP。     

Physicochemical properties of l- and dl-valine: first-principles calculations

At present, physicochemical properties of amino acid molecular crystals are of the utmost interest. The compounds where molecules have different chirality are the focus of particular interest. This paper, presents a study on the structural and electronic properties of crystalline l- and dl-valine within the framework of density functional theory including van der Waals interactions. The results of this study showed that electronic properties of the two forms of valine are similar at zero pressure. Pressure leads to different responses in these crystals which is manifested as various deformations of molecules. The pressure effect on the infrared spectra and distribution of electron density of l- and dl-valine has been studied.

     

Phosphorus removal coupled to bioenergy production by three cyanobacterial isolates in a biofilm dynamic growth system

In the present study a closed incubator, designed for biofilm growth on artificial substrata, was used to grow three isolates of biofilm-forming heterocytous cyanobacteria using an artificial wastewater secondary effluent as the culture medium. We evaluated biofilm efficiency in removing phosphorus, by simulating biofilm-based tertiary wastewater treatment and coupled this process with biodiesel production from the developed biomass. The three strains were able to grow in the synthetic medium and remove phosphorus in percentages, between 6 and 43%, which varied between strains and also among each strain according to the biofilm growth phase. Calothrix sp. biofilm turned out to be a good candidate for tertiary treatment, showing phosphorus reducing capacity (during the exponential biofilm growth) at the regulatory level for the treated effluent water being discharged into natural water systems.

Besides phosphorus removal, the three cyanobacterial biofilms produced high quality lipids, whose profile showed promising chemical stability and combustion behavior. Further integration of the proposed processes could include the integration of oil extracted from these cyanobacterial biofilms with microalgal oil known for high monounsaturated fatty acids content, in order to enhance biodiesel cold flow characteristics.     

Catechol-o-methyltransferase in rat erythrocyte and three other tissues: comparison of biochemical properties after removal of inhibitory calcium

The biochemical characteristics of soluble catechol-O-methyltransferase (COMT) activity in rat erythrocytes were compared with the properties of the soluble enzyme in rat liver, heart, and brain. COMT was measured by a procedure that avoided artifacts of some other assay procedures including inhibition of the enzyme by endogenous calcium. After the removal of calcium from the reaction mixture the apparent Michaelis-Menten constants for the two cosubstrates of the COMT reaction, S-adenosyl-1-methionine (SAM) and 3,4-dihydroxybenzoic acid (DBA), were similar in tissue preparations of rat liver, brain, heart and blood. The apparent Km values for the four tissues ranged from 5.7 to 6.7 x 10(-6) M and from 0.9-1.4 x 10(-4) M for SAM and DBA, respectively. The optimal pH and the optimal concentration of magnesium for the assay of red blood cell COMT were also similar to those for the enzyme in the three other rat tissues. After the removal of endogenous calcium, COMT activity in all four tissues was inhibited by the addition of calcium, and the [CaCl2] necessary to inhibit the enzyme activity 50% was 3-5 x 10(-4) M in all cases. The relative activities of COMT in the rat heart, brain, erythrocyte, and liver when expressed per g tissue or per ml of packed red blood cells were 1 to 1.15 to 1.58 to 140, respectively.     

Physicochemical properties of oilseed proteins

This review attempts to consolidate the information on the physicochemical properties of proteins from groundnut, soybean, sesame seed, mustard seed, rapeseed, sunflower seed, cottonseed, and other oilseeds. It deals with the extraction and characterization of the oilseed proteins and describes the methods for isolation of the various protein fractions and determination of their physicochemical characteristics. Also discussed are the subunit composition of the oligomeric proteins, their hydrodynamic properties, and the effect of denaturants on these proteins. The similarity in the properties of the proteins from various oilseed materials is discussed. The review article aims to indicate the gaps in our knowledge about the physicochemical properties of oilseed proteins and suggests areas for future investigation.     

Physicochemical properties of multicomponent polyhydroxyalkanoates

X-ray structure analysis, IR spectrometry, differential thermal analysis, and viscosimetry have been used to investigate the properties of novel five-component polyhydroxyalkanoates formed by short- and medium-chain-length monomers synthesized by the bacterium Wautersia eutropha B5786. As the molar fraction of hydroxyhexanoate contained in polyhydroxyalkanoates samples increased from 2.5 to 18.0 mol%, their degree of crystallinity decreased from 72 to 57%. The melting temperature of multicomponent polyhydroxyalkanoates (Tm) and their temperature for the onset of decomposition (Td) are lower than those of polyhydroxybutyrate, whose Tm is 168-170 degrees C and Td 260-265 degrees C. In multicomponent polymers (PHA(SC+MC)), both parameters decrease as the molar fraction of hydroxyhexanoate grows to 156 and 252 degrees C, respectively, in the range of hydroxyhexanoate content studied. Hydroxyhexanoate influences the physicochemical properties of polyhydroxyalkanoates similarly to hydroxyvalerate; as the fraction of either of these medium-chain-length monomers in polyhydroxyalkanoates increases, the crystallinity of the polymer decreases, but its thermostability remains unchanged.     

Physicochemical properties of kidney-specific antigen

Using specific antirenal sera obtained from rabbits and absorbed with a mixture of extracts from heterologous organs, a specific antigen was detected in human and CBA mouse renal extracts. Its molecular weight was found to amount to about 100 000 dalton. It is salted out with ammonium sulfate at 50-70% saturation of renal extract and is destroyed on extract heating for 30 min at 75 degrees C. This antigen is sensitive to trypsin and papain but resistant to hyaluronidase. It is partially destroyed by DNase and RNase, provided the latter ones are used in comparatively high doses (1 mg per 0.3 ml extract) and exposure lasts one day. Based on the study of the physicochemical properties it is suggested that the kidney-specific antigen may be a ribonucleoprotein or a deoxyribonucleoprotein but cannot be attributed to glycoproteins.