Further characterization and chemical purity assessment of the human erythrocyte glucose transporter preparation

Chemical and functional purity of the human erythrocyte glucose transporter preparation obtained by DEAE column chromatography after octyl glucoside solubilization was assessed. The cytochalasin B binding capacity of the preparation indicates that the preparation is 60-85% functional glucose transporter. Gel filtration chromatography on TSK 250 column separates this preparation into at least three major peptide fractions, namely, P0, P1 and P2, with apparent Mr of approx. 80 000, 43 000 and 17 000, respectively. When the preparation is photolabelled with [3H]cytochalasin B prior to the separation only P0 and P1 are labelled. Exposure of the preparation to octyl glucoside or to ultraviolet light irradiation results in an increase in P0 in a time-dependent manner with a concomitant and proportional reduction in P1, without affecting P2 appreciably. For individual preparations, relative abundance of P0 and P1 vary widely in a reciprocal fashion, while that of P2 is practically fixed at approx. 10% of the total protein. The specific activity of cytochalasin B binding of each preparation correlates linearly with the relative abundance of P1 of the preparation, which gives a calculated specific binding activity of 22 nmol/mg protein for this fraction. These results indicate that P1 and P0 are native and denatured transporter, respectively, while P2 is contaminating protein impurities. These results demonstrate that the glucose transporter preparation contains approx. 10% of nontransporter protein impurities, with a varying amount (up to 30%) of denatured transporter, and that the transporter free of the chemical impurities and the denatured transporter can be obtained by a gel filtration chromatography of this preparation.     

The proton-pumping site of cytochrome c oxidase: a model of its structure and mechanism

Cytochrome c oxidase is an electron-transfer driven proton pump. In this paper, we propose a complete chemical mechanism for the enzyme's proton-pumping site. The mechanism achieves pumping with chemical reaction steps localized at a redox center within the enzyme; no indirect coupling through protein conformational changes is required. The proposed mechanism is based on a novel redox-linked transition metal ligand substitution reaction. The use of this reaction leads in a straightforward manner to explicit mechanisms for achieving all of the processes previously determined (Blair, D.F., Gelles, J. and Chan, S.I. (1986) Biophys. J. 50, 713-733) to be needed to accomplish redox-linked proton pumping. These processes include: (1) modulation of the energetics of protonation/deprotonation reactions and modulation of the energetics of redox reactions by the structural state of the pumping site; (2) control of the rates of the pump's redox reactions with its electron-transfer partners during the turnover cycle (gating of electrons); and (3) regulation of the rates of the protonation/deprotonation reactions between the pumping site and the aqueous phases on the two sides of the membrane during the reaction cycle (gating of protons). The model is the first proposed for the cytochrome oxidase proton pump which is mechanistically complete and sufficiently specific that a realistic assessment can be made of how well the model pump would function as a redox-linked free-energy transducer. This assessment is accomplished via analyses of the thermodynamic properties and steady-state kinetics expected of the model. These analyses demonstrate that the model would function as an efficient pump and that its behavior would be very similar to that observed of cytochrome oxidase both in the mitochondrion and in purified preparations. The analysis presented here leads to the following important general conclusions regarding the mechanistic features of the oxidase proton pump. (1) A workable proton-pump mechanism does not require large protein conformational changes. (2) A redox-linked proton pump need not display a pH-dependent midpoint potential, as has frequently been assumed. (3) Mechanisms for redox-linked proton pumps that involve transition metal ligand exchange reactions are quite attractive because such reactions readily lend themselves to the linked gating processes necessary for proton pumping.     

Redox-linked proton translocation in cytochrome oxidase: the importance of gating electron flow. The effects of slip in a model transducer.

In at least one component of the mitochondrial respiratory chain, cytochrome c oxidase, exothermic electron transfer reactions are used to drive vectorial proton transport against an electrochemical hydrogen ion gradient across the mitochondrial inner membrane. The role of the gating of electrons (the regulation of the rates of electron transfer into and out of the proton transport site) in this coupling between electron transfer and proton pumping has been explored. The approach involves the solution of the steady-state rate equations pertinent to proton pump models which include, to various degrees, the uncoupled (i.e., not linked to proton pumping) electron transfer processes which are likely to occur in any real electron transfer-driven proton pump. This analysis furnishes a quantitative framework for examining the effects of variations in proton binding site pKas and metal center reduction potentials, the relationship between energy conservation efficiency and turnover rate, the conditions for maximum power output or minimum heat production, and required efficiency of the gating of electrons. Some novel conclusions emerge from the analysis, including: An efficient electron transfer-driven proton pump need not exhibit a pH-dependent reduction potential; Very efficient gating of electrons is required for efficient electron transfer driven proton pumping, especially when a reasonable correlation of electron transfer rate and electron transfer exoergonicity is assumed; and A consideration of the importance and possible mechanisms of the gating of electrons suggests that efficient proton pumping by CuA in cytochrome oxidase could, in principle, take place with structural changes confined to the immediate vicinity of the copper ion, while proton pumping by Fea would probably require conformational coupling between the iron and more remote structures in the enzyme. The conclusions are discussed with reference to proton pumping by cytochrome c oxidase, and some possible implications for oxidative phosphorylation are noted.     

Binding inhibition by monoclonal antibodies of ovine placental lactogen to growth hormone receptors in human liver

In the radioreceptor assay for growth hormone (RRA-GH) using [125I]iodo-hGH, hGH and human liver membrane particulate fractions as tracer, hormone standard and receptors, respectively, ovine placental lactogen (oPL) is capable of inhibiting the binding of [125I]iodo-hGH in a parallel manner with hGH and in equipotency. Similarly, in the RRA-GH by employing [125I]iodo-oPL, oPL and human liver membrane particulate fractions as tracer, hormone standard and receptors, respectively, hGH is also equipotent as oPL in inhibiting the binding of [125I]iodo-oPL in a parallel fashion. The addition of monoclonal antibodies against oPL in the assay was effective in inhibiting the binding of [125I] iodo-oPL to human liver, but could not, however, inhibit the binding of [125I]iodo-hGH to human liver. Furthermore, the addition of the monoclonal antibodies in the RRA-GH did not affect the parallelism of the oPL standard but lowered the total binding of oPL. Our studies indicate that the structure of the binding sequence in oPL which binds to the GH receptor of human liver is not identical to the equivalent sequence of hGH and that the monoclonal antibodies compete with GH receptors in human liver for the binding of oPL.     

Occurrence and distribution of halophilic vibrios in subtropical coastal waters of Hong Kong.

The summer occurrence and distribution of halophilic vibrios in the subtropical coastal waters of Hong Kong were investigated. The density of vibrios in six sample sites ranged from 90 to 6,700 per ml, which made up 0.41 to 40% of the total bacterial populations of these sample sites. The sucrose-positive vibrios were found to be much more common (88% of total vibrios) than the sucrose-negative ones. A total of 48 strains belonging to six Vibrio species were fully characterized. Among these, Vibrio alginolyticus was the most frequently isolated, followed by V. parahaemolyticus, V. harveyi, V. vulnificus, V. campbellii, and V. fluvialis. The finding that eight of the nine strains of V. harveyi showed a positive Kanagawa reaction warrants further study.     

Enzyme regulation in C4 photosynthesis: purification, properties, and activities of thioredoxins from C4 and C3 plants

Procedures are described for the purification to homogeneity of chloroplast thioredoxins f and m from leaves of corn (Zea mays, a C4 plant) and spinach (Spinacea oleracea, a C3 plant). The C3 and C4f thioredoxins were similar immunologically and biochemically, but differed in certain of their physiochemical properties. The f thioredoxins from the two species were capable of activating both NADP-malate dehydrogenase (EC 1.1.1.37) and fructose-1,6-bisphosphatase (EC 3.1.3.11) when tested in standard thioredoxin assays. Relative to its spinach counterpart, corn thioredoxin f showed a greater molecular mass (15.0-16.0 kDa vs 10.5 kDa), lower isoelectric point (ca. 5.2 vs 6.0), and lower ability to form a stable noncovalent complex with its target fructose bisphosphatase enzyme. The C3 and C4 m thioredoxins were similar in their specificity (ability to activate NADP-malate dehydrogenase, and not fructose-1,6-bisphosphatase) and isoelectric points (ca. 4.8), but differed slightly in molecular mass (13.0 kDa for spinach vs 13.5 kDa for corn) and substantially in their immunological properties. Results obtained in conjunction with these studies demonstrated that the thioredoxin m-linked activation of NADP-malate dehydrogenase in selectively enhanced by the presence of halide ions (e.g., chloride) and by an organic solvent (e.g., 2-propanol). The results suggest that in vivo NADP-malate dehydrogenase interacts with thylakoid membranes and is regulated to a greater extent by thioredoxin m than thioredoxin f.     

Monoclonal antibody detection of transformation associated protein (TAP) in ts110 Moloney murine sarcoma virus transformed 6M2 cells that are different from the mos gene product

By the use of a highly specific monoclonal antibody (designated MC), we were able to detect three radiolabeled bands with molecular weights of 60,000, 63,000, and 66,000 daltons in the ts-110 Moloney murine sarcoma virus mutant-transformed rat kidney cells known as 6M2. Expression of transformation properties as well as these three bands in 6M2 cells was found to be temperature sensitive. Therefore, MC detected factors that are apparently associated with the transformation of 6M2 cells. These factors are tentatively referred to as transformation associated proteins. These transformation proteins were found in two other Moloney murine sarcoma virus-transformed rat cell lines. These proteins were found to differ from known gene products of the ts-110 Moloney murine sarcoma virus mutant and do not have kinase activity. The transformation associated proteins may represent rat cellular factors activated during the transformation of rat cells by Moloney murine sarcoma virus.     

Temperature dependence of the reduction potential of CuA in carbon monoxide inhibited cytochrome c oxidase

The temperature dependence of the reduction potential of the CuA site in carbon monoxide inhibited cytochrome c oxidase has been measured with a spectroelectrochemical method adapted to the relatively weak near-infrared absorption of this copper ion. These measurements, together with parallel measurements on the 604-nm absorption due to Fea, indicate that an interaction between CuA and Fea causes the reduction potential for one of these sites to be decreased by approximately 40 mV upon reduction of the other. The temperature dependence of the CuA reduction potential indicates a relatively large and negative standard entropy of reduction of CuA (delta So' = -48.7 +/- 2.3 eu). Possible implications of the intersite redox interaction and the large standard entropy of reduction of the CuA site are discussed.     

Epitopes, structural domains, and asymmetry of amino acid residues in SS-B/La nuclear protein

SS-B/La is a conserved cellular phosphoprotein of 46 to 48 KD that is the target antigen of autoantibodies in sera of patients with Sjogren's syndrome and systemic lupus erythematosus. SS-B/La is also known to be associated with certain small cellular and viral RNA, including adenovirus VAI and VAII RNA. Two relatively protease-resistant domains (X and Y) were defined in SS-B from HeLa cells by using human autoantibodies as reagents. Domain X, a methionine-containing nonphosphorylated 28 KD polypeptide, was found to be resistant to partial digestion with six different proteases. Similar domains were also found in calf and rabbit SS-B. Domain Y, a 23 KD polypeptide, was detected after limited digestion with S. aureus V8 and trypsin. This domain contained little if any methionine, but all the detectable phosphorylated amino acids. Among 16 anti-SS-B sera tested by immunoblotting, 11 (69%) were reactive with both domains, three (19%) only with domain X, and two (13%) only with domain Y. These results showed that there are at least two distinct antigenic epitopes on the 46 to 48 KD SS-B/La protein, each located on a separate structural domain. The asymmetric distribution of methionine and phosphorylated amino acid residues in SS-B/La show striking similarity to the two reported domains of the adenovirus 72 KD DNA-binding protein, and raises questions concerning functional similarities that await investigation.     

Heterogeneity of EBV-transformable human B lymphocyte populations

Although most human B cells express receptors for Epstein Barr virus (EBV), few (usually less than 1%) are readily transformed into B lymphoblastoid cell lines after exposure to EBV. Transformable cells previously have been found to be mostly resting B lymphocytes. We recently developed a limiting dilution culture system which permits the growth of EBV-transformed B lymphocytes with high efficiency. Because in this system up to over 30% of peripheral blood- or tonsil-derived B cells respond to EBV, we re-examined the properties of EBV-transformable cells. Frequencies of transformable lymphocytes were determined by Poisson analysis. EBV-susceptible B cells committed to IgM, IgG, or IgA secretion were found to occur in the range of 3 to 27, 0.1 to 6, and 0.1 to 5 per 100 B cells, respectively. Under our culture conditions, a major proportion of the IgM-committed cells derived from large lymphocytes which appeared to have entered the cell cycle. This population contains most of the EBV-responsive cells detected and, therefore, most of the additional cells responding in our culture system. In contrast, precursors of IgG- or IgA-producing lymphoblast lines were small cells with DNA contents typical for the G0/G1 phases of the cell cycle. Anti-immunoglobulin antibodies were used in panning experiments to separate B cell subpopulations which expressed different immunoglobulin isotypes on their surface. In limiting dilution cultures of these purified B lymphocytes subsets, it was found that virtually all precursors of IgM-producing cell lines expressed surface IgM (sIgM) before their infection and transformation by EBV. The "cloning efficiency" of positively selected, large sIgM+ cells approached 100%. In contrast, sIgG or sIgA were found only on cells committed to the production of IgG or IgA, respectively. The expression of sIgD was examined by using sequential panning procedures. Virtually all IgM-committed lymphocytes and a subset of cells committed to IgA secretion were found among the sIgD+ cells. The majority of cells committed to IgA production and all IgG-committed cells were found in the sIgD- B cell population. Our findings indicate that the EBV-susceptible B cell subset of normal lymphocytes is heterogeneous with respect to cell size, cell cycle, sIg determinants, and efficiency of transformation. On the basis of our findings and previous reports, we propose a model in which transformability is a B cell-inherent property. Factors unrelated to the virus but present in our culture system appear responsible for the enhanced vulnerability to viral transformation in some cells which entered into the cell cycle.(ABSTRACT TRUNCATED AT 400 WORDS)