The action of tributyltin chloride on the uptake of proline and glutamine by intact cells of Escherichia coli.

Tributyltin chloride inhibits growth and uptake of glutamine and proline into intact cells of Escherichia coli. It causes efflux of the accumulated amino acids. A pH gradient generated in intact cells and everted membrane vesicles is dissipated by this compound. These effects do not require lipoic acid but are dependent on the presence of chloride, bromide, or iodide ions. We conclude that tributyltin chloride can catalyse a transmembrane OH- -anion exchange exchange reaction and that this is its mode of inhibition of the uptake of these amino acids. The response of proline and glutamine uptake to the inhibitor is similar and is consistent with the transport of both amino acids requiring an electrochemical gradient of protons.     

Isozymal differention between two species of Prosopis

The patterns of five multilocus isozyme systems were investigated in seed, shoot and cotyledon tissue of two species of mesquite, Prosopis glandulosa var. glandulosa and P. pallida. The isozymes of malate dehydrogenase, peroxidase, esterase, alcohol dehydrogenase and acid phosphatase from each of these tissues were analysed by starch gel electrophoresis and specific histochemical stains. In the case of each enzyme system examined, there were distinctly different isozymes which could be utilized to differentiate between these two species.     

Lack of involvement of lipoic acid in membrane-associated energy transduction in Escherichia coli.

Oxidative phosphorylation, active transport of proline, aerobic- and ATP-driven proton translocation and transhydrogenation of NADP⁺ by NADH, occurred in lipoic acid-deficient cells or vesicles of a lipoic acid auxotroph of $\text{E. coli}$, W1485 lip 2. Addition of lipoic acid had little effect on these processes. Tributyltin chloride, which has been proposed to inhibit oxidative phosphorylation by reaction with lipoic acid (Cain $\text{et al.}$, Biochem. J. (1977) $\text{166}$, 593), was an effective inhibitor of aerobic and ATP-dependent proton translocation and transhydrogenation in lipoic acid-deficient vesicles from this organism. Our results do not support the proposal of Partis $\text{et al.}$ (FEBS Lett. (1977) $\text{75}$, 47) that lipoic acid is involved in the energy transducing processes associated with the membrane of $\text{E. coli}$.     

Salmonella typhimurium HfrA, a mutant in which adenosine triphosphate can drive amino acid transport but not energy-dependent nicotinamide nucleotide transhydrogenation.

In contrast with wild-type Salmonella typhimurium LT2, strain HfrA did not have ATP-driven energy-dependent transhydrogenase activity, although ATP-dependent quenching of atebrin fluorescence was normal. Respiration-dependent and energy-independent transhydrogenase, and Ca2+-activated ATPase (adenosine triphosphatase) activities were similar in both strains. Purified ATPases from the two strains had similar specific activities, similar subunit polypeptides, and were equally effective in restoring energy-dependent transhydrogenase activities to membrane particles of strain LT2 from which the ATPase had been stripped. The purified ATPases from both strains could restore respiration-dependent but not ATP-dependent transhydrogenation to stripped particles of strain HfrA. Both strains grew aerobically equally well on salts media containing glucose, malate, succinate, citrate, acetate, pyruvate, fumarate, lactate or aspartate as substrates. Growth on glucose under anaerobic conditions was similar. Strains LT2 and HfrA were equally effective in the accumulation under both aerobic and anaerobic conditions of the amino acids proline, phenylalanine, histidine, lysine, isoleucine and aspartic acid. Inhibition of amino acid accumulation by KCN and dicyclohexylcarbodi-imide occurred to the same extent in both strains. The complete inhibition by dicyclohexylcarbodi-imide of amino acid uptake under anaerobic conditions suggested that ATP could drive amino acid uptake in both strains. The ability of strain HfrA to carry out ATP-dependent transport or quenching of atebrin fluorescence but not ATP-dependent transhydrogenation is different from the wild-type strain and from any previously described energy-coupling mutant. It is difficult to reconcile the properties of this mutant with the chemiosmotic hypothesis.     

Crosslinking studies on the CA2+, MG2+-activated ATPase of escherichia coli

Crosslinking of membrane proteins of Escherichia coli with dithiobis (succinimidyl propionate) (DSP) resulted in loss of several enzyme activities including the Ca²⁺, Mg²⁺-activated ATPase. This enzyme was crosslinked by DSP to the membrane and was not released by dialysis at low ionic strength in the absence of dithiothreitol which could cleave the crosslinking group. DSP inactivated both phosphohydrolase and coupling activities of the solubilized ATPase. Loss of hydrolytic activity could be correlated with the extent of reaction of the α and/or β subunits of the enzyme. The loss of coupling activity appeared to be associated with modification of the γ and/or δ subunits.     

Conformational interactions between alpha and beta subunits in the F1 ATPase of Escherichia coli as shown by chemical modification of uncA401 and uncD412 mutant enzymes

In contrast to wild-type F1 adenosine triphosphatase, the beta subunits of soluble ATPase from Escherichia coli mutant strains AN120 (uncA401) and AN939 (uncD412) were not labeled by the fluorescent thiol-specific reagents 5-iodoacetamidofluorescein, 2-(4'-iodoacetamidoanilino)naphthalene-6-sulfonic acid or 4-[N-(iodoacetoxy)ethyl-N-methyl]amino-7-nitrobenzo-2-oxa-1,3-diazole. The mutation in the alpha subunit (uncA401) of F1 ATPase thus influences the accessibility of the single cysteinyl residue in the beta subunit. Following reaction of ATPase with 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole or N,N'-dicyclohexylcarbodiimide, the alpha and beta subunits of the uncA401, but not of the uncD412 mutant F1 ATPase were intensely labeled by a fluorescent thiol reagent. The mutation in the beta subunit (uncD412) thus influences the accessibility of the cysteinyl residues in the alpha subunit. In other work [Stan-Lotter, H. and Bragg, P.D. (1986) Arch. Biochem. Biophys. 248] we have shown that 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole and 2-(4'-iodoacetamidoanilino)naphthalene-6-sulfonic acid react with a different beta subunit from that labeled by N,N'-dicyclohexylcarbodiimide. This asymmetry with respect to modification by 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole and N,N'-dicyclohexylcarbodiimide was seen in both mutant enzymes. In addition, the modification of one beta subunit of the uncA401 F1 ATPase induced the previously unreactive sulfhydryl group of another beta subunit to react with 2-(4'-iodoacetamidoanilino-naphthalene-6-sulfonic acid. These results provide evidence for at least three types of conformational interactions of the major subunits of F1 ATPase: from alpha to beta, from beta to alpha, and from beta to beta. As in wild-type ATPase, labeling of membrane-bound unc mutant ATPase by a fluorescent thiol reagent modified the alpha subunits. This suggests that a conformational change of yet a different type occurs when the enzyme binds to the membrane.     

Variation in abundance and harvest of sooty shearwaters (Puffinus griseus) by Rakiura Maori on Putauhinu Island,New Zealand

Abstract

Sooty shearwater (Puffinus griesus, titi) abundance, harvest levels and chick mass were monitored repeatedly on Putauhinu Island, south‐west of Rakiura (Stewart Island) between 1997 and 2005. Putauhinu is the second largest of the Titi Islands and has a relatively high density of chicks distributed over most of the island, so it supports what is likely the second‐largest population of sooty shearwaters in the Rakiura region (after Taukihepa, Big South Cape Island). Rakiura Maori harvested chicks from five “manu” (family birding areas) that covered 56% of the 128.4 ha of breeding colony of the island. Chick density was lower on the unharvested area in the interior of the island than on harvested areas. Burrow entrance density was higher where there was more ground cover (mainly fern) vegetation, but these areas had lower burrow occupancy, so overall chick density was similar at different levels of ground cover. Twenty‐six harvesters present on Putauhinu in 2005 took 31 280 chicks in total, equivalent to 8.4% (95% CI = 6.6–12%) of the available chicks on the entire island. Seasonal variation in total chicks harvested (CV 15–22%) was not related to chick abundance or mass. Refuges, including impenetrable patches of vegetated ground within manu, the unharvested centre of the island, and even nearby unharvested islands, will ameliorate localised impacts of harvest if density‐dependent immigration is operating.     

Intersubunit crosslinking of the heterotetrameric proton-translocating pyridine nucleotide transhydrogenase of Escherichia coli defines intersubunit contacts between transmembrane helices of the beta subunits

The proton-translocating pyridine nucleotide transhydrogenase of Escherichia coli is composed of two types of subunits, alpha and beta, organized as an alpha(2)beta(2) tetramer. The protein contains three recognizable domains, of which domain II is the transmembrane region of the molecule containing the pathway for proton translocation. Domain II is composed of four transmembrane helices at the carboxyl-terminus of the alpha subunit and nine transmembrane helices at the amino-terminal region of the beta subunit. We have introduced pairs of cysteine residues into all of the loops connecting the transmembrane helices of domain II of the beta subunit. Crosslinking between the two beta subunits of the tetramer was induced spontaneously, or by treatment with cupric 1,10-phenanthrolinate or o-phenylenedimaleimide. Crosslinks between pairs of betaA114C, betaS183C, and betaA262C residues were observed, suggesting that pairs of domain II transmembrane helices 11, 12, and 14 were in proximity. These results, together with previous data (Bragg and Hou (2000) Biochem. Biophys. Res. Commun. 273, 955-959) suggest that the transhydrogenase tetramer is formed by apposition of alpha(2) and beta(2) dimers. Crosslinking between pairs of cysteine residues in the same beta subunit was not observed, possibly because the interhelical loops of the domain II region of the beta subunit were too short to allow correct orientation of the sulfhydryl groups for crosslinking.     

Characterization of mutants of beta histidine91, beta aspartate213, and beta asparagine222, possible components of the energy transduction pathway of the proton-translocating pyridine nucleotide transhydrogenase of Escherichia coli

The roles of three residues (betaHis91, betaAsp213, and betaAsn222) implicated in energy transduction in the membrane-spanning domain II of the proton-translocating pyridine nucleotide transhydrogenase of Escherichia coli have been examined using site-directed mutagenesis. All mutations affected transhydrogenation and proton pumping activities, although to various extents. Replacing betaHis91 or betaAsn222 of domain II by the basic residues lysine or arginine resulted in occlusion of NADP(H) at the NADP(H)-binding site of domain III. This was not seen with betaD213K or betaD213R mutants. It is suggested that betaHis91 and betaAsn222 interact with betaAsp392, a residue probably involved in initiating conformational changes at the NADP(H)-binding site in the normal catalytic cycle of the enzyme (M. Jeeves et al. (2000) Biochim. Biophys. Acta 1459, 248-257). The introduced positive charges in the betaHis91 and betaAsn222 mutants might stabilize the carboxyl group of betaAsp392 in its anionic form, thus locking the NADP(H)-binding site in the occluded conformation. In comparison with the nonmutant enzyme, and those of mutants of betaAsp213, most mutant enzymes at betaHis91 and betaAsn222 bound NADP(H) more slowly at the NADP(H)-binding site. This is consistent with the effect of these two residues on the binding site. We could not demonstrate by mutation or crosslinking or through the formation of eximers with pyrene maleimide that betaHis91 and betaAsn222 were in proximity in domain II.