Characterization of semi-uncoupled hybrid Escherichia coli-Bacillus megaterium F1F0 proton-translocating ATPases

Spatial hepatocyte plasticity of gluconeogenesis during the metabolic transitions between fed, fasted and starvation states

The liver acts as a master regulator of metabolic homeostasis in part by performing gluconeogenesis. This process is dysregulated in type 2 diabetes, leading to elevated hepatic glucose output. The parenchymal cells of the liver (hepatocytes) are heterogeneous, existing on an axis between the portal triad and the central vein, and perform distinct functions depending on location in the lobule. Here, using single cell analysis of hepatocytes across the liver lobule, we demonstrate that gluconeogenic gene expression ( Pck1 and G6pc ) is relatively low in the fed state and gradually increases first in the periportal hepatocytes during the initial fasting period. As the time of fasting progresses, pericentral hepatocyte gluconeogenic gene expression increases, and following entry into the starvation state, the pericentral hepatocytes show similar gluconeogenic gene expression to the periportal hepatocytes. Similarly, pyruvate-dependent gluconeogenic activity is approximately 10-fold higher in the periportal hepatocytes during the initial fasting state but only 1.5-fold higher in the starvation state. In parallel, starvation suppresses canonical beta-catenin signaling and modulates expression of pericentral and periportal glutamine synthetase and glutaminase, resulting in an enhanced pericentral glutamine-dependent gluconeogenesis. These findings demonstrate that hepatocyte gluconeogenic gene expression and gluconeogenic activity are highly spatially and temporally plastic across the liver lobule, underscoring the critical importance of using well-defined feeding and fasting conditions to define the basis of hepatic insulin resistance and glucose production.

Transcriptional cross-regulation between Gram-negative and gram-positive bacteria, demonstrated using ArgP-argO of Escherichia coli and LysG-lysE of Corynebacterium glutamicum

The protein-gene pairs ArgP-argO of Escherichia coli and LysG-lysE of Corynebacterium glutamicum are orthologous, with the first member of each pair being a LysR-type transcriptional regulator and the second its target gene encoding a basic amino acid exporter. Whereas LysE is an exporter of arginine (Arg) and lysine (Lys) whose expression is induced by Arg, Lys, or histidine (His), ArgO exports Arg alone, and its expression is activated by Arg but not Lys or His. We have now reconstituted in E. coli the activation of lysE by LysG in the presence of its coeffectors and have shown that neither ArgP nor LysG can regulate expression of the noncognate orthologous target. Of several ArgP-dominant (ArgP(d)) variants that confer elevated Arg-independent argO expression, some (ArgP(d)-P274S, -S94L, and, to a lesser extent, -P108S) activated lysE expression in E. coli. However, the individual activating effects of LysG and ArgP(d) on lysE were mutually extinguished when both proteins were coexpressed in Arg- or His-supplemented cultures. In comparison with native ArgP, the active ArgP(d) variants exhibited higher affinity of binding to the lysE regulatory region and less DNA bending at both argO and lysE. We conclude that the transcription factor LysG from a Gram-positive bacterium, C. glutamicum, is able to engage appropriately with the RNA polymerase from a Gram-negative bacterium, E. coli, for activation of its cognate target lysE in vivo and that single-amino-acid-substitution variants of ArgP can also activate the distantly orthologous target lysE, but by a subtly different mechanism that renders them noninterchangeable with LysG.

Localization of a conformational energy-coupling determinant near the C terminus of the beta subunit of the F1F0-ATPase

Escherichia coli mutants in the beta subunit of the F1F0-ATPase can be complemented with the beta subunit from the obligate aerobe Bacillus megaterium. It has been shown that cells carrying such hybrid ATPases have an unusual energy-coupling phenotype. Although they are able to grow on minimal succinate medium, and therefore carry a functional ATP synthase, they are defective in the ability to grow anaerobically, indicating some defect in ATP-driven proton pumping (Scarpetta, M., Hawthorne, C. A., and Brusilow, W. S. A. (1991) J. Biol. Chem. 266, 18567-18572). In this study, chimeric beta subunits were constructed consisting of the E. coli or the B. megaterium beta subunit carrying the C-terminal 18% of the other's beta subunit. The phenotypes of an E. coli beta mutant complemented with these chimeric subunits showed that the energy-coupling defect was located in this C-terminal region. The E. coli beta subunit carrying the B. megaterium C-terminal region displayed the energy-coupling defect, while the B. megaterium beta subunit carrying the E. coli C-terminal region did not. In ATP-dependent fluorescence quenching assays, membranes isolated from cells displaying the energy-coupling defect also pumped protons less well than membranes isolated from cells that were able to grow anaerobically. These results demonstrate that the C terminus of the beta subunit is involved in the conformational coupling pathway, which, through the polypeptide backbone of the beta subunit, physically links ATP synthesis or hydrolysis to the energy of proton translocation.

Construction and function of chimeric beta subunits containing regions from the beta subunits of the F1F0 ATPases of Escherichia coli and Bacillus megaterium

The highly conserved beta subunit of the Escherichia coli F1F0 ATPase was divided into three sections, each of which was exchanged with the homologous section of the beta subunit of the obligate aerobe Bacillus megaterium. Plasmids coding for the resultant six chimeric beta subunits varied in their abilities to complement two E. coli beta mutants as measured by testing transformed cells for aerobic growth on a nonfermentable carbon source or anaerobic growth on rich medium containing glucose. Two chimeras were able to restore both growth on succinate and anaerobic growth on rich medium. The genetic results corresponded to increased levels of membrane-bound ATPase and ATP synthase activities. These chimeric subunits were therefore capable of being assembled into functional E. coli ATPase complexes. The results indicate that chimeric beta subunits can be used to analyze assembly of the beta subunit and that the final 181 amino acids of the beta subunit might contain a region involved in functional energy coupling.

Hybrid Fo complexes of the ATP synthases of spinach chloroplasts and Escherichia coli. Immunoprecipitation and mutant analyses

Hybrid Fo complexes of the ATP synthases of spinach chloroplast (CFo) and Escherichia coli (EFo) were investigated. Immunoprecipitations with polyclonal antibodies against the different Fo subunits clearly revealed that hybrid Fo complexes derived from CFo subunit III and EFo subunits a and b were formed in vivo. In addition, the ATPase activities of the hybrid ATP synthase, measured in everted cytoplasmic membranes of an atpE mutant strain transformed with the atpH gene coding for CFo III, were comparable to activities obtained for the same mutant strain complemented with the atpE gene (EFo c). Nevertheless, CFo III was not able to replace EFo c functionally, since the strain containing the hybrid ATP synthase was not able to grow on succinate. In order to investigate the reason for this lack of function, hybrid proteolipids of CFo III and EFo c were constructed. Only a chimaeric protein comprising the seven N-terminal amino acid residues from CFo III and the remaining part of EFo c was able to replace wild-type EFo c, whereas hybrid proteins with 13 and 33 N-terminal amino acids of CFo III were not functional. The results suggested that a network of interactions between the subunits essential for proton translocation and/or coupling of the F1 part exists, which was optimized for each species during evolution, although the overall structure of FoF1 complexes has been conserved.

The F1 genes of the F1F0 ATP synthase from the acidophilic bacterium Thiobacillus ferrooxidans complement Escherichia coli F1 unc mutants

An atp gene cluster from the extreme acidophile Thiobacillus ferrooxidans was able to complement Escherichia coli F1 unc mutants for growth on minimal medium plus succinate. Complementation with all four E. coli F1 mutants tested was observed and subunits for the F1 portion of the T. ferrooxidans ATP synthase formed a functional association with the F0 subunits of the E. coli enzyme. In addition, a hybrid F1 enzyme in which some units were derived from E. coli and some from T. ferrooxidans was partially functional. No clones capable of complementing E. coli F0 unc mutants were isolated. The nucleotide sequence of the gene cluster was determined and the genes for the F0 and the F1 ATP synthase subunits were found to be physically linked.

Role of the delta subunit in enhancing proton conduction through the F0 of the Escherichia coli F1F0 ATPase

We studied the effect of the delta subunit of the Escherichia coli F1 ATPase on the proton permeability of the F0 proton channel synthesized and assembled in vivo. Membranes isolated from an unc deletion strain carrying a plasmid containing the genes for the F0 subunits and the delta subunit were significantly more permeable to protons than membranes isolated from the same strain carrying a plasmid containing the genes for the F0 subunits alone. This increased proton permeability could be blocked by treatment with either dicyclohexyl-carbodiimide or purified F1, both of which block proton conduction through the F0. After reconstitution with purified F1 in vitro, both membrane preparations could couple proton pumping to ATP hydrolysis. These results demonstrate that an interaction between the delta subunit and the F0 during synthesis and assembly produces a significant change in the proton permeability of the F0 proton channel.

Complementation of an Enterococcus hirae (Streptococcus faecalis) mutant in the alpha subunit of the H(+)-ATPase by cloned genes from the same and different species

We isolated an Enterococcus hirae (formerly Streptococcus faecalis) mutant, designated MS117, in which 'G' at position 301 of the alpha-subunit gene of the F1F0 type of H(+)-ATPase was deleted. MS117 had low H(+)-ATPase activity, was deficient in the regulatory system of cytoplasmic pH, and was unable to grow at pH 6.0. When the alpha-subunit gene of E. hirae H(+)-ATPase was ligated with the shuttle vector pHY300PLK at the downstream region of the tet gene of the vector, it was expressed without its own promoter in MS117, and the mutation of MS117 was complemented; the mutant harbouring the plasmid had the ability to maintain a neutral cytoplasm and grew at pH 6.0. We next transformed MS117 with pHY300PLK containing the alpha-subunit gene of Bacillus megaterium F1F0-ATPase constructed in the same way. The transformant grew at pH 6.0, and the ATP hydrolysis activity was recovered. These results suggested that an active hybrid H(+)-ATPase containing the B. megaterium alpha subunit was produced, and that the hybrid enzyme regulated the enterococcal cytoplasmic pH, although the function of the B. megaterium enzyme did not include pH regulation. Thus, our present results support the previous proposal that the enterococcal cytoplasmic pH is regulated by the F1F0 type of H(+)-ATPase.

Effects of inducing expression of cloned genes for the F0 proton channel of the Escherichia coli F1F0 ATPase

To evaluate whether expression of cloned genes for the F0 proton channel of the Escherichia coli F1F0 ATPase is sufficient to cause membrane proton permeability, plasmids carrying different combinations of the uncB, E, and F genes, encoding the a, c, and b subunits of the F0 sector, cloned behind the inducible lac promoter in pUC9 or pUC18, were constructed. The effects of inducing F0 synthesis in an unc deletion strain were monitored by measuring cell growth rate, quantitating F0 subunits by immunoblotting, and measuring the ability of membranes to maintain a respiration-induced proton gradient and to bind F1 and carry out energy-coupling reactions. The levels of functional reconstitutable F0 in membranes could be increased four- to sixfold with no change in cellular growth rate or membrane proton permeability (assayed by fluorescence quenching). These results were obtained in uninduced cultures, so the F0 genes were presumably being transcribed from some promoter besides lac. Induction of transcription of all three F0 genes produced increased amounts of F0 subunits in membranes as determined by immunoblot and F1-binding assays, but, when reconstituted with F1, the F0 in membranes isolated from induced cultures was significantly less functional than the F0 in membranes isolated from uninduced cultures. Such induction did result in growth inhibition, but there was no correlation between growth inhibition and either increased membrane proton permeability or the presence of functional, reconstitutable F0.