Evolutionary relationships among the permease proteins of the bacterial phosphoenolpyruvate: Sugar phosphotransferase system. Construction of phylogenetic trees and possible relatedness to proteins of eukaryotic mitochondria

Summary The amino acid sequences of 15 sugar permeases of the bacterial phosphoenolpyruvatedependent phosphotransferase system (PTS) were divided into four homologous segments, and these segments were analyzed to give phylogenetic trees. The permease segments fell into four clusters: the lactose-cellobiose cluster, the fructose-mannitol cluster, the glucose-N-acetylglucosamine cluster, and the sucrose--glucoside cluster. Sequences of the glucitol and mannose permeases (clusters 5 and 6, respectively) were too dissimilar to establish homology with the other permeases, but short regions of statistically significant sequence similarities were noted. The functional and structural relationships of these permease segments are discussed.Some of the homologous PTS permeases were found to exhibit sufficient sequence similarity to subunits 4 and 5 of the eukaryotic mitochondrial NADH dehydrogenase complex to suggest homology. Moreover, subunits 4 and 5 of this complex appeared to be homologous to each other, suggesting that these PTS and mitochondrial proteins comprise a superfamily. The integral membrane subunits of the evolutionarily divergent mannose PTS permease, the P and M subunits, exhibited limited sequence similarity to subunit 6 of the mitochondrial F₁F₀-ATPase and subunit 5b of cytochrome oxidase, respectively. These results suggest that PTS sugar permeases and mitochondrial proton-translocating proteins may be related, although the possibility of convergent evolution cannot be ruled out.     

The levanase operon of Bacillus subtilis expressed in Escherichia coli can substitute for the mannose permease in mannose uptake and bacteriophage lambda infection.

Bacteriophage lambda adsorbs to its Escherichia coli K-12 host by interacting with LamB, a maltose- and maltodextrin-specific porin of the outer membrane. LamB also serves as a receptor for several other bacteriophages. Lambda DNA requires, in addition to LamB, the presence of two bacterial cytoplasmic integral membrane proteins for penetration, namely, the IIC(Man) and IID(Man) proteins of the E. coli mannose transporter, a member of the sugar-specific phosphoenolpyruvate:sugar phosphotransferase system (PTS). The PTS transporters for mannose of E. coli, for fructose of Bacillus subtilis, and for sorbose of Klebsiella pneumoniae were shown to be highly similar to each other but significantly different from other PTS transporters. These three enzyme II complexes are the only ones to possess distinct IIC and IID transmembrane proteins. In the present work, we show that the fructose-specific permease encoded by the levanase operon of B. subtilis is inducible by mannose and allows mannose uptake in B. subtilis as well as in E. coli. Moreover, we show that the B. subtilis permease can substitute for the E. coli mannose permease cytoplasmic membrane components for phage lambda infection. In contrast, a series of other bacteriophages, also using the LamB protein as a cell surface receptor, do not require the mannose transporter for infection.     

Mannose permease of Escherichia coli. Domain structure and function of the phosphorylating subunit

The mannose permease of Escherichia coli is a component of the phosphotransferase system. It transports mannose and related hexoses by a mechanism that couples sugar transport with sugar phosphorylation. It is a complex consisting of two transmembrane subunits (II-PMan and II-MMan) and a hydrophilic subunit (IIIMan). IIIMan also exists in a soluble form as dimer in the cytoplasm. Each monomer of IIIMan consists of two structurally and functionally distinct domains which are linked by a flexible hinge of the sequence KAAPAPAAAAPKAAPTPAKP. Both domains are transiently phosphorylated. The NH2-terminal domain (P13) is phosphorylated at N-3 of His-10 by the cytoplasmic phosphorylcarrier protein phospho-HPr. The COOH-terminal domain (P20) is phosphorylated by P13 at N-1 of His-175. Phosphoryltransfer occurs not only between P13 and P20 on the same IIIMan subunit but also between isolated domains and between domains on different subunits of the dimer. In the presence of the IIMan subunits, the phosphoryl group is directly transferred from His-175 of P20 to the sugar substrates of the permease. The P13 domain contains the contact sites for dimerization of IIIMan. The P20 domain contains the contact sites for interaction with the IIMan subunits. By reconstructing the ptsL gene, the two domains were expressed as individual polypeptides and the length of the hinge between P13 and P20 was changed. The in vivo and in vitro activities of mutant IIIMan were little affected by these modifications. The hinge is highly sensitive to proteolytic cleavage in vitro and its specificity for proteases can be modified by introducing the appropriate specificity determinants.     

Enzymes II of the phosphotransferase system do not catalyze sugar transport in the absence of phosphorylation.

In Salmonella typhimurium, glucose, mannose, and fructose are normally transported and phosphorylated by the phosphoenolpyruvate:sugar phosphotransferase system. We have investigated the transport of these sugars and their non-metabolizable analogs in mutant strains lacking the phospho-carrier proteins of the phosphoenolpyruvate:sugar phosphotransferase system, the enzymes I and HPr, to determine whether the sugar-specific, membrane-bound components of the phosphonenolpyruvate: sugar phosphotransferase system, the enzymes II, can catalyze the uptake of these sugars in the absence of phosphorylation. This process does not occur. We have also isolated mutant strains which lack enzyme I and HPr, but have regained the ability to grow on mannose or fructose. These mutants contained elevated levels of mannokinase (fructokinase). In addition, growth on mannose required constitutive synthesis of the galactose permease. When strains were constructed which lacked the galactose permease, they were unable to grow even on high concentrations of mannose, although elevated levels of mannokinase (fructokinase) were present. These results substantiate the conclusion that the enzymes II of the phosphoenolpyruvate:sugar phosphotransferase system are unable to carry out facilitated diffusion.     

Size and shape of the Escherichia coli lactose permease measured in filamentous arrays

The Escherichia coli lactose permease has been purified on cation exchanger to contain a minimal amount of phospholipids, i.e., 4-5 mol/mol of permease, in the presence of the detergent dodecyl beta-maltoside at its critical micelle concentration. This preparation is active in galactoside binding. When the detergent level is further reduced by dialysis, the lactose permease forms filaments one molecule wide and up to several micrometers long. The filaments tend to associate laterally to form sheets. Analysis of electron micrographs of negatively stained filamentous arrays indicates an average filament spacing of 51 A and a subunit period of 26-30 A along individual filaments. These values most probably correspond to the dimensions of the lactose permease molecule measured parallel to the membrane plane. In many filaments, the subunits show a stain-penetrated cleft. It suggests that the lactose permease molecule comprises two domains, which may be correlated with internal repeats between the N- and C-terminal halves of the polypeptide sequence.     

Membrane insertion of uracil permease, a polytopic yeast plasma membrane protein.

Uracil permease is a multispanning protein of the Saccharomyces cerevisiae plasma membrane which is encoded by the FUR4 gene and produced in limited amounts. It has a long N-terminal hydrophilic segment, which is followed by 10 to 12 putative transmembrane segments, and a hydrophilic C terminus. The protein carries seven potential N-linked glycosylation sites, three of which are in its N-terminal segment. Overexpression of this permease and specific antibodies were used to show that uracil permease undergoes neither N-linked glycosylation nor proteolytic processing. Uracil permease N-terminal segments of increasing lengths were fused to a reporter glycoprotein, acid phosphatase. The in vitro and in vivo fates of the resulting hybrid proteins were analyzed to identify the first signal anchor sequence of the permease and demonstrate the cytosolic orientation of its N-terminal hydrophilic sequence. In vivo insertion of the hybrid protein bearing the first signal anchor sequence of uracil permease into the endoplasmic reticulum membrane was severely blocked in sec61 and sec62 translocation mutants.     

A simple way for sequential assignment in isotopically enriched proteins using a H(N)CACO correlation

Summary A simplified scheme for sequential assignment in isotopically enriched proteins is presented. It is based on the standard triple resonance experiments HNCO, HN(CO)CA, HNCA and a modified H(N)CACO correlation, in which both of the H^N connectivities to the CA/C pair of residue i and i-1 are observed. The H(N)CACO was tested on uniformly ¹³C/¹⁵N enriched P13 domain of mannose permease (31 kDa).     

Fructose catabolism in Xanthomonas campestris pv. campestris. Sequence of the PTS operon, characterization of the fructose-specific enzymes.

In Xanthomonas campestris pv. campestris, fructose is transported and phosphorylated into fructose 1-phosphate through a phosphoenolpyruvate-dependent phosphotransferase system. The nucleotide sequence of the fruA gene encoding the phosphotransferase system permease specific of fructose (EIIFru) was determined. The fructose 1-phosphate produced by the phosphotransferase system is phosphorylated into fructose 1,6-bisphosphate by a 1-phosphofructokinase. This enzyme was characterized and the corresponding gene (fruK) was sequenced. Sequence comparisons revealed that FruK is a member of a new family of ATP-binding proteins composed of sugar (or sugar-phosphate) kinases. In phosphotransferase system-deficient strains, fructose can still be transported by an unidentified permease. The intracellular fructose is then phosphorylated by a multimeric fructokinase of 135 kDa specific for fructose and inhibited by fructose, fructose 1,6-bisphosphate, and mannose. Several other enzymes of fructose metabolism were assayed and a potential pathway for fructose catabolism is presented.     

Isolation and biochemical characterization of the subunits of the rabbit sperm acrosome stabilizing factor

The rabbit Acrosome Stabilizing Factor (ASF) is a glycoprotein synthesized in the corpus epididymis that demonstrates the ability to reversibly decapacitate sperm. Separation of the molecule into its individual subunits (92,000 Da and 38,000 Da) was accomplished via electroelution from polyacrylamide gels or via gel filtration on a Sephadex G-200 column in the presence of 0.1% sodium dodecyl sulfate. Column separation of the subunits revealed an entity of low molecular mass (500 daltons) associated with the ASF molecule. Amino acid compositional analysis of the subunits revealed the lack of cysteine and high glycine in the small subunit (38,000 Da) and high proline and glycine in the large subunit (92,000 Da). Lysine and aspartic acid were identified as the N-terminal amino acids for the large and small subunits, respectively. Identification of a 20 amino acid N-terminal sequence was accomplished for both of the subunits. Carbohydrate compositional analysis demonstrated that the small subunit contained N-asparagine-linked high mannose sugar chains while the large subunit contained N-asparagine-linked complex sugar chains. Endoglycosidase-H and N-Glycanase treatment of ASF indicated that the small subunit appears to contain four high mannose chains and the large subunit contains three complex chains.     

NatC Nalpha-terminal acetyltransferase of yeast contains three subunits, Mak3p, Mak10p, and Mak31p

The yeast Saccharomyces cerevisiae contains three types of N(alpha)-terminal acetyltransferases, NatA, NatB, and NatC, with each having a different catalytic subunit, Ard1p, Nat3p, and Mak3p, respectively, and each acetylating different sets of proteins with different N(alpha)-terminal regions. We show that the NatC N(alpha)-terminal acetyltransferases contains Mak10p and Mak31p subunits, in addition to Mak3p, and that all three subunits are associated with each other to form the active complex. Genetic deletion of any one of the three subunits results in identical abnormal phenotypes, including the lack of acetylation of a NatC substrate in vivo, diminished growth at 37 degrees C on media containing nonfermentable carbon sources, and the lack of maintenance or assembly of the L-A dsRNA viral particle.     

A topological model for the general aromatic amino acid permease, AroP, of Escherichia coli.

The general aromatic amino acid permease, AroP, of Escherichia coli is responsible for the active transport of phenylalanine, tyrosine, and tryptophan. A proposed topological model for the AroP permease, consisting of 12 hydrophobic transmembrane spans connected by hydrophilic loops, is very similar to that of the closely related phenylalanine-specific permease. The validity of this model and its similarity to that of the PheP permease were investigated by studying fusion proteins of AroP permease and alkaline phosphatase. Based on the results obtained from the AroP-alkaline phosphatase sandwich fusions, we have significantly revised the proposed topological model for AroP in two regions. In this modified AroP topological model, the three charged residues E151, E153, and K160 are repositioned within the membrane in span 5. These three residues are conserved in a large family of amino acid transport proteins, and site-directed mutagenesis identifies them as being essential for transport activity. It is postulated that these residues together with E110 in transmembrane span 3 may be involved in a proton relay system.     

A family of glutamate receptor genes: evidence for the formation of heteromultimeric receptors with distinct channel properties.

We have isolated two cDNA clones (GluR-K2 and GluR-K3) that share considerable sequence identity with the previously described glutamate receptor subunit, GluR-K1. The three glutamate receptor subunits show significant sequence conservation with the glutamine binding component of the glutamine permease of E. coli. Each of these clones encodes a channel responsive to both kainate and AMPA. The coexpression of GluR-K2 with either GluR-K3 or GluR-K1 results in the formation of channels whose current-voltage relationships differ from those of the individual subunits alone and more closely approximate the properties of kainate receptors in neurons. These observations indicate that the kainate/quisqualate receptors are encoded by a family of genes and are likely to be composed of hetero-oligomers of at least two distinct subunits.     

Characterization of the oligosaccharides of prolyl hydroxylase, a microsomal glycoprotein

Prolyl hydroxylase is a tetrameric glycoprotein that catalyzes a vital posttranslational modification in the biosynthesis of collagen. The enzyme purified from whole chick embryos (WCE) possesses two nonidentical subunits, alpha and beta, and has been shown by several techniques to reside in the endoplasmic reticulum of chick embryo fibroblasts. The studies described here demonstrate that the larger of the two subunits (alpha) exists in two forms in chick embryo fibroblasts (CEF); these two forms differ in carbohydrate content. The larger alpha subunit, alpha', contains two N-linked high mannose oligosaccharides, each containing eight mannose units; the smaller subunit, alpha, contains a single seven-mannose N-linked oligosaccharide. Both oligosaccharides could be cleaved by endo-beta-N-acetylglucosaminidase H and completely digested with alpha-mannosidase to yield mannosyl-N-acetylglucosamine.     

Chemolithoorganotrophic growth of Nitrosomonas europaea on fructose

The nitrifying bacterium Nitrosomonas europaea can obtain all its carbon for growth from CO(2) and all its energy and reductant for growth from the oxidation of NH(3) and is considered an obligate chemolithoautotroph. Previous studies have shown that N. europaea can utilize limited amounts of certain organic compounds, including amino acids, pyruvate, and acetate, although no organic compound has been reported to support the growth of N. europaea. The recently completed genomic sequence of N. europaea revealed a potential permease for fructose. With this in mind, we tested if N. europaea could utilize fructose and other compounds as carbon sources to support growth. Cultures were incubated in the presence of fructose or other organic compounds in sealed bottles purged of CO(2). In these cultures, addition of either fructose or pyruvate as the sole carbon source resulted in a two- to threefold increase in optical density and protein content in 3 to 4 days. Studies with [(14)C]fructose showed that >90% of the carbon incorporated by the cells during growth was derived from fructose. Cultures containing mannose, glucose, glycerol, mannitol, citrate, or acetate showed little or no growth. N. europaea was not able to grow with fructose as an energy source, although the presence of fructose did provide an energy benefit to the cells. These results show that N. europaea can be grown in CO(2)-free medium by using fructose and pyruvate as carbon sources and may now be considered a facultative chemolithoorganotroph.     

Biosynthesis and maturation of the Lyt-2/3 molecular complex in mouse thymocytes

The biosynthesis and maturation of the three subunits alpha (Mr = 37,000), beta (Mr = 32,000), and gamma (Mr = 27,000) of the mouse Lyt-2/3 antigenic complex have been studied by using two monoclonal antibodies directed against a monomorphic determinant of the Lyt-2 antigen. Short time-pulse labeling of thymocytes reveals three different high mannose intermediates that give rise upon endo-beta-N-acetyl-glucosaminidase H digestion to three distinct precursor polypeptides of Mr = 22,000 (alpha P), Mr = 18,000 (beta P), and Mr = 19,500 (gamma P). Pulse-chase analysis indicates rapid posttranslational processing, because mature forms already appear after 10 min of chase. The half-life of the endo-H-sensitive early forms are in the range of 20 to 30 min. Both the alpha and beta subunits are suggested to contain three N-asparagine-linked oligosaccharides, one of which is of the high mannose type. In contrast, the gamma-chain contains only one such glycan unit of the complex type. Moreover, the results presented show that all three chains undergo additional posttranslational modifications. Finally, the data suggest that the cytoplasmic domains of these chains are of different size.     

Substrate selectivity of YgfU, a uric acid transporter from Escherichia coli

The ubiquitous nucleobase-ascorbate transporter (NAT/NCS2) family includes more than 2,000 members, but only 15 have been characterized experimentally. Escherichia coli has 10 members, of which the uracil permease UraA and the xanthine permeases XanQ and XanP are functionally known. Of the remaining members, YgfU is closely related in sequence and genomic locus with XanQ. We analyzed YgfU and showed that it is a proton-gradient dependent, low-affinity (K(m) 0.5 mM), and high-capacity transporter for uric acid. It also shows a low capacity for transport of xanthine at 37 °C but not at 25 °C. Based on the set of positions delineated as important from our previous Cys-scanning analysis of permease XanQ, we subjected YgfU to rationally designed site-directed mutagenesis. The results show that the conserved His-37 (TM1), Glu-270 (TM8), Asp-298 (TM9), and Gln-318 and Asn-319 (TM10) are functionally irreplaceable, and Thr-100 (TM3) is essential for the uric acid selectivity because its replacement with Ala allows efficient uptake of xanthine. The key role of these residues is corroborated by the conservation pattern and homology modeling on the recently described x-ray structure of permease UraA. In addition, site-specific replacements at TM8 (S271A, M274D, V282S) impair expression in the membrane, and V320N (TM10) inactivates the permease, whereas R327G (TM10) or S426N (TM14) reduces the affinity for uric acid (4-fold increased K(m)). Our study shows that comprehensive analysis of structure-function relationships in a newly characterized transporter can be accomplished with relatively few site-directed replacements, based on the knowledge available from Cys-scanning mutagenesis of a prototypic homolog.