Fictive rhythmic motor patterns produced by the tail spinal cord in salamanders.

Most investigations into the role of the body axis in vertebrate locomotion have focused on the trunk, although in most tetrapods, the tail also plays an active role. In salamanders, the tail contributes to propulsion during swimming and to dynamic balance and maneuverability during terrestrial locomotion. The aim of the present study was to obtain information concerning the neural mechanisms that produce tail muscle contractions during locomotion in the salamander Pleurodeles waltlii. We recorded the ventral root activities in in vitro spinal cord preparations in which locomotor-like activity was induced via bath application of N-methyl-d-aspartate (20µM) and d-serine (10µM). Recordings showed that the tail spinal cord is capable of producing propagated waves of motor activity that alternate between the left and right sides. Lesion experiments further revealed that the tail rhythmogenic network is composed of a double chain of identical hemisegmental oscillators. Finally, using spinal cord preparations bathed in a chamber partitioned into two pools, we revealed efficient short-distance coupling between the trunk and tail networks. Together, our results demonstrate the existence of a pattern generator for rhythmic tail movements in the salamander and show that the global architecture of the tail network is similar to that previously proposed for the mid-trunk locomotor network in the salamander. Our findings further support the view that salamanders can control their trunk and tail independently during stepping movements. The relevance of our results in relation to the generation of tail muscle contractions in freely moving salamanders is discussed.

Crystal structures of two human pyrophosphorylase isoforms in complexes with UDPGlc(Gal)NAc: role of the alternatively spliced insert in the enzyme oligomeric assembly and active site architecture.

The recently published human genome with its relatively modest number of genes has highlighted the importance of post-transcriptional and post-translational modifications, such as alternative splicing or glycosylation, in generating the complexities of human biology. The human UDP-N-acetylglucosamine (UDPGlcNAc) pyrophosphorylases AGX1 and AGX2, which differ in sequence by an alternatively spliced 17 residue peptide, are key enzymes synthesizing UDPGlcNAc, an essential precursor for protein glycosylation. To better understand the catalytic mechanism of these enzymes and the role of the alternatively spliced segment, we have solved the crystal structures of AGX1 and AGX2 in complexes with UDPGlcNAc (at 1.9 and 2.4 A resolution, respectively) and UDPGalNAc (at 2.2 and 2.3 A resolution, respectively). Comparison with known structures classifies AGX1 and AGX2 as two new members of the SpsA-GnT I Core superfamily and, together with mutagenesis analysis, helps identify residues critical for catalysis. Most importantly, our combined structural and biochemical data provide evidence for a change in the oligomeric assembly accompanied by a significant modification of the active site architecture, a result suggesting that the two isoforms generated by alternative splicing may have distinct catalytic properties.

Limited proteolysis as a structural probe of the soluble alpha-glycerophosphate oxidase from Streptococcus sp.

As reported previously [Parsonage, D., Luba, J., Mallett, T. C., and Claiborne, A. (1998) J. Biol. Chem. 273, 23812-23822], the flavoprotein alpha-glycerophosphate oxidases (GlpOs) from a number of enterococcal and streptococcal sources contain a conserved 50-52 residue insert that is completely absent in the homologous alpha-glycerophosphate dehydrogenases. On limited proteolysis with trypsin, the GlpO from Streptococcus sp. (m = 67.6 kDa) is readily converted to two major fragments corresponding to masses of approximately 40 and 23 kDa. The combined application of sequence and mass spectrometric analyses demonstrates that the 40-kDa fragment represents the N-terminus of intact GlpO (Met1-Lys368; 40.5 kDa), while the 23-kDa band represents a C-terminal fragment (Ala405-Lys607; 22.9 kDa). Hence, limited proteolysis in effect excises most of the GlpO insert (Ser355-Lys404), indicating that this represents a flexible region on the protein surface. The active-site and other spectroscopic properties of the enzyme, including both flavin and tryptophan fluorescence spectra, titration behavior with both dithionite and sulfite, and preferential binding of the anionic form of the oxidized flavin, were largely unaffected by proteolysis. Enzyme-monitored turnover analyses of the intact and nicked streptococcal GlpOs (at [GlpO] approximately 10 microM) demonstrate that the single major catalytic defect in the nicked enzyme corresponds to a 20-fold increase in K(m)(Glp); the basis for this altered kinetic behavior is derived from an 8-fold decrease in the second-order rate constant for reduction of the nicked enzyme, as measured in anaerobic stopped-flow experiments. These results indicate that the flexible surface region represented by elements of the GlpO insert plays an important role in mediating efficient flavin reduction.

Protein-sulfenic acids: diverse roles for an unlikely player in enzyme catalysis and redox regulation.

While it has been known for more than 20 years that unusually stable cysteine-sulfenic acid (Cys-SOH) derivatives can be introduced in selected proteins by mild oxidation, only recently have chemical and crystallographic evidence for functional Cys-SOH been presented with native proteins such as NADH peroxidase and NADH oxidase, nitrile hydratase, and the hORF6 and AhpC peroxiredoxins. In addition, Cys-SOH forms of protein tyrosine phosphatases and glutathione reductase have been suggested to play key roles in the reversible inhibition of these enzymes during tyrosine phosphorylation-dependent signal transduction events and nitrosative stress, respectively. Substantial chemical data have also been presented which implicate Cys-SOH in redox regulation of transcription factors such as Fos and Jun (activator protein-1) and bovine papillomavirus-1 E2 protein. Functionally, the Cys-SOHs in NADH peroxidase, NADH oxidase, and the peroxiredoxins serve as either catalytically essential redox centers or transient intermediates during peroxide reduction. In nitrile hydratase, the active-site Cys-SOH functions in both iron coordination and NO binding but does not play any catalytic redox role. In Fos and Jun and the E2 protein, on the other hand, a key Cys-SH serves as a sensor for intracellular redox status; reversible oxidation to Cys-SOH as proposed inhibits the corresponding DNA binding activity. These functional Cys-SOHs have roles in diverse cellular processes, including signal transduction, oxygen metabolism and the oxidative stress response, and transcriptional regulation, as well as in the industrial production of acrylamide, and their detailed analyses are beginning to provide the chemical foundation necessary for understanding protein-SOH stabilization and function.

Coenzyme A-disulfide reductase from Staphylococcus aureus: evidence for asymmetric behavior on interaction with pyridine nucleotides.

An unusual flavoprotein disulfide reductase, which catalyzes the NADPH-dependent reduction of CoASSCoA, has recently been purified from the human pathogen Staphylococcus aureus [delCardayré, S. B., Stock, K. P., Newton, G. L., Fahey, R. C., and Davies, J. E. (1998) J. Biol. Chem. 273, 5744-5751]. Coenzyme A-disulfide reductase (CoADR) lacks the redox-active protein disulfide characteristic of the disulfide reductases; instead, NADPH reduction yields 1 protein-SH and 1 CoASH. Furthermore, the CoADR sequence reveals the presence of a single putative active-site Cys (Cys43) within an SFXXC motif also seen in the Enterococcus faecalis NADH oxidase and NADH peroxidase, which use a single redox-active cysteine-sulfenic acid in catalysis. In this report, we provide a detailed examination of the equilibrium properties of both wild-type and C43S CoADRs, focusing on the role of Cys43 in the catalytic redox cycle, the behavior of both enzyme forms on reduction with dithionite and NADPH, and the interaction of NADP+ with the corresponding reduced enzyme species. The results of these analyses, combined with electrospray mass spectrometric data for the two oxidized enzyme forms, fully support the catalytic redox role proposed for Cys43 and confirm that this is the attachment site for bound CoASH. In addition, we provide evidence indicating dramatic thermodynamic inequivalence between the two active sites per dimer, similar to that documented for the related enzymes mercuric reductase and NADH oxidase; only 1 FAD is reduced with NADPH in wild-type CoADR. The EH2.NADPH/EH4.NADP+ complex which results is reoxidized quantitatively in titrations with CoASSCoA, supporting a possible role for the asymmetric reduced dimer in catalysis.

Antagonistic effects of dual PTS-catalysed phosphorylation on the Bacillus subtilis transcriptional activator LevR.

LevR, which controls the expression of the levoperon of Bacillus subtilis, is a regulatory protein containing an N-terminal domain similar to the NifA/NtrC transcriptional activator family and a C-terminal domain similar to the regulatory part of bacterial anti-terminators, such as BgIG and LicT. Here, we demonstrate that the activity of LevR is regulated by two phosphoenolpyruvate (PEP)-dependent phosphorylation reactions catalysed by the phosphotransferase system (PTS), a transport system for sugars, polyols and other sugar derivatives. The two general components of the PTS, enzyme I and HPr, and the two soluble, sugar-specific proteins of the lev-PTS, LevD and LevE, form a signal transduction chain allowing the PEP-dependent phosphorylation of LevR, presumably at His-869. This phosphorylation seems to inhibit LevR activity and probably regulates the induction of the lev operon. Mutants in which His-869 of LevR has been replaced with a non-phosphorylatable alanine residue exhibited constitutive expression from the lev promoter, as do levD or levE mutants. In contrast, PEP-dependent phosphorylation of LevR in the presence of only the general components of the PTS, enzyme I and HPr, regulates LevR activity positively. This phosphorylation most probably occurs at His-585. Mutants in which His-585 has been replaced with an alanine had lost stimulation of LevR activity and PEP-dependent phosphorylation by enzyme I and HPr. This second phosphorylation of LevR at His-585 is presumed to play a role in carbon catabolite repression.

Cloning and sequencing of two enterococcal glpK genes and regulation of the encoded glycerol kinases by phosphoenolpyruvate-dependent, phosphotransferase system-catalyzed phosphorylation of a single histidyl residue.

The glpK genes of Enterococcus casseliflavus and Enterococcus faecalis, encoding glycerol kinase, the key enzyme of glycerol uptake and metabolism in bacteria, have been cloned and sequenced. The translated amino acid sequences exhibit strong homology to the amino acid sequences of other bacterial glycerol kinases. After expression of the enterococcal glpK genes in Escherichia coli, both glycerol kinases were purified and were found to be phosphorylated by enzyme I and the histidine-containing protein of the phosphoenolpyruvate:glycose phosphotransferase system. Phosphoenolpyruvate-dependent phosphorylation caused a 9-fold increase in enzyme activity. The site of phosphorylation in glycerol kinase of E. casseliflavus was determined as His-232. Site-specific mutagenesis was used to replace His-232 in glycerol kinase of E. casseliflavus with an alanyl, glutamate, or arginyl residue. The mutant proteins could no longer be phosphorylated confirming that His-232 of E. casseliflavus glycerol kinase represents the site of phosphorylation. The His232 --> Arg glycerol kinase exhibited an about 3-fold elevated activity compared with wild-type glycerol kinase. Fructose 1,6-bisphosphate was found to inhibit E. casseliflavus glycerol kinase activity. However, neither EIIAGlc from E. coli nor the EIIAGlc domain of Bacillus subtilis had an inhibitory effect on glycerol kinase of E. casseliflavus.

Protein phosphorylation chain of a Bacillus subtilis fructose-specific phosphotransferase system and its participation in regulation of the expression of the lev operon.

The proteins encoded by the fructose-inducible lev operon of Bacillus subtilis are components of a phosphotransferase system. They transport fructose by a mechanism which couples sugar uptake and phosphoenolpyruvate-dependent sugar phosphorylation. The complex transport system consists of two integral membrane proteins (LevF and LevG) and two soluble, hydrophilic proteins (LevD and LevE). The two soluble proteins from together with the general proteins of the phosphotransferase system, enzyme I and HPr, a protein phosphorylation chain which serves to phosphorylate fructose transported by LevF and LevG. We have synthesized modified LevD and LevE by fusing a His-tag to the N-terminus of each protein allowing rapid and efficient purification of the proteins. We determined His-9 in LevD and His-15 in LevE as the sites of PEP-dependent phosphorylation by isolating single, labeled peptides derived from 32P-labeled LevD, LevD(His)6, and LevE(His)6. The labeled peptides were subsequently analyzed by amino acid sequencing and mass spectroscopy. Mutations replacing the phosphorylatable histidyl residue in LevD with an alanyl residue and in LevE with a glutamate or aspartate were introduced in the levD and levE genes. These mutations caused strongly reduced fructose uptake via the lev-PTS. The mutant proteins were synthesized with a N-terminal His-tag and purified. Mutant LevD(His)6 was very slowly phosphorylated, whereas mutant LevE(His)6 was not phosphorylated at all. The corresponding levD and levE alleles were incorporated into the chromosome of a B. subtilis strain expressing the lacZ gene under control of the lev promoter. The mutations affecting the site of phosphorylation in either LevD or LevE were found to cause constitutive expression from the lev promoter of B. subtilis.

Regulation of carbon metabolism in gram-positive bacteria by protein phosphorylation.

The main function of the bacterial phosphotransferase system is to transport and to phosphorylate mono- and disaccharides as well as sugar alcohols. However, the phosphotransferase system is also involved in regulation of carbon metabolism. In Gram-positive bacteria, it is implicated in carbon catabolite repression and regulation of expression of catabolic genes by controlling either catabolic enzyme activities, transcriptional activators or antiterminators. All these different regulations follow a protein phosphorylation mechanism.

The HPr protein of the phosphotransferase system links induction and catabolite repression of the Bacillus subtilis levanase operon.

The LevR protein is the activator of expression of the levanase operon of Bacillus subtilis. The promoter of this operon is recognized by RNA polymerase containing the sigma 54-like factor sigma L. One domain of the LevR protein is homologous to activators of the NtrC family, and another resembles antiterminator proteins of the BglG family. It has been proposed that the domain which is similar to antiterminators is a target of phosphoenolpyruvate:sugar phosphotransferase system (PTS)-dependent regulation of LevR activity. We show that the LevR protein is not only negatively regulated by the fructose-specific enzyme IIA/B of the phosphotransferase system encoded by the levanase operon (lev-PTS) but also positively controlled by the histidine-containing phosphocarrier protein (HPr) of the PTS. This second type of control of LevR activity depends on phosphoenolpyruvate-dependent phosphorylation of HPr histidine 15, as demonstrated with point mutations in the ptsH gene encoding HPr. In vitro phosphorylation of partially purified LevR was obtained in the presence of phosphoenolpyruvate, enzyme I, and HPr. The dependence of truncated LevR polypeptides on stimulation by HPr indicated that the domain homologous to antiterminators is the target of HPr-dependent regulation of LevR activity. This domain appears to be duplicated in the LevR protein. The first antiterminator-like domain seems to be the target of enzyme I and HPr-dependent phosphorylation and the site of LevR activation, whereas the carboxy-terminal antiterminator-like domain could be the target for negative regulation by the lev-PTS.