YjeQ, an essential, conserved, uncharacterized protein from Escherichia coli, is an unusual GTPase with circularly permuted G-motifs and marked burst kinetics

The GTPase, CpgA(YloQ), a putative translation factor, is implicated in morphogenesis in Bacillus subtilis

YloQ, from Bacillus subtilis, was identified previously as an essential nucleotide-binding protein of unknown function. YloQ was successfully over-expressed in Escherichia coli in soluble form. The purified protein displayed a low GTPase activity similar to that of other small bacterial GTPases such as Bex/Era. Based on the demonstrated GTPase activity and the unusual order of the yloQ G motifs, we now designate this protein as CpgA (circularly permuted GTPase). An unexpected property of this low abundance GTPase was the demonstration, using gel filtration and ultracentrifugation analysis, that the protein formed stable dimers, dependent upon the concentration of YloQ(CpgA), but independent of GTP. In order to investigate function, cpgA was placed under the control of the pspac promotor in the B. subtilis chromosome. When grown in E or Spizizen medium in the absence of IPTG, the rate of growth was significantly reduced. A large proportion of the cells exhibited a markedly perturbed morphology, with the formation of swollen, bent or 'curly' shapes. To confirm that this was specifically due to depleted CpgA a plasmid-borne cpgA under pxyl control was introduced. This restored normal cell shape and growth rate, even in the absence of IPTG, provided xylose was present. The crystal structure of CpgA(YloQ) suggests a role as a translation initiation factor and we discuss the possibility that CpgA is involved in the translation of a subset of proteins, including some required for shape maintenance.

Biochemical properties of the Vibrio harveyi CgtAV GTPase

Bacteria encode a number of relatively poorly characterized GTPases, including the essential, ribosome-associated Obg/CgtA proteins. In contrast to Ras-like proteins, it appears that the Obg/CgtA proteins bind guanine nucleotides with modest affinity and hydrolyze GTP relatively slowly. We show here that the Vibrio harveyi CgtA(V) exchanges guanine nucleotides rapidly and has a modest affinity for nucleotides, suggesting that these features are a universal property of the Obg/CgtA family. Interestingly, CgtA(V) possesses a significantly more rapid GTP hydrolysis rate than is typical of other family members, perhaps reflecting the diversity and specificity of bacterial ecological niches.

Characterization of the Bacillus subtilis GTPase YloQ and its role in ribosome function

We present an analysis of the cellular phenotype and biochemical activity of a conserved bacterial GTPase of unknown function (YloQ and YjeQ in Bacillus subtilis and Escherichia coli respectively) using a collection of antibiotics of diverse mechanisms and chemical classes. We created a yloQ deletion strain, which exhibited a slow growth phenotype and formed chains of filamentous cells. Additionally, we constructed a conditional mutant in yloQ, where growth was dependent on inducible expression from a complementing copy of the gene. In phenotypic studies, depletion of yloQ sensitized cells to antibiotics that bind at the peptide channel or peptidyl transferase centre, providing the first chemical genetic evidence linking this GTPase to ribosome function. Additional experiments using these small-molecule probes in vitro revealed that aminoglycoside antibiotics severely affected a previously characterized ribosome-associated GTPase activity of purified, recombinant YjeQ from E. coli. None of the antibiotics tested competed with YjeQ for binding to 30 or 70 S ribosomes. A closer examination of YloQ depletion revealed that the polyribosome profiles were altered and that decreased expression of YloQ led to the accumulation of ribosomal subunits at the expense of intact 70 S ribosomes. The present study provides the first evidence showing that YloQ/YjeQ may be involved in several areas of cellular metabolism, including cell division and ribosome function.

The homologous putative GTPases Grn1p from fission yeast and the human GNL3L are required for growth and play a role in processing of nucleolar pre-rRNA

Grn1p from fission yeast and GNL3L from human cells, two putative GTPases from the novel HSR1_MMR1 GTP-binding protein subfamily with circularly permuted G-motifs play a critical role in maintaining normal cell growth. Deletion of Grn1 resulted in a severe growth defect, a marked reduction in mature rRNA species with a concomitant accumulation of the 35S pre-rRNA transcript, and failure to export the ribosomal protein Rpl25a from the nucleolus. Deleting any of the Grn1p G-domain motifs resulted in a null phenotype and nuclear/nucleolar localization consistent with the lack of nucleolar export of preribosomes accompanied by a distortion of nucleolar structure. Heterologous expression of GNL3L in a Deltagrn1 mutant restored processing of 35S pre-rRNA, nuclear export of Rpl25a and cell growth to wild-type levels. Genetic complementation in yeast and siRNA knockdown in HeLa cells confirmed the homologous proteins Grn1p and GNL3L are required for growth. Failure of two similar HSR1_MMR1 putative nucleolar GTPases, Nucleostemin (NS), or the dose-dependent response of breast tumor autoantigen NGP-1, to rescue deltagrn1 implied the highly specific roles of Grn1p or GNL3L in nucleolar events. Our analysis uncovers an important role for Grn1p/GNL3L within this unique group of nucleolar GTPases.

Human Lsg1 defines a family of essential GTPases that correlates with the evolution of compartmentalization

BACKGROUND

Compartmentalization is a key feature of eukaryotic cells, but its evolution remains poorly understood. GTPases are the oldest enzymes that use nucleotides as substrates and they participate in a wide range of cellular processes. Therefore, they are ideal tools for comparative genomic studies aimed at understanding how aspects of biological complexity such as cellular compartmentalization evolved.

RESULTS

We describe the identification and characterization of a unique family of circularly permuted GTPases represented by the human orthologue of yeast Lsg1p. We placed the members of this family in the phylogenetic context of the YlqF Related GTPase (YRG) family, which are present in Eukarya, Bacteria and Archea and include the stem cell regulator Nucleostemin. To extend the computational analysis, we showed that hLsg1 is an essential GTPase predominantly located in the endoplasmic reticulum and, in some cells, in Cajal bodies in the nucleus. Comparison of localization and siRNA datasets suggests that all members of the family are essential GTPases that have increased in number as the compartmentalization of the eukaryotic cell and the ribosome biogenesis pathway have evolved.

CONCLUSION

We propose a scenario, consistent with our data, for the evolution of this family: cytoplasmic components were first acquired, followed by nuclear components, and finally the mitochondrial and chloroplast elements were derived from different bacterial species, in parallel with the formation of the nucleolus and the specialization of nuclear components.

Transcriptional response reveals translation machinery as target for high pressure in Lactobacillus sanfranciscensis

The effect of sublethal hydrostatic pressure on the transcriptome of Lactobacillus sanfranciscensis was determined using a shot-gun-microarray. Among the 750 spots that passed quality analysis 42 genes were induced, while six were repressed when cells were incubated at 45 MPa for 30 min. The nature of genes and their differential expression clearly indicate cellular efforts to counteract a decrease in translational capacity. The majority of high pressure affected genes were found to encode either translation factors (EF-G, EF-TU), ribosomal proteins (S2, L6, L11), genes changing translational accuracy or molecular chaperones (GroEL, ClpL). These data agree with previously reported effects observed in in vitro studies as well as with physiological and proteomic data. This study provides in vivo evidence to identify ribosomes and impaired translation among primary targets for high pressure treatment. The observed induction of heat as well as cold shock genes (e.g. hsp60, gyrA) may be explained as a result of high pressure affected protein synthesis.

The Caulobacter crescentus GTPase CgtAC is required for progression through the cell cycle and for maintaining 50S ribosomal subunit levels

The Obg subfamily of bacterial GTP-binding proteins are biochemically distinct from Ras-like proteins raising the possibility that they are not controlled by conventional guanine nucleotide exchange factors (GEFs) and/or guanine nucleotide activating proteins (GAPs). To test this hypothesis, we generated mutations in the Caulobacter crescentus obg gene (cgtAC) which, in Ras-like proteins, would result in either activating or dominant negative phenotypes. In C. crescentus, a P168V mutant is not activating in vivo, although in vitro, the P168V protein showed a modest reduction in the affinity for GDP. Neither the S173N nor N280Y mutations resulted in a dominant negative phenotype. Furthermore, the S173N was significantly impaired for GTP binding, consistent with a critical role of this residue in GTP binding. In general, conserved amino acids in the GTP-binding pocket were, however, important for function. To examine the in vivo consequences of depleting CgtAC, we generated a temperature-sensitive mutant, G80E. At the permissive temperature, G80E cells grow slowly and have reduced levels of 50S ribosomal subunits, indicating that CgtAC is important for 50S assembly and/or stability. Surprisingly, at the non-permissive temperature, G80E cells rapidly lose viability and yet do not display an additional ribosome defect. Thus, the essential nature of the cgtAC gene does not appear to result from its ribosome function. G80E cells arrest as predivisional cells and stalkless cells. Flow cytometry on synchronized cells reveals a G1-S arrest. Therefore, CgtAC is necessary for DNA replication and progression through the cell cycle.

Release of the export adapter, Nmd3p, from the 60S ribosomal subunit requires Rpl10p and the cytoplasmic GTPase Lsg1p

In eukaryotes, nuclear export of the large (60S) ribosomal subunit requires the adapter protein Nmd3p to provide the nuclear export signal. Here, we show that in yeast release of Nmd3p from 60S subunits in the cytoplasm requires the ribosomal protein Rpl10p and the G-protein, Lsg1p. Mutations in LSG1 or RPL10 blocked Nmd3-GFP shuttling into the nucleus and export of pre-60S subunits from the nucleus. Overexpression of NMD3 alleviated the export defect, indicating that the block in 60S export in lsg1 and rpl10 mutants results indirectly from failing to recycle Nmd3p. The defect in Nmd3p recycling and the block in 60S export in both lsg1 and rpl10 mutants was also suppressed by mutant Nmd3 proteins that showed reduced binding to 60S subunits in vitro. We propose that the correct loading of Rpl10p into 60S subunits is required for the release of Nmd3p from subunits by Lsg1p. These results suggest a coupling between recycling the 60S export adapter and activation of 60S subunits for translation.

A novel GTPase activated by the small subunit of ribosome

The GTPase activity of Escherichia coli YjeQ, here named RsgA (ribosome small subunit-dependent GTPase A), has been shown to be significantly enhanced by ribosome or its small subunit. The enhancement of GTPase activity was inhibited by several aminoglycosides bound at the A site of the small subunit, but not by a P site-specific antibiotic. RsgA stably bound the small subunit in the presence of GDPNP, but not in the presence of GTP or GDP, to dissociate ribosome into subunits. Disruption of the gene for RsgA from the genome affected the growth of the cells, which predominantly contained the dissociated subunits having only a weak activation activity of RsgA. We also found that 17S RNA, a putative precursor of 16S rRNA, was contained in the small subunit of the ribosome from the RsgA-deletion strain. RsgA is a novel GTPase that might provide a new insight into the function of ribosome.

Crystal structure of YjeQ from Thermotoga maritima contains a circularly permuted GTPase domain

We have determined the crystal structure of the GDP complex of the YjeQ protein from Thermotoga maritima (TmYjeQ), a member of the YjeQ GTPase subfamaily. TmYjeQ, a homologue of Escherichia coli YjeQ, which is known to bind to the ribosome, is composed of three domains: an N-terminal oligonucleotide/oligosaccharide-binding fold domain, a central GTPase domain, and a C-terminal zinc-finger domain. The crystal structure of TmYjeQ reveals two interesting domains: a circularly permutated GTPase domain and an unusual zinc-finger domain. The binding mode of GDP in the GTPase domain of TmYjeQ is similar to those of GDP or GTP analogs in ras proteins, a prototype GTPase. The N-terminal oligonucleotide/oligosaccharide-binding fold domain, together with the GTPase domain, forms the extended RNA-binding site. The C-terminal domain has an unusual zinc-finger motif composed of Cys-250, Cys-255, Cys-263, and His-257, with a remote structural similarity to a portion of a DNA-repair protein, rad51 fragment. The overall structural features of TmYjeQ make it a good candidate for an RNA-binding protein, which is consistent with the biochemical data of the YjeQ subfamily in binding to the ribosome.

The crystal structure of YloQ, a circularly permuted GTPase essential for Bacillus subtilis viability

yloQ is one of 11 essential genes in Bacillus subtilis with unknown roles in the physiology of the cell. It encodes a polypeptide of 298 residues with motifs characteristic of GTPases. As a contribution to elucidating its indispensable cellular function, we have solved the crystal structure of YloQ to 1.6 A spacing, revealing a three-domain organisation. At the heart of the molecule is the putative GTPase domain, which exhibits a classical alpha/beta nucleotide-binding fold with a topology very similar to that of Ras and Era. However, as anticipated from the order in which the conserved G protein motifs appear in the sequence, the GTPase domain fold in YloQ is circularly permuted with respect to the classical GTPases. The nucleotide-binding pocket in YloQ is unoccupied, and analysis of the phosphate-binding (P) loop indicates that conformational changes in this region would be needed to accommodate GTP. The GTPase domain is flanked at its N terminus by a beta-barrel domain with an oligonucleotide/oligosaccharide-binding (OB) fold, and at its C terminus by an alpha-helical domain containing a coordinated zinc ion. This combination of protein modules is unique to YloQ and its orthologues. Sequence comparisons reveal a clustering of conserved basic and aromatic residues on one face of the OB domain, perhaps pointing to a role for YloQ in nucleic acid binding. The zinc ion in the alpha-helical domain is coordinated by three cysteine residues and a histidine residue in a novel ligand organisation. The juxtaposition of the switch I and switch II regions of the G domain and the OB and zinc-binding domains suggests that chemical events at the GTPase active site may be transduced into relative movements of these domains. The pattern of conserved residues and electrostatic surface potential calculations suggest that the OB and/or Zn-binding domains participate in nucleic acid binding consistent with a possible role for YloQ at some stage during mRNA translation.

Studies of the interaction of Escherichia coli YjeQ with the ribosome in vitro

Escherichia coli YjeQ represents a conserved group of bacteria-specific nucleotide-binding proteins of unknown physiological function that have been shown to be essential to the growth of E. coli and Bacillus subtilis. The protein has previously been characterized as possessing a slow steady-state GTP hydrolysis activity (8 h(-1)) (D. M. Daigle, L. Rossi, A. M. Berghuis, L. Aravind, E. V. Koonin, and E. D. Brown, Biochemistry 41: 11109-11117, 2002). In the work reported here, YjeQ from E. coli was found to copurify with ribosomes from cell extracts. The copy number of the protein per cell was nevertheless low relative to the number of ribosomes (ratio of YjeQ copies to ribosomes, 1:200). In vitro, recombinant YjeQ protein interacted strongly with the 30S ribosomal subunit, and the stringency of that interaction, revealed with salt washes, was highest in the presence of the nonhydrolyzable GTP analog 5'-guanylylimidodiphosphate (GMP-PNP). Likewise, association with the 30S subunit resulted in a 160-fold stimulation of YjeQ GTPase activity, which reached a maximum with stoichiometric amounts of ribosomes. N-terminal truncation variants of YjeQ revealed that the predicted OB-fold region was essential for ribosome binding and GTPase stimulation, and they showed that an N-terminal peptide (amino acids 1 to 20 in YjeQ) was necessary for the GMP-PNP-dependent interaction of YjeQ with the 30S subunit. Taken together, these data indicate that the YjeQ protein participates in a guanine nucleotide-dependent interaction with the ribosome and implicate this conserved, essential GTPase as a novel factor in ribosome function.