The structural and functional organization of H-NS-like proteins is evolutionarily conserved in Gram-negative bacteria

The structural gene of the H-NS protein, a global regulator of bacterial metabolism, has been identified in the group of enterobacteria as well as in closely related bacteria, such as Erwinia chrysanthemi and Haemophilus influenzae . Isolated outside these groups, the BpH3 protein of Bordetella pertussis exhibits a low amino acid conservation with H-NS, particularly in the N-terminal domain. To obtain information on the structure, function and/or evolution of H-NS, we searched for other H-NS-related proteins in the latest databases. We found that HvrA, a trans -activator protein in Rhodobacter capsulatus , has a low but significant similarity with H-NS and H-NS-like proteins. This Gram-negative bacterium is phylogenetically distant from Escherichia coli . Using theoretical analysis (e.g. secondary structure prediction and DNA binding domain modelling) of the amino acid sequence of H-NS, StpA (an H-NS-like protein in E. coli ), BpH3 and HvrA and by in vivo and in vitro experiments (e.g. complementation of various H-NS-related phenotypes and competitive gel shift assay), we present evidence that these proteins belong to the same class of DNA binding proteins. In silico analysis suggests that this family also includes SPB in R. sphaeroides , XrvA in Xanthomonas oryzae and VicH in Vibrio cholerae . These results demonstrate that proteins structurally and functionally related to H-NS are widespread in Gram-negative bacteria.     

The evolution of signal receptor proteins: conserved regions and the similarity to GTP-binding proteins

A sequence comparison of signal receptor proteins (SR) was carried out using computer techniques based on physicochemical characteristics of amino acids. A new method of conserved regions determination for a family of proteins is described. Visual pigments have four, and all SR--three such regions in the cytoplasmic loops. Possible functional significance of these regions is discussed. We also report here that the family of SR is similar with the family of G-proteins involved in extracellular signal transduction. Both families have similar regions consisting of 7-8 amino acids and a number of identical amino acids distributed on the considerable part of the polypeptide chain of the proteins. These facts may indicate that the whole ensemble of the proteins participating in transmembrane signalling pathways (or some part of it) could evolve from a common progenitor. At the same time, similar structure elements of members of the mentioned protein families my be functionally important for protein-protein interaction.     

Insulin/IGF-I-signaling pathway: an evolutionarily conserved mechanism of longevity from yeast to humans

Although the underlying mechanisms of longevity are not fully understood, it is known that mutation in genes that share similarities with those in humans involved in the insulin/insulin-like growth factor I (IGF-I) signal response pathway can significantly extend life span in diverse species, including yeast, worms, fruit flies, and rodents. Intriguingly, the long-lived mutants, ranging from yeast to mice, share some important phenotypic characteristics, including reduced insulin signaling, enhanced sensitivity to insulin, and reduced IGF-I plasma levels. Such genetic homologies and phenotypic similarities between insulin/IGF-I pathway mutants raise the possibility that the fundamental mechanism of aging may be evolutionarily conserved from yeast to mammals. Very recent findings also provide novel and intriguing evidence for the involvement of insulin and IGF-I in the control of aging and longevity in humans. In this study, we focus on how the insulin/IGF-I pathway controls yeast, nematode, fruit fly, and rodent life spans and how it is related to the aging process in humans to outline the prospect of a unifying mechanism in the genetics of longevity.     

The proteomics of lipid droplets: structure, dynamics, and functions of the organelle conserved from bacteria to humans

Lipid droplets are cellular organelles that consists of a neutral lipid core covered by a monolayer of phospholipids and many proteins. They are thought to function in the storage, transport, and metabolism of lipids, in signaling, and as a specialized microenvironment for metabolism in most types of cells from prokaryotic to eukaryotic organisms. Lipid droplets have received a lot of attention in the last 10 years as they are linked to the progression of many metabolic diseases and hold great potential for the development of neutral lipid-derived products, such as biofuels, food supplements, hormones, and medicines. Proteomic analysis of lipid droplets has yielded a comprehensive catalog of lipid droplet proteins, shedding light on the function of this organelle and providing evidence that its function is conserved from bacteria to man. This review summarizes many of the proteomic studies on lipid droplets from a wide range of organisms, providing an evolutionary perspective on this organelle.     

Electrophoretic and immunological comparisons of chloroplast and prokaryotic ribosomal proteins reveal that certain families of large subunit proteins are evolutionarily conserved

Summary Antibodies to individual chloroplast ribosomal (r-)proteins ofChlamydomonas reinhardtii synthesized in either the chloroplast or the cytoplasm were used to examine the relatedness ofChlamydomonas r-proteins to r-proteins from the spinach (Spinacia oleracea) chloroplast,Escherichia coli, and the cyanobacteriumAnabaena 7120. In addition,³⁵S-labeled chloroplast r-proteins from large and small subunits ofC. reinhardtii were coelectrophoresed on 2-D gels with unlabeled r-proteins from similar subunits of spinach chloroplasts,E. coli, andAnabaena to compare their size and net charge. Comigrating protein pairs were not always immunologically related, whereas immunologically related r-protein pairs often did not comigrate but differed only slightly in charge and molecular weight. In constrast, when³⁵S-labeled chloroplast r-proteins from large and small subunits of a closely related speciesC. smithii were coelectrophoresed with unlabeledC. reinhardtii chloroplast r-proteins, only one pair of proteins from each subunit showed a net displacement in mobility.Analysis of immunoblots of one-dimensional SDS and two-dimensional urea/SDS gels of large and small subunit r-proteins from these species revealed more antigenic conservation among the four species of large subunit r-proteins than small subunit r-proteins.Anabaena r-proteins showed the greatest immunological similarity toC. reinhardtii chloroplast r-proteins. In general, antisera made against chloroplast-synthesized r-proteins inC. reinhardtii showed much higher levels of cross-reactivity with r-proteins fromAnabaena, spinach, andE. coli than did antisera to cytoplasmically synthesized r-proteins. All spinach r-proteins that cross-reacted with antisera to chloroplast-synthesized r-proteins ofC. reinhardtii are known to be made in the chloroplast (Dorne et al. 1984b). FourE. coli r-proteins encoded by the S10 operon (L2, S3, L16, and L23) were found to be conserved immunologically among the four species. Two of the large subunit r-proteins, L2 and L16, are essential for peptidyltransferase activity. The third (L23) and two otherE. coli large subunit r-proteins (L5 and L27) that have immunological equivalents among the four species are functionally related to but not essential for peptidyltransferase activity.     

The HORMA domain: an evolutionarily conserved domain discovered in chromatin-associated proteins,has unanticipated diverse functions

The HORMA domain (for Hop1p, Rev7p and MAD2) was discovered in three chromatin-associated proteins in the budding yeast Saccharomyces cerevisiae. This domain has also been found in proteins with similar functions in organisms including plants, animals and nematodes. The HORMA domain containing proteins are thought to function as adaptors for meiotic checkpoint protein signaling and in the regulation of meiotic recombination. Surprisingly, new work has disclosed completely unanticipated and diverse functions for the HORMA domain containing proteins. A. M. Villeneuve and colleagues (Schvarzstein et al., 2013) show that meiosis-specific HORMA domain containing proteins plays a vital role in preventing centriole disengagement during Caenorhabditis elegans spermatocyte meiosis. Another recent study reveals that S. cerevisiae Atg13 HORMA domain acts as a phosphorylation-dependent conformational switch in the cellular autophagic process.     

Induction of IL-10 and inhibition of experimental arthritis are specific features of microbial heat shock proteins that are absent for other evolutionarily conserved immunodominant proteins

Bacterial heat shock proteins (hsp) are evolutionary conserved immunodominant proteins that manifest amino acid homologies with hsp present in mammalian cells. Preimmunization with mycobacterial hsp65 has been found to protect against various forms of experimental arthritis. As these protective effects have previously been attributed to induction of self homologue cross-reactive T cell responses, the question was raised as to whether this protective effect could be extended to other highly conserved and immunodominant microbial Ags with mammalian homologues. Therefore, we immunized Lewis rats with conserved bacterial Ags (superoxide dismutase, aldolase, GAPDH, and hsp70). Although all Ags appeared highly immunogenic, we only found a protective effect in experimental arthritis after immunization with bacterial hsp70. The protective effect of hsp70 was accompanied with a switch in the subclasses of hsp70-specific Abs, suggesting the induction of Th2-like response. The most striking difference between immunization with hsp70 and all other immunodominant Ags was the expression of IL-10 found after immunization with hsp70. Even more, while immunization with hsp70 led to Ag-induced production of IL-10 and IL-4, immunization with aldolase led to increased production of IFN-gamma and TNF-alpha. Thus, the protective effect of conserved immunodominant proteins in experimental arthritis seems to be a specific feature of hsp. Therefore, hsp may offer unique possibilities for immunological intervention in inflammatory diseases.     

Self peptides bound by HLA class I molecules are derived from highly conserved regions of a set of evolutionarily conserved proteins

An evolutionary analysis of self peptides reported to be bound by HLA class I molecules showed that these peptides are largely derived from proteins that have been highly conserved in the history of mammals. These proteins also often have universal tissue expression and have a higher than average frequency of highly hydrophilic residues. The peptides themselves are generally still more highly conserved than the source proteins and have a higher frequency of highly hydrophobic residues, evidently often derived from conserved hydrophobic cores of the source proteins. These results suggest that the mechanism by which peptides are derived for MHC presentation may preferentially select peptides from conserved protein regions. In the case of parasite-derived peptides, such a mechanism would be adaptive in that it would reduce the likelihood of escape mutants.     

SMC proteins and chromosome mechanics: from bacteria to humans

Chromosome cohesion and condensation are essential prerequisites of proper segregation of genomes during mitosis and meiosis, and are supported by two structurally related protein complexes, cohesin and condensin, respectively. At the core of the two complexes lie members of the structural maintenance of chromosomes (SMC) family of ATPases. SMC proteins are also found in most bacterial and archaeal species, implicating the existence of an evolutionarily conserved theme of higher-order chromosome organization and dynamics. SMC dimers adopt a two-armed structure with an ATP-binding cassette (ABC)-like domain at the distal end of each arm. This article reviews recent work on the bacterial and eukaryotic SMC protein complexes, and discusses current understanding of how these uniquely designed protein machines may work at a mechanistic level. It seems most likely that the action of SMC proteins is highly dynamic and plastic, possibly involving a diverse array of intramolecular and intermolecular protein-protein interactions.     

The functions of the multiproduct and rapidly evolving dec-1 eggshell gene are conserved between evolutionarily distant species of Drosophila.

The Drosophila dec-1 gene encodes multiple proteins that are required for female fertility and proper eggshell morphogenesis. Genetic and immunolocalization data suggest that the different DEC-1 proteins are functionally distinct. To identify regions within the proteins with potential biological significance, we cloned and sequenced the D. yakuba and D. virilis dec-1 homologs. Interspecies comparisons of the predicted translation products revealed rapidly evolving sequences punctuated by blocks of conserved amino acids. Despite extensive amino acid variability, the proteins produced by the different dec-1 homologs were functionally interchangeable. The introduction of transgenes containing either the D. yakuba or the D. virilis dec-1 open reading frames into a D. melanogaster DEC-1 protein null mutant was sufficient to restore female fertility and wild-type eggshell morphology. Normal expression and extracellular processing of the DEC-1 proteins was correlated with the phenotypic rescue. The nature of the conserved features highlighted by the evolutionary comparison and the molecular resemblance of some of these features to those found in other extracellular proteins suggests functional correlates for some of the multiple DEC-1 derivatives.     

The small GTP-binding proteins in the cytosol of insulin-secreting cells are complexed to GDP dissociation inhibitor proteins.

Ras-related small GTP-binding proteins (SMGs) exist in a cytosolic and a membrane-bound pool. The mechanism regulating the intracellular distribution of SMGs remains to be elucidated. We have, therefore, investigated the properties of SMGs expressed in cells of the insulin-secreting lines RINm5F and HIT-T15. Phase-partitioning analysis revealed that smg25A/rab3A as well as all the SMGs in the 23-27 kDa range, labeled by radioactive GTP after blotting, were hydrophobic, regardless of their subcellular distribution. In contrast, the cytosolic forms of ADP ribosylation factor, rho, and CDC42 were hydrophilic. The cytosolic pool of the 23-27-kDa group, including smg25A/rab3A, sedimented in a sucrose density gradient as complexes with an apparent M(r) of about 80,000, whereas rho and CDC42 were recovered in 45-kDa complexes. ARF, however, was uncomplexed (M(r) close to 20,000). The 80-kDa aggregates were likely to be formed by 1:1 complexes with the regulatory protein smg25/GDP dissociation inhibitor (smg25/GDI). In fact, pure smg25/GDI by sucrose gradient exhibited a molecular mass of 55 kDa, but cosedimented with the 80-kDa complexes in cytosolic extracts of insulin-secreting cells. Moreover, purified smg25/GDI was able to extract the SMGs of the 23-27-kDa group from the membranes. Similarly, in cytosolic extracts, rho/GDI cosedimented with the 45-kDa aggregates. Blocking the synthesis of isoprenoid groups with lovastatin resulted in the appearance in the cytosol of SMGs that were hydrophilic. These SMGs were found to sediment with an apparent M(r) close to 25,000 and to be unable to form complexes with smg25/GDI. Lovastatin treatment also caused the accumulation of the noncomplexed form of CDC42 but not of rho proteins. We propose that 1) except for ARF, all the SMGs detected in the cytosol of insulin-secreting cells are associated in 1:1 complexes with their regulatory proteins; 2) the different SMGs can be subdivided into functional groups according to the regulatory protein bound to them; 3) the formation of the 80-kDa complexes with smg25/GDI and of the CDC42 complexes with rho/GDI necessitate the correct carboxyl-terminal post-translational modification of the SMGs.     

Evolution of mitochondrial oxa proteins from bacterial YidC. Inherited and acquired functions of a conserved protein insertion machinery

Members of the Oxa1/YidC family are involved in the biogenesis of membrane proteins. In bacteria, YidC catalyzes the insertion and assembly of proteins of the inner membrane. Mitochondria of animals, fungi, and plants harbor two distant homologues of YidC, Oxa1 and Cox18/Oxa2. Oxa1 plays a pivotal role in the integration of mitochondrial translation products into the inner membrane of mitochondria. It contains a C-terminal ribosome-binding domain that physically interacts with mitochondrial ribosomes to facilitate the co-translational insertion of nascent membrane proteins. The molecular function of Cox18/Oxa2 is not well understood. Employing a functional complementation approach with mitochondria-targeted versions of YidC we show that YidC is able to functionally replace both Oxa1 and Cox18/Oxa2. However, to integrate mitochondrial translation products into the inner membrane of mitochondria, the ribosome-binding domain of Oxa1 has to be appended onto YidC. On the contrary, the fusion of the ribosome-binding domain onto YidC prevents its ability to complement COX18 mutants suggesting an indispensable post-translational activity of Cox18/Oxa2. Our observations suggest that during evolution of mitochondria from their bacterial ancestors the two descendents of YidC functionally segregated to perform two distinct activities, one co-translational and one post-translational.     

Arabidopsis thaliana has a set of J proteins in the endoplasmic reticulum that are conserved from yeast to animals and plants

J domain-containing proteins (J proteins) are functional partners for heat shock protein 70 (Hsp70) molecular chaperones and mediate various cellular processes by regulating activities of Hsp70. Budding yeast has three J proteins in the endoplasmic reticulum (ER): Scj1p and Jem1p functioning in protein folding and quality control in the ER, and Sec63p functioning in protein translocation across the ER membrane as partners for BiP, an Hsp70 in the ER. Here we report that Arabidopsis thaliana has orthologs of these yeast ER J proteins, which we designated as AtERdj3A, AtERdj3B, AtP58(IPK), AtERdj2A and AtERdj2B. Tunicamycin treatment of Arabidopsis cells, which causes ER stress, led to up-regulation of AtERdj3A, AtERdj3B, AtP58(IPK) and AtERdj2B. Subcellular fractionation analyses showed their ER localization, indicating that the identified J proteins indeed function as partners for BiP in Arabidopsis cells. Since expression of AtERdj3A, AtERdj3B and AtP58(IPK) partially suppressed the growth defects of the yeast jem1Deltascj1Delta mutant, they have functions similar to those of Scj1p and Jem1p. T-DNA insertions of the AtERDJ2A gene resulted in pollen germination defects, probably reflecting its essential function in protein translocation. These results suggest that A. thaliana has a set of ER J proteins structurally and functionally conserved from yeast to plants.     

Moesin-ezrin-radixin-like protein merlin: Its conserved and distinct functions from those of ERM proteins

Neurofibromatosis type 2 (NF2), which encodes merlin (moesin-ezrin-radixin-like protein), belongs to the band 4.1, ezrin, radixin, moesin (FERM) domain-containing 4.1 superfamily. Merlin shares sequence homology with ERM proteins, is evolutionarily conserved, and acts as a tumour suppressor. Here, we describe the molecular functions of merlin from a biophysical point of view. We describe the structural basis for merlin regulatory mechanisms based on its interaction with phosphatidylinositol 4,5-bisphosphate (PI(4,5)P₂) along with its interaction partners, and then describe its physiological functions in cell–cell adhesions. Elucidation of these merlin functions will lead to a clear understanding of its fundamental roles in cells and tissues.     

Structural and functional characterization of CFE88: evidence that a conserved and essential bacterial protein is a methyltransferase

CFE88 is a conserved essential gene product from Streptococcus pneumoniae. This 227-residue protein has minimal sequence similarity to proteins of known 3D structure. Sequence alignment models and computational protein threading studies suggest that CFE88 is a methyltransferase. Characterization of the conformation and function of CFE88 has been performed by using several techniques. Backbone atom and limited side-chain atom NMR resonance assignments have been obtained. The data indicate that CFE88 has two domains: an N-terminal domain with 163 residues and a C-terminal domain with 64 residues. The C-terminal domain is primarily helical, while the N-terminal domain has a mixed helical/extended (Rossmann) fold. By aligning the experimentally observed elements of secondary structure, an initial unrefined model of CFE88 has been constructed based on the X-ray structure of ErmC' methyltransferase (Protein Data Bank entry 1QAN). NMR and biophysical studies demonstrate binding of S-adenosyl-L-homocysteine (SAH) to CFE88; these interactions have been localized by NMR to the predicted active site in the N-terminal domain. Mutants that target this predicted active site (H26W, E46R, and E46W) have been constructed and characterized. Overall, our results both indicate that CFE88 is a methyltransferase and further suggest that the methyltransferase activity is essential for bacterial survival.     

The NodI and NodJ proteins from Rhizobium and Bradyrhizobium strains are similar to capsular polysaccharide secretion proteins from Gram-negative bacteria

The NodI and NodJ nodulation proteins have been described in different Rhizobium and Bradyrhizobium species. The NodIJ genes belong to the nod regulon. Other genes from this regulon are involved in the biosynthesis and modification of lipo-oligosaccharide molecule(s) which are morphogénic signals when acting on legume roots. It has been proposed that the NodI and NodJ proteins belong to a bacterial inner membrane transport system of small molecules. Nucleotide sequencing of MudII PR 13 insertions in the nodulation region of the symbiotic plasmid from a Rhizobium leguminosarum bv. phaseoli strain CE3 has revealed the presence of NodI and nodJ related sequences downstream of nodC. Computer nucleotide sequence analysis of the entire NodI and NodJ sequences from R. leguminosarum bv. viciae and Bradyrhizobium japonicum strains show that both proteins are similar to the KpsT and KpsM proteins from Escherichia coli Kl and K5 strains, to the BexB and BexA proteins from Haemophilis influenzae and to the CtrD and CtrC proteins from Neisseria meningitidis, respectively. Except for the NodI and NodJ proteins, all of them have been involved in the mechanism of secretion of polysaccharides in each of their harbouring species. On the basis of the similarity found, we propose that the NodI and the NodJ proteins could be involved in the export of a lipo-oligosaccharide.