Thermostability of two cyanobacterial GrpE thermosensors

GrpE proteins act as co-chaperones for DnaK heat-shock proteins. The dimeric protein unfolds under heat stress conditions, which results in impaired interaction with a DnaK protein. Since interaction of GrpE with DnaK is crucial for the DnaK chaperone activity, GrpE proteins act as a thermosensor in bacteria. Here we have analyzed the thermostability and function of two GrpE homologs of the mesophilic cyanobacterium Synechocystis sp. PCC 6803 and of the thermophilic cyanobacterium Thermosynechococcus elongatus BP1. While in Synechocystis an N-terminal helix pair of the GrpE dimer appears to be the thermosensing domain and mainly mediates GrpE dimerization, the C-terminal four-helix bundle is involved in additional stabilization of the dimeric structure. The four-helix bundle domain has a key role in the thermophilic cyanobacterium, since dimerization of the Thermosynechococcus protein appears to be mediated by the four-helix bundle domain, and melting of this domain is linked to monomerization of the GrpE protein. Thus, in two related cyanobacteria the GrpE thermosensing function might be mediated by different protein domains.     

Physical interactions between members of the DnaK chaperone machinery: characterization of the DnaK.GrpE complex

Many of the functions of the Escherichia coli Hsp 70, DnaK, require two cofactors, DnaJ and GrpE. GrpE acts as a nucleotide exchange factor in the DnaK reaction cycle but the details of its mechanism remain unclear. GrpE has high affinity for monomeric native DnaK, with a K_d estimated at ≤50 nM. GrpE is a very asymmetric molecule and exists as either a dimer or trimer in its native state. The stoichiometry of GrpE to DnaK in the isolated complex was 3:1, suggesting a trimer. Formation of the complex is quite fast (k_on >1 S⁻¹, whereas the off-rate is very slow on the HPLC timescale (k_off ≤ 10⁻⁴ S⁻¹). GrpE has no affinity for ATP or ADP, nor the oligomeric and moltn globule states of DnaK. The complex is much more thermally stable than either GrpE or DnaK alone, and prevents the formation of the molten globule-like state of DnaK at physiologically relevant temperatures. Formation of the complex does not cause any change in secondary structure, as determined by the lack of change in the circular dichroism spectrum. However, binding of GrpE induces a similar tertiary strcutral change in DnaK to that induced by binding of ATP₁ based on the blue shift in λ_max from the fluroscence of the single tryptophan in DnaK. The nucleotide exchange properties of GrpE can be explained by the conformational change which may represent the opening of the nucleotide cleft on DnaK, subsequently inducing a low affinity state for ADP.     

Influence of cation-pi interactions on RNA-binding proteins

The energy contribution due to cation-π interactions has been computed for 37 RNA binding proteins. The contribution of these cation-π interacting residues in sequential separation, secondary structure involvement, solvent accessibility, and stabilization centers has been evaluated. Sequential separation of the cation-π involving residues show that, long range contacts predominates in all the proteins studied. Lys and Arg prefers to be in helical structures. Of the cation-π interacting residues, Arg and Lys were in the exposed regions and the aromatic residues (Phe, Tyr and Trp) were in the buried and partially buried regions in the protein structures. Stabilization centers for these proteins showed that all the five residues found in cation-π interactions are important in locating one or more of such centers. On the whole, the results presented in this work will be very useful for further investigations on the specificity and selectivity of RNA binding proteins and also for their structural studies.     

Molecular characterization of a plant mitochondrial chaperone GrpE

Escherichia coli DnaK (Hsp70) cooperates with DnaJ and GrpE in its essential role as a molecular chaperone. Function of mitochondrial Hsp70 (mHsp70) in protein folding and organellar import in eukaryotes is critically dependent on GrpE. We cloned two genes from tobacco (Nicotiana tabacum) BY2 cells based on peptide sequences from a purified protein. The predicted amino acid sequences of both clones resembled that of GrpE from E. coli and its homologues from eukaryotes, and a cDNA clone from Arabidopsis thaliana. One gene (Type 1) encoded a deduced protein that was identical to the purified protein while the other (Type 2) encoded a deduced protein that has 80% sequence identity to Type 1. Both tobacco and Arabidopsis thaliana GrpE homologues bound to DnaK and ATP inhibited this binding. The tobacco GrpE homologue contained a typical N-terminal mitochondrial target presequence of 64 residues and the presequence directed the green fluorescent protein to tobacco mitochondria. The tobacco GrpE homologue also associated with mHsp70 when reintroduced into BY2 protoplasts, and this association was disrupted by ATP. A three-dimensional structure for the tobacco GrpE homologue was modeled based on the X-ray structure of E. coli GrpE complexed with DnaK. The modeled structure has the same overall structure as E. coli GrpE. We propose that the tobacco GrpE homologue interacts with mHsp70 in a manner analogous to E. coli GrpE with DnaK and designate it as tobacco mitochondrial GrpE (NtmGrpE).     

Chloroplastic isoforms of DnaJ and GrpE in pea

The folding and assembly of proteins in cells often requires the assistance of molecular chaperones such as the Hsp70 and Hsp60 heat shock proteins. Hsp70 chaperones cooperate with DnaJ and GrpE homologues to ensure a productive folding cycle. In this study we describe the gene for the first chloroplast localized DnaJ homologue and present evidence that the gene product is at least partially associated with the inner envelope membrane. Immunoblot analysis also provides evidence for the presence of a GrpE homologue in plastids.     

Folding properties of the nucleotide exchange factor GrpE from Thermus thermophilus: GrpE is a thermosensor that mediates heat shock response.

Hsp70 proteins like DnaK bind unfolded polypeptides in a nucleotide-dependent manner. The switch from high-affinity ADP-state to low- affinity ATP-state with concomitant substrate release is accelerated significantly by GrpE proteins. GrpE thus fulfils an important role in regulation of the chaperone cycle. Here, we analysed the thermal stability of GrpE from Thermus thermophilus using differential scanning calorimetry and CD-spectroscopy. The protein exhibits unusual unfolding characteristics with two observable thermal transitions. The first transition is CD-spectroscopically silent with a transition midpoint at 90 degrees C. The second transition, mainly constituting the CD-signal, ranges between 100 and 105 degrees C depending on the GrpE(Tth) concentration, according to the model N(2) <==> I(2) <==> 2U. Using a C-terminally truncated version of GrpE(Tth) it was possible to assign the second thermal transition to the dimerisation of GrpE(Tth), while the first transition represents the completely reversible unfolding of the globular C-terminal domain. The unfolding of this domain is accompanied by a distinct decrease in nucleotide exchange rates and impaired binding to DnaK(Tth). Under heat shock conditions, the DnaK-ADP-protein-substrate complex is thus stabilised by a reversibly inactivated GrpE-protein that refolds under permissive conditions. In combination with studies on GrpE from Escherichia coli presented recently by Christen and co-workers, it thus appears that the general role of GrpE is to function as a thermosensor that modulates nucleotide exchange rates in a temperature-dependent manner to prevent substrate dissociation at non-permissive conditions.     

Probing the stability and mechanism for folding of the GrpE1-112 tetrameric deletion mutant of the GrpE protein from E. coli

Insight into the stability and folding of oligomeric proteins is essential to the understanding of protein folding, especially since the majority of proteins found in nature are oligomeric. A deletion mutant of the GrpE protein from Escherichia coli, that contains the first 112 residues (GrpE1-112) of 197 total, is an oligomeric protein forming a tetrameric structure. A four-helix bundle structure is formed via the interaction of an α-helix (22 amino acids in length) from each monomer. Using both thermal and chemical (urea) denaturation studies, the GrpE1-112 protein has rather low stability with a T(m) of unfolding of 37 °C, a C(m) (urea) of 1.3M, and a ΔG(unfolding) of 8.4 kJ mol(-1). Investigation into the folding pathway using circular dichroism (CD) stopped-flow revealed a two step process with a fast first phase (k(refolding)=8.0 × 10(6)s(-1)M(-1)) forming a multimeric intermediate that possesses significant α-helical content followed by a slow, first order, step forming the folded tetramer.     

GrpE, a nucleotide exchange factor for DnaK

The cochaperone GrpE functions as a nucleotide exchange factor to promote dissociation of adenosine 5'-diphosphate (ADP) from the nucleotide-binding cleft of DnaK. GrpE and the DnaJ cochaperone act in concert to control the flux of unfolded polypeptides into and out of the substrate-binding domain of DnaK by regulating the nucleotide-bound state of DnaK. DnaJ stimulates nucleotide hydrolysis, and GrpE promotes the exchange of ADP for adenosine triphosphate (ATP) and also augments peptide release from the DnaK substrate-binding domain in an ATP-independent manner. The eukaryotic cytosol does not contain GrpE per se because GrpE-like function is provided by the BAG1 protein, which acts as a nucleotide exchange factor for cytosolic Hsp70s. GrpE, which plays a prominent role in mitochondria, chloroplasts, and bacterial cytoplasms, is a fascinating molecule with an unusual quaternary structure. The long alpha-helices of GrpE have been hypothesized to act as a thermosensor and to be involved in the decrease in GrpE-dependent nucleotide exchange that is observed in vitro at temperatures relevant to heat shock. This review describes the molecular biology of GrpE and focuses on the structural and kinetic aspects of nucleotide exchange, peptide release, and the thermosensor hypothesis.     

Influence of hydrocarbon-stapling on membrane interactions of synthetic antimicrobial peptides

Cyclization has been recognized as a valuable technique for increasing the efficacy of small molecule and peptide therapeutics. Here we report the application of a hydrocarbon staple to a rationally-designed cationic antimicrobial peptide (CAP) that acquires increased membrane targeting and interaction vs. its linear counterpart. The previously-described CAP, 6K-F17 (KKKKKK-AAFAAWAAFAA-NH₂) was used as the backbone for incorporation of an i to i?+?4 helical hydrocarbon staple through olefin ring closing metathesis. Stapled versions of 6K-F17 showed an increase in non-selective membrane interaction, where the staple itself enhances the degree of membrane interaction and rate of cell death while maintaining high potency against bacterial membranes. However, the higher averaged hydrophobicity imparted by the staple also significantly increases toxicity to mammalian cells. This deleterious effect is countered through stepwise reduction of the stapled 6K-F17’s backbone hydrophobicity through polar amino acid substitutions. Circular dichroism assessment of secondary structure in various bacterial membrane mimetics reveals that a helical structure may improve – but is not an absolute requirement for – antimicrobial activity of 6K-F17. Further, phosphorus-31 static solid state NMR spectra revealed that both non-toxic stapled and linear peptides bind bacterial membranes in a similar manner that does not involve a detergent-like mechanism of lipid removal. The overall results suggest that the technique of hydrocarbon stapling can be readily applied to membrane-interactive CAPs to modulate how they interact and target biological membranes.     

Influence of hydrogen bonds on edge-to-face interactions between pyridine molecules

Edge-to-face interactions between two pyridine molecules and the influence of simultaneous hydrogen bonding of one or both of the pyridines to water on those interactions were studied by analyzing data from ab initio calculations. The results show that the edge-to-face interactions of pyridine dimers that are hydrogen bonded to water are generally stronger than those of non-H-bonded pyridine dimers, especially when the donor pyridine forms a hydrogen bond. The binding energy of the most stable edge-to-face interacting H-bonded pyridine dimer is ?5.05 kcal/mol, while that for the most stable edge-to-face interacting non-H-bonded pyridine dimer is ?3.64 kcal/mol. The interaction energy data obtained in this study cannot be explained solely by the differences in electrostatic potential between pyridine and the pyridine–water dimer. However, the calculated cooperative effect can be predicted using electrostatic potential maps.     

Influence of fungal-bacterial interactions on bacterial conjugation in the residuesphere

Conjugal gene transfer among bacteria in the residuesphere (area between decaying plant material and soil) of leaves of barley straw was studied. The residuesphere was shown to be a hot-spot for conjugal gene transfer compared to conjugation in sterile sand and non-sterile bulk soil. Impact of fungal colonisation of the residuesphere on bacterial colonisation and conjugation was also investigated. The inhibition of fungal colonisation, due to the application of an eukaryotic inhibitor, increased bacterial colonisation of the residuesphere in soil microcosms compared to non-treated leaves. This treatment also had a transient, positive effect on conjugation. Bacterial conjugation in the residuesphere of leaves subjected to 17 days of fungal colonisation was significantly lower than in the residuesphere of non-colonised leaves. Fungal biomass, as measured by chitinase activity, was inversely related to the conjugation efficiency.     

Influence of chlorophyll a on intermolecular interactions in liquid crystal

Studies of the variability of the spectral properties (linear dichroism, polarized fluorescence and the energetic separation of the absorption and emission bands) of chlorophyll a in a nematic liquid crystal matrix with respect to the effects of solute concentration and the external electric fields were made. A close examination of the above mentioned types of variability suggest that the pigment molecules can influence a high initial order of the liquid crystal matrix. These structural changes of the matrix can be explained by the assumption that two types of chlorophyll with different orientations occur: the surface layers with the high degree of orientation, and a central volume of the sample with disordered molecules. The ordered molecules are sensitive to an reorientation by the external electric field.     

Influence of fungal isolates infecting tall fescue on multitrophic interactions

The epichloae are ascomycetous fungi in the genera Epichloë and Neotyphodium that live within grasses. Some of these fungi produce alkaloids that can help protect the host from herbivores. The alkaloids may also travel up the food web and affect members of the third trophic level. In this way they can produce trophic cascades which are rippling effects when a trophic level impacts those above or below it. We briefly summarize the general patterns of multitrophic effects of endophytes and highlight the most recent studies on this topic. Further, we report on our study in which we tested if different fungal strains in tall fescue (cultivar Jesup) affect multitrophic interactions involving aphids and their parasitoid natural enemies. Using both the common strain of N. coenophialum and a novel isolate (AR577), we allowed potted plants to be colonized by aphids and parasitoids in a semi-natural setting. We found that endophyte infection of tall fescue resulted in greater vegetative growth of the plant. We also found that N. coenophialum modified bottom-up cascades by depressing both aphid and parasitoid densities. Finally, we found that multitrophic effects were modified by fungal isolate: the common strain had stronger negative impacts on aphid and parasitoid densities than did the novel isolate.     

Influence of previous agonistic interactions with conspecifics on contest decisions

Recent wins and losses can inform individuals about their relative fighting abilities and modify their subsequent contest decisions. Using a mangrove rivulus, Kryptolebias marmoratus, we tested the hypothesis that visual and limited physical interactions can also convey information and modify subsequent contest decisions. Individuals were exposed to a stronger or weaker conspecific through a glass or a mesh partition before a contest with a size‐matched naïve opponent. Individuals were expected to (a) assess themselves to have worse/better fighting ability and behave less/more aggressively after having interacted with a stronger/weaker conspecific and (b) display different degrees of behavioural modifications for the two partition treatments (mesh‐partition > glass‐partition). The results showed that interactions with a stronger/weaker conspecific through a glass partition did not have a strong effect on the fish's subsequent contest behaviour. Restricted physical interaction with a stronger/weaker conspecific through a mesh partition, however, had an unexpected effect, causing individuals to behave more/less aggressively (matching the behaviour of the conspecifics) and/or win more/fewer subsequent contests. These results indicate that contest resolution is important for the fish to exhibit the loser–winner effects (i.e. behaving less/more aggressively after having lost/won against a stronger/weaker conspecific) detected in previous studies of the fish. We propose and discuss the possibility that the “behavioural matching” of the mesh‐partition treatment results from unresolved physical interactions with a stronger/weaker conspecific causing the individuals to either anticipate stronger/weaker opponents in subsequent competitions or assess themselves to be an equally good/bad fighter as the conspecific. The results of previous studies and the present study of the fish show that pre‐exposing an individual to the same type of conspecifics could elicit diverse, sometimes opposite, behavioural responses depending on how the individual is permitted to interact with the conspecific.     

A structure-based interpretation of E.coli GrpE thermodynamic properties

GrpE is the nucleotide exchange factor for the Escherichia coli molecular chaperone DnaK, the prokaryotic homologue of Hsp70. Thermodynamic properties of GrpE structural domains were characterized by examining a number of structural and point mutants using circular dichroism, differential scanning calorimetry and analytical ultracentrifugation. These structural domains are the long paired N-terminal helices, the central four-helix bundle, and the C-terminal compact beta-domains. We show that the central four-helix bundle (t(m) approximately 75 degrees C) provides a stable platform for the association of the long paired N-terminal helices (t(m) approximately 50 degrees C), which can then function as a temperature sensor. The stability of the N-terminal helices is linked to the presence of the C-terminal compact beta-domains of GrpE, providing a potential mechanism for coupling of DnaK-binding activity of GrpE with temperature. On the basis of our thermodynamic analysis of E.coli GrpE, we present a structure-based model for the melting properties of the nucleotide exchange factor, wherein the long paired helices function as a molecular thermocouple.     

Influence of the solvent structure on the electrostatic interactions in proteins

The proper estimation of the influence of the many-body dynamic solvent microstructure on a pairwise electrostatic interaction (PEI) at the protein-solvent interface is very important for solving many biophysical problems. In this work, the PEI energy was calculated for a system that models the interface between a protein and an aqueous solvent. The concept of nonlocal electrostatics for interfacial electrochemical systems was used to evaluate the contribution of a solvent orientational polarization, correlated by the network of hydrogen bonds, into the PEI energy in proteins. The analytical expression for this energy was obtained in the form of Coulomb's law with an effective distance-dependent dielectric function. The asymptotic and numerical analysis carried out for this function revealed several features of dielectric heterogeneity at the protein-solvent interface. For charges located in close proximity to this interface, the values of the dielectric function for the short-distance electrostatic interactions were found to be remarkably smaller than those determined by the classical model, in which the solvent was considered as the uniform dielectric medium of high dielectric constant. Our results have shown that taking into consideration the dynamic solvent microstructure remarkably increases the value of the PEI energy at the protein-solvent interface.     

Influence of ATM function on interactions between telomeres and nuclear matrix

The ATM (ataxia telangiectasia mutated) gene product has been implicated in mitogenic signal transduction, chromosome condensation, meiotic recombination, and cell cycle control. The human ATM protein shows similarity to several yeast and mammalian proteins involved in meiotic recombination and cell cycle progression. Because of the homology of the human ATM gene to the TEL1 and rad3 genes of yeast, it has been suggested that mutations in ATM could lead to defective telomere maintenance. Recently, we have shown that the ATM gene product, which is defective in the cancer-prone disorder ataxia telangiectasia (AT), influences chromosome end associations and telomere length. A possible hypothesis explaining these results is that the defective telomere metabolism in AT cells is due to altered interactions between the telomeres and the nuclear matrix. These interactions were examined in nuclear matrix halos prior to and after irradiation. A difference was observed in the ratio of soluble and matrix-associated telomeric DNA between cells derived from AT and normal individuals. Treatment with ionizing radiation affected the ratio of soluble and matrix-associated telomeric DNA only in the AT cells. To test the hypothesis that the ATM gene product is involved in interactions between telomeres and the nuclear matrix, such interactions were examined in human cells expressing either a dominant-negative effect or complementation of the ATM gene. The phenotype of RKO colorectal tumor cells expressing ATM fragments containing a leucine zipper motif mimics the altered interactions of telomere and nuclear matrix seen in AT cells. Fibroblasts from AT individuals transfected with a wild-type ATM gene had corrected telomere-nuclear matrix interactions. In experiments designed to determine whether there is a link between the altered telomere-nuclear matrix interactions and defective telomere movement and clustering, a significant difference was observed in the ratio of soluble compared to matrix-associated telomeric DNA sequences in meiocytes of Atm(-/-) and control mice. These results suggest that the ATM gene influences the interactions between telomeres and the nuclear matrix and that alterations in telomere chromatin could be at least partly responsible for the pleiotropic phenotypes of the ATM gene. This paper summarizes our recent publications on the influence of inactivation of ATM on the interaction of telomeres with nuclear matrix in somatic and germ cells.     

Influence of salts on electrostatic interactions between poliovirus and membrane filters

Neither solutions of salts nor solutions of detergents or of an alcohol at pH 4 are capable of eluting poliovirus adsorbed to membrane filters. However, solutions containing both a salt, such as magnesium chloride or sodium chloride, and a detergent or alcohol at pH 4 were capable of eluting adsorbed virus. The ability of ions to promote elution of virus at low pH in the presence of detergent or alcohol was dependent on the size of the ions and the ionic strength of the medium. These results suggest that both electrostatic and hydrophobic interactions are important in maintaining virus adsorption to membrane filters. Hydrophobic interactions can be disrupted by detergents or alcohols. It appears that electrostatic interactions can be disrupted by raising the pH of a solution or by adding certain salts. Disruption of either electrostatic or hydrophobic interactions alone does not permit efficient elution of the adsorbed virus at low pHs. However, when both interactions are disrupted, most of the poliovirus adsorbed to membrane filters is eluted, even at pH 4.