Disassembly/reassembly strategy for the production of highly pure GroEL, a tetradecameric supramolecular machine, suitable for quantitative NMR, EPR and mutational studies.

GroEL, a prototypical member of the chaperonin class of chaperones, is a large supramocular machine that assists protein folding and plays an important role in proteostasis. GroEL comprises two heptameric rings, each of which encloses a large cavity that provides a folding chamber for protein substrates. Many questions remain regarding the mechanistic details of GroEL facilitated protein folding. Thus, data at atomic resolution of the type provided by NMR and EPR are invaluable. Such studies often require complete deuteration of GroEL, uniform or residue specific 13C and 15N isotope labeling, and the introduction of selective cysteine mutations for site-specific spin labeling. In addition, high purity GroEL is essential for detailed studies of substrate-GroEL interactions as quantitative interpretation is impossible if the cavities are already occupied and blocked by other protein substrates present in the bacterial expression system. Here we present a new purification protocol designed to provide highly pure GroEL devoid of non-specific protein substrate contamination.

GroEL PCR- RFLP - An efficient tool to discriminate closely related pathogenic Vibrio species.

Vibrio sp. are autochthonous to marine and estuarine waters. Several species of Vibrio are pathogens. It is of utmost importance to detect and discriminate the Vibrio sp. that are often involved in food and water borne infections. Since 16S rRNA based identification has limited utility in differentiating the closely related pathogenic species from non pathogenic species, we have evaluated the discriminatory power of groEL PCR-RFLP for identification of closely related Vibrio sp. Accordingly, in the current study, the efficiency of groEL PCR- RFLP for detection and accurate differentiation of known pathogens among Vibrio sp. such as V. cholerae, V. parahaemolyticus, V. vulnificus, V. mimicus, V. fluvialis, V. alginolyticus, V. anguillarum was evaluated. PCR amplified groEL gene fragment of each Vibrio sp. was digested separately using 5 restriction enzymes viz. Hha1, Rsa1, Alu1, Dde1 and Mbo1. The accuracy of the method was further validated by insilico restriction analysis of multiple strains of each species using NEBcutter. The method proved to be efficient for detection and differentiation of Vibrio species under study. Phylogenetic analysis also revealed groEL gene to be a better phylogenetic marker for Vibrio compared to 16S rRNA. Hence, the method can be employed for accurate detection of Vibrio sp. including the closely related species.

Affinity chromatography of chaperones based on denatured proteins: Analysis of cell lysates of different origin.

Molecular chaperones are involved in folding, oligomerization, transport, and degradation of numerous cellular proteins. Most of chaperones are heat-shock proteins (HSPs). A number of diseases of various organisms are accompanied by changes in the structure and functional activity of chaperones, thereby revealing their vital importance. One of the fundamental properties of chaperones is their ability to bind polypeptides lacking a rigid spatial structure. Here, we demonstrate that affinity chromatography using sorbents with covalently attached denatured proteins allows effective purification and quantitative assessment of their bound protein partners. Using pure Escherichia coli chaperone GroEL (Hsp60), the capacity of denatured pepsin or lysozyme-based affinity sorbents was evaluated as 1 mg and 1.4 mg of GroEL per 1 ml of sorbent, respectively. Cell lysates of bacteria (E. coli, Thermus thermophilus, and Yersinia pseudotuberculosis), archaea (Halorubrum lacusprofundi) as well as the lysate of rat liver mitochondria were analyzed using affinity carrier with denatured lysozyme. It was found that, apart from Hsp60, other proteins with a molecular weight of about 100, 50, 40, and 20 kDa are able to interact with denatured lysozyme.

Recombinant human HSP60 produced in ClearColi™ BL21(DE3) does not activate the NFκB pathway.

HSP60, an intracellular molecular chaperone has been largely described as an alarmin or damage-associated molecular pattern when released outside the cell. HSP60 has been reported as a possible ligand of TLR2 or TLR4 inducing NFκB-dependant signaling pathway leading to cytokine secretion. However, recent publications suggested that HSP60 could not act as an activator of TLR4 by itself. The observed effect could be due to the presence of endotoxin in HSP60 preparation especially LPS. In order to clarify the controversy, we produced recombinant human HSP60 in two different strains of Escherichia coli, standard strain for protein overproduction, BL21(DE3), and the new ClearColi BL21(DE3) strain which lacks LPS-activity through TLR4. Undoubtedly, we have shown that recombinant HSP60 by itself was not able to induce NFκB-dependant signaling pathway in a model of THP1 monocyte cell line. Our data suggest that HSP60 needs either pathogen-associated molecules, specific post-translational modification and/or other host factors to activate immune cells via NFκB activation.

Identification of differentially expressed water-insoluble proteins in the encystment process of Colpoda cucullus by two-dimensional electrophoresis and LC-MS/MS analysis.

In the encystment process of the ciliate protist Colpoda cucullus, we observed that the cell total protein abundance was reduced at 12 h-1 d after the onset of encystment induction subsequent to the reduction in mRNA abundance. We analyzed the alteration of the expression levels of water-insoluble proteins by two-dimensional polyacrylamide gel electrophoresis using polyoxyethylene (20) sorbitan monooleate (Tween-80), and we identified proteins whose expression levels were altered in the encystment process by a liquid chromatography tandem mass spectrometry analysis. The expression level of a 60-kDa protein (p60; heat shock protein 60) was temporarily enhanced and that of a 55-kDa protein (p55; actin) and a 49-kDa protein (p49; actin) was enhanced in the Colpoda encystment process. In mature cysts, the expression level of p55 and p49 tended to be reduced, whereas the expression level of a 50-kDa protein (p50d; α-tubulin), a 25-kDa protein (p25; α-tubulin) and a 52-kDa protein (p52c; ß-tubulin) was enhanced.

An insecticidal protein from Xenorhabdus ehlersii triggers prophenoloxidase activation and hemocyte decrease in Galleria mellonella.

The bacteria Xenorhabdus spp. are entomopathogenic symbionts that can produce several toxic proteins that interfere the immune system of insects. We purified an insecticidal protein from Xenorhabdus ehlersii, and designated it as XeGroEL with an estimated molecular mass of ~58 kDa. Galleria mellonella larva injected with XeGroEL presented prophenoloxidase activation and hemocyte decrease. XeGroEL can kill G. mellonella larva in 48 h with an LD(50) of 0.76 ± 0.08 µg/larva. Our results demonstrate that X. ehlersii possesses a toxic XeGroEL protein acting as a potential factor to activate proPO in host insect, which also provides a meaningful hypothesis to understand the interaction between nematode-symbiotic bacteria and host.

Heat shock protein 60 of filarial parasite Brugia malayi: cDNA cloning, expression, purification and in silico modeling and analysis of its ATP binding site.

We report here cloning and expression of full length mitochondrial HSP60 gene of Brugia malayi adult worm (mtHSP60bm), purification of the gene product by affinity chromatography, its in silico 3D structure and the sequence homology of the protein with Escherichia coli GroEL/ES and human HSP60. The ATP binding pocket of human HSP60 and mtHSP60bm were analyzed and compared using in silico models. The distribution of HSP60 in different life-stages of the parasite was determined using antibodies raised against recombinant mtHSP60bm (rmtHSP60bm). mtHSP60bm was present in all life-stages of the parasite except third stage infective larvae, in which it could be induced by heat-shock, and showed high degree of homology with E. coli GroEL/ES. The ATP binding pocket of HSP60 in humans, E. coli and B. malayi were also found structurally conserved. This similarity between human and mtHSP60bm might be useful in understanding the host-parasite interactions. This is the first ever report on distribution, cloning, sequence homology and ATP binding site of mtHSP60bm.

An insecticidal protein from Xenorhabdus budapestensis that results in prophenoloxidase activation in the wax moth, Galleria mellonella.

Xenorhabdus budapestensis can produce a variety of proteins that help this bacterium and its mutualistic nematode vector kill the host insect. In this report, we purified one protein fraction from the intracellular extract of X. budapestensis D43, which was designated HIP57. By injection, HIP57 caused Galleria mellonella larval bodies to blacken and die with an LD(50) of 206.81 ng/larva. Analyzes of HIP57 by two-dimensional gel electrophoresis showed that this protein was a single spot on the gel with a molecular weight of 57 kDa and a pI of ∼5. Sequencing and bioinformatic analysis suggested that the HIP57 toxin was homologous to GroEL. GroEL has been accepted as molecule chaperon; however, our research revealed that HIP57 (GroEL) possesses another novel function as an insecticide. A GroEL phylogenetic tree defined the relationship among the related species of mutualistic bacteria (Xenorhabdus and Photorhabdus) from the entomopathogenic nematodes and the evolution within the family Enterobacteriaceae. Thus, GroEL could be a complement to 16S rDNA for studying the molecular phylogenies of the family Enterobacteriaceae. Phenoloxidase (PO) activity analysis of G. mellonella larvae injected with HIP57 suggested that the toxin activates the PO cascade, which provides an extensive defense reaction that potentially responsible for G. mellonella larval death.

Immunodetection of the recombinant GroEL by the Nanobody NbBruc02.

Brucella has a great impact on health and economy in Syria, thus much effort is being placed on the development of diagnostics and vaccines. In this context, a wide Nanobody "immune" library was previously established, from which several Brucella-specific binders were isolated. One of these camel genetically engineered heavy-chain antibody fragments was referred to as NbBruc02. The precise antigen of NbBruc02 was presumed to be, according to proteomic approaches, the Brucella heat shock protein of 60 kDa (HSP-60). HSP-60, or alternatively named GroEL, is an interesting Brucella immunodominant antigen with important roles in the parasite life cycle, mainly adhesion and penetration during the infection of macrophages. In the present work, the capacity of NbBruc02 to filtrate the native GroEL from Brucella total extract was tested by immunochromatography approach. The interaction between NbBruc02 and its antigen was further confirmed using recombinant GroEL from Brucella. Interestingly, NbBruc02 was able to immunodetect the native as well as the denatured forms of the rGroEL in ELISA and immunoblotting, respectively. In agreement with previously reported data, NbBruc02 was able only to detect the denatured Yersinia rGroEL. Using surface plasmon resonance (SPR) biosensor, NbBruc02 showed a strong interaction, with nanomolar affinity (K (D) = ~10(-8) M), with the native rGroEL of Brucella and not of Yersinia. Because the casual conformational changes in the GroEL 3D structure make the base of its function, NbBruc02 by its ability to recognize a "conformational epitope," could open wide perspectives to study the role of GroEL in Brucella physiology.

Differential expression of LvHSP60 in shrimp in response to environmental stress.

Previous studies showed that heat-shock protein 60 (HSP60) was known to function as a molecular chaperone and is an important factor in the innate immune system in mammals. However, little was known about the physiological relevance of HSP60 in marine invertebrates. This study focuses on long-term monitoring of the differential expression of LvHSP60 in shrimp Litopenaeus vannamei in response to environmental stress. The thermal aggregation assay elucidated that LvHSP60 was an effective chaperone. It also suggested that LvHSP60 may employ the cell's intrinsic mechanism to start the immunizing process. Using quantitative real-time PCR to monitor gene expression showed that LvHSP60 was variable under different stresses including environmental stress and pathogenic infection. LvHSP60 was speculated to regulate the adaptive responses to overcome environmental stresses. In conclusion, our study proved that LvHSP60 plays an important role in the intrinsic immune system and stress responses of shrimp.

Separating and visualising protein assemblies by means of preparative mass spectrometry and microscopy.

Many multi-protein assemblies exhibit characteristics which hamper their structural and dynamical characterization. These impediments include low copy number, heterogeneity, polydispersity, hydrophobicity, and intrinsic disorder. It is becoming increasingly apparent that both novel and hybrid structural biology approaches need to be developed to tackle the most challenging targets. Nanoelectrospray mass spectrometry has matured over the last decade to enable the elucidation of connectivity and composition of large protein assemblies. Moreover, comparing mass spectrometry data with transmission electron microscopy images has enabled the mapping of subunits within topological models. Here we describe a preparative form of mass spectrometry designed to isolate specific protein complexes from within a heterogeneous ensemble, and to 'soft-land' these target complexes for ex situ imaging. By building a retractable probe incorporating a versatile target holder, and modifying the ion optics of a commercial mass spectrometer, we show that we can steer the macromolecular ion beam onto a target for imaging by means of transmission electron microscopy and atomic force microscopy. Our data for the tetradecameric chaperonin GroEL show that not only are the molecular volumes of the landed particles consistent with the overall dimensions of the complex, but also that their gross topological features can be maintained.

Expression and purification of secreted recombinant hsp60 from eukaryotic cells.

Human heat shock protein 60 (hsp60) is a mitochondrial protein that functions as a molecular chaperone. Recently, it has been observed that hsp60 can become exposed on the cell surface and released into the extracellular space. Extracellular hsp60 is thought to function as a danger signal that activates the immune response. However, concerns have been raised that the effects of recombinant hsp60 on cytokines might be the result of contamination with bacterial components, given that the recombinant hsp60 protein used in these studies was produced with a bacterial expression system. In the present study, recombinant hsp60 was produced using a eukaryotic expression system, and the resulting protein was purified. The results obtained demonstrated that recombinant hsp60 was secreted efficiently from cells when fused to the leader peptide of interleukin-2 and the secreted protein was modified by N-linked glycosylation. Furthermore, we successfully obtained unglycosylated recombinant protein that was capable of binding to macrophages.

Purification of clinical-grade recombinant HSP65-MUCI fusion protein.

HSP65-MUCI is a fusion protein between BCG (Bacille Calmette-Guerin)-derived HSP65 (heat-shock protein 65) and human MUCI (mucin I) VNTR (variable number of tandem repeats)-domain peptides that has shown antitumour efficacy. China's Food and Drug Administration has recently approved a Phase I clinical trial using HSP65-MUCI for the treatment of MUCI-positive breast cancer. In order to produce sufficient quantities of clinical-grade HSP65-MUCI, we established a pilot-scale purification scheme comprising two steps of column chromatography: HIC (hydrophobic-interaction chromatography) and IEX (ion-exchange chromatography). The pH values of the buffers used in homogenization and HIC were adjusted to pH 9.0 to maintain protein stability and prevent protein degradation. Using this manufacturing process, we obtained clinical-grade HSP65-MUCI with a yield of 400 mg per 70 g of wet cell pellet and >96% purity.

Fusion of barnase to antiferritin antibody F11 VH domain results in a partially folded functionally active protein.

A chimeric protein, VH-barnase, was obtained by fusing the VH domain of anti-human ferritin monoclonal antibody F11 to barnase, a bacterial RNase from Bacillus amyloliquefaciens. After refolding from inclusion bodies, the fusion protein formed insoluble aggregates. Off-pathway aggregation was significantly reduced by adding either purified GroEL/GroES chaperones or arginine, with 10-12-fold increase in the yield of the soluble protein. The final protein conformation was identical by calorimetric criteria and CD and fluorescence spectroscopy to that obtained without additives, thus suggesting that VH-barnase structure does not depend on folding conditions. Folding of VH-barnase resulted in a single calorimetrically revealed folding unit, the so-called "calorimetric domain", with conformation consistent with a molten globule that possessed well-defined secondary structure and compact tertiary conformation with partial exposure of hydrophobic patches and low thermodynamic stability. The unique feature of VH-barnase is that, despite the partially unfolded conformation and coupling into a single "calorimetric domain", this immunofusion retained both the antigen-binding and RNase activities that belong to the two heterologous domains.

Detection and separation of heterogeneity in molecular complexes by statistical analysis of their two-dimensional projections.

Progress in molecular structure determination by cryo electron microscopy and single particle analysis has led to improvements in the resolution achievable. However, in many cases the limiting factor is structural heterogeneity of the sample. To address this problem, we have developed a method based on statistical analysis of the two-dimensional images to detect and sort localised structural variations caused, for example, by variable occupancy of a ligand. Images are sorted by two consecutive stages of multivariate statistical analysis (MSA) to dissect out the two main sources of variation, namely out of plane orientation and local structural changes. Heterogeneity caused by local changes is detected by MSA that reveals significant peaks in the higher order eigenimages. The eigenimages revealing local peaks are used for automated classification. Evaluation of differences between classes allows discrimination of molecular images with and without ligand. This method is very rapid, independent of any initial three-dimensional model, and can detect even minor subpopulations in an image ensemble. A strategy for using this technique was developed on model data sets. Here, we demonstrate the successful application of this method to both model and real EM data on chaperonin-substrate and ribosome-ligand complexes.

A femtomolar-acting neuroprotective peptide.

A novel 14-amino acid peptide, with stress-protein-like sequences, exhibiting neuroprotection at unprecedented concentrations, is revealed. This peptide prevented neuronal cell death associated with the envelope protein (GP 120) from HIV, with excitotoxicity (N-methyl d-aspartate), with the beta amyloid peptide (putative cytotoxin in Alzheimer's disease), and with tetrodotoxin (electrical blockade). The peptide was designed to contain a sequence derived from a new neuroprotective protein secreted by astroglial cells in the presence of vasoactive intestinal peptide. The neurotrophic protein was isolated by sequential chromatographic methods combining ion exchange, size separation, and hydrophobic interaction. The protein (mol mass, 14 kD and pI, 8.3 +/- 0.25) was named activity-dependent neurotrophic factor, as it protected neurons from death associated with electrical blockade. Peptide sequencing led to the synthesis of the novel 14-amino acid peptide that was homologous, but not identical, to an intracellular stress protein, heat shock protein 60. Neutralizing antiserum to heat shock protein 60 produced neuronal cell death that could be prevented by cotreatment with the novel protein, suggesting the existence of extracellular stress-like proteins with neuroprotective properties. These studies identify a potent neuroprotective glial protein and an active peptide that provide a basis for developing treatments of currently intractable neurodegenerative diseases.

Purification, crystallization and structure determination of native GroEL from Escherichia coli lacking bound potassium ions.

GroEL is a member of the ATP-dependent chaperonin family that promotes the proper folding of many cytosolic bacterial proteins. The structures of GroEL in a variety of different states have been determined using X-ray crystallography and cryo-electron microscopy. In this study, a 3.02 A crystal structure of the native GroEL complex from Escherichia coli is presented. The complex was purified and crystallized in the absence of potassium ions, which allowed evaluation of the structural changes that may occur in response to cognate potassium-ion binding by comparison to the previously determined wild-type GroEL structure (PDB code 1xck), in which potassium ions were observed in all 14 subunits. In general, the structure is similar to the previously determined wild-type GroEL crystal structure with some differences in regard to temperature-factor distribution.

Chloroplast heat shock protein Cpn60 from Chlamydomonas reinhardtii exhibits a novel function as a group II intron-specific RNA-binding protein.

Intron-binding proteins in eukaryotic organelles are mainly encoded by the nuclear genome and are thought to promote the maturation of precursor RNAs. Here, we present a biochemical approach that enable the isolation of a novel nuclear-encoded protein from Chlamydomonas reinhardtii showing specific binding properties to organelle group II intron RNA. Using FPLC chromatography of chloroplast protein extracts, a 61-kDa RNA-binding protein was isolated and then tentatively identified by mass spectrometry as the chloroplast heat shock protein Cpn60. Heterologous Cpn60 protein was used in RNA protein gel mobility shift assays and revealed that the ATPase domains of Cpn60 mediates the specific binding of two group II intron RNAs, derived from the homologous chloroplast psaA gene and the heterologous mitochondrial LSU rRNA gene. The function of Cpn60 as a general organelle splicing factor is discussed.

Bacterial Heat Shock Protein GroEL (Hsp64) Exerts Immunoregulatory Effects on T Cells by Utilizing Apoptosis.

Aggregatibacter actinomycetemcomitans (Aa) expresses a 64-kDa GroEL protein belonging to the heat shock family of proteins. This protein has been shown to influence human host cells, but the apoptotic capacity of the GroEL protein regarding T cells is not yet known. The purpose of this study was to investigate the ability of A. actinomycetemcomitans GroEL (AaGroEL) protein to induce human peripheral blood T-cell apoptosis. Endogenous, purified AaGroEL protein was used as an antigen. In AaGroEL-treated T cells, the data indicated that phosphatidylserine exposure, an early apoptotic event, was dose- and time-dependent. The AaGroEL-treated T cells were also positive for active caspase-3 in a dose-dependent manner. The rate of AaGroEL-induced apoptosis was suppressed by the addition of the general caspase inhibitor Z-VAD-FMK. Furthermore, cleaved caspase-8 bands (40/36 kDa and 23 kDa) were identified in cells responding to AaGroEL. DNA fragmentation was also detected in the AaGroEL-treated T cells. Overall, we demonstrated that the endogenous GroEL from A. actinomycetemcomitans has the capacity to induce T-cell apoptosis.

Isolation and biochemical characterization of highly purified Escherichia coli molecular chaperone Cpn60 (GroEL) by affinity chromatography and urea-induced monomerization.

Isolated Escherichia coli molecular chaperone Cpn60 (GroEL) has been further purified from tightly bound substrate polypeptides by two different procedures: (i) group-specific affinity chromatography by using the triazine dye Procion yellow HE-3G as affinity ligand, and (ii) urea-induced monomerization and subsequent chromatography. Procion yellow binds specifically to aromatic amino-acid side chains present in the majority of proteins, but has no affinity to GroEL because of its low content of aromatic residues. Some GroEL-bound polypeptides are buried within the aqueous cavity of the GroEL oligomer, whereas others are exposed on its surface and available for affinity-ligand interactions and the complex is thereby retarded on Procion yellow columns. Pure substrate-free GroEL was obtained after ion-exchange chromatography of GroEL monomers followed by reassembly of the purified monomers into functional GroEL oligomers. The final preparation contained no substrate polypeptides bound to GroEL as judged by electrophoretic analysis and lack of tryptophan fluorescence. GroEL preparations also displayed two equally strong bands on native electrophoresis suggesting the presence of two conformers. Monomers of GroEL showed heterogeneity with respect to isoelectric point and molecular mass when analysed by MALDI-MS and electrophoresis under native and denaturing conditions respectively. By use of MALDI-MS, highly accurate molecular masses of wild-type and a truncated form of GroEL were determined and verified, by comparison with their respective gene sequences.