Molecular Chaperones: The Plant Connection

Protein-mediated protein maturation in eukaryotes

Eukaryotic cells have developed particular strategies to support the critical steps in protein maturation that starts in the cytosol with the birth of a nascent polypeptide chain, and ends when the protein has reached the appropriate compartment and/or has attained its mature structure. Many of the cellular proteins that have evolved to promote maturation processes are constitutively expressed members of the highly conserved heat shock protein (hsp) family, also known as 'molecular chaperones'. Protein-mediated processes that occur in the cytosol are discussed.

The chaperonin containing t-complex polypeptide 1 (TCP-1). Multisubunit machinery assisting in protein folding and assembly in the eukaryotic cytosol

Many proteins in the cell require assistance from molecular chaperones at stages in their life cycles in order to attain correctly folded states and functional conformations during protein synthesis or during recovery from denatured states. A recently discovered molecular chaperone, which is abundant in the eukaryotic cytosol and is called the chaperonin containing TCP-1 (CCT), has been shown to assist the folding of some proteins in cytosol. This chaperone is a member of the chaperonin family which includes GroEL, 60-kDa heat shock protein (Hsp60), Rubisco subunit binding protein (RBP) and thermophilic factor 55 (TF55), but is distinct from the other members in several respects. Presently the most intriguing feature is the hetero-oligomeric nature of the CCT; at least eight subunit species which are encoded by independent and highly diverged genes are known. These genes are calculated to have diverged around the starting point of the eukaryotic lineage and they are maintained in all eukaryotes investigated, suggesting a specific function for each subunit species. The amino acid sequences of these subunits share approximately 30% identity and have some highly conserved motifs probably responsible for ATPase function, suggesting this function is common to all subunits. Thus, each subunit is thought to have both specific and common functions. These observations, in conjunction with biochemical and genetic analysis, suggest that CCT functions as a very complex machinery for protein folding in the eukaryotic cell and that its chaperone activity may be essential for the folding and assembly of various newly synthesized polypeptides. This complex behaviour of CCT may have evolved to cope with the folding and assembly of certain highly evolved proteins in eukaryotic cells.

A chloroplast homologue of the signal recognition particle subunit SRP54 is involved in the posttranslational integration of a protein into thylakoid membranes

The mechanisms involved in the integration of proteins into the thylakoid membrane are largely unknown. However, many of the steps of this process for the light-harvesting chlorophyll a/b protein (LHCP) have been described and reconstituted in vitro. LHCP is synthesized as a precursor in the cytosol and posttranslationally imported into chloroplasts. Upon translocation across the envelope membranes, the N-terminal transit peptide is cleaved, and the apoprotein is assembled into a soluble "transit complex" and then integrated into the thylakoid membrane via three transmembrane helices. Here we show that 54CP, a chloroplast homologue of the 54-kDa subunit of the mammalian signal recognition particle (SRP54), is essential for transit complex formation, is present in the complex, and is required for LHCP integration into the thylakoid membrane. Our data indicate that 54CP functions posttranslationally as a molecular chaperone and potentially pilots LHCP to the thylakoids. These results demonstrate that one of several pathways for protein routing to the thylakoids is homologous to the SRP pathway and point to a common evolutionary origin for the protein transport systems of the endoplasmic reticulum and the thylakoid membrane.

Molecular analysis of Caenorhabditis elegans tcp-1, a gene encoding a chaperonin protein

A Caenorhabditis elegans (Ce) homologue to the eukaryotic tcp-1 gene (encoding t-complex polypeptide-1) has been mapped, isolated and sequenced. Ce tcp-1 is a single-copy gene located on chromosome II. Nucleotide sequence analysis of the gene reveals the presence of four introns in the coding region and repetitive elements upstream from the start codon. The predicted Ce TCP-1 protein displays more than 60% amino-acid sequence identity to other eukaryotic TCP-1, suggesting a common origin and function for these proteins. The primary tcp-1 transcript undergoes trans-splicing to the spliced leader SL1 RNA, in addition to cis-splicing, to yield a single mRNA species of 1.9 kb. Northern blot analysis shows that unlike the evolutionarily related Hsp60 chaperonin genes, tcp-1 is not upregulated at elevated temperatures, but instead appears to be down-regulated. Additionally, the overall level of the tcp-1 transcript is approximately constant throughout the development of the nematode. The Ce chaperonin-containing TCP-1 (CCT) was identified. A protein extract made from Ce embryos was subjected to sucrose gradient fractionation and ATP-agarose chromatography. Western blot analysis of the purified protein fractions, using anti-mouse TCP-1 monoclonal antibody and antibodies raised against Ce TCP-1, reveals that Ce TCP-1 is a 57-kDa protein subunit of a high-molecular-mass complex capable of binding ATP.

Enzymatic product formation impairs both the chloroplast receptor-binding function as well as translocation competence of the NADPH: protochlorophyllide oxidoreductase, a nuclear-encoded plastid precursor protein

The key enzyme of chlorophyll biosynthesis in higher plants, the light-dependent NADPH:protochlorophyllide oxidoreductase (POR, EC 1.6.99.1), is a nuclear-encoded plastid protein. Its posttranslational transport into plastids of barley depends on the intraplastidic availability of one of its substrates, protochlorophyllide (PChlide). The precursor of POR (pPOR), synthesized from a corresponding full-length barley cDNA clone by coupling in vitro transcription and translation, is enzymatically active and converts PChlide to chlorophyllide (Chlide) in a light- and NADPH-dependent manner. Chlorophyllide formed catalytically remains tightly but noncovalently bound to the precursor protein and stabilizes a transport-incompetent conformation of pPOR. As shown by in vitro processing experiments, the chloroplast transit peptide in the Chlide-pPOR complex appears to be masked and thus is unable to physically interact with the outer plastid envelope membrane. In contrast, the chloroplast transit peptide in the naked pPOR (without its substrates and its product attached to it) and in the pPOR-substrate complexes, such as pPOR-PChlide or pPOR-PChlide-NADPH, seems to react independently of the mature region of the polypeptide, and thus is able to bind to the plastid envelope. When envelope-bound pPOR-PChlide-NADPH complexes were exposed to light during a short preincubation, the enzymatically produced Chlide slowed down the actual translocation step, giving rise to the sequential appearance of two partially processed translocation intermediates. However, ongoing translocation induced by feeding the chloroplasts delta-aminolevulinic acid, a precursor of PChlide, was able to override these two early blocks in translocation, suggesting that the plastid import machinery has a substantial capacity to denature a tightly folded, envelope-bound precursor protein. Together, our results show that pPOR with Chlide attached to it is impaired both in the ATP-dependent step of binding to a receptor protein component of the outer chloroplast envelope membrane, as well as in the PChlide-dependent step of precursor translocation.

Expression in Escherichia coli, purification and functional activity of recombinant human chaperonin 10

We have recently reported the cloning of a cDNA coding for a stress inducible human chaperonin 10. The protein was shown to possess 100% identity with the bovine homologue and a single amino acid replacement (glycine to serine at position 52) compared to rat chaperonin 10. Here we report the heterologous expression of human chaperonin 10 in Escherichia coli, its purification and its functional characterization. The recombinant protein was purified to homogeneity as judged by different analytical techniques, and mass spectrometry analysis showed a MW of 10,801 Da in agreement with the predicted sequence. This molecular weight accounts for a protein which is not modified post-translationally. In fact, natural rat chaperonin 10 has been shown to be acetylated at the N-terminus, a feature suggested to be important for targeting and functional activity. Here we show that recombinant human chaperonin 10 is fully active in assisting the chaperonin 60 GroEL in the refolding of denatured yeast enolase, thereby showing that, at least in the present system, post-translational acetylation is not necessary for its activity.

Primary structure of the thermosome from Thermoplasma acidophilum

The thermosome, a chaperonin from the archaebacterium Thermoplasma acidophilum, consists of two subunits (M(r) 58,000 and 60,000) which assemble into a cylindrical complex of pseudo eight-fold rotational symmetry. The sequences of the two subunits are approximately 60% identical to each other and to TF55 from Sulfolobus shibatae, and are 30-40% identical to the subunits of the TCP1 containing ring complex (TRiC) from the eukaryotic cytosol. A dendrogram of this family of chaperonins contains eight eukaryotic branches of TRiC subunits and one archaebacterial branch of thermosome subunits. Alignment of thermosome/TRiC sequences with eubacterial and eukaryotic Hsp60 sequences reveals a statistically significant similarity in two large N- and C-terminal blocks of sequence. Based on this alignment and on the recently published crystal structure of GroEL, we propose that subunits of the thermosome/TRiC family of chaperonins have a similar equatorial domain and overall domain topology as GroEL but differ in the structure of the apical domain.

A mutation in the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase that reduces the rate of its incorporation into holoenzyme

A mutant of the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco), in which Arg53 is replaced by Glu, was synthesized and imported into isolated chloroplasts. The mutant protein was efficiently imported into the chloroplast and correctly processed to the mature size. Like the wild type protein, it was stable over a period of at least 2 h. Unlike the wilk-type protein however, most of the mutant protein was not assembled with holo-Rubisco at the end of a 10-min import reaction. It migrated instead as a diffused band on a non-denaturing gel, slower than the precursor protein, but faster than the holoenzyme. The level of the unassembled mutant protein in the stroma decreased with time, while its level in the assembled fraction has increased, indicating that this protein is a slowly-assembled, rather than a non-assembled, mutant of the small suubunit of Rubisco. Accumulation of the mutant protein in the holoenzyme fraction was dependent on ATP and light. The transient species, migrating faster than the holoenzyme but slower than the precursor protein, may represent an intermediate in the assembly process of the small subunit of Rubisco.

Expression of the axolotl homologue of mouse chaperonin t-complex protein-1 during early development

Molecular chaperones assist in the folding of proteins, but their role during development is not well understood. Here we report the temporal and spatial expression pattern of the axolotl homologue of mouse chaperonin TCP-1 during normal amphibian embryogenesis and in several models of abnormal embryogenesis. A partial axolotl TCP-1 cDNA (646 bp; 519 coding bp) isolated by 3' RACE PCR shows considerable homology to mouse TCP-1. Developmental Northerns and RT-PCR analyses of whole axolot1 embryos revealed a low level of maternal TCP-1 transcripts in fertilized eggs. The maternal transcripts were down-regulated to a non-detectable level in early gastrulae. Zygotic TCP-1 transcripts first appeared during gastrulation. They were mainly expressed in mid-neurula and later stage embryos. Whole-mount in situ hybridization studies showed abundant TCP-1 transcripts in the blastopore at the mid-gastrula stage and in the brain and spinal cord beginning at the neurula stage, and in the somites (myotomes) at the tailbud stage. RT-PCR analysis of TCP-1 expression in axolotl embryos treated with either high salt (causing exogastrulation) or ultraviolet (UV) irradiation (causing ventralization) substantiated the correlation between TCP-1 expression and neural and somitic development. In high salt-induced exogastrulated embryos TCP-1 mRNA was detectable in the ectoderm part (with neural tissues) but not in its exogastrulated endoderm part. Lower levels of TCP-1 expression were detected in UV-irradiated, ventralized embryos with smaller head and reduced neural and somitic tissues. Normal levels of TCP-1 expression were detected in embryos with double axes/heads. These studies provide strong evidence that at the transcript level axolotl chaperonin TCP-1 is regulated both temporally and spatially during embryogenesis, especially in neural and somitic development.

Evolution of the chaperonin families (Hsp60, Hsp10 and Tcp-1) of proteins and the origin of eukaryotic cells

The members of the 10 kDa and 60 kDa heat-shock chaperonin proteins (Hsp10 and Hsp60 or Cpn10 and Cpn60), which form an operon in bacteria, are present in all eubacteria and eukaryotic cell organelles such as mitochondria and chloroplasts. In archaebacteria and eukaryotic cell cytosol, no close homologues of Hsp10 or Hsp60 have been identified. However, these species (or cell compartments) contain the Tcp-1 family of proteins (distant homologues of Hsp60). Phylogenetic analysis based on global alignments of Hsp60 and Hsp10 sequences presented here provide some evidence regarding the evolution of mitochondria from a member of the alpha-subdivision of Gram-negative bacteria and chloroplasts from cyanobacterial species, respectively. This interference is strengthened by the presence of sequence signatures that are uniquely shared between Hsp60 homologues from alpha-purple bacteria and mitochondria on one hand, and the chloroplasts and cyanobacterial hsp60s on the other. Within the alpha-purple subdivision, species such as Rickettsia and Ehrlichia, which live intracellularly within eukaryotic cells, are indicated to be the closest relatives of mitochondrial homologues. In the Hsp60 evolutionary tree, rooted using the Tcp-1 homologue, the order of branching of the major groups was as follows: Gram-positive bacteria--cyanobacteria and chloroplasts--chlamydiae and spirochaetes--beta- and gamma-Gram-negative purple bacteria--alpha-purple bacteria--mitochondria. A similar branching order was observed independently in the Hsp10 tree. Multiple Hsp60 homologues, when present in a group of species, were found to be clustered together in the trees, indicating that they evolved by independent gene-duplication events. This review also considers in detail the evolutionary relationship between Hsp60 and Tcp-1 families of proteins based on two different models (viz. archaebacterial and chimeric) for the origin of eukaryotic cell nucleus. Some predictions of the chimeric model are also discussed.

The essential yeast Tcp1 protein affects actin and microtubules

Previously, we showed that the yeast Saccharomyces cerevisiae cold-sensitive mutation tcp1-1 confers growth arrest concomitant with cytoskeletal disorganization and disruption of microtubule-mediated processes. We have identified two new recessive mutations, tcp1-2 and tcp1-3, that confer heat- and cold-sensitive growth. Cells carrying tcp1 alleles were analyzed after exposure to the appropriate restrictive temperatures by cell viability tests, differential contrast microscopy, fluorescent, and immunofluorescent microscopy of DNA, tubulin, and actin and by determining the DNA content per cell. All three mutations conferred unique phenotypes indicative of cytoskeletal dysfunction. A causal relationship between loss of Tcp1p function and the development of cytoskeletal abnormalities was established by double mutant analyses. Novel phenotypes indicative of allele-specific genetic interactions were observed when tcp1-1 was combined in the same strain with tub1-1, tub2-402, act1-1, and act1-4, but not with other tubulin or actin mutations or with mutations in other genes affecting the cytoskeleton. Also, overproduction of wild-type Tcp1p partially suppressed growth defects conferred by act1-1 and act1-4. Furthermore, Tcp1p was localized to the cytoplasm and the cell cortex. Based on our results, we propose that Tcp1p is required for normal development and function of actin and microtubules either through direct or indirect interaction with the major cytoskeletal components.

A yeast TCP-1-like protein is required for actin function in vivo

We previously identified the ANC2 gene in a screen for mutations that enhance the defects caused by yeast actin mutations. Here we report that ANC2 is an essential gene that encodes a member of the TCP-1 family. TCP-1-related proteins are subunits of cytosolic heteromeric protein complexes referred to as chaperonins. These complexes can bind to newly synthesized actin and tubulin in vitro and can convert these proteins into an assembly-competent state. We show that anc2-1 mutants contain abnormal and disorganized actin structures, are defective in cellular morphogenesis, and are hypersensitive to the microtubule inhibitor benomyl. Furthermore, overexpression of wild-type Anc2p ameliorates defects in actin organization and cell growth caused by actin overproduction. Mutations in BIN2 and BIN3, two other genes that encode TCP-1-like proteins, also enhance the phenotypes of actin mutants. Taken together, these findings demonstrate that TCP-1-like proteins are required for actin and tubulin function in vivo.

Identification and cloning of human chaperonin 10 homologue

We have identified a heat-shock-inducible 10 kDa protein in the human hepatoma cell line HepG2. The total RNA extracted from the heat-shocked cells was amplified by reverse transcription PCR (polymerase chain reaction) using 21 5' and 18 3' oligonucleotides of rat cpn10 (chaperonin10) cDNA as primers. Sequencing of the above PCR fragment showed a very high homology between human, bovine and rat cpn10 cDNA. The predicted amino acid sequence revealed a 100% identity with the bovine homologue.

Molecular chaperones. Opening and closing the Anfinsen cage

Dynamic interactions between chaperonins allow newly synthesized polypeptides to begin correct folding inside a transiently closed cage. Specialized chaperonins may be used to deal with recalcitrant proteins.

Reversible membrane association of heat-shock protein 22 in Chlamydomonas reinhardtii during heat shock and recovery

The process of reversible membrane association of the nuclear-encoded heat-shock protein hsp22 in Chlamydomonas reinhardtii cells during recovery from heat stress has been investigated. hsp22 associates with a chloroplast membrane-enriched fraction, dissociates from the membranes during recovery from heat shock and rebinds during a subsequent heat-shock treatment in vivo. The protein remains in the cell soluble fraction for at least 22 h after heat-stress treatment. Dissociation of membrane-bound hsp22 occurs only at 25-38 degrees C and reassociation occurs only at the hsp22 induction temperature (38-42 degrees C). Hsp22 dissociation from the membrane fraction is not related to de novo protein synthesis in vivo and does not occur in vitro. Based on the derived amino acid sequence, hsp22 is not considered a typical chloroplast-associated heat-shock protein [Vierling, E. (1991) Annu. Rev. Plant Physiol. Plant Mol. Biol. 42, 579-620] and may be associated with the chloroplast envelope membrane. However, the reversible association of hsp22 with the chloroplast-enriched membrane fraction indicates similar properties to those of pea low-molecular-mass heat-shock proteins [Glaczinski, H. & Kloppstech, K. (1988) Eur. J. Biochem. 173, 579-583] and may be related to the transient response of the chloroplast to heat stress.

Translational regulation of the heat shock response

All organisms from bacteria to man respond to an exposure to higher than physiological temperatures by reprogramming their gene expression, leading to the increased synthesis of a unique set of proteins termed heat shock proteins (hsps). The hsps function as molecular chaperones in both normal and stressed cells. The rapid and efficient synthesis of hsps is achieved as a result of changes occurring at gene transcription, RNA processing and degradation, and mRNA translation. With regard to the translational regulation, the emerging picture is that the two key steps of polypeptide chain initiation, namely mRNA binding and Met-tRNA(i) binding to ribosomes, are regulated in heat-shocked mammalian cells. In Drosophila, mRNA binding is regulated by a structural feature of the leader of heat shock mRNAs and by the inactivation of eukaryotic initiation factor- (eIF-) 4F. No clear evidence for changes in Met-tRNA(i) binding has been obtained yet.

A eukaryotic cytosolic chaperonin is associated with a high molecular weight intermediate in the assembly of hepatitis B virus capsid, a multimeric particle

We have established a system for assembly of hepatitis B virus capsid, a homomultimer of the viral core polypeptide, using cell-free transcription-linked translation. The mature particles that are produced are indistinguishable from authentic viral capsids by four criteria: velocity sedimentation, buoyant density, protease resistance, and electron microscopic appearance. Production of unassembled core polypeptides can be uncoupled from production of capsid particles by decreasing core mRNA concentration. Addition of excess unlabeled core polypeptides allows the chase of the unassembled polypeptides into mature capsids. Using this cell-free system, we demonstrate that assembly of capsids proceeds by way of a novel high molecular weight intermediate. Upon isolation, the high molecular weight intermediate is productive of mature capsids when energy substrates are manipulated. A 60-kD protein related to the chaperonin t-complex polypeptide 1 (TCP-1) is found in association with core polypeptides in two different assembly intermediates, but is not associated with either the initial unassembled polypeptides or with the final mature capsid product. These findings implicate TCP-1 or a related chaperonin in viral assembly and raise the possibility that eukaryotic cytosolic chaperonins may play a distinctive role in multimer assembly apart from their involvement in assisting monomer folding.

Primary structure and function of a second essential member of the heterooligomeric TCP1 chaperonin complex of yeast, TCP1 beta

A role for heterooligomeric TCP1 complex as a chaperonin in the eukaryotic cytosol has recently been suggested both by structural similarities with other chaperonins and by in vitro experiments showing it to mediate ATP-dependent folding of actin, tubulin, and luciferase. Here we present the primary structure of a second subunit of the complex and present genetic and functional analyses. The TCP1 beta amino acid sequence, predicted from the cloned gene, bears 35% identity to TCP1, termed here TCP1 alpha, containing the same highly conserved residues found in the collective sequence of chaperonins. The predicted product was identified as the fastest-migrating species of the TCP1 complex purified from soluble extracts of yeast. The TCP1 beta gene, like TCP1 alpha, is essential. Strains containing lethal disruptions of either gene could not be rescued by additional copies of the other. Spores bearing disruption of either gene germinated as single, large-budded cells. Similarly, large-budded cells were observed following shift to 37 degrees C of strains carrying temperature-sensitive mutations in either TCP1 alpha or TCP1 beta. The arrested cells contained replicated DNA present in single nuclear masses, associated with abnormal tubulin staining patterns, supporting the assertion that mitotic spindle formation and function are impaired. We conclude that TCP1 beta supplies an essential function that partially overlaps with that of TCP1 alpha in acting as a molecular chaperone in tubulin and spindle biogenesis.

Circulating IgA antibody against a 65 kDa heat shock protein in acute alcoholic hepatitis

Heat shock proteins are known to be immunogenic in a number of diverse conditions and can be induced by hypoxia, tumour necrosis factor and alcohol--all potential triggers in patients with acute alcoholic hepatitis. In the present study, sera from 23 patients with acute alcoholic hepatitis, 18 liver disease controls, ten patients with inactive alcoholic liver disease and six alcoholics without liver damage were screened for the antibody to a 65 kDa heat shock protein using an ELISA technique. IgA antibody was found to be closely associated with alcoholic hepatitis; 20/23 patients were seropositive compared to 5/18 liver disease controls and 4/10 with inactive alcoholic cirrhosis. IgM and IgG antibodies to the 65 kDa heat shock protein were less closely associated with alcoholic hepatitis and were positive in nine and eight of the 23 patients, respectively, compared with six and seven of 18 liver disease controls. Neither antibody was detected in alcoholics without liver damage or normal controls. These data indicate that an IgA immune mediated response to the 65 kDa heat shock protein is characteristic of patients with acute alcoholic hepatitis and may be one mechanism underlying observed persistence of liver damage after cessation of alcohol consumption.

Two Tcp-1-related but highly divergent gene families exist in oat encoding proteins of assumed chaperone function

Tcp-1-related sequences have been isolated from a cDNA library of etiolated 6-day-old oat (Avena sativa) seedlings. This attempt was made to obtain cDNAs of a recently published 60 kDa plant chaperone that re-folds denatured phytochrome and which was biochemically characterised as a Tcp-1-related protein [(1993) Nature 363, 644-647]. The translation of the putative coding sequence from one full-length cDNA clone displays no specific homologies to amino acid sequences known from peptide sequencing of the oat 60 kDa chaperone. Antibodies raised against the 60 kDa chaperone and over-expressed protein from one full-length coding sequence for Tcp-1 from oat show no cross-reactivity, whereas a monoclonal antibody raised against mouse Tcp-1 protein recognizes both the 60 kDa protein purified from plant extracts and over-expressed protein from Tcp-1-related cDNA sequences.

Co-expression of plastid chaperonin genes and a synthetic plant Rubisco operon in Escherichia coli

It has been suggested that lack of specialized molecular chaperone function(s) in Escherichia coli may account for the fact that although E. coli cells transformed with plant Rubisco genes synthesize the Rubisco subunit polypeptides, the active enzyme fails to assemble. If so, co-expression of plant chaperone and Rubisco genes might permit plant Rubisco assembly in E. coli. Introduction of genes encoding plant chaperonin polypeptides has been shown to enhance the capacity of E. coli to assemble active cyanobacterial Rubisco. We now report that co-expression of plant Rubisco and chaperonin genes affected the solubility and stability of Rubisco large subunit polypeptides, however, neither the assembled oligomeric protein nor Rubisco enzyme activity was detected.

Intramolecular chaperones and protein folding

Many proteins from both prokaryotic and eukaryotic sources are produced with amino-terminal propeptides. These propeptides, which are usually located between the signal peptide and the mature protein, are essential for the proper function of that protein. Recent research has indicated that these polypeptides are indispensible for proper folding of the proteins they are attached to. As propeptides perform a function similar to that of a large family of heat shock proteins, they had been broadly classified as molecular chaperones. However, significant differences exist between these two classes of proteins and to distinguish them from one another, propeptides have been termed intramolecular chaperones. Recent results have suggested that such intramolecular chaperones may be found in a large number of proteins.

The t-complex polypeptide 1 complex is a chaperonin for tubulin and actin in vivo

A role in folding newly translated cytoskeletal proteins in the cytosol of eukaryotes has been proposed for t-complex polypeptide 1 (TCP1). In this study, we investigated tubulin and actin biogenesis in Chinese hamster ovary (CHO) cells. When extracts of pulse-labeled cells were analyzed by anion-exchange and size-exclusion chromatography, newly synthesized alpha-tubulin, beta-tubulin, and actin were observed to enter a large molecular mass complex (approximately 900 kDa). These proteins were released from this complex capable, in the case of tubulin, of forming heterodimers. The large molecular mass complexes coeluted with TCP1 and could be immunoprecipitated by using an anti-TCP1 antibody. These findings demonstrate that there is a cytosolic pathway for folding tubulin and actin in vivo that involves the TCP1 complex.

Theory of chaperonin action: inertial model for enhancement of prokaryotic Rubisco assembly

We have performed a computational simulation of the aggregation and chaperonin-dependent reconstitution of dimeric prokaryotic ribulose bisphosphate carboxylase/oxygenase (Rubisco), based on the data of P. Goloubinoff et al. (1989, Nature 342, 884-889) and P. V. Viitanen et al. (1990, Biochemistry 29, 5665-5671). The aggregation is simulated by a set of 12 differential equations representing the aggregation of the Rubisco folding intermediate, Rubisco-I, with itself and with aggregates of Rubisco-I, leading up to dodecamers. Four rate constants, applying to forward or reverse steps in the aggregation process, were included. Optimal values for these constants were determined using the ellipsoid algorithm as implemented by one of us (Ecker, J.G. & Kupferschmid, M., 1988, Introduction to Operations Research, Wiley, New York, pp. 315-322). Intensive exploration of simpler aggregation models did not identify an alternative that could simulate the data as well as this one. The activity of the chaperonin in this system was simulated by using this aggregation model, combined with a model similar to that proposed by Goloubinoff et al. (1989). The model assumes that the chaperonin can bind the folding intermediate rapidly, and that the chaperonin complex releases the Rubisco molecule slowly, permitting time for its spontaneous folding while interacting with the chaperonin. This is followed by self-association of the folded Rubisco monomer to yield the active dimeric Rubisco. A modification of the model that simulates temperature effects was also constructed. The most important results we obtained indicate that the chaperonin-dependent reconstitution of Rubisco can be simulated adequately without invoking any catalysis of folding by the chaperonin. In addition, the simulations predict values for the association rate constant of Rubisco-I with the chaperonin, and other variables, that are subject to experimental verification.

A TCP1-related molecular chaperone from plants refolds phytochrome to its photoreversible form

Folding of the major cytoskeletal components in the cytosol of mammalian cells is mediated by interactions with t-complex polypeptide-1 (TCP1) molecular chaperones, a situation analogous to the chaperonin 60-aided folding of polypeptides in bacteria, chloroplasts and mitochondria. We have purified a TCP1-related molecular chaperone from etiolated oat seedlings that has a unique structure. Although immunologically related to TCP1, and having amino-acid sequence similarity, its quaternary structure is different from animal TCP1 proteins. Electron microscopy and image analysis reveals that the chaperone has two stacked rings of six subunits each, and is distinct in size and configuration. The chaperone copurifies with the soluble cytosolic photoreceptor phytochrome, and can stimulate refolding of denatured phytochrome to a photoactive form in the presence of Mg-ATP. We propose that this protein is the cytosolic chaperone involved in phytochrome biogenesis in plant cells.

Identification of chaperonin particles in mammalian brain cytosol and of T-complex polypeptide 1 as one of their components

An approximately 950-kDa heteromeric particle was purified from guinea-pig and rat brain by sucrose gradient fractionation of post-mitochondrial supernatants. Further purification, by affinity chromatography on ATP-Sepharose and anion exchange FPLC on MonoQ, yielded a particle with typical chaperonin ultrastructure. One of the component polypeptides was recognized by a monoclonal antibody to murine T-complex polypeptide 1. Brain cytosolic chaperonin particles formed a binary complex with unfolded tubulin subunits. The polypeptide compositions of the cytosolic chaperonin particles appeared very similar between brain and testicular tissues of the same animal, but differed subtly between the guinea-pig and rat.

Heat shock proteins: molecular chaperones of protein biogenesis

Heat shock proteins (Hsps) were first identified as proteins whose synthesis was enhanced by stresses such as an increase in temperature. Recently, several of the major Hsps have been shown to be intimately involved in protein biogenesis through a direct interaction with a wide variety of proteins. As a reflection of this role, these Hsps have been referred to as molecular chaperones. Hsp70s interact with incompletely folded proteins, such as nascent chains on ribosomes and proteins in the process of translocation from the cytosol into mitochondria and the endoplasmic reticulum. Hsp60 also binds to unfolded proteins, preventing aggregation and facilitating protein folding. Although less well defined, other Hsps such as Hsp90 also play important roles in modulating the activity of a number of proteins. The function of the proteolytic system is intertwined with that of molecular chaperones. Several components of this system, encoded by heat-inducible genes, are responsible for the degradation of abnormal or misfolded proteins. The budding yeast Saccharomyces cerevisiae has proven very useful in the analysis of the role of molecular chaperones in protein maturation, translocation, and degradation. In this review, results of experiments are discussed within the context of experiments with other organisms in an attempt to describe the current state of understanding of these ubiquitous and important proteins.

Two cofactors and cytoplasmic chaperonin are required for the folding of alpha- and beta-tubulin

Though the chaperonins that mediate folding in prokaryotes, mitochondria, and chloroplasts have been relatively well characterized, the folding of proteins in the eukaryotic cytosol is much less well understood. We recently identified a cytoplasmic chaperonin as an 800-kDa multisubunit toroid which forms a binary complex with unfolded actin; the correctly folded polypeptide is released upon incubation with Mg-ATP (Y. Gao, J. O. Thomas, R. L. Chow, G.-H. Lee, and N. J. Cowan, Cell 69:1043-1050, 1992). Here we show that the same chaperonin also forms a binary complex with unfolded alpha- or beta-tubulin; however, there is no detectable release of the correctly folded product, irrespective of the concentration of added Mg-ATP and Mg-GTP or the presence of added carrier tubulin heterodimers with which newly folded alpha- or beta-tubulin polypeptides might exchange. Rather, two additional protein cofactors are required for the generation of properly folded alpha- or beta-tubulin, which is then competent for exchange into preexisting alpha/beta-tubulin heterodimers. We show that actin and tubulins compete efficiently with one another for association with cytoplasmic chaperonin complexes. These data imply that actin and alpha- and beta-tubulin interact with the same site(s) on chaperonin complexes.

Two cofactors and cytoplasmic chaperonin are required for the folding of alpha- and beta-tubulin

Though the chaperonins that mediate folding in prokaryotes, mitochondria, and chloroplasts have been relatively well characterized, the folding of proteins in the eukaryotic cytosol is much less well understood. We recently identified a cytoplasmic chaperonin as an 800-kDa multisubunit toroid which forms a binary complex with unfolded actin; the correctly folded polypeptide is released upon incubation with Mg-ATP (Y. Gao, J. O. Thomas, R. L. Chow, G.-H. Lee, and N. J. Cowan, Cell 69:1043-1050, 1992). Here we show that the same chaperonin also forms a binary complex with unfolded alpha- or beta-tubulin; however, there is no detectable release of the correctly folded product, irrespective of the concentration of added Mg-ATP and Mg-GTP or the presence of added carrier tubulin heterodimers with which newly folded alpha- or beta-tubulin polypeptides might exchange. Rather, two additional protein cofactors are required for the generation of properly folded alpha- or beta-tubulin, which is then competent for exchange into preexisting alpha/beta-tubulin heterodimers. We show that actin and tubulins compete efficiently with one another for association with cytoplasmic chaperonin complexes. These data imply that actin and alpha- and beta-tubulin interact with the same site(s) on chaperonin complexes.

Highly selective binding of nascent polypeptides by an Escherichia coli chaperone protein in vivo

Chaperone proteins bind to newly synthesized polypeptides and assist in various assembly reactions. The Escherichia coli chaperone protein SecB binds precursors of exported proteins and assists in export. In vitro, SecB can bind to many unfolded proteins. In this report, we demonstrate that SecB binding in vivo is highly selective; the major polypeptides that are bound by SecB are nascent precursors of the exported proteins maltose-binding protein (MBP), LamB, OmpF, and OmpA. These results support the hypothesis that the primary physiological function of SecB is to stimulate protein export. By interacting with nascent polypeptides, SecB probably stimulates their cotranslational association with the membrane-bound protein translocation apparatus.

A mutation of Escherichia coli SecA protein that partially compensates for the absence of SecB

The Escherichia coli SecB protein is a cytosolic chaperone protein that is required for rapid export of a subset of exported proteins. To aid in elucidation of the activities of SecB that contribute to rapid export kinetics, mutations that partially suppressed the export defect caused by the absence of SecB were selected. One of these mutations improves protein export in the absence of SecB and is the result of a duplication of SecA coding sequences, leading to the synthesis of a large, in-frame fusion protein. Unexpectedly, this mutation conferred a second phenotype. The secA mutation exacerbated the defective protein export caused by point mutations in the signal sequence of pre-maltose-binding protein. One explanation for these results is that the mutant SecA protein has sustained a duplication of its binding site(s) for exported protein precursors so that the mutant SecA is altered in its interaction with precursor molecules.

Heat shock proteins functioning as molecular chaperones: their roles in normal and stressed cells

In response to either elevated temperatures or several other metabolic insults, cells from all organisms respond by increasing the expression of so-called heat shock proteins (hsp or stress proteins). In general, the stress response appears to represent a universal cellular defence mechanism. The increased expression and accumulation of the stress proteins provides the cell with an added degree of protection. Studies over the past few years have revealed a role for some of the stress proteins as being intimately involved in protein maturation. Members of the hsp 70 family, distributed throughout various intracellular compartments, interact transiently with other proteins undergoing synthesis, translocation, or higher ordered assembly. Although not yet proven, it has been suggested that members of the hsp 70 family function to slow down or retard the premature folding of proteins in the course of synthesis and translocation. Yet another family of stress proteins, the hsp 60 or GroEL proteins (chaperonins), appear to function as catalysts of protein folding. Here I discuss the role of those stress proteins functioning as molecular chaperones, both within the normal cell and in the cell subjected to metabolic stress.

Protein folding in the cell: functions of two families of molecular chaperone, hsp 60 and TF55-TCP1

Two families of molecular chaperone, the hsp 60-GroEL family and the TF55-TCP1 family, have been discovered in evolutionarily related cellular compartments. A member of one of these families, hsp 60, has been shown to play a global role in polypeptide chain folding in mitochondria. We review here studies of both hsp 60 and other family members, discussing their essential physiological roles and mechanism of action.

The general concept of molecular chaperones

This introductory article proposes a conceptual framework in which to consider the information that is emerging about the proteins called molecular chaperones, and suggests some definitions that may be useful in this new field of biochemistry. Molecular chaperones are currently defined in functional terms as a class of unrelated families of protein that assist the correct non-covalent assembly of other polypeptide-containing structures in vivo, but which are not components of these assembled structures when they are performing their normal biological functions. The term assembly in this definition embraces not only the folding of newly synthesized polypeptides and any association into oligomers that may occur, but also includes any changes in the degree of either folding or association that may take place when proteins carry out their functions, are transported across membranes, or are repaired or destroyed after stresses such as heat shock. Known molecular chaperones do not convey steric information essential for correct assembly, but appear to act by binding to interactive protein surfaces that are transiently exposed during various cellular processes; this binding inhibits incorrect interactions that may otherwise produce non-functional structures. Thus the concept of molecular chaperones does not contradict the principle of protein self-assembly, but qualifies it by suggesting that in vivo self-assembly requires assistance by other protein molecules.

Predicted amino acid sequence and genomic organization of Trypanosoma cruzi hsp 60 genes

We describe the isolation of a Trypanosoma cruzi protein-coding gene that exhibited about 50% identity with members of the family of heat shock protein (hsp) 60 genes. Since this homology extended for most of the predicted 562 amino acid open reading frame and was comparable to the level of sequence identity between the individual hsp 60 genes from diverged species, we conclude that we have isolated and characterized a T. cruzi hsp 60 gene. The T. cruzi hsp 60 genes are arranged in tandem arrays, and the presence of restriction fragment length polymorphisms (RFLPs) among the different hsp 60 genes suggests the presence of several separate gene arrays encoding hsp 60 members.

Cloning, characterization, and functional expression in Escherichia coli of chaperonin (groESL) genes from the phototrophic sulfur bacterium Chromatium vinosum

A recombinant lambda phage which was able to propagate in groE mutants of Escherichia coli was isolated from a Chromatium vinosum genomic DNA library. A 4-kbp SalI DNA fragment, isolated from this phage and subcloned in plasmid vectors, carried the C. vinosum genes that allowed lambda growth in these mutants. Sequencing of this fragment indicated the presence of two open reading frames encoding polypeptides of 97 and 544 amino acids, respectively, which showed high similarity to the molecular chaperones GroES and GroEL, respectively, from several eubacteria and eukaryotic organelles. Expression of the cloned C. vinosum groESL genes in E. coli was greatly enhanced when the cells were transferred to growth temperatures that induce the heat shock response in this host. Coexpression in E. coli of C. vinosum groESL genes and the cloned ribulose bisphosphate carboxylase/oxygenase genes from different phototrophic bacteria resulted in an enhanced assembly of the latter enzymes. These results indicate that the cloned DNA fragment encodes C. vinosum chaperonins, which serve in the assembly process of oligomeric proteins. Phylogenic analysis indicates a close relationship between C. vinosum chaperonins and their homologs present in pathogenic species of the gamma subdivision of the eubacterial division Proteobacteria.

The unfolding and attempted refolding of the bacterial chaperone protein groEL (cpn60)

The unfolding of the bacterial chaperone protein groEL (cpn60) in solutions of guanidinium chloride (GdnHCl) has been studied. From the results of CD, fluorescence and light scattering, it is clear that major structural transitions in the protein occur over the range 1.0-1.5 M GdnHCl. The ATPase activity of the protein is lost at lower concentrations (0.75 M). After denaturation in concentrations of GdnHCl above 1.5 M, removal of the denaturing agent by dialysis results in very nearly complete regain of secondary structure (as judged by CD), but not the regain of correct tertiary or quaternary structure, or ATPase activity. The product was shown to be very sensitive to proteolysis by thermolysin, unlike the native protein, and not to show enhanced binding of ANS, a characteristic property of the 'molten globule' state of proteins. The results are discussed in relation to current information concerning the assembly of the groEL protein.

Synaptophysin-containing microvesicles transport heat-shock protein hsp60 in insulin-secreting beta cells

58-62 kDa heat-shock proteins (hsp60) are molecular chaperonins involved in the process of protein folding, transmembrane translocation and assembly of oligomeric protein complexes. In eukaryotic cells hsp60 proteins have been found in mitochondria and chloroplasts. However, we have recently documented that, in addition to mitochondria, a hsp60-like protein is present in secretory granules of insulin-secreting beta cells. The pathway by which hsp60 is targeted to secretory granules was unknown. Here we report the existence of microvesicles involved in the transport of hsp60 protein. Immunoelectron microscopy of serial thin-sections of beta cells directly visualized stages associated with hsp60 delivery: attachment of microvesicles to a secretory granule, fusion with the secretory granule membrane and release of hsp60 molecules. Further biochemical and immunological analysis of microvesicles revealed the presence in their membrane of synaptophysin, a major component of synaptic-like microvesicles (SLMV) of neuroendocrine cells. Double immunogold labelling with antibodies to synaptophysin and hsp60 demonstrated co-localization of both proteins in the same microvesicles. Moreover, fusion of synaptophysin-positive microvesicles leaves synaptophysin incorporated, at least transiently, to secretory granule membranes. These findings suggest that, in beta cells, synaptic-like vesicles are involved in the transport and delivery of hsp60 and represent a novel pathway for protein transport and secretion.

Cloning of a cDNA encoding the Tcp-1 (t complex polypeptide 1) homologue of Arabidopsis thaliana

We isolated a plant homologue of Tcp-1 (t complex polypeptide 1) cDNA from Arabidopsis thaliana. It encodes a 545-amino acid (aa) protein, which has extensive aa and nucleotide sequence homology to the corresponding proteins of mouse, yeast, fruit fly and archaebacteria.

Purification, cDNA cloning and Northern-blot analysis of mitochondrial chaperonin 60 from pumpkin cotyledons

Two different cDNA clones, pMCPN60-1 and pMCPN60-2, encoding the mitochondrial homologues of chaperonin 60 (Cpn60) were isolated from a cDNA library of germinating pumpkin cotyledons by use of mixtures of synthetic oligonucleotides based on the N-terminal amino acid sequence of the protein. Determination of the complete nucleotide sequences of the two cDNA revealed that pMCPN60-1 and pMCPN60-2 each contain one open reading frame that encodes a protein of 575 amino acids with molecular masses of 61052 Da and 61127 Da, respectively. The deduced amino acid sequences of the two polypeptides include a 32-residue N-terminal putative mitochondrial presequence attached to the mature polypeptides, and they are 95.3% identical. From a comparison of deduced amino acid sequences with other Cpn60, it appears that the mature polypeptides of pumpkin mitochondrial Cpn60 are 44-59% identical to the other Cpn60, namely, GroEL of Escherichia coli, the 60-kDa heat-shock protein (Hsp60) of mitochondria in the yeast Saccharomyces cerevisiae, P1 protein of mammalian mitochondria and the Ribulose-1,5-bisphosphate carboxylase/oxygenase subunit-binding proteins alpha and beta of plastids in higher plants. Genomic Southern-blot analysis identified at least two copies of the gene for mitochondrial Cpn60 in the pumpkin genome. The levels of mRNA for mitochondrial Cpn60 in cotyledons, hooks and hypocotyls of pumpkin seedlings increased in response to heat stress, as deduced from Northern-blot analysis, indicating that pumpkin mitochondrial Cpn60 is a heat-induced stress protein.