Origin and evolution of eukaryotic chaperonins: phylogenetic evidence for ancient duplications in CCT genes

Cryptosporidium parvum Cpn60 targets a relict organelle

Chaperonin 60 (Cpn60) is a well-established marker protein for eukaryotic mitochondria and plastids. In order to determine whether the small double-membrane-bounded organelle posterior to the nucleus in the apicomplexan Cryptosporidium parvum is a mitochondrion, the Cpn60 gene of C. parvum sporozoites ( CpCpn60) was analyzed and antibodies were generated for localization of the peptide. Sequence and phylogenetic analyses indicated that CpCpn60 is a mitochondrial isotype and that antibodies against it localize to the rough endoplasmic reticulum-enveloped remnant organelle of C. parvum sporozoites. These data show this organelle is of mitochondrial origin.

Mitochondrial connection to the origin of the eukaryotic cell

Phylogenetic evidence is presented that primitively amitochondriate eukaryotes containing the nucleus, cytoskeleton, and endomembrane system may have never existed. Instead, the primary host for the mitochondrial progenitor may have been a chimeric prokaryote, created by fusion between an archaebacterium and a eubacterium, in which eubacterial energy metabolism (glycolysis and fermentation) was retained. A Rickettsia-like intracellular symbiont, suggested to be the last common ancestor of the family Rickettsiaceae and mitochondria, may have penetrated such a host (pro-eukaryote), surrounded by a single membrane, due to tightly membrane-associated phospholipase activity, as do present-day rickettsiae. The relatively rapid evolutionary conversion of the invader into an organelle may have occurred in a safe milieu via numerous, often dramatic, changes involving both partners, which resulted in successful coupling of the host glycolysis and the symbiont respiration. Establishment of a potent energy-generating organelle made it possible, through rapid dramatic changes, to develop genuine eukaryotic elements. Such sequential, or converging, global events could fill the gap between prokaryotes and eukaryotes known as major evolutionary discontinuity.

Function and regulation of cytosolic molecular chaperone CCT

Molecular chaperones are a group of proteins that assists in the folding of newly synthesized proteins or in the refolding of denatured proteins. The cytosolic chaperonin-containing t-complex polypeptide 1 (CCT) is a molecular chaperone that plays an important role in the folding of proteins in the eukaryotic cytosol. Actin, tubulin, and several other proteins are known to be folded by CCT, and an estimated 15% of newly translated proteins in mammalian cells are folded with the assistance of CCT. CCT differs from other chaperonin family proteins in its subunit composition, which consists of eight subunit species comprising the CCT 16-mer double-ring-like complex. CCT preferentially recognizes quasinative (or partially folded) intermediates, whereas its Escherichia coli homologue GroEL recognizes more unfolded intermediates, especially those displaying hydrophobic surfaces. Molecular evolutionary analyses have suggested that each subunit species has a specific function in addition to contributing to a common ATPase activity. Consistent with this view, it has been suggested that each subunit recognizes specific substrate proteins (or their parts) and that they collectively modulate the ATPase activity of the complex. The overall expression of CCT in mammalian cells is primarily dependent on cell growth, but each subunit exhibits an individual patterns of expression. Recent progress in CCT research is reviewed, focusing particularly on CCT function and expression. From these observations, the possible roles of the distinct subunits in CCT-assisted folding in the eukaryotic cytosol are discussed.

Heterologous expression and folding analysis of a beta-tubulin isotype from the Antarctic ciliate Euplotes focardii

Mammalian tubulins and actins attain their native conformation following interactions with CCT (the cytosolic chaperonin containing t-complex polypeptide 1). To study the beta-tubulin folding in lower eukaryotes, an isotype of beta-tubulin (beta-T1) from the Antarctic ciliate Euplotes focardii, was expressed in Escherichia coli. Folding analysis was performed by incubation of the 35S-labeled, denatured beta-T1 in the presence, or absence, of purified rabbit CCT and cofactor A, a polypeptide that stabilizes folded monomeric beta-tubulin. We show for the first time in protozoa that beta-tubulin folding is assisted by CCT and requires cofactor A. In addition, we observed that E. focardiibeta-T1 competes with human beta5 tubulin isotype for binding to CCT. The affinity of CCT to E. focardiibeta-T1 and beta5 tubulin are compared. Finally, the mitochondrial chaperonin mt-cpn60 binds to beta-T1 but is unable to release it in a native or quasi-native state.

Structure and function of a protein folding machine: the eukaryotic cytosolic chaperonin CCT

Chaperonins are large oligomers made up of two superimposed rings, each enclosing a cavity used for the folding of other proteins. Among the chaperonins, the eukaryotic cytosolic chaperonin CCT is the most complex, not only with regard to its subunit composition but also with respect to its function, still not well understood. Unlike the more well studied eubacterial chaperonin GroEL, which binds any protein that presents stretches of hydrophobic residues, CCT recognises in its substrates specific binding determinants and interacts with them through particular combinations of CCT subunits. Folding then occurs after the conformational changes induced in the chaperonin upon nucleotide binding have occurred, through a mechanism that, although still poorly defined, clearly differs from the one established for GroEL. Although CCT seems to be mainly involved in the folding of actin and tubulin, other substrates involved in various cellular roles are beginning to be characterised, including many WD40-repeat, 7-blade propeller proteins.

Crystal structure of the CCTgamma apical domain: implications for substrate binding to the eukaryotic cytosolic chaperonin

The chaperonin containing TCP-1 (CCT, also known as TRiC) is the only member of the chaperonin family found in the cytosol of eukaryotes. Like other chaperonins, it assists the folding of newly synthesised proteins. It is, however, unique in its specificity towards only a small subset of non-native proteins. We determined two crystal structures of mouse CCTgamma apical domain at 2.2 A and 2.8 A resolution. They reveal a surface patch facing the inside of the torus that is highly evolutionarily conserved and specific for the CCTgamma apical domain. This putative substrate-binding region consists of predominantly positively charged side-chains. It suggests that the specificity of this apical domain towards its substrate, partially folded tubulin, is conferred by polar and electrostatic interactions. The site and nature of substrate interaction are thus profoundly different between CCT and its eubacterial homologue GroEL, consistent with their different functions in general versus specific protein folding assistance.

Subunit composition of a bicomponent toxin: staphylococcal leukocidin forms an octameric transmembrane pore

Staphylococcal leukocidin pores are formed by the obligatory interaction of two distinct polypeptides, one of class F and one of class S, making them unique in the family of beta-barrel pore-forming toxins (beta-PFTs). By contrast, other beta-PFTs form homo-oligomeric pores; for example, the staphylococcal alpha-hemolysin (alpha HL) pore is a homoheptamer. Here, we deduce the subunit composition of a leukocidin pore by two independent methods: gel shift electrophoresis and site-specific chemical modification during single-channel recording. Four LukF and four LukS subunits coassemble to form an octamer. This result in part explains properties of the leukocidin pore, such as its high conductance compared to the alpha HL pore. It is also pertinent to the mechanism of assembly of beta-PFT pores and suggests new possibilities for engineering these proteins.

The chaperonin genes of jakobid and jakobid-like flagellates: implications for eukaryotic evolution

The jakobids are free-living mitochondriate protists that share ultrastructural features with certain amitochondriate groups and possess the most bacterial-like mitochondrial genomes described thus far. Jakobids belong to a diverse group of mitochondriate and amitochondriate eukaryotes, the excavate taxa. The relationships among the various excavate taxa and their relationships to other putative deep-branching protist groups are largely unknown. With the hope of clarifying these issues, we have isolated the cytosolic chaperonin CCTalpha gene from the jakobid Reclinomonas americana (strains 50394 and 50283), the jakobid-like malawimonad Malawimonas jakobiformis, two heteroloboseans (Acrasis rosea and Naegleria gruberi), a euglenozoan (Trypanosoma brucei), and a parabasalid (Monocercomonas sp.). We also amplified the CCTdelta gene from M. jakobiformis. The Reclinomonas and Malawimonas sequences presented here are among the first nuclear protein-coding genes to be described from these organisms. Unlike other putative early diverging protist lineages, a high density of spliceosomal introns was found in the jakobid and malawimonad CCTs-similar to that observed in vertebrate protein-coding genes. An analysis of intron positions in CCT genes from protists, plants, animals, and fungi suggests that many of the intron-sparse or intron-lacking protist lineages may not be primitively so but have lost spliceosomal introns during their evolutionary history. In phylogenetic trees constructed from CCTalpha protein sequences, R. americana (but not M. jakobiformis) shows a weak but consistent affinity for the Heterolobosea and Euglenozoa.

A spliceosomal intron in Giardia lamblia

Short introns occur in numerous protist lineages, but there are no reports of intervening sequences in the protists Giardia lamblia and Trichomonas vaginalis, which may represent the deepest known branches in the eukaryotic line of descent. We have discovered a 35-bp spliceosomal intron in a gene encoding a putative [2Fe-2S] ferredoxin of G. lamblia. The Giardia intron contains a canonical splice site at its 3' end (AG), a noncanonical splice site at its 5' end (CT), and a branch point sequence that fits the yeast consensus sequence of TACTAAC except for the first nucleotide (AACTAAC). We have also identified several G. lamblia genes with spliceosomal peptides, including homologues of eukaryote-specific spliceosomal peptides (Prp8 and Prp11), several DExH-box RNA-helicases that have homologues in eubacteria, but serve essential functions in the splicing of introns in eukaryotes, and 11 predicted archaebacteria-like Sm and like-Sm core peptides, which coat small nuclear RNAs. Phylogenetic analyses show the Giardia Sm core peptides are the products of multiple, ancestral gene duplications followed by divergence, but they retain strong similarity to Sm and like-Sm peptides of other eukaryotes. Although we have documented only a single intron in Giardia, it likely has other introns and fully functional, spliceosomal machinery. If introns were added during eukaryotic evolution (the introns-late hypothesis), then these results push back the date of this event before the branching of G. lamblia.

Gene duplication and gene conversion shape the evolution of archaeal chaperonins

Chaperonins are multi-subunit double-ring complexes that mediate the folding of nascent or denatured proteins. Gene duplication has been a potent force in the evolution of chaperonins in Archaea. Here we show that gene conversion has also been an important factor. We utilized a novel maximum likehood-based phylogenetic method for scanning DNA sequence alignments for regions of anomalous phylogenetic signal, such as those affected by gene conversion. Our results suggest that in crenarchaeotes, where an ancient gene duplication producing alpha and beta subunits took place in the common ancestor of the Pyrodictium, Aeropyrum, Pyrobaculum and Sulfolobus lineages, multiple independent gene conversions have occurred between the alpha and beta genes independently in each of these groups. Significantly, the conversions have repeatedly homogenized the region of the gene encoding the substrate-binding domain. This suggests that while the alpha and beta subunits in crenarchaeotes share only 50-60% overall amino acid sequence identity, they do not possess distinct roles in the binding of substrate. Cryptic gene conversion between distantly related paralogs may be more common than is currently appreciated, and could be a significant factor in slowing the functional differentiation of proteins encoded by duplicate genes long after their duplication.

Reconstructing/deconstructing the earliest eukaryotes: how comparative genomics can help

We could reconstruct the evolution of eukaryote-specific molecular and cellular machinery if some living eukaryotes retained primitive cellular structures and we knew which eukaryotes these were. It's not clear that either is the case, but the expanding protist genomic database could help us in several ways.

Gene duplication and the evolution of group II chaperonins: implications for structure and function

Chaperonins are multisubunit protein-folding assemblies. They are composed of two distinct structural classes, which also have a characteristic phylogenetic distribution. Group I chaperonins (called GroEL/cpn60/hsp60) are present in Bacteria and eukaryotic organelles while group II chaperonins are found in Archaea (called the thermosome or TF55) and the cytoplasm of eukaryotes (called CCT or TriC). Gene duplication has been an important force in the evolution of group II chaperonins: Archaea possess one, two, or three homologous chaperonin subunit-encoding genes, and eight distinct CCT gene families (paralogs) have been described in eukaryotes. Phylogenetic analyses indicate that while the duplications in archaeal chaperonin genes have occurred numerous times independently in a lineage-specific fashion, the eight different CCT subunits found in eukaryotes are the products of duplications that occurred early and very likely only once in the evolution of the eukaryotic nuclear genome. Analyses of CCT sequences from diverse eukaryotic species reveal that each of the CCT subunits possesses a suite of invariant subunit-specific amino acid residues ("signatures"). When mapped onto the crystal structure of the archaeal chaperonin from Thermoplasma acidophilum, these signatures are located in the apical, intermediate, and equatorial domains. Regions that were found to be variable in length and/or amino acid sequence were localized primarily to the exterior of the molecule and, significantly, to the extreme tip of the apical domain (the "helical protrusion"). In light of recent biochemical and electron microscopic data describing specific CCT-substrate interactions, our results have implications for the evolution of subunit-specific functions in CCT.

Analysis of the interaction between the eukaryotic chaperonin CCT and its substrates actin and tubulin

Two mechanisms have thus far been characterized for the assistance by chaperonins of the folding of other proteins. The first and best described is that of the prokaryotic chaperonin GroEL, which interacts with a large spectrum of proteins. GroEL uses a nonspecific mechanism by which any conformation of practically any unfolded polypeptide interacts with it through exposed, hydrophobic residues. ATP binding liberates the substrate in the GroEL cavity where it is given a chance to fold. A second mechanism has been described for the eukaryotic chaperonin CCT, which interacts mainly with the cytoskeletal proteins actin and tubulin. Cryoelectron microscopy and biochemical studies have revealed that both of these proteins interact with CCT in quasi-native, defined conformations. Here we have performed a detailed study of the docking of the actin and tubulin molecules extracted from their corresponding CCT:substrate complexes obtained from cryoelectron microscopy and image processing to localize certain regions in actin and tubulin that are involved in the interaction with CCT. These regions of actin and tubulin, which are not present in their prokaryotic counterparts FtsA and FtsZ, are involved in the polymerization of the two cytoskeletal proteins. These findings suggest coevolution of CCT with actin and tubulin in order to counteract the folding problems associated with the generation in these two cytoskeletal protein families of new domains involved in their polymerization.

Arabidopsis thaliana type I and II chaperonins

An examination of the Arabidopsis thaliana genome sequence led to the identification of 29 predicted genes with the potential to encode members of the chaperonin family of chaperones (CPN60 and CCT), their associated cochaperonins, and the cytoplasmic chaperonin cofactor prefoldin. These comprise the first complete set of plant chaperonin protein sequences and indicate that the CPN family is more diverse than previously described. In addition to surprising sequence diversity within CPN subclasses, the genomic data also suggest the existence of previously undescribed family members, including a 10-kDa chloroplast cochaperonin. Consideration of the sequence data described in this review prompts questions about the complexities of plant CPN systems and the evolutionary relationships and functions of the component proteins, most of which have not been studied experimentally.

Eukaryotic chaperonin CCT stabilizes actin and tubulin folding intermediates in open quasi-native conformations

Three-dimensional reconstruction from cryoelectron micrographs of the eukaryotic cytosolic chaperonin CCT complexed to tubulin shows that CCT interacts with tubulin (both the alpha and beta isoforms) using five specific CCT subunits. The CCT-tubulin interaction has a different geometry to the CCT-actin interaction, and a mixture of shared and unique CCT subunits is used in binding the two substrates. Docking of the atomic structures of both actin and tubulin to their CCT-bound conformation suggests a common mode of chaperonin-substrate interaction. CCT stabilizes quasi-native structures in both proteins that are open through their domain-connecting hinge regions, suggesting a novel mechanism and function of CCT in assisted protein folding.