Proteasomes and protein conjugation across domains of life

Like other energy-dependent proteases, proteasomes, which are found across the three domains of life, are self-compartmentalized and important in the early steps of proteolysis. Proteasomes degrade improperly synthesized, damaged or misfolded proteins and hydrolyse regulatory proteins that must be specifically removed or cleaved for cell signalling. In eukaryotes, proteins are typically targeted for proteasome-mediated destruction through polyubiquitylation, although ubiquitin-independent pathways also exist. Interestingly, actinobacteria and archaea also covalently attach small proteins (prokaryotic ubiquitin-like protein (Pup) and small archaeal modifier proteins (Samps), respectively) to certain proteins, and this may serve to target the modified proteins for degradation by proteasomes.     

Proteasomes are essential for yeast proliferation. cDNA cloning and gene disruption of two major subunits.

The cDNAs encoding two major subunits, named YC1 and YC7-alpha, of yeast proteasomes (multicatalytic proteinase complexes) were isolated and sequenced. As deduced from their nucleotide sequences, YC1 and YC7-alpha consist of 288 and 252 amino acid residues with calculated molecular weights of 31,534 and 27,999, respectively. They showed marked sequence homology to other eukaryotic proteasome components, suggesting that proteasomes are composed of a family of subunits with the same evolutional origin. To obtain information on the physiological role of proteasomes, we disrupted the chromosomal genes of YC1 and YC7-alpha of yeast cells independently, using isolated cDNA clones. Disruption of the coding region of one copy of the YC1 gene in diploid yeast created a recessive lethal mutation, but disruption of the 3'-noncoding region of the gene had no effect on cell proliferation. Disruption of the YC7-alpha gene also had a lethal effect on haploid yeast cells. These findings demonstrated that YC1 and YC7-alpha are both encoded by a single copy gene and that these genes are essential for proliferation of yeast cells.     

Proteasomes modulate conjugation to the ubiquitin-like protein,ISG15

ISG15 is a ubiquitin-like protein that is induced by interferon and microbial challenge. Ubiquitin-like proteins are covalently conjugated to cellular proteins and may intersect the ubiquitin-proteasome system via common substrates or reciprocal regulation. To investigate the relationship between ISG15 conjugation and proteasome function, we treated interferon-induced cells with proteasome inhibitors. Surprisingly, inhibition of proteasomal, but not lysosomal, proteases dramatically enhanced the level of ISG15 conjugates. The stimulation of ISG15 conjugates occurred rapidly in the absence of protein synthesis and was most dramatic in the cytoskeletal protein fraction. Inhibition of ISG15 conjugation by ATP depletion abrogated the proteasome inhibitor-dependent increase in ISG15 conjugates, suggesting that the effect was mediated by de novo conjugation, rather than protection from proteasomal degradation or inhibition of ISG15 deconjugating activity. The increase in ISG15 conjugates did not occur through a stabilization of the ISG15 E1 enzyme, UBE1L. Furthermore, simultaneous modification of proteins by both ISG15 and ubiquitin did not account for the proteasome inhibitor-dependent increase in ISG15 conjugates. These findings provide the first evidence for a link between ISG15 conjugation and proteasome function and support a model in which proteins destined for ISG15 conjugation are proteasome-regulated.     

Proteasomes of the yeastS. cerevisiae: genes,structure and functions

Proteasomes are large multicatalytic protease complexes which fulfil central functions in major intracellular proteolytic pathways of the eukaryotic cell. 20S proteasomes are 700 kDa cylindrically shaped particles, found in the cytoplasm and the nucleus of all eukaryotes. They are composed of a pool of 14 different subunits (MW 22–25 kDa) arranged in a stack of 4 rings with 7-fold symmetry. In the yeastSaccharomyces cerevisiae a complete set of 14 genes coding for 20S proteasome subunits have been cloned and sequenced. 26S proteasomes are even larger proteinase complexes (about 1700 kDa) which degrade ubiquitinylated proteins in an ATP-dependent fashionin vitro. The 26S proteasome is build up from the 20S proteasome as core particle and two additional 19S complexes at both ends of the 20S cylinder. Recently existence of a 26S proteasome in yeast has been demonstrated. Several 26S proteasome specific genes have been cloned and sequenced. They share similarity with a novel defined family of ATPases. 20S and 26S proteasomes are essential for functioning of the eukaryotic cell. Chromosomal deletion of 20S and 26S proteasomal genes in the yeastS. cerevisiae caused lethality of the cell. Thein vivo functions of proteasomes in major proteolytic pathways have been demonstrated by the use of 20S and 26S proteasomal mutants. Proteasomes are needed for stress dependent and ubiquitin mediated proteolysis. They are involved in the degradation of short-lived and regulatory proteins. Proteasomes are important for cell differentiation and adaptation to environmental changes. Proteasomes have also been shown to function in the control of the cell cycle.     

Proteasomes: machines for all reasons

Emerging data reveal that besides degrading proteins tagged with ubiquitin, the proteasome plays a more varied and decisive role in cellular regulation than previously imagined. In this issue, Hanna et al. (2007) expand our view of the proteasome by showing that under certain conditions, proteasome composition can be altered to control ubiquitin homeostasis.     

Proteasomes and ubiquitin are involved in the turnover of the wild-type prion protein

Prion diseases propagate by converting a normal glycoprotein of the host, PrP(C), into a pathogenic "prion" conformation. Several misfolding mutants of PrP(C) are degraded through the ER-associated degradation (ERAD)-proteasome pathway. In their infectious form, prion diseases such as bovine spongiform encephalopathy involve PrP(C) of wild-type sequence. In contrast to mutant PrP, wild-type PrP(C) was hitherto thought to be stable in the ER and thus immune to ERAD. Using proteasome inhibitors, we now show that approximately 10% of nascent PrP(C) molecules are diverted into the ERAD pathway. Cells incubated with N-acetyl-leucinal-leucinal-norleucinal (ALLN), lactacystin or MG132 accumulated both detergent-soluble and insoluble PrP species. The insoluble fraction included an unglycosylated 26 kDa PrP species with a protease-resistant core, and a M(r) "ladder" that contained ubiquitylated PrP. Our results show for the first time that wild-type PrP(C) molecules are subjected to ERAD, in the course of which they are dislocated into the cytosol and ubiquitylated. The presence of wild-type PrP molecules in the cytosol may have potential pathogenic implications.     

Analysis of ribosomal protein gene structures: implications for intron evolution

Many spliceosomal introns exist in the eukaryotic nuclear genome. Despite much research, the evolution of spliceosomal introns remains poorly understood. In this paper, we tried to gain insights into intron evolution from a novel perspective by comparing the gene structures of cytoplasmic ribosomal proteins (CRPs) and mitochondrial ribosomal proteins (MRPs), which are held to be of archaeal and bacterial origin, respectively. We analyzed 25 homologous pairs of CRP and MRP genes that together had a total of 527 intron positions. We found that all 12 of the intron positions shared by CRP and MRP genes resulted from parallel intron gains and none could be considered to be “conserved,” i.e., descendants of the same ancestor. This was supported further by the high frequency of proto-splice sites at these shared positions; proto-splice sites are proposed to be sites for intron insertion. Although we could not definitively disprove that spliceosomal introns were already present in the last universal common ancestor, our results lend more support to the idea that introns were gained late. At least, our results show that MRP genes were intronless at the time of endosymbiosis. The parallel intron gains between CRP and MRP genes accounted for 2.3% of total intron positions, which should provide a reliable estimate for future inferences of intron evolution.     

Proteasomes and their associated ATPases: a destructive combination

Protein degradation by 20S proteasomes in vivo requires ATP hydrolysis by associated hexameric AAA ATPase complexes such as PAN in archaea and the homologous ATPases in the eukaryotic 26S proteasome. This review discusses recent insights into their multistep mechanisms and the roles of ATP. We have focused on the PAN complex, which offers many advantages for mechanistic and structural studies over the more complex 26S proteasome. By single-particle EM, PAN resembles a "top-hat" capping the ends of the 20S proteasome and resembles densities in the base of the 19S regulatory complex. The binding of ATP promotes formation of the PAN-20S complex, which induces opening of a gate for substrate entry into the 20S. PAN's C-termini, containing a conserved motif, docks into pockets in the 20S's alpha ring and causes gate opening. Surprisingly, once substrates are unfolded, their translocation into the 20S requires ATP-binding but not hydrolysis and can occur by facilitated diffusion through the ATPase in its ATP-bound form. ATP therefore serves multiple functions in proteolysis and the only step that absolutely requires ATP hydrolysis is the unfolding of globular proteins. The 26S proteasome appears to function by similar mechanisms.     

Evolution of protein sequences and structures.

The relationship between sequence similarity and structural similarity has been examined in 36 protein families with five or more diverse members whose structures are known. The structural similarity within a family (as determined with the DALI structure comparison program) is linearly related to sequence similarity (as determined by a Smith-Waterman search of the protein sequences in the structure database). The correlation between structural similarity and sequence similarity is very high; 18 of the 36 families had linear correlation coefficients r>/=0.878, and only nine had correlation coefficients r相似文献   

Rethinking Proteasome Evolution: Two Novel Bacterial Proteasomes

The proteasome is a multisubunit structure that degrades proteins. Protein degradation is an essential component of regulation because proteins can become misfolded, damaged, or unnecessary. Proteasomes and their homologues vary greatly in complexity: from HslV (heat shock locus v), which is encoded by 1 gene in bacteria, to the eukaryotic 20S proteasome, which is encoded by more than 14 genes. Despite this variation in complexity, all the proteasomes are composed of homologous subunits. We searched 238 complete bacterial genomes for structures related to the proteasome and found evidence of two novel groups of bacterial proteasomes. The first, which we name Anbu, is sparsely distributed among cyanobacteria and proteobacteria. We hypothesize that Anbu must be very ancient because of its distribution within the cyanobacteria, and that it has been lost in many more recent species. We also present evidence for a fourth type of bacterial proteasome found in a few beta-proteobacteria, which we call beta-proteobacteria proteasome homologue (BPH). Sequence and structural analyses show that Anbu and BPH are both distinct from known bacterial proteasomes but have homologous structures. Anbu is encoded by one gene, so we postulate a duplication of Anbu created the 20S proteasome. Anbu's function appears to be related to transglutaminase activity, not the general stress response associated with HslV. We have found different combinations of Anbu, BPH, and HslV within these bacterial genomes, which raises questions about specialized protein degradation systems.     

Proteasomes play an essential role in thymocyte apoptosis.

Cell death in many different organisms requires the activation of proteolytic cascades involving cytosolic proteases. Here we describe a novel requirement in thymocyte cell death for the 20S proteasome, a highly conserved multicatalytic protease found in all eukaryotes. Specific inhibitors of proteasome function blocked cell death induced by ionizing radiation, glucocorticoids or phorbol ester. In addition to inhibiting apoptosis, these signals prevented the cleavage of poly(ADP-ribose) polymerase that accompanies many cell deaths. Since overall rates of protein degradation were not altered significantly during cell death in thymocytes, these results suggest that the proteasome may either degrade regulatory protein(s) that normally inhibit the apoptotic pathway or may proteolytically activate protein(s) than promote cell death.     

Correlation of gene and protein structures in the FXYD family proteins

The FXYD family proteins are auxiliary subunits of the Na,K-ATPase, expressed primarily in tissues that specialize in fluid or solute transport, or that are electrically excitable. These proteins range in size from about 60 to 160 amino acid residues, and share a core homology of 35 amino acid residues in and around a single transmembrane segment. Despite their relatively small sizes, they are all encoded by genes with six to nine small exons. We show that the helical secondary structures of three FXYD family members, FXYD1, FXYD3, and FXYD4, determined in micelles by NMR spectroscopy, reflect the structures of their corresponding genes. The coincidence of helical regions, and connecting segments, with the positions of intron-exon junctions in the genes, support the hypothesis that the FXYD proteins may have been assembled from discrete structural modules through exon shuffling.     

Proteasomes and other self-compartmentalizing proteases in prokaryotes

The proteasome represents the major non-lysosomal proteolytic system in eukaryotes. It confines proteolytic activity to an inner compartment that is accessible to unfolded proteins only. The strategy of controlling intracellular breakdown of proteins by self-compartmentalization is also used by different types of prokaryotic energy-dependent proteases. Genomic sequencing data reveal that various combinations of these energy-dependent proteases occur in prokaryotic cells from different lineages.     

Characterization and comparison of protein structures. Part I-characterization.

The quantitative criteria characterizing the regularity of Calpha-backbones in the protein structures are presented. A technique is based on the Fourier remapping of the Cartesian coordinates for the Calpha-chain. The Fourier spectra identify the hidden periodicities and symmetries in protein structures, while the integral regularity is assessed via the spectral structural entropies. The formal unification of digitizing and the similarities in statistics for the random counterparts allow study of the direct correlations between the distribution of physico-chemical characteristics along the amino acid sequence and the spatial conformation of the polypeptide chain. The significant correlations are found for both hydrophobicity and side-chain volumes, though, as expected, the effects for hydrophobicity turn out essentially stronger. A scheme is illustrated by the set of 120 protein structures comprising the representatives from the main superfamilies and superfolds.     

Characterization and comparison of protein structures. Part II-comparison.

The Fourier methods are applied to the pairwise comparison of Calpha-backbones in protein structures. The technique allows to assess both the general similarity and the main origins of resemblance (coincident periodicities, similarity of fragments, or large-scale semblance of folding). The analogous methods can be extended to the study of correlations between the structural characteristics for the Calpha-backbone of one protein and the distribution of physico-chemical parameters along the primary amino acid sequence for the other. Finally, we discuss the problem of clusterization of pairwise data into tree-like hierarchical system.     

Mammalian cell gene expression: protein glycosylation.

Considerable advances have been made in identifying the factors determining the glycosylation pattern of glycoproteins secreted by mammalian cells. This has allowed a greater appreciation of the way in which recombinant proteins may be glycosylated after expression in a heterologous system. The studies reviewed herein extend the wider view that glycosylation of native and recombinant proteins is a complex event dependent on the protein moiety, the host cell, and also the environment in which transfected cells are cultured. The details of the way in which these factors combine to establish the glycosylation pattern of a secreted protein are now beginning to be unravelled.     

Enlarged representative set of protein structures.

To reduce redundancy in the Protein Data Bank of 3D protein structures, which is caused by many homologous proteins in the data bank, we have selected a representative set of structures. The selection algorithm was designed to (1) select as many nonhomologous structures as possible, and (2) to select structures of good quality. The representative set may reduce time and effort in statistical analyses.