Proteinase yscE of yeast shows homology with the 20 S cylinder particles of Xenopus laevis

Microbial Proteases Applications

The use of chemicals around the globe in different industries has increased tremendously, affecting the health of people. The modern world intends to replace these noxious chemicals with environmental friendly products for the betterment of life on the planet. Establishing enzymatic processes in spite of chemical processes has been a prime objective of scientists. Various enzymes, specifically microbial proteases, are the most essentially used in different corporate sectors, such as textile, detergent, leather, feed, waste, and others. Proteases with respect to physiological and commercial roles hold a pivotal position. As they are performing synthetic and degradative functions, proteases are found ubiquitously, such as in plants, animals, and microbes. Among different producers of proteases, Bacillus sp. are mostly commercially exploited microbes for proteases. Proteases are successfully considered as an alternative to chemicals and an eco-friendly indicator for nature or the surroundings. The evolutionary relationship among acidic, neutral, and alkaline proteases has been analyzed based on their protein sequences, but there remains a lack of information that regulates the diversity in their specificity. Researchers are looking for microbial proteases as they can tolerate harsh conditions, ways to prevent autoproteolytic activity, stability in optimum pH, and substrate specificity. The current review focuses on the comparison among different proteases and the current problems faced during production and application at the industrial level. Deciphering these issues would enable us to promote microbial proteases economically and commercially around the world.

Mechanisms of cell regulation - proteolysis, the big surprise

Precise regulation of cellular processes is essential for life. Regarding proteins, many regulatory mechanisms were explored over the years, such as posttranslational modifications (e.g., phosphorylation), enzyme activation or inhibition by small molecules, and modulation of protein-protein interactions. Complete removal of a protein via proteolysis as a regulatory mechanism, however, was denied for a long time, mainly due to economical considerations. Scientists could not believe that a protein which is synthesized at the expense of a lot of energy could be destroyed again. Here, we discuss the landmark discoveries and the use of yeast as a eukaryotic model organism that finally paved the way for our current understanding of proteolysis as an essential regulatory principle in the cell.

Identification of the reactive cysteine residues in yeast dipeptidyl peptidase III

Dipeptidyl peptidases III (DPPs III) form a distinct metallopeptidase family characterized by the unique HEXXGH motif. High susceptibility to inactivation by organomercurials suggests the presence of a reactive cysteine residue(s) in, or close to, their active site. Yeast DPP III contains five Cys, none of which is absolutely conserved within the family. In order to identify reactive residue(s), site-directed mutagenesis on yeast His(6)-tagged DPP III was employed to substitute specifically all five cysteine residues to serine. The variant enzymes thus obtained were enzymatically active and showed an overall structure not greatly affected by the mutations as judged by circular dichroism. Analysis by native and SDS-PAGE under non-reducing conditions revealed the existence of a monomeric and dimeric form in all DPP III proteins except in the C130S, implying that dimerization of yeast DPP III is mediated by the surface-exposed cysteine 130. The investigation of the effect of thiol reagent 4,4'-dithiodipyridine (DTDP) on all five Cys to Ser single protein variants showed that Cys639 and Cys518 are more reactive than the remainder. Only the C639S mutant protein displayed the remarkable resistance against p-hydroxy-mercuribenzoate (pHMB) indicating that modification of Cys639 is responsible for the fast inactivation of yeast DPP III by this sulfhydryl reagent.

tRNA import into yeast mitochondria is regulated by the ubiquitin-proteasome system

In Saccharomyces cerevisiae, one of two cytosolic lysine-tRNAs is partially imported into mitochondria. We demonstrate that three components of the ubiquitin/26S proteasome system (UPS), Rpn13p, Rpn8p and Doa1p interact with the imported tRNA and with the essential factor of its mitochondrial targeting, pre-Msk1p. Genetic and biochemical assays demonstrate that UPS plays a dual regulatory role, since the overall inhibition of cellular proteasome activity reduces tRNA import, while specific depletion of Rpn13p or Doa1p increases it. This result suggests a functional link between UPS and tRNA mitochondrial import in yeast and indicates on the existence of negative and positive import regulators.

Cysteinyl proteinases and their selective inactivation

The affinity-labeling of cysteinyl proteinases may now be carried out with a number of peptide-derived reagents with selectivity, particularly for reactions carried out in vitro. These reagents have been described with emphasis on their selectivity for cysteine proteinases and lack of action on serine proteinases, the most likely source of side reactions among proteinases. Perhaps a crucial feature of this selectivity is an enzyme-promoted activation due to initial formation of a hemiketal, which may destabilize the reagent. Prominent among the reagent types that have this class selectivity are the peptidyl diazomethyl ketones, the acyloxymethyl ketones, the peptidylmethyl sulfonium salts, and peptidyl oxides analogous to E-64. The need for specific inhibitors capable of inactivating the target enzyme in intact cells and animals is inevitably pushing the biochemical application of these inhibitors into more complex molecular environments where the possibilities of competing reactions are greatly increased. In dealing with the current state and potential developments for the in vivo use of affinity-labeling reagents of cysteine proteinases, the presently known variety of cysteinyl proteinases had to be considered. Therefore this chapter has, at the same time, attempted to survey these proteinases with respect to specificity and gene family. The continual discovery of new proteinases will increase the complexity of this picture. At present the lysosomal cysteine proteinases cathepsins B and L and the cytoplasmic calcium-dependent proteinases are reasonable goals for a fairly complete metabolic clarification. The ability of investigators to inactivate individual members of this family in vivo, possibly without complications due to concurrent inactivation of serine proteinases by improvements in reagent specificity, is increasing. Among the cysteine proteinases, at least those of the papain super family, hydrophobic interactions in the S2 and S3 subsites are important and some specificity has been achieved by taking advantage of topographical differences among members of this group. Some of this has probably involved surface differences removed from the regions involved in proteolytic action. The emerging cysteine proteinases include some which, in contrast to the papain family, have a pronounced specificity in S1 for the binding of basic side chains, familiar in the trypsin family of serine proteinases. At least a potential conflict with serine proteinases can be avoided by choice of a covalent bonding mechanism. The departing group region, has not been exploited. As a sole contributor to binding, this region may be rather limited as a source of specificity.(ABSTRACT TRUNCATED AT 400 WORDS)

The proteasome: a proteolytic nanomachine of cell regulation and waste disposal

The final destination of the majority of proteins that have to be selectively degraded in eukaryotic cells is the proteasome, a highly sophisticated nanomachine essential for life. 26S proteasomes select target proteins via their modification with polyubiquitin chains or, in rare cases, by the recognition of specific motifs. They are made up of different subcomplexes, a 20S core proteasome harboring the proteolytic active sites hidden within its barrel-like structure and two 19S caps that execute regulatory functions. Similar complexes equipped with PA28 regulators instead of 19S caps are a variation of this theme specialized for the production of antigenic peptides required in immune response. Structure analysis as well as extensive biochemical and genetic studies of the 26S proteasome and the ubiquitin system led to a basic model of substrate recognition and degradation. Recent work raised new concepts. Additional factors involved in substrate acquisition and delivery to the proteasome have been discovered. Moreover, first insights in the tasks of individual subunits or subcomplexes of the 19S caps in substrate recognition and binding as well as release and recycling of polyubiquitin tags have been obtained.

The prepropeptide of vacuolar aminopeptidase I is necessary and sufficient to target the fluorescent reporter protein GFP to the vacuole of yeast by the Ccvt pathway

We have studied the capacity of the prepro amino extension of vacuolar protease leucine aminopeptidase I (API) to target the fluorescent reporter protein GFP to the vacuole of yeast. The preproGFP chimera constructed by extending the amino end of GFP with the prepro-part of API is rapidly degraded in both wild-type WCG cells and WCG 11/21a cells deficient in the proteasome. In contrast, the chimera expressed in WCG-PP cells deficient in both proteasome activity and vacuolar proteinase A accumulates in the vacuole, where it remains stable. Replacement of Gly by Ile-7, a substitution that prevents folding of the pre-part into an amphipathic helix and inhibits the targeting of the API precursor to the vacuole, inhibits the targeting of preproGFP to the vacuole. The separated pre- and pro-parts of the API precursor do not target GFP to the vacuole. Targeting of preproGFP to the vacuole is independent of its levels of expression, as the fluorescent protein localizes to the vacuole in cells expressing the protein under the control of both the GAL 1/10 or the API promoter. The preproGFP expressed under both promoters is recovered as monomers from cytosolic cell extracts. PreproGFP expressed under the API promoter is packed into cytoplasmic bodies that penetrate into the vacuolar lumen to release the protein. Altogether our results show that the prepro-part of the API precursor is necessary and sufficient to target the green fluorescent reporter protein to the vacuole.

The active sites of the eukaryotic 20 S proteasome and their involvement in subunit precursor processing

The 26 S proteasome is the central protease involved in ubiquitin-mediated protein degradation and fulfills vital regulatory functions in eukaryotes. The proteolytic core of the complex is the 20 S proteasome, a cylindrical particle with two outer rings each made of 7 different alpha-type subunits and two inner rings made of 7 different beta-type subunits. In the archaebacterial 20 S proteasome ancestor proteolytically active sites reside in the 14 uniform beta-subunits. Their N-terminal threonine residues, released by precursor processing, perform the nucleophilic attack for peptide bond hydrolysis. By directed mutational analysis of 20 S proteasomal beta-type proteins of Saccharomyces cerevisiae, we identified three active site-carrying subunits responsible for different peptidolytic activities as follows: Pre3 for post-glutamyl hydrolyzing, Pup1 for trypsin-like, and Pre2 for chymotrypsin-like activity. Double mutants harboring only trypsin-like or chymotrypsin-like activity were viable. Mutation of two potentially active site threonine residues in the Pre4 subunit excluded its catalytic involvement in any of the three peptidase activities. The generation of different, incompletely processed forms of the Pre4 precursor in active site mutants suggested that maturation of non-active proteasomal beta-type subunits is exerted by active subunits and occurs in the fully assembled particle. This trans-acting proteolytic activity might also account for processing intermediates of the active site mutated Pre2 subunit, which was unable to undergo autocatalytic maturation.

Purification and characterization of proteasome from ostrich liver

The proteasome (EC 3.4.99.46) is a high molecular mass (approximately 700 kDa) multisubunit enzyme complex which is the focus of worldwide research in order to identify the structure, mechanism of action and specificity of the complex. The purpose of the present study was to investigate the tryptic, chymotryptic and peptidylglutamyl-peptide hydrolysing (PGPH) activities of ostrich liver proteasome. The proteasome was purified from ostrich liver by employing ammonium sulphate fractionation, followed by three sequential chromatographic steps on Toyopearl Super Q-650 S, Sephadex G-150 and phenyl-Toyopearl columns. Temperature and pH optima were examined and the effect of inhibitors, detergents, fatty acids and cations on the peptidase activities was determined. Ostrich proteasome exhibited a relative M(r) of approximately 665,000 using non-denaturing gradient PAGE and dissociated into the characteristic "ladder" associated with the proteasome subunits during SDS-PAGE. The pH optima for the peptidase activities were found to be slightly alkaline (tryptic activity) and neutral (chymotryptic-like and PGPH activities). Ostrich liver proteasome was found to be activated in terms of the PGPH activity by fatty acids and SDS, whereas the chymotryptic and tryptic-like activities were differentially inhibited. Ostrich proteasome, in its inhibition by monovalent cations, was similar to the proteasomes extracted from other sources. The specificity of the proteasome appears to be very broad, although it lacks aminopeptidase activity. The yield compared favourably with similar extraction procedures which have been reported. On the basis of the physicochemical and kinetic properties which ostrich liver proteasome exhibited, it can be safely concluded that it corresponds well with the proteasomes isolated from many other sources.

Proteasomes of the yeast S. 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 yeast Saccharomyces 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 fashion in 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 yeast S. cerevisiae caused lethality of the cell. The in 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.

The 26S proteasome of the yeast Saccharomyces cerevisiae

Proteasomes are large multicatalytic proteinase complexes found in all eukaryotic organisms investigated so far. They have been shown to play a central role in cytosolic and nuclear proteolysis. According to their sedimentation coefficients two types of these particles can be distinguished: 20S proteasomes and 26S proteasomes. In contrast to 20S proteasomes, which were mainly characterized on the basis of their ability to cleave small chromogenic peptide substrates and certain proteins in an ATP-independent manner, 26S proteasomes degrade ubiquitinylated proteins in an ATP-dependent reaction. 20S proteasomes have been found in all eukaryotes from yeast to man. So far 26S proteasomes have only been discovered in higher eukaryotes. We now report the existence of the 26S proteasome in a lower eukaryote, the yeast Saccharomyces cerevisiae. Formation of the 26S proteasome could most effectively be induced in crude extracts of heat stressed yeast cells by incubation with ATP and Mg2+ ions. This treatment yielded a protein complex, which eluted from gel filtration columns at molecular masses higher than 1500 kDa. Besides chromogenic peptide substrates, this complex cleaves ubiquitinylated proteins in an ATP-dependent fashion. In non-denaturing-PAGE, the purified 26S proteasome disintegrated and migrated as four protein bands. One of these bands could be identified as the 20S proteasome. On SDS-PAGE, the 26S proteasome showed a complex pattern of subunit bands with molecular masses between 15 and 100 kDa. Further evidence for the 20S proteasome being the proteolytically active core of the 26S proteasome was obtained by following peptide cleaving activities in extracts of yeast strains carrying mutations in various subunits of the 20S proteasome.

Proteasome-associated RNAs are non-specific

The RNA isolated from RNase-treated proteasome preparations from human erythrocytes, HeLa cells, the archaeon Thermoplasma acidophilum and also from recombinant proteasomes of T. acidophilum expressed in Escherichia coli was characterized. The RNA associated with structurally similar protein particles, namely with the two molecular chaperones, groEL from E. coli and with the thermosome from T. acidophilum, served as controls. Electrophoretic analysis on polyacrylamide gels of the radioactively end-labelled RNA revealed a very similar size distribution pattern, irrespectively of the protein particles from which they had been isolated. The predominant RNA species were in the size ranges 80 nucleotides and 120 nucleotides, respectively. Partial sequencing of their terminal regions by mobility-shift analysis revealed that, of the proteasomes from human erythrocytes, the approximately 80-nucleotide-long RNA consists of a heterogenous population of mostly tRNA species because they carried the tRNA-specific 3'-terminal sequence motif 5'-CCA-3'. The RNA in the size range 120 nucleotides isolated from the proteasomes of human erythrocytes and of T. acidophilum was also heterogeneous and displayed, in the terminal regions, a remarkable sequence similarity to the corresponding regions of the 5S rRNA from the same and different organisms. The total content of RNA of all the protein particles was quantified and found to be consistently sub-stoichiometric. All these findings strongly suggest that RNA associated with the proteasomes and with the molecular chaperones originate from the abundant cellular pool of the tRNAs and 5S rRNAs which bind non-specifically to these large protein particles.

PRE5 and PRE6, the last missing genes encoding 20S proteasome subunits from yeast? Indication for a set of 14 different subunits in the eukaryotic proteasome core

The 20S proteasome of eukaryotes is an abundant multicatalytic/multifunctional proteinase complex composed of an array of nonidentical subunits which are encoded by alpha- or beta-type members of the proteasomal gene family. In budding yeast, 14 subunits had been detected and 12 proteasomal genes had been cloned and sequenced so far. Starting from peptide sequences of purified subunits of the yeast 20S proteasome, we cloned two additional proteasomal genes, PRE5 and PRE6, which both encode essential alpha-type subunits. Sequence comparison of all known eukaryotic proteasomal proteins show the presence of a total of 14 subgroups, which can be divided into seven alpha- and seven beta-type groups. Including the Pre5 and Pre6 proteins, every subgroup contains a single yeast member. We anticipate that the 14 genes encoding subunits of the yeast proteasome represent the complete set of proteasomal genes of this organism. The ancestral archaebacterial proteasome is composed of four stacks of rings, the two outer rings containing seven identical alpha-subunits and the inner rings containing seven identical beta-subunits. We speculate that, in analogy to the archaebacterial proteasome, every eukaryotic proteasome is made of two halves of 14 distinct subunits, each half consisting of seven different alpha-type and 7 different beta-type subunits. In higher eukaryotes, subunit isoforms may contribute to variability in the subunit composition of the 20S proteasome allowing functional modulations.

DFP-sensitive multicatalytic protease complexes (proteasomes) involved in the control of oocyte maturation in the toad, Bufo japonicus

The inhibition of progesterone-induced oocyte maturation by diisopropylfluorophosphate (DFP), a typical serine protease inhibitor, was investigated in oocytes of the Japanese toad Bufo japonicus for the first time. Oocytes to which DFP was externally applied did not undergo germinal vesicle breakdown (GVBD), which is an early signal of oocyte maturation, in response to progesterone. The more inhibitory period was found to be 0-0.5 GVBD50 on a relative time scale [when the time at which 50% of the oocytes had completed GVBD (GVBD50) was set at 1.0], namely, before the beginning of GVBD. DFP-sensitive proteases, which seem to be multifunctional nonlysosomal protease complexes (proteasomes), may already be present in the cytosol of premature oocytes. Peptide hydrolyzing activity, as reflected by proteasome activity, was found to be regulated before and after GVBD. In addition, immunoblotting regarding the native electrophoretic protein profile of the proteasomes throughout the maturational process demonstrated that they undergo alterations in mobility dependent upon the maturational process. These findings raise the possibility that the activities of some endogenous DFP-sensitive proteasomes play distinct, essential roles in oocyte maturation triggered by progesterone in Bufo.

PRE3, highly homologous to the human major histocompatibility complex-linked LMP2 (RING12) gene, codes for a yeast proteasome subunit necessary for the peptidylglutamyl-peptide hydrolyzing activity

20S proteasomes are multifunctional proteinase complexes ubiquitous in eucaryotes. We have cloned the yeast PRE3 gene by complementation of the pre3-2 mutation, which leads to a defect in the peptidylglutamyl-peptide hydrolyzing activity of the 20S proteasome. The PRE3 gene, a beta-type member of the proteasomal gene family, is essential for cellular life and codes for a 193-amino acid proteasomal subunit with a predicted molecular mass of 21.2 kDa. The Pre3 protein shows striking homology to the human proteasome subunits Hs delta and Lmp2 (Ring12). Lmp2 is encoded in the major histocompatibility complex class II region implicating proteasomes in antigen processing.

The 20S proteasome mediates the degradation of mouse and yeast ornithine decarboxylase in yeast cells

Ornithine decarboxylase (ODC), a key enzyme in the biosynthesis of polyamines, is one of the most rapidly degraded proteins in mammalian cells. Recently it has been demonstrated that mammalian ODC is degraded in vitro by the 26S protease that contains the 20S proteasome as its catalytic core, in a reaction that does not require ubiquitin. Here, we show that yeast and mouse ODC are both rapidly degraded in yeast cells and that their degradation severely inhibited in a mutant yeast cell line defective in the chymotryptic activity of proteinase yscE, the yeast 20S proteasome. These results provide compelling genetic support to previous biochemical studies suggesting the involvement of the 20S proteasome in the degradation of ornithine decarboxylase.

Proteinase yscD (oligopeptidase yscD). Structure, function and relationship of the yeast enzyme with mammalian thimet oligopeptidase (metalloendopeptidase, EP 24.15)

The yeast PRD1 gene, encoding proteinase yscD, was cloned by complementation of the prd1-6 point mutation. Sequencing of the gene revealed an open reading frame of 2.136 kb, encoding a protein of 712 amino acids with a calculated molecular mass of 81.8 kDa. The sequence HEGLG beginning at residue 501 represents the HEXXH motif, unique for the zinc metallo-peptidases. Sequence comparison revealed complete identity of the proteinase yscD gene with a recently published open reading frame of yeast chromosome III. We found 34.8% identity between proteinase yscD and rat metalloendopeptidase (thimet oligopeptidase, EP 24.15). Proteinase yscD hydrolyzes several chromogenic and fluorogenic peptides that are substrates of thimet oligopeptidase. N-[1-(RS)-carboxy-3-phenylpropyl]-Ala-Ala-Phe-p-aminobenzoic acid, a compound designed as specific inhibitor of EP 24.15, is also a strong inhibitor of the yeast enzyme. Proteinase yscD is a nonvacuolar enzyme. 3-5% of the total enzyme activity can be detected in the intermembrane space of mitochondria. In a mutant carrying a deletion of the PRD1 gene no proteinase yscD activity is detectable in the cytoplasm and in mitochondria of these cells. They do not show any grossly altered phenotype but exhibit a decrease in the intracellular degradation of peptides. This suggests a function of proteinase yscD in the late stages of protein degradation.

Proteasomes (prosomes) inhibit the translation of tobacco mosaic virus RNA by preventing the formation of initiation complexes

Proteasomes (prosomes) are large multiprotein complexes. They are involved in protein degradation of ubiquitin-conjugated proteins and in the generation of MHC class I peptides. We gave further evidence that they interfere with in vitro protein synthesis. Proteasomes inhibit the translation of Tobacco mosaic virus RNA. Analysis of cell-free systems by sucrose gradient centrifugation revealed that they prevent the formation of 80S initiation complexes but not the early phase of initiation.

Purification and characterization of the cystinyl bond cleaving yeast aminopeptidase yscXVI

Aminopeptidase yscXVI was purified from the yeast Saccharomyces cerevisiae. By SDS-PAGE the enzyme has a molecular weight of 45,000 Da, and in chromatofocusing, elution was observed at pH 6.2. The synthetic substrate cystinyl-4-nitroanilide (Km 22.5 microM, Vmax 12.9 mU/mg) is cleaved most efficiently in the pH range 7-8. Besides cleaving this standard substrate, aminopeptidase yscXVI acts on several other 4-nitroanilide substrates with unsubstituted N-terminal L-amino acids. Highest hydrolysis rate was measured with Lys-4-nitroanilide and Leu-4-nitroanilide. The activity of aminopeptidase yscXVI is abolished by chelating agents and restored by Zn2+, Mn2+ and Co2+ ions. Bestatin and amastatin are both strong inhibitors of the enzyme, with Ki values of 0.53 microM and 0.93 microM, respectively. Aminopeptidase yscXVI is detectable in the logarithmic growth phase, stationary phase, and in starved cultures of yeast.

Prosomes and their multicatalytic proteinase activity

Prosomes were first described as being mRNA-associated RNP (ribonucleoprotein) particles and subcomponents of repressed mRNPs (messenger ribonucleoprotein). We show here that prosomes isolated from translationally inactive mRNP have a protease activity identical to that described by others for the multicatalytic proteinase complex (MCP, 'proteasome'). By RNase or non-ionic detergent treatment, the MCP activity associated with repressed non-globin mRNP from avian erythroblasts, sedimenting at 35 S, could be quantitatively shifted on sucrose gradients to the 19-S sedimentation zone characteristic of prosomes, which were identified by monoclonal antibodies. The presence of small RNA in the enzymatic complex was shown by immunoprecipitation of the protease activity out of dissociated mRNP using a mixture of anti-prosome monoclonal antibodies; a set of small RNAs 80-120 nucleotides long was isolated from the immunoprecipitate. Furthermore, on CsCl gradients, colocalisation of the MCP activity with prosomal proteins and prosomal RNA was found, and no difference in the prosomal RNA pattern was observed whether the particles were fixed or not prior to centrifugation. These data indicate that the MCP activity is a property of prosomes, shown to be in part RNP and subcomplexes of in vivo untranslated mRNP. A hypothesis for the role of the prosome-MCP particles in maintaining homeostasis of specific protein levels is proposed.

Proteolysis, proteasomes and antigen presentation

Proteins presented to the immune system must first be cleaved to small peptides by intracellular proteinases. Proteasomes are proteolytic complexes that degrade cytosolic and nuclear proteins. These particles have been implicated in ATP-ubiquitin-dependent proteolysis and in the processing of intracellular antigens for cytolytic immune responses.

The proteasome/multicatalytic-multifunctional proteinase. In vivo function in the ubiquitin-dependent N-end rule pathway of protein degradation in eukaryotes

Proteinase yscE, the proteasome/multicatalytic-multifunctional proteinase of yeast had been shown to function in stress response and in the degradation of ubiquitinated proteins [(1991) EMBO J. 10, 555-562]. A well-defined set of proteins degraded via ubiquitin-mediated proteolysis are the substrates of the N-end rule pathway [(1986) Science 234, 179-186; (1989) Science 243, 1576-1583]. We show that mutants defective in the chymotryptic activity of proteinase yscE fail to degrade substrates of the N-end rule pathway. This gives further proof of the proteasome being a central catalyst in ubiquitin-mediated proteolysis.

Structure and RNA content of the prosomes

Duck erythroblasts prosomes were analysed by small angle neutron scattering (SANS), dynamic light scattering and (cryo-)electron microscopy. A molecular weight of approximately 720,000 +/- 50,000, a radius of gyration of 64 +/- 2 A and a hydrodynamic radius of approximately 86 A were obtained. Electron micrographs show a hollow cylinder-like particle with a diameter of 120 A, a height of 170 A and a diameter of 40 A for the cavity, built of four discs, the two outer ones being more pronounced than those in the center. Results from SANS indicate less then 5% of RNA in the purified prosomes, but nuclease protection assays confirm its presence.

Enzymatic changes of the bovine pituitary multicatalytic proteinase complex, induced by magnesium ions

The effect of magnesium ions on the catalytic activities of the bovine pituitary multicatalytic proteinase complex (MPC) was studied. Mg2+ markedly stimulated the breakdown of dephosphorylated beta-casein (caseinolytic activity) and the hydrolysis of Cbz-Leu-Leu-Glu-2-naphthylamide (peptidylglutamyl peptide bond hydrolyzing activity) by a 1700-fold purified preparation of MPC. Cleavage of Cbz-D-Ala-Leu-Arg-2-naphthylamide (trypsin-like activity) was strongly inhibited and cleavage of Cbz-Gly-Gly-Leu-p-nitroanilide (chymotrypsin-like activity) was weakly inhibited. Similar results were produced when enzymatic activities in the absence of Mg2+ were measured at 52 degrees C rather than at 37 degrees C. Trace protein impurities were removed by phenyl-Sepharose chromatography. This additional chromatographic step, while not changing the specific activities of hydrolysis of the three synthetic chromogenic substrates, led to a marked activation of the breakdown of dephosphorylated beta-casein. Mg2+ was not able to further stimulate the caseinolytic activities of either the phenyl-Sepharose-treated preparation or the preparation measured at 52 degrees C. Mg2+ therefore converts a "repressed" form of MPC to an "activated" form, possibly by promoting dissociation of a protein inhibitor, and may serve as a physiological regulator of this enzyme complex.

High-molecular-mass multicatalytic proteinase complexes produced by the nitrogen-fixing actinomycete Frankia strain BR

A major-high-molecular mass proteinase and seven latent minor proteinases were found in cell extracts and in concentrates of culture medium from Frankia sp. strain BR after nondenaturing electrophoresis in mixed gelatin-polyacrylamide gels. All of these complexes showed multicatalytic properties. Their molecular masses and their sedimentation coefficients varied from 1,300 kDa (28S) to 270 kDa (12S). The electroeluted 1,300-kDa proteinase complex dissociated into 11 low-molecular-mass proteinases (40 to 19 kDa) after sodium dodecyl sulfate activation at 30 degrees C and electrophoresis under denaturing conditions. All of these electroeluted proteinases hydrolyzed N-carbobenzoxy-Pro-Ala-Gly-Pro-4-methoxy-beta- naphthylamide, D-Val-Leu-Arg-4-methoxy-beta-naphthylamide, and Boc-Val-Pro-Arg-4-methyl-7-coumarylamide, whereas Suc-Leu-Leu-Val-Tyr-4-methyl-7-coumarylamide was cleaved only by the six lower-molecular-mass proteinases (27.5 to 19 kDa). Examination by electron microscopy of uranyl acetate-stained, electroeluted 1,300- and 650-kDa intracellular and extracellular proteinase complexes showed ring-shaped and cylindrical particles (10 to 11 nm in diameter, 15 to 16 nm long) similar to those of eukaryotic prosomes and proteasomes. Polyclonal antibodies raised against rat skeletal muscle proteasomes cross-reacted with all of the high-molecular-mass proteinase complexes and, after denaturation of the electroeluted 1,300-kDa band, with polypeptides of 35 to 38, 65, and 90 kDa. Electrophoresis of the activated cell extracts under denaturing conditions revealed 11 to 17 gelatinases from 40 to 19 kDa, including the 11 proteinases of the 1,300-kDa proteinase complex. The inhibition pattern of these proteinases is complex. Thiol-reactive compounds and 1-10-phenanthroline strongly inhibited all of the proteinases, but inhibitors against serine-type proteinases were also effective for most of them.

Differential proteolytic sensitivity of yeast fatty acid synthetase subunits alpha and beta contributing to a balanced ratio of both fatty acid synthetase components

The Saccharomyces cerevisiae genes FAS1 and FAS2 encoding the beta and alpha subunit of yeast fatty acid synthetase (FAS), respectively, were individually deleted by one-step gene disruption. Northern blot analysis of RNA from the resulting fas null allele mutants indicated that deletion of FAS2 did not influence the transcription of FAS1, while FAS2 transcription was significantly reduced in the delta fas1 strain. These data suggest an activating role of subunit beta on FAS2 gene expression or, alternatively, a repression of FAS2 by an excess of its own gene product. Compared to the intact alpha 6 beta 6 complex, the individual FAS subunits synthesized in the delta fas1 or delta fas2 strains exhibit a considerably increased sensitivity towards the proteinases present in the yeast cell homogenate. Using yeast mutants specifically defective in the vacuolar proteinases yscA (PRA1/ PEP4 gene product) and/or yscB (PRB1 gene product), it was shown that in vitro, subunit alpha is efficiently degraded by proteinase yscA while for degradation of subunit beta, the combined action of proteinases yscA and yscB is necessary. In vivo, besides the vacuolar proteinases, an additional proteolytic activity specifically affecting free FAS subunit alpha becomes increasingly apparent in cells entering the stationary growth phase. In contrast, under similar conditions uncomplexed FAS subunit beta is stable in strains lacking the vacuolar proteinases yscA and yscB. The reduced FAS subunit levels, at the stationary phase, were independent of the corresponding FAS transcript concentrations. Thus, differential degradation pathways are obviously removing an excess of either FAS subunit, at least under starvation conditions. A combination of both regulation of FAS gene expression and proteolysis of free FAS polypeptides may therefore explain the equimolar amounts of both FAS subunits observed in yeast wild-type cells.

Purification and characterization of proteinase yscJ, a new yeast peptidase

A newly recognized peptidase, designated proteinase yscJ, was purified from the yeast Saccharomyces cerevisiae. The enzyme is of non-vacuolar origin and cleaves the Tyr-Lys bond of the synthetic peptide substrate Cbz-Tyr-Lys-Arg-NH-Ph (Cbz, benzyloxycarbonyl; NH-Ph, 4-nitroanilide) and the Glu-Lys bond of the substrate Boc-Glu-Lys-Lys-NH-Mec (Boc, butoxycarbonyl; Mec, 4-methylcoumarinyl) with high efficiency. Optimum pH for cleavage of Cbz-Tyr-Lys-Arg-NH-Ph is in the range 7.0-7.5. The purified enzyme has a molecular mass of approximately 58 kDa, as judged by gel filtration on a Superose 12 FPLC column. Mercury compounds and EDTA were found to be potent inhibitors of proteinase yscJ activity.

Properties of subunits of the multicatalytic proteinase complex revealed by the use of subunit-specific antibodies

The multicatalytic proteinase (MCP) is a high-molecular-mass non-lysosomal proteinase that gives rise to a characteristic pattern of bands of molecular mass 22-34 kDa on SDS/PAGE gels. Isoelectric-focusing gels of the enzyme purified from rat liver show 16 bands with isoelectric points in the range of pH 5-8.5. Two-dimensional PAGE gels reveal that there are more than the previously reported 13 polypeptides associated with the MCP from rat liver and show a pattern of 15-20 major spots and several minor ones, similar to that of MCP isolated from some other sources. Possible relationships between the different polypeptides were investigated by immunoblot analysis of electrophoretically purified proteinase subunits with affinity-purified subunit-specific antibodies as well as antibodies raised against individual denatured subunits of the complex. The results demonstrate that many of the major polypeptide components of the MCP complex are antigenically distinct. Moreover comparison of immunoreactive material in crude cell extracts with that in purified MCP preparations has shown that the polypeptides are not derived from a smaller number of higher-molecular-mass subunits. Also, individual subunits have the same apparent molecular mass in a variety of rat tissues, suggesting close similarity between MCPs of different tissues. The highest concentrations of MCP subunits occur in liver and kidney. Gel-filtration analysis of crude extracts has demonstrated that MCP polypeptides are also associated with a higher-molecular-mass complex, which may be the 26 S proteinase that has been implicated in the degradation of ubiquitin-protein conjugates.

The ubiquitin-mediated system for intracellular protein degradation

Degradation of proteins by the ubiquitin system involves several discrete steps. Initially, multiple molecules of ubiquitin are covalently conjugated to the target substrate in an energy-requiring reaction. The protein thus marked is degraded by a specific ATP-dependent protease, and free and reutilizable ubiquitin is released. In this review we discuss the mechanisms involved in ubiquitin activation, selection of substrates for conjugation, and subsequent degradation of ubiquitin-conjugated proteins in the cell-free system. In addition, we summarize briefly what is currently known of the physiological roles of the ubiquitin system in vivo.

The three-dimensional structure of proteasomes from Thermoplasma acidophilum as determined by electron microscopy using random conical tilting

The three-dimensional structure of proteasomes from the archaebacterium Thermoplasma acidophilum has been determined to a resolution of approximately 2 nm from electron micrographs of negatively stained preparations using the method of 'random conical tilting'. The particles turn out to be essentially cylinder-shaped barrels, 15 nm long and 11 nm wide, enclosing a tripartite inner compartiment. An account is given of some of the present limitations which prevent to attain a higher resolution and possible ways to overcome these limitations are indicated.

Molecular cloning and sequence analysis of cDNAs for five major subunits of human proteasomes (multi-catalytic proteinase complexes)

Proteasomes are multicatalytic proteinase complexes consisting of a set of non-identical polypeptide components. Of these multiple components, the nucleotide sequences of five major subunits (named HC2, HC3, HC5, HC8 and HC9) of human proteasomes have been determined from recombinant cDNA clones by screening a human HepG2 hepatoblastoma cell cDNA library with rat proteasome cDNAs isolated previously as probes. The polypeptides deduced from their nucleotide sequences consisted of 263, 234, 241, 255 and 261 amino acid residues with calculated molecular weights of 29,554, 25,897, 26,487, 28,431 and 29,482, respectively, which are encoded by single independent genes. The primary structures of these subunits of human proteasomes closely resemble those of their rat counterparts and show considerably high inter-subunit homology, although the homology of HC5 is relatively low. These findings, together with the structural similarities of other eukaryotic proteasomes including those of Drosophila and yeast (Saccharomyces cerevisiae) support and extend the previously proposed concept that eukaryotic proteasome genes form a multi-gene family with the same evolutionary origin.

Proteinase yscE, the yeast proteasome/multicatalytic-multifunctional proteinase: mutants unravel its function in stress induced proteolysis and uncover its necessity for cell survival

Proteinase yscE is the yeast equivalent of the proteasome, a multicatalytic-multifunctional proteinase found in higher eukaryotic cells. We have isolated three mutants affecting the proteolytic activity of proteinase yscE. The mutants show a specific reduction in the activity of the complex against peptide substrates with hydrophobic amino acids at the cleavage site and define two complementation groups, PRE1 and PRE2. The PRE1 gene was cloned and shown to be essential. The deduced amino acid sequence encoded by the PRE1 gene reveals weak, but significant similarities to proteasome subunits of other organisms. Two-dimensional gel electrophoresis identified the yeast proteasome to be composed of 14 different subunits. Comparison of these 14 subunits with the translation product obtained from PRE1 mRNA synthesized in vitro demonstrated that PRE1 encodes the 22.6 kd subunit (numbered 11) of the yeast proteasome. Diploids homozygous for pre1-1 are defective in sporulation. Strains carrying the pre1-1 mutation show enhanced sensitivity to stresses such as incorporation of the amino acid analogue canavanine into proteins or a combination of poor growth medium and elevated temperature. Under these stress conditions pre1-1 mutant cells exhibit decreased protein degradation and accumulate ubiquitin-protein conjugates.

Co-purification of a small RNA species with multicatalytic proteinase (proteasome) from rat liver

Previous studies have come to different conclusions about the presence of RNA in particles known variously as prosomes, proteasomes or multicatalytic proteinase (MCP). To determine the reason for this, MCP was isolated from rat liver by 4 different purification protocols. One major band of RNA, about 80 nucleotides in length, co-purified in all preparations. The amount of RNA detected was less than one molecule per MCP particle suggesting that there may be more than one population of MCP in rat liver cells.

Functions of Intracellular Protein Degradation in Yeast

Diverse vacuolar and nonvacuolar pathways of protein degradation have been described in yeast. In several cases, much is known about the proteases involved, but most of these studies utilized nonphysiological model substrates. On the other hand, many regulatory proteins, such as those involved in cell cycle control, cell type determination, and the regulation of metabolite fluxes through biosynthetic pathways, have been shown to be rapidly and selectively destroyed in vivo, either constitutively or in response to specific regulatory signals. Precisely what molecular features of this class of proteins target them for degradation is largely unknown; this question is an area of intense current interest. A connection has been made between a particular proteolytic mechanism and a specific naturally short-lived protein in only a handful of examples. It is in this regard that the powerful molecular and genetic techniques available in yeast will probably have their greatest impact in the near future. The promise of this type of approach is already becoming apparent with the molecular genetic analysis of the yeast ubiquitin system. Although this work began less than ten years ago, the genes encoding at least 22 proteins involved in ubiquitin-dependent processes have already been isolated, and questions of their physiological and mechanistic function are being answered at an ever quickening pace.

Cell-specific accumulation of Drosophila proteasomes (MCP) during early development

The proteasome (MCP) is a high relative molecular mass multicatalytic proteinase complex composed of nonidentical protein subunits. We have investigated the cellular distribution of the enzyme complex during Drosophila embryogenesis using the proteasome specific antibodies N19-35 and N19-28 for immunocytology. Antibody staining of whole-mount embryos shows that during embryogenesis proteasomes are present in proliferating cells and that their accumulation and turnover is differentially regulated. Our data suggest that the proteasome may serve different proteolytic processes and that the enzyme may be involved in cell-specific proteolytic events required for cell proliferation and morphogenesis during early Drosophila development.

Abnormally high expression of proteasomes in human leukemic cells

Proteasomes are eukaryotic ring-shaped or cylindrical particles with multicatalytic protease activities. To clarify the involvement of proteasomes in tumorigenesis of human blood cells, we compared their expression in human hematopoietic malignant tumor cells with that in normal peripheral blood mononuclear cells. Immunohistochemical staining showed considerably increased concentrations of proteasomes in leukemic cells from the bone marrow of patients with various types of leukemia and the predominant localization of these proteasomes in the nuclei. Moreover, enzyme immunoassay and Northern blot analysis indicated that the concentrations of proteasomes and their mRNA levels were consistently much higher in a variety of malignant human hematopoietic cell lines than in resting peripheral lymphocytes and monocytes from healthy adults. Proteasome expression was also greatly increased in normal blood mononuclear cells during blastogenic transformation induced by phytohemagglutinin; their expression increased in parallel with induction of DNA synthesis and returned to the basal level with progress of the cell cycle. Thus, abnormally high expression of proteasomes may play an important role in transformation and proliferation of blood cells and in specific functions of hematopoietic tumor cells.

The Drosophila PROS-28.1 gene is a member of the proteasome gene family

In the present communication, we report the identification of a new gene family which encodes the protein subunits of the proteasome. The proteasome is a high-Mr complex possessing proteolytic activity. Screening a Drosophila lambda gt11 cDNA expression library with the proteasome-specific antibody N19-28 we isolated a clone encoding the 28-kDa No. 1 proteasome protein subunit. In accordance with the nomenclature of proteasome subunits in Drosophila, the corresponding gene is designated PROS-28.1, and it encodes an mRNA of 1.1 kb with an open reading frame of 249 amino acids (aa). Genomic Southern-blot hybridization shows PROS-28.1 to be a member of a family of related genes. Analysis of the predicted aa sequence reveals a potential nuclear targeting signal, a potential site for tyrosine kinase and a potential cAMP/cGMP-dependent phosphorylation site. The aa sequence comparison of the products of PROS-28.1 and PROS-35 with the C2 proteasome subunit of rat shows a strong sequence similarity between the different proteasome subunits. The data suggest that at least a subset of the proteasome-encoding genes belongs to a family of related genes (PROS gene family) which may have evolved from a common ancestral PROS gene.

N-terminal sequence similarities between components of the multicatalytic proteinase complex

The multicatalytic proteinase complex is a high molecular weight nonlysosomal proteinase which is composed of many different types of subunit. As part of a study of the possible relationships between subunits, polypeptides derived from the multicatalytic proteinase from rat liver have been subjected to N-terminal amino acid sequence analysis. Although several of the subunits are blocked at their N-termini, sequences have been obtained for 7 of the polypeptides. Each of the 7 sequences is unique but they show considerable sequence similarity, suggesting that the proteins are encoded by members of the same gene family.