Wolfgang Hilt

Proteasomes: destruction as a programme

Proteasomes are large multi-subunit protease complexes that selectively degrade intracellular proteins. Most of the proteins removed by these proteases are tagged for destruction by ubiquitination. Proteasomes have a role to play in controlling cellular processes, such as metabolism and the cell cycle, through signal-mediated proteolysis of key enzymes and regulatory proteins. They also operate in the stress response, by removing abnormal proteins, and in the immune response, by generating antigenic peptides.

Mammalian Bax triggers apoptotic changes in yeast

Apoptosis is co‐regulated by the conserved family of Bcl‐2‐related proteins, which includes both its agonists (Bax) and antagonists (Bcl‐XL). A mutant strain of the yeast Saccharomyces cerevisiae has been shown to express all morphological signs of apoptosis. Overexpression of Bax is lethal in S. cerevisiae, whereas simultaneous overexpression of Bcl‐XL rescues the cells. We report that overexpression of mammalian Bax in a S. cerevisiae wild type strain triggers morphological changes similar to those of apoptotic metazoan cells: the loss of asymmetric distribution of plasma membrane phosphatidylserine, plasma membrane blebbing, chromatin condensation and margination, and DNA fragmentation. Simultaneous overexpression of Bcl‐XL prevents these changes. We demonstrate that Bax triggers phenotypic alterations in yeast strongly resembling those it causes in metazoan apoptotic cells.

Cdc48: a power machine in protein degradation

Cdc48 is an essential, highly prominent ATP driven machine in eukaryotic cells. Physiological function of Cdc48 has been found in a multitude of cellular processes, for instance cell cycle progression, homotypic membrane fusion, chromatin remodeling, transcriptional and metabolic regulation, and many others. The molecular function of Cdc48 is arguably best understood in endoplasmic reticulum-associated protein degradation by the ubiquitin proteasome system. In this review, we summarize the general characteristics of Cdc48/p97 and the most recent results on the molecular function of Cdc48 in some of the above processes, which were found to finally end in proteolysis-connected pathways, either involving the proteasome or autophagocytosis-mediated lysosomal degradation.

Stress‐induced proteolysis in yeast

Survival of cells in their natural environment is crucially dependent on their ability to adapt to constantly occurring changes. The ability of cells to respond to extremes of environmental influences is vital to survival. Proteolysis is a central cellular tool in stress response. Proteins of pathways necessary for normal growth, but harmful under stress conditions, as well as proteins damaged by stress have to be eliminated. The yeast Saccharomyces cerevisiae, a model eukaryote, has evolved two different proteolytic systems: (i) a membrane‐enveloped, vacuolar (lysosomal) system, which contains a variety of non‐specific peptidases and (ii) highly specific peptidases residing at different cellular locations. The best characterized peptidase of the specific system is proteinase yscE, the proteasome equivalent found in all eukaryotic cells. Both the vacuolar and the non‐vacuolar systems are vital components of the stress response in yeast.

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 β‐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 Hsδ and Lmp2 (Ring12). Lmp2 is encoded in the major histocompatibility complex class II region implicating proteasomes in antigen processing.

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 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.

Glucose dehydrogenase from Bacillus subtilis expressed in Escherichia coli I: purification, characterization and comparison with glucose dehydrogenase from Bacillus megaterium

Escherichia coli containing the Bacillus subtilis glucose dehydrogenase gene on a plasmid (prL7) was used to produce the enzyme in high quantities. Gluc-DH-S was purified from the cell extract by (NH4)2SO4-precipitation, ion-exchange chromatography and Triazine-dye chromatography to a specific activity of 375 U/mg. The enzyme was apparently homogenous on SDS-PAGE with a subunit molecular mass of 31.5 kDa. Investigation of Gluc-DH-S was performed for comparison with the corresponding properties of Gluc-DH-M. The limiting Michaelis constant at pH 8.0 for NAD+ is Ka = 0.11 mM and for D-glucose Kb = 8.7 mM. The dissociation constant for NAD+ is Kia = 17.1 mM. Similar to Gluc-DH-M, Gluc-DH-S is inactivated by dissociation under weak alkaline conditions at pH 9.0. Complete reactivation is attained by readjustment to pH 6.5. Ultraviolet absorption, fluorescence and CD-spectra of native Gluc-DH-S, as well as fluorescence- and CD-backbone-spectra of the dissociated enzyme were nearly identical to the corresponding spectra of Gluc-DH-M. The aromatic CD-spectrum of dissociated Gluc-DH-S was different, representing a residual ellipticity of tryptophyl moieties in the 290-310 nm region. Density gradient centrifugation proved that this behaviour is due to the formation of inactive dimers in equilibrium with monomers after dissociation. In comparison to Gluc-DH-M, the kinetics of inactivation as well as the time-dependent change of fluorescence intensity at pH 9.0 of Gluc-DH-S showed a higher velocity and a changed course of the dissociation process.

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.

Studies on the yeast proteasome uncover its basic structural features and multiple in vivo functions.

Proteasomes are large multicatalytic protease complexes found in the cytoplasm and nucleus of all eukaryotic cells. 20S proteasomes are cylindrically shaped particles composed of a set of different subunits arranged in a stack of 4 rings with 7-fold symmetry. In yeast 14 different genes are known, which are proposed to code for the complete set of 20S proteasomal subunits. They can be divided in 7 alpha- and 7 beta-type subunits. 26S proteasomes are even larger proteinase complexes which contain the 20S proteasome as the functional proteolytic core. They degrade ubiquitinylated proteins in vitro. Several yeast 26S proteasome subunits have been characterized as members of a novel ATPase family. Studies with yeast 20S and 26S proteasome mutants uncovered the function of proteasomes in stress-dependent and ubiquitin-mediated proteolytic pathways. Proteasomes are important for cellular regulation, cell differentiation, adaptation to environmental changes and are involved in cell cycle control.

The Proteasome and Protein Degradation in Yeast

In 1984 a high molecular mass multisubunit protease complex was isolated from Saccharomyces cerevisiae [Achstetter et al. 1984] which proved to be the yeast homologue of the 20S proteasome complexes found in all eukaryotic cells [Kleinschmidt et al. 1988]. The yeast 20S proteasome is able to cleave chromo- and fluorogenic peptides at the carboxyterminus of hydrophobic, basic or acidic amino acids (chymotrypsin-like-, trypsin-like- and peptidyl-glutamyl-peptide hydrolyzing activity, respectively) [Heinemeyer et al. 1991]. The yeast 20S proteasome is composed of different subunits, showing a set of protein bands in the SDS-PAGE with molecular masses ranging from 20 to 35 kDa. They can be separated into 14 protein spots after two-dimensional gel electrophoresis [Heinemeyer et al. 1991]. Genes named Y7, Y13, PRS1 and PRS2 (independendly cloned as Y8 and SCL1) were cloned and sequenced on the basis of protein sequences of 20S proteasome subunits, genes named PRS3, PUP1, PUP2 and PUP3 were sequenced by chance [for summary see Hilt et al. 1993b]. We cloned the s-type genes PREI, PRE2, PRE3 and PRE4 by complementation of mutants defective in the chymotrypsin-like- (prel and pre2 mutants) or the PGPH-activity (pre3 and pre4 mutants) of the proteasome [Heinemeyer et al. 1991, Heinemeyer et al. 1993, Hilt et al. 1993a, Enenkel et al. 1994]. Additionally we cloned two α-type genes PRE5 and PRE6 using peptide sequences derived from purified proteasome subunits, extending the number of yeast 20S proteasome subunit genes to 14 [Heinemeyer et al. 1994].