Analysis of the deubiquitinating enzymes of the yeast Saccharomyces cerevisiae.

Attachment of proteins to ubiquitin is reversed by specialized proteases called deubiquitinating enzymes (Dubs), which are also essential for ubiquitin precursor processing. In the genome of Saccharomyces cerevisiae, 17 potential DUB genes can be discerned. We have now constructed strains deleted for each of these genes. Surprisingly, given the essential nature of the ubiquitin system, none of the mutants is lethal or strongly growth defective under standard conditions, although a number have detectable abnormalities. Including results from this study, 14 of the 17 Dubs have now been shown to have ubiquitin-cleaving activity. The most extensively characterized yeast Dub is Doa4, which is required for both ubiquitin homeostasis and proteasome-dependent proteolysis. To help determine what distinguishes Doa4 functionally from other Dubs, we have cloned a DOA4 ortholog from the yeast Kluyveromyces lactis. The K. lactis protein is 42% identical to Doa4, but unexpectedly the K. lactis gene is slightly closer in nucleotide sequence to UBP5, which cannot substitute for DOA4 even in high dosage. The data suggest that the DOA4 locus underwent a duplication after the divergence of K. lactis and S. cerevisiae. This information will facilitate fine-structure analysis of the Doa4 protein to help delineate its key functional elements.

The Doa4 deubiquitinating enzyme is functionally linked to the vacuolar protein-sorting and endocytic pathways.

The Saccharomyces cerevisiae DOA4 gene encodes a deubiquitinating enzyme that is required for rapid degradation of ubiquitin-proteasome pathway substrates. Both genetic and biochemical data suggest that Doa4 acts in this pathway by facilitating ubiquitin recycling from ubiquitinated intermediates targeted to the proteasome. Here we describe the isolation of 12 spontaneous extragenic suppressors of the doa4-1 mutation; these involve seven different genes, six of which were cloned. Surprisingly, all of the cloned DID (Doa4-independent degradation) genes encode components of the vacuolar protein-sorting (Vps) pathway. In particular, all are class E Vps factors, which function in the maturation of a late endosome/prevacuolar compartment into multivesicular bodies that then fuse with the vacuole. Four of the six Did proteins are structurally related, suggesting an overlap in function. In wild-type and several vps strains, Doa4-green fluorescent protein displays a cytoplasmic/nuclear distribution. However, in cells lacking the Vps4/Did6 ATPase, a large fraction of Doa4-green fluorescent protein, like several other Vps factors, concentrates at the late endosome-like class E compartment adjacent to the vacuole. These results suggest an unanticipated connection between protein deubiquitination and endomembrane protein trafficking in which Doa4 acts at the late endosome/prevacuolar compartment to recover ubiquitin from ubiquitinated membrane proteins en route to the vacuole.

The Doa4 deubiquitinating enzyme is required for ubiquitin homeostasis in yeast.

Attachment of ubiquitin to cellular proteins frequently targets them to the 26S proteasome for degradation. In addition, ubiquitination of cell surface proteins stimulates their endocytosis and eventual degradation in the vacuole or lysosome. In the yeast Saccharomyces cerevisiae, ubiquitin is a long-lived protein, so it must be efficiently recycled from the proteolytic intermediates to which it becomes linked. We identified previously a yeast deubiquitinating enzyme, Doa4, that plays a central role in ubiquitin-dependent proteolysis by the proteasome. Biochemical and genetic data suggest that Doa4 action is closely linked to that of the proteasome. Here we provide evidence that Doa4 is required for recycling ubiquitin from ubiquitinated substrates targeted to the proteasome and, surprisingly, to the vacuole as well. In the doa4Delta mutant, ubiquitin is strongly depleted under certain conditions, most notably as cells approach stationary phase. Ubiquitin depletion precedes a striking loss of cell viability in stationary phase doa4Delta cells. This loss of viability and several other defects of doa4Delta cells are rescued by provision of additional ubiquitin. Ubiquitin becomes depleted in the mutant because it is degraded much more rapidly than in wild-type cells. Aberrant ubiquitin degradation can be partially suppressed by mutation of the proteasome or by inactivation of vacuolar proteolysis or endocytosis. We propose that Doa4 helps recycle ubiquitin from both proteasome-bound ubiquitinated intermediates and membrane proteins destined for destruction in the vacuole.

Interaction of the Doa4 deubiquitinating enzyme with the yeast 26S proteasome.

e Saccharomyces cerevisiae Doa4 deubiquitinating enzyme is required for the rapid degradation of protein substrates of the ubiquitin-proteasome pathway. Previous work suggested that Doa4 functions late in the pathway, possibly by deubiquitinating (poly)-ubiquitin-substrate intermediates associated with the 26S proteasome. We now provide evidence for physical and functional interaction between Doa4 and the proteasome. Genetic interaction is indicated by the mutual enhancement of defects associated with a deletion of DOA4 or a proteasome mutation when the two mutations are combined. Physical association of Doa4 and the proteasome was investigated with a new yeast 26S proteasome purification procedure, by which we find that a sizeable fraction of Doa4 copurifies with the protease. Another yeast deubiquitinating enzyme, Ubp5, which is related in sequence to Doa4 but cannot substitute for it even when overproduced, does not associate with the proteasome. DOA4-UBP5 chimeras were made by a novel PCR/yeast recombination method and used to identify an N-terminal 310-residue domain of Doa4 that, when appended to the catalytic domain of Ubp5, conferred Doa4 function, consistent with Ubp enzymes having a modular architecture. Unlike Ubp5, a functional Doa4-Ubp5 chimera associates with the proteasome, suggesting that proteasome binding is important for Doa4 function. Together, these data support a model in which Doa4 promotes proteolysis through removal of ubiquitin from proteolytic intermediates on the proteasome before or after initiation of substrate breakdown.

A deubiquitinating enzyme that disassembles free polyubiquitin chains is required for development but not growth in Dictyostelium.

Although cell differentiation usually involves synthesis of new proteins, little is known about the role of protein degradation. In eukaryotes, conjugation to ubiquitin polymers often targets a protein for destruction. This process is regulated by deubiquitinating enzymes, which can disassemble ubiquitin polymers or ubiquitin-substrate conjugates. We find that a deubiquitinating enzyme, UbpA, is required for Dictyostelium development. ubpA cells have normal protein profiles on gels, grow normally, and show normal responses to starvation such as differentiation and secretion of conditioned medium factor. However, ubpA cells have defective aggregation, chemotaxis, cAMP relay, and cell adhesion. These defects result from low expression of cAMP pulse-induced genes such as those encoding the cAR1 cAMP receptor, phosphodiesterase, and the gp80 adhesion protein. Treatment of ubpA cells with pulses of exogenous cAMP allows them to aggregate and express these genes like wild-type cells, but they still fail to develop fruiting bodies. Unlike wild type, ubpA cells accumulate ubiquitin-containing species that comigrate with ubiquitin polymers, suggesting a defect in polyubiquitin metabolism. UbpA has sequence similarity with yeast Ubp14, which disassembles free ubiquitin chains. Yeast ubp14 cells have a defect in proteolysis, due to excess ubiquitin chains competing for substrate binding to proteasomes. Cross-species complementation and enzyme specificity assays indicate that UbpA and Ubp14 are functional homologs. We suggest that specific developmental transitions in Dictyostelium require the degradation of specific proteins and that this process in turn requires the disassembly of polyubiquitin chains by UbpA.

[ATP-dependent proteinase La from Escherichia coli]. / ATP-zavisimaia proteinaza La iz Escherichia coli.

Homogeneous preparations of the ATP-dependent La proteinase from E. coli and two its mutant forms, containing an alanine residue instead of Ser679 or Ser368, were isolated. Ser679 was shown to be catalytically active rather than Ser368 as suggested in the literature. To choose between the alternative structures of the gene lon La proteinase fragments within the controversial regions were analysed and the gene structure established at the Laboratory of Proteolytic Enzymes (Institute of Bioorganic Chemistry) was confirmed. Inactivity of La proteinase in some in vitro systems suggests its functioning in vivo to be not autonomous, requiring additional factors.

[Cloning and expression of the 3C-proteinase gene from the poliomyelitis virus in E. coli cells]. / Konirovanie i ékspressiia gena 3C-proteinazy virusa poliomielita v kletkakh E. coli.

Expression of the 3C protease gene of poliovirus type 1 (Mahoney) in E. coli cells using various vectors was studied. The 3C gene was shown to be expressed effectively upon its cloning in HindII/HindII (bases 5240 to 6770) and in HindII/HindIII (bases 5240 to 6056) fragments of poliovirus cDNA in pTTQ8 vector containing tac-promoter and lacI-repressor gene. Products of processing at the N-terminal 3C protease Gln-Gly site and polypeptides formed upon translation from an alternative methionine, which was coded by bases 5516-5518 of poliovirus cDNA, were found among virus-specific proteins. Processing at the C-terminal 3C protease Gln-Gly site was not observed.

[Cloning, structure and expression of the full-size lon gene in Escherichia coli coding for ATP-dependent La-proteinase]. / Klonirovanie, struktura i ékspressiia polnorazmernogo gena lon Escherichia coli, kodiruiushchego ATP-zavisimuiu La-proteinazu.

Assembly of the full Escherichia coli K-12 lon gene from the EcoRI--SphI fragment of the bacterial DNA ("modified" gene) cloned and sequenced earlier and the PstI fragment of the same DNA containing 3'-terminal region of the lon gene has been performed. Both "modified" and full genes showed all phenotype properties of lon gene. The complete nucleotide sequence of the gene (2770 bp) coding for the 784 amino acid sequence of protease La was determined. Location of catalytically active serine, histidine and aspartic acid residues was suggested, and ATP-binding site found. The lon gene and protease La structures we found are compared with those described independently and differences observed are discussed.

[Cloning, expression and structure of the functionally active shortened lon gene in Escherichia coli]. / Klonirovanie, ékspressiia i struktura funktsional'no aktivnogo ukorochennogo gena lon Escherichia coli.

Lon gene of E. coli has been cloned into the plasmid pBR327. Full nucleotide sequence of the gene has been established. It was shown that the cloned gene does not possess the terminal codon and is somewhat shortened. Nevertheless it retains full phenotypic activity and expresses the C-end modified La proteinase which retains ATP-dependent proteolytic activity.

[Comparative characteristics of soluble and membrane brain aminopeptidases. I. Isolation, physico-chemical properties, catalytic activity]. / Sravnitel'naia kharakteristika rastvorimoi i membrannoi aminopeptidamozga. I. Vydelenie, fiziko-khimicheskie svoistva, kataliticheskaia aktivnost'.

The methods were worked out for isolating of the bovine brain soluble and membrane-bound aminopeptidases in highly purified state. One of the stages involved a biospecific-type chromatography on aminohexyl-Sepharose. Both enzymes were found to have equal molecular masses (ca. 100-107 kD) and isoelectric points (pI 4,6). None of the enzymes possessed a subunit structure. Both aminopeptidases were inactivated by omicron-phenanthroline and by an SH-reagent, p-hydroxymercuribenzoate. The catalytic constants for the hydrolysis of a specific substrate, L-leucine p-nitroanilide, were identical for the two enzymes. So far no differences in the physico-chemical or enzymatic properties of the soluble and membrane-bound enzymes were disclosed.