Demonstration of two distinct high molecular weight proteases in rabbit reticulocytes, one of which degrades ubiquitin conjugates

Reticulocytes contain a nonlysosomal proteolytic pathway that requires ATP and ubiquitin. By DEAE chromatography and gel filtration, we were able to fractionate the ATP-dependent system into a 30-300-kDa fraction that catalyzes the ATP-dependent conjugation of ubiquitin to substrates ("Conjugation Fraction") and a high mass fraction (greater than 450 kDa) necessary for hydrolysis of the conjugated proteins. The latter contains two distinct proteases. One protease is unusually large, approximately 1500 kDa, and degrades proteins only when ATP and the conjugating fractions are added. This activity precipitates at 0-38% (NH4)2SO4 saturation and is essential for ATP-dependent proteolysis. Like crude extracts, it is labile in the absence of nucleotides and is inhibited by heparin, poly(Glu-Ala-Tyr), 3,4-dichloroisocoumarin, hemin, decavanadate, N-ethylmaleimide, and various peptide chloromethyl ketones. It lacks amino-peptidase and insulin-degrading activities and does not require tRNA for activity. The ubiquitin-conjugate degrading enzyme, which we suggest be named UCDEN, is inactive against substrates that cannot undergo ubiquitin conjugation. The smaller protease (670 kDa), which precipitates at 40-80% (NH4)2SO4 saturation, does not require ATP or ubiquitin and is therefore not required for ATP-dependent proteolysis. It is stimulated by N-ethylmaleimide and 3,4-dichloroisocoumarin and is stable at 37 degrees C. It hydrolyzes fluorometric tetrapeptides and proteins, including proteins which cannot be conjugated to ubiquitin. Thus, reticulocytes contain two large cytosolic proteases: one is essential for the degradation of ubiquitin conjugates, while the function of the other is uncertain.     

Rad23 promotes the targeting of proteolytic substrates to the proteasome

Rad23 contains a ubiquitin-like domain (UbL(R23)) that interacts with catalytically active proteasomes and two ubiquitin (Ub)-associated (UBA) sequences that bind Ub. The UBA domains can bind Ub in vitro, although the significance of this interaction in vivo is poorly understood. Rad23 can interfere with the assembly of multi-Ub chains in vitro, and high-level expression caused stabilization of proteolytic substrates in vivo. We report here that Rad23 interacts with ubiquitinated cellular proteins through the synergistic action of its UBA domains. Rad23 plays an overlapping role with Rpn10, a proteasome-associated multi-Ub chain binding protein. Mutations in the UBA domains prevent efficient interaction with ubiquitinated proteins and result in poor suppression of the growth and proteolytic defects of a rad23 Delta rpn10 Delta mutant. High-level expression of Rad23 revealed, for the first time, an interaction between ubiquitinated proteins and the proteasome. This increase was not observed in rpn10 Delta mutants, suggesting that Rpn10 participates in the recognition of proteolytic substrates that are delivered by Rad23. Overexpression of UbL(R23) caused stabilization of a model substrate, indicating that an unregulated UbL(R23)-proteasome interaction can interfere with the efficient delivery of proteolytic substrates by Rad23. Because the suppression of a rad23 Delta rpn10 Delta mutant phenotype required both UbL(R23) and UBA domains, our findings support the hypothesis that Rad23 encodes a novel regulatory factor that translocates ubiquitinated substrates to the proteasome.     

Structure of the ubiquitin-interacting motif of S5a bound to the ubiquitin-like domain of HR23B

Ubiquitination, a modification in which single or multiple ubiquitin molecules are attached to a protein, serves signaling functions that control several cellular processes. The ubiquitination signal is recognized by downstream effectors, many of which carry a ubiquitin-interacting motif (UIM). Such interactions can be modulated by regulators carrying a ubiquitin-like (UbL) domain, which binds UIM by mimicking ubiquitination. Of them, HR23B regulates the proteasomal targeting of ubiquitinated substrates, DNA repair factors, and other proteins. Here we report the structure of the UIM of the proteasome subunit S5a bound to the UbL domain of HR23B. The UbL domain presents one hydrophobic and two polar contact sites for interaction with UIM. The residues in these contact sites are well conserved in ubiquitin, but ubiquitin also presents a histidine at the interface. The pH-dependent protonation of this residue interferes with the access of ubiquitin to the UIM and the ubiquitin-associated domain (UBA), and its mutation to a smaller residue increases the affinity of ubiquitin for UIM.     

Binding surface mapping of intra- and interdomain interactions among hHR23B,ubiquitin, and polyubiquitin binding site 2 of S5a

hHR23B is the human homologue of the yeast protein RAD23 and is known to participate in DNA repair by stabilizing xeroderma pigmentosum group C protein. However, hHR23B and RAD23 also have many important functions related to general proteolysis. hHR23B consists of N-terminal ubiquitin-like (UbL), ubiquitin association 1 (UBA1), xeroderma pigmentosum group C binding, and UBA2 domains. The UBA domains interact with ubiquitin (Ub) and inhibit the assembly of polyubiquitin. On the other hand, the UbL domain interacts with the poly-Ub binding site 2 (PUbS2) domain of the S5a protein, which can carry polyubiquitinated substrates into the proteasome. We calculated the NMR structure of the UbL domain of hHR23B and determined binding surfaces of UbL and Ub to UBA1, UBA2, of hHR23B and PUbS2 of S5a by using chemical shift perturbation. Interestingly, the surfaces of UbL and Ub that bind to UBA1, UBA2, and PUbS2 are similar, consisting of five beta-strands and their connecting loops. This is the first report that an intramolecular interaction between UbL and UBA domains is possible, and this interaction could be important for the control of proteolysis by hHR23B. The binding specificities of UbL and Ub for PUbS1, PUbS2, and general ubiquitin-interacting motifs, which share the LALA motif, were evaluated. The UBA domains bind to the surface of Ub including Lys-48, which is required for multiubiquitin assembly, possibly explaining the observed inhibition of multiubiquitination by hHR23B. The UBA domains bind to UbL through electrostatic interactions supported by hydrophobic interactions and to Ub mainly through hydrophobic interactions supported by electrostatic interactions.     

Yeast contains multiple forms of histone acetyltransferase

We have assayed several methods to quantitatively recover yeast histone acetyltransferases in an attempt to study the multiplicity of enzymatic activities. Two methods, namely (NH4)2SO4 precipitation and salt dissociation of chromatin in 0.5 M NaCl, yielded convenient preparations of total histone acetyltransferases. DEAE-Sepharose chromatography of the crude extracts resulted in the separation of three peaks of activity when total yeast histones were used as substrate. However, the scanning of the enzymatic activity toward individual histones along the chromatography, achieved by determining the specific activity of the individual histones after incubating whole histones and [14C]acetyl-CoA with the chromatographic fractions, yielded four peaks. The first two peaks showed specificity toward H2B and H3, respectively. Although they partially overlapped, rechromatography on cation exchangers allowed us to resolve the two activities, and several criteria were used to prove that they correspond to different enzyme molecules. The last two peaks were H4-specific, but the present data suggest that one of the activities is chromatin-bound, whereas the other surely corresponds to the cytoplasmic B-form of the enzyme. The enzyme specific for yeast H2B acetylates chicken erythrocyte H2A, rather than H2B. The detected multiplicity of yeast histone acetyltransferases may correspond to the multiplicity of roles proposed for histone acetylation.     

An enzyme related to the high molecular weight multicatalytic proteinase, macropain, participates in a ubiquitin-mediated, ATP-stimulated proteolytic pathway in soluble extracts of BHK 21/C13 fibroblasts

Soluble, cell-free extracts of BHK 21/C13 fibroblasts degraded a variety of exogenous proteins to acid-soluble peptides at pH 8.0. ATP stimulated the rates of proteolysis. Both the absolute rate of proteolysis and the magnitude of the ATP effect depended on the specific substrate. For example, casein was degraded approximately 10-fold faster than lysozyme, but lysozyme degradation was more highly stimulated by ATP than was casein degradation. Ubiquitin enhanced the ATP-stimulated proteolysis of each substrate in both postmicrosomal extracts and DEAE-cellulose fractionated extracts. In each extract, ubiquitin enhanced the ATP-stimulated degradation of lysozyme to a greater degree than that of casein. These results suggested that lysozyme was degraded by a pathway that was more dependent upon ubiquitin than was casein. Further evidence for this conclusion was obtained in studies using substrates whose amino groups were blocked by extensive methylation or carbamoylation. The high molecular weight proteinase, macropain, appears to be involved in the ATP-stimulated degradation of both substrates. Specific immunoprecipitation of macropain with polyclonal antibodies resulted in the inhibition of ATP-stimulated proteinase activity both in the absence and presence of ubiquitin. These results indicate that macropain plays a role in both ubiquitin-mediated and ubiquitin-independent ATP-stimulated proteolysis in BHK cell extracts.     

A novel, arsenite-sensitive E2 of the ubiquitin pathway: purification and properties

In the multienzyme ubiquitin-dependent proteolytic pathway, conjugation of ubiquitin to target proteins serves as a signal for protein degradation. Rabbit reticulocytes possess a family of proteins, known as E2's, that form labile ubiquitin adducts by undergoing transthiolation with the ubiquitin thiol ester form of ubiquitin activating enzyme (E1). Only one E2 appears to function in ubiquitin-dependent protein degradation. The others have been postulated to function in regulatory ubiquitin conjugation. We have purified and characterized a previously undescribed E2 from rabbit reticulocytes. E2(230K) is an apparent monomer with a molecular mass of 230 kDa. The enzyme forms a labile ubiquitin adduct in the presence of E1, ubiquitin, and MgATP and catalyzes conjugation of ubiquitin to protein substrates. Exogenous protein substrates included yeast cytochrome c(Km = 125 mu M; kcat approximately 0.37 min-1) and histone H3 (Km less than 1.3 mu M; kcat approximately 0.18 min-1) as well as lysozyme, alpha-lactalbumin, and alpha-casein. E2(230K) did not efficiently reconstitute Ub-dependent degradation of substrates that it conjugated, either in the absence or in the presence of the ubiquitin-protein ligase that is involved in degradation. E2(230K) may thus be an enzyme that functions in regulatory Ub conjugation. Relative to other E2's, which are very iodoacetamide sensitive, E2(230K) was more slowly inactivated by iodoacetamide (k(obs) = 0.037 min-1 at 1.5 mM iodoacetamide; pH 7.0, 37 degrees C). E2(230K) was also unique among E2's in being subject to inactivation by inorganic arsenite (k(i)max = 0.12 min-1; K(0.5) = 3.3 mM; pH 7.0, 37 degrees C). Arsenite is considered to be a reagent specific for vicinal sulfhydryl sites in proteins, and inhibition is usually rapidly reversed upon addition of competitive dithiol compounds. Inactivation of E2(230K) by arsenite was not reversed within 10 min after addition of dithiothreitol at a concentration that blocked inactivation if it was premixed with arsenite; inactivation is therefore irreversible or very slowly reversible. We postulate that a conformation change of E2(230K) may be rate-limiting for interaction of enzyme thiol groups with arsenite.     

A conditional yeast E1 mutant blocks the ubiquitin-proteasome pathway and reveals a role for ubiquitin conjugates in targeting Rad23 to the proteasome

E1 ubiquitin activating enzyme catalyzes the initial step in all ubiquitin-dependent processes. We report the isolation of uba1-204, a temperature-sensitive allele of the essential Saccharomyces cerevisiae E1 gene, UBA1. Uba1-204 cells exhibit dramatic inhibition of the ubiquitin-proteasome system, resulting in rapid depletion of cellular ubiquitin conjugates and stabilization of multiple substrates. We have employed the tight phenotype of this mutant to investigate the role ubiquitin conjugates play in the dynamic interaction of the UbL/UBA adaptor proteins Rad23 and Dsk2 with the proteasome. Although proteasomes purified from mutant cells are intact and proteolytically active, they are depleted of ubiquitin conjugates, Rad23, and Dsk2. Binding of Rad23 to these proteasomes in vitro is enhanced by addition of either free or substrate-linked ubiquitin chains. Moreover, association of Rad23 with proteasomes in mutant and wild-type cells is improved upon stabilizing ubiquitin conjugates with proteasome inhibitor. We propose that recognition of polyubiquitin chains by Rad23 promotes its shuttling to the proteasome in vivo.     

Proteolysis in heat-stressed HeLa cells. Stabilization of ubiquitin correlates with the loss of proline endopeptidase

When intact HeLa cells were incubated at 45 degrees C, there was progressive inactivation of proline endopeptidase. Rapid loss of the enzyme did not occur in extracts maintained at 45 degrees C. Since Western blots of sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels showed no decrease in the immunoreactive 70-kDa proline endopeptidase band, its in vivo disappearance apparently results from irreversible denaturation or modification. Loss of proline endopeptidase activity was paralleled by reduced degradation of injected ubiquitin and bovine serum albumin. In contrast, proteolysis of injected lysozyme or pancreatic trypsin inhibitor was barely affected. Electrophoretic analysis of ubiquitin or bovine serum albumin retrieved from heated HeLa cells showed that the injected proteins were intact. Thus, the presence of proline endopeptidase appears to be required for initial cleavage of these two substrates, but it has not been shown that the enzyme is directly responsible. Selective stabilization of a subset of the injected proteins does, however, demonstrate the existence of distinct proteolytic pathways in HeLa cytosol.     

2',5'-oligoadenylate synthetase gene in chicken: gene structure, distribution of alleles and their expression

We have cloned the gene for chicken 2',5'-oligoadenylate synthetase (ChOAS) by the method of polymerase chain reaction with use of ChOAS cDNA sequence. The ChOAS gene is composed of five introns and six exons containing all of the sequence of the ChOAS cDNA from the start to the stop codon. The first five exons of ChOAS gene which encode the OAS catalytic domain have a similar structure to HuOAS1 gene including the exon-intron boundaries. However, the length of introns of ChOAS gene is only 1/7 of those of HuOAS1 gene. The sixth exon of the ChOAS gene encodes the ubiquitin-like (UbL) domain of two consecutive sequence (UbL1 and UbL2) homologous to ubiquitin. ChOAS encoded in a single copy gene has at least two alleles, OAS(*)A and OAS(*)B. The differences between these two alleles are in the sixth exon of the gene; a 96-nucleotide sequence in the UbL1 portion of OAS(*)A is deleted from OAS(*)B. No OAS(*)B gene was detected in nine lines of chickens tested other than Leghorns. Almost the same levels of ChOAS-A and -B proteins induced physiologically in erythrocytes were detected in infant chickens (2-week-old), but in grown-up chickens (6-month-old) the level of erythrocyte OAS-B was markedly reduced in most of B/B chickens. Thus, the UbL domain of ChOAS is responsible for the maintenance of the OAS level in the tissue.     

A comparison of the cholinesterases of an oyster (Crassostrea virginica) and a clam (Macrocallista nimbosa).

Cholinesterase activities in the hearts and ganglia of an oyster (Crassostrea virginica) and a venerid clam (Macrocallista nimbosa) were measured and compared. Tissue extracts were partially purified by ammonium sulfate fractionation followed by gel column chromatography. Enzymatic activity was assayed spectrophotometrically; substrates were acetyl-, butyryl-, and propionylthiocholine (ATC, BTC, PTC). Kinetic constants characterizing each enzyme were derived. At all substrate concentrations, the hydrolysis rates of both clam enzymes were in the order: BTC greater than PTC greater than ATC. With oyster enzymes the ranking was ATC greater than or equal to PTC greater BTC. The specific activities of oyster heart and ganglion enzymes were similar. In contrast, clam ganglion extracts were 75-100 times more active than clam heart extracts and, with any substrate, had greater activity than either oyster enzyme. All enzyme preparations proved to be homogeneous on the bases of constant substrate activity ratios in successive column fractions, and of intermediate velocities with mixed substrates. Six cholinesterase inhibitors were tested. The specific acetylcholinesterase antagonist, B.W. 62C47, WAS MUCH MORE EFFECTIVE AGAINST OYSTER ENZYMES, WHILE THE SPECIFIC ANTIBUTYRYLCHOLINESTERASE, ISO-OMPA, almost totally inhibited calm enzyme activity, but had little effect on oyster. Eserine was the most effective inhibitor of both enzymes. In conclusion, the enzymes in oyster tissues are acetylcholinesterases, while clam enzymes are butyrylcholinesterases. Nevertheless, clam ganglion esterase is sifficiently active to hydrolyze the physiological substrate, acetylcholine. These results explain the long-observed differences in isolated heart pharmacology between ostreid and venerid bivalves.     

Characterization of the enzymatic properties of the first and second domains of metallocarboxypeptidase D.

Carboxypeptidase D (CPD) contains three domains with homology to other metallocarboxypeptidases. To further characterize the various domains, we constructed a series of point mutants with a critical active site Glu of duck CPD converted to Gln. The proteins were expressed in the baculovirus system, purified to homogeneity, and characterized. Point mutations within both the first and second domains eliminated enzyme activity, indicating that the third domain is inactive toward dansyl-Phe-Ala-Arg. CPD removed only the C-terminal Lys or Arg from peptides, with the first domain more efficient toward Arg and the second domain more efficient toward Lys. Peptides containing Pro in the penultimate position were poorly cleaved by either domain. Cleavage of a peptide with Ala in the penultimate position was most efficient, with the relative order Ala >/= Met > Ser, Phe > Tyr > Trp > Thr >/= Gln, Asp, Leu, Gly > Pro for CPD with both domains active. There were only minor differences between the first and the second domains regarding the influence of the penultimate amino acid. The first domain was optimally active at pH 6.3-7.5, whereas the second domain was optimally active at pH 5. 0-6.5. Thus, the first and second carboxypeptidase domains have complementary enzyme activities. Furthermore, the finding that CPD with both domains active shows a broad activity to a wide range of substrates is consistent with a role for this enzyme in the processing of many proteins that transit the secretory pathway.     

Antibacterial activity in four marine crustacean decapods

A search for antibacterial activity in different body-parts of Pandalus borealis (northern shrimp), Pagurus bernhardus (hermit crab), Hyas araneus (spider crab) and Paralithodes camtschatica (king crab) was conducted. Dried samples were extracted with 60% (v/v) acetonitrile, containing 0.1% (v/v) trifluoroacetic acid, and further extracted and concentrated on C18 cartridges. Eluates from the solid phase extraction were tested for antibacterial, lysozyme and haemolytic activity. Antibacterial activity against Escherichia coli, Vibrio anguillarum, Corynebacterium glutamicum and Staphylococcus aureus was detected in extracts from several tissues in all species tested, but mainly in the haemolymph and haemocyte extracts. V. anguillarum and C. glutamicum were generally the most sensitive micro-organisms. In P. borealis and P. bernhardus most of the active fractions were not affected by proteinase K treatment, while in H. araneus and P. camtschatica most fractions were sensitive to proteinase K treatment, indicating antibacterial factors of proteinaceous nature. In P. bernhardus the active fractions were generally heat labile, whereas in H. araneus the activities were resistant to heat. Differences between active extracts regarding hydrophobicity and sensitivity for heat and proteinase K treatment indicate that several compounds are responsible for the antibacterial activities detected. Lysozyme-like activity could be detected in some fractions and haemolytic activity against human red blood cells could be detected in haemolymph/haemocyte and exoskeleton extracts from all species tested.     

Ribonucleotide reductase from Escherichia coli: demonstration of a highly active form of the enzyme.

Ribonucleotide reductase from Escherichia coli consists of two nonidentical subunits, proteins B1 and B2. The activity of the enzyme in crude extracts prepared from mechanically disrupted bacteria is very low. Enzyme activity is stimulated 5 to 10-fold by addition of an excess of either subunit. Concentrated extracts from cells lysed gently on Cellophane discs (Schaller et al.) contained 10 to 20-fold higher activity than extracts from mechanically disrupted cells. This activity was not further stimulated by either B1 or B2. The system is suitable for complementation tests for the analysis of temperature-sensitive mutants affecting the ribonucleotide reductase system. Concentrated high-speed supernatants from E. coli treated with lysozyme (Wickner et al.) also contained a high ribonucleotide reductase activity, which was stimulated slightly or not at all by addition of B1 and B2. This active form of the enzyme was unstable and could not be purified. The results suggest that the intracellular form of the enzyme consists of a tight complex of proteins B1 and B2, possibly stabilized by other intracellular structures.     

The acyl-CoA oxidases from the yeast Yarrowia lipolytica: characterization of Aox2p

One of the acyl-CoA oxidases from the yeast Yarrowia lipolytica, acyl-CoA oxidase 2 (Aox2p), has been expressed in Escherichia coli as an active, N-terminally tagged (His)(6) fusion protein. The specific activity of the purified enzyme, containing FAD, was 19.7 micromolmin(-1)mg(-1) using myristoyl-CoA as substrate. Using substrates with different chain lengths and different substituents, its kinetic properties were further analyzed. Straight-chain acyl-CoAs, with a chain length of 10-14C, are well oxidized, reflecting the properties of Aox2p as deduced from in vivo studies. Acyl-CoAs containing more than 14C were also desaturated, if their concentration was below 25 microM or if proteins capable of binding these CoA-esters, such as albumin or beta-casein, were added to the assay. These long-chain acyl-CoAs, although poor substrates, acted as competitors for the short- and medium-chain substrates. Compared to palmitoyl-CoA, activity toward hexadecadioyl-CoA, containing a omega-carboxy group, was similar. Taken together, these data suggest that micelles of long-chain acyl-CoAs are able to bind and inhibit Aox2p. The enzyme was also active toward acyl-CoA-esters containing a 2-methyl group, but only the 2S isomer was recognized.     

Protein phosphatase 2A1 is the major enzyme in vertebrate cell extracts that dephosphorylates several physiological substrates for cyclin-dependent protein kinases.

Okadaic acid (2 nM) inhibited by 80-90% the protein phosphatase activities in diluted extracts of rat liver, human fibroblasts, and Xenopus eggs acting on three substrates (high mobility group protein-I(Y), caldesmon and histone H1) phosphorylated by a cyclin-dependent protein kinase (CDK) suggesting that a type-2A phosphatase was responsible for dephosphorylating each protein. This result was confirmed by anion exchange chromatography of rat liver and Xenopus extracts, which demonstrated that the phosphatases acting on these substrates coeluted with the two major species of protein phosphatase 2A, termed PP2A1 and PP2A2. When matched for activity toward glycogen phosphorylase, PP2A1 was five- to sevenfold more active than PP2A2 and 35-fold to 70-fold more active than the free catalytic subunit (PP2Ac) toward the three CDK-labeled substrates. Protein phosphatases 1, 2B, and 2C accounted for a negligible proportion of the activity toward each substrate under the assay conditions examined. The results suggest that PP2A1 is the phosphatase that dephosphorylates a number of CDK substrates in vivo and indicate that the A and B subunits that are associated with PP2Ac in PP2A1 accelerate the dephosphorylation of CDK substrates, while suppressing the dephosphorylation of most other proteins. The possibility that PP2A1 activity is regulated during the cell cycle is discussed.     

Transfer RNA is required for conjugation of ubiquitin to selective substrates of the ubiquitin- and ATP-dependent proteolytic system

Degradation of intracellular proteins via the ubiquitin- and ATP-dependent proteolytic pathway involves several steps. In the initial event, ubiquitin, an abundant 76-residue polypeptide is covalently linked to the protein substrate in an ATP-requiring reaction. Proteins marked by ubiquitin are selectively proteolyzed in a reaction that also requires ATP. Ubiquitin conjugation to proteins appears also to be involved in regulation of cell cycle and cell division, and probably in the regulation of gene expression at the level of chromatin structure. We have previously shown (Ciechanover, A., Wolin, S. L., Steitz, J. A., and Lodish, H. F. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 1341-1345) that transfer RNA is an essential component of the ubiquitin pathway. Ribonucleases strongly and specifically inhibited the degradation of 125I-labeled bovine serum albumin, while tRNA purified from reticulocyte extract could restore the proteolytic activity. Specifically, pure tRNAHis isolated by immunoprecipitation with human autoimmune serum could restore the proteolytic activity. Here we demonstrate that tRNA is required for conjugation of ubiquitin to some but not all proteolytic substrates of the ubiquitin mediated pathway. Conjugation of 125I-labeled ubiquitin to reduced carboxymethylated bovine serum albumin, alpha-lactalbumin, and soybean trypsin inhibitor was strongly and specifically inhibited by ribonucleases. Consequently, the ATP-dependent degradation of these substrates in the cell-free ubiquitin-dependent reticulocyte system was inhibited as well. Addition of tRNA to the ribonuclease inhibited system (following inhibition of the ribonuclease) restored both the conjugation activity and the ubiquitin- and ATP-dependent degradation of these substrates. Conjugation of ubiquitin to some endogenous reticulocyte proteins was also inhibited by ribonucleases and could be restored by the addition of tRNA. In striking contrast, the conjugation of radiolabeled ubiquitin to lysozyme, oxidized RNase A, alpha-casein, and beta-lactoglobulin was not affected by the ribonuclease treatment, and the degradation of these substrates was significantly accelerated by the ribonucleases. These findings indicate that there are at least two distinct ubiquitin conjugation systems. One requires tRNA, and the other is tRNA independent. These pathways, however, must share some common component(s) of the system, since the inhibition of one system accelerates the other. The possible function of tRNA in the selective conjugation reaction and the possible role of the two distinct ubiquitin marking mechanisms are discussed.     

Detection, resolution, and nomenclature of multiple ubiquitin carboxyl-terminal esterases from bovine calf thymus

In vivo, ubiquitin exists both free and conjugated through its carboxyl terminus to the alpha- and epsilon-amino groups of a wide variety of cellular proteins. Ubiquitin carboxyl-terminal hydrolytic activity is likely a necessary step in the regeneration of the ubiquitin cofactor from ubiquitin-protein conjugates. In addition, this type of activity is required to generate the active, monomeric ubiquitin from the only known gene products: the polyprotein precursor and various ubiquitin fusion proteins. Thus, this activity is of vital importance to systems that utilize ubiquitin as a cofactor. A generic substrate, ubiquitin ethyl ester, was previously developed [Wilkinson, K. D., Cox, M. J., Mayer, A. N., & Frey, T. (1986) Biochemistry 25, 6644-6649] and utilized here to monitor the fractionation of these activities from calf thymus. By use of a rapid HPLC assay, four distinct, ubiquitin-specific esterases were identified and separated. A previously undescribed activity has been resolved and characterized, in addition to the bovine homologue of ubiquitin carboxyl-terminal hydrolase purified from rabbit reticulocytes. Two other activities resemble deconjugating activities previously detected in crude extracts but not previously purified. These activities appear to form a family of mechanistically related hydrolases. All four activities are inhibited by iodoacetamide, indicating the presence of an essential thiol group, and are inhibited to various extents by manganese. All have specific ubiquitin binding sites as judged by the low observed Km values (0.6-30 microM). The carboxyl-terminal aldehyde of ubiquitin is a potent inhibitor of these enzyme activities, with Ki values approximately 1000-fold lower than the respective Km values.(ABSTRACT TRUNCATED AT 250 WORDS)     

Endogenous substrates for in vitro phosphorylation by cyclic AMP-dependent protein kinase from Dictyostelium discoideum

Endogenous proteins which could serve as substrates for cyclic AMP-dependent protein kinase in vitro were measured in cytosolic fractions at four stages of development. A peak of cyclic AMP-dependent phosphorylation occurred at the slug stage, coincident with the appearance of cyclic AMP-dependent protein kinase. After partial purification of the slug-stage extracts by DE-52 cellulose and Sephacryl S-300 chromatography, cyclic AMP dependency of six proteins was observed. The apparent subunit molecular weights of the proteins were greater than 200,000, 110,000, 107,000, 91,000, 75,000 and 69,000. Upon further purification of the cyclic AMP-dependent protein kinase by chromatofocusing, the endogenous substrates were separated from the enzyme. In addition, the enzyme separated into catalytic and regulatory subunits. If the purified catalytic subunit was added to heated S300 fractions, proteins with apparent molecular weights of 91,000 and 107,000 were specificity phosphorylated. The results show the stage-dependent appearance of a cyclic AMP-dependent protein kinase and point out several in vitro substrates for the enzyme.     

High-resolution nuclear magnetic resonance studies of proteins

The combination of advanced high-resolution nuclear magnetic resonance (NMR) techniques with high-pressure capability represents a powerful experimental tool in studies of protein folding. This review is organized as follows: after a general introduction of high-pressure, high-resolution NMR spectroscopy of proteins, the experimental part deals with instrumentation. The main section of the review is devoted to NMR studies of reversible pressure unfolding of proteins with special emphasis on pressure-assisted cold denaturation and the detection of folding intermediates. Recent studies investigating local perturbations in proteins and the experiments following the effects of point mutations on pressure stability of proteins are also discussed. Ribonuclease A, lysozyme, ubiquitin, apomyoglobin, alpha-lactalbumin and troponin C were the model proteins investigated.