Regulated degradation of yeast ornithine decarboxylase.

Ornithine decarboxylase (ODC) declines in cells that accumulate an excess of polyamines, the downstream products of the enzyme. Superfluous production of polyamines is thus prevented. In animal cells, polyamines reduce ODC activity by accelerating its degradation. Similar down-regulation of ODC activity has been observed in the budding yeast Saccharomyces cerevisiae, but induced degradation has not been documented. Here we show using pulse-chase analysis that the loss of enzyme activity is the result of increased degradation of ODC. Polyamines reduce the half-life of the newly synthesized protein from 3 h to approximately 10 min. Degradation of bulk ODC pools is also accelerated by polyamines, but the absolute rate of turnover is slower, with a half-life of 5 h in untreated and 1 h in treated cells. Newly synthesized ODC polypeptide thus undergoes a process of maturation that renders it relatively resistant to both basal and polyamine-induced degradation. Proteasome mutants have a blunted or absent regulatory response, implicating both the core protease and the regulatory cap of the proteasome in induced degradation of yeast ODC.     

Yeast antizyme mediates degradation of yeast ornithine decarboxylase by yeast but not by mammalian proteasome: new insights on yeast antizyme

Mammalian antizyme (mAz) is a central element of a feedback circuit regulating cellular polyamines by accelerating ornithine decarboxylase (ODC) degradation and inhibiting polyamine uptake. Although yeast antizyme (yAz) stimulates the degradation of yeast ODC (yODC), we show here that it has only a minor effect on polyamine uptake by yeast cells. A segment of yODC that parallels the Az binding segment of mammalian ODC (mODC) is required for its binding to yAz. Although demonstrating minimal homology to mAz, our results suggest that yAz stimulates yODC degradation via a similar mechanism of action. We demonstrate that interaction with yAz provokes degradation of yODC by yeast but not by mammalian proteasomes. This differential recognition may serve as a tool for investigating proteasome functions.     

20S proteasomal degradation of ornithine decarboxylase is regulated by NQO1

Ornithine decarboxylase (ODC), a key enzyme in the biosynthesis of polyamines, is a very labile protein. ODC is a homodimeric enzyme that undergoes ubiquitin-independent proteasomal degradation via direct interaction with antizyme, a polyamine-induced protein. Binding of antizyme promotes the dissociation of ODC homodimers and marks ODC for degradation by the 26S proteasomes. We describe here an alternative pathway for ODC degradation that is regulated by NAD(P)H quinone oxidoreductase 1 (NQO1). We show that NQO1 binds and stabilizes ODC. Dicoumarol, an inhibitor of NQO1, dissociates ODC-NQO1 interaction and enhances ubiquitin-independent ODC proteasomal degradation. We further show that dicoumarol sensitizes ODC monomers to proteasomal degradation in an antizyme-independent manner. This process of NQO1-regulated ODC degradation was recapitulated in vitro by using purified 20S proteasomes. Finally, we show that the regulation of ODC stability by NQO1 is especially prominent under oxidative stress. Our findings assign to NQO1 a role in regulating ubiquitin-independent degradation of ODC by the 20S proteasomes.     

Crystallization of a mammalian ornithine decarboxylase

Crystals of truncated (Δ425-461) pyridoxal-5′-phosphate (PLP)-dependent mouse ornithine decarboxylase (mOrnDC′) have been obtained that diffract to 2.2 Å resolution (P2₁2₁2, a = 119.5 Å, b = 74.3 Å, c = 46.1 Å). OrnDC produces putrescine, which is the precursor for the synthesis of polyamines in eukaryotes. Regulation of activity and understanding of the mechanism of action of this enzyme may aid in the development of compounds against cancer. mOrnDC is a member of group IV PLP-dependent decarboxylases, for which there are no known representative structures.     

Ubiquitin-independent mechanisms of mouse ornithine decarboxylase degradation are conserved between mammalian and fungal cells

The polyamine biosynthetic enzyme ornithine decarboxylase (ODC) is degraded by the 26 S proteasome via a ubiquitin-independent pathway in mammalian cells. Its degradation is greatly accelerated by association with the polyamine-induced regulatory protein antizyme 1 (AZ1). Mouse ODC (mODC) that is expressed in the yeast Saccharomyces cerevisiae is also rapidly degraded by the proteasome of that organism. We have now carried out in vivo and in vitro studies to determine whether S. cerevisiae proteasomes recognize mODC degradation signals. Mutations of mODC that stabilized the protein in animal cells also did so in the fungus. Moreover, the mODC degradation signal was able to destabilize a GFP or Ura3 reporter in GFP-mODC and Ura3-mODC fusion proteins. Co-expression of AZ1 accelerated mODC degradation 2-3-fold in yeast cells. The degradation of both mODC and the endogenous yeast ODC (yODC) was unaffected in S. cerevisiae mutants with various defects in ubiquitin metabolism, and ubiquitinylated forms of mODC were not detected in yeast cells. In addition, recombinant mODC was degraded in an ATP-dependent manner by affinity-purified yeast 26 S proteasomes in the absence of ubiquitin. Degradation by purified yeast proteasomes was sensitive to mutations that stabilized mODC in vivo, but was not accelerated by recombinant AZ1. These studies demonstrate that cell constituents required for mODC degradation are conserved between animals and fungi, and that both mammalian and fungal ODC are subject to proteasome-mediated proteolysis by ubiquitin-independent mechanisms.     

L-ornithine-induced inactivation of mammalian ornithine decarboxylase in vitro

Partially purified ornithine decarboxylase, isolated from the liver of thioacetamide-treated rats, is stable in the absence of added low-molecular-mass thiols or other reducing agents. However, under these conditions, the enzyme is rapidly inactivated upon incubation with L-ornithine or L-2-methylornithine. The inactivation process follows first-order kinetics, and saturation kinetics are observed. Rapid recovery of activity is observed after subsequent addition of dithiothreitol. As distinct from L-ornithine, D-ornithine, putrescine, spermidine, or spermine do not produce inactivation of ornithine decarboxylase. Very similar results are obtained with pure ornithine decarboxylase isolated from androgen-stimulated mouse kidney, stabilized with a rat liver extract.     

Translational regulation of mammalian ornithine decarboxylase by polyamines

Ornithine decarboxylase, which catalyses the formation of putrescine, is the first and rate-limiting enzyme in the biosynthesis of polyamines in mammalian cells. The enzyme is highly regulated, as indicated by rapid changes in its mRNA and protein during cell growth. Here we report that ornithine decarboxylase is regulated at the translational level by polyamines in difluoromethylornithine-resistant mouse myeloma cells that overproduce the enzyme due to amplification of an ornithine decarboxylase gene. When such cells are exposed to putrescine or other polyamines, there is a rapid and specific decrease in the rate of synthesis of ornithine decarboxylase, assayed by pulse-labeling. Neither the cellular content of ornithine decarboxylase mRNA nor the half-life of ornithine decarboxylase protein is affected. Our results indicate that polyamines negatively regulate the translation of ornithine decarboxylase mRNA, thereby controlling their own synthesis.     

Mechanisms of degradation of the fungal ornithine decarboxylase

Ornithine decarboxylase (ODC) is the first enzyme in polyamine biosynthesis in numerous living organisms, from bacteria to mammalian cells. Its control is under negative feedback regulation by the end products of the pathway. In dimorphic fungi, ODC activity and therefore polyamine concentrations are related to the morphogenetic process. From the fission yeast Schizosaccharomyces pombe to human, polyamines induce antizyme synthesis which in turn inactivates ODC. This is hydrolyzed by the 26S proteasome without ubiquitination. The regulatory mechanism of antizyme on polyamines is conserved, although to date no antizyme homology has been identified in some fungal species. The components that are responsible for regulating polyamine levels in cells and the current knowledge of ODC regulation in dimorphic fungi are presented in this review. ODC degradation is of particular interest because inhibitors of this pathway may lead to the discovery of novel antifungal drugs.     

Regulated degradation of ornithine decarboxylase requires interaction with the polyamine-inducible protein antizyme.

Intracellular degradation of vertebrate ornithine decarboxylase (ODC) is accelerated by polyamines, the products of the pathway controlled by ODC. Antizyme, a reversible, tightly binding protein inhibitor of ODC activity, is believed to be involved in this process. Mouse and Trypanosoma brucei ODCs are structurally similar, but the trypanosome enzyme, unlike that of the mouse, is not regulated by intracellular polyamines when expressed in hamster cells (L. Ghoda, D. Sidney, M. Macrae, and P. Coffino, Mol. Cell. Biol. 12:2178-2185, 1992). We found that mouse ODC interacts with antizyme in vitro but trypanosome ODC does not. To localize the region necessary for binding, we made a series of enzymatically active chimeric mouse-trypanosome ODCs and tested them for antizyme interaction. Replacing residues 117 to 140 within the 461-amino-acid mouse ODC sequence with the equivalent region of trypanosome ODC disrupted both antizyme binding and in vivo regulation. Formation of an antizyme-ODC complex is therefore required for regulated degradation.     

Interrelation between the charge isoforms of mammalian ornithine decarboxylase

Ornithine decarboxylase (ODC) isolated from a variety of tissues has been separated, using DEAE ion-exchange chromatography, into multiple peaks of activity that appear to be related to control of this enzyme stability. Reports of these charge isoforms in current literature are generally unclear as to whether these represent a covalent posttranslational modification or merely an alteration in structural conformation or association. In this study we investigated the relationship of this form separation to the degree of enzyme polymerization, interaction with other proteins and buffer components, and the multiple isoelectric forms of this enzyme noted in denaturing concentrations of urea. High-performance chromatography techniques were used to demonstrate that two of the major enzyme forms, ODC I and II, are really monomers of the enzyme, while minor peaks of activity frequently observed to elute after ODC II contain various dimeric enzyme states. Pyridoxal 5'-phosphate (0.05 mM) added to isolated enzyme preparations composed of I and II monomers induced the formation of I and II dimers as well as a mixed I-II dimer. All three dimer forms were observed to be natural components of freshly isolated crude cell homogenates. The charge distinction between the monomer forms I and II was found to be maintained during ion-exchange chromatography in the presence of 8 M urea, and the enzyme isoforms demonstrated distinct bands on isoelectric focusing gels run in the presence of 9 M urea. Thus, although some of the multiple ornithine decarboxylase forms identified by ion-exchange chromatography of crude mammalian cell homogenates are related to enzyme conformation, the two major forms are distinctly charged protein states that can be visualized using two-dimensional gel electrophoresis of highly purified samples.     

Studies of mammalian ornithine decarboxylase using a monoclonal antibody.

A monoclonal antibody of the immunoglobulin M class was produced against mouse kidney ornithine decarboxylase. Screening for the antibody was carried out using alpha-difluoromethyl[5-3H]ornithine-labelled ornithine decarboxylase. The antibody reacted with this antigen and with native ornithine decarboxylase. The antibody attached to Sepharose could be used to form an immunoaffinity column that retained mammalian ornithine decarboxylase. The active enzyme could then be eluted in a highly purified form by 1.0M-sodium thiocyanate. The monoclonal antibody could also be used to precipitate labelled ornithine decarboxylase from homogenates of kidneys from androgen-treated mice given [35S]methionine. Only one band, corresponding to Mr of about 55000, was observed. The extensive labelling of this band is consistent with the rapid turnover of ornithine decarboxylase protein, since this enzyme represents only about 1 part in 10000 of the cytosolic protein.     

Biochemical and genetic characterization of the structure of yeast ornithine decarboxylase

The ornithine decarboxylase gene of S. cerevisiae encodes a predicted protein of approximately 53 kD highly homologous with the ornithine decarboxylase of other species. However, the native enzyme has been reported as an 86 kD protein. Our molecular sieve analysis indicated a Mr = 110,000 for the native enzyme. SDS-PAGE analysis of [H3]-alpha-difluoromethylornithine labelled enzyme demonstrated a subunit Mr of approximately 50 kD and suggested the native enzyme is a dimer. Genetic analyses support this conclusion. The complementary, ornithine decarboxylase deficient mutations spe 1A and spe 1B were mapped to the enzyme structural gene by linkage analysis and gene conversion mapping. This demonstrated that the mutations exhibit intragenic complementation which suggests protein-protein interactions and an oligomeric structure for the yeast enzyme. We conclude that yeast ornithine decarboxylase is a dimeric enzyme of 53 kD subunits.     

Structural elements of ornithine decarboxylase required for intracellular degradation and polyamine-dependent regulation.

Mammalian ornithine decarboxylase (ODC), a key enzyme in polyamine biosynthesis, is rapidly degraded in cells, an attribute important to the regulation of its activity. Mutant and chimeric ODCs were created to determine the structural requirements for two modes of proteolysis. Constitutive degradation requires the carboxy terminus and is independent of intracellular polyamines. Truncation of five or more carboxy-terminal amino acids prevents this mode of degradation, as do several internal deletions within the 37 carboxy-most amino acids that spare the last five residues. Polyamine-dependent degradation of ODC requires a distinct region outside the carboxy terminus. The ODC of a parasite, Trypanosoma brucei, is structurally very similar to mouse ODC but lacks the carboxy-terminal domain; it is not a substrate for either pathway. The regulatory properties of enzymatically active chimeric proteins incorporating regions of the two ODCs support the conclusion that distinct domains of mouse ODC confer constitutive degradation and polyamine-mediated regulation. Mouse ODC contains two PEST regions. The first was not required for either form of degradation; major deletions within the second ablated constitutive degradation. When mouse and T. brucei ODC RNAs were translated in vitro in a reticulocyte lysate system, the effects of polyamine concentration on ODC protein production and activity were similar for the two mRNAs, which contradicts claims that this system accurately reflects the in vivo effects of polyamines on responsive ODCs.     

Catalytic properties of yeast protein kinase C: difference between the yeast and mammalian enzymes.

With bovine myelin basic protein as a model common substrate, protein kinases C (PKC) purified from yeast (Saccharomyces cerevisiae) and mammalian tissue (rat brain) were shown to exhibit clearly different catalytic properties. The major sites of phosphorylation in bovine myelin basic protein by the yeast PKC were identified: Thr-19, Thr-34, and Thr-65. These sites are distinctly different from those for the mammalian PKC: Ser-8, Ser-46, Ser-55, Ser-110, Ser-132, Ser-151, and Ser-161, which were previously identified [Kishimoto, A., Nishiyama, K., Nakanishi, H., Uratsuji, Y., Nomura, H., Takeyama, Y., & Nishizuka, Y. (1985) J. Biol. Chem. 160, 12492-12499]. The results suggest that the yeast and mammalian enzymes may play distinct roles in cellular regulation. No evidence is available, however, that a yeast-type PKC exists in mammalian tissues. An oligopeptide containing the sequence around Thr-19 of bovine myelin basic protein, Lys-Tyr-Leu-Ala-Ser-Ala-Ser-Thr(19)-Met-Asp-His-Ala, can be used as a substrate for selective assaying of the yeast PKC.     

Translational regulation of ornithine decarboxylase and other enzymes of the polyamine pathway

It has long been known that polyamines play an essential role in the proliferation of mammalian cells, and the polyamine biosynthetic pathway may provide an important target for the development of agents that inhibit carcinogenesis and tumor growth. The rate-limiting enzymes of the polyamine pathway, ornithine decarboxylase (ODC) and S-adenosylmethionine decarboxylase (AdoMetDC), are highly regulated in the cell, and much of this regulation occurs at the level of translation. Although the 5' leader sequences of ODC and AdoMetDC are both highly structured and contain small internal open reading frames (ORFs), the regulation of their translation appears to be quite different. The translational regulation of ODC is more dependent on secondary structure, and therefore responds to the intracellular availability of active eIF-4E, the cap-binding subunit of the eIF-4F complex, which mediates translation initiations. Cell-specific translation of AdoMetDC appears to be regulated exclusively through the internal ORF, which causes ribosome stalling that is independent of eIF-4E levels and decreases the efficiency with which the downstream ORF encoding AdoMetDC protein is translated. The translation of both ODC and AdoMetDC is negatively regulated by intracellular changes in the polyamines spermidine and spermine. Thus, when polyamine levels are low, the synthesis of both ODC and AdoMetDC is increased, and an increase in polyamine content causes a corresponding decrease in protein synthesis. However, an increase in active eIF-4E may allow for the synthesis of ODC even in the presence of polyamine levels that repress ODC translation in cells with lower levels of the initiation factor. In contrast, the amino acid sequence that is encoded by the upstream ORF is critical for polyamine regulation of AdoMetDC synthesis and polyamines may affect synthesis by interaction with the putative peptide, MAGDIS.     

DL-a-Monofluoromethylputrescine is a potent irreversible inhibitor of Escherichia coli ornithine decarboxylase.

DL-alpha-Monofluoromethylputrescine (compound R.M.I. 71864) is an enzyme-activated irreversible inhibitor of the biosynthetic enzyme ornithine decarboxylase from Escherichia coli. This compound, however, has much less effect in vitro on ornithine decarboxylase obtained from Pseudomonas aeruginosa. These findings are in contrast with those previously found with the substrate analogue DL-alpha-difluoromethylornithine (compound R.M.I. 71782). The K1 of the DL-alpha-monofluoromethylputrescine for the E. coli ornithine decarboxylase is 110 microM, and the half-life (t1/2) calculated for an infinite concentration of inhibitor is 2.1 min. When DL-alpha-monofluoromethylputrescine is used in combination with DL-alpha-difluoromethylarginine (R.M.I. 71897), an irreversible inhibitor of arginine decarboxylase, in vivo in E. coli, both decarboxylase activities are inhibited (greater than 95%) but putrescine levels are only decreased to about one-third of control values and spermidine levels are slightly increased.     

Structural elements of antizymes 1 and 2 are required for proteasomal degradation of ornithine decarboxylase

The antizymes constitute a conserved gene family with at least three mammalian orthologs. As described previously, in a degradation system utilizing rabbit reticulocyte lysate, antizyme 1 (AZ1) accelerates proteasomal ornithine decarboxylase (ODC) degradation, but antizyme 2 (AZ2) does not. To examine the relationship between antizyme structure and function, we further characterized the properties of AZ1 and AZ2 and protein chimeras composed of elements of the two. AZ1 binds to ODC with about a 3-fold higher potency than AZ2, but this cannot account for their distinct degradative activities. The dissimilar degradative capacity of AZ1 and AZ2 is also observed using purified proteasomes. A series of reciprocal AZ1/AZ2 chimeras was used to determine the sequence elements needed to direct ODC degradation. An element contained within amino acids 130-145 of AZ1 is essential for this function. Constructs in which amino acids 130-145 were exchanged between the antizymes confirmed the critical nature of this region. Within this region, amino acids 131 and 145 proved responsible for the functional difference between the two forms of AZ.