Subcellular localization and levels of aminopeptidases and dipeptidase in Saccharomyces cerevisiae

Methionine sulfoxide reductase 2 regulates Cvt autophagic pathway by altering the stability of Atg19 and Ape1 in Saccharomyces cerevisiae

The reversible oxidation of methionine plays a crucial role in redox regulation of proteins. Methionine oxidation in proteins causes major structural modifications that can destabilize and abrogate their function. The highly conserved methionine sulfoxide reductases protect proteins from oxidative damage by reducing their oxidized methionines, thus restoring their stability and function. Deletion or mutation in conserved methionine sulfoxide reductases leads to aging and several human neurological disorders and also reduces yeast growth on nonfermentable carbon sources. Despite their importance in human health, limited information about their physiological substrates in humans and yeast is available. For the first time, we show that Mxr2 interacts in vivo with two core proteins of the cytoplasm to vacuole targeting (Cvt) autophagy pathway, Atg19, and Ape1 in Saccharomyces cerevisiae. Deletion of MXR2 induces instability and early turnover of immature Ape1 and Atg19 proteins and reduces the leucine aminopeptidase activity of Ape1 without affecting the maturation process of Ape1. Additonally, Mxr2 interacts with the immature Ape1, dependent on Met17 present within the propeptide of Ape1 as a single substitution mutation of Met17 to Leu abolishes this interaction. Importantly, Ape1 M17L mutant protein resists oxidative stress-induced degradation in WT and mxr2Δ cells. By identifying Atg19 and Ape1 as cytosolic substrates of Mxr2, our study maps the hitherto unexplored connection between Mxr2 and the Cvt autophagy pathway and sheds light on Mxr2-dependent oxidative regulation of the Cvt pathway.

The entry of unclosed autophagosomes into vacuoles and its physiological relevance

It is widely stated in the literature that closed mature autophagosomes (APs) fuse with lysosomes/vacuoles during macroautophagy/autophagy. Previously, we showed that unclosed APs accumulated as clusters outside vacuoles in Vps21/Rab5 and ESCRT mutants after a short period of nitrogen starvation. However, the fate of such unclosed APs remains unclear. In this study, we used a combination of cellular and biochemical approaches to show that unclosed double-membrane APs entered vacuoles and formed unclosed single-membrane autophagic bodies after prolonged nitrogen starvation or rapamycin treatment. Vacuolar hydrolases, vacuolar transport chaperon (VTC) proteins, Ypt7, and Vam3 were all involved in the entry of unclosed double-membrane APs into vacuoles in Vps21-mutant cells. Overexpression of the vacuolar hydrolases, Pep4 or Prb1, or depletion of most VTC proteins promoted the entry of unclosed APs into vacuoles in Vps21-mutant cells, whereas depletion of Pep4 and/or Prb1 delayed the entry into vacuoles. In contrast to the complete infertility of diploid cells of typical autophagy mutants, diploid cells of Vps21 mutant progressed through meiosis to sporulation, benefiting from the entry of unclosed APs into vacuoles after prolonged nitrogen starvation. Overall, these data represent a new observation that unclosed double-membrane APs can enter vacuoles after prolonged autophagy induction, most likely as a survival strategy.

The endosomal sorting complex required for transport complex negatively regulates Erg6 degradation under specific glucose restriction conditions

Lipid droplets (LDs) are cytosolic fat storage organelles that play roles in lipid metabolism, trafficking and signaling. Breakdown of LDs in Saccharomyces cerevisiae is mainly achieved by lipolysis and lipophagy. In this study, we found that the endosomal sorting complex required for transport (ESCRT) in S. cerevisiae negatively regulated the turnover of a LD marker, Erg6, under both simplified glucose restriction (GR) and acute glucose restriction (AGR) conditions by monitoring the localization and degradation of Erg6. Loss of Vps27, Snf7 or Vps4, representative subunits of the ESCRT machinery, facilitated the delivery of Erg6-GFP to vacuoles and its degradation depending on the lipophagy protein Atg15 under simplified GR. Additionally, the lipolysis proteins Tgl3 and Tgl4 were also involved in the enhanced vacuolar localization and degradation of Erg6-GFP in vps4Δ cells. Furthermore, we found that Atg14, which is required for the formation of putatively liquid-ordered (Lo) membrane domains on the vacuole that act as preferential internalization sites for LDs, abundantly localized to vacuolar membranes in ESCRT mutants. Most importantly, the depletion or overexpression of Atg14 correspondingly abolished or promoted the observed Erg6 degradation in ESCRT mutant cells. We propose that Atg14 together with other proteins promotes Erg6 degradation in ESCRT mutant cells under specific glucose restriction conditions. These results shed new light on the regulation of ESCRT on LD turnover.

Vacuolar hydrolysis and efflux: current knowledge and unanswered questions

Hydrolysis within the vacuole in yeast and the lysosome in mammals is required for the degradation and recycling of a multitude of substrates, many of which are delivered to the vacuole/lysosome by autophagy. In humans, defects in lysosomal hydrolysis and efflux can have devastating consequences, and contribute to a class of diseases referred to as lysosomal storage disorders. Despite the importance of these processes, many of the proteins and regulatory mechanisms involved in hydrolysis and efflux are poorly understood. In this review, we describe our current knowledge of the vacuolar/lysosomal degradation and efflux of a vast array of substrates, focusing primarily on what is known in the yeast Saccharomyces cerevisiae. We also highlight many unanswered questions, the answers to which may lead to new advances in the treatment of lysosomal storage disorders. Abbreviations: Ams1: α-mannosidase; Ape1: aminopeptidase I; Ape3: aminopeptidase Y; Ape4: aspartyl aminopeptidase; Atg: autophagy related; Cps1: carboxypeptidase S; CTNS: cystinosin, lysosomal cystine transporter; CTSA: cathepsin A; CTSD: cathepsin D; Cvt: cytoplasm-to-vacuole targeting; Dap2: dipeptidyl aminopeptidase B; GS-bimane: glutathione-S-bimane; GSH: glutathione; LDs: lipid droplets; MVB: multivesicular body; PAS: phagophore assembly site; Pep4: proteinase A; PolyP: polyphosphate; Prb1: proteinase B; Prc1: carboxypeptidase Y; V-ATPase: vacuolar-type proton-translocating ATPase; VTC: vacuolar transporter chaperone.

New mechanisms that regulate Saccharomyces cerevisiae short peptide transporter achieve balanced intracellular amino acid concentrations

The budding yeast Saccharomyces cerevisiae is able to take up large quantities of amino acids in the form of di- and tripeptides via a short peptide transporter, Ptr2p. It is known that PTR2 can be induced by certain peptides and amino acids, and the mechanisms governing this upregulation are understood at the molecular level. We describe two new opposing mechanisms of regulation that emphasize potential toxicity of amino acids: the first is upregulation of PTR2 in a population of cells, caused by amino acid secretion that accompanies peptide uptake; the second is loss of Ptr2p activity, due to transporter internalization following peptide uptake. Our findings emphasize the importance of proper amino acid balance in the cell and extend understanding of peptide import regulation in yeast.

The Cytoplasm-to-Vacuole Targeting Pathway: A Historical Perspective

From today's perspective, it is obvious that macroautophagy (hereafter autophagy) is an important pathway that is connected to a range of developmental and physiological processes. This viewpoint, however, is relatively recent, coinciding with the molecular identification of autophagy-related (Atg) components that function as the protein machinery that drives the dynamic membrane events of autophagy. It may be difficult, especially for scientists new to this area of research, to appreciate that the field of autophagy long existed as a “backwater” topic that attracted little interest or attention. Paralleling the development of the autophagy field was the identification and analysis of the cytoplasm-to-vacuole targeting (Cvt) pathway, the only characterized biosynthetic route that utilizes the Atg proteins. Here, we relate some of the initial history, including some never-before-revealed facts, of the analysis of the Cvt pathway and the convergence of those studies with autophagy.

The Cvt pathway as a model for selective autophagy

Autophagy is a highly conserved, ubiquitous process that is responsible for the degradation of cytosolic components in response to starvation. Autophagy is generally considered to be non-selective; however, there are selective types of autophagy that use receptor and adaptor proteins to specifically isolate a cargo. One type of selective autophagy in yeast is the cytoplasm to vacuole targeting (Cvt) pathway. The Cvt pathway is responsible for the delivery of the hydrolase aminopeptidase I to the vacuole; as such, it is the only known biosynthetic pathway that utilizes the core machinery of autophagy. Nonetheless, it serves as a model for the study of selective autophagy in other organisms.

Partial characterization of cheese-ripening proteinases produced by the yeastKluyveromyces lactis

An extract ofKluyveromyces lactis416 and a β-galactosidase preparation (Maxilact 40000) contaminated with proteinase, showed similar pH profiles of caseinolytic activity. Similar modes of casein hydrolysis (κ-, > αs-, ≥ β-) were observed at pH 5·0 (the pH of Cheddar cheese), without detection of bitterness. The contaminated Maxilact preparation contained similar proteinase types to those detected in an autolysate ofK. lactis. Both the autolysate and the Maxilact preparation contained acid endopeptidase (proteinase A), serine endopeptidase (proteinase B) and serine exopeptidase (carboxypeptidase Y) activities. Some aminopeptidase activity was also detected in both preparations. There were some differences in apparent molecular weight and charge properties between proteinase A and B and carboxypeptidase Y from the 2 proteinase sources.

Identification of yeast aspartyl aminopeptidase gene by purifying and characterizing its product from yeast cells

Aspartyl aminopeptidase (EC 3.4.11.21) cleaves only unblocked N-terminal acidic amino-acid residues. To date, it has been found only in mammals. We report here that aspartyl aminopeptidase activity is present in yeast. Yeast aminopeptidase is encoded by an uncharacterized gene in chromosome VIII (YHR113W, Saccharomyces Genome Database). Yeast aspartyl aminopeptidase preferentially cleaved the unblocked N-terminal acidic amino-acid residue of peptides; the optimum pH for this activity was within the neutral range. The metalloproteases inhibitors EDTA and 1.10-phenanthroline both inhibited the activity of the enzyme, whereas bestatin, an inhibitor of most aminopeptidases, did not affect enzyme activity. Gel filtration chromatography revealed that the molecular mass of the native form of yeast aspartyl aminopeptidase is approximately 680,000. SDS/PAGE of purified yeast aspartyl aminopeptidase produced a single 56-kDa band, indicating that this enzyme comprises 12 identical subunits.

Aminopeptidase yscCo-II: a new cobalt-dependent aminopeptidase from yeast-purification and biochemical characterization

Saccharomyces cerevisiae aminopeptidase yscCo-II (APCo-II) was purified to apparent homogeneity by gel filtration, affinity chromatography and anion-exchange chromatography. APCo-II is an hexameric cobalt-dependent metallo-enzyme with an estimated native molecular mass of 290 kDa. Enzyme activity is only detected in the presence of cobalt ions at pH 7.0. Substrate specificity studies indicate that aminopeptidase yscCo-II cleaves only basic N-terminal residues. PMSF, Cu(2+), 1,10-phenanthroline and bestatin were found to be very strong inhibitors of aminopeptidase yscCo-II activity. Kinetic studies indicated that the enzyme has a similar K(m) and Ka(Co )(activation constant of cobalt) and, following extraction of cobalt from the enzyme, activity was recovered only after cobalt addition.

The proteolytic system of the yeast Kluyveromyces lactis

Major proteolytic activities were characterized in the yeast K. lactis NRRL 1118, grown in chemostat cultures. This yeast expressed proteolytic activities similar to those found in S. cerevisiae. This fact was particularly evident in the case of proteases such as PrA, PrB and CpY with regard to substrate specificity, activation at pH 5. 0 and inhibition patterns. The presence of a CpS activity could not be detected in either fresh or activated cell-free extracts by using the dipeptide N-Cbz-Gly-Leu, even in the presence of Zn(+2). On the other hand, K. lactis exhibits at least two major intracellular Ap activities different from those reported in other yeasts, and these seem to be carried out by closely related proteins. These activities corresponded to molecular masses of about 60 kDa, close pI values, and a similar behaviour in non-denaturing polyacrylamide electrophoresis. Both activities were enhanced by Co(+2) and inhibited by EDTA. Among different aminoacyl-p-NAs, they preferentially hydrolysed Lys-p-NA. No increase of Ap activity was obtained by incubation of extracts at acid pH. The maximum PrA and PrB activities detected in N-limited cultures were six-fold higher than those expressed under C- or P-limitation. The effect of culture conditions on the Cp and Ap expression was much less pronounced in comparison with PrA and PrB activities, Ap levels even being slightly higher in C-limited cells. This fact suggests that hydrolysis of protein to peptides might be the limiting step in the pathway of general protein degradation in the vacuole.

Folding of the presequence of yeast pAPI into an amphipathic helix determines transport of the protein from the cytosol to the vacuole

To investigate the role of the 17 residues long presequence (p17) in the transport of the precursor of yeast API (pAPI) from the cytosol to the vacuole we have studied the effects of point mutations upon its conformation and on the process of transport. 1H NMR analysis of p17 indicates that in aqueous solution 26% of the molecules have the 4-12 segment folded into an helix. The hydrophobic environment provided by SDS micelles promotes the folding of 54% of the p17 molecules into a 5-16 amphipathic alpha-helix. Both Schiffer-Edmunson helical wheel analysis of segment 4-12 and residue hydrophobic moments calculated considering all possible side-chain orientations between 80 and 120 degrees, indicate the amphipathic character of the helixes assembled in water and detergent. Charge interactions between the dipole pairs N-Glu2Glu3 and C-Lys12Lys13 are essential for helix stability and condition pAPI transport. Substitution of either Pro2Pro3 or Lys2Lys3 for Glu2Glu3, results in moderate destabilization of the helix, decreases protein targeting to the vacuolar membrane and partly inhibits translocation of the protein to the vacuolar lumen. Replacement of either Pro12Pro13 or Glu12Glu13 for Lys12Lys13, causes a major disruption of the helix, decreases protein targeting and blocks completely the translocation of the protein to the vacuolar lumen. Replacement of Gly7 for Ile7, a substitution which is known to destabilize alpha-helixes in peptides and proteins as a result of the peptide bond to the solvent at Gly residues, produces similar effects as the substitutions for the K12K13 pair. The effects of Gly7 on helix stability and protein transport are partly reversed by introduction of Asp residues at positions 2 and 3 and Ala at position 4. Replacements such as Arg2 for Glu2, or Arg6 for Glu6, which change the net and local charges of the presequence without altering its conformation, have no effect on the protein transport. These results provide direct evidence of the involvement of the presequence in the transport of pAPI from the cytosol to the vacuole. They show that folding of the pAPI presequence is conditioned by the physical/chemical properties of the environment and is critical for targeting the protein to the vacuolar membrane and for its translocation to the vacuolar lumen.

Identification of a cytoplasm to vacuole targeting determinant in aminopeptidase I

Aminopeptidase I (API) is a soluble leucine aminopeptidase resident in the yeast vacuole (Frey, J., and K.H. Rohm. 1978. Biochim. Biophys. Acta. 527:31-41). The precursor form of API contains an amino-terminal 45-amino acid propeptide, which is removed by proteinase B (PrB) upon entry into the vacuole. The propeptide of API lacks a consensus signal sequence and it has been demonstrated that vacuolar localization of API is independent of the secretory pathway (Klionsky, D.J., R. Cueva, and D.S. Yaver. 1992. J. Cell Biol. 119:287-299). The predicted secondary structure for the API propeptide is composed of an amphipathic alpha-helix followed by a beta-turn and another alpha-helix, forming a helix-turn-helix structure. With the use of mutational analysis, we determined that the API propeptide is essential for proper transport into the vacuole. Deletion of the entire propeptide from the API molecule resulted in accumulation of a mature-sized protein in the cytosol. A more detailed examination using random mutagenesis and a series of smaller deletions throughout the propeptide revealed that API localization is severely affected by alterations within the predicted first alpha-helix. In vitro studies indicate that mutations in this predicted helix prevent productive binding interactions from taking place. In contrast, vacuolar import is relatively insensitive to alterations in the second predicted helix of the propeptide. Examination of API folding revealed that mutations that affect entry into the vacuole did not affect the structure of API. These data indicate that the API propeptide serves as a vacuolar targeting determinant at a critical step along the cytoplasm to vacuole targeting pathway.

Transcriptional regulation of the yeast vacuolar aminopeptidase yscI encoding gene (APE1) by carbon sources

Transcription of the vacuolar aminopeptidase yscI-encoding gene (APE1) is regulated by the carbon source used for yeast growth, responding to carbon catabolite repression. By Northern blot analyses, we determined the kinetics of glucose repression in growth-shift experiments. When added to induced cells, glucose leads to the disappearance of hybridizable aminopeptidase yscI RNA sequences within 30 min. However, the amount of inmunoreactive protein, once induced, is not affected by the addition of glucose. By deletion analysis of the fusion gene APE1-lacZ we have identified a number of strong regulatory regions in the APE1 promoter. Consensus sequences for the binding of yAP1 and the HAP2/HAP3/HAP4 complex are contained in those regions. Control of the APE1 gene expression is not mediated by the HXK2 regulatory gene, but a strain bearing a deletion in the CAT1 gene can not derepress APE1 transcription to wild-type levels.

Purification and characterization of aminopeptidase yspI from Schizosaccharomyces pombe

Aminopeptidase yspI was purified to apparent homogeneity from the fission yeast Schizosaccharomyces pombe. The molecular mass of the native enzyme was estimated to be 184 kDa by gel filtration chromatography. A value of 92 kDa was calculated after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The enzyme is thus a dimer with two identical subunits. Optimum pH for cleavage of synthetic aminoacyl-4-nitroanilides is 7.0. Mercury ions, EDTA and chloroquine were found to be potent inhibitors of aminopeptidase yspI activity. Substrate specificity studies indicate that the purified enzyme cleaves L-lysine-4-nitroanilide with high efficiency.

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.

Autophagy in yeast demonstrated with proteinase-deficient mutants and conditions for its induction

For determination of the physiological role and mechanism of vacuolar proteolysis in the yeast Saccharomyces cerevisiae, mutant cells lacking proteinase A, B, and carboxypeptidase Y were transferred from a nutrient medium to a synthetic medium devoid of various nutrients and morphological changes of their vacuoles were investigated. After incubation for 1 h in nutrient-deficient media, a few spherical bodies appeared in the vacuoles and moved actively by Brownian movement. These bodies gradually increased in number and after 3 h they filled the vacuoles almost completely. During their accumulation, the volume of the vacuolar compartment also increased. Electron microscopic examination showed that these bodies were surrounded by a unit membrane which appeared thinner than any other intracellular membrane. The contents of the bodies were morphologically indistinguishable from the cytosol; these bodies contained cytoplasmic ribosomes, RER, mitochondria, lipid granules and glycogen granules, and the density of the cytoplasmic ribosomes in the bodies was almost the same as that of ribosomes in the cytosol. The diameter of the bodies ranged from 400 to 900 nm. Vacuoles that had accumulated these bodies were prepared by a modification of the method of Ohsumi and Anraku (Ohsumi, Y., and Y. Anraku. 1981. J. Biol. Chem. 256:2079-2082). The isolated vacuoles contained ribosomes and showed latent activity of the cytosolic enzyme glucose-6-phosphate dehydrogenase. These results suggest that these bodies sequestered the cytosol in the vacuoles. We named these spherical bodies "autophagic bodies." Accumulation of autophagic bodies in the vacuoles was induced not only by nitrogen starvation, but also by depletion of nutrients such as carbon and single amino acids that caused cessation of the cell cycle. Genetic analysis revealed that the accumulation of autophagic bodies in the vacuoles was the result of lack of the PRB1 product proteinase B, and disruption of the PRB1 gene confirmed this result. In the presence of PMSF, wild-type cells accumulated autophagic bodies in the vacuoles under nutrient-deficient conditions in the same manner as did multiple protease-deficient mutants or cells with a disrupted PRB1 gene. As the autophagic bodies disappeared rapidly after removal of PMSF from cultures of normal cells, they must be an intermediate in the normal autophagic process. This is the first report that nutrient-deficient conditions induce extensive autophagic degradation of cytosolic components in the vacuoles of yeast cells.

Aminopeptidase I of Saccharomyces cerevisiae is localized to the vacuole independent of the secretory pathway

The Saccharomyces cerevisiae APE1 gene product, aminopeptidase I (API), is a soluble hydrolase that has been shown to be localized to the vacuole. API lacks a standard signal sequence and contains an unusual amino-terminal propeptide. We have examined the biosynthesis of API in order to elucidate the mechanism of its delivery to the vacuole. API is synthesized as an inactive precursor that is matured in a PEP4-dependent manner. The half-time for processing is approximately 45 min. The API precursor remains in the cytoplasm after synthesis and does not enter the secretory pathway. The precursor does not receive glycosyl modifications, and removal of its propeptide occurs in a sec-independent manner. Neither the precursor nor mature form of API are secreted into the extracellular fraction in vps mutants or upon overproduction, two additional characteristics of soluble vacuolar proteins that transit through the secretory pathway. Overproduction of API results in both an increase in the half-time of processing and the stable accumulation of precursor protein. These results suggest that API enters the vacuole by a posttranslational process not used by most previously studied resident vacuolar proteins and will be a useful model protein to analyze this alternative mechanism of vacuolar localization.

Molecular cloning of soluble aminopeptidases from Saccharomyces cerevisiae. Sequence analysis of aminopeptidase yscII, a putative zinc-metallopeptidase

Plasmids capable of complementing lap1, lap2 and lap3 mutations [R.J. Trumbly and G. Bradley (1983) J. Bacteriol. 156, 36-48] were isolated from a yeast YEp13 library by screening for activity against the chromogenic aminopeptidase substrate L-leucine beta-naphthylamide in intact yeast colonies. The genomic inserts were shown to contain the structural genes for aminopeptidases yscII, yscIII and yscIV. Plasmids containing the gene encoding aminopeptidase yscII of Saccharomyces cerevisiae, APE2 (LAP1) were analyzed in detail. APE2 was determined by DNA blot analysis to be a single-copy gene located on chromosome XI. The cloned fragment was used to identify a 2.7-kb mRNA. The cloned APE2 gene was sequenced and found to consist of an open reading frame of 2583 bp encoding a protein of 861 amino acids. The protein sequence contains two putative N-glycosylation sites. A significant amino acid similarity was detected between the APE2 gene product and members of the zinc-dependent metallopeptidase gene family. Chromosomal disruption of the APE2 gene completely abolishes the distinct activity band previously identified as aminopeptidase yscII [H.H. Hirsch, P. Suárez-Rendueles, T. Achstetter and D.H. Wolf (1988) Eur. J. Biochem. 173, 589-598] in crude extracts subjected to non-denaturing polyacrylamide gel electrophoresis and subsequent aminopeptidase activity staining. No vital consequence of aminopeptidase yscII absence on cell growth could be detected.

The fungal vacuole: composition, function, and biogenesis

The fungal vacuole is an extremely complex organelle that is involved in a wide variety of functions. The vacuole not only carries out degradative processes, the role most often ascribed to it, but also is the primary storage site for certain small molecules and biosynthetic precursors such as basic amino acids and polyphosphate, plays a role in osmoregulation, and is involved in the precise homeostatic regulation of cytosolic ion and basic amino acid concentration and intracellular pH. These many functions necessitate an intricate interaction between the vacuole and the rest of the cell; the vacuole is part of both the secretory and endocytic pathways and is also directly accessible from the cytosol. Because of the various roles and properties of the vacuole, it has been possible to isolate mutants which are defective in various vacuolar functions including the storage and uptake of metabolites, regulation of pH, sorting and processing of vacuolar proteins, and vacuole biogenesis. These mutants show a remarkable degree of genetic overlap, suggesting that these functions are not individual, discrete properties of the vacuole but, rather, are closely interrelated.

Yeast vacuolar aminopeptidase yscI. Isolation and regulation of the APE1 (LAP4) structural gene

The structural gene, APE1, (LAP4), for the vacuolar aminopeptidase I of Saccharomyces cerevisiae was cloned with the aid of a staining technique which permitted monitoring of aminopeptidase activity in yeast colonies. Genetic linkage data demonstrate that integrated copies of the cloned gene map to the APE1 locus. The nucleotide sequence of the cloned gene was determined. The open reading frame of APE1 consists of 514 codons and, therefore, encodes a larger protein (MW 57,003) than the reported mature aminopeptidase yscI (MW 44,800), suggesting that proteolytic processing must occur. A 1.75-kb mRNA, which is made in substantial amounts only when yeast cells have exhausted the glucose supply, was identified.

Ultracytochemical localization of the vacuolar marker enzymes alkaline phosphatase, adenosine triphosphatase, carboxypeptidase Y and aminopeptidase reveal new concept of vacuole biogenesis in Saccharomyces cerevisiae

Logarithmic cultures of Saccharomyces cerevisiae strains LBG H 1022, FL-100, X 2180 1A and 1B were studied together with the mutants pep4-3, sec18-1 and sec7-1. The necessary ultrastructural observations showed that, as a rule, juvenile vacuoles were formed de novo from perinuclear endoplasmic reticulum cisternae (ER) packed and inflated with electron-dense (polyanionic) matrix material. This process was disturbed solely in the sec18-1 mutant under non-permissive conditions. The vacuolar marker enzymes adenosine triphosphatase (ATPase) and alkaline phosphohydrolase (ALPase) were assayed by the ultracytochemical cerium precipitation technique. The neutral ATPase was active in vacuolar membranes and in the previously shown (coated) microglobules nearby. ALPase activity was detected in microglobules inside juvenile vacuoles, inside nucleus and in the cytoplasm as well as in the membrane vesicles and in the periplasm. The sites of vacuolar protease carboxypeptidase Y (CPY) activity were assayed using N-CBZ-L-tyrosine-4-methoxy-2-naphthyl-amide (CBZ-Tyr-MNA) as substrate and sites of the amino-peptidase M activity using Leu-MNA as substrate. Hexazotized p-rosaniline served as a coupler for the primary reaction product of both the above proteases (MNA) and the resulting azo-dye was osmicated during postfixation. The CPY reaction product was found in both polar layers of vacuolar membranes (homologous to ER) and in ER membranes enclosing condensed lipoprotein bodies which were taken up by the vacuoles of late logarithmic yeast. Both before and after the uptake into the vacuoles the bodies contained the CPY reaction product in concentric layers or in cavities. Microglobules with CPY activity were also observed. Aminopeptidase was localized in microglobules inside the juvenile vacuoles. These findings combined with the previous cytochemical localizations of polyphosphates and X-prolyl-dipeptidyl (amino)peptidase in S. cerevisiae suggest the following cytologic mechanism for the biosynthetic protein transport: coated microglobules convey metabolites and enzymes either to the cell surface for secretion or enter the vacuoles in all phases of the cell cycle. The membrane vesicles represent an alternative secretory mechanism present in yeast cells only during budding. The homology of the ER with the vacuolar membranes and with the surface membranes of the lipoprotein condensates (bodies) indicates a cotranslational entry of the CPY into these membranes. The secondary transfer of a portion of CPY into vacuoles is probably mediated by the lipoprotein uptake process.

Aminopeptidase yscII of yeast. Isolation of mutants and their biochemical and genetic analysis

Mutant strains of the yeast Saccharomyces cerevisiae defective in aminopeptidase yscII were isolated by screening for reduced external activity against the chromogenic substrate lysine beta-naphthylamide. One of the selected mutant strains analyzed in detail showed wild-type staining activity when tested at 23 degrees C but mutant activity after exposure to 37 degrees C, suggesting a temperature-sensitive mutation. Electrophoretic separation of mutant crude extracts on non-denaturing polyacrylamide gels and subsequent activity staining using lysine and leucine beta-naphthylamides as substrates revealed that in all strains isolated the same distinct activity band was affected, which corresponded to the aminopeptidase activity identified previously as aminopeptidase yscII [Achstetter, T., Ehmann, C. & Wolf, D. H. (1983) Arch. Biochem. Biophys. 226, 292-305]. All mutants strains isolated fell into the same complementation group. Tetrad dissection of sporulated diploids heterozygous for the wild-type and mutant allele resulted in a 2:2 segregation of mutant and wild-type phenotype indicating a single gene mutation. The characteristics of the mutations analyzed point to the gene which we called APE2 as the structural gene of aminopeptidase yscII. No vital consequences of aminopeptidase yscII deficiency on cell life and differentiation could be detected. However, the enzyme seems to be involved in the cellular supply of leucine from externally offered leucine-containing dipeptide substrates.

Variable region framework differences result in decreased or increased affinity of variant anti-digoxin antibodies

Rare spontaneous variants of the anti-digoxin antibody-producing hybridoma 40-150 (Ko = 5.4 x 10(9) M-1) were selected for altered antigen binding by two-color fluorescence-activated cell sorting. The parent antibody binds digoxin 890-fold greater than digitoxin. The variant 40-150 A2.4 has reduced affinity for digoxin (Ko = 9.2 x 10(6) M-1) and binds digoxin 33-fold greater than digitoxin. A second-order variant, derived from 40-150 A2.4 (designated 40-150 A2.4 P.10), demonstrated partial regain of digoxin binding (Ko = 4.4 x 10(8) M-1). The altered binding of the variant 40-150 A2.4 was accounted for by a point mutation resulting in substitution of arginine for serine at position 94 in the heavy chain variable region. Antibody 40-150 A2.4 P.10 also contains this arginine but owes its enhanced antigen binding to deletion of two amino acids from the heavy chain amino terminus. This unusual sequence alteration in an immunoglobulin framework region confers increased affinity for antigen.

Proteases of Melilotus alba mesophyll protoplasts : II. General properties and effectiveness in degradation of cytosolic and vacuolar enzymes

Proteases from mesophyll protoplasts of Melilotus alba were identified by standard proteolytic assays and separated using different chromatographic techniques. Their characterization also included their subcellular location. Besides the evidence for the multiplicity of the proteolytic enzymes, two protease sets were distinguished endopeptidases, which are exclusively vacuolar, and aminopeptidases, which are widely distributed throughout the cell. Cytosol-located enzymes were tested as substrates of the two sets of proteases, by studying comparatively the time-course changes of enzyme activities during incubation in total protoplast extracts, or in cytosol fractions devoid of vacuolar proteases. The degradation of phosphoenolpyruvate-carboxylase protein, a typical cytosolic enzyme, in the presence of purified amino-and endopeptidases, was also estimated by immunoprecipitation studies. Only the vacuolar endopeptidases are effective in the degradation of cytosolic enzymes. Hydrolytic enzyme activities mostly of vacuolar origin were very stable during incubation in total protoplast extracts. These proteins therefore appear to be particularly resistant to proteolytic attack. The results indicate that, in plants, the effective proteolytic system acting on cytosolic enzymes seems to be vacuole-located, and that the selectivity in protein degradation may be imposed by the susceptibility of the protein being degraded and by its transfer into the vacuoles.

Purification and properties of three intracellular proteinases from Candida albicans

Three intracellular proteinases termed A, B and C were purified to homogeneity from the unicellular form of the yeast Candida albicans. Enzyme A is an aspartic proteinase that acts on a variety of proteins. Its optimal pH is around 5 and it is displaced to 6.5 by KSCN. It is not significantly inhibited by PMSF, TLCK (Tos-Lys-CHCl2) or soybean trypsin inhibitor but it is inhibited by pepstatin. Its molecular weight is 60 000. Enzyme B is a dipeptidase that acts on esters or on dipeptides without blocks in either the carboxyl or amino ends. Its pH optimum is around 7.5 and the molecular weight is 57 000. It is inhibited by PMSF, TLCK and DANME (N2Ac-Nle-OMe). Proteinase C is an aminopeptidase with an optimum pH around 8. Its molecular weight was 67 000 when determined by SDS gel electrophoresis and 243 000 when determined by gel weight was 67 000 when determined by SDS gel electrophoresis and 243 000 when determined by gel filtration. It is active towards dipeptides in which at least one amino acid is apolar and is not active when the N-terminal amino acid is blocked. It is inhibited by EDTA or o-phenanthroline and activated by several divalent cations.

Physicochemical properties of proteinases from selected psychrotrophic bacteria

The physicochemical properties of eight extracellular proteinases secreted by psychrotrophic bacteria of dairy origin have been studied. Seven of these proteinases were able to withstand ultra heat treatment (UHT) with D values at 140 degrees C ranging from 2 to 300 s. The six Pseudomonas fluorescens proteinases were glycoproteins of mol. wt 47000-49500. The two Serratia marcescens proteinases, of mol. wt of 51000, did not contain carbohydrate but in other respects were similar to the Pseudomonas proteinases. The proteinases were inhibited by various metal chelators and all contained Ca and Zn in similar proportions. Their amino acid compositions were similar, with alanine as the N-terminal group, cysteine completely absent and very low levels of methionine. Isoelectric points ranged from 5.10 to 8.25. Their physical and chemical properties enabled them to be classified as alkaline metalloendopeptidases. A similarity index (S delta n) was used to predict sequence homology between ten proteinases of known amino acid composition. Comparisons of S delta n of these proteinases showed only minor sequence differences except for those of Ps. fluorescens MC60. Heat resistance could not be related wholly to similarities in protein sequence, but could be related both to the strength of stabilizing Ca2+-protein interactions and to the randomness inherent within the folding of the peptide chain.

Chloride as allosteric effector of yeast aminopeptidase I

Activation of yeast aminopeptidase I by chloride was studied by kinetic methods. Several effects contributed to overall activity enhancement: At low concentrations of Zn2+ (an essential component of aminopeptidase I) chloride increased the amounts of active enzyme by reducing the cooperativity of metal binding. In addition, substrate turnover was enhanced due to increased kcat and a moderate decrease of Km. At high concentrations of Zn2+ substrate saturation curves were sigmoidal. Under these conditions chloride activated by restoring Michaelis-Menten kinetics of substrate turnover. At the same time, reconstitution of active enzyme from apoprotein and Zn2+ was substantially accelerated and its inactivation due to loss of Zn2+ was retarded. Co2+-Substituted aminopeptidase I, although catalytically active, was much less sensitive to chloride activation. Apparent binding constants for chloride, as estimated from its effects on metal binding and catalysis, respectively, were different. This suggests that two independent activation mechanisms may be operative. Both appear to be mediated by conformational changes of the enzyme protein.

Metal binding to yeast aminopeptidase I

Binding of Zn(II) and Co(II) to homogeneous dodecameric aminopeptidase I from yeast was studied. Apparent binding constants were estimated from the dependence of enzyme activity on metal levels in solution as established by metal buffer systems. The binding curves were sigmoidal with Hill coefficients of 1.2-1.6, depending on the metal and on pH. Metal concentrations at half-saturation were 28 nM with Zn(II), and 390 nM with Co(II) at pH 7.0, they increased with decreasing pH. Equilibrium binding studies yielded binding stoichiometries of 0.5-0.6 mol metal/mol subunit for both Zn(II) and Co(II). However, after oxidation of Co(II)-substituted enzyme with H2O2 almost stoichiometric amounts of cobalt (greater than 0.9 mol/mol subunit) were found. The oxidized enzyme was inactive and did not exchange cobalt with the solvent. Native aminopeptidase I was also affected by H2O2, however only after prolonged incubation and at a much lower rate. Apoenzyme modified by ethoxyformic anhydride could not be reconstituted by Zn(II) or Co(II). On the other hand, either metal afforded full protection against ethoxyformic anhydride. This finding, and the pH dependence of stability constants suggest that histidine residues are involved in metal binding. Both the reconstitution of active enzyme from apoprotein and metal and its inactivation due to loss of metal are slow processes with half-times in the minute range. The rate of reconstitution did not depend on Zn(II) concentration. The rates of metal loss were not enhanced by chelating agents containing carboxylate functions. In contrast, chelators coordinating via nitrogen atoms and 2,3-dimercaptopropanol accelerated dissociation. A model is proposed that accounts for the substoichiometric metal contents of aminopeptidase I and for the slow time course of reconstitution. It is assumed that reconstitution involves a slow, monomolecular transition, leading to an active enzyme conformation with lower affinity for metal ions.

Vacuoles are not the sole compartments of proteolytic enzymes in yeast

Localization in vacuoles, the lysosome-like organelle of yeast, was checked for several newly detected proteolytic enzymes. While aminopeptidase Co and carboxypeptidase S were found in vacuoles, proteinase D and proteinase E as well as a variety of other proteolytic activities detectable with the aid of chromogenic peptide substrates do not reside in this cell compartment.

Synthesis and maturation of the yeast vacuolar enzymes carboxypeptidase Y and aminopeptidase I

We have studied the two vacuolar enzymes carboxypeptidase Y and aminopeptidase I from Saccharomyces cerevisiae with respect to biosynthesis, maturation and transfer from their site of synthesis into the organelle. The levels of translatable mRNA for these two proteins increase more than 10-fold at the end of the exponential growth period on glucose as carbon source and decrease again in the stationary phase. Two precursors of carboxypeptidase Y have been identified by in vivo pulse-labelling with [35S]methionine. These differ in their amount of carbohydrate as shown by inhibition of N-linked glycosylation with tunicamycin. The first is a protein with an apparent molecular weight of 67 kDa, which can be converted into the mature 60-kDa protein via an intermediate of 69 kDa. In the pep4-3 mutant, which is disturbed in the maturation of several vacuolar enzymes (Hemmings, B.A., Zubenko, G.S., Hasilik, A. and Jones, E.W. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 435-439), the 69-kDa precursor accumulates in the vacuole. This suggests that the final proteolytic cleavage of carboxypeptidase Y can occur in the vacuole.