Biochemical and genetic characterization of Yra1p in budding yeast

Yra1p and its vertebrate homologues bind to the mRNA export factor Mex67p/TAP and are thought to play a role in mRNA export in vivo. To further characterize Yra1p, we used immunoaffinity chromatography to purify endogenous Yra1p complexes. These experiments demonstrated that two importin beta homologues (Kap123p and Pse1p) and the poly A tail-binding proteins Pab1p and Nab2p associate with Yra1p. The other major proteins that associate with Yra1p include proteins involved in mRNA and rRNA processing and the Yra1p-related protein Yra2p. Additional biochemical and genetic experiments suggest a close functional relationship between Yra1p and Yra2p. We generated a temperature-sensitive allele of YRA1 and used it to demonstrate that cells which lack the function of both Yra1p and Yra2p are able to exit a G0 arrest and go through several rounds of cell division before arresting. We also identified high-copy suppressors of the yra1-2 temperature-sensitive growth defect. These include SUB2, a splicing factor important in mRNA export, ULP1, a nuclear cysteine protease localized to the nuclear pore and involved in Smt3p/SUMO processing, and YRA2. Taken together, these results suggest that Yra1p has roles in diverse RNA processing events in addition to a role in mRNA export.     

Identification of ACT4, a novel essential actin-related gene in the yeast Saccharomyces cerevisiae

Actin molecules are major cytoskeleton components of all eukaryotic cells. All conventional actins that have been identified so far are 374–376 amino acids in size and exhibit at least 70% amino acid sequence identity when compared with one another. In the yeast Saccharomyces cerevisiae, one conventional actin gene ACT1 and three so-called actin-related genes, ACT2, ACT3 and ACT5, have been identified. We report here the discovery of a new actin-related gene in this organism, which we have named ACT4. The deduced protein, Act4, of 449 amino acids, exhibits only 33·4%, 26·7%, 23·4% and 29·2% identity to Act1, Act2, Act3 and Act5, respectively. In contrast, it is 68·4% identical to the product of the Schizosaccharomyces pombe Act2 gene and has a similar level of identity to other Sch. pombe Act2 homologues. This places Act4 in the Arp3 family of actin-related proteins. ACT4 gene disruption and tetrad analysis demonstrate that this gene is essential for the vegetative growth of yeast cells. The act4 mutants exhibit heterogenous morphological phenotypes. We hypothesize that Act4 may have multiple roles in the cell cycle. The sequence has been deposited in the Genome Sequence Data Base under Accession Number L37111.     

Heat shock transiently enhances the synthesis rate of Sis1p,a ribosome-associated DnaJ protein in the oleagenous yeast Apiotrichum curvatum

DnaJ proteins have been localized in different intracellular compartments of eukaryotes. In Apiotrichum curvatum, a fat-storing yeast, we found a DnaJ homolog associated with ribosomes and large cytosolic complexes as well. Using a plant DnaJ probe and a cDNA library constructed from poly(A)⁺ -RNA of A. curvatum grown on oleate we isolated a SIS1 cDNA coding for a 39·5 kDa protein. The putative protein contains neither a zinc finger motif nor a CAAX motif but is characterized by a J-domain at the N-terminal region and a large G-rich region in the middle part of the molecule. Heat shock applied for 1 h resulted in a pronounced but transient increase of the SIS1 mRNA. An antiserum was raised against the bacterially expressed protein. Cell fractions from A. curvatum were further separated by sedimentation centrifugation on sucrose gradients. Analysing the sub-fractions, we detected Sis1p mainly associated with ribosomes, and with particles sedimenting at approximately 200S. Hsp70 was found to be associated with the 200S fraction. The respective cytosolic A. curvatum Hsp70 cDNA was cloned and sequenced. High salt conditions caused the removal of Hsp70 and Sis1p from the 200S complexes. Mild RNase treatment of the 200S fraction afforded monosomes and 200S complexes unaffected by RNase. Heat shock led to a pronounced increase in the rate of de novo synthesis. However, due to the large pools of Sis1p on ribosomes and large cytosolic complexes, the increase in gene activation did not lead to a significant change of the total amount of Sis1p. Accession numbers are: Y12079 for ACHSP70 and Y12080 for ACSIS1. © 1998 John Wiley & Sons, Ltd.     

Identification of a putative histidine kinase two-component phosphorelay gene (CaHK1) in Candida albicans

We have cloned and analysed the sequence of a putative histidine kinase, two-component gene (CaHK1) from Candida albicans. This gene encodes a 2471 amino acid protein (Cahk1p) with an estimated molecular mass of 281·8 kDa. A homology search of Cahk1p with other proteins in the databases showed that Cahk1p exhibits the greatest homology at its C-terminus with both the sensor and regulator components of prokaryotic and eukaryotic two-component histidine kinases. A further analysis of this homology showed that the Cahk1p possessed both sensor and regulator domains in the same polypeptide. Also, Cahk1p is likely to be a soluble protein. The sensor kinase domain of Cahk1p contains conserved motifs that are characteristic of all histidine kinase proteins, including the putative histidine which is believed to be autophosphorylated during activation, ATP binding motifs and others (F- and N-motifs), with unknown function. The Cahk1p regulator domain also contains conserved aspartate and lysine residues and the putative aspartate, which is secondarily phosphorylated by the autophosphorylated histidine. Finally, according to the codon usage frequency of the CaHK1 gene in comparison with other genes from C. albicans, there would appear to be a low level of expression of the gene. The accession number for the described sequence is AF013273, as filed in the EMBL/GenBank/DDBJ database. © 1998 John Wiley & Sons, Ltd.     

Effect of site-directed mutagenesis of conserved lysine residues upon Pas1 protein function in peroxisome biogenesis

The Pas1 protein (Pas1p) is required for peroxisome biogenesis in Saccharomyces cerevisiae and contains two putative ATP-binding sites, each within a domain which is conserved among members of the recently characterized AAA-family. To elucidate whether both putative ATP-binding sites are essential for Pas1p function, lysine⁴⁶⁷ of the first and lysine⁷⁴⁴ of the second putative ATP-binding site were each changed to glutamate by site-directed mutagenesis. While replacement of lysine⁷⁴⁴ abolished the function of the Pas1 protein in peroxisome biogenesis, replacement of lysine⁴⁶⁷ had no obvious effect.     

Characterization of mouse spermatogonia by transmission electron microscopy

Characteristics of the various type A, intermediate (In) and B spermatogonia were determined in C57BL/6J mice using transmission electron microscopy. Spermatogonia were photographed at all stages of the cycle of the seminiferous epithelium. Over 450 images were taken. Spermatogonia could be classified into As, Apr, Aal, A1 cells, A2 cells, A3 cells, A4 cells, intermediate type and type B cells primarily on the basis of nuclear and nucleolar characteristics. The most primitive spermatogonia (As, Apr, Aal) had mottled chromatin; A1 cells contained homogeneously finely granular chromatin throughout the nucleus; A2, A3, A4 and intermediate type spermatogonia had progressively increasing amounts of chromatin encrusting the nuclear envelope; type B spermatogonia had less heterochromatin along the nuclear envelope, although the particles were more dense and rounded than in intermediate type spermatogonia. Mitochondrial size and position of Golgi complexes varied in different types of spermatogonia. These data show that types of spermatogonia can be differentiated such that these characteristics can be used in functional studies.     

Overexpressed yeast mitochondrial putative RNA helicase Mss116 partially restores proper mtRNA metabolism in strains lacking the Suv3 mtRNA helicase

RNA helicase, encoded by the Saccharomyces cerevisiae nuclear gene SUV3, is a subunit of the mitochondrial (mt) degradosome: an enzyme complex that takes part in turnover of mtRNAs. Deletion of the SUV3 gene leads to a variety of disturbances in mtRNA metabolism and results in respiratory incompetence of yeast cells. Here we show that the nuclear gene MSS116, which codes for a mitochondrial putative RNA helicase necessary for splicing of several mt introns, can suppress the lack of the SUV3 gene. Overexpression of the Mss116 putative helicase from a multicopy plasmid present in the SUV3-deleted strains partially restores respiratory competence, brings the steady-state levels of COB and ATP6/8 mRNA back almost to normal and lowers the accumulation of 21S rRNA and ATP6/8 RNA precursors to the wild-type levels. To the best of our knowledge, this is the first reported case of a substitution of one RNA helicase by another, belonging to a different class of RNA helicases.     

Schizosaccharomyces pombe Arc3 is a conserved subunit of the Arp2/3 complex required for polarity, actin organization, and endocytosis

We characterized the Schizosaccharomyces pombe arc3 gene, whose product shares sequence homology with that of the budding yeast ARC18 and human ARPC3/p21 subunits of the Arp2/3 complex. Our data showed that Arc3p co-localizes with F-actin patches at the cell ends, but not with F-actin cables or the equatorial actin ring, and binds other subunits of the Arp2/3 complex. Gene deletion analysis showed that arc3 is essential for viability. When arc3 expression was repressed, F-actin patches became dispersed throughout the cell with greatly reduced mobility. Furthermore, in arc3-repressed cells, endocytosis was also inhibited. Human ARPC3 rescued the viability of the Sz. pombe arc3 null mutant; in addition, ARPC3 also localized to F-actin patches in human cells. These data suggest that Arc3p is an evolutionarily conserved subunit of the Arp2/3 complex required for proper F-actin organization and efficient endocytosis.     

Formation and characterization of noncovalent ternary complexes based on whey protein concentrate,high methoxyl pectin,and phenolic acid

Protein-polysaccharide-polyphenol noncovalent ternary complexes possess unique physicochemical, structural, and functional properties. In the present study, ternary complexes based on whey protein concentrate (WPC; 2%, wt/vol) and high methoxyl pectin (HMP; 0.5%, wt/vol) complexes and 0.2 to 0.6% (wt/vol) chlorogenic acid (CA) or rosmarinic acid (RA) were formed and characterized at 3 pH values (4, 4.5, and 5). The pH conditions were decided according to phase diagram of WPC and HMP during acidification. Fluorescence quenching experiments indicated that WPC-HMP complexes bound RA stronger than CA and the binding constant increased with increasing pH for both phenolic acids. Particle size of ternary complexes decreased and absolute ζ-potential increased with pH values changing from 4 to 5, and RA influenced the particle size of WPC-HMP complexes greater than CA. The CA and RA in ternary complexes showed good stability against UV light with pH order of pH 5 > pH 4.5 > pH 4. Fourier-transform infrared spectroscopy spectra indicated the involvement of hydrogen bonding between WPC-HMP and CA or RA. Antibacterial tests showed that ternary complexes had good antibacterial activity against Staphylococcus aureus and Escherichia coli at concentrations of 6.2 mg/mL and the ability increased with decreasing pH values. All ternary complexes possessed strong scavenging radical capacities with median inhibitory concentration (IC₅₀) values ranging from 2.71 ± 0.05 to 6.20 ± 0.41 μg/mL. Antioxidative ability of ternary complexes increased as pH went up and WPC-HMP-RA showed significantly higher antioxidative property compared with WPC-HMP-CA. Data may provide useful information for rational design of ternary complexes and applications of the formed complexes in food matrices such as beverages and emulsions.     

Specific negative effects resulting from elevated levels of the recombinational repair protein Rad54p in Saccharomyces cerevisiae

RAD54 is an important gene in the RAD52 group that controls recombinational repair of DNA damage in Saccharomyces cerevisiae. Rad54p is a DNA‐dependent ATPase and shares seven conserved sequence motifs with proteins of the Swi2p/Snf2p family. Genetic analysis of mutations in motif IA, the putative ATP‐binding fold of Rad54p, demonstrated the functional importance of this motif. Overexpression of these mutant proteins resulted in strong, dominant‐negative effects on cell survival. High levels of full‐length wild‐type Rad54p or specific parts of Rad54p also resulted in negative effects, dependent on the ploidy of the host cell. This differential effect was not under a /α mating‐type control. Deletion of the RAD54 gene led to a small but significant increase in the mutation rate. However, the negative overexpression effects in haploid cells could not be explained by an accumulation of (recessive) lethal mutations. All negative overexpression effects were found to be enhanced under genotoxic stress. We suggest that the negative overexpression effects are the result of unbalanced protein–protein interactions, indicating that Rad54p is involved in multiple interactions, dependent on the physiological situation. Diploid wild‐type cells contained an estimated 7000 Rad54p molecules/cell, whereas haploid cells about 3500/cell. Rad54p levels were highest in actively growing cells compared to stationary phase cells. Rad54 protein levels were found to be elevated after DNA damage. Copyright © 1999 John Wiley & Sons, Ltd.     

ABC transporters Cdr1p, Cdr2p and Cdr3p of a human pathogen Candida albicans are general phospholipid translocators

We have used fluorescent 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD)-tagged phospholipid analogues, NBD-PE (phosphatidylethanolamine), NBD-PC (phosphatidylcholine) and NBD-PS (phosphatidylserine), to demonstrate that Cdr1p and its other homologues, Cdr2p and Cdr3p, belonging to the ATP-binding cassette (ABC) superfamily behave as general phospholipid translocators. Interestingly, CDR1 and CDR2, whose overexpression leads to azole resistance in C. albicans, elicit in-to-out transbilayer phospholipid movement, while CDR3, which is not involved in drug resistance, carries out-to-in translocation of phospholipids between the two monolayers of plasma membrane. Cdr1p, Cdr2p and Cdr3p could be further distinguished on the basis of their sensitivities to different inhibitors. For example, the in-to-out activity associated with Cdr1p and Cdr2p is energy-dependent and sensitive to sulphydryl blocking agents such as N-ethylmaleimide (NEM) and cytoskeleton disrupting agent cytochalasin E, while Cdr3p-associated out-to-in activity is energy-dependent but insensitive to NEM and cytochalasin E. We found that certain drugs, such as fluconazole, cycloheximide and miconazole, to which Cdr1p confers resistance could also affect in-to-out transbilayer movement of NBD-PE, while the same drugs had no effect on Cdr3p-mediated out-to-in translocation of NBD-PE. The ineffectiveness of these drugs to affect Cdr3p mediated out-to-in phospholipid translocation further confirms the inherent difference in the directionality of phospholipid translocation between these pumps. Notwithstanding the role of some of the Cdrps in drug resistance, this study clearly demonstrates that these ABC transporters of C. albicans are phospholipid translocators and this function could represent one of the physiological functions of such large family of proteins.     

Emodin,a natural inhibitor of protein kinase CK2, suppresses growth,hyphal development,and biofilm formation of Candida albicans

Emodin (1,3,8‐trihydroxy‐6‐methyl‐anthraquinone) is a natural secondary plant product, originally isolated from the rhizomes of Rheum palmatum. Many reports show its diuretic, vasorelaxant, antibacterial, antiviral, anti‐ulcerogenic, immunosuppressive, hepatoprotective, anti‐inflammatory and anticancer potential. Emodin is a pleiotropic molecule capable of interacting with several major molecular targets, e.g. NF‐κB, AKT/mTOR and STAT3. The compound can also act as an inhibitor of some protein kinases, with special affinity to protein kinase CK2. The aim of the presented report was to evaluate antifungal properties of emodin and its activity towards CK2 isolated from Candida cells. Our studies revealed that the compound suppressed growth of the cells of reference strains as well as clinical Candida strains, with minimal inhibitory concentration and minimal fungicidal concentration values between 12.5 and 200 μg/mL. Moreover, at a low concentration, the compound was able to effectively stop hyphal formation, thus showing a distinct antivirulent potential. Interestingly, we showed that emodin added to Candida culture inhibited the phosphorylation of many cellular proteins, presumably owing to the inhibition of protein kinase CK2. Notably, the enzyme isolated from the Candida cells was susceptible to emodin with IC₅₀ of 2.8 μg/mL. Indeed, our computational modelling revealed that emodin was able to occupy the ATP‐binding pocket of CK2. Copyright © 2017 John Wiley & Sons, Ltd.     

A network of proteins around Rvs167p and Rvs161p, two proteins related to the yeast actin cytoskeleton

The Rvs161p and Rvs167p proteins of Saccharomyces cerevisiae, homologues of higher eukaryotes' amphiphysins, associate with actin and appear to be involved in several functions related to the actin cytoskeleton. In order to identify partners of the Rvsp proteins, yeast libraries constructed in two-hybrid vectors were screened using either Rvs167p or Rvs161p as a bait. The selected candidates, representing 34 ORFs, were then tested against both Rvsp proteins, as well as domains of Rvs167p or Rvs161p. Among the most significant ones, 24 ORFs were specific preys of Rvs167p only and two gave interactions with Rvs161p only. Interestingly, five ORFs were preys of both Rvs161p and Rvs167p (RVS167, LAS17, YNL094w, YMR192w and YPL249c). Analysis of putative functions of the candidates confirm involvement of the Rvsp in endocytosis/vesicle traffic, but also opens possible new fields, such as nuclear functions.     

Physiological effects of unassembled chaperonin Cct subunits in the yeast Saccharomyces cerevisiae

Eukaryotic chaperonins, the Cct complexes, are assembled into two rings, each of which is composed of a stoichiometric array of eight different subunits, which are denoted Cct1p-Cct8p. Overexpression of a single CCT gene in Saccharomyces cerevisiae causes an increase of the corresponding Cct subunit, but not of the Cct complex. Nevertheless, overexpression of certain Cct subunits, especially CCT6, suppresses a wide range of abnormal phenotypes, including those caused by the diverse types of conditional mutations tor2-21, lst8-2 and rsp5-9 and those caused by the concomitant overexpression of Sit4p and Sap155p. The examination of 73 altered forms of Cct6p revealed that the cct6-24 mutation, containing GDGTT --> AAAAA replacements of the conserved ATP-binding motif, was unable to suppress any of these traits, although the cct6-24 allele was completely functional for growth. These results provide evidence for functional differences among Cct subunits and for physiological properties of unassembled subunits. We suggest that the suppression is due to the competition of specific Cct subunits for activities that normally modify various cellular components. Furthermore, we also suggest that the Cct subunits can act as suppressors only in certain states, such as when associated with ATP.     

Saccharomyces cerevisiae Atf1p is an alcohol acetyltransferase and a thioesterase in vitro

The alcohol‐O‐acyltransferases are bisubstrate enzymes that catalyse the transfer of acyl chains from an acyl‐coenzyme A (CoA) donor to an acceptor alcohol. In the industrial yeast Saccharomyces cerevisiae this reaction produces acyl esters that are an important influence on the flavour of fermented beverages and foods. There is also a growing interest in using acyltransferases to produce bulk quantities of acyl esters in engineered microbial cell factories. However, the structure and function of the alcohol‐O‐acyltransferases remain only partly understood. Here, we recombinantly express, purify and characterize Atf1p, the major alcohol acetyltransferase from S. cerevisiae. We find that Atf1p is promiscuous with regard to the alcohol cosubstrate but that the acyltransfer activity is specific for acetyl‐CoA. Additionally, we find that Atf1p is an efficient thioesterase in vitro with specificity towards medium‐chain‐length acyl‐CoAs. Unexpectedly, we also find that mutating the supposed catalytic histidine (H191) within the conserved HXXXDG active site motif only moderately reduces the thioesterase activity of Atf1p. Our results imply a role for Atf1p in CoA homeostasis and suggest that engineering Atf1p to reduce the thioesterase activity could improve product yields of acetate esters from cellular factories. © 2017 The Authors. Yeast published by John Wiley & Sons, Ltd.