Rapid indexing of the sunblotch disease of avocados using a complementary DNA probe to avocado sunblotch viroid

A routine procedure has been established for the sensitive and specific detection of avocado sunblotch viroid in partially purified nucleic acid extracts of avocado leaves by hybridisation analysis with ³²P-complementary DNA prepared against the purified viroid. Avocado sunblotch viroid was shown to be present in 12 avocado trees that had indexed positive in a biological test for sunblotch disease but was absent from 10 trees that indexed negative. The complete correlation between sunblotch disease and the presence of viroid indicates that the complementary DNA hybridisation assay procedure can be used for the indexing of sunblotch disease. The overall procedure of leaf extraction and hybridisation analysis can be completed in 5 days and is to be compared with up to 2 yr required for indexing by biological methods. The level of avocado sunblotch viroid in partially purified nucleic acid extracts of a number of different sources of sunblotch infected avocado leaves was found to vary 10 000-fold from 0.2% to 2 × 10^-5% by weight. The lower limit of detectability of the viroid by the hybridisation assay is considered to be about 10^-5% by weight; this is at least 10³ times more sensitive than the detection of the viroid by polyacrylamide gel electrophoresis of the leaf nucleic acid extracts followed by staining.     

In situ hybridization localizes avocado sunblotch viroid on chloroplast thylakoid membranes and coconut cadang cadang viroid in the nucleus

Viroids, small single-stranded circular RNA molecules, are the smallest known infectious agents in Nature. The apparent inability of viroids to encode for proteins means that they must rely fully on host functions for their replication. The specific ultrastructural localization of viroids is fundamental to the determination of their replication strategies. In this paper the first in situ hybridization study to localize viroids within the cell at the electron microscope level is reported. Biotin-labelled RNA probes were used with subsequent detection by gold-labelled monoclonal anti-biotin antibodies to localize avocado sunblotch viroid and coconut cadang cadang viroid. Avocado sunblotch viroid was located in chloroplasts, mostly on the thylakoid membranes of cells from infected leaves of avocado (Persea americana). In contrast, coconut cadang cadang viroid was located in the nucleolus and nucleoplasm of cells of infected leaves of oil palm (Elaeis guineensis), with a higher concentration in the nucleolus. The results provide insight on the potential host RNA polymerases involved in the replication of these two viroids.     

Iron-reductases in the yeast Saccharomyces cerevisiae

Several NAD(P)H-dependent ferri-reductase activities were detected in sub-cellular extracts of the yeast Saccharomyces cerevisiae. Some were induced in cells grown under iron-deficient conditions. At least two cytosolic iron-reducing enzymes having different substrate specificities could contribute to iron assimilation in vivo. One enzyme was purified to homogeneity: it is a flavoprotein (FAD) of 40 kDa that uses NADPH as electron donor and Fe(III)-EDTA as artificial electron acceptor. Isolated mitochondria reduced a variety of ferric chelates, probably via an 'external' NADH dehydrogenase, but not the siderophore ferrioxamine B. A plasma membrane-bound ferri-reductase system functioning with NADPH as electron donor and FMN as prosthetic group was purified 100-fold from isolated plasma membranes. This system may be involved in the reductive uptake of iron in vivo.     

Detection of avocado sunblotch viroid (ASBV) by dot-spot self-hybridization with a [32P]-labelled ASBV-RNA

RNA was extracted from plants infected with avocado sunblotch viroid (ASBV) and was analyzed by electrophoresis in polyacrylamide gel. The ASBV related fraction was eluted from the gel, labelled with [³²P] using polynucleotide kinase and used as a probe for hybridization with a purified ASBV-RNA preparation dot spotted on nitrocellulose paper. Positive self-hybridization indicated a high degree of internal complementarity. Dot spots of whole cell RNA and of leaf sap from ASBV infected plants were shown to hybridize with the labelled probe. This hybridization procedure proved to be 16–64 times more sensitive in diagnosing ASBV when compared with polyacrylamide gel analysis.     

Replication of single-stranded DNA templates by primase-polymerase complexes of the yeast, Saccharomyces cerevisiae.

A partially purified primase-polymerase complex from the yeast, Saccharomyces cerevisiae, was capable of replicating a single stranded circular phage DNA into a replicative form with high efficiency. The primase-polymerase complex exhibited primase activity and polymerase activity on singly primed circular ssDNA as well as on gapped DNA. In addition, it was able to replicate an unprimed, single-stranded, circular phage DNA through a coupled primase-polymerase action. On Biogel A-O.5m filtration the primase-polymerase activities appeared in the void volume, demonstrating a mass of greater than 500 kilodaltons. Primase and various primase-polymerase complexes synthesized unique primers on single stranded DNA templates and the size distribution of primers was dependent on the structure of the DNA and the nature of the primase-polymerase assembly.     

Replication in Saccharomyces cerevisiae of plasmid pBR313 carrying DNA from the yeast trpl region.

Plasmid pBR313 carrying a 1.4 kb EcoRI fragment from the yeast TRP1 region (designated pLC544) is capable of transforming yeast trp1 mutants to Trp+ at high frequency (10(3)--10(4) transformants/micrograms DNA). Transformation can be achieved either by using purified plasmid DNA or by fusion of yeast spheroplasts with partially lysed Escherichia coli [pLC544] protoplast preparations. The Trp+ yeast transformants are highly unstable, segregating Trp- cells at frequencies of 0.18 per cell per generation (haploids) and 0.056 per cell per generation (diploids) in media containing tryptophan. Plasmid pLC544 replicates autonomously in the nucleus of yeast cells and segregation of Trp-cells is associated with the complete loss of plasmid sequences. In genetic crosses, pLC544 is randomly assorted during meiosis and is carried unchanged through the mating process into haploid recombinants.     

Exopolyphosphatases of the yeast Saccharomyces cerevisiae

Separate compartments of the yeast cell possess their own exopolyphosphatases differing from each other in their properties and dependence on culture conditions. The low-molecular-mass exopolyphosphatases of the cytosol, cell envelope, and mitochondrial matrix are encoded by the PPX1 gene, while the high-molecular-mass exopolyphosphatase of the cytosol and those of the vacuoles, mitochondrial membranes, and nuclei are presumably encoded by their own genes. Based on recent works, a preliminary classification of the yeast exopolyphosphatases is proposed.     

Damage-induced recombination in the yeast Saccharomyces cerevisiae

Prokaryotic and eukaryotic cells have developed a network of DNA repair systems that restore genomic integrity following DNA damage from endogenous and exogenous genotoxic sources. One of the mechanisms used to repair damaged chromosomes is genetic recombination, in which information present as a second chromosomal copy is used to repair a damaged region of the genome. In this review, I summarized what is known about the molecular and cellular mechanisms by which various DNA-damaging agents induce recombination in yeast. The yeast Saccharomyces cerevisiae has served as an excellent model organism to study the induction of recombination. It has helped to define the basic phenomenology and to isolate the genes involved in the process. Given the evolutionary conservation of the various DNA repair systems in eukaryotes, it is likely that the knowledge gathered about induced recombination in yeast is applicable to mammalian cells and thus to humans. Many carcinogens are known to induce recombination and to cause chromosomal rearrangements. An understanding of the mechanisms, by which genotoxic agents cause increased levels of recombination will have important consequences for the treatment of cancer, and for the assessment of risks arising from exposure to genotoxic agents in humans.     

Sporulation in the budding yeast Saccharomyces cerevisiae

In response to nitrogen starvation in the presence of a poor carbon source, diploid cells of the yeast Saccharomyces cerevisiae undergo meiosis and package the haploid nuclei produced in meiosis into spores. The formation of spores requires an unusual cell division event in which daughter cells are formed within the cytoplasm of the mother cell. This process involves the de novo generation of two different cellular structures: novel membrane compartments within the cell cytoplasm that give rise to the spore plasma membrane and an extensive spore wall that protects the spore from environmental insults. This article summarizes what is known about the molecular mechanisms controlling spore assembly with particular attention to how constitutive cellular functions are modified to create novel behaviors during this developmental process. Key regulatory points on the sporulation pathway are also discussed as well as the possible role of sporulation in the natural ecology of S. cerevisiae.     

Aquaporins in Saccharomyces cerevisiae wine yeast

AQY1 and AQY2 were sequenced from five commercial and five native wine yeasts. Of these, two AQY1 alleles from UCD 522 and UCD 932 were identified that encoded three or four amino-acid changes, respectively, compared with the Sigma1278b sequence. Oocytes expressing these AQY1 alleles individually exhibited increased water permeability vs. water-injected oocytes, whereas oocytes expressing the AQY2 allele from UCD 932 did not show an increase, as expected, owing to an 11 bp deletion. Wine strains lacking Aqy1p did not show a decrease in spore fitness or enological aptitude under stressful conditions, limited nitrogen, or increased temperature. The exact role of aquaporins in wine yeasts remains unclear.     

Meiotic karyotype of the yeast Saccharomyces cerevisiae

A cytogenetic study of the meiotic chromosomes of the budding yeast Saccharomyces cerevisiae was undertaken by high resolution epifluorescence microscopy. Condensation of chromatin into separate chromosomes takes place during prophase I. At metaphase I, there are 16 separate and distinct bivalents which are roughly classified into three groups by morphological differences and DNA content.     

Atg9 trafficking in the yeast Saccharomyces cerevisiae

Autophagy can be divided into selective and nonselective modes. This process is considered selective when a precise cargo is specifically and exclusively incorporated into autophagosomes, the double-membrane vesicles that are the hallmark of autophagy. In contrast, during nonselective, bulk autophagy, cytoplasmic components are randomly enwrapped into autophagosomes. To date, approximately 30 autophagy-related genes called ATG have been identified. Sixteen of them compose the general basic machinery catalyzing the formation of double-membrane vesicles in all eukaryotic cells. The rest of them are often not conserved between species and cooperate with the basic Atg proteins during either selective or nonselective autophagy. Atg9 is the only integral membrane component of the conserved Atg machinery and appears to be a crucial organizational element. Recent studies in the S. cerevisiae have shown that Atg9 transport is differentially regulated depending on the autophagy mode. In this addendum, we will review and discuss what has recently been unveiled about yeast S. cerevisiae Atg9 trafficking, its modulators and its potential role in double-membrane vesicle biogenesis.     

cAMP-dependent phosphoprotein changes in the yeast Saccharomyces cerevisiae

Abstract cAMP-dependent phosphoprotein changes were determined using 1-dimensional SDS-gel electrophoresis in a cAMP-requiring yeast mutant ( Saccharomyces cerevisiae AM18). During cAMP starvation, the yeast cells accumulated 3 ³²P-labeled bands with M _r/ 72000, 54000, and 37000. The M _r/ 72000 protein was the most prominent phosphorylated protein. After the readdition of cAMP, these phosphoproteins lost their ³²P-label while phosphoproteins with M _r/ 76000, 65000, 56000 and 30000 were accumulated. Similar phosphoprotein changes were also detected in cdc35 at the nonpermissive temperature, but not in wildtype (A363A) or cdc7 strains of S. cerevisiae .     

Lipid droplet autophagy in the yeast Saccharomyces cerevisiae

Cytosolic lipid droplets (LDs) are ubiquitous organelles in prokaryotes and eukaryotes that play a key role in cellular and organismal lipid homeostasis. Triacylglycerols (TAGs) and steryl esters, which are stored in LDs, are typically mobilized in growing cells or upon hormonal stimulation by LD-associated lipases and steryl ester hydrolases. Here we show that in the yeast Saccharomyces cerevisiae, LDs can also be turned over in vacuoles/lysosomes by a process that morphologically resembles microautophagy. A distinct set of proteins involved in LD autophagy is identified, which includes the core autophagic machinery but not Atg11 or Atg20. Thus LD autophagy is distinct from endoplasmic reticulum–autophagy, pexophagy, or mitophagy, despite the close association between these organelles. Atg15 is responsible for TAG breakdown in vacuoles and is required to support growth when de novo fatty acid synthesis is compromised. Furthermore, none of the core autophagy proteins, including Atg1 and Atg8, is required for LD formation in yeast.     

Stationary phase in the yeast Saccharomyces cerevisiae.

Growth and proliferation of microorganisms such as the yeast Saccharomyces cerevisiae are controlled in part by the availability of nutrients. When proliferating yeast cells exhaust available nutrients, they enter a stationary phase characterized by cell cycle arrest and specific physiological, biochemical, and morphological changes. These changes include thickening of the cell wall, accumulation of reserve carbohydrates, and acquisition of thermotolerance. Recent characterization of mutant cells that are conditionally defective only for the resumption of proliferation from stationary phase provides evidence that stationary phase is a unique developmental state. Strains with mutations affecting entry into and survival during stationary phase have also been isolated, and the mutations have been shown to affect at least seven different cellular processes: (i) signal transduction, (ii) protein synthesis, (iii) protein N-terminal acetylation, (iv) protein turnover, (v) protein secretion, (vi) membrane biosynthesis, and (vii) cell polarity. The exact nature of the relationship between these processes and survival during stationary phase remains to be elucidated. We propose that cell cycle arrest coordinated with the ability to remain viable in the absence of additional nutrients provides a good operational definition of starvation-induced stationary phase.