Breck Byers

Phenotypic Instability and Rapid Gene Silencing in Newly Formed Arabidopsis Allotetraploids

Allopolyploid hybridization serves as a major pathway for plant evolution, but in its early stages it is associated with phenotypic and genomic instabilities that are poorly understood. We have investigated allopolyploidization between Arabidopsis thaliana (2n = 2x = 10; n, gametic chromosome number; x, haploid chromosome number) and Cardaminopsis arenosa (2n = 4x = 32). The variable phenotype of the allotetraploids could not be explained by cytological abnormalities. However, we found suppression of 20 of the 700 genes examined by amplified fragment length polymorphism of cDNA. Independent reverse transcription–polymerase chain reaction analyses of 10 of these 20 genes confirmed silencing in three of them, suggesting that ∼0.4% of the genes in the allotetraploids are silenced. These three silenced genes were characterized. One, called K7, is repeated and similar to transposons. Another is RAP2.1, a member of the large APETALA2 (AP2) gene family, and has a repeated element upstream of its 5′ end. The last, L6, is an unknown gene close to ALCOHOL DEHYDROGENASE on chromosome 1. CNG DNA methylation of K7 was less in the allotetraploids than in the parents, and the element varied in copy number. That K7 could be reactivated suggests epigenetic regulation. L6 was methylated in the C. arenosa genome. The present evidence that gene silencing accompanies allopolyploidization opens new avenues to this area of research.

The HOP1 gene encodes a meiosis-specific component of yeast chromosomes

The HOP1 gene in Saccharomyces cerevisiae is important for meiotic chromosomal pairing, because hop1 diploids fail to form synaptonemal complex during meiosis and are defective in crossing over between, but not within, chromosomes. We demonstrate here that the HOP1 gene is transcriptionally regulated during sporulation and that the HOP1 protein is situated along the lengths of meiotic chromosomes. Furthermore, the HOP1 protein contains a Cys2/Cys2 zinc finger motif. A mutation within this motif that changes a cysteine to serine results in the hop1 phenotype, consistent with the possibility that the HOP1 gene product acts in chromosome synapsis by directly interacting with DNA. These observations demonstrate that HOP1 encodes a component of meiotic chromosomes, perhaps serving as a constituent of the synaptonemal complex.

Cdc53p acts in concert with cdc4p and cdc34p to control the G1-to-S- phase transition and identifies a conserved family of proteins

Regulation of cell cycle progression occurs in part through the targeted degradation of both activating and inhibitory subunits of the cyclin-dependent kinases. During G1, CDC4, encoding a WD-40 repeat protein, and CDC34, encoding a ubiquitin-conjugating enzyme, are involved in the destruction of these regulators. Here we describe evidence indicating that CDC53 also is involved in this process. Mutations in CDC53 cause a phenotype indistinguishable from those of cdc4 and cdc34 mutations, numerous genetic interactions are seen between these genes, and the encoded proteins are found physically associated in vivo. Cdc53p defines a large family of proteins found in yeasts, nematodes, and humans whose molecular functions are uncharacterized. These results suggest a role for this family of proteins in regulating cell cycle proliferation through protein degradation.

A yeast gene essential for regulation of spindle pole duplication.

In eucaryotic cells, duplication of spindle poles must be coordinated with other cell cycle functions. We report here the identification in Saccharomyces cerevisiae of a temperature-sensitive lethal mutation, esp1, that deregulates spindle pole duplication. Mutant cells transferred to the nonpermissive temperature became unable to continue DNA synthesis and cell division but displayed repeated duplication of their spindle pole bodies. Although entry into this state after transient challenge by the nonpermissive temperature was largely lethal, rare survivors were recovered and found to have become increased in ploidy. If the mutant cells were held in G0 or G1 during exposure to the elevated temperature, they remained viable and maintained normal numbers of spindle poles. These results suggest dual regulation of spindle pole duplication, including a mechanism that promotes duplication as cells enter the division cycle and a negative regulatory mechanism, controlled by ESP1, that limits duplication to a single occurrence in each cell division cycle. Tetrad analysis has revealed that ESP1 resides at a previously undescribed locus on the right arm of chromosome VII.

Meiotic effects of DNA-defective cell division cycle mutations of Saccharomyces cerevisiae.

The meiotic effects of several cell division cycle (cdc) mutations of Saccharomyces cerevisiae have been investigated by electron microscopy and by genetic and biochemical methods. Diploid strains homozygous for cdc mutations known to confer defects on vegetative DNA synthesis were subjected to restrictive conditions during meiosis. Electron microscopy revealed that all four mutants were conditionally arrested in meiosis after duplication of the spindle pole bodies but before spindle formation for the first meiotic division. None of these mutants became committed to recombination or contained synaptonemal complex at the meiotic arrest. — The mutants differed in their ability to undergo premeiotic DNA synthesis under restrictive conditions. Both cdc8 and cdc21, which are defective in the propagation of vegetative DNA synthesis, also failed to undergo premeiotic DNA synthesis. The arrest of these mutants at the stage before meiosis I spindle formation could be attributed to the failure of DNA synthesis because inhibition of synthesis by hydroxyurea also caused arrest at this stage. — Premeiotic DNA synthesis occurred before the arrest of cdc7, which is defective in the initiation of vegetative DNA synthesis, and of cdc2, which synthesizes vegetative DNA but does so defectively. The meiotic arrest of cdc7 homozygotes was partially reversible. Even if further semiconservative DNA replication was inhibited by the addition of hydroxyurea, released cells rapidly underwent commitment to recombination and formation of synaptonemal complexes. The cdc7 homozygote is therefore reversibly arrested in meiosis after DNA replication, whereas vegetative cultures have previously been shown to be defective only in the initiation of DNA synthesis.

Separation of branched from linear DNA by two-dimensional gel electrophoresis

A general method for separating branched DNA molecules, such as replication forks and recombination intermediates, from linear forms has been developed. Using as a model a stable X-shaped molecule constructed in vitro, it was found that this branched form migrated more slowly during agarose gel electrophoresis than did a linear form of the same mass. Higher agarose concentrations and higher electrophoretic voltages enhanced the extent of retardation. These properties provided the basis for an electrophoretic method of separating branched from linear molecules by variation of agarose concentration and voltage over two dimensions. In the first dimension, concentration and voltage were low; in the second, both parameters were increased, thereby forcing X-shaped molecules to migrate to positions distinct from a diagonal arc of linear molecules. In addition, two-dimensional electrophoresis was capable of separating X-shaped forms of different mass from each other, as well as from linear molecules.

Assembly and functions of the spindle pole body in budding yeast

The spindle pole body (SPB) serves as the centrosome in yeasts and in a variety of other lower eukaryotes. In Saccharomyces cerevisiae, this organelle controls the assembly of all microtubules in the cell, acting not only as a pole of the mitotic or meiotic spindle but also as the site from which cytoplasmic microtubules emanate. The distinctive structure of the SPB has permitted definition of discrete stages in its duplication and behavior at all stages of the yeast life cycle. In association with genetic analyses, studies of the yeast SPB are providing insights into the mechanisms that control centrosomal behavior in this model eukaryote.

Structural comparison of the yeast cell division cycle gene CDC4 and a related pseudogene

The function of the cell division cycle gene, CDC4, is required in Saccharomyces cerevisiae for progression beyond the G1 phase of the cell cycle. The wild-type gene was isolated from a plasmid library by selection for complementation of a recessive, temperature-sensitive allele. Hybridization of genomic sequences with the cloned gene revealed the presence of a duplicated sequence. Both CDC4 and the duplicated sequence were subjected to DNA sequence analysis. These analyses revealed (1) that CDC4 contains a large open reading frame encoding a protein of 779 amino acids, and (2) that the duplicated sequence bears strong homology with the carboxy-terminal segment of this open reading frame. Presence of a nonsense codon within the duplicated sequence suggested that it does not encode a functional product. Disruption of the duplicated sequence within the yeast genome provided a more critical test for function. The absence of any detectable phenotype for this disruption confirms that the sequence should be considered a pseudogene. The marker inserted to disrupt the sequence also served to map the duplication and to establish that it is not genetically linked to CDC4. The structural features determined suggest evolutionary relationships between these genes as well as between the CDC4 product and other proteins.

Preparation of yeast cells for thin-section electron microscopy

Publisher Summary This chapter describes the preparation of yeast cells for thin-section electron microscopy. Yeast cells present the electron microscopist with a variety of challenges that have been met by the modification of standard protocols suitable for higher eukaryotes. A principal difficulty is the unusually high density of the cell. A partial solution is achieved by enzymatic removal of the cell wall after an initial fixation in glutaraldehyde, before further fixation and embedding. Removing the wall not only facilitates permeation of the embedding resin but also permits the cell to expand slightly, conferring differences in density that provide for variation in visual contrast. The walls of cells fixed during logarithmic growth are easily digested with appropriate enzymes without making any special provision at the time of glutaraldehyde fixation, but the walls of meiotic cells and certain types of vegetative cells, such as those approaching stationary phase, are refractory to digestion and require a pretreatment procedure. Use of these methods permits visualization of microtubules, certain filament systems, and many other features. As an alternative, membrane systems can be accentuated by special methods, such as fixation with permanganate or the more recently applied technique of postfixation in an osmium tetroxide-ferrocyanide solution. No single method has been described to date that addresses both requirements fully, so the investigator must opt for the method that favors structures of primary concern.

Yeast Meiosis-Specific Protein Hop1 Binds to G4 DNA and Promotes Its Formation

ABSTRACT DNA molecules containing stretches of contiguous guanine residues can assume a stable configuration in which planar quartets of guanine residues joined by Hoogsteen pairing appear in a stacked array. This conformation, called G4 DNA, has been implicated in several aspects of chromosome behavior including immunoglobulin gene rearrangements, promoter activation, and telomere maintenance. Moreover, the ability of the yeast SEP1 gene product to cleave DNA in a G4-DNA-dependent fashion, as well as that of the SGS1 gene product to unwind G4 DNA, has suggested a crucial role for this structure in meiotic synapsis and recombination. Here, we demonstrate that the HOP1 gene product, which plays a crucial role in the formation of synaptonemal complex in Saccharomyces cerevisiae, binds robustly to G4 DNA. The apparent dissociation constant for interaction with G4 DNA is 2 × 10−10, indicative of binding that is about 1,000-fold stronger than to normal duplex DNA. Oligonucleotides of appropriate sequence bound Hop1 protein maximally if the DNA was first subjected to conditions favoring the formation of G4 DNA. Furthermore, incubation of unfolded oligonucleotides with Hop1 led to their transformation into G4 DNA. Methylation interference experiments confirmed that modifications blocking G4 DNA formation inhibit Hop1 binding. In contrast, neither bacterial RecA proteins that preferentially interact with GT-rich DNA nor histone H1 bound strongly to G4 DNA or induced its formation. These findings implicate specific interactions of Hop1 protein with G4 DNA in the pathway to chromosomal synapsis and recombination in meiosis.