The new yeast genetics

Acetate and hypertonic stress stimulate vacuole membrane fission using distinct mechanisms

Vacuoles in plants and fungi play critical roles in cell metabolism and osmoregulation. To support these functions, vacuoles change their morphology, e.g. they fragment when these organisms are challenged with draught, high salinity or metabolic stress (e.g. acetate accumulation). In turn, morphology reflects an equilibrium between membrane fusion and fission that determines size, shape and copy number. By studying Saccharomyces cerevisiae and its vacuole as models, conserved molecular mechanisms responsible for fusion have been revealed. However, a detailed understanding of vacuole fission and how these opposing processes respond to metabolism or osmoregulation remain elusive. Herein we describe a new fluorometric assay to measure yeast vacuole fission in vitro. For proof–of–concept, we use this assay to confirm that acetate, a metabolic stressor, triggers vacuole fission and show it blocks homotypic vacuole fusion in vitro. Similarly, hypertonic stress induced by sorbitol or glucose caused robust vacuole fission in vitro whilst inhibiting fusion. Using wortmannin to inhibit phosphatidylinositol (PI) -kinases or rGyp1-46 to inactivate Rab–GTPases, we show that acetate stress likely targets PI signaling, whereas osmotic stress affects Rab signaling on vacuole membranes to stimulate fission. This study sets the stage for further investigation into the mechanisms that change vacuole morphology to support cell metabolism and osmoregulation.

High-Throughput Automated Chemical Screens in Zebrafish

Zebrafish are increasingly used to perform phenotypic screens to identify agents that can alter physiology in a whole organismal context. Here, we describe an automated high-content chemical screen using transgenic zebrafish embryos to identify small molecules that modulate Fibroblast Growth Factor Signaling. High content multi-well screening was further refined with a particular emphasis on automated imaging and quantification that increases sensitivity and throughput of whole organism chemical screens.

Generation of stable mutants and targeted gene deletion strains in Cryptococcus neoformans through electroporation

Cryptococcus neoformans is the etiologic agent of cryptococcal meningitis that causes more than half a million deaths worldwide each year. This capsulated basidiomycetous yeast also serves as a model for micropathogenic studies. The ability to make stable mutants, either via ectopic integration or homologous recombination, has been accomplished using biolistic transformation. This technical advance has greatly facilitated the research on the basic biology and pathogenic mechanisms of this pathogen in the past two decades. However, biolistic transformation is costly, and its reproducibility varies widely. Here we found that stable ectopic integration or targeted gene deletion via homologous replacement could be accomplished through electroporative transformation. The stability of the transformants obtained through electroporation and the frequency of homologous replacement is highly dependent on the selective marker. A frequency of homologous recombination among the stable transformants obtained by electroporation is comparable to those obtained by biolistic transformation (∼10%) when dominant drug selection markers are used, which is much higher than what has been previously reported for electroporation when auxotrophic markers were used (0.001% to 0.1%). Furthermore, disruption of the KU80 gene or generation of gene deletion constructs using the split marker strategy, two approaches known to increase homologous replacement among transformants obtained through biolistic transformation, also increase the frequency of homologous replacement among transformants obtained through electroporation. Therefore, electroporation provides a low cost alternative for mutagenesis in Cryptococcus.

Improving industrial yeast strains: exploiting natural and artificial diversity

Yeasts have been used for thousands of years to make fermented foods and beverages, such as beer, wine, sake, and bread. However, the choice for a particular yeast strain or species for a specific industrial application is often based on historical, rather than scientific grounds. Moreover, new biotechnological yeast applications, such as the production of second-generation biofuels, confront yeast with environments and challenges that differ from those encountered in traditional food fermentations. Together, this implies that there are interesting opportunities to isolate or generate yeast variants that perform better than the currently used strains. Here, we discuss the different strategies of strain selection and improvement available for both conventional and nonconventional yeasts. Exploiting the existing natural diversity and using techniques such as mutagenesis, protoplast fusion, breeding, genome shuffling and directed evolution to generate artificial diversity, or the use of genetic modification strategies to alter traits in a more targeted way, have led to the selection of superior industrial yeasts. Furthermore, recent technological advances allowed the development of high-throughput techniques, such as 'global transcription machinery engineering' (gTME), to induce genetic variation, providing a new source of yeast genetic diversity.

Stochastic association of neighboring replicons creates replication factories in budding yeast

Inside the nucleus, DNA replication is organized at discrete sites called replication factories, consisting of DNA polymerases and other replication proteins. Replication factories play important roles in coordinating replication and in responding to replication stress. However, it remains unknown how replicons are organized for processing at each replication factory. Here we address this question using budding yeast. We analyze how individual replicons dynamically organized a replication factory using live-cell imaging and investigate how replication factories were structured using super-resolution microscopy. Surprisingly, we show that the grouping of replicons within factories is highly variable from cell to cell. Once associated, however, replicons stay together relatively stably to maintain replication factories. We derive a coherent genome-wide mathematical model showing how neighboring replicons became associated stochastically to form replication factories, which was validated by independent microscopy-based analyses. This study not only reveals the fundamental principles promoting replication factory organization in budding yeast, but also provides insight into general mechanisms by which chromosomes organize sub-nuclear structures.

Development of an autonomously replicating linear vector of the yeast Cryptococcus humicola by using telomere-like sequence repeats

The yeast Cryptococcus humicola has several attractive properties for practical applications such as in bioremediation and as a source of industrially useful enzymes and compounds. We have developed an autonomously replicating vector of C. humicola to improve its properties. We initially tried to isolate an autonomously replicating sequence (ARS) from genomic DNA by transformation using a genomic DNA library. We obtained a candidate plasmid vector harboring an ARS that gave high transformation efficiency. Southern blot analysis of transformants revealed the autonomous replication of the introduced vector in some transformants. However, the vector was not only variously altered in length but also linearized. PCR analysis indicated that a telomere-like sequence repeat (TTAGGGGG)( n ) was added to the termini of linearized vector. Thus, we constructed an autonomously replicating linear vector having ten repeats of the telomere-like sequence at both ends. The vector transformed the yeast cells with high transformation efficiency (3230 CFU/μg of DNA), which was approximately 25-fold higher than that of a control vector lacking the repeats, and was autonomously replicated at a roughly constant size. The copy number was estimated to be less than one copy, and Ura(+) mitotic stability varied widely among the transformants and was related to plasmid segregation efficiency.

A cosmid for selecting genes by complementation in Aspergillus nidulans: Selection of the developmentally regulated yA locus

We constructed a 9.9-kilobase cloning vector, designated pKBY2, for isolating genes by complementation of mutations in Aspergillus nidulans. pKBY2 contains the bacteriophage lambda cos site, to permit in vitro assembly of phage particles; a bacterial origin of replication and genes for resistance to ampicillin and chloramphenicol, to permit propagation in Escherichia coli; the A. nidulans trpC(+) gene, to permit selection in Aspergillus; and a unique BamHI restriction site, to permit insertion of DNA fragments produced by digestion with restriction endonucleases BamHI, BglII, Mbo I, or Sau3A. We used this cosmid to form a quasirandom recombinant DNA library containing 35- to 40-kilobase DNA fragments from a wild-type strain of A. nidulans. DNA from this library transformed a yellow-spored (yA(-)) pabaA(-)trpC(-)Aspergillus strain (FGSC237) to trpC(+) at frequencies of approximately 10 transformants per mug of DNA. Three of approximately 1000 trpC(+)pabaA(-) colonies obtained were putative yA(+) transformants, because they produced wild-type (green) spores. DNA from each of the green-spored transformants contained pKBY2 sequences and DNA from two transformants transduced E. coli to ampicillin resistance following treatment in vitro with a lambda packaging extract. The cosmids recovered in E. coli had similar restriction patterns and both yielded trpC(+) transformants of A. nidulans FGSC237, 85% of which produced green spores. Several lines of evidence indicate that the recovered cosmids contain a wild-type copy of the yA gene.

Rescue and characterization of episomally replicating DNA from the moss Physcomitrella

The moss Physcomitrella is unique among plants in that it permits efficient gene targeting by homologous recombination. Furthermore, transformed DNA can replicate episomally in Physcomitrella. Here we show that episomally replicating DNA can be rescued back into Escherichia coli, and we use such rescue to study the fate of the transformed DNA. Significantly, plasmids rescued from moss transformed with circular DNA are identical to the original plasmid, whereas plasmids rescued from moss transformed with linearized DNA frequently have deletions created by direct repeat recombination. These events are highly predictable in that they target the longest direct repeat on the plasmid if this repeat is at least 12 bp. Episomal transformants obtained with linearized DNA show a more than 1,000-fold amplification of the DNA whereas transformants obtained with circular DNA have much lower copy numbers. Most episomal transformants quickly lose the plasmid in the absence of selection, but a semistable type of transformant that loses the plasmid at a much lower frequency was also observed. The consistent rescue of the original plasmid, or of predictable derivatives thereof, suggests that molecular genetics methods which rely on shuttle plasmids are feasible in Physcomitrella.

Neocentromeres form efficiently at multiple possible loci in Candida albicans

Centromeres are critically important for chromosome stability and integrity. Most eukaryotes have regional centromeres that include long tracts of repetitive DNA packaged into pericentric heterochromatin. Neocentromeres, new sites of functional kinetochore assembly, can form at ectopic loci because no DNA sequence is strictly required for assembly of a functional kinetochore. In humans, neocentromeres often arise in cells with gross chromosome rearrangements that rescue an acentric chromosome. Here, we studied the properties of centromeres in Candida albicans, the most prevalent fungal pathogen of humans, which has small regional centromeres that lack pericentric heterochromatin. We functionally delimited centromere DNA on Chromosome 5 (CEN5) and then replaced the entire region with the counter-selectable URA3 gene or other marker genes. All of the resulting cen5Δ::URA3 transformants stably retained both copies of Chr5, indicating that a functional neocentromere had assembled efficiently on the homolog lacking CEN5 DNA. Strains selected to maintain only the cen5Δ::URA3 homolog and no wild-type Chr5 homolog also grew well, indicating that neocentromere function is independent of the presence of any wild-type CEN5 DNA. Two classes of neocentromere (neoCEN) strains were distinguishable: “proximal neoCEN” and “distal neoCEN” strains. Neocentromeres in the distal neoCEN strains formed at loci about 200–450 kb from cen5Δ::URA3 on either chromosome arm, as detected by massively parallel sequencing of DNA isolated by CENP-A^Cse4p chromatin immunoprecipitation (ChIP). In the proximal neoCEN strains, the neocentromeres formed directly adjacent to cen5Δ::URA3 and moved onto the URA3 DNA, resulting in silencing of its expression. Functional neocentromeres form efficiently at several possible loci that share properties of low gene density and flanking repeated DNA sequences. Subsequently, neocentromeres can move locally, which can be detected by silencing of an adjacent URA3 gene, or can relocate to entirely different regions of the chromosome. The ability to select for neocentromere formation and movement in C. albicans permits mechanistic analysis of the assembly and maintenance of a regional centromere.

Centromere function is essential for proper chromosomal segregation. Most organisms, including humans, have regional centromeres in which centromere function is not strictly dependent on DNA sequence. Upon alteration of chromosomes, new functional centromeres (neocentromeres) can form at ectopic positions. The mechanisms of neocentromere formation are not understood, primarily because neocentromere formation is rarely detected. Here. we show that C. albicans, an important fungal pathogen of humans, has small regional centromeres and can form neocentromeres very efficiently when normal centromere DNA is deleted, and the resulting chromosomes are stably propagated. Neocentromeres can form either very close to the position of the deleted centromere or at other positions along the chromosome arms, including at the telomeres. Subsequently, neocentromeres can move to new chromosomal positions, and this movement can be detected by silencing of a counterselectable gene. The features common to sites of neocentromere formation are longer-than-average intergenic regions and the proximity of inverted or direct repeat sequences. The ability to select for neocentromere formation and movement in C. albicans permits mechanistic analysis of the assembly and maintenance of a regional centromere.

Cell cycle-dependent transcription in yeast: promoters, transcription factors, and transcriptomes

In the budding yeast, Saccharomyces cerevisiae, a significant fraction of genes (>10%) are transcribed with cell cycle periodicity. These genes encode critical cell cycle regulators as well as proteins with no direct connection to cell cycle functions. Cell cycle-regulated genes can be organized into 'clusters' exhibiting similar patterns of regulation. In most cases periodic transcription is achieved via both repressive and activating mechanisms. Fine-tuning appears to have evolved by the juxtaposition of regulatory motifs characteristic of more than one cluster within the same promoter. Recent reports have provided significant new insight into the role of the cyclin-dependent kinase Cdk1 (Cdc28) in coordination of transcription with cell cycle events. In early G1, the transcription factor complex known as SBF is maintained in a repressed state by association of the Whi5 protein. Phosphorylation of Whi5 by Cdk1 in late G1 leads to dissociation from SBF and transcriptional derepression. G2/M-specific transcription is achieved by converting the repressor Fkh2 into an activator. Fkh2 serves as a repressor during most of the cell cycle. However, phosphorylation of a cofactor, Ndd1, by Cdk1 late in the cell cycle promotes binding to Fkh2 and conversion into a transcriptional activator. Such insights derived from analysis of specific genes when combined with genome-wide analysis provide a more detailed and integrated view of cell cycle-dependent transcription.

Development of a highly efficient gene targeting system for using the disruption of a polyketide synthase gene as a visible marker

We cloned a polyketide synthase gene (pks12) from Fusarium graminearum, a devastating fungal pathogen of cereals. Transformation-mediated gene disruption led to an easily detectable albino phenotype of the disruptants. We used the disruption of the pks12 gene as a visible marker for transformation-mediated homologous recombination and optimized the transformation procedure to achieve a high rate of homologous recombination. In combination with the published genomic sequence data and the generation of expressed sequence tags (ESTs) for F. graminearum, this is a useful tool to investigate this important plant pathogen on a molecular level. Optimized transformation of F. graminearum resulted in at least 93% homologous recombination events when the homologous genomic DNA fragment in the vector had a size of approximately 800bp and was linearized in the middle. Using a genomic sequence of approximately 500bp in the transformation vector, 70% of the transformants still exhibited homologous recombination. On the contrary, no more than 10% homologous recombination events were observed when less than 400bp DNA fragments were used. We co-transformed F. graminearum with two different vectors. One vector harboured a DNA insert homologous to the pks12 gene, while the other vector consisted of the same vector backbone carrying the selection marker specific for F. graminearum. About 70% of the transformants had a disrupted pks12 gene, and all of these showed an integration of the second vector into the pks disruption vector. Therefore, the time-consuming construction of a single transformation vector can be avoided; furthermore, it is now easily feasible to express a gene construct at a defined and mutated genomic site.

Mapping of the Physcomitrella patens proteome

The moss Physcomitrella patens is unique among land plants due to the high rate of homologous recombination in its nuclear DNA. The feasibility of gene targeting makes Physcomitrella an unrivalled model organism in the field of plant functional genomics. To further extend the potentialities of this seed-less plant we aimed at exploring the P. patens proteome. Experimental conditions had to be adopted to meet the special requirements connected to the investigations of this moss. Here we describe the identification of 306 proteins from the protonema of Physcomitrella. Proteins were separated by two dimensional electrophoresis, excised form the gel and analysed by means of mass spectrometry. This reference map will lay the basis for further profound studies in the field of Physcomitrella proteomics.

Modeling cancer in mice

The laboratory mouse is one of the most powerful tools for both gene discovery and validation in cancer genetics. Recent technological advances in engineering the mouse genome with chromosome translocations, latent alleles, and tissue-specific and temporally regulated mutations have provided more exacting models of human disease. The marriage of mouse tumor models with rapidly evolving methods to profile genetic and epigenetic alterations in tumors, and to finely map genetic modifier loci, will continue to provide insight into the key pathways leading to tumorigenesis. These discoveries hold great promise for identifying relevant drug targets for treating human cancer.

A new moss genetics: targeted mutagenesis in Physcomitrella patens

The potential of moss as a model system to study plant biology is associated with their relatively simple developmental pattern that nevertheless resembles the basic organization of the body plan of land plants, the direct access to cell-lineage analysis, their similar responses to plant growth factors and environmental stimuli as those observed in other land plants, and the dominance of the gametophyte in the life cycle that facilitates genetic approaches. Transformation studies in the moss Physcomitrella patens have revealed a totally unique feature for plants, i.e., that foreign DNA sequences integrate in the genome preferentially at targeted locations by homologous recombination, enabling for the first time in plants the application of the powerful molecular genetic approaches used routinely in bacteria, yeast, and since 1989, the mouse embryonic stem cells. This article reviews our current knowledge of Physcomitrella patens transformation and its unique suitability for functional genomic studies.

Gene targeting in Physcomitrella patens

Gene-targeting efficiency in the land plant Physcomitrella patens (Bryophyta) can only be compared with that observed in Saccharomyces cerevisiae. Sequencing programs and microbiological molecular genetic approaches are now being developed to unravel the precise function of plant genes. Physcomitrella patens, as the new 'green yeast', might well become a major tool for functional genomic studies of multicellular eukaryotes.

An adhesin of the yeast pathogen Candida glabrata mediating adherence to human epithelial cells

Candida glabrata is an important fungal pathogen of humans that is responsible for about 15 percent of mucosal and systemic candidiasis. Candida glabrata adhered avidly to human epithelial cells in culture. By means of a genetic approach and a strategy allowing parallel screening of mutants, it was possible to clone a lectin from a Candida species. Deletion of this adhesin reduced adherence of C. glabrata to human epithelial cells by 95 percent. The adhesin, encoded by the EPA1 gene, is likely a glucan-cross-linked cell-wall protein and binds to host-cell carbohydrate, specifically recognizing asialo-lactosyl-containing carbohydrates.

Targeted gene disruption reveals an adhesin indispensable for pathogenicity of Blastomyces dermatitidis

Systemic fungal infections are becoming more common and difficult to treat, yet the pathogenesis of these infectious diseases remains poorly understood. In many cases, pathogenicity can be attributed to the ability of the fungi to adhere to target tissues, but the lack of tractable genetic systems has limited progress in understanding and interfering with the offending fungal products. In Blastomyces dermatitidis, the agent of blastomycosis, a respiratory and disseminated mycosis of people and animals worldwide, expression of the putative adhesin encoded by the WI-1 gene was investigated as a possible virulence factor. DNA-mediated gene transfer was used to disrupt the WI-1 locus by allelic replacement, resulting in impaired binding and entry of yeasts into macrophages, loss of adherence to lung tissue, and abolishment of virulence in mice; each of these properties was fully restored after reconstitution of WI-1 by means of gene transfer. These findings establish the pivotal role of WI-1 in adherence and virulence of B. dermatitidis yeasts. To our knowledge, they offer the first example of a genetically proven virulence determinant among systemic dimorphic fungi, and underscore the value of reverse genetics for studies of pathogenesis in these organisms.

Functional analysis of HO gene in delayed homothallism in Saccharomyces cerevisiae wy2

Saccharomyces cerevisiae wy2 exhibits a novel life cycle, with delayed homothallism caused by a defective HO gene. In this strain, gradual diploidization occurs during successive subcultures. Three amino acids of wy2 HO were different from those of wild-type (wt) HO, which included a nonsense mutation (TAG) from Trp-292 and two amino acid changes of His-475 to Leu and Glu-530 to Lys. The ho gene of heterothallic strain CG379 was also sequenced in this study. Four amino acids of ho were different from those of HO. Among different amino acids in wy2 HO and ho, the alteration of His-475 to Leu was common between them. His-475 in HO was previously suggested to be involved in the DNA binding. We constructed a variety of chimeric HO genes by exchanging the corresponding restriction fragments generated from the wt HO, wy2 HO and ho genes. These results and the site-directed mutagenesis studies allowed us to draw the following conclusions: (a) Gly-223 is essential for HO activity; (b) mutation of His-475 to Leu significantly reduces the HO activity; (c) amber mutation (TAG) in wy2 HO car be suppressed inefficiently.

Efficient homologous and illegitimate recombination in the opportunistic yeast pathogen Candida glabrata

The opportunistic pathogen Candida glabrata causes significant disease in humans. To develop genetic tools to investigate the pathogenicity of this organism, we have constructed ura3 and his3 auxotrophic strains by deleting the relevant coding regions in a C. glabrata clinical isolate. Linearized plasmids carrying a Saccharomyces cerevisiae URA3 gene efficiently transformed the ura3 auxotroph to prototrophy. Homologous recombination events were observed when the linearized plasmid carried short terminal regions homologous with the chromosome. In contrast, in the absence of any chromosomal homology, the plasmid integrated by illegitimate recombination into random sites in the genome. Sequence analysis of the target sites revealed that for the majority of illegitimate transformants there was no microhomology with the integration site. Approximately 0.25% of the insertions resulted in amino acid auxotrophy, suggesting that insertion was random at a gross level. Sequence analysis suggested that illegitimate recombination is nonrandom at the single-gene level and that the integrating plasmid has a preference for inserting into noncoding regions of the genome. Analysis of the relative numbers of homologous and illegitimate recombination events suggests that C. glabrata possesses efficient systems for both homologous and nonhomologous recombination.

Synergistic activation of yeast-expressed rat androgen receptor by modulators of protein kinase-A

We have employed a yeast (Saccharomyces cerevisiae) based rat androgen receptor expression system to examine the cross-talk between different signalling pathways. We report here the synergistic modulation of androgen regulated transcriptional activation of beta-galactosidase reporter activity by the activators of protein kinase-A, like forskolin and 8-bromo-cyclic AMP. A similar ligand-dependent enhancement of reporter activity compared to a DHT treated control has been noticed with okadaic acid, which is a potent inhibitor of protein phosphatase. The activation could be blocked by protein kinase-A/C inhibitor, H7. Forskolin treatment neither altered levels of receptor mRNA nor [3H]R1881 binding to the receptor. Although it promotes binding of receptor to an androgen response element, forskolin was unable to activate subsequent interaction with the transcription machinery in the absence of androgen. Additionally, the synergistic actions of these activators were independent of the degree of androgen response element occupancy. Anti-androgens, cyproterone acetate and flutamide, which failed to exhibit antagonistic behaviour with yeast expressed receptor, were able to antagonize only the forskolin mediated augmentation of reporter activity. Finally, analyses of mutants established the role of DNA and steroid binding domains of receptor for this synergism.

Rare homologous gene targeting in Histoplasma capsulatum: disruption of the URA5Hc gene by allelic replacement

URA5 genes encode orotidine-5'-monophosphate pyrophosphorylase (OMPpase), an enzyme involved in pyrimidine biosynthesis. We cloned the Histoplasma capsulatum URA5 gene (URA5Hc) by using a probe generated by PCR with inosine-rich primers based on relatively conserved sequences in OMPpases from other organisms. Transformation with this gene restored uracil prototrophy and OMPpase activity to UV-mutagenized ura5 strains of H. capsulatum. We attempted to target the genomic URA5 locus in this haploid organism to demonstrate homologous allelic replacement with transforming DNA, which has not been previously done in H. capsulatum and has been challenging in some other pathogenic fungi. Several strategies commonly used in Saccharomyces cerevisiae and other eukaryotes were unsuccessful, due to the frequent occurrence of ectopic integration, linear plasmid formation, and spontaneous resistance to 5-fluoroorotic acid, which is a selective agent for URA5 gene inactivation. Recent development of an efficient electrotransformation system and of a second selectable marker (hph, conferring hygromycin B resistance) for this fungus enabled us to achieve allelic replacement by using transformation with an insertionally inactivated Deltaura5Hc::hph plasmid, followed by dual selection with hygromycin B and 5-fluoroorotic acid, or by screening hygromycin B-resistant transformants for uracil auxotrophy. The relative frequency of homologous gene targeting was approximately one allelic replacement event per thousand transformants. This work demonstrates the feasibility but also the potential challenge of gene disruption in this organism. To our knowledge, it represents the first example of experimentally directed allelic replacement in H. capsulatum, or in any dimorphic systemic fungal pathogen of humans.

High efficiency site-specific modification of the chromosomal immunoglobulin locus by gene targeting

Site-specific modification of the chromosomal immunoglobulin locus by gene targeting is a powerful tool in studying the molecular requirements for immunoglobulin gene structure and function and in the production of engineered antibodies. Here, we describe a two step- integration then excision-gene targeting procedure for introducing planned genetic alterations into the chromosomal immunoglobulin locus. The efficiency of gene targeting with an enhancer-trap vector in which an enhancerless neo and HSV-tk gene were inserted into the vector backbone was compared to that of the corresponding enhancer-positive vector. Both insertion vectors also contained homology to the chromosomal immunoglobulin target locus along with the desired genetic alteration. The first step involved insertion of the transferred vector into the target locus by homologous recombination. An approximately 15-fold enrichment in the frequency of vector insertion was obtained with the enhancer-trap compared to the enhancer-positive vector. The majority of targeted cells (75%) contained a single copy of the vector integrated into the chromosomal immunoglobulin locus. The second step involved excision of the integrated vector by intrachromosomal homologous recombination between the duplicated region of homology that removed the integrated vector, neo and tk genes along with one copy of homologous DNA. Vector excision was very efficient generating G418S, FIAU(R) secondary recombinants at the high rate of approximately 10(-3)/cell generation. In the secondary recombinants, the overall structure of the chromosomal immunoglobulin locus was restored with the desired genetic alteration being present in an expected proportion of the cells.

Plant nuclear gene knockout reveals a role in plastid division for the homolog of the bacterial cell division protein FtsZ, an ancestral tubulin

Little is known about the division of eukaryotic cell organelles and up to now neither in animals nor in plants has a gene product been shown to mediate this process. A cDNA encoding a homolog of the bacterial cell division protein FtsZ, an ancestral tubulin, was isolated from the eukaryote Physcomitrella patens and used to disrupt efficiently the genomic locus in this terrestrial seedless plant. Seven out of 51 transgenics obtained were knockout plants generated by homologous recombination; they were specifically impeded in plastid division with no detectable effect on mitochondrial division or plant morphology. Implications on the theory of endosymbiosis and on the use of reverse genetics in plants are discussed.

18S rRNA processing requires the RNA helicase-like protein Rrp3

We report the identification of a new gene, RRP3 (rRNA processing), which is required for pre-rRNA processing. Rrp3 is a 60.9 kDa protein that is required for maturation of the 35S primary transcript of pre-rRNA and is required for cleavages leading to mature 18S RNA. RRP3 was identified in a PCR screen for DEAD box genes. DEAD box genes are part of a large family of proteins homologous to the eukaryotic transcription factor elF-4a. Most of these proteins are RNA-dependent ATPases and some of them have RNA helicase activity. This is the third yeast DEAD box protein that has been shown to be involved in rRNA assembly, but the only one required for the processing of 18S RNA. Mutants of the two other putative helicases, Spb4 and Drsl, both show processing defects in 25S rRNA maturation. In strains where Rrp3 is depleted, 35S precursor RNA is improperly processed. Cleavage normally occurs at sites A0O, Al and A2, but in the Rrp3 depletion stain cleavage occurs between A2 and B1. Rrp3 has been purified to homogeneity and has a weak RNA-dependent ATPase activity which is not specific for rRNA.

Transformation of Sordaria macrospora to hygromycin B resistance: characterization of transformants by electrophoretic karyotyping and tetrad analysis

The ascomycete Sordaria macrospora was transformed using different plasmid molecules containing the bacterial hygromycin B resistance gene (hph) under the control of different expression signals. The highest transformation frequency was obtained with vector pMW1. On this plasmid molecule, expression of the hph gene is directed by the upstream region of the isopenicillin N synthetase gene (pcbC) from the deuteromycete Acremonium chrysogenum. Southern analysis suggests that the vector copies are integrated as tandem repeats into the S. macrospora chromosomes and that duplicated sequences are most probably not inactivated by methylation during meiosis. Furthermore, the hygromycin B resistance (hygR) is not correlated with the number of integrated vector molecules. Electrophoretic karyotyping was used to further characterize S. macrospora transformants. Five chromosomal bands were separated by pulsed-field gel electrophoresis (PFGE) representing seven chromosomes with a total genome size of 39.5Mb. Hybridization analysis revealed ectopic integration of vector DNA into different chromosomes. In a few transformants, major rearrangements were detected. Transformants were sexually propagated to analyze the fate of the heterologous vector DNA. Although the hygR phenotype is stably maintained during mitosis, about a third of all lines tested showed loss of the resistance marker gene after meiosis. However, as was concluded from electrophoretic karyotyping, the resistant spores showed a Mendelian segregation of the integrated vector molecules in at least three consecutive generations. Our data indicate that heterologous marker genes can be used for transformation tagging, or the molecular mapping of chromosomal loci in S. macrospora.

Schizosaccharomyces pombe: a model for molecular studies of eukaryotic genes

Several features of the fission yeast Schizosaccharomyces pombe make it exceptionally well suited for the study of eukaryotic genes. It is a relatively simple eukaryote that can be readily grown and manipulated in the laboratory, using a variety of highly developed and sophisticated methodologies. Schizosaccharomyces pombe cells share many molecular, genetic, and biochemical features with cells from multicellular organisms, making it a particularly useful model to study the structure, function, and regulation of genes from more complex species. For examples, this yeast divides by binary fission, has many genes that contain introns, is capable of using mammalian gene promoters and polyadenylation signals, and has been used to clone mammalian genes by functional complementation of mutants. We present a summary of the biology of S. pombe, useful features that make it amenable to laboratory studies, and molecular techniques available to manipulate the genome of this organism as well as other eukaryotic genes within the fission yeast cellular environment.

Targeted integration into the Acremonium chrysogenum genome: disruption of the pcbC gene

The cephalosporin C-producing fungus Acremonium chrysogenum was transformed to hygromycin B resistance using different vector constructs. These constructs contain sequences of the pcbC gene from A. chrysogenum, encoding isopenicillin N synthetase. Detailed analysis of transformants, including pulsed-field gel electrophoresis (PFGE), suggests that integration of multiple vector copies takes place predominantly via non-homologous integration. By increasing the length of vector-DNA homologous to genomic DNA, integration occurs more frequently into chromosome VI, carrying the endogenous pcbC gene copy. In gene disruption experiments, the length of vector homology required to obtain cephalosporin C-minus transformants was investigated. Inactivation of the pcbC gene was observed only when homologous fragments of more than 3.0 kb were used on both sites of the resistance cassette. Southern analysis indicated homologous, as well as heterologous, integration of recombinant DNA. The integration of multiple vector copies leads to the appearance of truncated pcbC transcripts.

Predisposition to neoplastic transformation caused by gene replacement of H-ras1

Homologous recombination was used to introduce a nominally transforming mutation into an endogenous H-ras1 gene in Rat1 fibroblasts. Although both the mutant and the remaining normal allele were expressed equally, the heterozygous cells were not neoplastically transformed. Instead, spontaneously transformed cells arose from the heterozygotes at a low frequency, and the majority of these cells had amplified the mutant allele. Thus, the activated H-ras1 allele was not by itself dominant over the normal allele but predisposed cells to transformation by independent events, such as amplification of the mutant allele.

Efficient mass transformation of Tetrahymena thermophila by electroporation of conjugants

Conjugating cells of the ciliate Tetrahymena thermophila were electroporated in the presence of plasmid DNA containing a paromomycin-resistant ribosomal RNA gene (rDNA). Cells were selected with paromomycin following 12-24 hr of growth on nonselective medium. Resistant cells appeared after 2-3 days. Processing vectors containing the micronuclear rDNA and somatic vectors containing the macronuclear gene transformed the cells, with the former yielding frequencies up to 900 transformants per microgram of plasmid DNA. A ribosomal protein gene (rpL29) conferring cycloheximide resistance also transformed conjugating cells. The transformation efficiency of the plasmid containing only the rpL29 gene was increased by insertion of an rDNA replication origin and by cotransformation and preselection with an rDNA vector. These results indicate that electroporation can be used for the production of large numbers of transformed Tetrahymena.

Molecular and genetic analysis of URA5 transformants of Cryptococcus neoformans

Cryptococcus neoformans var. neoformans ura5 mutants were transformed with linearized or circular plasmids containing the C. neoformans orotidine monophosphate pyrophosphorylase gene. Following electroporation, randomly isolated transformants were analyzed for the mitotic and meiotic stability of uracil prototrophy. All stable transformants tested showed nonspecific ectopic integration. Uracil prototrophy in these transformants was stable through meiosis. Some of the stable transformants showed integration of both URA5 and vector sequences, while others lacked any vector sequences. Unstable transformants exhibited the presence of an autonomously replicating plasmid which had undergone significant sequence rearrangement. The autonomously replicating plasmid in the transformants was observed to be the same size or smaller than the transforming plasmid, was maintained in a linear form, and had acquired a genomic sequence(s) with homology to a sequence(s) on all the chromosomes. The conservation of a 300-bp sequence at the 5' end of the URA5 gene was observed in all the rearranged plasmids. These results suggest mechanisms of plasmid maintenance in C. neoformans that are different from those reported for other yeasts. The ura5 mutant was significantly less virulent than the wild type. The transformants did not recover virulence regardless of prototrophic stability.

Effects of phosphoglycerate kinase overproduction in Saccharomyces cerevisiae on the physiology and plasmid stability

In this report the effects of phosphoglycerate kinase (PGK) overproduction on the physiology and plasmid stability in baker's yeast Saccharomyces cerevisiae containing the PGK1 gene on an episomal plasmid are described. This examination reveals that there is a preferred intracellular level for this enzyme, amounting to 10-15% of the total soluble protein. Strains containing the plasmid and the host strain were grown in non-selective batch cultures and continuous culture, under different growth conditions. Plasmid-containing yeast strains stabilize the copy number of the episomal plasmid at a level at which the PGK concentration is about 12%. This stabilization is due to an equilibrium between normal plasmid loss and selective pressure because of advantages resulting from the increased amount of PGK under glucose-limited conditions. During respiro-fermentative growth, PGK-overproducing cells showed an increased respiration rate and decreased fermentative activity, compared to the host strain. The PGK1 gene can be applied as a direct positive selection marker to obtain a high episomal plasmid stability during growth on glucose. The results are consistent with previously reported data on the physiology and gene stability of PGK-overproducing yeast cells that contain multiple copies of the PGK1 gene integrated into the genome.

A paradoxical increase of a metabolite upon increased expression of its catabolic enzyme: the case of diadenosine tetraphosphate (Ap4A) and Ap4A phosphorylase I in Saccharomyces cerevisiae

The APA1 gene in Saccharomyces cerevisiae encodes Ap4A phosphorylase I, the catabolic enzyme for diadenosine 5',5"'-P1,P4-tetraphosphate (Ap4A). APA1 has been inserted into a multicopy plasmid and into a centromeric plasmid with a GAL1 promoter. Enhanced expression of APA1 via the plasmids resulted in 10- and 90-fold increases in Ap4A phosphorylase activity, respectively, as assayed in vitro. However, the intracellular concentration of Ap4A exhibited increases of 2- and 15-fold, respectively, from the two different plasmids. Intracellular Ap4A increased 3- to 20-fold during growth on galactose of a transformant with APA1 under the control of the GAL1 promoter. Intracellular adenosine 5'-P1-tetraphospho-P4-5"'-guanosine (Ap4G) and diguanosine 5',5"'-P1,P4-tetraphosphate (Gp4G) also increased in the transformant under these conditions. The chromosomal locus of APA1 has been disrupted in a haploid strain. The Ap4A phosphorylase activity decreased by 80% and the intracellular Ap4A concentration increased by a factor of five in the null mutant. These results with the null mutant agree with previous results reported by Plateau et al. (P. Plateau, M. Fromant, J.-M. Schmitter, J.-M. Buhler, and S. Blancquet, J. Bacteriol. 171:6437-6445, 1989). The paradoxical increase in Ap4A upon enhanced expression of APA1 indicates that the metabolic consequences of altered gene expression may be more complex than indicated solely by assay of enzymatic activity of the gene product.

Targeted disruption of chloroplast genes in Chlamydomonas reinhardtii

We have developed an efficient procedure for the disruption of Chlamydomonas chloroplast genes. Wild-type C. reinhardtii cells were bombarded with microprojectiles coated with a mixture of two plasmids, one encoding selectable, antibiotic-resistance mutations in the 16S ribosomal RNA gene and the other containing either the atpB or rbcL photosynthetic gene inactivated by an insertion of 0.48 kb of yeast DNA in the coding sequence. Antibiotic-resistant transformants were selected under conditions permissive for growth of non-photosynthetic mutants. Approximately half of these transformants were initially heteroplasmic for copies of the disrupted atpB or rbcL genes integrated into the recipient chloroplast genome but still retained photosynthetic competence. A small fraction of the transformants (1.1% for atpB; 4.3% for rbcL) were nonphotosynthetic and homoplasmic for the disrupted gene at the time they were isolated. Single cell cloning of the initially heteroplasmic transformants also yielded nonphotosynthetic segregants that were homoplasmic for the disrupted gene. Polypeptide products of the disrupted atpB and rbcL genes could not be detected using immunoblotting techniques. We believe that any nonessential Chlamydomonas chloroplast gene, such as those involved in photosynthesis, should be amenable to gene disruption by cotransformation. The method should prove useful for the introduction of site-specific mutations into chloroplast genes and flanking regulatory sequences with a view to elucidating their function.

Glucose-responsive and oleic acid-responsive elements in the gene encoding the peroxisomal trifunctional enzyme of Candida tropicalis

We have investigated the regulation of expression of the gene (HDE), encoding the peroxisomal trifunctional enzyme hydratase-dehydrogenase-epimerase (HDE), of the diploid yeast Candida tropicalis. Heterologous expression in Saccharomyces cerevisiae of constructs containing deletions in the upstream region of the HDE gene has allowed for determination of regions responsible for the control of expression of the HDE gene. Expression was monitored by immunoblot analysis of yeast lysates with anti-HDE serum. Regions have been identified that are responsible for both repression by glucose and induction by oleic acid. A glucose-responsive region lies between nucleotides (nt) -526 and -393. An oleic acid-responsive region lies between nt -393 and -341. An additional region controlling derepression by nonfermentable carbon sources is located downstream from nt -341. Comparison of the nt sequences of these regions to upstream regions of other oleic acid-responsive genes of C. tropicalis has identified possible consensus nt sequences for glucose- and oleic acid-responsive upstream elements in these genes. The regulation of the HDE gene in S. cerevisiae closely resembles that found in C. tropicalis, suggesting that similar mechanisms of transcriptional control operate in both yeasts.

Isolation of transcripts preferentially expressed during fruit body primordia differentiation in the basidiomycete Agrocybe aegerita

An Agrocybe aegerita cDNA library, constructed from fruit body primordia poly(A)+ RNAs, was screened by differential colony hybridization. Clones which preferentially hybridized to poly(A)+ RNA sequences from fruit body primordia, versus poly(A)+ RNAs from mycelium, were isolated. Eight of these clones (EMAa-1 to EMAa-8) encoded eight different poly(A)+ RNAs which were demonstrated to be undetectable in the four stages preceding primordia formation and to be concomitantly accumulated when primordia differentiate, suggesting that EMAa gene products are closely involved in the morphogenesis of primordia. The eight EMAa cDNAs hybridize to at least seven unique regions distributed randomly in the A. aegerita genome. The expression of two EMAa cDNA sequences in E. coli led to the isolation of their gene products as fusion proteins.

Ethanol improves the transformation efficiency of intact yeast cells

A technique is described in which ethanol is used to improve the genetic transformation of intact yeast (Saccharomyces cerevisiae) cells pretreated with LiAc and PEG. Transformation efficiency was increased with increasing concentrations of ethanol with a peak at 10% concentration. The effect varies with different yeast strains and plasmids and up to a maximum of a 15-fold increase was observed.