Precise excision of bacterial transposon Tn5 in yeast

Summary We have demonstrated that precise excision of bacterial transposon Tn5 can occur in the yeast, Saccharomyces cerevisiae. Tn5 insertions in the yeast gene LYS2 were generated by transposon mutagenesis made in Escherichia coli by means of a ::Tn5 vector. Nine insertions of Tn5 into the structural part of the yeast LYS2 gene situated in a shuttle epsiomal plasmid were selected. All the plasmids with a Tn5 insertion were used to transform yeast strains carrying a deletion of the entire LYS2 gene or a deletion of the part of LYS2 overlapping the point of insertion.All insertions inactivated the LYS2 gene and were able to revert with low (about 10^-8) frequencies to lysine prototrophy. Restriction analysis of revertant plasmids revealed them to be indistinguishable from the original plasmid without Tn5 insertion. DNA sequencing of the regions containing the points of insertions, made for two revertants, proved that Tn5 excision was completely precise.     

The Saccharomyces cerevisiae ADE1 gene: structure, overexpression and possible regulation by general amino acid control.

The ADE1 gene of the yeast Saccharomyces cerevisiae has been cloned by complementation of the ade1 mutation. The nucleotide sequence has been determined for the 918-bp coding region, 240-bp 5'-noncoding region and 292-bp 3'-noncoding region. The sequenced region includes a single large open reading frame coding for a protein of 306 amino acid (aa) residues. The promoter of the ADE1 gene contains a copy of the 5'-TGACTC hexanucleotide, a feature characteristic of promoters under general aa control. Subsequent search of other published purine biosynthesis gene sequences revealed that all of them also contain general aa control signals in their promoter regions. An expression plasmid containing the ADE1 coding region under control of the PHO5 promoter produced N-succinyl-5-aminoimidazole-4-carboxamide ribotide (SAICAR) synthetase in yeast cells at a level of 40% of total cellular protein. One-step purification resulted in an almost homogeneous preparation of SAICAR synthetase.     

Cloning and physical mapping of the ADE1 gene of the yeast Saccharomyces cerevisiae

ADE1 gene of Saccharomyces cerevisiae codes for the primary structure of SAICAR-synthetase. Mutational changes of ADE1 gene result in the accumulation of red pigment in cells. Colour differences, thus, serve as a basis for the selection of mutants or transformants. ADE1 gene was cloned as a 4.0 kb HindIII fragment of yeast DNA in a shuttle vector by complementing the ade1 mutation in yeast. The study of ADE1 gene expression in Escherichia coli showed that the 4.0 kb fragment containing the ADE1 gene does not complement purC mutations in E. coli. However, prototrophic colonies appeared at a frequency of 10(-7)-10(-8) after incubating clones bearing the recombinant plasmid with ADE1 gene on selective media. The plasmid DNA isolated from such clones complements the purC mutation in E. coli and the ade1 mutation in S. cerevisiae. Structural analysis of the plasmid demonstrated that the cloned DNA fragment contained an additional insertion of the bacterial origin. Further restriction enzyme analysis proved the insertion to be the bacterial element IS1. Expression of the cloned ADE1 gene in S. cerevisiae is controlled by its own promoter, whereas in E. coli it is controlled by the IS1 bacterial element.     

Tetrameric restriction enzymes: expansion to the GIY-YIG nuclease family

The GIY-YIG nuclease domain was originally identified in homing endonucleases and enzymes involved in DNA repair and recombination. Many of the GIY-YIG family enzymes are functional as monomers. We show here that the Cfr42I restriction endonuclease which belongs to the GIY-YIG family and recognizes the symmetric sequence 5′-CCGC/GG-3′ (‘/’ indicates the cleavage site) is a tetramer in solution. Moreover, biochemical and kinetic studies provided here demonstrate that the Cfr42I tetramer is catalytically active only upon simultaneous binding of two copies of its recognition sequence. In that respect Cfr42I resembles the homotetrameric Type IIF restriction enzymes that belong to the distinct PD-(E/D)XK nuclease superfamily. Unlike the PD-(E/D)XK enzymes, the GIY-YIG nuclease Cfr42I accommodates an extremely wide selection of metal-ion cofactors, including Mg²⁺, Mn²⁺, Co²⁺, Zn²⁺, Ni²⁺, Cu²⁺ and Ca²⁺. To our knowledge, Cfr42I is the first tetrameric GIY-YIG family enzyme. Similar structural arrangement and phenotypes displayed by restriction enzymes of the PD-(E/D)XK and GIY-YIG nuclease families point to the functional significance of tetramerization.     

Oligomeric Structure Diversity within the GIY-YIG Nuclease Family

The GIY-YIG nuclease domain has been identified in homing endonucleases, DNA repair and recombination enzymes, and restriction endonucleases. The Type II restriction enzyme Eco29kI belongs to the GIY-YIG nuclease superfamily and, like most of other family members, including the homing endonuclease I-TevI, is a monomer. It recognizes the palindromic sequence 5′-CCGC/GG-3′ (“/” marks the cleavage position) and cuts it to generate 3′-staggered ends. The Eco29kI monomer, which contains a single active site, either has to nick sequentially individual DNA strands or has to form dimers or even higher-order oligomers upon DNA binding to make a double-strand break at its target site. Here, we provide experimental evidence that Eco29kI monomers dimerize on a single cognate DNA molecule forming the catalytically active complex. The mechanism described here for Eco29kI differs from that of Cfr42I isoschisomer, which also belongs to the GIY-YIG family but is functional as a tetramer. This novel mechanism may have implications for the function of homing endonucleases and other enzymes of the GIY-YIG family.     

Cloning of the gene of Saccharomyces cerevisiae yeasts that determines resistance to the toxic action of cadmium ions

A gene conferring resistance to cadmium in Saccharomyces cerevisiae was isolated from a yeast gene library created on the basis of the pL3 vector. The phenotype of resistance is only expressed in the yeast cells with cloned DNA inserted into a multicopy plasmid. Integration of the plasmid into chromosome or introduction of the centromeric region into the plasmid decreases the level of cadmium resistance. The cloned Sau3A I fragment of the yeast chromosome is 3.5 kbp in size. Restriction analysis and subcloning experiments showed the gene to be located within 1.6 kbp of the XhoI-Sau3A I fragment of DNA. Instability was observed in the vicinity of the XhoI-Sau3A I fragment of the yeast DNA in Escherichia coli.     

DNA synapsis through transient tetramerization triggers cleavage by Ecl18kI restriction enzyme

To cut DNA at their target sites, restriction enzymes assemble into different oligomeric structures. The Ecl18kI endonuclease in the crystal is arranged as a tetramer made of two dimers each bound to a DNA copy. However, free in solution Ecl18kI is a dimer. To find out whether the Ecl18kI dimer or tetramer represents the functionally important assembly, we generated mutants aimed at disrupting the putative dimer–dimer interface and analysed the functional properties of Ecl18kI and mutant variants. We show by atomic force microscopy that on two-site DNA, Ecl18kI loops out an intervening DNA fragment and forms a tetramer. Using the tethered particle motion technique, we demonstrate that in solution DNA looping is highly dynamic and involves a transient interaction between the two DNA-bound dimers. Furthermore, we show that Ecl18kI cleaves DNA in the synaptic complex much faster than when acting on a single recognition site. Contrary to Ecl18kI, the tetramerization interface mutant R174A binds DNA as a dimer, shows no DNA looping and is virtually inactive. We conclude that Ecl18kI follows the association model for the synaptic complex assembly in which it binds to the target site as a dimer and then associates into a transient tetrameric form to accomplish the cleavage reaction.     

Synthesis of mumps virus nucleocapsid protein in yeast Pichia pastoris

The expression of mumps virus nucleocapsid protein in yeast Pichia pastoris was investigated. Viral nucleocapsid proteins usually elicit a strong long-term humoral immune response in patients and experimental animals. Therefore, the detection of antibodies specific to mumps virus nucleoprotein can play an important role in immunoassays for mumps diagnosis. For producing a high-level of recombinant mumps virus nucleoprotein the expression system of yeast P. pastoris was employed. The recombinant nucleocapsid protein was purified by cesium chloride ultracentrifugation of yeast lysates. Electron microscopy of the purified recombinant nucleocapsid protein revealed a herring-bone structure similar to the one discovered in mammalian cells infected with mumps virus. The yield of purified nucleocapsid-like particles from P. pastoris constituted 2.1 mg per 1 g of wet biomass and was considerably higher in comparison to the other expression systems.