Cloning of the PYR3 gene of Ustilago maydis and its use in DNA transformation.

The Ustilago maydis PYR3 gene encoding dihydroorotase activity was cloned by direct complementation of Escherichia coli pyrC mutations. PYR3 transformants of E. coli pyrC mutants expressed homologous transcripts of a variety of sizes and regained dihydroorotase activity. PYR3 also complemented Saccharomyces cerevisiae ura4 mutations, and again multiple transcripts were expressed in transformants, and enzyme activity was regained. A 1.25-kilobase poly(rA)+ PYR3 transcript was detected in U. maydis itself. Linear DNA carrying the PYR3 gene transformed a U. maydis pyr3-1 pyrimidine auxotroph to prototrophy. Hybridization analysis revealed that three different types of transformants could be generated, depending on the structure of the transforming DNA used. The first type involved exchange of chromosomal mutant gene sequences with the cloned wild-type plasmid sequences. A second type had integrated linear transforming DNA at the chromosomal PYR3 locus, probably via a single crossover event. The third type had integrated transforming DNA sequences at multiple sites in the U. maydis genome. In the last two types, tandemly reiterated copies of the transforming DNA were found to have been integrated. All three types had lost the sensitivity of the parental pyr3-1 mutant to UV irradiation. They had also regained dihydroorotase activity, although its level did not correlate with the PYR3 gene copy number.

Sensitivity of Chinese hamster ovary mutants defective in DNA double strand break repair to topoisomerase II inhibitors.

xrs-1 is an ionizing radiation sensitive Chinese hamster ovary (CHO) strain and has a defect in double strand break rejoining. It is also highly sensitive to topoisomerase II inhibiting anticancer drugs. Sensitivity is specific for those drugs that inhibit the breakage/reunion mechanism of topoisomerase II. xrs-1 and its parent strain CHO-K1 have equal levels of topoisomerase II activity, assayed by their ability to unknot complex knotted P4 head DNA. Drug stimulated protein-DNA complex formation was similar in xrs-1 and CHO-K1, showing that they accrued equal levels of drug induced lesions. Thus sensitivity most likely results from subsequent differences in the processing of these lesions rather than the rate of formation. Drug sensitivity is directly related to the xrs phenotype since drug and gamma-ray resistance are coordinately reactivated by azacytidine treatment. All six members of the xrs complementation group are hypersensitive to etoposide. Sensitivity is not a feature common to all X-ray sensitive mutants but is shown by another complementation group, which also has a defect in double strand break rejoining. These results thus demonstrate a correlation between an inability to rejoin double strand breaks and sensitivity to topoisomerase II targeting antitumor drugs.

DNA ligase-AMP adducts: identification of yeast DNA ligase polypeptides.

Yeast DNA ligase is radioactively labelled in vitro by incubating a crude cell extract with [alpha-32P]ATP. The product of this reaction is the stable covalent ligase-AMP adduct, which can be characterized by its reactivity with either pyrophosphate or nicked DNA and visualized by gel electrophoresis and autoradiography. The Saccharomyces cerevisiae DNA ligase was identified as an 89 kDa polypeptide by exploiting the fact that transformants with multiple copies of the plasmid-encoded DNA ligase (CDC9) gene overproduce the enzyme by two orders of magnitude. A similar strategy has been used to identify the Schizosaccharomyces pombe DNA ligase as an 87 kDa polypeptide. Both values agree well with the coding capacities of the respective cloned gene sequences. When the S. cerevisiae ligase is greatly overproduced with respect to wild-type levels, a second polypeptide of 78.5 kDa is also labelled and has the same properties as the 89 kDa adduct. We suggest that this polypeptide is generated by proteolysis.

Structural and functional architecture of the yeast cell-cycle transcription factor swi6.

The structural and functional organisation of Swi6, a transcriptional regulator of the budding yeast cell cycle has been analysed by a combination of biochemical, biophysical and genetic methods. Limited proteolysis indicates the presence of a approximately 15 kDa N-terminal domain which is dispensable for Swi6 activity in vivo and which is separated from the rest of the molecule by an extended linker of at least 43 residues. Within the central region, a 141 residue segment that is capable of transcriptional activation encompasses a structural domain of approximately 85 residues. In turn, this is tightly associated with an adjacent 28 kDa domain containing at least four ankyrin-repeat (ANK) motifs. A second protease sensitive region connects the ANK domain to the remaining 30 kDa C-terminal portion of Swi6 which contains a second transcriptional activator and sequences required for heteromerisation with Swi4 or Mbp1. Transactivation by the activating regions of Swi6 is antagonised when either are combined with the central ankyrin repeat motifs. Hydrodynamic measurements indicate that an N-terminal 62 kDa fragment comprising the first three domains is monomeric in solution and exhibits an unusually high frictional coefficient consistent with the extended, multi-domain structure suggested by proteolytic analysis.

The Ustilago maydis pyr3 gene: sequence and transcriptional analysis.

The pyr3 gene of Ustilago maydis encodes a 391-amino acid (aa) polypeptide. The sequence has identifies with dihydro-orotases (DHOases) from other organisms, but is most related to sequences of other monofunctional enzymes. The polypeptide contains the three domains conserved in other DHOases. The polypeptide encoded by the pyr3-1 allele has an aa change seven residues away from the C-terminal conserved domain. Transcription start point (tsp) is 58 nucleotides upstream from the start codon, and is in a region characterised by CTTT and CATC motifs. In the absence of TATA and CAAT boxes, these motifs might be important in transcriptional regulation. Gene disruption experiments suggest that the pyr3 gene product might have another function in addition to that in pyrimidine biosynthesis.

The Ustilago maydis nar1 gene encoding nitrate reductase activity: sequence and transcriptional regulation.

The nar1 gene was cloned from Ustilago maydis and the 908-amino-acid (aa) sequence of the encoded protein found to have strong identities with other nitrate reductases from fungi and plants. This was especially so in three domains which define enzyme cofactor-binding sites. The gene was isolated alone and in association with the nir1 gene, suggesting that the two genes are closely linked on the chromosome. The phenotype of a strain in which nar1 had been disrupted was consistent with the only role of nar1 being in nitrate reduction. Nitrate ions induced a 90-fold increase in nar1 transcript levels, while ammonium ions repressed transcript levels.

Biosynthesis and activity of DNA polymerase throughout the mitotic cycle of Physarum polycephalum.

Measurements of DNA polymerase protein levels and polymerase activity through the naturally synchronous mitotic cycle of Physarum polycephalum show that active DNA polymerase-alpha is synthesized throughout the G2 phase, in step with the profile of general protein biosynthesis. Three main components of P. poly-cephalum DNA polymerase of 200, 112 and 70 kDa were found to be immunologically related.

Amines in the marking fluid and anal sac secretion of the tiger, Panthera tigris.

Analysis of the marking fluid of two tigers (one Bengal and one Sumatran) by GC using an amine-specific column and a nitrogen-specific detector has shown the presence of the following amines: ammonia, methylamine, dimethylamine, trimethylamine, triethylamine, propylamine, and butane-1,4-diamine (putrescine). In contrast to previously published reports, we were unable to detect 2-phenylethylamine. The anal sac secretion was found to have a similar amine content.

Transformation of Ustilago maydis by a plasmid containing yeast 2-micron DNA.

U. maydis has been transformed to aminoglycoside antibiotic resistance by plasmid pMP81 DNA, which contains the yeast LEU-2 gene and 2-micron DNA inserted into pCRI, encoding a gene for an aminoglycoside phosphotransferase. The resistant phenotype of transformants is mitotically unstable in the absence of antibiotics. Closed, circular pMP81 DNA was detected in transformant DNA preparations by hybridization to pCR1 DNA and by transformation of Escherichia coli to kanamycin resistance. Plasmid pMP81 DNA recovered from the transformant was not rearranged at the gross sequence level as a result of transmission in U. maydis. Preliminary evidence suggests that the yeast 2-micron DNA promotes autonomous plasmid replication in U. maydis, albeit inefficiently, resulting in low transformation frequencies and plasmid copy numbers.

Chromosomal DNA sequences from Ustilago maydis promote autonomous replication of plasmids in Saccharomyces cerevisiae.

U. maydis chromosomal DNA sequences which promote the autonomous replication of plasmid YIp5 in S. cerevisiae YNN27 have been isolated and three of them characterised in some detail. Their properties are idential to yeast ars sequences in that plasmids containing them are maintained extrachromosomally as circular double-stranded DNA molecules, are mitotically unstable in yeast transformants and transform yeast at high frequencies. There is no sequence homology between the three U. maydis sequences and they are not reiterated in the U. maydis genome.

Direct ATP photolabeling of Escherichia coli recA proteins: identification of regions required for ATP binding.

When the Escherichia coli RecA protein is UV irradiated in the presence of [alpha-32P]ATP, a labeled protein--ATP adduct is formed. All the experimental evidence indicates that, in forming such an adduct, the ATP becomes specifically immobilized in the catalytically relevant ATP binding site. The adduct can also be identified after irradiation of E. coli cell lysates in a similar manner. This direct ATP photolabeling of RecA proteins has been used to identify regions of the polypeptide chain involved in the binding of ATP. The photolabeling of a RecA protein that lacks wild-type carboxy-terminal amino acids is not detectable. A RecA protein in which the amino-terminal sequence NH2-Ala-Ile-Asp-Glu-Asn- is replaced by NH2-Thr-Met-Ile-Thr-Asn-Ser-Ser-Ser- is only about 5% as efficiently photolabeled as the wild-type protein. Both of these RecA protein constructions, however, contain all the elements previously implicated, directly or indirectly, in the binding of ATP. ATP-photolabeled RecA protein has also been chemically cleaved at specific amino acids in order to identify regions of the polypeptide chain to which the nucleotide becomes covalently photolinked. The evidence is consistent with a region comprising amino acids 116-170. Thus, this work and that of others suggest that several disparate regions of the unfolded polypeptide chain may combine to form the ATP binding site upon protein folding or may influence binding through long-range effects.

A DNA polymerase from Ustilago maydis. Evidence of proof-reading by the associated 3' leads to 5' deoxyribonuclease activity.

The 3' leads to 5' deoxyribonuclease activity associated with an Ustilago maydis DNA polymerase hydrolysed non-complementary 3'-primer termini about 12 times more rapidly than complementary termini. An analysis of its substrate specificity suggested that, although it was unable to hydrolyse fully single-stranded polynucleotides, it could hydrolyse such regions less than about four nucleotides in length covalently bound to a primer molecule which was base-paired to a complementary template strand. Template-primer combinations containing complementary or non-complementary primer termini both supported polynucleotide synthesis, but whereas the former were conserved, the latter were hydrolysed during the reaction thus allowing synthesis to occur. No addition of nucleotides onto a conserved non-complementary 3'-primer terminus was detected. The deoxyribonuclease activity therefore fulfilled a proof-reading function during DNA synthesis in vitro.

Further characterisation of a nucleic acid binding protein.

A glycoprotein which binds to nucleic acids has now been purified from Ustilago maydis until free from detectable deoxyribonuclease activity. It binds to a variety of substrates and in doing so, makes them soluble in dilute trichloroacetic acid. Physical studies suggest that it forms a variety of aggregates under low ionic strength, but at high ionic strength the monomer consists of a single polypeptide chain. Preliminary experiments have detected this novel binding activity in bacterial, fungal and mammalian cells.

DNA polymerase of Ustilago maydis: partial characterization of the enzyme and a pol 1 mutation.

The major DNA polymerase activity of wild-type U. maydis has been extensively purified. It possesses a molecular weight of about 150,000 daltons and appears to require a DNA primer with a 3'-hydroxyl terminus as well as a template. The polymerase activity has also been purified from the pol 1-1 strain, which is temperature sensitive fro growth and DNA synthesis, and which at the restrictive temperature contains only 10-25% levels of the DNA polymerase activity obtained from wild-type strains. It was similar in all properties studied, except that the activity was thermolabile at 40 degrees C compared to that from the wild-type strain. Physiological studies on the mutant showed that it was only slightly sensitive to UV, ionising radiation and nitrosoguanidine at the permissive temperature, and was proficient in genetic recombination. The results suggest that the pol 1-1 gene product does not play an important role in repair and recombination processes within the cell, and that its primary function lies in replication.

A DNA polymerase from Ustilago maydis. 2. Properties of the associated deoxyribonuclease activity.

The polymerase and deoxyribonuclease activities of the purified Ustilago maydis DNA polymerase coeluted from a hydroxyapatite column, cosedimented in sucrose gradients in both the absence and presence of salt, possessed similar thermolabilities and reaction requirements. These observations suggest that both activities are associated with the same enzyme and that the deoxyribonuclease activity is not a contaminant. The initial rate of degradation of native 3'-end-group-labelled DNA was similar to that of a heat-denatured substrate, but the final extent was greater for the former. The enzyme exhibits a high specificity for degradation of DNA in a 3' leads to 5' direction. The degradation of a DNA template was inhibited by the presence of the deoxyribonucleoside triphosphates necessary for simultaneous DNA synthesis, but not that of the newly synthesised DNA. About 50%, 29% and 13% of the purine, cytosine and thymine deoxyribonucleotide residues incorporated by the enzyme into DNA respectively, were subsequently excised when monitored by the resulting conversion of the triphosphate substrates to free monophosphate. The majority of the purine deoxyribonucleoside monophosphates appear after the synthetic phase of the reaction has ceased. In many respects, therefore, the deoxyribonuclease activity of the U. maydis DNA polymerase is similar to the bacteriophage T4-induced enzyme.