Correction of the mutation responsible for sickle cell anemia by an RNA-DNA oligonucleotide.

A chimeric oligonucleotide composed of DNA and modified RNA residues was used to direct correction of the mutation in the hemoglobin betaS allele. After introduction of the chimeric molecule into lymphoblastoid cells homozygous for the betaS mutation, there was a detectable level of gene conversion of the mutant allele to the normal sequence. The efficient and specific conversion directed by chimeric molecules may hold promise as a therapeutic method for the treatment of genetic diseases.

Cloning and disruption of Ustilago maydis genes.

We have demonstrated that genes from Ustilago maydis can be cloned by direct complementation of mutants through the use of genomic libraries made in a high-frequency transformation vector. We isolated a gene involved in amino acid biosynthesis as an illustrative example and showed that integrative and one-step disruption methods can be used to create null mutations in the chromosomal copy of the gene by homologous recombination. The results of this investigation make it clear that one-step gene disruption will be of general utility in investigations of U. maydis, since simple, precise replacement of the sequence under study was readily achieved.

A DNA-binding protein from Ustilago maydis prefers duplex DNA without chain interruptions.

Using a nitrocellulose filter binding assay, we have partially purified a protein from mitotic cells of Ustilago maydis that binds preferentially to covalently closed circular duplex DNA. DNA containing single- or double-strand breaks is bound poorly by the protein. Once formed, the DNA-protein complex is stable, resisting dissociation in high salt. However, when a DNA strand is broken, the complex appears to dissociate. The protein binds equally well to form I DNA of phi X174 or the plasmid pBR322, but has a higher affinity for a hybrid plasmid containing a cloned region of Drosophila melanogaster satellite DNA.

Isolation and characterization of an autonomously replicating sequence from Ustilago maydis.

DNA fragments that function as autonomously replicating sequences (ARSs) have been isolated from Ustilago maydis. When inserted into an integrative transforming vector, the fragments increased the frequency of U. maydis transformation several-thousandfold. ARS-containing plasmids were transmitted in U. maydis as extrachromosomal elements through replication. They were maintained at a level of about 25 copies per cell but were mitotically unstable. One ARS characterized in detail, which we called UARS1, was localized to a 1.7-kilobase fragment. UARS1 contained a cluster of active sequences. This element could be reduced further into three separate subfragments, each of which retained ARS activity. The smallest one was 383 base pairs (bp) long. Although not active itself in yeast, this small fragment contained seven 8-bp direct repeats, two contiguous 30-bp direct repeats, and five 11-bp units in both orientations with sequences similar but not identical to the consensus sequence found to be crucial for ARS activity in Saccharomyces cerevisiae.

Structure of REC2, a recombinational repair gene of Ustilago maydis, and its function in homologous recombination between plasmid and chromosomal sequences.

Mutation in the REC2 gene of Ustilago maydis leads to defects in DNA repair, recombination, and meiosis. Analysis of the primary sequence of the Rec2 protein reveals a region with significant homology to bacterial RecA protein and to the yeast recombination proteins Dmc1, Rad51, and Rad57. This homologous region in the U. maydis Rec2 protein was found to be functionally sensitive to mutation, lending support to the hypothesis that Rec2 has a functional RecA-like domain essential for activity in recombination and repair. Homologous recombination between plasmid and chromosomal DNA sequences is reduced substantially in the rec2 mutant following transformation. The frequency can be restored to a level approaching, but not exceeding, that observed in the wild-type strain if transformation is performed with cells containing multiple copies of REC2.

The REC2 gene encodes the homologous pairing protein of Ustilago maydis.

Amino acid sequence analysis has established that the homologous pairing protein of Ustilago maydis, known previously in the literature as rec1, is encoded by REC2, a gene essential for recombinational repair and meiosis with regional homology to Escherichia coli RecA. The 70-kDa rec1 protein is most likely a proteolytic degradation product of REC2, which has a predicted mass of 84 kDa but which runs anomalously during sodium dodecyl sulfate-gel electrophoresis with an apparent mass of 110 kDa. To facilitate purification of the protein product, the REC2 gene was overexpressed from a vector that fused a hexahistidine leader sequence onto the amino terminus, enabling isolation of the REC2 protein on an immobilized metal affinity column. The purified protein exhibits ATP-dependent DNA renaturation and DNA-dependent ATPase activities, which were reactions characteristic of the protein as purified from cell extracts of U. maydis. Homologous pairing activity was established in an assay that measures recognition via non-Watson-Crick bonds between identical DNA strands. A size threshold of about 50 bp was found to govern pairing between linear duplex molecules and homologous single-stranded circles. Joint molecule formation with duplex DNA well under the size threshold was efficiently catalyzed when one strand of the duplex was composed of RNA. Linear duplex molecules with hairpin caps also formed joint molecules when as few as three RNA residues were present.

Mutation avoidance and DNA repair proficiency in Ustilago maydis are differentially lost with progressive truncation of the REC1 gene product.

The REC1 gene of Ustilago maydis has an uninterrupted open reading frame, predicted from the genomic sequence to encode a protein of 522 amino acid residues. Nevertheless, an intron is present, and functional activity of the gene in mitotic cells requires an RNA processing event to remove the intron. This results in a change in reading frame and production of a protein of 463 amino acid residues. The 3'-->5' exonuclease activity of proteins derived from the REC1 genomic open reading frame, the intronless open reading frame, and several mutants was investigated. The mutants included a series of deletions constructed by removing restriction fragments at the 3' end of the cloned REC1 gene and a set of mutant alleles previously isolated in screens for radiation sensitivity. All of these proteins were overproduced in Escherichia coli as N-terminal polyhistidine-tagged fusions that were subsequently purified by immobilized metal affinity chromatography and assayed for 3'-->5' exonuclease activity. The results indicated that elimination of the C-terminal third of the protein did not result in a serious reduction in 3'-->5' exonuclease activity, but deletion into the midsection caused a severe loss of activity. The biological activity of the rec1-1 allele, which encodes a truncated polypeptide with full 3'-->5' exonuclease activity, and the rec1-5 allele, which encodes a more severely truncated polypeptide with no exonuclease activity, was investigated. The two mutants were equally sensitive to the lethal effect of UV light, but the spontaneous mutation rate was elevated 10-fold over the wild-type rate in the rec1-1 mutant and 100-fold in the rec1-5 mutant. The elevated spontaneous mutation rate correlated with the ablation of exonuclease activity, but the radiation sensitivity did not. These results indicate that the C-terminal portion of the Rec1 protein is not essential for exonuclease activity but is crucial in the role of REC1 in DNA damage repair.

Properties of a purified nuclear topoisomerase from L1210 cells.

A nuclear type I topoisomerase from mouse leukemia L1210 cells has been partially purified and characterized. The sedimentation coefficient of the enzyme by velocity sedimentation is 4.3 S, consistent with a globular protein of 68 kDa. Enzyme activity is stimulated 20-fold in the presence of magnesium over that achieved in KCl alone. The enzyme is completely inhibited in the presence of the berenil congeners HOE 13548 and 15030 while berenil itself caused only partial inhibition at concentrations below 200 micrograms/ml. An acid soluble protein of 30 kDa (by SDS-polyacrylamide gel electrophoresis) co-purified with the topoisomerase but could be separated by precipitation in a low salt buffer. This protein, as well as a protein of similar characteristics, histone H1, stimulated topoisomerase activity over a narrow concentration range. The role of topoisomerase in the DNA strand scission observed in L1210 cells following exposure to intercalating agents remains conjectural as the purified enzyme did not produce nicks in plasmid DNA in the presence of adriamycin.

DNA relaxation mediated by Ustilago maydis type I topoisomerase; modulation by chromatin associated proteins.

Ustilago maydis topoisomerase I relaxes superhelical DNA in the absence of any co-factors. The reaction reaches a defined end-point proportional to the amount of enzyme added and an analysis of the reaction by Hill plot transformation indicates that at least two molecules of topoisomerase must interact with the DNA to catalyze relaxation. The addition of purified Ustilago histone H1 reduces the stoichiometric amount of topoisomerase I required by 50%. H1 histone may function to enhance DNA relaxation through a cooperative mechanism. The purified HMG-like protein from Ustilago also enhances DNA relaxation mediated by the topoisomerase. Whereas H1 stimulates topo I-mediated DNA relaxation through a processive mode, the HMG-like protein enhances through a distributive mechanism. Taken together, these results demonstrate that the interaction of chromosomal proteins with topoisomerase can influence DNA topology, and mechanisms are proposed to explain this enhancement.

Extrachromosomal recombination is deranged in the rec2 mutant of Ustilago maydis.

Transformation of a leu1 auxotroph of Ustilago maydis to prototrophy with an autonomously replicating plasmid containing the selectable LEU1 gene was found to be efficient regardless of whether the transforming DNA was circular or linear. When pairs of autonomously replicating plasmids bearing noncomplementing leu1 alleles were used to cotransform strains deleted entirely for the genomic copy of the LEU1 gene, Leu+ transformants were observed to arise by extrachromosomal recombination. The frequency of recombination increased severalfold when one plasmid of the pair was made linear by cleavage at one end of the leu1 gene, but increased 10-100-fold when both plasmids were first made linear. The increase in recombination noted in wild-type and rec1 strains was not apparent in the rec2 mutant unless the members of the pair of plasmids were cut at opposite ends of the leu1 gene to yield linear molecules offset in only one of the two possible configurations. Use of a pair of plasmid substrates designed to measure nonreciprocal and multiple exchange events revealed only a minor fraction of the total events arise through these modes, and further that no stimulation occurred when the plasmid DNA was linear. It is unlikely that the defect in rec2 lies in a mismatch correction step since a high yield of Leu+ recombinants was obtained from the rec2 mutant when it was transformed with heteroduplex DNA constructed from plasmids with the two different leu1 alleles.

Pathways of transformation in Ustilago maydis determined by DNA conformation.

Ustilago maydis was transformed by plasmids bearing a cloned, selectable gene but lacking an autonomously replicating sequence. Transformation was primarily through integration at nonhomologous loci when the plasmid DNA was circular. When the DNA was made linear by cleavage within the cloned gene, the spectrum of integration events shifted from random to targeted recombination at the resident chromosomal allele. In a large fraction of the transformants obtained using linear DNA, the plasmid DNA was not integrated but was maintained in an extrachromosomal state composed of a concatameric array of plasmid units joined end-to-end. The results suggest the operation of several pathways for transformation in U. maydis, and that DNA conformation at the time of transformation governs choice of pathways.

Interaction between Ustilago maydis REC2 and RAD51 genes in DNA repair and mitotic recombination.

A gene encoding a Ustilago maydis Rad51 orthologue has been isolated, rad51-1, a mutant constructed by disrupting the gene, was as sensitive to killing by ultraviolet light and gamma radiation as the rec2-1 mutant and slightly more sensitive to killing by methyl methanesulfonate. There was no suppression of killing by ultraviolet light when a rec2-1 strain was transformed with a multicopy plasmid containing RAD51, nor was there suppression when rad51-1 was transformed with a multicopy plasmid containing REC2. Recombination proficiency as measured by a gap repair assay was diminished in both rec2-1 and rad51-1 strains. In rec2-1 the frequency of recombination was decreased, but the spectrum of events was similar to that observed in wild type, while in rad51-1 the frequency as well as the spectrum of recombination events were different. Studies with the rec2-1 rad51-1 double mutant indicated that there was epistasis in the action of REC2 and RAD51 in certain repair and recombination functions, but some measure of independent action in other functions.

The REC1 gene of Ustilago maydis, which encodes a 3'-->5' exonuclease, couples DNA repair and completion of DNA synthesis to a mitotic checkpoint.

Mutation in the REC1 gene of Ustilago maydis results in extreme sensitivity to killing by ultraviolet light. The lethality of the rec1-1 mutant was found to be partially suppressed if irradiated cells were held artificially in G2-phase by addition of a microtubule inhibitor. This mutant was also found to be sensitive to killing when DNA synthesis was inhibited by external means through addition of hydroxyurea or by genetic control in a temperature-sensitive mutant strain defective in DNA synthesis. Flow cytometric analysis of exponentially growing cultures indicated that wild-type cells accumulated in G2 after UV irradiation, while rec1-1 cells appeared to exit from G2 and accumulate in G1/S. Analysis of mRNA levels in synchronized cells indicated that the REC1 gene is periodically expressed with the cell cycle and reaches maximal levels at G1/S. The results are interpreted to mean that a G2-M checkpoint is disabled in the rec1-1 mutant. It is proposed that the REC1 gene product functions in a surveillance system operating during S-phase and G2 to find and repair stretches of DNA with compromised integrity and to communicate with the cell cycle apparatus.

Isolation of the REC2 gene controlling recombination in Ustilago maydis.

The rec2 mutant of Ustilago maydis is defective in DNA repair, induced allelic recombination, and meiosis. We cloned the REC2 gene by complementing the radiation-sensitive phenotype of the mutant using a genomic DNA library. The transcript of the REC2 gene was identified as a 2.8-kb damage-inducible RNA.

The LEU1 gene of Ustilago maydis.

The nucleotide sequence of the Ustilago maydis LEU1 gene has been determined. It contains a continuous open reading frame predicted to encode a protein of 773 amino acids with a molecular mass of 83,234 Da. The protein is homologous to alpha-isopropylmalate isomerases from prokaryotes and eukaryotes, as well as to other members of a family of structurally related isomerases.

Isolation of the REC1 gene controlling recombination in Ustilago maydis.

Previous studies on the rec1 mutant of Ustilago maydis revealed a complex phenotype. The mutant was found to be defective in DNA repair, recombination, growth, mutagenesis, and meiosis. We cloned the REC1 gene by complementing the phenotype of the mutant using a genomic DNA library made in a replicating vector and provided proof of identity by one-step gene disruption of the wild-type (wt) REC1 locus with a mutant allele constructed in vitro. The transcript of the REC1 gene was identified as a damage-inducible 1.7-kb RNA. After UV irradiation, the level of the transcript was observed to rise ten- to 15-fold. In the rec1 mutant, the basal level of the 1.7-kb transcript was tenfold lower than in wt. In addition, a second transcript of 1.1 kb was noted in rec1-1 cells in response to DNA damage.

A protein from Ustilago which forms an acid-soluble complex with deoxyribonucleic acid.

A protein which can render DNA largely acid-soluble has been purified 1600-fold from high salt extracts of Ustilago maydis. The activity is unusual in that substrate DNA is not made acid-soluble through hydrolysis to small oligomers. Rather, the protein appears to bind to DNA to form a complex which itself is acid-soluble. The activity of conversion of DNA to an acid-soluble form is cold-labile, but the inactivation by cold is reversible by brief heat treatment. Divalent cations stimulate the activity; phosphate is inhibitory. Optimal activity is observed at pH 6.0 and again at pH 9.0. Nucleoside triphosphates and diphosphates stimulate activity at low protein concentrations but are not hydrolyzed during the course of reaction. The protein behaves anomalously on gel filtration columns and is completely excluded by Sephadex or agarose gels. When analyzed by sedimentation velocity, the protein was found to sediment at 5.3 S, the same rate at which a globular protein of 65,000 daltons would sediment. Dependence of activity upon protein concentrations is sigmoidal. K+ and to a lesser degree NH4+ are partially effective in abolishing the lag in the concentration curve. The protein displays a saturation curve when exposed to increasing DNA concentrations. Such a curve could only result from a non-random or cooperative mode of binding of the protein to DNA. A mutant sensitive to gamma and ultraviolet radiation with an abnormally high level of the protein has been found. Haploid populations of the mutant grow slowly and contain a large proportion (10 to 20%) of inviable cells. Diploids are defective in mitotic allelic recombination and fail to complete meiosis. It is speculated that the protein may be important in the regulation of chromosome condensation.

Heteroduplex formation and polarity during strand transfer promoted by Ustilago rec 1 protein.

Ustilago rec1 protein promotes formation of joint molecules between circular strands and linear duplex DNA in two stages. During the first stage--synapsis--ATP, or the nonhydrolyzable analog adenylyl-imidodiphosphate, is a necessary cofactor in the formation of complexes. During the second stage--strand exchange--transfer of the circular single strand to the duplex appears to require energy derived from ATP hydrolysis. Rec1-promoted strand exchange is driven in a unique direction. Circular plus strand pairs with the 5' end of its complement in the linear duplex molecule. The 3' end of the plus strand is displaced from the duplex as the circle rolls in.