Purification and characterization of OBF1: a Saccharomyces cerevisiae protein that binds to autonomously replicating sequences

Novel DNA binding properties of the Mcm10 protein from Saccharomyces cerevisiae

The Mcm10 protein is essential for chromosomal DNA replication in eukaryotic cells. We purified the Saccharomyces cerevisiae Mcm10 (ScMcm10) and characterized its DNA binding properties. Electrophoretic mobility shift assays and surface plasmon resonance analysis showed that ScMcm10 binds stably to both double strand (ds) DNA and single strand (ss) DNA. On short DNA templates of 25 or 50 bp, surface plasmon resonance analysis showed a approximately 1:1 stoichiometry of ScMcm10 to dsDNA. On longer dsDNA templates, however, multiple copies of ScMcm10 cooperated in the rapid assembly of a large, stable nucleoprotein complex. The amount of protein bound was directly proportional to the length of the DNA, with an average occupancy spacing of 21-24 bp. This tight spacing is consistent with a nucleoprotein structure in which ScMcm10 is aligned along the helical axis of the dsDNA. In contrast, the stoichiometry of ScMcm10 bound to ssDNA of 20-50 nucleotides was approximately 3:1 suggesting that interaction with ssDNA induces the assembly of a multisubunit ScMcm10 complex composed of at least three subunits. The tight packing of ScMcm10 on dsDNA and the assembly of a multisubunit complex on ssDNA suggests that, in addition to protein-DNA, protein-protein interactions may be involved in forming the nucleoprotein complex. We propose that these DNA binding properties have an important role in (i) initiation of DNA replication and (ii) formation and maintenance of a stable replication fork during the elongation phase of chromosomal DNA replication.

Biochemical and genetic characterization of the dominant positive element driving transcription ofthe yeast TBP-encoding gene, SPT15

We previously demonstrated that a combination of both positive and negative cis -acting upstream elements control the transcription of the gene encoding TBP ( SPT15 ) in Saccharomyces cerevisiae . One of these elements found in that study, resident between 5' flanking sequences -147 and -128 , and termed PED (for positive element distal), was found to play an essential positive role in driving transcription of the gene encoding TBP. In this report, we map at nucleotide-level resolution, the critical residues which comprise PED, purify and sequence the protein that binds to it and determine that this PED binding factor is Abf1p, an abundant yeast protein previously broadly implicated in both gene regulation and DNA replication. In the case of the TBP-encoding gene, however, Abf1p works through the PED element which is a non-consensus binding site. Based upon the work of others, the PED-variant ABF1 site would be predicted to be a very poor binding site for this factor yet Abf1p binds PED and a consensus ABF1 site with comparable affinity. These results are discussed in light of the broader context of Abf1p-mediated gene regulation.

Functional analysis of a replication origin from Saccharomyces cerevisiae: identification of a new replication enhancer

Yeast replication origins have a modular arrangement of essential DNA sequences containing the ARS consensus sequence (ACS) flanked by auxiliary DNA elements which stimulate origin function. One of the auxiliary elements identified at several origins is a DNA replication enhancer that binds the Abf1p protein. We have isolated an ARS sequence from Saccharomyces cerevisiae based on its ability to bind Abf1p. Here we present a detailed molecular dissection of this ARS, designated ARS 1501, and we demonstrate that it functions as a genomic replication origin on chromosome XV . Mutagenesis of the Abf1p DNA-binding sites revealed that these sequences did not contribute significantly to ARS function. Instead, a new DNA element important for replication, designated REN1501, has been located 5' to the T-rich strand of the ACS. We show that REN1501 functions in either orientation and at variable distances from the ACS, defining this element as a DNA replication enhancer. Most significantly, point mutations within this element decreased the stability of plasmids bearing ARS 1501, suggesting that REN1501 binds a protein important for replication initiation. Only three elements found at origins are known to specifically bind proteins. These include the ARS essential sequences and the Abf1p and Rap1p DNA-binding sites. We show that the function of REN1501 at the origin cannot be replaced by a Rap1p DNA-binding site or a site that binds the transcriptional factor Gal4p and can only be partially substituted for by an Abf1p recognition sequence. This implies that the role of the REN1501 element at the ARS 1501 origin is specific, and suggest that the frequency of origin firing in eukaryotic cells may be regulated by origin-specific enhancers.

The Ku-like protein from Saccharomyces cerevisiae is required in vitro for the assembly of a stable multiprotein complex at a eukaryotic origin of replication

We have previously shown that three distinct DNA-binding activities, in crude form, are necessary for the ATP-dependent assembly of a specific and stable multiprotein complex at a yeast origin of replication. Here we show the purification of one of these DNA binding activities, referred to as origin binding factor 2 (OBF2). The purified protein is a heterodimer composed of two polypeptides with molecular mass values of 65 and 80 kDa as determined by SDS/PAGE. Purified OBF2 not only binds DNA but also supports the formation of a protein complex at essential sequences within the ARS121 origin of replication. Interestingly, OBF2 binds tightly and nonspecifically to both duplex DNA and single-stranded DNA. The interaction with duplex DNA occurs at the termini. N-terminal sequencing of the 65-kDa subunit has revealed that this polypeptide is identical to the previously identified HDF1 peptide, a yeast homolog of the small subunit of the mammalian Ku autoantigen. Although the potential involvement of Ku in DNA metabolic events has been proposed, this is the first requirement for a Ku-like protein in the assembly of a protein complex at essential sequences within a eukaryotic origin of replication.

Ease of DNA unwinding is a conserved property of yeast replication origins

Autonomously replicating sequence (ARS) elements function as plasmid replication origins. Our studies of the H4 ARS and ARS307 have established the requirement for a DNA unwinding element (DUE), a broad easily-unwound sequence 3' to the essential consensus that likely facilitates opening of the origin. In this report, we examine the intrinsic ease of unwinding a variety of ARS elements using (1) a single-strand-specific nuclease to probe for DNA unwinding in a negatively-supercoiled plasmid, and (2) a computer program that calculates DNA helical stability from the nucleotide sequence. ARS elements that are associated with replication origins on chromosome III are nuclease hypersensitive, and the helical stability minima correctly predict the location and hierarchy of the hypersensitive sites. All well-studied ARS elements in which the essential consensus sequence has been identified by mutational analysis contain a 100-bp region of low helical stability immediately 3' to the consensus, as do ARS elements created by mutation within the prokaryotic M13 vector. The level of helical stability is, in all cases, below that of ARS307 derivatives inactivated by mutations in the DUE. Our findings indicate that the ease of DNA unwinding at the broad region directly 3' to the ARS consensus is a conserved property of yeast replication origins.

At least three distinct proteins are necessary for the reconstitution of a specific multiprotein complex at a eukaryotic chromosomal origin of replication

We have reconstituted in vitro a multistage assembly of a protein complex that specifically recognizes a yeast genomic origin of replication, the autonomously replicating sequence ARS121. The first step in the assembly was the interaction of the known origin-binding factor OBF1 and another factor, OBF2, with the ARS121 origin of replication to form the OBF1-OBF2-origin complex. This complex was the substrate for the ATP-dependent binding of a third DNA-binding activity, the core binding factor, CBF. Binding of CBF to the origin, identified by the retarded mobility of the origin DNA fragment in agarose gels, required, in addition to ATP and the OBF1-OBF2-origin complex, a functional essential core nucleotide sequence. ARS121 DNA containing mutations in the core, which inactivate the origin in vivo, did not sustain stable CBF binding, whereas ARS121 DNA mutated outside the boundaries of the essential core, which has normal origin function, bound CBF as wild type. This tight, direct correlation between the ability of the origin to bind CBF and its function as an origin of replication in vivo strongly suggest that the multiprotein complex reconstituted in vitro has a key role in the initiation of DNA replication.

Role of multifunctional autonomously replicating sequence binding factor 1 in the initiation of DNA replication and transcriptional control in Saccharomyces cerevisiae

Autonomously replicating sequence (ARS) binding factor 1 (ABF1) is an abundant DNA-binding protein that specifically recognizes the motif RTCRYN5ACG at many sites in the yeast genome, including promoter elements, mating-type silencers, and ARSs. Mutational analysis of these sites suggests that ABF1 is involved in constitutive and carbon source-regulated transcriptional activation, transcriptional silencing, and ARS activity. To better assess the role of ABF1 in DNA replication and transcriptional control, temperature-sensitive lethal mutations in the ABF1 gene were isolated. Several of the abf1(Ts) strains show rapid growth arrest at the nonpermissive temperature. At the semipermissive temperature, these strains show an ARS-specific defect in the mitotic stability of ARS-CEN plasmids, such that the abf1 mutants show defects in ARS function identical to those of mutants bearing the mutations in the cis-acting ABF1 binding sites analyzed previously by numerous investigators. Flow cytometric analysis and in vivo DNA labeling experiments on an alpha-factor synchronized abf1(Ts) strain showed that at the nonpermissive temperature, these cells fail to progress efficiently from G1 through S phase and synthesize DNA at 25% of the level seen in the isogenic ABF1 strain. RNA synthesis is also reduced in the abf1(Ts) strains. In addition, transcriptional activation by an ABF1 binding site upstream activation sequence is completely defective in an abf1(Ts) strain at the semipermissive temperature. These phenotypes provide evidence that the same protein, ABF1, functions in the initiation of DNA replication and transcriptional activation.

Role of multifunctional autonomously replicating sequence binding factor 1 in the initiation of DNA replication and transcriptional control in Saccharomyces cerevisiae

Autonomously replicating sequence (ARS) binding factor 1 (ABF1) is an abundant DNA-binding protein that specifically recognizes the motif RTCRYN5ACG at many sites in the yeast genome, including promoter elements, mating-type silencers, and ARSs. Mutational analysis of these sites suggests that ABF1 is involved in constitutive and carbon source-regulated transcriptional activation, transcriptional silencing, and ARS activity. To better assess the role of ABF1 in DNA replication and transcriptional control, temperature-sensitive lethal mutations in the ABF1 gene were isolated. Several of the abf1(Ts) strains show rapid growth arrest at the nonpermissive temperature. At the semipermissive temperature, these strains show an ARS-specific defect in the mitotic stability of ARS-CEN plasmids, such that the abf1 mutants show defects in ARS function identical to those of mutants bearing the mutations in the cis-acting ABF1 binding sites analyzed previously by numerous investigators. Flow cytometric analysis and in vivo DNA labeling experiments on an alpha-factor synchronized abf1(Ts) strain showed that at the nonpermissive temperature, these cells fail to progress efficiently from G1 through S phase and synthesize DNA at 25% of the level seen in the isogenic ABF1 strain. RNA synthesis is also reduced in the abf1(Ts) strains. In addition, transcriptional activation by an ABF1 binding site upstream activation sequence is completely defective in an abf1(Ts) strain at the semipermissive temperature. These phenotypes provide evidence that the same protein, ABF1, functions in the initiation of DNA replication and transcriptional activation.

Analysis of the interactions of functional domains of a nuclear origin of replication from Saccharomyces cerevisiae

We have determined that ARS121 is an efficient origin of replication on chromosome X of Saccharomyces cerevisiae. This origin is comprised of at least three distinct functional domains. One of these domains is the ARS121 core sequence (approximately 35 bp-long), which is essential for origin activity. This essential core contains an 11 bp sequence resembling (2 bp mismatch) the ARS consensus. Another important domain is an enhancer of DNA replication, which binds the OBF1 protein. The third domain, ATR (A/T-rich, approximately 72 bp), is auxiliary and works in either orientation, but only when located 3' to the essential core. When fused to the ARS121 core both the enhancer and the ATR domain act synergistically to enhance the activity of the origin. Furthermore, when fused to the essential core sequences of heterologous ARSs, ARS1 and ARS307, the auxiliary domains also appeared to stimulate synergistically origin function. These results suggest that (i) in order to elicit maximal origin activity all three domains have to interact and (ii) activation of the essential core sequences at different origins of replication may share a common mechanism.

The multifunctional protein OBF1 is phosphorylated at serine and threonine residues in Saccharomyces cerevisiae

We have purified a DNA replication enhancer-binding protein, OBF1, from yeast cells grown in a medium containing 32P-labeled orthophosphate. The purified 32P-labeled protein comigrated on polyacrylamide gels with OBF1 bands identified by immunoblotting with anti-OBF1 antibodies. Furthermore, trypsin treatment of the 32P-labeled OBF1 revealed several phosphorylated peptides, suggesting that OBF1 is multiply phosphorylated in vivo. Incubation of phosphorylated peptides with calf intestinal phosphatase liberated the radiolabel as free phosphate, indicating a phosphoester linkage. Acid hydrolysis of the tryptic peptides revealed 32P-label label comigrating with phosphoserine; some of it, however, was also identified as phosphothreonine. Using anti-OBF1 antibodies, we cloned the OBF1 gene from a lambda gt11 yeast expression library. The DNA sequence of the isolated gene and its over-expression in yeast indicated that OBF1 is identical to ABF-1 and BAF1 proteins, believed to have a role in transcriptional repression and activation. Therefore, we suggest that OBF1 is a multifunctional protein, acting in transcription and replication, and that these activities are regulated by phosphorylation.

rar mutations which increase artificial chromosome stability in Saccharomyces cerevisiae identify transcription and recombination proteins

In an attempt to identify trans-acting factors involved in replication origin function, we have characterized the RAR3 and RAR5 genes, identified by mutations which increase the mitotic stability of artificial chromosomes whose replication is dependent on the activity of weak ARS elements. Sequence analysis has shown that the RAR3 gene is identical to GAL11/SPT13, which encodes a putative transcription factor involved in the expression of a wide range of genes. Change-of-function mutations that truncate the RAR3 protein appear to be required to enhance chromosome stability. In contrast, loss of the RAR5 protein results in enhanced chromosome stability, as if the protein is an inhibitor of ARS function. The RAR5 gene encodes the 175 kDa DNA strand transfer protein beta, an activity that can promote the transfer of a strand from a double-stranded DNA molecule to a complementary single strand. This observation implies that a presumed recombination activity can affect eukaryotic chromosomal replication.

The phenotype of the minichromosome maintenance mutant mcm3 is characteristic of mutants defective in DNA replication

MCM3 is an essential gene involved in the maintenance of minichromosomes in yeast cells. It encodes a protein of 971 amino acids that shows striking homology to the Mcm2 protein. We have mapped the mcm3-1 mutation of the left arm of chromosome V approximately 3 kb centromere proximal of anp1. The mcm3-1 mutant was found to be thermosensitive for growth. Under permissive growth conditions, it was defective in minichromosome maintenance in an autonomously replicating sequence-specific manner and showed an increase in chromosome loss and recombination. Under nonpermissive conditions, mcm3-1 exhibited a cell cycle arrest phenotype, arresting at the large-bud stage with an undivided nucleus that had a DNA content of nearly 2n. These phenotypes are consistent with incomplete replication of the genome of the mcm3-1 mutant, possibly as a result of limited replication initiation at selective autonomously replicating sequences leading to cell cycle arrest before mitosis. The phenotype exhibited by the mcm3 mutant is very similar to that of mcm2, suggesting that the Mcm2 and Mcm3 protein may play interacting roles in DNA replication.

The phenotype of the minichromosome maintenance mutant mcm3 is characteristic of mutants defective in DNA replication

MCM3 is an essential gene involved in the maintenance of minichromosomes in yeast cells. It encodes a protein of 971 amino acids that shows striking homology to the Mcm2 protein. We have mapped the mcm3-1 mutation of the left arm of chromosome V approximately 3 kb centromere proximal of anp1. The mcm3-1 mutant was found to be thermosensitive for growth. Under permissive growth conditions, it was defective in minichromosome maintenance in an autonomously replicating sequence-specific manner and showed an increase in chromosome loss and recombination. Under nonpermissive conditions, mcm3-1 exhibited a cell cycle arrest phenotype, arresting at the large-bud stage with an undivided nucleus that had a DNA content of nearly 2n. These phenotypes are consistent with incomplete replication of the genome of the mcm3-1 mutant, possibly as a result of limited replication initiation at selective autonomously replicating sequences leading to cell cycle arrest before mitosis. The phenotype exhibited by the mcm3 mutant is very similar to that of mcm2, suggesting that the Mcm2 and Mcm3 protein may play interacting roles in DNA replication.

Molecular cloning of a gene encoding an ARS binding factor from the yeast Saccharomyces cerevisiae

We report the isolation of the gene for origin binding factor 1 (OBF1) from the yeast Saccharomyces cerevisiae by screening a yeast genomic DNA library in lambda gt11 with an ARS-specific oligonucleotide probe. One recombinant encoded a fusion protein of approximately 180 kDa that bound ARS-specific oligonucleotide probes in vitro. The restriction map of this gene was determined after isolation of the complete gene by screening a yeast genomic DNA library in YEp24. Characterization of the gene for OBF1 by pulsed-field gel electrophoresis and Northern and Southern blot analyses demonstrated that (i) the gene is located in chromosome IV, (ii) the gene is a single-copy gene, (iii) the mRNA is approximately 3.8 kilobases, which could code for an approximately 130-kDa polypeptide, consistent with the reported size of OBF1. An antibody, affinity-purified using the lysogen-encoded fusion protein, specifically detected an approximately 130-kDa polypeptide in yeast extract. The isolation of the gene for OBF1 should allow further analysis of the mechanism of action of this protein in vitro and in vivo.

A DNA replication enhancer in Saccharomyces cerevisiae

We have dissected the autonomously replicating sequence ARS121 using site-directed in vitro mutagenesis. Three domains important for origin function were identified; one of these is essential and contains an 11-base-pair sequence resembling the canonical ARS core consensus; the second region, deletion of which affects the efficiency of the origin, is located 3' to the T-rich strand of the essential sequence and encompasses several elements with near matches to the ARS core consensus; the third region, containing two OBF1 DNA-binding sites and located 5' to the essential sequence, also affects the efficiency of the ARS. Here we demonstrate that a synthetic OBF1 DNA-binding site can substitute for the entire third domain in origin function. A dimer of the synthetic binding site, fused to a truncated origin containing only domains one and two, restored the origin activity to the levels of the wild-type ARS. The stimulation of origin function by the synthetic binding site was relatively orientation independent and could occur at distances as far as 1 kilobase upstream to the essential domain. Based on these results we conclude that the OBF1 DNA-binding site is an enhancer of DNA replication. We suggest that the DNA-binding site and the OBF1 protein are involved in the regulation of the activation of nuclear origins of replication in Saccharomyces cerevisiae.

ARS binding factor I of the yeast Saccharomyces cerevisiae binds to sequences in telomeric and nontelomeric autonomously replicating sequences

We have analyzed various autonomously replicating sequences (ARSs) in yeast nuclear extract with ARS-specific synthetic oligonucleotides. The EI oligonucleotide sequence, which is derived from HMRE-ARS, and the F1 oligonucleotide sequence, which is derived from telomeric ARS120, appeared to bind to the same cellular factor with high specificity. In addition, each of these oligonucleotides was a competitive inhibitor of the binding of the other. Binding of the ARS binding factor (ABF) to either of these oligonucleotides was inhibited strongly by plasmids containing ARS1 and telomeric TF1-ARS. DNase I footprinting analyses with yeast nuclear extract showed that EI and F1 oligonucleotides eliminated protection of the binding site of ARS binding factor I (ABFI) in domain B of ARS1. Sequence analyses of various telomeric (ARS120 and TF1-ARS) and nontelomeric ARSs (ARS1 and HMRE-ARS) showed the presence of consensus ABFI binding sites in the protein binding domains of all of these ARSs. Consequently, the ABFI and ABFI-like factors bind to these domain B-like sequences in a wide spectrum of ARSs, both telomeric and nontelomeric.

ARS binding factor I of the yeast Saccharomyces cerevisiae binds to sequences in telomeric and nontelomeric autonomously replicating sequences

We have analyzed various autonomously replicating sequences (ARSs) in yeast nuclear extract with ARS-specific synthetic oligonucleotides. The EI oligonucleotide sequence, which is derived from HMRE-ARS, and the F1 oligonucleotide sequence, which is derived from telomeric ARS120, appeared to bind to the same cellular factor with high specificity. In addition, each of these oligonucleotides was a competitive inhibitor of the binding of the other. Binding of the ARS binding factor (ABF) to either of these oligonucleotides was inhibited strongly by plasmids containing ARS1 and telomeric TF1-ARS. DNase I footprinting analyses with yeast nuclear extract showed that EI and F1 oligonucleotides eliminated protection of the binding site of ARS binding factor I (ABFI) in domain B of ARS1. Sequence analyses of various telomeric (ARS120 and TF1-ARS) and nontelomeric ARSs (ARS1 and HMRE-ARS) showed the presence of consensus ABFI binding sites in the protein binding domains of all of these ARSs. Consequently, the ABFI and ABFI-like factors bind to these domain B-like sequences in a wide spectrum of ARSs, both telomeric and nontelomeric.

The OBF1 protein and its DNA-binding site are important for the function of an autonomously replicating sequence in Saccharomyces cerevisiae

The autonomously replicating sequence ARS121 was cloned as a 480-base-pair (bp) long DNA fragment that confers on plasmids autonomous replication in Saccharomyces cerevisiae. This fragment contains two OBF1-binding sites (sites I and II) of different affinities, as identified by a gel mobility shift assay and footprint analysis. Nucleotide substitutions (16 to 18 bp) within either of the two sites obliterated detectable in vitro OBF1 binding to the mutagenized site. Linker substitution (6 bp) mutations within the high-affinity site I showed effects similar to those of the complete substitution, whereas DNA mutagenized outside the binding site bound OBF1 normally. We also tested the mitotic stability of centromeric plasmids bearing wild-type and mutagenized copies of ARS121. Both deletion of the sites and the extensive base alterations within either of the two OBF1-binding sites reduced the percentage of plasmid-containing cells in the population from about 88% to 50 to 63% under selective growth and from about 46% to 15 to 20% after 10 to 12 generations of nonselective growth. Furthermore, linker (6 bp) substitutions within site I, the high-affinity binding site, showed similar deficiencies in plasmid stability. In contrast, plasmids containing linker substitutions in sequences contiguous to site I displayed wild-type stability. In addition, plasmid copy number analysis indicated that the instability probably resulted not from nondisjunction during mitosis but rather from inefficient plasmid replication. The results strongly support the notion that the OBF1-binding sites and the OBF1 protein are important for normal ARS function as an origin of replication.

The OBF1 protein and its DNA-binding site are important for the function of an autonomously replicating sequence in Saccharomyces cerevisiae

The autonomously replicating sequence ARS121 was cloned as a 480-base-pair (bp) long DNA fragment that confers on plasmids autonomous replication in Saccharomyces cerevisiae. This fragment contains two OBF1-binding sites (sites I and II) of different affinities, as identified by a gel mobility shift assay and footprint analysis. Nucleotide substitutions (16 to 18 bp) within either of the two sites obliterated detectable in vitro OBF1 binding to the mutagenized site. Linker substitution (6 bp) mutations within the high-affinity site I showed effects similar to those of the complete substitution, whereas DNA mutagenized outside the binding site bound OBF1 normally. We also tested the mitotic stability of centromeric plasmids bearing wild-type and mutagenized copies of ARS121. Both deletion of the sites and the extensive base alterations within either of the two OBF1-binding sites reduced the percentage of plasmid-containing cells in the population from about 88% to 50 to 63% under selective growth and from about 46% to 15 to 20% after 10 to 12 generations of nonselective growth. Furthermore, linker (6 bp) substitutions within site I, the high-affinity binding site, showed similar deficiencies in plasmid stability. In contrast, plasmids containing linker substitutions in sequences contiguous to site I displayed wild-type stability. In addition, plasmid copy number analysis indicated that the instability probably resulted not from nondisjunction during mitosis but rather from inefficient plasmid replication. The results strongly support the notion that the OBF1-binding sites and the OBF1 protein are important for normal ARS function as an origin of replication.