I-Sce III an intron-encoded DNA endonuclease from yeast mitochondria. Asymmetrical DNA binding properties and cleavage reaction

Engineering variants of the I-SceI homing endonuclease with strand-specific and site-specific DNA-nicking activity

The number of strand-specific nicking endonucleases that are currently available for laboratory procedures and applications in vivo is limited, and none is sufficiently specific to nick single target sites within complex genomes. The extreme target specificity of homing endonucleases makes them attractive candidates for engineering high-specificity nicking endonucleases. I-SceI is a monomeric homing enzyme that recognizes an 18 bp asymmetric target sequence, and cleaves both DNA strands to leave 3'-overhangs of 4 bp. In single turnover experiments using plasmid substrates, I-SceI generates transient open circle intermediates during the conversion of supercoiled to linear DNA, indicating that the enzyme cleaves the two DNA strands sequentially. A novel hairpin substrate was used to demonstrate that although wild-type I-SceI cleaves either the top or bottom DNA strand first to generate two nicked DNA intermediates, the enzyme has a preference for cleaving the bottom strand. The kinetics data are consistent with a parallel sequential reaction mechanism. Substitution of two pseudo-symmetric residues, Lys122 and Lys223, markedly reduces top and bottom-strand cleavage, respectively, to generate enzymes with significant strand- and sequence-specific nicking activity. The two active sites are partially interdependent, since alterations to one site affect the second. The kinetics analysis is consistent with X-ray crystal structures of I-SceI/DNA complexes that reveal a role for the lysines in establishing important solvent networks that include nucleophilic water molecules thought to attack the scissile phosphodiester bonds.

Degradation of DNA during the autolysis of Saccharomyces cerevisiae

The autolysis of yeast cells has practical implications in the production of fermented foods and beverages and flavourants for food processing. Protein and RNA degradation during yeast autolysis are well described but the fate of DNA is unclear. Yeast cells ( Saccharomyces cerevisiae) were autolysed by incubating suspensions at 30-60 degrees C (pH 7.0), and at pH 4.0-7.0 (40 degrees C) for 10-14 days. Up to 55% of total DNA was degraded, with consequent leakage into the extracellular environment of mainly 3'- and 5'-deoxyribonucleotides, and lesser amounts of polynucleotides. The rate and extent of DNA degradation, composition of the DNA degradation products and DNase activity were affected by temperature and pH. The highest amount of DNA degradation occurred at 40 degrees C and pH 7.0, where the highest DNase activity was recorded. DNase activity was lowest at 60 degrees C and pH 4.0, where the proportion of polynucleotides in the degradation products was higher.

Functional characterization of isoschizomeric His-Cys box homing endonucleases from Naegleria

Several species within the amoeboflagellate genus Naegleria harbor an optional ORF containing group I introns in their nuclear small subunit ribosomal DNA. The different ORFs encode homing endonucleases with 65 to 95% identity at the amino-acid level. I-NjaI, I-NanI and I-NitI, from introns in Naegleria jamiesoni, N. andersoni and N. italica, respectively, were analyzed in more detail and found to be isoschizomeric endonucleases that recognize and cleave an approximal 19-bp partially symmetrical sequence, creating a pentanucleotide 3' overhang upon cleavage. The optimal conditions for cleavage activity with respect to temperature, pH, salt and divalent metal ions were investigated. The optimal cleavage temperature for all three endonucleases was found to be 37 degrees C and the activity was dependent on the concentration of NaCl with an optimum at 200 mM. Divalent metal ions, primarily Mg2+, are essential for Naegleria endonuclease activity. Whereas both Mn2+ and Ca2+ could substitute for Mg2+, but with a slower cleavage rate, Zn2+ was unable to support cleavage. Interestingly, the pH dependence of DNA cleavage was found to vary significantly between the I-NitI and I-NjaI/I-NanI endonucleases with optimal pH values at 6.5 and 9, respectively. Site-directed mutagenesis of conserved I-NjaI residues strongly supports the hypothesis that Naegleria homing endonucleases share a similar zinc-binding structure and active site with the His-Cys box homing endonuclease I-PpoI.

I-PpoI and I-CreI homing site sequence degeneracy determined by random mutagenesis and sequential in vitro enrichment

Plasmid libraries containing partially randomized cleavage sites for the eukaryotic homing endonucleases I-PpoI and I-CreI were constructed, and sites that could be cleaved by I-PpoI or I-CreI were selectively recovered by successive cycles of cleavage and gel separation followed by religation and growth in Escherichia coli. Twenty-one different I-PpoI-sensitive homing sites, including the native homing site, were isolated. These sites were identical at four nucleotide positions within the 15 bp homing site, had a restricted pattern of base substitutions at the remaining 11 positions and displayed a preference for purines flanking the top strand of the homing site sequence. Twenty-one different I-CreI-sensitive homing sites, including the native site, were isolated. Ten nucleotide positions were identical in homing site variants that were I-CreI-sensitive and required the addition of SDS for efficient cleavage product release. Four of these ten positions were identical in homing sites that did not require SDS for product release. There was a preference for pyrimidines flanking the top strand of the homing site sequence. Three of the 24 I-CreI homing site nucleotide positions apparently lacked informational content, i. e. were permissive of cleavage when occupied by any nucleotide. These results suggest that I-PpoI and I-CreI make a large number of DNA-protein contacts across their homing site sequences, and that different subsets of these contacts may be sufficient to maintain a high degree of sequence-specific homing site recognition and cleavage. The sequential enrichment protocol we used should be useful for defining the sequence degeneracy and informational content of other homing endonuclease target sites.

Evolutionarily conserved and functionally important residues in the I-CeuI homing endonuclease

Two approaches were used to discern critical amino acid residues for the function of the I- Ceu I homing endonuclease: sequence comparison of subfamilies of homologous proteins and genetic selection. The first approach revealed residues potentially involved in catalysis and DNA recognition. Because I- Ceu I is lethal in Escherichia coli , enzyme variants not perturbing cell viability were readily selected from an expression library. A collection of 49 variants with single amino acid substitutions at 37 positions was assembled. Most of these positions are clustered within or around the LAGLI-DADG dodecapeptide and the TQH sequence, two motifs found in all protein subfamilies examined. The Km and kcat values of the wild-type and nine variant enzymes synthesized in vitro were determined. Three variants, including one showing a substitution of the glutamine residue in the TQH motif, revealed no detectable endonuclease activity; five others showed reduced activity compared to the wild-type enzyme; whereas the remaining variant cleaved the top strand about three times more efficiently than the wild-type. Our results not only confirm recent reports indicating that amino acids in the LAGLI-DADG dodecapeptide are functionally critical, but they also suggest that some residues outside this motif directly participate in catalysis.

Mapping metal ions at the catalytic centres of two intron-encoded endonucleases

Divalent metal ions play a crucial role in forming the catalytic centres of DNA endonucleases. Substitution of Mg2+ ions by Fe2+ ions in two archaeal intron-encoded homing endonucleases, I-DmoI and I-PorI, yielded functional enzymes and enabled the generation of reactive hydroxyl radicals within the metal ion binding sites. Specific hydroxyl radical-induced cleavage was observed within, and immediately after, two conserved LAGLIDADG motifs in both proteins and at sites at, and near, the scissile phosphates of the corresponding DNA substrates. Titration of Fe2+-containing protein-DNA complexes with Ca2+ ions, which are unable to support endonucleolytic activity, was performed to distinguish between the individual metal ions in the complex. Mutations of single amino acids in this region impaired catalytic activity and caused the preferential loss of a subset of hydroxyl radical cleavages in both the protein and the DNA substrate, suggesting an active role in metal ion coordination for these amino acids. The data indicate that the endonucleases cleave their DNA substrates as monomeric enzymes, and contain a minimum of four divalent metal ions located at or near the catalytic centres of each endonuclease. The metal ions involved in cleaving the coding and the non-coding strand are positioned immediately after the N- and C-terminally located LAGLIDADG motifs, respectively. The dual protein/nucleic acid footprinting approach described here is generally applicable to other protein-nucleic acid complexes when the natural metal ion can be replaced by Fe2+.

Protein footprinting approach to mapping DNA binding sites of two archaeal homing enzymes: evidence for a two-domain protein structure

The archaeal intron-encoded homing enzymes I-PorI and I-DmoI belong to a family of endonucleases that contain two copies of a characteristic LAGLIDADG motif. These endonucleases cleave their intron- or intein- alleles site-specifically, and thereby facilitate homing of the introns or inteins which encode them. The protein structure and the mechanism of DNA recognition of these homing enzymes is largely unknown. Therefore, we examined these properties of I-PorI and I-DmoI by protein footprinting. Both proteins were susceptible to proteolytic cleavage within regions that are equidistant from each of the two LAGLIDADG motifs. When complexed with their DNA substrates, a characteristic subset of the exposed sites, located in regions immediately after and 40-60 amino acids after each of the LAGLIDADG motifs, were protected. Our data suggest that the enzymes are structured into two, tandemly repeated, domains, each containing both the LAGLIDADG motif and two putative DNA binding regions. The latter contains a potentially novel DNA binding motif conserved in archaeal homing enzymes. The results are consistent with a model where the LAGLIDADG endonucleases bind to their non-palindromic substrates as monomeric enzymes, with each of the two domains recognizing one half of the DNA substrate.

Replacement of two non-adjacent amino acids in the S.cerevisiae bi2 intron-encoded RNA maturase is sufficient to gain a homing-endonuclease activity

Two homologous group I introns, the second intron of the cyt b gene, from related Saccharomyces species differ in their mobility. The S.capensis intron is mobile and encodes the I-ScaI endonuclease promoting intron homing, whilst the homologous S.cerevisiae intron is not mobile, but functions as an RNA maturase promoting splicing. These two intron-encoded proteins differ by only four amino acid substitutions. Taking advantage of the remarkable similarity of the two intron open reading frames and using biolistic transformation of mitochondria, we show that the replacement of only two non-adjacent residues in the S.cerevisiae maturase carboxy-terminal sequence is sufficient to induce a homing-endonuclease activity without losing the splicing function. Also, we demonstrate that these two activities reside in the S.capensis bi2-encoded protein which functions in both splicing and intron mobility in the wild-type cells. These results provide new insight into our understanding of the activity and the evolution of group I intron-encoded proteins.

Endo.SK1: an inducible site-specific endonuclease from yeast mitochondria

Site-specific endonucleases have been found in various eukaryotic organelles such as mitochondria, chloroplasts and nuclei. These endonucleases initiate site-specific or homologous gene conversion in mitochondrial and nuclear DNA. Here, we report a new site-specific endonuclease activity, Endo.SK1, identified in mitochondria of strain SK1, a homothallic diploid strain of Saccharomyces cerevisiae. Nucleotide sequences around the Endo.SK1-cleavage sites are different from those of known yeast site-specific endonucleases. The Endo.SK1 activity is, at least partly, specified by a gene in the SK1-derived mitochondria. A novel feature of the Endo.SK1 activity is its inducibility: the endonuclease activity was induced by ca. 40-fold by transfer of cells from a glucose medium into an acetate medium, and was then repressed. This transient induction was independent of the ploidy level of the cells, and coincided with induction of fumarase, a mitochondrial enzyme involved in the TCA cycle. Co-induction and co-repression of the mitochondrial site-specific endonuclease activity and a respiration-related enzyme indicate that the endonuclease activity in regulated in response to physiological conditions, and suggest a possible role for the endonuclease in mitochondrial DNA metabolism.

The mobile group I intron 3 alpha of the yeast mitochondrial COXI gene encodes a 35-kDa processed protein that is an endonuclease but not a maturase

Three mitochondrial mutants were characterized that block the splicing of aI3 alpha, a mobile group I intron of the COXI gene of yeast mtDNA. Mutant C1085 alters helical structures known to be important for splicing of group I introns. M44 and C1072 are point mutants in exon 3 that block correct splicing but allow some splicing at cryptic 5'-splice sites. M44 alters the P1 helix needed for 5'-splice site definition, while the mutation in C1072 is a new kind of mutation because it is located upstream of the exon sequence involved in the P1 helix. All three mutants accumulate novel proteins of 35 and 44 kDa (p35 and p44, respectively) detected both by labeling of mitochondrial translation products and by Western blotting. Partial protease digestions indicate that p44 and p35 are closely related, probably as precursor and processed protein. The level of the intron-encoded endonuclease activity, I-SceIII, is elevated approximately 10-fold in the mutants. Partial purification of I-SceIII from the mutants showed that most, if not all, of the activity is associated with p35. Finally, because aI3 alpha splices accurately in a petite mutant, we conclude that aI3 alpha splicing does not depend on a mtDNA-encoded maturase.

Mutations in the mitochondrial split gene COXI are preferentially located in exons: a mapping study of 170 mutants

We have analysed the precise location of a large number (170) of mutations affecting the structural gene for subunit I of the cytochrome c oxidase complex. This gene, COXI, is 12.9 kb long and the major part of the sequence (i.e. 11.3 kb) is composed of introns. Several conclusions can be drawn from this study: (1) A significant proportion (84/170) of the mutations cannot be assigned to a single position within the gene by deletion mapping, in spite of clearly being located in it. These mutations are probably large deletions or multiple mutations. (2) Four mutants carry distant double mutations, which have been individually localized. (3) Eighty-two mutants have lesions that are restricted to very short regions of the gene and we therefore conclude that they are most probably due to single hits; amongst these single mutations, 41 are unambiguously located in exons and 28 in introns. This result implies that, at least in this particular split gene, the probability of selection of a mutant phenotype in an exon is, on the average, 13.3 times greater than in an intron, in spite of the existence, within most of these introns, of open reading frames specifying intronic proteins. The evolutionary significance and biological implications of these results are discussed.

Nucleo-mitochondrial interactions in mitochondrial gene expression

All proteins encoded by mitochondrial DNA (mtDNA) are dependent on proteins encoded by nuclear genes for their synthesis and function. Recent developments in the identification of these genes and the elucidation of the roles their products play at various stages of mitochondrial gene expression are covered in this review, which focuses mainly on work with the yeast Saccharomyces cerevisiae. The high degree of evolutionary conservation of many cellular processes between this yeast and higher eukaryotes, the ease with which mitochondrial biogenesis can be manipulated both genetically and physiologically, and the fact that it will be the first organism for which a complete genomic sequence will be available within the next 2 to 3 years makes it the organism of choice for drawing up an inventory of all nuclear genes involved in mitochondrial biogenesis and for the identification of their counterparts in other organisms.

A mitochondrial group-I intron in fission yeast encodes a maturase and is mobile in crosses

The open reading frame in the first intron of the mitochondrial gene encoding subunit I of cytochrome c oxidase encodes a maturase and stimulates homologous recombination in Escherichia coli. In this paper, we demonstrate that this intron is mobile in crosses, indicating that it also encodes an endonuclease. This is the first report on an intron which possesses mobility and acts as a maturase.

Two homologous introns from related Saccharomyces species differ in their mobility

We have studied gene conversion initiated by the ai3 intron of the Saccharomyces cerevisiae mitochondrial (mt) COXI gene and its homologous intron (S.cap.ai1) from Saccharomyces capensis. The approach used involved the measurement of intron transmission amongst the progeny of crosses between constructed recipient and donor strains. We found that the S. cerevisiae ai3 intron is extremely active as a donor in gene conversion, whereas its homologous S. capensis intron is not. We have established the sequence of S.cap.ai1 and compared its open reading frame (ORF) with that of I-SceIII encoded by the homologous S. cerevisiae intron. The two protein-coding intron sequences are almost identical, except that the S. capensis ORF contains an in-frame stop codon. This finding provides a strong indication that the 3' part of the S. cerevisiae intron ORF encoding I-SceIII (which should not be translated in the S. capensis intron) must be critical for function of mtDNA endonucleases to mediate intron mobility.