Rapid evolution of the DNA-binding site in LAGLIDADG homing endonucleases.

Sequence analysis of chloroplast and mitochondrial large subunit rRNA genes from over 75 green algae disclosed 28 new group I intron-encoded proteins carrying a single LAGLIDADG motif. These putative homing endonucleases form four subfamilies of homologous enzymes, with the members of each subfamily being encoded by introns sharing the same insertion site. We showed that four divergent endonucleases from the I-CreI subfamily cleave the same DNA substrates. Mapping of the 66 amino acids that are conserved among the members of this subfamily on the 3-dimensional structure of I-CreI bound to its recognition sequence revealed that these residues participate in protein folding, homodimerization, DNA recognition and catalysis. Surprisingly, only seven of the 21 I-CreI amino acids interacting with DNA are conserved, suggesting that I-CreI and its homologs use different subsets of residues to recognize the same DNA sequence. Our sequence comparison of all 45 single-LAGLIDADG proteins identified so far suggests that these proteins share related structures and that there is a weak pressure in each subfamily to maintain identical protein-DNA contacts. The high sequence variability we observed in the DNA-binding site of homologous LAGLIDADG endonucleases provides insight into how these proteins evolve new DNA specificity.

Biochemical characterization of I-CmoeI reveals that this H-N-H homing endonuclease shares functional similarities with H-N-H colicins.

Endonuclease assays of the H-N-H proteins encoded by two group I introns in the Chlamydomonas moewusii chloroplast psbA gene revealed that the CmpsbA.1 intron specifies a site-specific DNA endonuclease, designated I-CMOE:I. Like most previously reported intron-encoded endonucleases, I-CMOE:I generates a double-strand break near the insertion site of its encoding intron, leaving 3' extensions of 4 nt. This enzyme was purified from Escherichia coli as a fusion protein with a His tag at its N-terminus. The recombinant protein (rI-CMOE:I) requires a divalent alkaline earth cation for DNA cleavage (Mg(2+) > Ca(2+) > Sr(2+) > Ba(2+)). It also requires a metal cofactor for DNA binding, a property shared with H-N-H colicins but not with the homing endonucleases characterized to date. rI-CMOE:I binds its recognition sequence as a monomer, as revealed by gel retardation assays. K:(m) and k(cat) values of 100 +/- 40 pM and 0.26 +/- 0.04 min(-1), respectively, were determined. Replacement of the first histidine of the H-N-H motif by an alanine residue abolishes both rI-CMOE:I activity and binding to its substrate. We propose that this conserved histidine residue plays a role in binding the metal cofactor and that such binding induces a structural modification of the enzyme which is required for DNA recognition.

Ancestral chloroplast genome in Mesostigma viride reveals an early branch of green plant evolution.

Sequence comparisons suggest that all living green plants belong to one of two major phyla: Streptophyta (land plants and their closest green algal relatives, the charophytes); and Chlorophyta (the rest of green algae). Because no green algae are known that pre-date the Streptophyta/Chlorophyta split, and also because the earliest diverging green algae show considerable morphological variation, the nature of the unicellular flagellate ancestor of the two green plant phyla is unknown. Here we report that the flagellate Mesostigma viride belongs to the earliest diverging green plant lineage discovered to date. We have sequenced the entire chloroplast DNA (118,360 base pairs) of this green alga and have conducted phylogenetic analyses of sequences derived from this genome. Mesostigma represents a lineage that emerged before the divergence of the Streptophyta and Chlorophyta, a position that is supported by several features of its chloroplast DNA. The structure and gene organization of this genome indicate that chloroplast DNA architecture has been extremely well conserved in the line leading to land plants.

The complete mitochondrial DNA sequences of Nephroselmis olivacea and Pedinomonas minor. Two radically different evolutionary patterns within green algae.

Green plants appear to comprise two sister lineages, Chlorophyta (classes Chlorophyceae, Ulvophyceae, Trebouxiophyceae, and Prasinophyceae) and Streptophyta (Charophyceae and Embryophyta, or land plants). To gain insight into the nature of the ancestral green plant mitochondrial genome, we have sequenced the mitochondrial DNAs (mtDNAs) of Nephroselmis olivacea and Pedinomonas minor. These two green algae are presumptive members of the Prasinophyceae. This class is thought to include descendants of the earliest diverging green algae. We find that Nephroselmis and Pedinomonas mtDNAs differ markedly in size, gene content, and gene organization. Of the green algal mtDNAs sequenced so far, that of Nephroselmis (45,223 bp) is the most ancestral (minimally diverged) and occupies the phylogenetically most basal position within the Chlorophyta. Its repertoire of 69 genes closely resembles that in the mtDNA of Prototheca wickerhamii, a later diverging trebouxiophycean green alga. Three of the Nephroselmis genes (nad10, rpl14, and rnpB) have not been identified in previously sequenced mtDNAs of green algae and land plants. In contrast, the 25,137-bp Pedinomonas mtDNA contains only 22 genes and retains few recognizably ancestral features. In several respects, including gene content and rate of sequence divergence, Pedinomonas mtDNA resembles the reduced mtDNAs of chlamydomonad algae, with which it is robustly affiliated in phylogenetic analyses. Our results confirm the existence of two radically different patterns of mitochondrial genome evolution within the green algae.

The complete chloroplast DNA sequence of the green alga Nephroselmis olivacea: insights into the architecture of ancestral chloroplast genomes.

Green plants seem to form two sister lineages: Chlorophyta, comprising the green algal classes Prasinophyceae, Ulvophyceae, Trebouxiophyceae, and Chlorophyceae, and Streptophyta, comprising the Charophyceae and land plants. We have determined the complete chloroplast DNA (cpDNA) sequence (200,799 bp) of Nephroselmis olivacea, a member of the class (Prasinophyceae) thought to include descendants of the earliest-diverging green algae. The 127 genes identified in this genome represent the largest gene repertoire among the green algal and land plant cpDNAs completely sequenced to date. Of the Nephroselmis genes, 2 (ycf81 and ftsI, a gene involved in peptidoglycan synthesis) have not been identified in any previously investigated cpDNA; 5 genes [ftsW, rnE, ycf62, rnpB, and trnS(cga)] have been found only in cpDNAs of nongreen algae; and 10 others (ndh genes) have been described only in land plant cpDNAs. Nephroselmis and land plant cpDNAs share the same quadripartite structure-which is characterized by the presence of a large rRNA-encoding inverted repeat and two unequal single-copy regions-and very similar sets of genes in corresponding genomic regions. Given that our phylogenetic analyses place Nephroselmis within the Chlorophyta, these structural characteristics were most likely present in the cpDNA of the common ancestor of chlorophytes and streptophytes. Comparative analyses of chloroplast genomes indicate that the typical quadripartite architecture and gene-partitioning pattern of land plant cpDNAs are ancient features that may have been derived from the genome of the cyanobacterial progenitor of chloroplasts. Our phylogenetic data also offer insight into the chlorophyte ancestor of euglenophyte chloroplasts.

Genome structure and gene content in protist mitochondrial DNAs.

Although the collection of completely sequenced mitochondrial genomes is expanding rapidly, only recently has a phylogenetically broad representation of mtDNA sequences from protists (mostly unicellular eukaryotes) become available. This review surveys the 23 complete protist mtDNA sequences that have been determined to date, commenting on such aspects as mitochondrial genome structure, gene content, ribosomal RNA, introns, transfer RNAs and the genetic code and phylogenetic implications. We also illustrate the utility of a comparative genomics approach to gene identification by providing evidence that orfB in plant and protist mtDNAs is the homolog of atp8 , the gene in animal and fungal mtDNA that encodes subunit 8 of the F0portion of mitochondrial ATP synthase. Although several protist mtDNAs, like those of animals and most fungi, are seen to be highly derived, others appear to be have retained a number of features of the ancestral, proto-mitochondrial genome. Some of these ancestral features are also shared with plant mtDNA, although the latter have evidently expanded considerably in size, if not in gene content, in the course of evolution. Comparative analysis of protist mtDNAs is providing a new perspective on mtDNA evolution: how the original mitochondrial genome was organized, what genes it contained, and in what ways it must have changed in different eukaryotic phyla.

The chloroplast ycf3 and ycf4 open reading frames of Chlamydomonas reinhardtii are required for the accumulation of the photosystem I complex.

The chloroplast genes ycf3 and ycf4 from the green alga Chlamydomonas reinhardtii have been characterized. The deduced amino acid sequences of Ycf4 (197 residues) and Ycf3 (172 residues) display 41-52% and 64-78% sequence identity, respectively, with their homologues from algae, land plants and cyanobacteria. In C. reinhardtii, ycf4 and ycf3 are co-transcribed as members of the rps9-ycf4-ycf3-rps18 polycistronic transcriptional unit into RNAs of 8.0 kb and 3.0 kb corresponding to the entire unit and to rps9-ycf4-ycf3, respectively. Using biolistic transformation, ycf4 and ycf3 were disrupted with a chloroplast selectable marker cassette. Transformants lacking ycf4 or ycf3 were unable to grow photoautotrophically and were deficient in photosystem I activity. Western blot analysis showed that the photosystem I (PSI) complex does not accumulate stably in thylakoid membranes of these transformants. Ycf4 and Ycf3 were localized on thylakoid membranes but not stably associated with the PSI complex and accumulated to wild-type levels in mutants lacking PSI. RNA blot hybridizations showed that transcripts of psaA, psaB and psaC accumulate normally in these mutants and use of chimeric reporter genes revealed that Ycf3 is not required for initiation of translation of psaA and psaB mRNA. Our results indicate that Ycf3 and Ycf4 are required for stable accumulation of the PSI complex.

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.

An ancestral mitochondrial DNA resembling a eubacterial genome in miniature.

Mitochondria, organelles specialized in energy conservation reactions in eukaryotic cells, have evolved from eubacteria-like endosymbionts whose closest known relatives are the rickettsial group of alpha-proteobacteria. Because characterized mitochondrial genomes vary markedly in structure, it has been impossible to infer from them the initial form of the proto-mitochondrial genome. This would require the identification of minimally derived mitochondrial DNAs that better reflect the ancestral state. Here we describe such a primitive mitochondrial genome, in the freshwater protozoon Reclinomonas americana. This protist displays ultrastructural characteristics that ally it with the retortamonads, a protozoan group that lacks mitochondria. R. americana mtDNA (69,034 base pairs) contains the largest collection of genes (97) so far identified in any mtDNA, including genes for 5S ribosomal RNA, the RNA component of RNase P, and at least 18 proteins not previously known to be encoded in mitochondria. Most surprising are four genes specifying a multisubunit, eubacterial-type RNA polymerase. Features of gene content together with eubacterial characteristics of genome organization and expression not found before in mitochondrial genomes indicate that R. americana mtDNA more closely resembles the ancestral proto-mitochondrial genome than any other mtDNA investigated to date.

A large open reading frame (orf1995) in the chloroplast DNA of Chlamydomonas reinhardtii encodes an essential protein.

An open reading frame potentially encoding a protein of 1995 amino acids (orf1995) has been found in the chloroplast genome of the green alga Chlamydomonas reinhardtii. Besides having a short hydrophobic N-terminal domain with five putative transmembrane helices, the predicted orf1995 product is highly basic. orf1995 might be a homologue of the ycf1 gene in land plants, whose function has not yet been determined. Mutants of C. reinhardtii transformed with a disruption of orf1995 remain heteroplasmic for the wild-type and disrupted alleles of this gene, indicating that the orf1995 product is essential for cell survival.

Optional elements in the chloroplast DNAs of chlamydomonas eugametos and C. moewusii: unidirectional gene conversion and co-conversion of adjacent markers in high-viability crossses.

Unlike most polymorphic markers in the Chlamydomonas eugametos and Chlamydomonas moewusii chloroplast DNAs (cpDNAs), the C. moewusii 6- and 21-kb extra sequences and the C. eugametos-specific CeLSU small middle dot 5 intron are transmitted to all of the few viable progeny in reciprocal crosses between the two green algae. To determine whether this unidirectional transmission pattern is due to gene conversion or to selection for F1 hybrid survival, we followed the inheritance of the parental alleles at the loci featuring these three deletions/additions and at several other polymorphic cpDNA loci in zygospore clones derived from high-viability crosses. The great majority of the zygospore clones examined inherited exclusively the long alleles from the mt- parent at the loci containing the three optional cpDNA elements, but as expected, they preferentially inherited the markers from the mt+ parent at most other loci. Our results therefore indicate that all three optional cpDNA sequences propagate themselves very efficiently by gene conversion in crosses between strains differing by the presence of these elements. The co-conversion tracts associated with these sequences are longer (>3 kb) than those previously reported for mobile elements spreading by gene conversion. Our results also revealed that less efficient gene conversion events occurred at two other cpDNA loci.

Phylogeny of the Chlamydomonadales (Chlorophyceae): a comparison of ribosomal RNA gene sequences from the nucleus and the chloroplast.

Phylogenetic analyses of nuclear-encoded small-subunit rRNA sequences and chloroplast-encoded large-subunit rRNA sequences from flagellate green algae representing the order Chlamydomonadales were found to show considerable congruence. In general, the chloroplast data set exhibited more robust support for comparable lineages than the nuclear data set. The phylogenetic inferences derived from the independent data sets support some, but also challenge many, traditional taxonomic and phylogenetic concepts regarding the green flagellates. Results from phylogenetic analyses of both molecular data sets support six distinct lineages that include taxa from the biflagellate genus, Chlamydomonas, and a basal lineage that comprises taxa from the quadriflagellate genus, Carteria. Both data sets support the conclusion that Chlamydomonas is not monophyletic. Although the chloroplast data are ambiguous regarding the question of Carteria monophyly, the nuclear data fail to support Carteria monophyly. The chlorococcalean genus Chlorococcum was found to have affinities with the Chlamydomonadales, indicating that the traditional concepts of both Chlorococcales and Chlamydomonadales may need revision. The genus Dunaliella is allied within the Chlamydomonadales, supporting the contention that it has lost a typical glycoprotein cell wall.

Extensive gene rearrangements in the chloroplast DNAs of Chlamydomonas species featuring multiple dispersed repeats.

We have constructed a physical and gene map for the chloroplast DNA (cpDNA) of the unicellular green alga Chlamydomonas gelatinosa, a close relative of Chlamydomonas reinhardtii. At 285 kb, the C. gelatinosa cpDNA is 89 kb larger than its C. reinhardtii counterpart. The alterations in the order of 77 genes on the cpDNAs of these green algae are attributable to nine inversions and one event of expansion/contraction of the inverted repeat. These rearrangements are much more extensive than those previously reported between the cpDNAs of the closely related Chlamydomonas moewusii and Chlamydomonas pitschmannii. Because the divergence level of the C. gelatinosa and C. reinhardtii chloroplast-encoded large subunit rRNA gene sequences is equivalent to that of the corresponding C. moewusii and C. pitschmannii sequences, our results may suggest that, in the same period of time, there have been more numerous rearrangements in the lineage comprising C. gelatinosa and C. reinhardtii than in the lineage comprising C. moewusii and C. pitschmannii. Alternatively, given that substitution rates in chloroplast genes are not necessarily uniform across lineages, the extensive rearrangements between the C. gelatinosa and C. reinhardtii cpDNAs may reflect a longer divergence period for this pair of Chlamydomonas species compared to that for the C. moewusii/C. pitschmannii pair. We have also found that, like its C. reinhardtii homologue but unlike its C. moewusii and C. pitschmannii counterparts, the C. gelatinosa cpDNA features a large number of dispersed repeated sequences that are readily detectable by Southern blot hybridization with homologous fragment probes. Assuming that the two pairs of closely related Chlamydomonas species diverged at about the same time, these data suggest that the susceptibility of Chlamydomonas cpDNAs to rearrangements is correlated with the abundance of repeated sequences. Preliminary characterization of a 345-bp C. gelatinosa cpDNA region containing a repeated sequence by both DNA sequencing and Southern blot analysis has revealed no sequence homology between this region and the cpDNAs of C. reinhardtii and other Chlamydomonas species.

The site-specific DNA endonuclease encoded by a group I intron in the Chlamydomonas pallidostigmatica chloroplast small subunit rRNA gene introduces a single-strand break at low concentrations of Mg2+.

Two group I introns (CpSSU.1 and CpSSU.2) that each potentially encode a protein with two copies of the LAGLI-DADG motif were identified in the Chlamydomonas pallidostigmatica chloroplast small subunit rRNA gene. They both belong to subgroup IA3 and represent novel insertion positions in this gene (sites 508 and 793 in the Escherichia coli 16S rRNA). The proteins encoded by the two introns were synthesized in vitro and tested for their ability to cleave the homing site of their respective introns. Only the CpSSU.1-encoded protein (I-CpaII) was found to display specific DNA endonuclease activity. At 0.1 mM MgCl2, I-CpaII nicks only the bottom (transcribed) DNA strand, but at concentrations ranging from 0.5 to 5.0 mM, it cleaves both DNA strands (leaving a 4 nucleotide single-stranded extension with 3'-OH overhangs) while preferentially nicking the bottom strand. The rate of cleavage of the top strand increases with increasing concentration of MgCl2. The preliminary data derived from these endonuclease assays suggest that the mode of DNA cleavage by I-CpaII is directed by the availability of Mg2+ and the affinity of different binding sites for this cation.

Evolutionary transfer of ORF-containing group I introns between different subcellular compartments (chloroplast and mitochondrion).

We describe here a case of homologous introns containing homologous open reading frames (ORFs) that are inserted at the same site in the large subunit (LSU) rRNA gene of different organelles in distantly related organisms. We show that the chloroplast LSU rRNA gene of the green alga Chlamydomonas pallidostigmatica contains a group I intron (CpLSU.2) encoding a site-specific endonuclease (I-CpaI). This intron is inserted at the identical site (corresponding to position 1931-1932 of the Escherichia coli 23S rRNA sequence) as a group I intron (AcLSU.m1) in the mitochondrial LSU rRNA gene of the amoeboid protozoon Acanthamoeba castellanii. The CpLSU.2 intron displays a remarkable degree of nucleotide similarity in both primary sequence and secondary structure to the AcLSU.m1 intron; moreover, the Acanthamoeba intron contains an ORF in the same location within its secondary structure as the CpLSU.2 ORF and shares with it a strikingly high level of amino acid similarity (65%; 42% identity). A comprehensive survey of intron distribution at site 1931 of the chloroplast LSU rRNA gene reveals a rather restricted occurrence within the polyphyletic genus Chlamydomonas, with no evidence of this intron among a number of non-Chlamydomonad green algae surveyed, nor in land plants. A parallel survey of homologues of a previously described and similar intron/ORF pair (C. reinhardtii chloroplast CrLSU/A. castellanii mitochondrial AcLSU.m3) also shows a restricted occurrence of this intron (site 2593) among chloroplasts, although the intron distribution is somewhat broader than that observed at site 1931, with site-2593 introns appearing in several green algal branches outside of the Chlamydomonas lineage. The available data, while not definitive, are most consistent with a relatively recent horizontal transfer of both site-1931 and site-2593 introns (and their contained ORFs) between the chloroplast of a Chlamydomonas-type organism and the mitochondrion of an Acanthamoeba-like organism, probably in the direction chloroplast to mitochondrion. The data also suggest that both introns could have been acquired in a single event.

The trans-spliced intron 1 in the psaA gene of the Chlamydomonas chloroplast: a comparative analysis.

In the secondary structure model that has been proposed for the trans-spliced intron 1 in the Chlamydomonas reinhardtii psaA gene, a third RNA species (tscA RNA) interacts with the 5' and 3' intron parts flanking the exons to reconstitute a composite structure with several features of group-II introns. To test the validity of this model, we undertook the sequencing and modelling of equivalent introns in the psaA gene from other unicellular green algae belonging to the highly diversified genus Chlamydomonas. Our comparative analysis supports the model reported for the C. reinhardtii psaA intron 1, and also indicates that the 5' end of the tscA RNA and the region downstream from the psaA exon 1 cannot be folded into a structure typical of domain I as described for most group-II introns. It is possible that a fourth RNA species, yet to be discovered, provides the parts of domain I which are apparently missing.

Gene rearrangements in Chlamydomonas chloroplast DNAs are accounted for by inversions and by the expansion/contraction of the inverted repeat.

To gain insight into the mutational events responsible for the extensive variation of chloroplast DNA (cpDNA) within the green algal genus Chlamydomonas, we have investigated the chloroplast gene organization of Chlamydomonas pitschmannii, a close relative of the interfertile species C. eugametos and C. moewusii whose cpDNAs have been well characterized. At 187 kb, the circular cpDNA of C. pitschmannii is the smallest Chlamydomonas cpDNA yet reported; it is 56 and 105 kb smaller than those of its C. eugametos and C. moewusii counterparts, respectively. Despite this substantial size difference, the arrangement of 77 genes on the C. pitschmannii cpDNA displays only three noticeable differences from the organization of the corresponding genes on the collinear C. eugametos and C. moewusii cpDNAs. These changes in gene order are accounted for by the expansion/contraction of the inverted repeat and one or two inversions in a single-copy region. In land plant cpDNAs, these kinds of events are also responsible for gene rearrangements. The large size difference between the C. pitschmannii and C. eugametos/C. moewusii cpDNAs is mainly attributed to multiple events of deletions/additions as opposed to the usually observed expansion/contraction of the inverted repeat in land plant cpDNAs. We also found that the mitochondrial genome of C. pitschmannii is a circular DNA molecule of 16.5 kb which is 5.5 and 7.5 kb smaller than its C. moewusii and C. eugametos counterparts, respectively.

In vitro self-splicing reactions of chloroplast and mitochondrial group-I introns in Chlamydomonas eugametos and Chlamydomonas moewusii.

The self-splicing activity of nine chloroplast group-I introns (CeLSU.1 to CeLSU.6, CepsbC.1, CepsbC.2 and CmpsaB.1) and of one mitochondrial group-I intron (CmmtLSU.1) from the interfertile green algae Chlamydomonas eugametos and C. moewusii was examined using RNA templates produced by in vitro transcription of cloned DNA sequences. All introns, with the exception of the mobile intron CeLSU.5 encoding the site-specific I-CeuI endonuclease, were found to catalyze their own splicing in the absence of proteins. The introns that proved to be the best substrates under the conditions employed are CeLSU.1, CeLSU.3, CeLSU.4, CepsbC.1 and CmmtLSU.1. The implications of our results for the origin and spread of group-I introns in the organellar genomes of green algae are discussed.

The chloroplast gene cluster containing psbF, psbL, petG and rps3 is conserved in Chlamydomonas.

We have sequenced a 6.8-kb segment of the Chlamydomonas eugametos chloroplast DNA which contains the psbF, psbL, petG and rps3 genes. As in the distantly related green alga Chlamydomonas reinhardtii, these genes reside in this order (5'-->3') on the same DNA strand, suggesting that such a chloroplast gene cluster was present in the most recent common ancestor of all Chlamydomonas species. For each of the four genes, with the exception of rps3, the C. eugametos and C. reinhardtii coding regions were found to be identical, or very similar, in length, whereas each of the intergenic spacers is substantially longer in C. eugametos than in C. reinhardtii. The central portion of both Chlamydomonas rps3 genes features a long extra coding region relative to other rps3 sequences. We have shown that the insertion sequence in the C. eugametos rps3 is not excised at the RNA level.