Evolutionary significance of an unusual chloroplast DNA inversion found in two basal angiosperm lineages.

Two basal lineages of flowering plants possess an intergenic inversion in the chloroplast inverted repeat (IR), a region of the genome from which there have been few previous reports of this class of structural mutation. The size of the inversion (approximately 200 bp) places it in a class not previously seen in the plastid genome. The two lineages with the rearrangement, representatives of the orders Laurales and Nymphaeales, are not closely related and the inversion therefore probably arose independently in each group. The inversion is bordered by short, but highly conserved, inverted repeat motifs that were most likely associated with the inversion process. A stem-loop structure that involves these motifs may play a functional role in mRNA stability. It is seen in all optimal or nearly optimal predicted RNA foldings of the intergenic region.

Utility of 17 chloroplast genes for inferring the phylogeny of the basal angiosperms.

Sequences from 14 slowly evolving chloroplast genes (including three highly conserved introns) were obtained for representative basal angiosperm and seed-plant taxa, using novel primers described here. These data were combined with published sequences from atpB, rbcL, and newly obtained sequences from ndhF. Combined data from these 17 genes permit sturdy, well-resolved inference of major aspects of basal angiosperm relationships, demonstrating that the new primers are valuable tools for sorting out the deepest events in flowering plant phylogeny. Sequences from the inverted repeat (IR) proved to be particularly reliable (low homoplasy, high retention index). Representatives of Cabomba and Illicium were the first two successive branches of the angiosperms in an initial sampling of 19 exemplar taxa. This result was strongly supported by bootstrap analysis and by two small insertion/deletion events in the slowly evolving introns. Several paleoherb groups (representatives of Piperales) formed a strongly supported clade with taxa representing core woody magnoliids (Laurales, Magnoliales, and Winteraceae). The monophyly of the sampled eudicots and monocots was also well supported. Analyses of three major partitions of the data showed many of the same clades and supported the rooting seen with all the data combined. While Amborella trichopoda was supported as the sister group of the remaining angiosperms when we added Amborella and Nymphaea odorata to the analysis, a strongly conflicting rooting was observed when Amborella alone was added.

Ninety extra nucleotide in ndhF gene of tobacco chloroplast DNA: a summary of revisions to the 1986 genome sequence.

Corrections to the published sequence of the tobacco chloroplast gene ndhF are presented, including a 90 bp Alu I restriction enzyme fragment internal to the gene that was apparently missed during the original sequencing effort. A summary of the corrections to the published tobacco chloroplast DNA that have come to light since its original publication is included.

Phylogeny of Poaceae subfamily Pooideae based on chloroplast ndhF gene sequences.

Forty-eight representatives of 12 tribes attributed to the subfamily Pooideae s.l. of grasses (Monocots) have been studied by sequencing the more variable 3' end of the chloroplast ndhF gene. Six representatives from 5 different tribes of Poaceae (Oryzeae, Streptogyneae, Bambuseae, Arundineae, Phareae) and from Joinvilleaceae were used as outgroups. Phylogenetic analyses of the data render a monophyletic Pooideae clade and provide an evolutionary hypothesis for all its tribes (Poeae, Aveneae, Bromeae, Triticeae, Brachypodieae, Meliceae, Stipeae, Lygeae, Nardeae, Diarrheneae, Brachyelytreae, Phaenospermatae). The subfamily is composed of two subsets of tribes, a basal group that includes six old lineages or satellite tribes, in which Brachyelytreae is the first diverging branch followed by the Lygeae/Nardeae clade, and a group of six more recently evolved tribes (Pooideae s.s.), in which the divergence of Diarrheneae antedates that of Brachypodieae, sister group to the "core pooids." The character changes found within the sequenced nucleotide positions of the ndhF gene also have proven to be informative at lower hierarchical levels (genus and species) for some tribes.

Molecular systematics of Clerodendrum (Lamiaceae): ITS sequences and total evidence.

Thirty-three species of Clerodendrum s.l. and five outgroup genera were included in a sequence analysis of internal transcribed spacers of the nuclear ribosomal DNA. The results of the cladistic analysis were compared to and combined with cpDNA restriction site data from a previous study. All molecular data identified four major clades within Clerodendrum s.l. and showed the genus to be polyphyletic. Clerodendrum s.s., minus Konocalyx and Cyclonema, is monophyletic and the genus should be restricted to this group. Cyclonema and Konocalyx form a clade distinct from Clerodendrum s.s., which has been recognized as Rotheca Raf.

Ebb and flow of the chloroplast inverted repeat.

The endpoints of the large inverted repeat (IR) of chloroplast DNA in flowering plants differ by small amounts between species. To quantify the extent of this movement and define a possible mechanism for IR expansion, DNA sequences across the IR-large single-copy (IR-LSC) junctions were compared among 13 Nicotiana species and other dicots. In most Nicotiana species the IR terminates just upstream of, or somewhere within, the 5' portion of the rps19 gene. The truncated copy of this gene, rps19', varies in length even between closely related species but is of constant size within a single species. In Nicotiana, six different rps19' structures were found. A phylogenetic tree of Nicotiana species based on restriction site data shows that the IR has both expanded and contracted during the evolution of this genus. Gene conversion is proposed to account for these small and apparently random IR expansions. A large IR expansion of over 12 kb has occurred in Nicotiana acuminata. The new IR-LSC junction in this species lies within intron 1 of the clpP gene. This rearrangement occurred via a double-strand DNA break and recombination between poly (A) tracts in clpP intron 1 and upstream of rps19. Nicotiana acuminata chloroplast DNA contains a "molecular fossil' of the IR-LSC junction that existed prior to this dramatic rearrangement.

The phylogeny of the Asteridae sensu lato based on chloroplast ndhF gene sequences.

A phylogenetic study of Asteridae sensu lato was conducted based on chloroplast ndhF gene sequences for 116 ingroup and 13 outgroup species. Prior molecular studies based on rbcL sequences identified terminal groups corresponding to families, but were unable to resolve relationships among them. These results are largely consistent with earlier rbcL studies, but provide much greater resolution and stronger bootstrap support throughout the tree. The parsimony analysis found eight equally parsimonious trees, all of which recognize four major clades with the following relationship: (Cornales (Ericales (Euasterids I, Euasterids II))). Euasterids I includes (Garryales ((Solanales, Boraginaceae) (Gentianales, Lamiales))), although with weak support for relationships among the named clades. Euasterids II includes (Aquifoliales (Asterales (Apiales, Dipsacales))) with strong support for these relationships. Relationships within Ericales are weakly supported and merit further attention.

Disintegration of the scrophulariaceae.

A molecular systematic study of Scrophulariaceae sensu lato using DNA sequences of three plastid genes (rbcL, ndhF, and rps2) revealed at least five distinct monophyletic groups. Thirty-nine genera representing 24 tribes of the Scrophulariaceae s.l. (sensu lato) were analyzed along with representatives of 15 other families of Lamiales. The Scrophulariaceae s.s. (sensu stricto) include part or all of tribes Aptosimeae, Hemimerideae, Leucophylleae, Manuleae, Selagineae, and Verbasceae (= Scrophularieae) and the conventional families Buddlejaceae and Myoporaceae. Veronicaceae includes all or part of tribes Angelonieae, Antirrhineae, Cheloneae, Digitaleae, and Gratioleae and the conventional families Callitrichaceae, Globulariaceae, Hippuridaceae, and Plantaginaceae. The Orobanchaceae include tribes Buchnereae, Rhinantheae, and the conventional Orobanchaceae. All sampled members of Orobanchaceae are parasitic, except Lindenbergia, which is sister to the rest of the family. Family Calceolariaceae Olmstead is newly erected herein to recognize the phylogenetic distinctiveness of tribe Calceolarieae. The Calceolariaceae are close to the base of the Lamiales. The Stilbaceae are expanded by the inclusion of Halleria. Mimulus does not belong in any of these five groups.

Many parallel losses of infA from chloroplast DNA during angiosperm evolution with multiple independent transfers to the nucleus.

We used DNA sequencing and gel blot surveys to assess the integrity of the chloroplast gene infA, which codes for translation initiation factor 1, in >300 diverse angiosperms. Whereas most angiosperms appear to contain an intact chloroplast infA gene, the gene has repeatedly become defunct in approximately 24 separate lineages of angiosperms, including almost all rosid species. In four species in which chloroplast infA is defunct, transferred and expressed copies of the gene were found in the nucleus, complete with putative chloroplast transit peptide sequences. The transit peptide sequences of the nuclear infA genes from soybean and Arabidopsis were shown to be functional by their ability to target green fluorescent protein to chloroplasts in vivo. Phylogenetic analysis of infA sequences and assessment of transit peptide homology indicate that the four nuclear infA genes are probably derived from four independent gene transfers from chloroplast to nuclear DNA during angiosperm evolution. Considering this and the many separate losses of infA from chloroplast DNA, the gene has probably been transferred many more times, making infA by far the most mobile chloroplast gene known in plants.