Milena Groth-Malonek

The deepest divergences in land plants inferred from phylogenomic evidence.

Phylogenetic relationships among the four major lineages of land plants (liverworts, mosses, hornworts, and vascular plants) remain vigorously contested; their resolution is essential to our understanding of the origin and early evolution of land plants. We analyzed three different complementary data sets: a multigene supermatrix, a genomic structural character matrix, and a chloroplast genome sequence matrix, using maximum likelihood, maximum parsimony, and compatibility methods. Analyses of all three data sets strongly supported liverworts as the sister to all other land plants, and analyses of the multigene and chloroplast genome matrices provided moderate to strong support for hornworts as the sister to vascular plants. These results highlight the important roles of liverworts and hornworts in two major events of plant evolution: the water-to-land transition and the change from a haploid gametophyte generation-dominant life cycle in bryophytes to a diploid sporophyte generation-dominant life cycle in vascular plants. This study also demonstrates the importance of using a multifaceted approach to resolve difficult nodes in the tree of life. In particular, it is shown here that densely sampled taxon trees built with multiple genes provide an indispensable test of taxon-sparse trees inferred from genome sequences.

A hypothesis on the identification of the editing enzyme in plant organelles

RNA editing in plant organelles is an enigmatic process leading to conversion of cytidines into uridines. Editing specificity is determined by proteins; both those known so far are pentatricopeptide repeat (PPR) proteins. The enzyme catalysing RNA editing in plants is still totally unknown. We propose that the DYW domain found in many higher plant PPR proteins is the missing catalytic domain. This hypothesis is based on two compelling observations: (i) the DYW domain contains invariant residues that match the active site of cytidine deaminases; (ii) the phylogenetic distribution of the DYW domain is strictly correlated with RNA editing.

Transport of magnesium and other divalent cations: evolution of the 2-TM-GxN proteins in the MIT superfamily

In bacteria, magnesium uptake is mainly mediated by the well-characterized CorA type of membrane proteins. In recent years, functional homologues have been characterized in the inner mitochondrial membrane of yeast and mammals (the MRS2/LPE10 type), in the plasma membrane of yeast (the ALR/MNR type) and, as an extended family of proteins, in the model plant Arabidopsis thaliana. Despite generally low sequence similarity, individual proteins can functionally complement each other over large phylogenetic distances. All these proteins are characterized by a universally conserved Gly-Met-Asn (GMN) motif at the end of the first of two conserved transmembrane domains near the C-terminus. Mutations of the GMN motif are known to abolish Mg2+ transport, but the naturally occurring variants GVN and GIN may be associated with the transport of other divalent cations, such as zinc and cadmium, respectively. We refer to this whole class of proteins as the 2-TM-GxN type. The functional membrane channel is thought to be formed by oligomers containing four or five subunits. The wealth of sequence data now available allows us to explore the evolutionary diversification of the basic 2-TM-GxN model within the so-called metal ion transporter (MIT) superfamily. Here we report phylogenetic analyses on more than 360 homologous protein sequences derived from genomic sequences from representatives of all three domains of life. Independent gene duplications have occurred in fungi, plants and proteobacteria at different phylogenetic depths. Moreover, there is ample evidence for several instances of horizontal gene transfer of members of the 2-TM-GxN superfamily in Eubacteria and Archaea. Only single genes of the MRS2 type have been identified in vertebrate genomes. In contrast, 15 members are found in the model plant Arabidopsis thaliana, which appear to have arisen by at least four independent founder events before the diversification of flowering plants. Phylogenetic clade assignment seems to correlate with alterations in the highly conserved sequence around the GMN motif. This presumably forms an integral part of the pore surface, and changes in its structure may result in altered transport capacities for different divalent cations.

Nuclear DYW-Type PPR Gene Families Diversify with Increasing RNA Editing Frequencies in Liverwort and Moss Mitochondria

RNA editing in mitochondria and chloroplasts of land plants alters transcript sequences by site-specific conversions of cytidines into uridines. RNA editing frequencies vary extremely between land plant clades, ranging from zero in some liverworts to more than 2,000 sites in lycophytes. Unique pentatricopeptide repeat (PPR) proteins with variable domain extension (E/E+/DYW) have recently been identified as specific editing site recognition factors in model plants. The distinctive functions of these PPR protein domain additions have remained unclear, although deaminase function has been proposed for the DYW domain. To shed light on diversity of RNA editing and DYW proteins at the origin of land plant evolution, we investigated editing patterns of the mitochondrial nad5, nad4, and nad2 genes in a wide sampling of more than 100 liverworts and mosses using the recently developed PREPACT program (www.prepact.de) and exemplarily confirmed predicted RNA editing sites in selected taxa. Extreme variability in RNA editing frequency is seen both in liverworts and mosses. Only few editings exist in the liverwort Lejeunea cavifolia or the moss Pogonatum urnigerum whereas up to 20% of cytidines are edited in the liverwort Haplomitrium mnioides or the moss Takakia lepidozioides. Interestingly, the latter are taxa that branch very early within their respective clades. Amplicons targeting the E/E+/DYW domains and subsequent random clone sequencing show DYW domains among bryophytes to be highly conserved in comparison with their angiosperm counterparts and to correlate well with RNA editing frequencies regarding their diversities. We propose that DYW proteins are the key players of RNA editing at the origin of land plants.

Bryophytes and other basal land plants: the mitochondrial perspective

The earliest diversifications of land plants in Ordovician and Silurian times are unclear, mainly due to a lack of macrofossils. The increasing wealth of molecular data, however, converges on the view that bryophytes are paraphyletic with only one of its classes being sister to all other land plants and another bryophyte clade being sister to the tracheophytes. We continue to explore mitochondrial gene regions with respect to their unique modes of gene expression such as RNA editing and trans-splicing and their phylogenetic information potential. Plant mitochondrial genes drift slowly in sequence and mitochondrial introns are mostly stable in position, yet vary in occurrence between clades. These two features make mitochondrial DNA an attractive reservoir of old phylogenetic information. On the other hand, there is striking structural plasticity of mitochondrial DNA (the chondriome) in embryophytes, which grossly contrasts with the conservative evolution of chloroplast DNA (the plastome) in the land plant lineage. We find that mitochondrial intron occurrence strongly adds to the view of the deepest dichotomy separating liverworts and all non-liverwort embryophytes. Other intron occurrences, including the presence of ancestors of trans-splicing group II introns, tend to place hornworts as a sister group to tracheophytes, a grouping that we find corroborated by most multi-gene analyses. Furthermore, conserved intron sequences add phylogenetic resolution within clades. The use of gene spacers for phylogenetic analysis, as commonly investigated in chloroplast DNA, has so far been precluded in plant mitochondria due to rampant recombination of the chondriome, at least in tracheophytes. To investigate whether at least some ancestral gene orders are still conserved among bryophytes and provide useful phylogenetic information, we have recently explored the nad5-nad4-nad2 gene arrangement. We find it conserved, yet with strikingly different modes of evolution in the two spacers.

Different Fates of Two Mitochondrial Gene Spacers in Early Land Plant Evolution

Plant mitochondrial DNA is generally characterized by slow sequence drift but frequent genomic recombination. Accordingly, gene sequences in plant mitochondria are informative for old cladogenic events, whereas intergenic regions have so far not been considered for phylogenetic reconstruction because high recombinational activity rearranges mitochondrial gene orders too frequently. Here we report that an ancient gene continuity, the nad5‐nad4‐nad2 gene arrangement, is conserved among the bryophyte lineages: mosses, liverworts, and hornworts. The nad4‐nad2 spacer is surprisingly conserved at a size of only 26 bp in all three bryophyte lineages. In striking contrast, the small ancestral nad5‐nad4 spacer, of only 57 bp in the alga Chara, is significantly increased in size, to about 600 bp in mosses and 1000–1300 bp in liverworts, and even exceeds 3000 bp in hornworts. A large group II intron fragment and a nad6 pseudogene sequence, respectively, contribute to the expanded spacer sizes in liverworts and in hornworts. The small nad4‐nad2 intergenic region is retained in the lycophyte Isoetes lacustris, whereas no linkage between nad5 and nad4 could be detected in this quillwort. Given its size and sequence variability, the intergenic region between nad5 and nad4 holds promise as a locus for phylogenetic analyses within the bryophyte lineages.

Tracing Plant Mitochondrial DNA Evolution: Rearrangements of the Ancient Mitochondrial Gene Cluster trnA-trnT-nad7 in Liverwort Phylogeny

Whereas frequent recombination characterizes flowering plant mitochondrial genomes, some mitochondrial gene arrangements may, in contrast, be conserved between streptophyte algae and early land plant clades (bryophytes). Here we explore the evolutionary fate of the mitochondrial gene arrangement trnA-trnT-nad7, which is conserved among the alga Chara, the moss Physcomitrella, and the liverwort Marchantia, although trnT is inverted in orientation in the latter. Surprisingly, we now find that the Chara-type gene arrangement is generally conserved in mosses, but that trnT is lacking between trnA and nad7 in all simple-thalloid and leafy (jungermanniid) liverworts. The ancient gene continuity trnA-trnT-nad7 is, however, conserved in Blasia, representing the sister lineage to all other complex-thalloid (marchantiid) liverworts. The recombinogenic insertion of short sequence stretches, including nad5 and rps7 pseudogene fragments copied from elsewhere in the liverwort mtDNA, likely mediated a subsequent inversion of trnT and flanking sequences in a basal grade of marchantiid liverworts, which was then followed by an independent secondary loss of trnT in derived marchantiid taxa later in evolution. In contrast to the previously observed extreme degree of coding sequence conservation and the assumed absence of active recombination in Marchantia mtDNA, this now reveals a surprisingly dynamic evolution of marchantiid liverwort mitochondrial genomes.

Exclusive conservation of mitochondrial group II intron nad4i548 among liverworts and its use for phylogenetic studies in this ancient plant clade

Liverworts occupy a pivotal position in land plant (embryophyte) phylogeny as the presumed earliest-branching major clade, sister to all other land plants, including the mosses, hornworts, lycophytes, monilophytes and seed plants. Molecular support for this earliest dichotomy in land plant phylogeny comes from strikingly different occurrences of introns in mitochondrial genes distinguishing liverworts from all other embryophytes. Exceptionally, however, the nad5 gene--the mitochondrial locus hitherto used most widely to elucidate early land plant phylogeny--carries a group I type intron that is shared between liverworts and mosses. We here explored whether a group II intron, the other major type of organellar intron, would similarly be conserved in position across the entire diversity of extant liverworts and could be of use for phylogenetic analyses in this supposedly most ancient embryophyte clade. To this end, we investigated the nad4 gene as a candidate locus possibly featuring different introns in liverworts as opposed to the non-liverwort embryophyte (NLE) lineage. We indeed found group II intron nad4i548 universally conserved in a wide phylogenetic sampling of 55 liverwort taxa, confirming clade specificity and surprising evolutionary stability of plant mitochondrial introns. As expected, intron nad4i548g2 carries phylogenetic information in its variable sequences, which confirms and extends previous cladistic insights on liverwort evolution. We integrate the new nad4 data with those of the previously established mitochondrial nad5 and the chloroplast rbcL and rps4 genes and present a phylogeny based on the fused datasets. Notably, the phylogenetic analyses suggest a reconsideration of previous phylogenetic and taxonomic assignments for the genera Calycularia and Mylia and resolve a sister group relationship of Ptilidiales and Porellales.