David Roy Smith

Phylogeny and molecular evolution of the green algae

The green lineage (Viridiplantae) comprises the green algae and their descendants the land plants, and is one of the major groups of oxygenic photosynthetic eukaryotes. Current hypotheses posit the early divergence of two discrete clades from an ancestral green flagellate. One clade, the Chlorophyta, comprises the early diverging prasinophytes, which gave rise to the core chlorophytes. The other clade, the Streptophyta, includes the charophyte green algae from which the land plants evolved. Multi-marker and genome scale phylogenetic studies have greatly improved our understanding of broad-scale relationships of the green lineage, yet many questions persist, including the branching orders of the prasinophyte lineages, the relationships among core chlorophyte clades (Chlorodendrophyceae, Ulvophyceae, Trebouxiophyceae and Chlorophyceae), and the relationships among the streptophytes. Current phylogenetic hypotheses provide an evolutionary framework for molecular evolutionary studies and comparative genomics. This review summarizes our current understanding of organelle genome evolution in the green algae, genomic insights into the ecology of oceanic picoplanktonic prasinophytes, molecular mechanisms underlying the evolution of complexity in volvocine green algae, and the evolution of genetic codes and the translational apparatus in green seaweeds. Finally, we discuss molecular evolution in the streptophyte lineage, emphasizing the genetic facilitation of land plant origins.

The Marine Microbial Eukaryote Transcriptome Sequencing Project (MMETSP): Illuminating the Functional Diversity of Eukaryotic Life in the Oceans through Transcriptome Sequencing.

Current sampling of genomic sequence data from eukaryotes is relatively poor, biased, and inadequate to address important questions about their biology, evolution, and ecology; this Community Page describes a resource of 700 transcriptomes from marine microbial eukaryotes to help understand their role in the worlds oceans.

Mitochondrial and plastid genome architecture: Reoccurring themes, but significant differences at the extremes.

Mitochondrial and plastid genomes show a wide array of architectures, varying immensely in size, structure, and content. Some organelle DNAs have even developed elaborate eccentricities, such as scrambled coding regions, nonstandard genetic codes, and convoluted modes of posttranscriptional modification and editing. Here, we compare and contrast the breadth of genomic complexity between mitochondrial and plastid chromosomes. Both organelle genomes have independently evolved many of the same features and taken on similar genomic embellishments, often within the same species or lineage. This trend is most likely because the nuclear-encoded proteins mediating these processes eventually leak from one organelle into the other, leading to a high likelihood of processes appearing in both compartments in parallel. However, the complexity and intensity of genomic embellishments are consistently more pronounced for mitochondria than for plastids, even when they are found in both compartments. We explore the evolutionary forces responsible for these patterns and argue that organelle DNA repair processes, mutation rates, and population genetic landscapes are all important factors leading to the observed convergence and divergence in organelle genome architecture.

The Dunaliella salina organelle genomes: large sequences, inflated with intronic and intergenic DNA

BackgroundDunaliella salina Teodoresco, a unicellular, halophilic green alga belonging to the Chlorophyceae, is among the most industrially important microalgae. This is because D. salina can produce massive amounts of β-carotene, which can be collected for commercial purposes, and because of its potential as a feedstock for biofuels production. Although the biochemistry and physiology of D. salina have been studied in great detail, virtually nothing is known about the genomes it carries, especially those within its mitochondrion and plastid. This study presents the complete mitochondrial and plastid genome sequences of D. salina and compares them with those of the model green algae Chlamydomonas reinhardtii and Volvox carteri.ResultsThe D. salina organelle genomes are large, circular-mapping molecules with ~60% noncoding DNA, placing them among the most inflated organelle DNAs sampled from the Chlorophyta. In fact, the D. salina plastid genome, at 269 kb, is the largest complete plastid DNA (ptDNA) sequence currently deposited in GenBank, and both the mitochondrial and plastid genomes have unprecedentedly high intron densities for organelle DNA: ~1.5 and ~0.4 introns per gene, respectively. Moreover, what appear to be the relics of genes, introns, and intronic open reading frames are found scattered throughout the intergenic ptDNA regions -- a trait without parallel in other characterized organelle genomes and one that gives insight into the mechanisms and modes of expansion of the D. salina ptDNA.ConclusionsThese findings confirm the notion that chlamydomonadalean algae have some of the most extreme organelle genomes of all eukaryotes. They also suggest that the events giving rise to the expanded ptDNA architecture of D. salina and other Chlamydomonadales may have occurred early in the evolution of this lineage. Although interesting from a genome evolution standpoint, the D. salina organelle DNA sequences will aid in the development of a viable plastid transformation system for this model alga, and they will complement the forthcoming D. salina nuclear genome sequence, placing D. salina in a group of a select few photosynthetic eukaryotes for which complete genome sequences from all three genetic compartments are available.

Cell to cell signals in plant, animal, and microbial symbiosis

In symbiosis, different organisms have to recognize each other and exchange material and information. While the functional morphology of symbiont cells has extensively been studied little attention has been paid to mutual interactions and cell-to-cell signals. The main topic of the book is the comparison and discussion of the short-distance signals triggering mutualism in animal and plant cells. Thus it provides a) the basis for a better understanding of various aspects of cell compatibility; b) standardisation of a common vocabulary for animal and plant symbiotic biology; c) optimization of experimental techniques for studying signals in symbiosis. The results show the differences and the general principles in the signalling processes of plant, animal and bacterial cells.

A Plastid without a Genome: Evidence from the Nonphotosynthetic Green Algal Genus Polytomella

Genome and transcriptome sequencing of species from the nonphotosynthetic green algal genus Polytomella revealed no evidence of a plastid genome or associated gene expression system and presents an example of a primary plastid-bearing lineage without plastid DNA. Polytomella spp. are free-living, nonphotosynthetic green algae closely related to the model organism Chlamydomonas reinhardtii. Although colorless, Polytomella spp. have a plastid, but it is still unknown whether they harbor a plastid genome. We took a next generation sequencing approach, along with transcriptome sequencing, to search for a plastid genome and an associated gene expression system in Polytomella spp. Illumina sequencing of total DNA from four Polytomella spp. did not produce any recognizable plastid-derived reads but did generate a large number of mitochondrial DNA sequences. Transcriptomic analysis of Polytomella parva uncovered hundreds of putative nuclear-encoded, plastid-targeted proteins, which support the presence of plastid-based metabolic functions, similar to those observed in the plastids of other nonphotosynthetic algae. Conspicuously absent, however, were any plastid-targeted proteins involved in the expression, replication, or repair of plastid DNA. Based on these findings and earlier findings, we argue that the Polytomella genus represents the first well-supported example, to our knowledge, of a primary plastid-bearing lineage without a plastid genome.

The mitochondrial and plastid genomes of Volvox carteri: bloated molecules rich in repetitive DNA

BackgroundThe magnitude of noncoding DNA in organelle genomes can vary significantly; it is argued that much of this variation is attributable to the dissemination of selfish DNA. The results of a previous study indicate that the mitochondrial DNA (mtDNA) of the green alga Volvox carteri abounds with palindromic repeats, which appear to be selfish elements. We became interested in the evolution and distribution of these repeats when, during a cursory exploration of the V. carteri nuclear DNA (nucDNA) and plastid DNA (ptDNA) sequences, we found palindromic repeats with similar structural features to those of the mtDNA. Upon this discovery, we decided to investigate the diversity and evolutionary implications of these palindromic elements by sequencing and characterizing large portions of mtDNA and ptDNA and then comparing these data to the V. carteri draft nuclear genome sequence.ResultsWe sequenced 30 and 420 kilobases (kb) of the mitochondrial and plastid genomes of V. carteri, respectively – resulting in partial assemblies of these genomes. The mitochondrial genome is the most bloated green-algal mtDNA observed to date: ~61% of the sequence is noncoding, most of which is comprised of short palindromic repeats spread throughout the intergenic and intronic regions. The plastid genome is the largest (>420 kb) and most expanded (>80% noncoding) ptDNA sequence yet discovered, with a myriad of palindromic repeats in the noncoding regions, which have a similar size and secondary structure to those of the mtDNA. We found that 15 kb (~0.01%) of the nuclear genome are homologous to the palindromic elements of the mtDNA, and 50 kb (~0.05%) are homologous to those of the ptDNA.ConclusionSelfish elements in the form of short palindromic repeats have propagated in the V. carteri mtDNA and ptDNA, resulting in the distension of these genomes. Copies of these same repeats are also found in a small fraction of the nucDNA, but appear to be inert in this compartment. We conclude that the palindromic repeats in V. carteri represent a single class of selfish DNA and speculate that the derivation of this element involved the lateral gene transfer of an organelle intron that first appeared in the mitochondrial genome, spreading to the ptDNA through mitochondrion-to-plastid DNA migrations, and eventually arrived in the nucDNA through organelle-to-nucleus DNA transfer events. The overall implications of palindromic repeats on the evolution of chlorophyte organelle genomes are discussed.

Correlation between Nuclear Plastid DNA Abundance and Plastid Number Supports the Limited Transfer Window Hypothesis

The abundance of nuclear plastid DNA-like sequences (NUPTs) in nuclear genomes can vary immensely; however, the forces responsible for this variation are poorly understood. “The limited transfer window hypothesis” predicts that species with only one plastid per cell will have fewer NUPTs than those with many plastids per cell, but a lack of genome sequence data from monoplastidic species has made this hypothesis difficult to test. Here, by analyzing newly available genome sequences from diverse mono- and polyplastidic taxa, we show that the hypothesis holds. On average, the polyplastidic species we studied had 80 times more NUPTs than those that were monoplastidic. Moreover, NUPT content was positively related to nuclear genome size, indicating that in addition to plastid number, NUPTs are influenced by the forces controlling the expansion and contraction of noncoding nuclear DNA. These findings are consistent with data on nuclear DNAs of mitochondrial origin (NUMTs), suggesting that similar processes govern the abundance of both NUPTs and NUMTs.

Unparalleled GC content in the plastid DNA of Selaginella.

One of the more conspicuous features of plastid DNA (ptDNA) is its low guanine and cytosine (GC) content. As of February 2009, all completely-sequenced plastid genomes have a GC content below 43% except for the ptDNA of the lycophyte Selaginella uncinata, which is 55% GC. The forces driving the S. uncinata ptDNA towards G and C are undetermined, and it is unknown if other Selaginella species have GC-biased plastid genomes. This study presents the complete ptDNA sequence of Selaginella moellendorffii and compares it with the previously reported S. uncinata plastid genome. Partial ptDNA sequences from 103 different Selaginella species are also described as well as a significant proportion of the S. moellendorffii mitochondrial genome. Moreover, S. moellendorffii express sequence tags are data-mined to estimate levels of plastid and mitochondrial RNA editing. Overall, these data are used to show that: (1) there is a genus-wide GC bias in Selaginella ptDNA, which is most pronounced in South American articulate species; (2) within the Lycopsida class (and among plants in general), GC-biased ptDNA is restricted to the Selaginella genus; (3) the cause of this GC bias is arguably a combination of reduced AT-mutation pressure relative to other plastid genomes and a large number of C-to-U RNA editing sites; and (4) the mitochondrial DNA (mtDNA) of S. moellendorffii is also GC biased (even more so than the ptDNA) and is arguably the most GC-rich organelle genome observed to date—the high GC content of the mtDNA also appears to be influenced by RNA editing. Ultimately, these findings provide convincing support for the earlier proposed theory that the GC content of land-plant organelle DNA is positively correlated and directly connected to levels of organelle RNA editing.

Mitochondrial Genome of the Colorless Green Alga Polytomella capuana: A Linear Molecule with an Unprecedented GC Content

One common observation concerning mitochondrial genomes is that they have a low guanine and cytosine content (GC content); of the complete mitochondrial genome sequences currently available at the National Center for Biotechnology Information (NCBI) (July 2007), the GC content ranges from 13.3% to 53.2% and has an average value of 38%. Here, we present the GC-rich mitochondrial genome (57% GC) of the colorless green alga Polytomella capuana. The disproportion of GC among the different regions of the P. capuana mitochondrial DNA (mtDNA) suggests that a neutral process is responsible for the GC bias. We propose that a biased gene conversion mechanism resulted in the GC-rich state of the P. capuana mtDNA. In addition, our analysis indicates that the P. capuana mitochondrial genome is a single 13-kb linear molecule with telomeres, which have a closed (hairpin-loop) conformation: a novel terminal structure among described linear green-algal mtDNAs. Furthermore, using a series of GC-rich inverted repeats found within the P. capuana mitochondrial genome, we describe recombination-based scenarios of how intact linear mtDNA conformations can be converted into the fragmented forms found in other Polytomella taxa.