Your search keyword '"Durnford DG"' showing total 7 results

1. Algal genomes reveal evolutionary mosaicism and the fate of nucleomorphs.

Author

Curtis BA, Tanifuji G, Burki F, Gruber A, Irimia M, Maruyama S, Arias MC, Ball SG, Gile GH, Hirakawa Y, Hopkins JF, Kuo A, Rensing SA, Schmutz J, Symeonidi A, Elias M, Eveleigh RJ, Herman EK, Klute MJ, Nakayama T, Oborník M, Reyes-Prieto A, Armbrust EV, Aves SJ, Beiko RG, Coutinho P, Dacks JB, Durnford DG, Fast NM, Green BR, Grisdale CJ, Hempel F, Henrissat B, Höppner MP, Ishida K, Kim E, Kořený L, Kroth PG, Liu Y, Malik SB, Maier UG, McRose D, Mock T, Neilson JA, Onodera NT, Poole AM, Pritham EJ, Richards TA, Rocap G, Roy SW, Sarai C, Schaack S, Shirato S, Slamovits CH, Spencer DF, Suzuki S, Worden AZ, Zauner S, Barry K, Bell C, Bharti AK, Crow JA, Grimwood J, Kramer R, Lindquist E, Lucas S, Salamov A, McFadden GI, Lane CE, Keeling PJ, Gray MW, Grigoriev IV, and Archibald JM

Subjects

Algal Proteins genetics, Algal Proteins metabolism, Alternative Splicing genetics, Cercozoa cytology, Cercozoa metabolism, Cryptophyta cytology, Cryptophyta metabolism, Cytosol metabolism, Gene Duplication genetics, Gene Transfer, Horizontal genetics, Genes, Essential genetics, Genome, Mitochondrial genetics, Genome, Plant genetics, Genome, Plastid genetics, Molecular Sequence Data, Phylogeny, Protein Transport, Proteome genetics, Proteome metabolism, Transcriptome genetics, Cell Nucleus genetics, Cercozoa genetics, Cryptophyta genetics, Evolution, Molecular, Genome genetics, Mosaicism, Symbiosis genetics

Abstract

Cryptophyte and chlorarachniophyte algae are transitional forms in the widespread secondary endosymbiotic acquisition of photosynthesis by engulfment of eukaryotic algae. Unlike most secondary plastid-bearing algae, miniaturized versions of the endosymbiont nuclei (nucleomorphs) persist in cryptophytes and chlorarachniophytes. To determine why, and to address other fundamental questions about eukaryote-eukaryote endosymbiosis, we sequenced the nuclear genomes of the cryptophyte Guillardia theta and the chlorarachniophyte Bigelowiella natans. Both genomes have >21,000 protein genes and are intron rich, and B. natans exhibits unprecedented alternative splicing for a single-celled organism. Phylogenomic analyses and subcellular targeting predictions reveal extensive genetic and biochemical mosaicism, with both host- and endosymbiont-derived genes servicing the mitochondrion, the host cell cytosol, the plastid and the remnant endosymbiont cytosol of both algae. Mitochondrion-to-nucleus gene transfer still occurs in both organisms but plastid-to-nucleus and nucleomorph-to-nucleus transfers do not, which explains why a small residue of essential genes remains locked in each nucleomorph.

Published

2012

2. Cyanophora paradoxa genome elucidates origin of photosynthesis in algae and plants.

Author

Price DC, Chan CX, Yoon HS, Yang EC, Qiu H, Weber AP, Schwacke R, Gross J, Blouin NA, Lane C, Reyes-Prieto A, Durnford DG, Neilson JA, Lang BF, Burger G, Steiner JM, Löffelhardt W, Meuser JE, Posewitz MC, Ball S, Arias MC, Henrissat B, Coutinho PM, Rensing SA, Symeonidi A, Doddapaneni H, Green BR, Rajah VD, Boore J, and Bhattacharya D

Subjects

Biological Evolution, Cyanobacteria genetics, Gene Transfer, Horizontal, Genes, Bacterial, Molecular Sequence Data, Phylogeny, Symbiosis, Cyanophora genetics, Evolution, Molecular, Genome, Plant, Photosynthesis genetics

Abstract

The primary endosymbiotic origin of the plastid in eukaryotes more than 1 billion years ago led to the evolution of algae and plants. We analyzed draft genome and transcriptome data from the basally diverging alga Cyanophora paradoxa and provide evidence for a single origin of the primary plastid in the eukaryote supergroup Plantae. C. paradoxa retains ancestral features of starch biosynthesis, fermentation, and plastid protein translocation common to plants and algae but lacks typical eukaryotic light-harvesting complex proteins. Traces of an ancient link to parasites such as Chlamydiae were found in the genomes of C. paradoxa and other Plantae. Apparently, Chlamydia-like bacteria donated genes that allow export of photosynthate from the plastid and its polymerization into storage polysaccharide in the cytosol.

Published

2012

3. Evolutionary distribution of light-harvesting complex-like proteins in photosynthetic eukaryotes.

Author

Neilson JA and Durnford DG

Subjects

Chlorophyll metabolism, Cryptophyta genetics, Cryptophyta metabolism, Eukaryota metabolism, Genome, Light-Harvesting Protein Complexes chemistry, Photosynthesis physiology, Protein Binding, Protein Interaction Domains and Motifs genetics, Protein Structure, Secondary genetics, Eukaryota genetics, Evolution, Molecular, Light-Harvesting Protein Complexes genetics, Photosynthesis genetics

Abstract

Light-harvesting-like (LIL) proteins are low-molecular-mass membrane proteins related to the light-harvesting complexes, which form the dominant antenna system in most photosynthetic eukaryotes. To analyze the LIL protein family, we mined a number of publicly available databases to identify members of this family in a broad range of organisms. LIL proteins are diverse, having one to three predicted transmembrane helices. One- and two-helix LIL proteins were found in all the major photosynthetic eukaryote lineages (glaucophytes, red algae, and green algae) and are particularly well conserved in the green algae and land plants. In most cases, however, these proteins are not conserved between major lineages, and in some cases appear to have evolved independently. Three-helix LIL proteins are well conserved within the gymnosperms and angiosperms, but are much more divergent, and have been duplicated multiple times, in the green algae and bryophytes. We also identified a novel LIL protein in two Micromonas strains that contains a fourth hydrophobic region. This analysis identifies conserved members of the LIL protein family, signifying their importance to photosynthetic eukaryotes. It also indicates that classification of these proteins based on structural characteristics alone inadequately reflects the evolutionary history observed in this complex protein family.

Published

2010

4. Euglena light-harvesting complexes are encoded by multifarious polyprotein mRNAs that evolve in concert.

Author

Koziol AG and Durnford DG

Subjects

Algal Proteins genetics, Animals, Multigene Family genetics, Protozoan Proteins genetics, Euglena gracilis genetics, Evolution, Molecular, Light-Harvesting Protein Complexes genetics, RNA, Algal genetics, RNA, Messenger genetics, RNA, Protozoan genetics

Abstract

Light-harvesting complexes (LHCs) are a superfamily of chlorophyll- and carotenoid-binding proteins that are responsible for the capture of light energy and its transfer to the photosynthetic reaction centers. Unlike those of most eukaryotes, the LHCs of Euglena gracilis are translated from large mRNAs, producing polyprotein precursors consisting of multiple concatenated LHC subunits that are separated by conserved decapeptide linkers. These precursors are posttranslationally targeted to the chloroplast and cleaved into individual proteins. We analyzed expressed sequence tags from Euglena to further characterize the structural features of the LHC polyprotein-coding genes and to examine the evolution of this multigene family. Of the 19 different LHC transcriptional units we detected, 17 encoded polyproteins composed of both tandem and nontandem repeats of LHC subunits; organizations that likely occurred through unequal crossing-over. Of the 2 nonpolyprotein-encoding LHC transcripts detected, 1 evolved from the truncation of a polyprotein-coding gene. Duplication of LHC polyprotein-coding genes was particularly important in the LHCI gene family where multiple paralogous sequences were detected. Intriguingly, several of the individual LHC-coding subunits both within and between transcriptional units appeared to be evolving in concert, suggesting that gene conversion has been a significant mechanism for LHC evolution in Euglena.

Published

2008

5. A complex and punctate distribution of three eukaryotic genes derived by lateral gene transfer.

Author

Rogers MB, Watkins RF, Harper JT, Durnford DG, Gray MW, and Keeling PJ

Subjects

Animals, Bacteria enzymology, Bacteria genetics, Bacterial Proteins genetics, DNA genetics, Expressed Sequence Tags, Genes, Bacterial, Molecular Sequence Data, Species Specificity, Carbohydrate Epimerases genetics, Conserved Sequence genetics, Eukaryotic Cells enzymology, Evolution, Molecular, Gene Transfer, Horizontal, Genes, Glyceraldehyde 3-Phosphate Dehydrogenase (NADP+) genetics, Glyceraldehyde-3-Phosphate Dehydrogenase (NADP+)(Phosphorylating) genetics, Transketolase genetics

Abstract

Background: Lateral gene transfer is increasingly invoked to explain phylogenetic results that conflict with our understanding of organismal relationships. In eukaryotes, the most common observation interpreted in this way is the appearance of a bacterial gene (one that is not clearly derived from the mitochondrion or plastid) in a eukaryotic nuclear genome. Ideally such an observation would involve a single eukaryote or a small group of related eukaryotes encoding a gene from a specific bacterial lineage., Results: Here we show that several apparently simple cases of lateral transfer are actually more complex than they originally appeared: in these instances we find that two or more distantly related eukaryotic groups share the same bacterial gene, resulting in a punctate distribution. Specifically, we describe phylogenies of three core carbon metabolic enzymes: transketolase, glyceraldehyde-3-phosphate dehydrogenase and ribulose-5-phosphate-3-epimerase. Phylogenetic trees of each of these enzymes includes a strongly-supported clade consisting of several eukaryotes that are distantly related at the organismal level, but whose enzymes are apparently all derived from the same lateral transfer. With less sampling any one of these examples would appear to be a simple case of bacterium-to-eukaryote lateral transfer; taken together, their evolutionary histories cannot be so simple. The distributions of these genes may represent ancient paralogy events or genes that have been transferred from bacteria to an ancient ancestor of the eukaryotes that retain them. They may alternatively have been transferred laterally from a bacterium to a single eukaryotic lineage and subsequently transferred between distantly related eukaryotes., Conclusion: Determining how complex the distribution of a transferred gene is depends on the sampling available. These results show that seemingly simple cases may be revealed to be more complex with greater sampling, suggesting many bacterial genes found in eukaryotic genomes may have a punctate distribution.

Published

2007

6. A phylogenetic assessment of the eukaryotic light-harvesting antenna proteins, with implications for plastid evolution.

Author

Durnford DG, Deane JA, Tan S, McFadden GI, Gantt E, and Green BR

Subjects

Amino Acid Sequence, Carrier Proteins chemistry, Molecular Sequence Data, Multigene Family, Photosystem II Protein Complex, Plants classification, Sequence Homology, Amino Acid, Carrier Proteins genetics, Chloroplasts genetics, Evolution, Molecular, Light-Harvesting Protein Complexes, Photosynthetic Reaction Center Complex Proteins genetics, Phylogeny, Plants genetics

Abstract

The light-harvesting complexes (LHCs) are a superfamily of chlorophyll-binding proteins present in all photosynthetic eukaryotes. The Lhc genes are nuclear-encoded, yet the pigment-protein complexes are localized to the thylakoid membrane and provide a marker to follow the evolutionary paths of plastids with different pigmentation. The LHCs are divided into the chlorophyll a/b-binding proteins of the green algae, euglenoids, and higher plants and the chlorophyll a/c-binding proteins of various algal taxa. This work examines the phylogenetic position of the LHCs from three additional taxa: the rhodophytes, the cryptophytes, and the chlorarachniophytes. Phylogenetic analysis of the LHC sequences provides strong statistical support for the clustering of the rhodophyte and cryptomonad LHC sequences within the chlorophyll a/c-binding protein lineage, which includes the fucoxanthin-chlorophyll proteins (FCP) of the heterokonts and the intrinsic peridinin-chlorophyll proteins (iPCP) of the dinoflagellates. These associations suggest that plastids from the heterokonts, haptophytes, cryptomonads, and the dinoflagellate, Amphidinium, evolved from a red algal-like ancestor. The Chlorarachnion LHC is part of the chlorophyll a/b-binding protein assemblage, consistent with pigmentation, providing further evidence that its plastid evolved from a green algal secondary endosymbiosis. The Chlorarachnion LHC sequences cluster with the green algal LHCs that are predominantly associated with photosystem II (LHCII). This suggests that the green algal endosymbiont that evolved into the Chlorarachnion plastid was acquired following the emergence of distinct LHCI and LHCII complexes.

Published

1999

7. The fucoxanthin-chlorophyll proteins from a chromophyte alga are part of a large multigene family: structural and evolutionary relationships to other light harvesting antennae.

Author

Durnford DG, Aebersold R, and Green BR

Subjects

Amino Acid Sequence, Carotenoids analogs & derivatives, Carotenoids metabolism, Chlorophyll metabolism, Chlorophyll A, DNA, Complementary, Eukaryota chemistry, Eukaryota classification, Models, Molecular, Molecular Sequence Data, Photosynthetic Reaction Center Complex Proteins chemistry, Photosynthetic Reaction Center Complex Proteins classification, Phylogeny, Protein Conformation, Sequence Homology, Amino Acid, Eukaryota genetics, Evolution, Molecular, Light-Harvesting Protein Complexes, Photosynthetic Reaction Center Complex Proteins genetics, Xanthophylls

Abstract

A fucoxanthin-chlorophyll protein (FCP) cDNA from the raphidophyte Heterosigma carterae encodes a 210-amino acid polypeptide that has similarity to other FCPs and to the chlorophyll a/b-binding proteins (CABs) of terrestrial plants and green algae. The putative transit sequence has characteristics that resemble a signal sequence. The Heterosigma fcp genes are part of a large multigene family which includes members encoding at least two significantly different polypeptides (Fcp1, Fcp2). Comparison of the FCP sequences to the recently determined three-dimensional structure of the pea LHC II complex indicates that many of the key amino acids thought to participate in the binding of chlorophyll and the formation of complex-stabilizing ionic interactions are well conserved. Phylogenetic analyses of sequences of light-harvesting proteins shows that the FCPs of several chromophyte phyla form a natural group separate from the intrinisic peridinin-chlorophyll proteins (iPCPs) of the dinoflagellates: Although the FCP and CAB genes shared a common ancestor, these lineages diverged from each other prior to the separation of the CAB LHC I and LHC II sequences in the green algae and terrestrial plants.

Published

1996