The Transcription of Plant Organelle Genomes

Structure and evolution of organelle genomes.

Microbiological Reviews ◽

10.1128/mr.46.2.208-240.1982 ◽

1982 ◽

Vol 46 (2) ◽

pp. 208-240 ◽

Cited By ~ 2

Author(s):

D C Wallace

Keyword(s):

Organelle Genomes

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Differential Segregation Patterns of Sperm Mitochondria in Embryos of the Blue Mussel (Mytilus edulis)

Genetics ◽

10.1093/genetics/166.2.883 ◽

2004 ◽

Vol 166 (2) ◽

pp. 883-894

Author(s):

Liqin Cao ◽

Ellen Kenchington ◽

Eleftherios Zouros

Keyword(s):

Mitochondrial Dna ◽

Mytilus Edulis ◽

Blue Mussel ◽

Uniparental Inheritance ◽

Male Gonad ◽

Doubly Uniparental Inheritance ◽

Organelle Genomes ◽

Somatic Tissues ◽

Tight Linkage ◽

Mitotracker Green

Abstract In Mytilus, females carry predominantly maternal mitochondrial DNA (mtDNA) but males carry maternal mtDNA in their somatic tissues and paternal mtDNA in their gonads. This phenomenon, known as doubly uniparental inheritance (DUI) of mtDNA, presents a major departure from the uniparental transmission of organelle genomes. Eggs of Mytilus edulis from females that produce exclusively daughters and from females that produce mostly sons were fertilized with sperm stained with MitoTracker Green FM, allowing observation of sperm mitochondria in the embryo by epifluorescent and confocal microscopy. In embryos from females that produce only daughters, sperm mitochondria are randomly dispersed among blastomeres. In embryos from females that produce mostly sons, sperm mitochondria tend to aggregate and end up in one blastomere in the two- and four-cell stages. We postulate that the aggregate eventually ends up in the first germ cells, thus accounting for the presence of paternal mtDNA in the male gonad. This is the first evidence for different behaviors of sperm mitochondria in developing embryos that may explain the tight linkage between gender and inheritance of paternal mitochondrial DNA in species with DUI.

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Horizontal Gene Transfer Involving Chloroplasts

International Journal of Molecular Sciences ◽

10.3390/ijms22094484 ◽

2021 ◽

Vol 22 (9) ◽

pp. 4484

Author(s):

Ewa Filip ◽

Lidia Skuza

Keyword(s):

Gene Transfer ◽

Horizontal Gene Transfer ◽

Driving Force ◽

Genetic Material ◽

Adaptive Significance ◽

Chloroplast Genomes ◽

Organelle Genomes ◽

Number Of Genes ◽

Cellular Compartments

Horizontal gene transfer (HGT)- is defined as the acquisition of genetic material from another organism. However, recent findings indicate a possible role of HGT in the acquisition of traits with adaptive significance, suggesting that HGT is an important driving force in the evolution of eukaryotes as well as prokaryotes. It has been noted that, in eukaryotes, HGT is more prevalent than originally thought. Mitochondria and chloroplasts lost a large number of genes after their respective endosymbiotic events occurred. Even after this major content loss, organelle genomes still continue to lose their own genes. Many of these are subsequently acquired by intracellular gene transfer from the original plastid. The aim of our review was to elucidate the role of chloroplasts in the transfer of genes. This review also explores gene transfer involving mitochondrial and nuclear genomes, though recent studies indicate that chloroplast genomes are far more active in HGT as compared to these other two DNA-containing cellular compartments.

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Evaluation of Four Methods to Identify the Homozygotic Sex Chromosome in Small Populations

10.21203/rs.3.rs-892602/v1 ◽

2021 ◽

Author(s):

Charles Christian Riis Hansen ◽

Kristen M. Westfall ◽

Snaebjörn Pálsson

Keyword(s):

Sex Chromosomes ◽

Sex Chromosome ◽

Read Depth ◽

Mapping Method ◽

Small Population ◽

Genomic Variation ◽

Z Chromosome ◽

Effective Population ◽

Organelle Genomes ◽

Heterogametic Sex

Abstract BackgroundWhole genomes are commonly assembled into a collection of scaffolds and often lack annotations of autosomes, sex chromosomes, and organelle genomes (i.e., mitochondrial and chloroplast). As these chromosome types differ in effective population size and can have highly disparate evolutionary histories, it is imperative to take this information into account when analysing genomic variation. Here we assessed the accuracy of four methods for identifying the homogametic sex chromosome in a small population using two whole genome sequences (WGS) and 133 RAD sequences of white-tailed eagles (Haliaeetus albicilla): i) difference in read depth per scaffold in a male and a female, ii) heterozygosity per scaffold in a male and a female, iii) mapping to a reference genome of a related species (chicken) with identified sex chromosomes, and iv) analysis of SNP-loadings from a principal components analysis (PCA), based on the low-depth RADseq data. ResultsThe best performing approach was the reference mapping (method iii), which identified 98.12% of the expected homogametic sex chromosome (Z). The read depth per scaffold (method i) identified 86.41% of the homogametic sex chromosome with few false positives. The SNP-loading scores (method iv) found 78.6% of the Z-chromosome and had a false positive discovery rate of more than 10%. The heterozygosity per scaffold (method ii) did not provide clear results due to a lack of diversity in both the Z and autosomal chromosomes, and potential interference from the heterogametic sex chromosome (W). The evaluation of these methods also revealed 10 Mb of likely PAR and gametologous regions.ConclusionIdentification of the homogametic sex chromosome in a small population is best accomplished by reference mapping or examining read depth differences between sexes.

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Genome expansion via lineage splitting and genome reduction in the cicada endosymbiont Hodgkinia

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1421386112 ◽

2015 ◽

Vol 112 (33) ◽

pp. 10192-10199 ◽

Cited By ~ 45

Author(s):

Matthew A. Campbell ◽

James T. Van Leuven ◽

Russell C. Meister ◽

Kaitlin M. Carey ◽

Chris Simon ◽

...

Keyword(s):

Genome Structure ◽

Structural Diversity ◽

Fold Increase ◽

Genome Reduction ◽

Endosymbiotic Bacteria ◽

Single Genome ◽

Organelle Genomes ◽

Genome Fragmentation ◽

Long Life ◽

Splitting Process

Comparative genomics from mitochondria, plastids, and mutualistic endosymbiotic bacteria has shown that the stable establishment of a bacterium in a host cell results in genome reduction. Although many highly reduced genomes from endosymbiotic bacteria are stable in gene content and genome structure, organelle genomes are sometimes characterized by dramatic structural diversity. Previous results from Candidatus Hodgkinia cicadicola, an endosymbiont of cicadas, revealed that some lineages of this bacterium had split into two new cytologically distinct yet genetically interdependent species. It was hypothesized that the long life cycle of cicadas in part enabled this unusual lineage-splitting event. Here we test this hypothesis by investigating the structure of the Ca. Hodgkinia genome in one of the longest-lived cicadas, Magicicada tredecim. We show that the Ca. Hodgkinia genome from M. tredecim has fragmented into multiple new chromosomes or genomes, with at least some remaining partitioned into discrete cells. We also show that this lineage-splitting process has resulted in a complex of Ca. Hodgkinia genomes that are 1.1-Mb pairs in length when considered together, an almost 10-fold increase in size from the hypothetical single-genome ancestor. These results parallel some examples of genome fragmentation and expansion in organelles, although the mechanisms that give rise to these extreme genome instabilities are likely different.

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Genomic Variation between PRSV Resistant Transgenic SunUp and Its Progenitor Cultivar Sunset

10.21203/rs.2.17159/v2 ◽

2020 ◽

Author(s):

Jingping Fang ◽

Andrew Wood ◽

Youqiang Chen ◽

Jingjing Yue ◽

Ray Ming

Keyword(s):

Spontaneous Mutation ◽

Nuclear Genome ◽

Plastid Dna ◽

High Impact ◽

Genomic Variation ◽

Reliable Estimate ◽

Nucleotide Polymorphisms ◽

Structural Variations ◽

Transgenic Papaya ◽

Organelle Genomes

Abstract Background: The safety of genetically transformed plants remains a subject of scrutiny. Genomic variants in PRSV resistant transgenic papaya will provide evidence to rationally address such concerns. Results: In this study, a total of more than 74 million Illumina reads for progenitor ‘Sunset’ were mapped onto transgenic papaya ‘SunUp’ reference genome. 310,364 single nucleotide polymorphisms (SNPs), 34,071 small Inserts/deletions (InDels) and 1,200 large structural variations (SVs) were detected between ‘Sunset’ and ‘SunUp’. Those variations have an uneven distribution across nine chromosomes in papaya. Only 0.27% of mutations were predicted to be high-impact mutations. ATP-related categories were highly enriched among these high-impact genes. The SNP mutation rate was about 8.4×10-4 per site, comparable with the rate induced by spontaneous mutation over numerous generations. The transition-to-transversion ratio was 1.439 and the predominant mutations were C/G to T/A transitions. Spontaneous mutations were the leading cause of SNPs in transgenic papaya ‘SunUp’. A total of 3,430 nuclear plastid DNA (NUPT) and 2,764 nuclear mitochondrial DNA (NUMT) junction sites have been found in ‘SunUp’, which is proportionally higher than the predicted total NUPT and NUMT junction sites in ‘Sunset’ (3,346 and 2,745, respectively). Among all nuclear organelle DNA (norgDNA) junction sites, 96% of junction sites were shared by ‘SunUp’ and ‘Sunset’. The average identity between ‘SunUp’ specific norgDNA and corresponding organelle genomes was higher than that of norgDNA shared by ‘SunUp’ and ‘Sunset’. Six ‘SunUp’ organelle-like borders of transgenic insertions were nearly identical to corresponding sequences in organelle genomes (98.18~100%). None of the paired-end spans of mapped ‘Sunset’ reads were elongated by any ‘SunUp’ transformation plasmid derived inserts. Significant amounts of DNA were transferred from organelles to the nuclear genome during bombardment, including the six flanking sequences of the three transgenic insertions.Conclusions: Comparative whole-genome analyses between ‘SunUp’ and ‘Sunset’ provide a reliable estimate of genome-wide variations and evidence of organelle-to-nucleus transfer of DNA associated with biolistic transformation.

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Genomic Variation between PRSV Resistant Transgenic SunUp and Its Progenitor Cultivar Sunset Induced by Particle Bombardment Transformation

10.21203/rs.2.17159/v1 ◽

2019 ◽

Author(s):

Jingping Fang ◽

Andrew Wood ◽

Youqiang Chen ◽

Jingjing Yue ◽

Ray Ming

Keyword(s):

Spontaneous Mutation ◽

Nuclear Genome ◽

Plastid Dna ◽

High Impact ◽

Genomic Variation ◽

Reliable Estimate ◽

Nucleotide Polymorphisms ◽

Structural Variations ◽

Transgenic Papaya ◽

Organelle Genomes

Abstract The safety of genetically transformed plants remains a subject of scrutiny. Genomic variants in PRSV resistant transgenic papaya will provide evidence to rationally address such concerns. In this study, a total of more than 74 million Illumina reads for progenitor ‘Sunset’ were mapped onto transgenic papaya ‘SunUp’ reference genome. 310,364 single nucleotide polymorphisms (SNPs), 34,071 Small Inserts/deletions (InDels) and 1,200 large structural variations (SVs) were detected between ‘Sunset’ and ‘SunUp’. Those variations have an uneven distribution across nine chromosomes in papaya. Only 0.27% of mutations were predicted to be high-impact mutations. ATP-related categories were highly enriched among these high-impact genes. The SNP mutation rate was about 8.4×10 -4 per site, comparable with the rate induced by spontaneous mutation over numerous generations. The transition-to-transversion ratio was 1.439 and the predominant mutations were C/G to T/A transitions. Spontaneous mutations were the leading cause of SNPs in transgenic papaya ‘SunUp’. A total of 3,430 nuclear plastid DNA (NUPT) and 2,764 nuclear mitochondrial DNA (NUMT) junction sites have been found in ‘SunUp’, which is proportionally higher than the predicted total NUPT and NUMT junction sites in ‘Sunset’ (3,346 and 2,745, respectively). Among all nuclear organelle DNA (norgDNA) junction sites, 96% of junction sites were shared by ‘SunUp’ and ‘Sunset’. The average identity between ‘SunUp’ specific norgDNA and corresponding organelle genomes was higher than that of norgDNA shared by ‘SunUp’ and ‘Sunset’. Six ‘SunUp’ organelle-like borders of transgenic insertions were nearly identical to corresponding sequences in organelle genomes (98.18~100%). None of the paired-end spans of mapped ‘Sunset’ reads were elongated by any ‘SunUp’ transformation plasmid derived inserts. Significant amounts of DNA were transferred from organelles to the nuclear genome during bombardment, including the six flanking sequences of the three transgenic insertions. Comparative whole-genome analyses between ‘SunUp’ and ‘Sunset’ provide a reliable estimate of genome-wide variations and evidence of organelle-to-nucleus transfer of DNA associated with biolistic transformation.

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Genome Sequences of Both Organelles of the Grapevine Rootstock Cultivar ‘Börner’

Microbiology Resource Announcements ◽

10.1128/mra.01471-19 ◽

2020 ◽

Vol 9 (15) ◽

Cited By ~ 2

Author(s):

Bianca Frommer ◽

Daniela Holtgräwe ◽

Ludger Hausmann ◽

Prisca Viehöver ◽

Bruno Huettel ◽

...

Keyword(s):

Rna Editing ◽

Mitochondrial Genes ◽

Genome Sequences ◽

Content Type ◽

Vitis Riparia ◽

Long Reads ◽

Organelle Genomes

Genomic long reads of the interspecific grapevine rootstock cultivar ‘Börner’ (Vitis riparia GM183 × Vitis cinerea Arnold) were used to assemble its chloroplast and mitochondrion genome sequences. We annotated 133 chloroplast and 172 mitochondrial genes, including the RNA editing sites. The organelle genomes in ‘Börner’ were maternally inherited from Vitis riparia.

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