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2. Genome copy number predicts extreme evolutionary rate variation in plant mitochondrial DNA.

Author

Zwonitzer, Kendra D., Tressel, Lydia G., Zhiqiang Wu, Shenglong Kan, Broz, Amanda K., Mower, Jeffrey P., Ruhlman, Tracey A., Jansen, Robert K., Sloan, Daniel B., and Havird, Justin C.

Subjects
MITOCHONDRIAL DNA, PLANT DNA, PLANT variation, NUCLEAR DNA, HOMOLOGOUS recombination, GENOMES
Abstract

Nuclear and organellar genomes can evolve at vastly different rates despite occupying the same cell. In most bilaterian animals, mitochondrial DNA (mtDNA) evolves faster than nuclear DNA, whereas this trend is generally reversed in plants. However, in some exceptional angiosperm clades, mtDNA substitution rates have increased up to 5,000-fold compared with closely related lineages. The mechanisms responsible for this acceleration are generally unknown. Because plants rely on homologous recombination to repair mtDNA damage, we hypothesized that mtDNA copy numbers may predict evolutionary rates, as lower copy numbers may provide fewer templates for such repair mechanisms. In support of this hypothesis, we found that copy number explains 47% of the variation in synonymous substitution rates of mtDNA across 60 diverse seed plant species representing ~300 million years of evolution. Copy number was also negatively correlated with mitogenome size, which may be a cause or consequence of mutation rate variation. Both relationships were unique to mtDNA and not observed in plastid DNA. These results suggest that homologous recombinational repair plays a role in driving mtDNA substitution rates in plants and may explain variation in mtDNA evolution more broadly across eukaryotes. Our findings also contribute to broader questions about the relationships between mutation rates, genome size, selection efficiency, and the drift-barrier hypothesis. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Plastid Genome Assembly Using Long‐read data.

Author

Zhou, Wenbin, Armijos, Carolina E., Lee, Chaehee, Lu, Ruisen, Wang, Jeremy, Ruhlman, Tracey A., Jansen, Robert K., Jones, Alan M., and Jones, Corbin D.

Subjects
GENOMES, CHLOROPLAST DNA, PHANEROGAMS
Abstract

Although plastid genome (plastome) structure is highly conserved across most seed plants, investigations during the past two decades have revealed several disparately related lineages that experienced substantial rearrangements. Most plastomes contain a large inverted repeat and two single‐copy regions, and a few dispersed repeats; however, the plastomes of some taxa harbour long repeat sequences (>300 bp). These long repeats make it challenging to assemble complete plastomes using short‐read data, leading to misassemblies and consensus sequences with spurious rearrangements. Single‐molecule, long‐read sequencing has the potential to overcome these challenges, yet there is no consensus on the most effective method for accurately assembling plastomes using long‐read data. We generated a pipeline, plastid Genome Assembly Using Long‐read data (ptGAUL), to address the problem of plastome assembly using long‐read data from Oxford Nanopore Technologies (ONT) or Pacific Biosciences platforms. We demonstrated the efficacy of the ptGAUL pipeline using 16 published long‐read data sets. We showed that ptGAUL quickly produces accurate and unbiased assemblies using only ~50× coverage of plastome data. Additionally, we deployed ptGAUL to assemble four new Juncus (Juncaceae) plastomes using ONT long reads. Our results revealed many long repeats and rearrangements in Juncus plastomes compared with basal lineages of Poales. The ptGAUL pipeline is available on GitHub: https://github.com/Bean061/ptgaul. [ABSTRACT FROM AUTHOR]

Published
2023
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13. Highly Resolved Papilionoid Legume Phylogeny Based on Plastid Phylogenomics.

Author

Choi, In-Su, Cardoso, Domingos, de Queiroz, Luciano P., de Lima, Haroldo C., Lee, Chaehee, Ruhlman, Tracey A., Jansen, Robert K., and Wojciechowski, Martin F.

Subjects
PHYLOGENY, LEGUMES, ANGIOSPERMS, AMINO acids, SPECIES, TREES
Abstract

Comprising 501 genera and around 14,000 species, Papilionoideae is not only the largest subfamily of Fabaceae (Leguminosae; legumes), but also one of the most extraordinarily diverse clades among angiosperms. Papilionoids are a major source of food and forage, are ecologically successful in all major biomes, and display dramatic variation in both floral architecture and plastid genome (plastome) structure. Plastid DNA-based phylogenetic analyses have greatly improved our understanding of relationships among the major groups of Papilionoideae, yet the backbone of the subfamily phylogeny remains unresolved. In this study, we sequenced and assembled 39 new plastomes that are covering key genera representing the morphological diversity in the subfamily. From 244 total taxa, we produced eight datasets for maximum likelihood (ML) analyses based on entire plastomes and/or concatenated sequences of 77 protein-coding sequences (CDS) and two datasets for multispecies coalescent (MSC) analyses based on individual gene trees. We additionally produced a combined nucleotide dataset comprising CDS plus matK gene sequences only, in which most papilionoid genera were sampled. A ML tree based on the entire plastome maximally supported all of the deep and most recent divergences of papilionoids (223 out of 236 nodes). The Swartzieae, ADA (Angylocalyceae, Dipterygeae, and Amburaneae), Cladrastis, Andira, and Exostyleae clades formed a grade to the remainder of the Papilionoideae, concordant with nine ML and two MSC trees. Phylogenetic relationships among the remaining five papilionoid lineages (Vataireoid, Dermatophyllum , Genistoid s.l., Dalbergioid s.l., and Baphieae + Non-Protein Amino Acid Accumulating or NPAAA clade) remained uncertain, because of insufficient support and/or conflicting relationships among trees. Our study fully resolved most of the deep nodes of Papilionoideae, however, some relationships require further exploration. More genome-scale data and rigorous analyses are needed to disentangle phylogenetic relationships among the five remaining lineages. [ABSTRACT FROM AUTHOR]

Published
2022
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14. Effects of Salt Stress on Transcriptional and Physiological Responses in Barley Leaves with Contrasting Salt Tolerance.

Author

Nefissi Ouertani, Rim, Arasappan, Dhivya, Ruhlman, Tracey A., Ben Chikha, Mariem, Abid, Ghassen, Mejri, Samiha, Ghorbel, Abdelwahed, and Jansen, Robert K.

Subjects
PHYSIOLOGICAL stress, BETAINE, BARLEY, ALDEHYDE dehydrogenase, GENE regulatory networks, CHLOROPHYLL spectra, SALT
Abstract

Salt stress negatively impacts crop production worldwide. Genetic diversity among barley (Hordeum vulgare) landraces adapted to adverse conditions should provide a valuable reservoir of tolerance genes for breeding programs. To identify molecular and biochemical differences between barley genotypes, transcriptomic and antioxidant enzyme profiles along with several morpho-physiological features were compared between salt-tolerant (Boulifa) and salt-sensitive (Testour) genotypes subjected to salt stress. Decreases in biomass, photosynthetic parameters, and relative water content were low in Boulifa compared to Testour. Boulifa had better antioxidant protection against salt stress than Testour, with greater antioxidant enzymes activities including catalase, superoxide dismutase, and guaiacol peroxidase. Transcriptome assembly for both genotypes revealed greater accumulation of differentially expressed transcripts in Testour compared to Boulifa, emphasizing the elevated transcriptional response in Testour following salt exposure. Various salt-responsive genes, including the antioxidant catalase 3, the osmoprotectant betaine aldehyde dehydrogenase 2, and the transcription factors MYB20 and MYB41, were induced only in Boulifa. By contrast, several genes associated with photosystems I and II, and light receptor chlorophylls A and B, were more repressed in Testour. Co-expression network analysis identified specific gene modules correlating with differences in genotypes and morpho-physiological traits. Overall, salinity-induced differential transcript accumulation underlies the differential morpho-physiological response in both genotypes and could be important for breeding salt tolerance in barley. [ABSTRACT FROM AUTHOR]

Published
2022
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15. Born in the mitochondrion and raised in the nucleus: evolution of a novel tandem repeat family in Medicago polymorpha (Fabaceae).

Author

Choi, In‐Su, Wojciechowski, Martin F., Steele, Kelly P., Hunter, Sarah G., Ruhlman, Tracey A., and Jansen, Robert K.

Subjects
TANDEM repeats, MITOCHONDRIA, CHLOROPLAST DNA, PLANT genomes, CELL nuclei, MEDICAGO, PLANT mitochondria
Abstract

SUMMARY: Plant nuclear genomes harbor sequence elements derived from the organelles (mitochondrion and plastid) through intracellular gene transfer (IGT). Nuclear genomes also show a dramatic range of repeat content, suggesting that any sequence can be readily amplified. These two aspects of plant nuclear genomes are well recognized but have rarely been linked. Through investigation of 31 Medicago taxa we detected exceptionally high post‐IGT amplification of mitochondrial (mt) DNA sequences containing rps10 in the nuclear genome of Medicago polymorpha and closely related species. The amplified sequences were characterized as tandem arrays of five distinct repeat motifs (2157, 1064, 987, 971, and 587 bp) that have diverged from the mt genome (mitogenome) in the M. polymorpha nuclear genome. The mt rps10‐like arrays were identified in seven loci (six intergenic and one telomeric) of the nuclear chromosome assemblies and were the most abundant tandem repeat family, representing 1.6–3.0% of total genomic DNA, a value approximately three‐fold greater than the entire mitogenome in M. polymorpha. Compared to a typical mt gene, the mt rps10‐like sequence coverage level was 691.5–7198‐fold higher in M. polymorpha and closely related species. In addition to the post‐IGT amplification, our analysis identified the canonical telomeric repeat and the species‐specific satellite arrays that are likely attributable to an ancestral chromosomal fusion in M. polymorpha. A possible relationship between chromosomal instability and the mt rps10‐like tandem repeat family in the M. polymorpha clade is discussed. Significance Statement: Mitogenome sequences as repetitive DNAs in nuclear genomes were reported before in eukaryotic evolution but often have been overlooked in plants. We discovered a lineage‐specific tandem repeat family of mitochondrial origin in the nuclear genome of Medicago polymorpha and closely related species that sheds light on an obscure process—intracellular gene transfer and extensive amplification in the plant cell nucleus, which may be associated with chromosomal instability in this clade. [ABSTRACT FROM AUTHOR]

Published
2022
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16. The chicken or the egg? Plastome evolution and an independent loss of the inverted repeat in papilionoid legumes.

Author

Lee, Chaehee, Choi, In‐Su, Cardoso, Domingos, de Lima, Haroldo C., de Queiroz, Luciano P., Wojciechowski, Martin F., Jansen, Robert K., and Ruhlman, Tracey A.

Subjects
LEGUMES, CHLOROPLAST DNA, MEDICAGO truncatula, ANGIOSPERMS, CHROMOSOME inversions, SPECIES, FAMILY history (Sociology), GENOMES
Abstract

Summary: The plastid genome (plastome), while surprisingly constant in gene order and content across most photosynthetic angiosperms, exhibits variability in several unrelated lineages. During the diversification history of the legume family Fabaceae, plastomes have undergone many rearrangements, including inversions, expansion, contraction and loss of the typical inverted repeat (IR), gene loss and repeat accumulation in both shared and independent events. While legume plastomes have been the subject of study for some time, most work has focused on agricultural species in the IR‐lacking clade (IRLC) and the plant model Medicago truncatula. The subfamily Papilionoideae, which contains virtually all of the agricultural legume species, also comprises most of the plastome variation detected thus far in the family. In this study three non‐papilioniods were included among 34 newly sequenced legume plastomes, along with 33 publicly available sequences, to assess plastome structural evolution in the subfamily. In an effort to examine plastome variation across the subfamily, approximately 20% of the sampling represents the IRLC with the remainder selected to represent the early‐branching papilionoid clades. A number of IR‐related and repeat‐mediated changes were identified and examined in a phylogenetic context. Recombination between direct repeats associated with ycf2 resulted in intraindividual plastome heteroplasmy. Although loss of the IR has not been reported in legumes outside of the IRLC, one genistoid taxon was found to completely lack the typical plastome IR. The role of the IR and non‐IR repeats in the progression of plastome change is discussed. Significance Statement: Comparative genomic approaches employing plastid genomes (plastomes) have revealed that they are more variable across angiosperms than previously suggested. This study examined 64 species of Fabaceae, including 34 newly sequenced taxa, to explore plastome structural evolution of the subfamily Papilionoideae in a phylogenetic context. Several unusual features of the inverted repeat highlight the importance of recombination in plastome structural changes within and between individuals and species. [ABSTRACT FROM AUTHOR]

Published
2021
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17. Complete plastid genome sequence of Daucus carota: Implications for biotechnology and phylogeny of angiosperms

Author

Ruhlman Tracey, Lee Seung-Bum, Jansen Robert K, Hostetler Jessica B, Tallon Luke J, Town Christopher D, and Daniell Henry

Subjects
Biotechnology, TP248.13-248.65, Genetics, QH426-470
Abstract

Abstract Background Carrot (Daucus carota) is a major food crop in the US and worldwide. Its capacity for storage and its lifecycle as a biennial make it an attractive species for the introduction of foreign genes, especially for oral delivery of vaccines and other therapeutic proteins. Until recently efforts to express recombinant proteins in carrot have had limited success in terms of protein accumulation in the edible tap roots. Plastid genetic engineering offers the potential to overcome this limitation, as demonstrated by the accumulation of BADH in chromoplasts of carrot taproots to confer exceedingly high levels of salt resistance. The complete plastid genome of carrot provides essential information required for genetic engineering. Additionally, the sequence data add to the rapidly growing database of plastid genomes for assessing phylogenetic relationships among angiosperms. Results The complete carrot plastid genome is 155,911 bp in length, with 115 unique genes and 21 duplicated genes within the IR. There are four ribosomal RNAs, 30 distinct tRNA genes and 18 intron-containing genes. Repeat analysis reveals 12 direct and 2 inverted repeats ≥ 30 bp with a sequence identity ≥ 90%. Phylogenetic analysis of nucleotide sequences for 61 protein-coding genes using both maximum parsimony (MP) and maximum likelihood (ML) were performed for 29 angiosperms. Phylogenies from both methods provide strong support for the monophyly of several major angiosperm clades, including monocots, eudicots, rosids, asterids, eurosids II, euasterids I, and euasterids II. Conclusion The carrot plastid genome contains a number of dispersed direct and inverted repeats scattered throughout coding and non-coding regions. This is the first sequenced plastid genome of the family Apiaceae and only the second published genome sequence of the species-rich euasterid II clade. Both MP and ML trees provide very strong support (100% bootstrap) for the sister relationship of Daucus with Panax in the euasterid II clade. These results provide the best taxon sampling of complete chloroplast genomes and the strongest support yet for the sister relationship of Caryophyllales to the asterids. The availability of the complete plastid genome sequence should facilitate improved transformation efficiency and foreign gene expression in carrot through utilization of endogenous flanking sequences and regulatory elements.

Published
2006
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18. Caught in the Act: Variation in plastid genome inverted repeat expansion within and between populations of Medicago minima.

Author

Choi, In‐Su, Jansen, Robert, and Ruhlman, Tracey

Subjects
MEDICAGO, INVERTED repeats (Genetics), POLYMERASE chain reaction, GENOMES, MAXIMA & minima, LEGUMES, GENE conversion
Abstract

The inverted repeat (IR) lacking clade (IRLC) is a monophyletic group within the Papilionoideae subfamily of Fabaceae where plastid genomes (plastomes) do not contain the large IR typical of land plants. Recently, an IRLC legume, Medicago minima, was found to have regrown a ~9 kb IR that contained a number of canonical IR genes, and closely related M. lupulina contained an incomplete IR of ~425 bp. Complete plastomes were generated for seven additional species, putative members of the M. minima clade. Polymerase chain reaction was employed to investigate the presence of the IR across M. minima and M. lupulina including individuals of nine and eight Eurasian and North African accessions and 15 and 14 Texas populations, respectively. While no sequence similar to the ~9 kb IR was detected among the seven newly sequenced plastomes, all Eurasian and North African accessions of M. minima contained the IR. Variation in IR extent was detected within and between the Texas populations. Expansions of 13 bp and 11 bp occurred at the boundaries of both IR/small single‐copy regions, and populations had one or the other expansion, but not both. Expansion of the IR was not detected in the accessions from Eurasia and North Africa suggesting recent mutations yielded at least two additional plastid haplotypes in M. minima. [ABSTRACT FROM AUTHOR]

Published
2020
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19. Rampant Nuclear Transfer and Substitutions of Plastid Genes in Passiflora.

Author

Shrestha, Bikash, Gilbert, Lawrence E, Ruhlman, Tracey A, and Jansen, Robert K

Subjects
PASSIFLORA, MOLECULAR motor proteins, GENES, RNA polymerases
Abstract

Gene losses in plastid genomes (plastomes) are often accompanied by functional transfer to the nucleus or substitution of an alternative nuclear-encoded gene. Despite the highly conserved gene content in plastomes of photosynthetic land plants, recent gene loss events have been documented in several disparate angiosperm clades. Among these lineages, Passiflora lacks several essential ribosomal genes, rps7 , rps16 , rpl20 , rpl22 , and rpl32 , the two largest plastid genes, ycf1 and ycf2 , and has a highly divergent rpoA. Comparative transcriptome analyses were performed to determine the fate of the missing genes in Passiflora. Putative functional transfers of rps7 , rpl22 , and rpl32 to nucleus were detected, with the nuclear transfer of rps7 , representing a novel event in angiosperms. Plastid-encoded rps7 was transferred into the intron of a nuclear-encoded plastid-targeted thioredoxin m-type gene, acquiring its plastid transit peptide (TP). Plastid rpl20 likely experienced a novel substitution by a duplicated, nuclear-encoded mitochondrial-targeted rpl20 that has a similar gene structure. Additionally, among rosids, evidence for a third independent transfer of rpl22 in Passiflora was detected that gained a TP from a nuclear gene containing an organelle RNA recognition motif. Nuclear transcripts representing rpoA , ycf1 , and ycf2 were not detected. Further analyses suggest that the divergent rpoA remains functional and that the gene is under positive or purifying selection in different clades. Comparative analyses indicate that alternative translocon and motor protein complexes may have substituted for the loss of ycf1 and ycf2 in Passiflora. [ABSTRACT FROM AUTHOR]

Published
2020
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20. Unprecedented Intraindividual Structural Heteroplasmy in Eleocharis (Cyperaceae, Poales) Plastomes.

Author

Lee, Chaehee, Ruhlman, Tracey A, and Jansen, Robert K

Subjects
*CYPERACEAE, *CHROMOSOME duplication, *POLYMERASE chain reaction, *NUCLEOTIDE sequence, *MEDICAGO, *CYPERUS
Abstract

Plastid genomes (plastomes) of land plants have a conserved quadripartite structure in a gene-dense unit genome consisting of a large inverted repeat that separates two single copy regions. Recently, alternative plastome structures were suggested in Geraniaceae and in some conifers and Medicago the coexistence of inversion isomers has been noted. In this study, plastome sequences of two Cyperaceae, Eleocharis dulcis (water chestnut) and Eleocharis cellulosa (gulf coast spikerush), were completed. Unlike the conserved plastomes in basal groups of Poales, these Eleocharis plastomes have remarkably divergent features, including large plastome sizes, high rates of sequence rearrangements, low GC content and gene density, gene duplications and losses, and increased repetitive DNA sequences. A novel finding among these features was the unprecedented level of heteroplasmy with the presence of multiple plastome structural types within a single individual. Illumina paired-end assemblies combined with PacBio single-molecule real-time sequencing, long-range polymerase chain reaction, and Sanger sequencing data identified at least four different plastome structural types in both Eleocharis species. PacBio long read data suggested that one of the four E. dulcis plastome types predominates. [ABSTRACT FROM AUTHOR]

Published
2020
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21. Lost and Found: Return of the Inverted Repeat in the Legume Clade Defined by Its Absence.

Author

Choi, In-Su, Jansen, Robert, and Ruhlman, Tracey

Subjects
PLANT genomes, LEGUMES, MEDICAGO, GENE conversion, MITOCHONDRIA, PLANT mitochondria
Abstract

The plant genome comprises a coevolving, integrated genetic system housed in three subcellular compartments: the nucleus, mitochondrion, and the plastid. The typical land plant plastid genome (plastome) comprises the sum of repeating units of 130–160 kb in length. The plastome inverted repeat (IR) divides each plastome monomer into large and small single copy regions, an architecture highly conserved across land plants. There have been varying degrees of expansion or contraction of the IR, and in a few distinct lineages, including the IR-lacking clade of papilionoid legumes, one copy of the IR has been lost. Completion of plastome sequencing and assembly for 19 Medicago species and Trigonella foenum-graceum and comparative analysis with other IR-lacking clade taxa revealed modest divergence with regard to structural organization overall. However, one clade contained unique variation suggesting an ancestor had experienced repeat-mediated changes in plastome structure. In Medicago minima, a novel IR of ∼9 kb was confirmed and the role of repeat-mediated, recombination-dependent replication in IR reemergence is discussed. [ABSTRACT FROM AUTHOR]

Published
2019
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22. Passiflora plastome sequencing reveals widespread genomic rearrangements.

Author

Rabah, Samar O., Alharby, Hesham F., Sabir, Mernan J., Shrestha, Bikash, Gilbert, Lawrence E., Ruhlman, Tracey A., Jansen, Robert K., Hajrah, Nahid H., Alhebshi, Alawiah M., Sabir, Jamal S.M., and Sabir, Mumdooh J.

Subjects
PASSIFLORA, PLASTIDS, GENOMES, NUCLEOTIDE sequencing, HOMOPLASY
Abstract

Although past studies have included Passiflora among angiosperm lineages with highly rearranged plastid genomes (plastomes), knowledge about plastome organization in the genus is limited. So far only one draft and one complete plastome have been published. Expanded sampling of Passiflora plastomes is needed to understand the extent of the genomic rearrangement in the genus, which is also unusual in having biparental plastid inheritance and plastome‐genome incompatibility. We sequenced 15 Passiflora plastomes using either Illumina paired‐end or shotgun cloning and Sanger sequencing approaches. Assembled plastomes were annotated using Dual Organellar GenoMe Annotator (DOGMA) and tRNAscan‐SE. The Populus trichocarpa plastome was used as a reference to estimate genomic rearrangements in Passiflora by performing whole genome alignment in progressiveMauve. The phylogenetic distribution of rearrangements was plotted on the maximum likelihood tree generated from 64 plastid encoded protein genes. Inverted repeat (IR) expansion/contraction and loss of the two largest hypothetical open reading frames, ycf1 and ycf2, account for most plastome size variation, which ranges from 139 262 base pairs (bp) in P. biflora to 161 494 bp in P. pittieri. Passiflora plastomes have experienced numerous inversions, gene and intron losses along with multiple independent IR expansions and contractions resulting in a distinct organization in each of the three subgenera examined. Each Passiflora subgenus has a unique plastome structure in terms of gene content, order and size. The phylogenetic distribution of rearrangements shows that Passiflora has experienced widespread genomic changes, suggesting that such events may not be reliable phylogenetic markers. [ABSTRACT FROM AUTHOR]

Published
2019
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23. Chapter Eight - Aberration or Analogy? The Atypical Plastomes of Geraniaceae.

Author

Ruhlman, Tracey A. and Jansen, Robert K.

Subjects
*BOTANICAL periodicals, *GERANIACEAE, *PLANT genomes, *TOBACCO
Abstract

A number of plant groups have been proposed as ideal systems to explore plastid inheritance, plastome evolution and plastome-nuclear genome coevolution. Quick generation times and a compact nuclear genome in Arabidopsis thaliana, the relative ease of plastid isolation from Spinacia oleracea and the tractability of plastid transformation in Nicotiana tabacum are all desirable attributes in a model system; however, these and most other groups all lack novelty in terms of plastome structure and nucleotide sequence evolution. Contemporary sequencing and assembly technologies have facilitated analyses of atypical plastomes and, as predicted by early investigations, Geraniaceae plastomes have experienced unprecedented rearrangements relative to the canonical structure and exhibit remarkably high rates of synonymous and nonsynonymous nucleotide substitutions. While not the only lineage with unusual plastome features, likely no other group represents the array of aberrant phenomena recorded for the family. In this chapter, Geraniaceae plastomes will be discussed and, where possible, compared with other taxa. [ABSTRACT FROM AUTHOR]

Published
2018
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24. Contrasting Patterns of Nucleotide Substitution Rates Provide Insight into Dynamic Evolution of Plastid and Mitochondrial Genomes of Geranium.

Author

Seongjun Park, Ruhlman, Tracey A., Mao-Lun Weng, Hajrah, Nahid H., Sabir, Jamal S. M., and Jansen, Robert K.

Subjects
*GERANIACEAE, *LINEAGE, *GENOMES, *ANGIOSPERMS, *EUKARYOTIC cells, *PLASTIDS
Abstract

Geraniaceae have emerged as amodel system for investigating the causes and consequences of variation in plastid andmitochondrial genomes. Incredible structural variation in plastid genomes (plastomes) and highly accelerated evolutionary rates have been reported in selected lineages and functional groups of genes in both plastomes and mitochondrial genomes (mitogenomes), and these phenomena have been implicated in cytonuclear incompatibility. Previous organelle genome studies have included limited sampling of Geranium, the largest genus in the family with over 400 species. This study reports on rates and patterns of nucleotide substitutions in plastomes and mitogenomes of 17 species of Geranium and representatives of other Geraniaceae. As detected across other angiosperms, substitution rates in the plastome are 3.5 times higher than the mitogenome in most Geranium. However, in the branch leading to Geranium brycei/Geranium incanum mitochondrial genes experienced significantly higher dN and dS than plastid genes, a pattern that has only been detected in one other angiosperm. Furthermore, rate accelerations differ in the two organelle genomes with plastomes having increased dN and mitogenomes with increased dS. In the Geranium phaeum/Geraniumreflexumclade, duplicate copies of clpP and rpoA genes that experienced asymmetric rate divergence were detected in the single copy region of the plastome. In the case of rpoA, the branch leading to G. phaeum/G. reflexum experiencedpositive selectionor relaxation of purifyingselection. Finally, the evolutionof acetyl-CoAcarboxylase isunusual inGeraniaceae because it is only the second angiosperm family where both prokaryotic and eukaryotic ACCases functionally coexist in the plastid. [ABSTRACT FROM AUTHOR]

Published
2017
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25. Expansion of inverted repeat does not decrease substitution rates in Pelargonium plastid genomes.

Author

Weng, Mao‐Lun, Ruhlman, Tracey A., and Jansen, Robert K.

Subjects
*INVERTED repeats (Genetics), *PELARGONIUMS, *GENOMES, *NUCLEOTIDES, *HETEROGENEITY
Abstract

For species with minor inverted repeat ( IR) boundary changes in the plastid genome (plastome), nucleotide substitution rates were previously shown to be lower in the IR than the single copy regions ( SC). However, the impact of large-scale IR expansion/contraction on plastid nucleotide substitution rates among closely related species remains unclear., We included plastomes from 22 Pelargonium species, including eight newly sequenced genomes, and used both pairwise and model-based comparisons to investigate the impact of the IR on sequence evolution in plastids., Ten types of plastome organization with different inversions or IR boundary changes were identified in Pelargonium. Inclusion in the IR was not sufficient to explain the variation of nucleotide substitution rates. Instead, the rate heterogeneity in Pelargonium plastomes was a mixture of locus-specific, lineage-specific and IR-dependent effects., Our study of Pelargonium plastomes that vary in IR length and gene content demonstrates that the evolutionary consequences of retaining these repeats are more complicated than previously suggested. [ABSTRACT FROM AUTHOR]

Published
2017
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26. Rate accelerations in plastid and mitochondrial genomes of Cyperaceae occur in the same clades.

Author

Lee, Chaehee, Ruhlman, Tracey A., and Jansen, Robert K.

Subjects
*GENOMES, *CYPERACEAE, *CYPERUS, *MITOCHONDRIA, *DNA replication, *RNA editing
Abstract

[Display omitted] • Eleocharis and Cyperaceae have accelerated substitution rates in plastid and mitochondrial genomes with lineage- and gene-specific patterns. • Both synonymous (dS) and nonsynoymous (dN) substitution rates are highly accelerated on the branch leading to Cyperaceae compared to most sampled angiosperms. • Cyperaceae organelle genomes show dynamic evolution of gene and intron content. • Mutagenic retroprocessing was supported as one of the most likely drivers for rate accelerations in organelle genomes. Cyperaceae, the second largest family in the monocot order Poales, comprises >5500 species and includes the genus Eleocharis with ∼ 250 species. A previous study of complete plastomes of two Eleocharis species documented extensive structural heteroplasmy, gene order changes, high frequency of dispersed repeats along with gene losses and duplications. To better understand the phylogenetic distribution of gene and intron content as well as rates and patterns of sequence evolution within and between mitochondrial and plastid genomes of Eleocharis and Cyperaceae, an additional 29 Eleocharis organelle genomes were sequenced and analyzed. Eleocharis experienced extensive gene loss in both genomes while loss of introns was mitochondria-specific. Eleocharis has higher rates of synonymous (dS) and nonsynonymous (dN) substitutions in the plastid and mitochondrion than most sampled angiosperms, and the pattern was distinct from other eudicot lineages with accelerated rates. Several clades showed higher dS and dN in mitochondrial genes than in plastid genes. Furthermore, nucleotide substitution rates of mitochondrial genes were significantly accelerated on the branch leading to Cyperaceae compared to most angiosperms. Mitochondrial genes of Cyperaceae exhibited dramatic loss of RNA editing sites and a negative correlation between RNA editing and dS values was detected among angiosperms. Mutagenic retroprocessing and dysfunction of DNA replication, repair and recombination genes are the most likely cause of striking rate accelerations and loss of edit sites and introns in Eleocharis and Cyperaceae organelle genomes. [ABSTRACT FROM AUTHOR]

Published
2023
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27. Plastid-Nuclear Interaction and Accelerated Coevolution in Plastid Ribosomal Genes in Geraniaceae.

Author

Mao-Lun Weng, Ruhlman, Tracey A., and Jansen, Robert K.

Subjects
*PLASTIDS, *GENOMES, *ANIMAL cell biotechnology, *MITOCHONDRIA, *PLANT cells & tissues, *GENETIC mutation
Abstract

Plastids andmitochondria have many protein complexes that include subunits encoded by organelle and nuclear genomes. In animal cells, compensatory evolution between mitochondrial and nuclear-encoded subunits was identified and the high mitochondrial mutation rates were hypothesized to drive compensatory evolution in nuclear genomes. In plant cells, compensatory evolution between plastid and nucleus has rarely been investigated in a phylogenetic frame work. To investigate plastid-nuclear coevolution, we focused on plastid ribosomal protein genes that are encodedby plastid and nuclear genomes from 27Geraniales species. Substitution rates were compared for five sets of genes representing plastid- and nuclear-encoded ribosomal subunit proteins targeted to the cytosolor theplastid aswell as nonribosomal protein controls. We found that nonsynonymous substitution rates (dN) and the ratios of nonsynonymous to synonymous substitution rates (ω) were accelerated in both plastid- (CpRP) and nuclear-encoded subunits (NuCpRP) of the plastid ribosome relative to control sequences. Our analyses revealed strong signals of cytonuclear coevolution between plastid- and nuclear-encoded subunits, in which nonsynonymous substitutions in CpRP and NuCpRP tend to occur alongthe same branches in the Geraniaceae phylogeny. This coevolution pattern cannot be explained by physical interaction between amino acid residues. The forces driving accelerated coevolution varied with cellular compartment of the sequence. Increased ω in CpRP was mainly due to intensified positive selection whereas increased ω in NuCpRP was caused by relaxed purifying selection. In addition, the many indels identified in plastid rRNA genes in Geraniaceae may have contributed to changes in plastid subunits. [ABSTRACT FROM AUTHOR]

Published
2016
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28. Coevolution between Nuclear-Encoded DNA Replication, Recombination, and Repair Genes and Plastid Genome Complexity.

Author

Jin Zhang, Ruhlman, Tracey A., Sabir, Jamal S. M., Blazier, John Chris, Mao-Lun Weng, Seongjun Park, and Jansen, Robert K.

Subjects
*DNA replication, *PLASTIDS, *GERANIACEAE, *ANGIOSPERMS, *BRASSICALES
Abstract

Disruption of DNA replication, recombination, and repair (DNA-RRR) systems has been hypothesized to cause highly elevated nucleotide substitution rates and genome rearrangements in the plastids of angiosperms, but this theory remains untested. To investigate nuclear-plastid genome (plastome) coevolution in Geraniaceae, four different measures of plastome complexity (rearrangements, repeats, nucleotide insertions/deletions, and substitution rates) were evaluated along with substitution rates of 12 nuclear-encoded, plastid-targeted DNA-RRR genes from 27 Geraniales species. Significant correlations were detected for nonsynonymous (dN) but not synonymous (dS) substitution rates for three DNA-RRR genes (uvrB/C,why1, andgyrA) supporting a role for these genes in accelerated plastid genome evolution in Geraniaceae. Furthermore, correlation between dN of uvrB/C and plastome complexity suggests the presence of nucleotide excision repair system in plastids. Significant correlations were also detected between plastome complexity and 13 of the 90 nuclear-encoded organelle-targeted genes investigated. Comparisons revealed significant acceleration of dN in plastid-targeted genes of Geraniales relative to Brassicales suggesting this correlation may be an artifact of elevated rates in this gene set in Geraniaceae. Correlation between dN of plastid-targeted DNA-RRR genes and plastome complexity supports the hypothesis that the aberrant patterns in angiosperm plastome evolution could be caused by dysfunction in DNA-RRR systems. [ABSTRACT FROM AUTHOR]

Published
2016
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29. Plastid Transformation in Lettuce (Lactuca sativa L.) by Biolistic DNA Delivery.

Author

Ruhlman, Tracey A.

Abstract

The interest in producing pharmaceutical proteins in a nontoxic plant host has led to the development of an approach to express such proteins in transplastomic lettuce (Lactuca sativa L.). A number of therapeutic proteins and vaccine antigen candidates have been stably integrated into the lettuce plastid genome using biolistic DNA delivery. High levels of accumulation and retention of biological activity suggest that lettuce may provide an ideal platform for the production of biopharmaceuticals. [ABSTRACT FROM AUTHOR]

Published
2014
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30. The Plastid Genomes of Flowering Plants.

Author

Ruhlman, Tracey A. and Jansen, Robert K.

Abstract

The plastid genome (plastome) has proved a valuable source of data for evaluating evolutionary relationships among angiosperms. Through basic and applied approaches, plastid transformation technology offers the potential to understand and improve plant productivity, providing food, fiber, energy and medicines to meet the needs of a burgeoning global population. The growing genomic resources available to both phylogenetic and biotechnological investigations are allowing novel insights and expanding the scope of plastome research to encompass new species. In this chapter we present an overview of some of the seminal and contemporary research that has contributed to our current understanding of plastome evolution and attempt to highlight the relationship between evolutionary mechanisms and tools of plastid genetic engineering. [ABSTRACT FROM AUTHOR]

Published
2014
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31. Dynamic evolution of Geranium mitochondrial genomes through multiple horizontal and intracellular gene transfers.

Author

Park, Seongjun, Grewe, Felix, Zhu, Andan, Ruhlman, Tracey A., Sabir, Jamal, Mower, Jeffrey P., and Jansen, Robert K.

Subjects
GERANIUMS, HORIZONTAL gene transfer, GERANIACEAE, MITOCHONDRIAL DNA, EUDICOTS
Abstract

The exchange of genetic material between cellular organelles through intracellular gene transfer ( IGT) or between species by horizontal gene transfer ( HGT) has played an important role in plant mitochondrial genome evolution. The mitochondrial genomes of Geraniaceae display a number of unusual phenomena including highly accelerated rates of synonymous substitutions, extensive gene loss and reduction in RNA editing., Mitochondrial DNA sequences assembled for 17 species of Geranium revealed substantial reduction in gene and intron content relative to the ancestor of the Geranium lineage. Comparative analyses of nuclear transcriptome data suggest that a number of these sequences have been functionally relocated to the nucleus via IGT., Evidence for rampant HGT was detected in several Geranium species containing foreign organellar DNA from diverse eudicots, including many transfers from parasitic plants. One lineage has experienced multiple, independent HGT episodes, many of which occurred within the past 5.5 Myr., Both duplicative and recapture HGT were documented in Geranium lineages. The mitochondrial genome of Geranium brycei contains at least four independent HGT tracts that are absent in its nearest relative. Furthermore, G. brycei mitochondria carry two copies of the cox1 gene that differ in intron content, providing insight into contrasting hypotheses on cox1 intron evolution. [ABSTRACT FROM AUTHOR]

Published
2015
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32. NDH expression marks major transitions in plant evolution and reveals coordinate intracellular gene loss.

Author

Ruhlman, Tracey A., Wan-Jung Chang, Chen, Jeremy J. W., Yao-Ting Huang, Ming-Tsair Chan, Jin Zhang, De-Chih Liao, Blazier, John C., Xiaohua Jin, Ming-Che Shih, Jansen, Robert K., and Choun-Sea Lin

Subjects
*NADH dehydrogenase, *PLANT evolution, *PHYLOGENY, *PLANTS, *PLASTIDS
Abstract

Background: Key innovations have facilitated novel niche utilization, such as the movement of the algal predecessors of land plants into terrestrial habitats where drastic fluctuations in light intensity, ultraviolet radiation and water limitation required a number of adaptations. The NDH (NADH dehydrogenase-like) complex of Viridiplantae plastids participates in adapting the photosynthetic response to environmental stress, suggesting its involvement in the transition to terrestrial habitats. Although relatively rare, the loss or pseudogenization of plastid NDH genes is widely distributed across diverse lineages of photoautotrophic seed plants and mutants/transgenics lacking NDH function demonstrate little difference from wild type under non-stressed conditions. This study analyzes large transcriptomic and genomic datasets to evaluate the persistence and loss of NDH expression across plants. Results: Nuclear expression profiles showed accretion of the NDH gene complement at key transitions in land plant evolution, such as the transition to land and at the base of the angiosperm lineage. While detection of transcripts for a selection of non-NDH, photosynthesis related proteins was independent of the state of NDH, coordinate, lineage-specific loss of plastid NDH genes and expression of nuclear-encoded NDH subunits was documented in Pinaceae, gnetophytes, Orchidaceae and Geraniales confirming the independent and complete loss of NDH in these diverse seed plant taxa. Conclusion: The broad phylogenetic distribution of NDH loss and the subtle phenotypes of mutants suggest that the NDH complex is of limited biological significance in contemporary plants. While NDH activity appears dispensable under favorable conditions, there were likely sufficiently frequent episodes of abiotic stress affecting terrestrial habitats to allow the retention of NDH activity. These findings reveal genetic factors influencing plant/environment interactions in a changing climate through 450 million years of land plant evolution. [ABSTRACT FROM AUTHOR]

Published
2015
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34. Plastid Pathways.

Author

Verpoorte, R., Alfermann, A. W., Johnson, T. S., Ruhlman, Tracey, and Daniell, Henry

Abstract

Plant metabolic engineering has the potential to provide for the needs of an expanding population. Environmentally benign biosyntheisis of novel materials and pharmaceutical proteins along with the opportunity to improve the productivity and nutritive value of crop plants has focused considerable effort towards the genetic manipulation of crop species. The most important output traits that could be conferred through biotechnology often require the coordinated expression of several foreign genes. Conservative estimates predict some 3000 proteins are posttranslationally imported into plant plastids. Among them are the enzymes of various metabolic pathways such as those involved in the biosynthesis of the tocopherols (vitamin E) and carotenoids (vitamin A), branched chain and aromatic amino acids, and fatty acids. The ability of the chloroplast to integrate and express foreign sequences as operons makes this site an attractive alternative for genetic manipulations. Multigene engineering, high levels of recombinant protein accumulation and the security of transgene containment due to maternal inheritance of plastid genomes in most crop species are some of the features that contribute to the potential of the chloroplast system. Here we offer an overview of the fundamental characteristics of plastid protein expression and consider some possible candidate genes for the improvement of crop species through metabolic engineering of pathways compartmentalized within plastids [ABSTRACT FROM AUTHOR]

Published
2007
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35. Evolutionary and biotechnology implications of plastid genome variation in the inverted-repeat-lacking clade of legumes.

Author

Sabir, Jamal, Schwarz, Erika, Ellison, Nicholas, Zhang, Jin, Baeshen, Nabih A, Mutwakil, Muhammed, Jansen, Robert, and Ruhlman, Tracey

Subjects
PLANT genomes, PLASTIDS, LEGUMES, PLANT species, LICORICE (Plant), GENETIC transformation, COMPARATIVE studies
Abstract

Land plant plastid genomes (plastomes) provide a tractable model for evolutionary study in that they are relatively compact and gene dense. Among the groups that display an appropriate level of variation for structural features, the inverted-repeat-lacking clade ( IRLC) of papilionoid legumes presents the potential to advance general understanding of the mechanisms of genomic evolution. Here, are presented six complete plastome sequences from economically important species of the IRLC, a lineage previously represented by only five completed plastomes. A number of characters are compared across the IRLC including gene retention and divergence, synteny, repeat structure and functional gene transfer to the nucleus. The loss of clpP intron 2 was identified in one newly sequenced member of IRLC, Glycyrrhiza glabra. Using deeply sequenced nuclear transcriptomes from two species helped clarify the nature of the functional transfer of accD to the nucleus in Trifolium, which likely occurred in the lineage leading to subgenus Trifolium. Legumes are second only to cereal crops in agricultural importance based on area harvested and total production. Genetic improvement via plastid transformation of IRLC crop species is an appealing proposition. Comparative analyses of intergenic spacer regions emphasize the need for complete genome sequences for developing transformation vectors for plastid genetic engineering of legume crops. [ABSTRACT FROM AUTHOR]

Published
2014
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36. Complete sequences of organelle genomes from the medicinal plant Rhazya stricta (Apocynaceae) and contrasting patterns of mitochondrial genome evolution across asterids.

Author

Seongjun Park, Ruhlman, Tracey A., Sabir, Jamal S. M., Mutwakil, Mohammed H. Z., Baeshen, Mohammed N., Sabir, Meshaal J., Baeshen, Nabih A., and Jansen, Robert K.

Subjects
*APOCYNACEAE, *PLANT genomes, *NUCLEOTIDE sequencing, *TRADITIONAL medicine, *MITOCHONDRIAL DNA, *PLANT phylogeny, *PLANTS
Abstract

Background Rhazya stricta is native to arid regions in South Asia and the Middle East and is used extensively in folk medicine to treat a wide range of diseases. In addition to generating genomic resources for this medicinally important plant, analyses of the complete plastid and mitochondrial genomes and a nuclear transcriptome from Rhazya provide insights into inter compartmental transfers between genomes and the patterns of evolution among eight asterid mitochondrial genomes. Results The 154,841 bp plastid genome is highly conserved with gene content and order identical to the ancestral organization of angiosperms. The 548,608 bp mitochondrial genome exhibits a number of phenomena including the presence of recombinogenic repeats that generate a multipartite organization, transferred DNA from the plastid and nuclear genomes, and bidirectional DNA transfers between the mitochondrion and the nucleus. The mitochondrial genes sdh3 and rps14 have been transferred to the nucleus and have acquired targeting presequences. In the case of rps14, two copies are present in the nucleus; only one has a mitochondrial targeting presequence and may be functional. Phylogenetic analyses of both nuclear and mitochondrial copies of rps14 across angiosperms suggests Rhazya has experienced a single transfer of this gene to the nucleus, followed by a duplication event. Furthermore, the phylogenetic distribution of gene losses and the high level of sequence divergence in targeting presequences suggest multiple, independent transfers of both sdh3 and rps14 across asterids. Comparative analyses of mitochondrial genomes of eight sequenced asterids indicates a complicated evolutionary history in this large angiosperm clade with considerable diversity in genome organization and size, repeat, gene and intron content, and amount of foreign DNA from the plastid and nuclear genomes. Conclusions Organelle genomes of Rhazya stricta provide valuable information for improving the understanding of mitochondrial genome evolution among angiosperms. The genomic data have enabled a rigorous examination of the gene transfer events. Rhazya is unique among the eight sequenced asterids in the types of events that have shaped the evolution of its mitochondrial genome. Furthermore, the organelle genomes of R. stricta provide valuable genomic resources for utilizing this important medicinal plant in biotechnology applications. [ABSTRACT FROM AUTHOR]

Published
2014
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37. Comparative analyses of two Geraniaceae transcriptomes using next-generation sequencing.

Author

Jin Zhang, Ruhlman, Tracey A., Mower, Jeffrey P., and Jansen, Robert K.

Subjects
*PLANT organelles, *GERANIACEAE, *RNA, *GENOMES, *ANTISENSE DNA
Abstract

Background Organelle genomes of Geraniaceae exhibit several unusual evolutionary phenomena compared to other angiosperm families including accelerated nucleotide substitution rates, widespread gene loss, reduced RNA editing, and extensive genomic rearrangements. Since most organelleencoded proteins function in multi-subunit complexes that also contain nuclear-encoded proteins, it is likely that the atypical organellar phenomena affect the evolution of nuclear genes encoding organellar proteins. To begin to unravel the complex co-evolutionary interplay between organellar and nuclear genomes in this family, we sequenced nuclear transcriptomes of two species, Geranium maderense and Pelargonium x hortorum. Results Normalized cDNA libraries of G. maderense and P. x hortorum were used for transcriptome sequencing. Five assemblers (MIRA, Newbler, SOAPdenovo, SOAPdenovo-trans [SOAPtrans], Trinity) and two next-generation technologies (454 and Illumina) were compared to determine the optimal transcriptome sequencing approach. Trinity provided the highest quality assembly of Illumina data with the deepest transcriptome coverage. An analysis to determine the amount of sequencing needed for de novo assembly revealed diminishing returns of coverage and quality with data sets larger than sixty million Illumina paired end reads for both species. The G. maderense and P. x hortorum transcriptomes contained fewer transcripts encoding the PLS subclass of PPR proteins relative to other angiosperms, consistent with reduced mitochondrial RNA editing activity in Geraniaceae. In addition, transcripts for all six plastid targeted sigma factors were identified in both transcriptomes, suggesting that one of the highly divergent rpoAlike ORFs in the P. x hortorum plastid genome is functional. Conclusions The findings support the use of the Illumina platform and assemblers optimized for transcriptome assembly, such as Trinity or SOAPtrans, to generate high-quality de novo transcriptomes with broad coverage. In addition, results indicated no major improvements in breadth of coverage with data sets larger than six billion nucleotides or when sampling RNA from four tissue types rather than from a single tissue. Finally, this work demonstrates the power of cross-compartmental genomic analyses to deepen our understanding of the correlated evolution of the nuclear, plastid, and mitochondrial genomes in plants. [ABSTRACT FROM AUTHOR]

Published
2013
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38. Phylogeny, rate variation, and genome size evolution of Pelargonium (Geraniaceae)

Author

Weng, Mao-Lun, Ruhlman, Tracey A., Gibby, Mary, and Jansen, Robert K.

Subjects
*MOLECULAR phylogeny, *GENOMES, *PELARGONIUMS, *PLASTIDS, *KARYOTYPES, *TAXONOMY, *HETEROGENEITY, *GENETIC mutation
Abstract

Abstract: The phylogeny of 58 Pelargonium species was estimated using five plastid markers (rbcL, matK, ndhF, rpoC1, trnL-F) and one mitochondrial gene (nad5). The results confirmed the monophyly of three major clades and four subclades within Pelargonium but also indicate the need to revise some sectional classifications. This phylogeny was used to examine karyotype evolution in the genus: plotting chromosome sizes, numbers and 2C-values indicates that genome size is significantly correlated with chromosome size but not number. Accelerated rates of nucleotide substitution have been previously detected in both plastid and mitochondrial genes in Pelargonium, but sparse taxon sampling did not enable identification of the phylogenetic distribution of these elevated rates. Using the multigene phylogeny as a constraint, we investigated lineage- and locus-specific heterogeneity of substitution rates in Pelargonium for an expanded number of taxa and demonstrated that both plastid and mitochondrial genes have had accelerated substitution rates but with markedly disparate patterns. In the plastid, the exons of rpoC1 have significantly accelerated substitution rates compared to its intron and the acceleration was mainly due to nonsynonymous substitutions. In contrast, the mitochondrial gene, nad5, experienced substantial acceleration of synonymous substitution rates in three internal branches of Pelargonium, but this acceleration ceased in all terminal branches. Several lineages also have dN/dS ratios significantly greater than one for rpoC1, indicating that positive selection is acting on this gene, whereas the accelerated synonymous substitutions in the mitochondrial gene are the result of elevated mutation rates. [Copyright &y& Elsevier]

Published
2012
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39. Expression of cholera toxin B–proinsulin fusion protein in lettuce and tobacco chloroplasts – oral administration protects against development of insulitis in non-obese diabetic mice.

Author

Ruhlman, Tracey, Ahangari, Raheleh, Devine, Andrew, Samsam, Mohtahsem, and Daniell, Henry

Subjects
*AUTOIMMUNE diseases, *DIABETES, *CHOLERA, *MICE, *PROINSULIN, *EDIBLE plants
Abstract

Lettuce and tobacco chloroplast transgenic lines expressing the cholera toxin B subunit–human proinsulin (CTB-Pins) fusion protein were generated. CTB-Pins accumulated up to ~16% of total soluble protein (TSP) in tobacco and up to ~2.5% of TSP in lettuce. Eight milligrams of powdered tobacco leaf material expressing CTB-Pins or, as negative controls, CTB–green fluorescent protein (CTB-GFP) or interferon–GFP (IFN-GFP), or untransformed leaf, were administered orally, each week for 7 weeks, to 5-week-old female non-obese diabetic (NOD) mice. The pancreas of CTB-Pins-treated mice showed decreased infiltration of cells characteristic of lymphocytes (insulitis); insulin-producing β-cells in the pancreatic islets of CTB-Pins-treated mice were significantly preserved, with lower blood or urine glucose levels, by contrast with the few β-cells remaining in the pancreatic islets of the negative controls. Increased expression of immunosuppressive cytokines, such as interleukin-4 and interleukin-10 (IL-4 and IL-10), was observed in the pancreas of CTB-Pins-treated NOD mice. Serum levels of immunoglobulin G1 (IgG1), but not IgG2a, were elevated in CTB-Pins-treated mice. Taken together, T-helper 2 (Th2) lymphocyte-mediated oral tolerance is a likely mechanism for the prevention of pancreatic insulitis and the preservation of insulin-producing β-cells. This is the first report of expression of a therapeutic protein in transgenic chloroplasts of an edible crop. Transplastomic lettuce plants expressing CTB-Pins grew normally and transgenes were maternally inherited in T1 progeny. This opens up the possibility for the low-cost production and delivery of human therapeutic proteins, and a strategy for the treatment of various other autoimmune diseases. [ABSTRACT FROM AUTHOR]

Published
2007
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40. Transcriptomic Analysis of Salt-Stress-Responsive Genes in Barley Roots and Leaves.

Author

Nefissi Ouertani, Rim, Arasappan, Dhivya, Abid, Ghassen, Ben Chikha, Mariem, Jardak, Rahma, Mahmoudi, Henda, Mejri, Samiha, Ghorbel, Abdelwahed, Ruhlman, Tracey A., and Jansen, Robert K.

Subjects
BARLEY, GENETIC variation, GENETIC regulation, GENES, HOMEOSTASIS, REACTIVE oxygen species, CROP improvement
Abstract

Barley is characterized by a rich genetic diversity, making it an important model for studies of salinity response with great potential for crop improvement. Moreover, salt stress severely affects barley growth and development, leading to substantial yield loss. Leaf and root transcriptomes of a salt-tolerant Tunisian landrace (Boulifa) exposed to 2, 8, and 24 h salt stress were compared with pre-exposure plants to identify candidate genes and pathways underlying barley's response. Expression of 3585 genes was upregulated and 5586 downregulated in leaves, while expression of 13,200 genes was upregulated and 10,575 downregulated in roots. Regulation of gene expression was severely impacted in roots, highlighting the complexity of salt stress response mechanisms in this tissue. Functional analyses in both tissues indicated that response to salt stress is mainly achieved through sensing and signaling pathways, strong transcriptional reprograming, hormone osmolyte and ion homeostasis stabilization, increased reactive oxygen scavenging, and activation of transport and photosynthesis systems. A number of candidate genes involved in hormone and kinase signaling pathways, as well as several transcription factor families and transporters, were identified. This study provides valuable information on early salt-stress-responsive genes in roots and leaves of barley and identifies several important players in salt tolerance. [ABSTRACT FROM AUTHOR]

Published
2021
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41. Clade-Specific Plastid Inheritance Patterns Including Frequent Biparental Inheritance in Passiflora Interspecific Crosses.

Author

Shrestha, Bikash, Gilbert, Lawrence E., Ruhlman, Tracey A., Jansen, Robert K., and Quesada-Pérez, Victor Manuel

Subjects
PASSIFLORA, CYTOPLASMIC inheritance, HEREDITY, COTYLEDONS, PLANT development, PLASTIDS
Abstract

Plastid inheritance in angiosperms is presumed to be largely maternal, with the potential to inherit plastids biparentally estimated for about 20% of species. In Passiflora, maternal, paternal and biparental inheritance has been reported; however, these studies were limited in the number of crosses and progeny examined. To improve the understanding of plastid transmission in Passiflora, the progeny of 45 interspecific crosses were analyzed in the three subgenera: Passiflora, Decaloba and Astrophea. Plastid types were assessed following restriction digestion of PCR amplified plastid DNA in hybrid embryos, cotyledons and leaves at different developmental stages. Clade-specific patterns of inheritance were detected such that hybrid progeny from subgenera Passiflora and Astrophea predominantly inherited paternal plastids with occasional incidences of maternal inheritance, whereas subgenus Decaloba showed predominantly maternal and biparental inheritance. Biparental plastid inheritance was also detected in some hybrids from subgenus Passiflora. Heteroplasmy due to biparental inheritance was restricted to hybrid cotyledons and first leaves with a single parental plastid type detectable in mature plants. This indicates that in Passiflora, plastid retention at later stages of plant development may not reflect the plastid inheritance patterns in embryos. Passiflora exhibits diverse patterns of plastid inheritance, providing an excellent system to investigate underlying mechanisms in angiosperms. [ABSTRACT FROM AUTHOR]

Published
2021
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42. Comparative Mitogenome Analysis of the Genus Trifolium Reveals Independent Gene Fission of ccmFn and Intracellular Gene Transfers in Fabaceae.

Author

Choi, In-Su, Ruhlman, Tracey A., and Jansen, Robert K.

Subjects
*GENETIC transformation, *CLOVER, *LEGUMES, *MOLECULAR phylogeny, *PLANT mitochondria, *COMPARATIVE studies, *COMPARATIVE genomics, *LOTUS (Genus)
Abstract

The genus Trifolium is the largest of the tribe Trifolieae in the subfamily Papilionoideae (Fabaceae). The paucity of mitochondrial genome (mitogenome) sequences has hindered comparative analyses among the three genomic compartments of the plant cell (nucleus, mitochondrion and plastid). We assembled four mitogenomes from the two subgenera (Chronosemium and Trifolium) of the genus. The four Trifolium mitogenomes were compact (294,911–348,724 bp in length) and contained limited repetitive (6.6–8.6%) DNA. Comparison of organelle repeat content highlighted the distinct evolutionary trajectory of plastid genomes in a subset of Trifolium species. Intracellular gene transfer (IGT) was analyzed among the three genomic compartments revealing functional transfer of mitochondrial rps1 to nuclear genome along with other IGT events. Phylogenetic analysis based on mitochondrial and nuclear rps1 sequences revealed that the functional transfer in Trifolieae was independent from the event that occurred in robinioid clade that includes genus Lotus. A novel, independent fission event of ccmFn in Trifolium was identified, caused by a 59 bp deletion. Fissions of this gene reported previously in land plants were reassessed and compared with Trifolium. [ABSTRACT FROM AUTHOR]

Published
2020
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43. Plastome based phylogenetics and younger crown node age in Pelargonium.

Author

van de Kerke, Sara J., Shrestha, Bikash, Ruhlman, Tracey A., Weng, Mao-Lun, Jansen, Robert K., Jones, Cynthia S., Schlichting, Carl D., Hosseini, Samin, Mohammadin, Setareh, Schranz, M. Eric, and Bakker, Freek T.

Subjects
*PELARGONIUMS, *PLANT diversity, *GENETIC code, *RECOMBINANT DNA, *CROWNS, *AMINO acids
Abstract

• We assembled the plastomes of 80 Pelargonium species based on Illumina sequencing data. • Phylogenetic relationships within Pelargonium are investigated based on 74 protein coding genes as well as nuclear rDNA ITS. • Molecular dating analysis indicate Pelargonium to have originated around 9.8 Mya. • Long standing issues within Pelargonium phylogenetics are resolved. The predominantly South-African plant genus Pelargonium L'Hér. (Geraniaceae) displays remarkable morphological diversity, several basic chromosome numbers as well as high levels of organelle genomic rearrangements, and represents the 7th largest Cape Floristic Region clade. In this study, we reconstructed a phylogenetic tree based on 74 plastome exons and nuclear rDNA ITS regions for 120 species, which represents 43% taxon coverage for Pelargonium. We also performed a dating analysis to examine the timing of the major radiations in the genus. Phylogenetic analyses of nucleotide, amino acid, and ITS alignments confirmed the previously-documented subgeneric split into five main clades ((C1,C2),(B(A1,A2))) although clade only A1 received low bootstrap support. Using calibration evidence from a range of sources the Pelargonium crown age was estimated to be 9.7 My old, much younger than previous estimates for the genus but similar to recent studies of other Cape Floristic lineages that are part of both Fynbos and Succulent Karoo biomes. [ABSTRACT FROM AUTHOR]

Published
2019
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44. The nuclear genome of Rhazya stricta and the evolution of alkaloid diversity in a medically relevant clade of Apocynaceae.

Author

Sabir, Jamal S. M., Jansen, Robert K., Arasappan, Dhivya, Calderon, Virginie, Noutahi, Emmanuel, Zheng, Chunfang, Park, Seongjun, Sabir, Meshaal J., Baeshen, Mohammed N., Hajrah, Nahid H., Khiyami, Mohammad A., Baeshen, Nabih A., Obaid, Abdullah Y., Al-Malki, Abdulrahman L., Sankoff, David, El-Mabrouk, Nadia, and Ruhlman, Tracey A.

Published
2016
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46. In and out: Evolution of viral sequences in the mitochondrial genomes of legumes (Fabaceae).

Author

Choi, In-Su, Wojciechowski, Martin F., Ruhlman, Tracey A., and Jansen, Robert K.

Subjects
*PLANT RNA, *MITOCHONDRIA, *PLANT mitochondria, *LEGUMES, *GENOMES, *GENOMICS, *PLANT genomes
Abstract

[Display omitted] • Mitovirus sequence evolution in mitochondrial genomes was investigated in 27 legumes. • Mimosoids have abundant mitovirus sequences and an almost full-length L1 element. • Mitovirus integration in four introns produced target site duplications. • Precise exclusion of mitoviral sequences occurred multiple times. • Mitochondrial gene is regained in mitogenome of Indigofera tinctoria. Plant specific mitoviruses in the 'genus' Mitovirus (Narnaviridae) and their integrated sequences (non-retroviral endogenous RNA viral elements or NERVEs) have been recently identified in various plant lineages. However, the sparse phylogenetic coverage of complete plant mitochondrial genome (mitogenome) sequences and the non-conserved nature of mitochondrial intergenic regions have hindered comparative studies on mitovirus NERVEs in plants. In this study, 10 new mitogenomes were sequenced from legumes (Fabaceae). Based on comparative genomic analysis of 27 total mitogenomes, we identified mitovirus NERVEs and transposable elements across the family. All legume mitogenomes included NERVEs and total NERVE length varied from ca. 2 kb in the papilionoid Trifolium to 35 kb in the mimosoid Acacia. Most of the NERVE integration sites were in highly variable intergenic regions, however, some were positioned in six cis -spliced mitochondrial introns. In the Acacia mitogenome, there were L1-like transposon sequences including an almost full-length copy with target site duplications (TSDs). The integration sites of NERVEs in four introns showed evidence of L1-like retrotransposition events. Phylogenetic analysis revealed that there were multiple instances of precise deletion of NERVEs between TSDs. This study provides clear evidence that a L1-like retrotransposition mechanism has a long history of contributing to the integration of viral RNA into plant mitogenomes while microhomology-mediated deletion can restore the integration site. [ABSTRACT FROM AUTHOR]

Published
2021
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47. Extensive variation in nucleotide substitution rate and gene/intron loss in mitochondrial genomes of Pelargonium.

Author

Choi, KyoungSu, Weng, Mao-Lun, Ruhlman, Tracey A., and Jansen, Robert K.

Subjects
*PELARGONIUMS, *GENOMES, *MITOCHONDRIA, *GENES, *TRANSCRIPTOMES, *SILENE (Genus), *MOBILE genetic elements
Abstract

• Extensive mitochondrial gene/intron losses occur in Geraniaceae, especially in Pelargonium. • Multiple, independent gene losses occurred, whereas intron losses closely track the phylogeny. • Synonymous nucleotide substitutions in nuclear genes were much lower than in mitochondrial genes. • Pelargonium is one of four angiosperm lineages with highly accelerated rates in mitogenomes. • The cause of rate accelerations in Pelargonium plastomes and mitogenomes may be different. Geraniaceae organelle genomes have been shown to exhibit several highly unusual features compared to most other photosynthetic angiosperms. This includes massively rearranged plastomes with considerable size variation, extensive gene and intron loss, accelerated rates of nucleotide substitutions in both mitogenomes and plastomes, and biparental inheritance and cytonuclear incompatibility of the plastome. Most previous studies have focused on plastome evolution with mitogenome comparisons limited to only a few taxa or genes. In this study, mitogenomes and transcriptomes were examined for 27 species of Geraniales, including 13 species of Pelargonium. Extensive gene and intron losses were detected across the Geraniales with Pelargonium representing the most gene depauperate lineage in the family. Plotting these events on the Geraniaceae phylogenetic tree showed that gene losses occurred multiple times, whereas intron losses more closely reflected the relationships among taxa. In addition, P. australe acquired an intron by horizontal transfer. Comparisons of nucleotide substitution rates in Pelargonium showed that synonymous changes in nuclear genes were much lower than in mitochondrial genes. This is in contrast to the previously published studies that indicated that nuclear genes have 16 fold higher rates than mitochondrial genes across angiosperms. Elevated synonymous substitutions occurred for each mitochondrial gene in Pelargonium with the highest values 783 and 324 times higher than outgroups and other Geraniaceae, respectively. Pelargonium is one of four unrelated genera of angiosperms (Ajuga , Plantago and Silene) that have experienced highly accelerated nucleotide substitutions in mitogenomes. It is distinct from most angiosperms in also having elevated substitution rates in plastid genes but the cause of rate accelerations in Pelargonium plastomes and mitogenomes may be different. [ABSTRACT FROM AUTHOR]

Published
2021
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48. Under the rug: Abandoning persistent misconceptions that obfuscate organelle evolution.

Author

Gonçalves, Deise J.P., Jansen, Robert K., Ruhlman, Tracey A., and Mandel, Jennifer R.

Subjects
*BOTANISTS, *CHLOROPLAST DNA, *MOLECULAR biologists, *DNA structure, *ORGANELLES, *RUGS, *NUCLEOTIDE sequencing, *GENETIC recombination
Abstract

The advent and advance of next generation sequencing over the past two decades made it possible to accumulate large quantities of sequence reads that could be used to assemble complete or nearly complete organelle genomes (plastome or mitogenome). The result has been an explosive increase in the availability of organelle genome sequences with over 4000 different species of green plants currently available on GenBank. During the same time period, plant molecular biologists greatly enhanced the understanding of the structure, repair, replication, recombination, transcription and translation, and inheritance of organelle DNA. Unfortunately many plant evolutionary biologists are unaware of or have overlooked this knowledge, resulting in misrepresentation of several phenomena that are critical for phylogenetic and evolutionary studies using organelle genomes. We believe that confronting these misconceptions about organelle genome organization, composition, and inheritance will improve our understanding of the evolutionary processes that underly organelle evolution. Here we discuss four misconceptions that can limit evolutionary biology studies and lead to inaccurate phylogenies and incorrect structure of the organellar DNA used to infer organelle evolution. [ABSTRACT FROM AUTHOR]

Published
2020
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49. Highly accelerated rates of genomic rearrangements and nucleotide substitutions in plastid genomes of Passiflora subgenus Decaloba.

Author

Shrestha, Bikash, Weng, Mao-Lun, Theriot, Edward C., Gilbert, Lawrence E., Ruhlman, Tracey A., Krosnick, Shawn E., and Jansen, Robert K.

Subjects
*PASSIFLORA, *RNA polymerases, *GENOMES, *RIBOSOMAL RNA, *PLANT phylogeny, *PHYLOGENY
Abstract

• Ten most phylogenetically informative genes produced a strongly supported phylogeny. • Extensive plastome rearrangements were detected some of which occurred multiple times. • Protein coding plastid genes show lineage- and gene-specific rate heterogeneity. • Passiflora shares features present in angiosperms with highly rearranged plastomes. Plastid genomes (plastomes) of photosynthetic angiosperms are for the most part highly conserved in their organization, mode of inheritance and rates of nucleotide substitution. A small number of distantly related lineages share a syndrome of features that deviate from this general pattern, including extensive genomic rearrangements, accelerated rates of nucleotide substitution, biparental inheritance and plastome-genome incompatibility. Previous studies of plastomes in Passiflora with limited taxon sampling suggested that the genus exhibits this syndrome. To examine this phenomenon further, 15 new plastomes from Passiflora were sequenced and combined with previously published data to examine the phylogenetic relationships, genome organization and evolutionary rates across all five subgenera and the sister genus Adenia. Phylogenomic analyses using 68 protein-coding genes shared by Passiflora generated a fully resolved and strongly supported tree that is congruent with previous phylogenies based on a few plastid and nuclear loci. This phylogeny was used to examine the distribution of plastome rearrangements across Passiflora. Multiple gene and intron losses and inversions were identified in Passiflora with some occurring in parallel and others that extended across the Passifloraceae. Furthermore, extensive expansions and contractions of the inverted repeat (IR) were uncovered and in some cases this resulted in exclusion of all ribosomal RNA genes from the IR. The most highly rearranged lineage was subgenus Decaloba , which experienced extensive IR expansion that incorporated up to 25 protein-coding genes usually located in large single copy region. Nucleotide substitution rate analyses of 68 protein-coding genes across the genus showed lineage- and locus-specific acceleration. Significant increase in dS, dN and dN / dS was detected for clpP across the genus and for ycf4 in certain lineages. Significant increases in dN and dN/dS for ribosomal subunits and plastid-encoded RNA polymerase genes were detected in the branch leading to the expanded IR-clade in subgenus Decaloba. This subgenus displays the syndrome of unusual features, making it an ideal system to investigate the dynamic evolution of angiosperm plastomes. [ABSTRACT FROM AUTHOR]

Published
2019
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50. Plastid Genomes of Flowering Plants: Essential Principles.

Author

Ruhlman TA and Jansen RK

Subjects
Genetic Engineering, Magnoliopsida growth & development, Phylogeny, Evolution, Molecular, Genes, Plant, Genetic Variation, Genome, Plastid, Magnoliopsida genetics, Plastids genetics
Abstract

The plastid genome (plastome ) has proved a valuable source of data for evaluating evolutionary relationships among angiosperms. Through basic and applied approaches, plastid transformation technology offers the potential to understand and improve plant productivity, providing food, fiber, energy, and medicines to meet the needs of a burgeoning global population. The growing genomic resources available to both phylogenetic and biotechnological investigations is allowing novel insights and expanding the scope of plastome research to encompass new species. In this chapter, we present an overview of some of the seminal and contemporary research that has contributed to our current understanding of plastome evolution and attempt to highlight the relationship between evolutionary mechanisms and the tools of plastid genetic engineering.

Published
2021
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