Inferring the evolutionary mechanism of the chloroplast genome size by comparing whole-chloroplast genome sequences in seed plants

Zheng, Xiaoming; Wang, Junrui; Li, Feng; Li, Sha; Pang, Hongbo; Liu, Qi; Li, Jing; Sun, Yan; Qiao, Weihua; Zhang, Lifang; Cheng, Yunlian; Yang, Qing

doi:10.1038/s41598-017-01518-5

Cited by 88 publications

(79 citation statements)

References 95 publications

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“…Chloroplast genome content and structure are reviewed for example in [4,5]. Chloroplast genomes are widely used for evolutionary analyses [6,7], barcoding [8,9,10], and meta-barcoding [11,12]. Interesting aspects of chloroplast genomes are their small size (120 kbp to 160 kbp, [1]), caused through endosymbiotic gene transfer [13,14] and the low number of 100 to 120 genes that are still encoded on the chloroplast genome [4].…”

Section: Introductionmentioning

confidence: 99%

A systematic comparison of chloroplast genome assembly tools

Freudenthal

Pfaff

Terhoeven

et al. 2019

Preprint

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Chloroplasts are photosynthetic organelles in plant cells and contain their own genomic information. That genome can be utilized in different scientific fields like phylogenetics or biotechnology. Thus, different assemblers have been developed specialized in chloroplast assemblies. Those assemblers often use the output of whole genome sequencing experiments as input. Such sequencing data usually contain the complete chloroplast genome information, even if the sequencing aims for the core genome. Different assembly tools have never been systematically compared. Here we present a benchmark of seven chloroplast assembly tools, capable to succeed in more than 60 % of real data sets. Our results show significant differences between the tested assemblers in terms of generating whole chloroplast genome sequences and computational requirements. Moreover, we suggest further development to improve user experience and success rate. In terms of reproducibility, we created docker images for each tested tool, which are available for the scientific community. Following the presented guidelines, users are able to analyze and screen data sets for chloroplast genomes using only standard computer infrastructure. Thus large scale screening for chloroplasts as hidden treasures within genomic sequencing data is feasible.

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Section: Introductionmentioning

confidence: 99%

A systematic comparison of chloroplast genome assembly tools

Freudenthal

Pfaff

Terhoeven

et al. 2019

Preprint

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“…The prospective of chloroplast phylogenomics to resolve contentious phylogenetic relationships, at nearly all taxonomic levels, have been proven over the recent past, e.g., in providing strong support for the evolutionary clades of the basal Angiosperms [4,7], the earlydiverging eudicots [8,23], and the early-diverging monocots [6]. Furthermore, through comparative phylogenomics, the availability of complete chloroplast genome sequences have significantly contributed to our understanding of genome evolutionary patterns driven by events such as gene transfers, duplications, and rearrangements [24,25].…”

Section: Introductionmentioning

confidence: 99%

Resolution of Intergeneric Relationships within the Early-Diverging Angiosperm Family Nymphaeaceae Based on Chloroplast Phylogenomics

He¹,

Gichira²,

Li³

et al. 2018

Preprint

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The order Nymphaeales, consisting of three families with a record of eight genera, has gained significant interest from botanists probably due to its position as a basal-angiosperm. The phylogenetic relationships within the order have well been studied and resolved; however, a few controversial nodes still remain in the Nymphaeaceae including the position of the genus Nuphar. The position of the genus Nuphar and the monophyly of the Nymphaeaceae family remain uncertain. This study adds to the increasing number of completely sequenced plastid genomes of the Nymphaeales and applies large chloroplast gene data set in reconstructing the intergeneric relationships within the Nymphaeaceae. Five complete chloroplast genomes were newly generated, including a first one for the monotypic genus Euryale. Using a set of 66 protein coding genes from the chloroplast genomes of 17 taxa, the phylogenetic position of Nuphar was determined and a monophyletic Nymphaeaceae family was obtained with a convincing statistical support from both partitioned and unpartitioned data schemes. Although genomic comparative analyses revealed a high degree of synteny among the chloroplast genomes of the ancient angiosperms, key minor variations were evident particularly in the contraction/expansion of the Inverted Repeat regions and in RNA editing events. Genome structure, gene content and arrangement were highly conserved among the chloroplast genomes.

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“…In terrestrial plants, the cpDNA varies between ≈120,000 and ≈160,000 bp (PALMER, 1995). For Gymnosperm, the size of cpDNA the chloroplast genome is significantly lower than for Angiosperm (XIAO-MING et al, 2017) and, for Eucalyptus spp. and another superior genus, cpDNAs with around 160,000 bp are commonly observed (EGUILUZ et al, 2017;LI et al, 2017;PAIVA et al, 2011;SAINA et al, 2018;STEANE et al, 2005 Regarding the cpSSR regions identified, the majority were classified as mononucleotides.…”

Section: Resultsmentioning

confidence: 94%

“…The size range observed in cpDNAs of closer species can be attributed to variations in intergenic regions length, that can be associated to species evolution process (XIAO-MING et al, 2017). In terrestrial plants, the cpDNA varies between ≈120,000 and ≈160,000 bp (PALMER, 1995).…”

Section: Resultsmentioning

confidence: 99%

In silico analysis of Pinus L. chloroplast DNA to microsatellites regions

Moro¹,

Pereira²,

Filho³

et al. 2019

Sci. For.

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The Pinus genus covers a wide variety of widely cultivated species due to adaptability, high growth and wood quality. Molecular markers have been used for many genetic analyses, and among them, the microsatellite markers (SSR) have several applications and can be found in chloroplast genome (cpDNA) as well as in nuclear genomes (ntDNA). The chloroplast microsatellites markers (cpSSR) can be used for gene flow analysis, identification of hybrids,clones, paternity tests, genetic diversity studies, phylogenetic analysis, among others. The work aimed to characterize the cpSSRs of Pinus species with cpDNA sequenced and deposited in NCBI (National Center for Biotechnology Information). In the twenty species of Pinus spp. studied, 1.542 cpSSRs were identified, with 86,45% of mononucleotide type, and the less frequent the penta-(1.10%) and hexanucleotide (1.04%) types. Predominated cpSSRs in non-coding regions (intergenic). The results indicate presence of a wide range of cpSSR for Pinus spp., which can subsidize breeding programs of interesting species.

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Inferring the evolutionary mechanism of the chloroplast genome size by comparing whole-chloroplast genome sequences in seed plants

Cited by 88 publications

References 95 publications

A systematic comparison of chloroplast genome assembly tools

A systematic comparison of chloroplast genome assembly tools

Resolution of Intergeneric Relationships within the Early-Diverging Angiosperm Family Nymphaeaceae Based on Chloroplast Phylogenomics

In silico analysis of Pinus L. chloroplast DNA to microsatellites regions

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