Tomato (Solanum lycopersicum) is a major crop plant and a model system for fruit development. Solanum is one of the largest angiosperm genera1 and includes annual and perennial plants from diverse habitats. Here we present a high-quality genome sequence of domesticated tomato, a draft sequence of its closest wild relative, Solanum pimpinellifolium2, and compare them to each other and to the potato genome (Solanum tuberosum). The two tomato genomes show only 0.6% nucleotide divergence and signs of recent admixture, but show more than 8% divergence from potato, with nine large and several smaller inversions. In contrast to Arabidopsis, but similar to soybean, tomato and potato small RNAs map predominantly to gene-rich chromosomal regions, including gene promoters. The Solanum lineage has experienced two consecutive genome triplications: one that is ancient and shared with rosids, and a more recent one. These triplications set the stage for the neofunctionalization of genes controlling fruit characteristics, such as colour and fleshiness.

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The tomato genome sequence provides insights into fleshy fruit evolution

We have developed a DNA extraction procedure for milligram amounts of plant tissue. Yields ranged from 0.3-200 nanograms of DNA per milligram of tissue. The factors affecting yield are discussed. Fresh tissue, as well as herbarium specimens (22-118 years old) and mummified seeds and embryos (500 to greater than 44 600 years old) were used. All tissues attempted (57 types from 29 species) yielded measurable amounts of DNA. In no case tested was inhibition observed for restriction enzymes BamHI or EcoRI.

Extraction of DNA from milligram amounts of fresh, herbarium and mummified plant tissues

The number of angiosperm species for which nuclear DNA amount estimates have been made has nearly trebled since the last collected lists of such values were published, and therefore, publication of a more comprehensive list is overdue. This paper lists absolute nuclear DNA amounts for 753 angiosperm species. The data were assembled primarily for reference purposes, and so the species are listed in alphabetical order, as this was felt to be more helpful to cyto- and biochemists whom, it is anticipated, will be among its major users. The paper also reviews aspects of the history, nomenclature, methods, accuracy and problems of nuclear DNA estimation in angiosperms. No attempt is made to reconsider those aspects of nuclear DNA estimation which have been fully revised previously, although the bibliography of such aspects is given. Instead, the paper is intended as a source of basic information regarding the terminology, practice and limitations of nuclear DNA estimation, especially by Feulgen microdensitometry, as currently practiced.

Nuclear DNA Amounts in Angiosperms

Plant cell walls are the starting materials for many commercial products, from lumber, paper and textiles to thickeners, films and explosives. The cell wall is secreted by each cell in the plant body, forming a thin fibreglass-like network with remarkable strength and flexibility. During growth, plant cells secrete a protein called expansin, which unlocks the network of wall polysaccharides, permitting turgor-driven cell enlargement. Germinating grass pollen also secretes an unusual expansin that loosens maternal cell walls to aid penetration of the stigma by the pollen tube. Expansin's action has puzzling implications for plant cell-wall structure. The recent explosion of gene sequences and expression data has given new hints of additional biological functions for expansins.

Loosening of plant cell walls by expansins

Genome sequences reveal that a deluge of DNA from organelles has constantly been bombarding the nucleus since the origin of organelles. Recent experiments have shown that DNA is transferred from organelles to the nucleus at frequencies that were previously unimaginable. Endosymbiotic gene transfer is a ubiquitous, continuing and natural process that pervades nuclear DNA dynamics. This relentless influx of organelle DNA has abolished organelle autonomy and increased nuclear complexity.

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Endosymbiotic Gene Transfer: Organelle Genomes Forge Eukaryotic Chromosomes

Transfer of organelle DNA into the nuclear genome has been significant in eukaryotic evolution, because it appears to be the origin of many nuclear genes. Most studies on organelle DNA transfer have been restricted to evolutionary events but experimental systems recently became available to monitor the process in real time. We designed an experimental screen to detect plastid DNA (ptDNA) transfers to the nucleus in whole plants grown under natural conditions. The resultant genotypes facilitated investigation of the evolutionary mechanisms underlying ptDNA transfer and nuclear integration. Here we report the characterization of nuclear loci formed by integration of newly transferred ptDNA. Large, often multiple, fragments of ptDNA between 6.0 and 22.3 kb in size are incorporated into chromosomes at single Mendelian loci. The lack of chloroplast transcripts of comparable size to the ptDNA integrants suggests that DNA molecules are directly involved in the transfer process. Microhomology (2–5 bp) and rearrangements of ptDNA and nuclear DNA were frequently found near integration sites, suggesting that nonhomologous recombination plays a major role in integration. The mechanisms of ptDNA integration appear similar to those of biolistic transformation of plant cells, but no sequence preference was identified near junctions. This article provides substantial molecular analysis of real-time ptDNA transfer and integration that has resulted from natural processes with no involvement of cell injury, infection, and tissue culture. We highlight the impact of cytoplasmic organellar genome mobility on nuclear genome evolution.

/pdf/simple-and-complex-nuclear-loci-created-by-newly-transferred-43zjr27ymi.pdf

Simple and complex nuclear loci created by newly transferred chloroplast DNA in tobacco

Long tracts of DNA with high sequence homology to chloroplast DNA were isolated from nuclear genomic libraries of Nicotiana tabacum. One lambda EMBL4 clone was characterised in detail and assigned to nuclear DNA. The majority of the 15.5-kb sequence is greater than 99% homologous with its chloroplast DNA counterpart, but a single base deletion causes premature termination of the reading frame of the psaA gene. One region of the clone contains a concentration of deleted regions, and these were used to identify and quantify the sequence in native nuclear DNA by polymerase chain reaction (PCR) methods. An estimated 15 copies of this specific region are present in a 1c tobacco nucleus.

Tobacco nuclear DNA contains long tracts of homology to chloroplast DNA.

In eukaryotes, many genes were transferred to the nucleus from prokaryotic ancestors of the cytoplasmic organelles during endosymbiotic evolution. In plants, the transfer of genetic material from the plastid (chloroplast) and mitochondrion to the nucleus is a continuing process. The cellular location of a kanamycin resistance gene tailored for nuclear expression (35SneoSTLS2) was monitored in the progeny of reciprocal crosses of tobacco (Nicotiana tabacum) in which, at the start of the experiments, the reporter gene was confined either to the male or the female parental plastid genome. Among 146,000 progeny from crosses where the transplastomic parent was male, 13 transposition events were identified, whereas only one atypical transposition was identified in a screen of 273,000 transplastomic ovules. In a second experiment, a transplastomic β-glucuronidase reporter gene, tailored to be expressed only in the nucleus, showed frequent stochastic expression that was confined to the cytoplasm in the somatic cells of several plant tissues. This gene was stably transferred in two out of 98,000 seedlings derived from a male transplastomic line crossed with a female wild type. These data demonstrate relocation of plastid DNA to the nucleus in both somatic and gametophytic tissue and reveal a large elevation of the frequency of transposition in the male germline. The results suggest a new explanation for the occurrence of uniparental inheritance in eukaryotes.

http://www.plantphysiol.org/content/plantphysiol/148/1/328.full.pdf

Transfer of Plastid DNA to the Nucleus Is Elevated during Male Gametogenesis in Tobacco

Dot-like micro B chromosomes of Brachycome dichromosomatica were analysed for their sequence composition. Southern hybridization patterns of a total micro B probe to genomic DNA from plants with and without micro Bs demonstrated that the micro Bs shared sequences with the A chromosomes. In addition to telomere, rDNA and common A and B chromosome sequences, a new B-specific, highly methylated tandem repeat (Bdm29) was detected. After in situ hybridization with Bdm29 the entire micro B chromosome was labelled and clustering of the condensed micro Bs could be observed at interphase. A high number of Bdm29-like sequences were also found in the larger B chromosomes of B. dichromosomatica and in other Bs within the genus Brachycome.

A repetitive DNA sequence common to the different B chromosomes of the genus Brachycome.

MANY eukaryotic DNAs can be resolved into two or more components by centrifugation to equilibrium in neutral CsCl1,2, the minor components being called satellite DNAs. In addition to CsCl satellites, minor portions of the genome have been resolved from the main DNA band by differential binding with Ag+ or Hg2+ ions, followed by centrifugation in Cs2SO4.

Jeremy N. Timmis

Papers

Simple and complex nuclear loci created by newly transferred chloroplast DNA in tobacco

Tobacco nuclear DNA contains long tracts of homology to chloroplast DNA.

Transfer of Plastid DNA to the Nucleus Is Elevated during Male Gametogenesis in Tobacco

A repetitive DNA sequence common to the different B chromosomes of the genus Brachycome.

Localisation of satellite DNA sequences in nuclei and chromosomes of two plants.