Molecular Cytogenetic Analysis of Podocarpus and Comparison with Other Gymnosperm Species

Murray, B. G.; Friesen, Nikolai; Heslop-Harrison, J.S.

doi:10.1093/aob/mcf047

Cited by 44 publications

(33 citation statements)

References 30 publications

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“…Sone et al (1999) suggested that the insertion of 5S rDNA into 45S rDNA had taken place after the divergence from land plants because the co-localization of 5S and 45S rDNAs has been reported in some lower eukaryotes whereas not found in any spermatophytes. Thereafter, FISH analyses have revealed that a part or all of 5S rRNA loci in the chromosome complement co-localizes with 45S rRNA loci in a few species of spermatophytes, such as Podocarpus (Murray et al 2002), Ginkgo (Nakao et al 2005), Linum (Muravenko et al 2004), Rhoeo (Golczyk et al 2005), Hordeum (Taketa et al 2005) and Alstroemeria (Baeza et al 2007). In addition to the plant species, 120 Cytologia 74(2) H. Matoba and H. Uchiyama Fig.…”

Section: Discussionmentioning

confidence: 99%

Physical Mapping of 5S rDNA, 18S rDNA and Telomere Sequences in Three Species of the Genus Artemisia (Asteraceae) with Distinct Basic Chromosome Numbers

Matoba

Uchiyama

2009

CYTOLOGIA

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Summary Fluorescence in situ hybridization (FISH) with both of 5S and 18S rDNAs, and Arabidopsis-type telomere sequences was carried out in 3 species of the genus Artemisia (Asteraceae) with different basic chromosome numbers, xϭ8, 9 and 17, to understand their chromosomal organization and evolution. Chromosomal distribution of telomere sequences, which was restricted only to the ends of all chromosomes, was reported here for the first time in this genus. Although 5S rRNA gene loci are generally localized independently of 45S rRNA gene loci in eukaryotic chromosomes, all of the 5S rDNA sites are the same number and co-localized with the 18S rDNA sites in the species investigated. We also discussed the chromosomal evolution of A. feddei (xϭ8) and A. princeps (xϭ17) having a derivative basic chromosome number in this genus.

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Section: Discussionmentioning

confidence: 99%

Physical Mapping of 5S rDNA, 18S rDNA and Telomere Sequences in Three Species of the Genus Artemisia (Asteraceae) with Distinct Basic Chromosome Numbers

Matoba

Uchiyama

2009

CYTOLOGIA

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“…A group of monocotyledonous plants in the order Asparagales, forming a distinct clade in phylogenetic analysis, was reported previously to lack the ''typical'' Arabidopsis-type telomere repeat sequence (TTTAGGG) n (Fajkus et al 2005). the variability of the interstitial sites and copy number of the Arabidopsis-type telomeric sequences also seemed to be a characteristic of gymnosperms (Murray et al 2002). Schmidt et al (2000) analyzed the telomere repeats of conifers by Southern hybridization and showed that the low copy number of (CAC) 5 and (GACA) 4 in conifers and G. biloba L. was consistent with the data for angiosperms, which indicated that the structure of large conifer genomes and the organization of simple sequence repeats were to some extent similar to those of other, higher, plants.…”

Section: Introductionmentioning

confidence: 95%

Comparative analysis of telomeric restriction fragment lengths in different tissues of Ginkgo biloba trees of different age

et al. 2007

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Ginkgo trees of four different ages were selected as experimental material. Telomeric restriction fragment (TRF) lengths, as an indicator of telomere length, were determined for different tissues by Southern hybridization analysis. Statistical analysis was performed to compare two aspects of TRF length. By determining TRF lengths for different tissues for each age, a latent tendency was found. TRF length varied from short to long in these tissues in the order microspore < embryonal callus < leaf < branchlet. TRF lengths for leaf tissue and branchlet tissue were dissimilar for female and male mature trees, although this difference between TRF lengths for the two sexes was not statistically significant. Evaluation of TRF lengths for each tissue for trees of all four ages revealed TRF lengths increased with age to some extent. Different rates of change were found for leaf tissue and for branchlet tissue, although tendencies to increase were not linear for either. Finally, a simple mathematical model was formulated to describe the relationship between telomere length and age for Ginkgo biloba L.

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“…Knowledge on conifer genomes, for instance, which have chromosome complements organized as metacentrics with similar sizes, was greatly increased by using rDNA FISH procedures (Hizume et al, 2002;Siljak-Yakovlev et al, 2002;Vischi et al, 2003;Cai et al, 2006). The rDNA loci have been localized in chromosomes of several gymnosperms species, for example, in members of the following families: Pinaceae, Podocarpaceae, and Cycadeceae (Tagashira and Kondo, 2001;Murray et al, 2002;Siljak-Yakovlev et al, 2002;Cai et al, 2006). The most studied genus until now has been Pinus , where comparison of karyotypes for 20 species revealed a great variation in the distribution of rDNA loci, especially the 45S rDNA, contrasting with other highly conserved genome characteristics as chromosome number and morphology (Cai et al, 2006).…”

Section: Rdna Sequences As Important Cytogenetic Toolsmentioning

confidence: 99%

Molecular cytogenetics of forest trees

Ribeiro

Barão

Viegas³

et al. 2008

Cytogenet Genome Res

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The economic and ecological importance of forest trees, as well as their unique biological features, has recently raised the level of interest in studies on their genomes, including sequencing of the entire poplar genome. However, cytogenetic studies have not moved in parallel with developments in genomics. This is especially true for hardwood species characterized by small genomes and relatively high numbers of small chromosomes. Molecular cytogenetic studies have mainly been focused on coniferous species, owing to the larger size of their chromosomes, and have been applied exclusively for chromosome identification and comparative karyotyping in an attempt to understand genome evolution and phylogenetic relationships. In this context, rRNA genes physical mapped by FISH reveal particularly useful chromosomal landmarks with variable distribution patterns between species. Here we present a contribution of DNA markers used for chromosome analysis, which already allowed a deeper characterization and understanding of the processes underlying genome diversity of forest trees. The use of advanced cytogenetic techniques and other potential important methods for genome analysis of forest trees is also discussed.

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Molecular Cytogenetic Analysis of Podocarpus and Comparison with Other Gymnosperm Species

Cited by 44 publications

References 30 publications

Physical Mapping of 5S rDNA, 18S rDNA and Telomere Sequences in Three Species of the Genus Artemisia (Asteraceae) with Distinct Basic Chromosome Numbers

Physical Mapping of 5S rDNA, 18S rDNA and Telomere Sequences in Three Species of the Genus Artemisia (Asteraceae) with Distinct Basic Chromosome Numbers

Comparative analysis of telomeric restriction fragment lengths in different tissues of Ginkgo biloba trees of different age

Molecular cytogenetics of forest trees

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