FISH Mapping of Telomeric and Non-Telomeric (AG3T3)3 Reveal the Chromosome Numbers and Chromosome Rearrangements of 41 Woody Plants

Luo, Xiaomei; He, Zhoujian; Liu, Jun-cheng; Wu, Hongyi; Gong, Xiao

doi:10.3390/genes13071239

Cited by 5 publications

(13 citation statements)

References 63 publications

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“…(2n = 28), P. cyrtonema (2n = 22) (Sun 1996, Chen and Zhou 2005); ii ) Zanthoxylum acanthopodium Candelle (2n = 64), Zanthoxylum dimorphophyllum Hemsley (2n = 36/68), Zanthoxylum scandens Blume (2n = 68), Zanthoxylum oxyphyllum Edgeworth (2n = 72), Zanthoxylum tomentellum J.D. Hance (2n = 72), Zanthoxylum simulans Hance (2n =∼132, Z. nitidum (2n = 68), Z. armatum (2n = 66/98/128/132/136), Z. bungeanum (2n = 132/136) (Zhang and Hartley 2008, Chen et al 2009, Yu et al 2010, Luo et al 2018d, Luo et al 2022b, He et al 2023, Hu et al 2023); iii ) Bletilla formosana (2n = 32/36), B. striata (2n = 32/34/36/48/51/64/76), B. ochracea (2n = 34/36) (Miduno 1954, He et al 2022c, Huan et al 2022, Yang et al 2023); iv ) J. regia and J. sigillata (2n = 34) (Luo and Chen 2020), Juglans (2n = 32) (Woodworth 1930, Hans 1970, Tulecke et al 1988, Mu and Xi 1988, Mu et al 1990). In this study, P. cyrtonema (2n = 18), Z. bungeanum (2n = 76/134/136/160), Z. armatum (2n = 96/100/102/104/132), Z. nitidum (2n = 66), B. formosana, B. striata , B. ochracea , J. regia, and J. sigillata (all 2n = 34).…”

Section: Discussionmentioning

confidence: 99%

“…The species used for this experiment were chosen due to the discovery of karyotype realignments (Luo et al 2017, Luo et al 2018d, Liu and Luo 2019, Luo and Liu 2019, Luo ang Chen 2019, 2020, Luo and He 2021, Luo et al 2022a, b, He et al 2022a, b, c, 2023). Because these species were checked, their 5S rDNA has not yet been explored.…”

Section: Methodsmentioning

confidence: 99%

“…The patent oligonucleotide FISH (Oligo-FISH) technology is widely problematic in related cytogenetic investigations compared to conventional FISH analysis because of its low cost (Beliveau et al 2012). Moreover, based on available DNA sequencing data, oligonucleotide probes (Oligo-probe) have been developed and successfully applied to many plants (He et al 2020, Xin et al 2020, Luo et al 2022a, b, He et al 2023). Therefore, examining the 5S rDNA sites by Oligo-FISH would efficiently contribute to further cytogenetic research on the 64 plants.…”

Section: Introductionmentioning

confidence: 99%

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Karyotype Description and Comparative Chromosomal Mapping of 5S rDNA in 21 species

Luo,

Liu,

Gong

et al. 2024

Preprint

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5S rDNA is essential component of all cell types. A survey was conducted to study the 5S rDNA site number, position, and origin of signal pattern diversity in 64 plants using fluorescencein situhybridization. The species used for this experiment were chosen due to the discovery of karyotype rearrangement, and for species checked in which 5S rDNA has not yet been explored. The chromosome number was 14160, while the chromosome length was 0.636.88 m, with 37 plants (58%) had small chromosome (<3 m). The chromosome numbers of three species and 5S rDNA loci of 19 species have been reported for the first time. 5S rDNA was varied and abundant in signal site number (218), position (e.g., interstitial, distal, and proximal position, occasionally, outside chromosome), and even as intense (e.g., strong, weak, and slight). Our results exposed modifiability in the number and location of 5S rDNA in 33 plants and demonstrated an extensive stable number and location of 5S rDNA in 31 plants. The potential origin of signal pattern diversity was probably caused by chromosome rearrangement (e.g., deletion, duplication, inversion, translocation), polyploidization, self-incompatibility, and chromosome satellites. These data characterized the variability of 5S rDNA within the karyotypes of the 64 plants that exhibited massive chromosomal rearrangements and provided anchor points for genetic physical maps. These data prove the utility of the 5S rDNA oligonucleotide as a chromosome marker in identifying plant chromosomes. This method provides a basis for developing similar applications for cytogenetic analysis in other species.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Karyotype Description and Comparative Chromosomal Mapping of 5S rDNA in 21 species

Luo,

Liu,

Gong

et al. 2024

Preprint

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“…With large amounts of genomic data now available and easily accessible, predicting or verifying laboratory experiments with in silico work is now an increasingly more sensible plan that should be accessible to any laboratory. Equally, as knowledge of telomeres and particularly subtelomeric satellites expands, it is apparent that open-access databases of this knowledge, particularly the results from karyotyping studies [ 151 , 167 ], would benefit the research community as a whole and make such data more visible and manageable. There are still many unanswered questions in satellite research making this an inviting topic for the open-minded researcher.…”

Section: Discussionmentioning

confidence: 99%

“…When such clusters are big enough, these can be detected by FISH ( Figure 2 d–f) and distinguished from telomeres (e.g., [ 49 , 157 , 159 , 164 , 165 , 166 , 167 , 168 , 169 ]). If they are shorter than the detection limit of this method, they can still show a positive signal when investigated by Southern hybridization or primer extension ( Figure 2 g).…”

Section: Telomere Minisatellites Are Much Like Any Other Dna Sequencesmentioning

confidence: 99%

Telomeres and Their Neighbors

Jenner

Peška

Fulnečková

et al. 2022

Genes

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Telomeres are essential structures formed from satellite DNA repeats at the ends of chromosomes in most eukaryotes. Satellite DNA repeat sequences are useful markers for karyotyping, but have a more enigmatic role in the eukaryotic cell. Much work has been done to investigate the structure and arrangement of repetitive DNA elements in classical models with implications for species evolution. Still more is needed until there is a complete picture of the biological function of DNA satellite sequences, particularly when considering non-model organisms. Celebrating Gregor Mendel’s anniversary by going to the roots, this review is designed to inspire and aid new research into telomeres and satellites with a particular focus on non-model organisms and accessible experimental and in silico methods that do not require specialized equipment or expensive materials. We describe how to identify telomere (and satellite) repeats giving many examples of published (and some unpublished) data from these techniques to illustrate the principles behind the experiments. We also present advice on how to perform and analyse such experiments, including details of common pitfalls. Our examples are a selection of recent developments and underexplored areas of research from the past. As a nod to Mendel’s early work, we use many examples from plants and insects, especially as much recent work has expanded beyond the human and yeast models traditional in telomere research. We give a general introduction to the accepted knowledge of telomere and satellite systems and include references to specialized reviews for the interested reader.

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Comparative cytogenetics of kenaf (Hibiscus cannabinus L.) breeding lines reveal chromosomal variability and instability

Ankrah,

El-nagish,

Breitenbach

et al. 2024

Genet Resour Crop Evol

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Kenaf (Hibiscus cannabinus), a native warm-seasonal crop in Africa, is being considered for genetic improvement for local bast fiber production. To expedite its genetic improvement through breeding, kenaf genotypes from Ghana were assessed for genomic diversity regarding their chromosomal composition and ploidy levels. To gain insight into the repetitive DNA fractions in kenaf, the organization of 5S and 35S rRNA genes, as well as telomeric signal patterns were studied by a molecular cytogenetic approach. Using multi-color fluorescent in situ hybridization, distinct rDNA loci and Arabidopsis-like telomere signal patterns were revealed. The 5S rRNA genes were conserved in kenaf and localized in interstitial regions of two chromosomes across all accessions. The 35S rRNA genes were variable across the kenaf accessions and localized at sub-terminal ends and rarely interstitially in eight or six chromosome arms. Telomeric signals were observed at terminal ends of all chromosomes and the chromosome configuration of Ghana kenaf accessions were each confirmed to be 2n = 2x = 36. Observed genomic instability in kenaf is discussed. This report provides cytogenetic insights into the genome organization of kenaf and variability of its breeding lines. Additionally, this study sets the basis for further research to analyze the repetitive DNA sequences and develop reference karyotypes to reveal genetic and evolutionary relationships between cultivated and wild Hibiscus species.

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FISH Mapping of Telomeric and Non-Telomeric (AG3T3)3 Reveal the Chromosome Numbers and Chromosome Rearrangements of 41 Woody Plants

Cited by 5 publications

References 63 publications

Karyotype Description and Comparative Chromosomal Mapping of 5S rDNA in 21 species

Karyotype Description and Comparative Chromosomal Mapping of 5S rDNA in 21 species

Telomeres and Their Neighbors

Comparative cytogenetics of kenaf (Hibiscus cannabinus L.) breeding lines reveal chromosomal variability and instability

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