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The search field accepts scientific plant names, i. e. names of genera or Brassicaceae tribes.

Examples:

  • Camelineae — will find information about all member genera of tribe Camelineae.
  • Arabidopsis — will find information about the genus Arabidopsis.

After having typed 3 characters, you'll be provided with suggestions from the database.

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"Mesopolyploidy: A not recent whole genome duplication event (WGD) that followed the early (paleoploid) WGD at the origin of the whole Brassicaceae family. Mesopolyploid species exhibit diploid-like meiosis, disomic inheritance, and diploidized genomes up to quasidiploid complements with a very low number of chromosomes. However, the parental subgenomes are still discernible by comparative (cyto)genetic and phylogenetic methods."

  • Mandakova T, Joly S, Krzywinski M, Mummenhoff K, Lysak MA. 2010. Fast Diploidization in Close Mesopolyploid Relatives of Arabidopsis. The Plant Cell, 22:2277–2290
  • Lysak A und Koch MA (2011) Phylogeny, Genome, and Karyotype Evolution of Crucifers (Brassicaceae). In: R. Schmidt; I. Bancraft (eds.) Genetics and Genomics of the Brassicaceae pp. 1-33. Springer New York, Dordrecht, Heidelberg, London
Neopolyploidy: "A recent whole genome duplication event (WGD) via auto- or allopolyploidization."
  • Lysak A und Koch MA (2011) Phylogeny, Genome, and Karyotype Evolution of Crucifers (Brassicaceae). In: R. Schmidt; I. Bancraft (eds.) Genetics and Genomics of the Brassicaceae pp. 1-33. Springer New York, Dordrecht, Heidelberg, London
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Scalable Vector Graphics: a graphics format suitable for import into many graphics programs e. g. Adobe, Corel, Inkscape...
"Comma-separated values": a data format suitable for import into most spreadsheet and database programs. The column separator used here is the semicolon. Character coding is UTF-8.
A format commonly used in phylogenetics to represent a tree structure as nested brackets.
"American standard code for information interchange": the name can be used almost synonymously with "plain text", also including a very limited graphics capability.
A format commonly used to store alignments along with meta-information, e. g. analysis parameters. Used e. g. by PAUP* and MrBayes.
Probably due to its simplicity the most frequently used sequence or alignment format ever designed. Used by a vast majority of bioinformatics programs and packages.
Widely used alignment format. Required as input by many bioinformatics programs. The interleaved version is exported here. Unfortunately very limited meta-information capabilities.
The alignment format originally used by the GCG Wisconsin bioinformatics package (e. g. Pileup). Still widely used as an alignment format.
The format used by Clustal (and some other programs) to store alignments.
Manual

A search in the Brassicaceae cytogenetics database according to your search terms is performed.

In the result table you can further narrow your search by giving a keyword (like species or subspecies epithets) in the field on the upper right. Click on column headers to choose a sorting column.

Search terms can include names of Brassicaceae tribes, resulting in reported data from all tribe representatives.

Visualization: A circular phylogenetic diagram of Brassicaceae tribes. The bar charts depict average genome size within tribes as a fraction of the family's maximum, with standard deviation.

Drag near name tags to turn the wheel.

Click on tribe names to display corresponding search results.

Downloads

Species Checklist v1.3

Heidelberg University >  COS Heidelberg >  Biodiversity and Plant Systematics >  BrassiBase  > Cytogenetics Tool

Cytogenetics Tool

The “Cytogenetics Tool” offers the search for currently available data on genome size, chromosome numbers, and ploidal level, and currently ca. 14% and 55%, respectively, out of the 3977 species from the Brassicaceae are incorporated in BrassiBase for genome size and chromosome numbers, respectively. Taxonomic groups from genera and species down to subspecies are searchable.

The phylogenetic backbone for the Cytogenetics Tool” is based on a synpopis of published comprehensive phylogenetic analyses.

 

Search in cytogenetic data
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The search field accepts scientific plant names, i. e. names of genera or Brassicaceae tribes.

Examples:

  • Arabideae — will find information about all member genera of tribe Arabideae.
  • Arabis — will find information about the genus Arabis.
  • Arabis alpina — will limit the search to the species Arabis alpina

After having typed 3 characters, you'll be provided with suggestions from the database.

Registered users can also use the advanced search to find data by combinations of values. Choose fields of interest and set criteria using dropdown menus. Fill in desired values (numbers or Y/N).

Details

Genome size data and chromosome numbers are fundamental information to characterize genomes, which are very dynamic in plants in both size and structure. Genome sizes in the Brassicaceae family are comparatively small on average (1C = 0.51 pg). Only a few Brassicaceae species from various tribes of Lineage III reach genome sizes up to 1C = 4.31 pg. Genome up- and downsizing has been shown to be rapid in the Brassicaceae family (Lysak et al., 2009), and the number of polyploids is with about 65% in congruence with the 50-70% portion of polyploids estimated for all extant angiosperms (Wendel, 2000). Tetraploidy is most frequent within the Brassicaceae, and numerous genera are characterized by high-polyploidy (e.g., Draba). Taxa frequently occur both as diploid and polyploid cytotypes.

Genome sizes were obtained from literature; chromosome counts were assembled from Warwick et al. (2006), and additional counts are ongoingly added from the literature since 2006. Ploidal levels were estimated based on literature and in collaboration with Martin Lysak (Brno). For all datasets, literature values were subjected to a critical quality check, and the newest taxonomic concept was applied.

References
  • Hohmann, H, Wolf, E, Lysak, M, Koch MA. 2015. A Time-Calibrated Road Map of Brassicaceae Species Radiation and Evolutionary History. The Plant Cell 27: 2770-2784.
  • Lysak, M.A., Koch, M.A., Leitch, I.J., Beaulieau, J.M., and Meister, A. (2009). The dynamic ups and downs of genome size evolution in Brassicaceae. Mol. Biol. Evol. 26: 85–98.
  • Warwick, S.I. and Al-Shehbaz, I.A. (2006). Brassicaceae: Chromosome number index and database on CD-Rom. Plant Syst. Evol. 259: 237–248.
  • Wendel J. F. 2000. Genome evolution in polyploids. Plant Molecular Biology 42: 225-249.

 

Cytogenetic Data Plots


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