Access the full text.
Sign up today, get DeepDyve free for 14 days.
T. Samatadze, O. Muravenko, K. Popov, A. Zelenin (2001)
Genome comparison of the Matricaria chamomilla L. varieties by the chromosome C- and OR-banding patternsCaryologia, 54
Haibao Tang, J. Bowers, Xiyin Wang, R. Ming, Maqsudul Alam, A. Paterson (2008)
Synteny and Collinearity in Plant GenomesScience, 320
M. Gardes, T. Bruns (1993)
ITS primers with enhanced specificity for basidiomycetes ‐ application to the identification of mycorrhizae and rustsMolecular Ecology, 2
(1976)
Zlaki SSSR (Grasses of the Soviet Union)
(1977)
On the Minimal Main Chromosome Cycle (2n = 4) in Colpodium versicolor (Stev.) Woronow (Poaseae)
Antony Cox, S. Bennett, A. Parokonny, A. Kenton, M. Callimassia, M. Bennett (1993)
Comparison of Plant Telomere Locations using a PCR-generated Synthetic ProbeAnnals of Botany, 72
Rudolf Schmid, W. Clayton, S. Renvoize (1987)
Genera Graminum: Grasses of the World
V. Saunders, A. Houben (2001)
The pericentromeric heterochromatin of the grass Zingeria biebersteiniana (2n = 4) is composed of Zbcen1-type tandem repeats that are intermingled with accumulated dispersedly organized sequences.Genome, 44 6
A. Rodionov, N. Tyupa, E. Kim, E. Machs, I. Loskutov (2005)
Genomic Configuration of the Autotetraploid Oat Species Avena macrostachya Inferred from Comparative Analysis of ITS1 and ITS2 Sequences: on the Oat Karyotype Evolution during the Early Events of the Avena Species DivergenceRussian Journal of Genetics, 41
Kotseruba Violetta, K. Pistrick, D. Gernand, A. Meister, A. Ghukasyan, I. Gabrielyan, A. Houben (2005)
Characterisation of the low-chromosome number grass Colpodium versicolor (Stev.) Schmalh. (2n = 4) by molecular cytogeneticsCaryologia, 58
E. Pahlich, Chr. Gerlitz (1980)
A rapid DNA isolation procedure for small quantities of fresh leaf tissuePhytochemistry, 19
(2001)
Specificity of Heterochromatic Regions Analysis in Small Chromosomes of Plants , Dokl
N.N. Tsvelev, Z.V. Bolkhovskikh (1965)
Genus Zingeria P. Smirn. and Related Genera of Gramineae (Karyo-Systematic Study)Bot. Zh., 50
J. Felsenstein (1985)
CONFIDENCE LIMITS ON PHYLOGENIES: AN APPROACH USING THE BOOTSTRAPEvolution, 39
(1939)
Cytological Bases of Evolution
A. Paterson, J. Bowers, B. Chapman (2004)
Ancient polyploidization predating divergence of the cereals, and its consequences for comparative genomics.Proceedings of the National Academy of Sciences of the United States of America, 101 26
(2006)
The Comparative Genome Study of the Flax Species of Sections Adenolinum and Stellerolinum by Means of Fluorescent Hybridization in situ (FISH)
(1965)
Smirn. and Related Genera of Gramineae (Karyo-Systematic Study)
(2006)
Chromosome Numbers of Some Grasses (Poaceae): Aveneae, Poeae, Phalarideae, Phleeae, Bromeae, Triticeae
S.T. Bennett, I.J. Leitch, M.D. Bennett (1995)
Chromosome Identification and Mapping in the Grass Zingeria biebersteiniana (2n = 4) Using FluorochromesChromosome Res., 3
N.N. Tsvelev (1976)
Zlaki SSSR
K. Ridgway, J. Duck, J. Young (2003)
Identification of roots from grass swards using PCR-RFLP and FFLP of the plastid trnL (UAA) intronBMC Ecology, 3
(2008)
Molecular Phylogenetic Study of Relationship between Representatives of Genus Poa (Poaseae)
R. Cremonini, M. Castiglione, V. Grif, V. Kotseruba, E. Punina, A. Rodionov, O. Muravenko, K. Popov, T. Samatadze, A. Zelenin (2003)
Chromosome Banding and DNA Methylation Patterns, Chromatin Organisation and Nuclear DNA Content in Zingeria biebersteinianaBiologia Plantarum, 46
W. Gerlach, T. Dyer (1980)
Sequence organization of the repeating units in the nucleus of wheat which contain 5S rRNA genes.Nucleic acids research, 8 21
T. White (1990)
Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics, 18
(1931)
Karyo-Systematic Study of the Family Gramineae, Tr
(2008)
Update on Comparative Genomics of Grasses Comparative Genomics of Grasses Promises a Bountiful Harvest
(1992)
Karyo-Systematics of Zingeria biebersteiniana (Poaceae)
A.H. Paterson, J.E. Bowers, F.A. Feltus (2009)
Comparative Genomics of Grasses Promises a Bountiful HarvestPlant Physiol., 149
S. Bennett, I. Leitch, M. Bennett (1995)
FISH of T-DNA on metaphase preparations reveals non-uniform recombination in Petunia hybridaChromosome Research, 3
O. Muravenko, T. Samatadze, K. Popov, A. Amosova, A. Zelenin (2001)
Comparative Genome Analysis in Two Flax Species by C-Banding PatternsRussian Journal of Genetics, 37
(1972)
Towards Karyological and Geographical Study of Aragats Montains Flora
V. Kotseruba, D. Gernand, A. Meister, A. Houben (2003)
Uniparental loss of ribosomal DNA in the allotetraploid grass Zingeria trichopoda (2n = 8).Genome, 46 1
Sudhir Kumar, K. Tamura, M. Nei (2004)
MEGA3: Integrated software for Molecular Evolutionary Genetics Analysis and sequence alignmentBriefings in bioinformatics, 5 2
(1998)
Computer and Visual Analysis of G-Like Banding Patterns of Matricaria chamomilla Chromosomes
(1975)
Differential Staining of Chromosomes in Zingeria biebersteiniana (Claus) P. Smirn. during Mitosis and Meiosis, Izv. Sib
W. Gerlach, J. Bedbrook (1979)
Cloning and characterization of ribosomal RNA genes from wheat and barley.Nucleic acids research, 7 7
D. Sutherland (1987)
Genera Graminum. Grasses of the WorldBrittonia, 39
A. Oskooi (2008)
Molecular Evolution and Phylogenetics
C. Alving, Z. Beck, Nicos Karasavva, G. Matyas, M. Rao (2006)
HIV-1, lipid rafts, and antibodies to liposomes: implications for anti-viral-neutralizing antibodies (Review)Molecular Membrane Biology, 23
(2001)
Specificity of Heterochromatic Regions Analysis in Small Chromosomes of Plants
(1974)
On the Minimal Main Chromosome Cycle in Poaceae
M. Bennett, J. Smith, A. Seal (1986)
The karyotype of the grass Zingeria biebersteiniana (2n = 4) by light and electron microscopyCanadian journal of genetics and cytology, 28
Chromosome C-banding and two-color fluorescent in situ hybridization (FISH) were used to compare the chromosomes, to identify the chromosomal localization of the 45S and 5S rRNA genes, and to analyze the sequences of internal transcribed spacers 1 and 2 (ITS1 and ITS2) of the 45S rRNA genes in the genomes of grasses Zingeria biebersteiniana (2n = 4), Z. pisidica, Z. trichopoda (2n = 8), Colpodium versicolor (2n = 4), and Catabrosella variegata (syn. Colpodium variegatum) (2 n = 10). Differences in C-banding pattern were observed for two Z. biebersteiniana accessions from different localities. Similar C-banding patterns of chromosomes 1 and 2 were demonstrated for the Z. pisidica and Z. biebersteininana karyotypes. Chromosome C banding and localization of the 45S and 5S rRNA genes on the chromosomes of the two Zingeria species confirmed the assumption that Z. pisidica is an allotetraploid with one of the subgenomes similar to the Z. biebersteiniana genome. ITS comparisons showed that the unique two-chromosome grasses (x = 2)—Z. biebersteiniana (2n = 4), Z. trichopoda (2n = 8), Z. pisidica (2n = 8), and C. versicolor (2n = 4), which were earlier assigned to different tribes of subtribes of the family Poaceae—represent two closely related genera, the genetic distance (p-distance) between their ITSs being only 1.2–4.4%. The Zingeria species and C. versicolor formed a common clade with Catabrosella araratica (2n = 42, x = 7) on a molecular phylogenetic tree. Thus, the karyotypes of Zingeria and Colpodium, which have the lowest known basic chromosome number (x = 2), proved to be monophyletic, rather than originating from different phylogenetic lineages.
Russian Journal of Genetics – Springer Journals
Published: Nov 12, 2009
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.