Modes of inheritance of two apomixis components, diplospory and parthenogenesis, in Chinese chive (Allium ramosum) revealed by analysis of the segregating population generated by back-crossing between amphimictic and apomictic diploids
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- Yamashita Ken-ichiro YAMASHITA Ken-ichiro
- Institute of Vegetable and Tea Science, National Agriculture and Food Research Organization
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- Nakazawa Yoshiko NAKAZAWA Yoshiko
- Tochigi Prefectural Agricultural Experiment Station
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- Namai Kiyoshi [他] NAMAI Kiyoshi
- Tochigi Prefectural Agricultural Experiment Station
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- AMAGAI Masayuki
- Tochigi Prefectural Agricultural Experiment Station
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- TSUKAZAKI Hikaru
- Institute of Vegetable and Tea Science, National Agriculture and Food Research Organization
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- WAKO Tadayuki
- Institute of Vegetable and Tea Science, National Agriculture and Food Research Organization
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- KOJIMA Akio
- Institute of Vegetable and Tea Science, National Agriculture and Food Research Organization
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Author(s)
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- Yamashita Ken-ichiro YAMASHITA Ken-ichiro
- Institute of Vegetable and Tea Science, National Agriculture and Food Research Organization
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- Nakazawa Yoshiko NAKAZAWA Yoshiko
- Tochigi Prefectural Agricultural Experiment Station
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- Namai Kiyoshi [他] NAMAI Kiyoshi
- Tochigi Prefectural Agricultural Experiment Station
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- AMAGAI Masayuki
- Tochigi Prefectural Agricultural Experiment Station
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- TSUKAZAKI Hikaru
- Institute of Vegetable and Tea Science, National Agriculture and Food Research Organization
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- WAKO Tadayuki
- Institute of Vegetable and Tea Science, National Agriculture and Food Research Organization
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- KOJIMA Akio
- Institute of Vegetable and Tea Science, National Agriculture and Food Research Organization
Journal
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- Breeding science
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Breeding science 62(2), 160-169, 2012-06-01
Japanese Society of Breeding
References: 34
-
1
- <no title>
-
ASKER S. E.
Apomixis in plants, 1992
Cited by (1)
-
2
- Asynchronous expression of duplicate genes in angiosperms may cause apomixis, bispory, tetraspory, and polycinbryony
-
CARMAN J. G.
Biol. J. Linn. Soc. 61, 51-94, 1997
Cited by (1)
-
3
- Evolution, domestication and taxonoiny
-
FRITSCH R. M.
Allium Crop Science : Recent Advances, 5-30, 2002
Cited by (1)
-
4
- Comparative mapping of the apospory-specific genomic region in two apomictic grasses : Pennisetum squamulatum and Cenchrus ciliaris
-
GOEL S.
Genetics 173, 389-400, 2006
Cited by (1)
-
5
- An analysis of methods for permanently mounting ovules cleared in four-and-a-half type clearing fluids
-
HERR J. M. Jr.
Stain Technol. 57, 161-169, 1982
Cited by (1)
-
6
- Degree of apomixis in Chinese chive (Allium tuberosum) estimated by esterase isozyme analysis
-
KOJIMA A.
Jpn. J. Breed. 41, 73-83, 1991
Cited by (1)
-
7
- Diplosporous embryo-sac formation and the degree of diplospory in Allium tuberosum
-
KOJIMA A.
Sex. Plant Reprod. 5, 72-78, 1992
Cited by (1)
-
8
- Pseudogamous embryogenesis and the degree of parthenogenesis in Allium tuberosum
-
KOJIMA A.
Sex. Plant Reprod. 5, 79-85, 1992
Cited by (1)
-
9
- Non-parthenogenetic plants detected in Chinese chive, a facultative apomict
-
KOJIMA A.
Breed. Sci. 44, 143-149, 1994
Cited by (1)
-
10
- Sexual diploids found among Mongolian accessions of Chinese chive
-
KOJIMA A.
Abstracts of the Second International Apomixis Conference, April 24-28, 2001, Como, Italy 86, 2001
Cited by (1)
-
11
- Apomixis : a developmental perspective
-
KOLTUNOW A. M.
Annu. Rev. Plant Biol. 54, 547-574, 2003
Cited by (1)
-
12
- Sexual reproduction is the default mode in apomictic Hieracium subgenus Polosella, in which two dominant loci faction to enable apomixis
-
KOLTUNOW A. M.
Plant J. 66, 890-902, 2011
Cited by (1)
-
13
- Nira (Chinese chives)
-
KUMAZAWA S.
Sosai-engei kakuron (Vegetable crops), 292-294, 1965
Cited by (1)
-
14
- Cytology of an autotetraploids Allium tuberosum
-
MATHUR M.
Indian J. Hort. 22, 382-384, 1965
Cited by (1)
-
15
- <no title>
-
MCMENIMAN S.
Project development : an economic evaluation of the potential benefits of interesting apomixis into hybrid rice, 1997
Cited by (1)
-
16
- Some genetic aspects of sex
-
MULLER H. J.
American Naturalist 66, 118-138, 1932
Cited by (1)
-
17
- Estimating the inheritance for parthenogenesis in tetraploid Chinese leek (Allium ramosum, syn. A. tuberosum)
-
NAKAZAWA Y.
Breed. Res. 8, 89-98, 2006
Cited by (1)
-
18
- <no title>
-
NISHIYAMA I.
Saibou Idengaku Kenkyuhou, 160-163, 1961
Cited by (1)
-
19
- Gametophytic apomixis
-
NOGLER G. A.
Embryology of angiosperms, 475-518, 1984
Cited by (1)
-
20
- Genetics of apospory in Ranunculus auricomus V, Conclusions
-
NOGLER G. A.
Bot. Helv. 94, 411-422, 1984
Cited by (1)
-
21
- Apomixis via recombination of genome regions for apomeiosis (diplospory) and parthenogenesis in Erigeron (daisy fleabane, Asteraceae)
-
NOYES R. D.
Sex. Plant Reprod. 19, 7-18, 2006
Cited by (1)
-
22
- Apomixis in the Asteraceae : Diamonds in the rough
-
NOYES R. D.
Func. Plant Sci. Biotech. 1, 207-222, 2007
Cited by (1)
-
23
- Two independent loci control agamospermy (apomixis) in the triploid flowering plant Erigeron annuus
-
NOYES R. D.
Genetics 155, 379-390, 2000
Cited by (1)
-
24
- An apospory specific genomic region is conserved between buffelgrass (Cenchrus ciliaris L.) and Pennisetum squamulatum Fresen
-
ROCHE D.
Plant J. 19, 203-208, 1999
Cited by (1)
-
25
- Genetics and utilization of apomixis for the improvement of guineagrass (Panicum maximum Jacq.)
-
SAVIDAN Y.
Proceedings of the XIV International Grasslands Congress, Lexington. Ky., 1981, 182-184, 1981
Cited by (1)
-
26
- Crosses between sexual and apomictic dandelions (Taraxacum) II : the breakdown of apomixis
-
VAN DIJK P. J.
Heredity 83, 715-721, 1999
Cited by (1)
-
27
- <no title>
-
AKIYAMA Y.
Plant Physiol. 134, 1733-1741, 2004
DOI Cited by (10)
-
28
- Inheritance of parental genomes in progenies of Poa pratensis L. From sexual and apomietic genotypes as assessed by RAPD markers and flow cytometry
-
BARCACCIA G.
Theor. Appl. Genet. 95, 516-524, 1997
Cited by (1)
-
29
- <no title>
-
BLAKEY C. A.
Genome 44, 222-230, 2001
DOI Cited by (2)
-
30
- Determining genetic origins of aberrant progeny from facultative apomictic Kentucky bluegrass using a combination of flow cytometry and silver-stained RAPD markers
-
HUFF D. R.
Theor. Appl. Genet. 87, 201-208, 1993
Cited by (1)
-
31
- Discovery of highly apomictic and highly amphimictic dihaploids in Allium tuberosum
-
KOJIMA A.
Sex. Plant Reprod. 10, 8-12, 1997
Cited by (3)
-
32
- Extreme fragmentation of meiotic chromosomes in Allium tuberosum ROTTLER.
-
KURITA M.
Memoirs of the Ehime University Section 2 Natural science 4(3B), 403-408, 1962-12
Cited by (1)
-
33
- <no title>
-
OZAIS-AKINS P.
Proc. Natl. Acad. Sci. 95, 5127-5132, 1998
DOI Cited by (7)
-
34
- A genetic linkage map of the diplosporous chromosomal region in Taraxacum officinale (common dandelion ; Asteraceae)
-
VIJVERBERG K.
Theor. Appl. Genet. 108, 725-732, 2004
Cited by (1)