Broadening the avenue of intersubgenomic heterosis in oilseed Brassica

Zou, Jun; Zhu, Jiali; Huang, Shunmou; Tian, Entang; Xiao, Yong; Fu, Donghui; Tu, Jinxing; Ting-dong, FU; Meng, Jianghong

doi:10.1007/s00122-009-1201-4

Cited by 81 publications

(56 citation statements)

References 32 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

mentioning

confidence: 99%

“…Several studies have demonstrated the value of utilizing allelic diversity of the allied Brassica species for increased heterosis in B. napus (Qian et al, 2005;Li et al, 2006;Zou et al, 2010;Girke et al, 2011Girke et al, , 2012Jesske et al, 2013;Li et al, 2014). For example, Zou et al (2010) observed a high level of heterosis in test hybrids while using germplasm diversified with the A genome of B. rapa and the C genome of B. carinata. A number of researchers have also utilized genetic diversity of resynthesized B. napus (from B. rapa × B. oleracea interspecific cross) for the improvement of openpollinated or hybrid winter B. napus cultivars (Gehringer et al, 2007;Radoev et al, 2008;Girke et al, 2011Girke et al, , 2012Jesske et al, 2013).…”

mentioning

confidence: 99%

“…Thus, most of the studies conducted to date to evaluate different gene pools of Brassica for the improvement of spring or winter or semi-winter B. napus were focused on either the use of spring B. napus for spring type hybrid (Grant and Beversdorf, 1985;Brandle and McVetty, 1990;Engqvist and Becker, 1991;Diers et al, 1996;Cuthbert et al, 2009), or the use of winter or semi-winter B. napus for spring type hybrid (Butruille et al, 1999;Udall et al, 2004;Quijada et al, 2004Quijada et al, , 2006Qian et al, 2007;Kramer et al, 2009), or the use of winter or semi-winter B. napus for winter type hybrid (Lefort-Buson et al, 1987;Qian et al, 2009), or the use of the allied species for winter or semiwinter (Gehringer et al, 2007;Radoev et al, 2008;Zou et al, 2010;Fu et al, 2012;Girke et al, 2012;Li et al, 2014) or spring Seyis et al, 2006) type of hybrid. However, so far, no study has been conducted to compare the value of different gene pools for increasing the level of heterosis and seed yield in spring B. napus hybrid canola.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Patterns of Heterosis in Three Distinct Inbred Populations of Spring Brassica napus Canola

2016

View full text Add to dashboard Cite

Allelic diversity of the allied species of Brassica napus L. as well as of the winter form of this species has been demonstrated to be related with increasing productivity of hybrid spring B. napus cultivars. To compare potential value of the different gene pools of Brassica species three spring B. napus inbred populations were developed by use of a B. oleracea L. line, a spring B. napus breeding line, and a winter B. napus cultivar crossed to a spring B. napus ‘Hi‐Q’; and test hybrids of these inbred lines were produced by crossing with Hi‐Q as the common tester. Mid‐parent heterosis (MPH) showed a negative correlation with seed yield of the inbred lines in all three populations; however, a positive correlation existed between seed yield of the inbred lines and heterosis over Hi‐Q (HiQH) (or, inbred vs. hybrid yield). On average, the level of MPH in hybrid of the inbred lines derived from B. napus × B. oleracea cross was twice greater than the level of heterosis found for the inbred lines derived from spring × spring or winter × spring B. napus crosses. The inbred population derived from winter × spring cross gave highest seed yield, and this population also gave highest HiQH. The results suggested that B. oleracea and winter canola could be used in spring B. napus canola breeding for accumulating additive and non‐additive effect genes for increased seed yield in hybrid cultivars.

show abstract

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Patterns of Heterosis in Three Distinct Inbred Populations of Spring Brassica napus Canola

2016

View full text Add to dashboard Cite

show abstract

“…The newly derived B. napus line may become a source of germplasm for broadening the genetic base and expanding yellow seed resources for B. napus. Importantly, by taking advantage of hybrids between the newly derived line and natural B. napus, stronger intersubgenomic heteroses between the subgenomic A j and A n , A r and A n , and C o and C n components could be studied and utilized (Zou et al 2010). From a breeding viewpoint, it is imperative that the reproductive efficiency and combining ability of the new B. napus lines, including those studied here, be properly evaluated in field trials before being used for heterosis.…”

Section: Discussionmentioning

confidence: 99%

Characterization of interploid hybrids from crosses between Brassica juncea and B. oleracea and the production of yellow-seeded B. napus

Wen

Zhu

et al. 2012

Theor Appl Genet

Self Cite

View full text Add to dashboard Cite

Yellow-seeded Brassica napus was for the first time developed from interspecific crosses using yellow-seeded B. juncea (AABB), yellow-seeded B. oleracea (CC), and black-seeded artificial B. napus (AACC). Three different mating approaches were undertaken to eliminate B-genome chromosomes after trigenomic hexaploids (AABBCC) were generated. Hybrids (AABCC, ABCC) from crosses AABBCC × AACC, AABBCC × CC and ABCC × AACC were advanced by continuous selfing in approach 1, 2 and 3, respectively. To provide more insight into Brassica genome evolution and the cytological basis for B. napus resynthesis in each approach, B-genome chromosome pairing and segregation were intensively analyzed in AABCC and ABCC plants using genomic in situ hybridization methods. The frequencies at which B-genome chromosomes underwent autosyndesis and allosyndesis were generally higher in ABCC than in AABCC plants. The difference was statistically significant for allosyndesis but not autosyndesis. Abnormal distributions of B-genome chromosomes were encountered at anaphase I, including chromosome lagging and precocious sister centromere separation of univalents. These abnormalities were observed at a significantly higher frequency in AABCC than in ABCC plants, which resulted in more rapid B-genome chromosome elimination in the AABCC derivatives. Yellow or yellow-brown seeds were obtained in all approaches, although true-breeding yellow-seeded B. napus was developed only in approaches 2 and 3. The efficiency of the B. napus construction approaches was in the order 1 > 3 > 2 whereas this order was 3 > 2 > 1 with respect to the construction of yellow-seeded B. napus. The results are discussed in relation to Brassica genome evolution and the development and utilization of the yellow-seeded B. napus obtained here.

show abstract

“…Inter-subgenomic heterosis may also occur in the disomic polyploid oilseed rape after partial introgression of subgenomic components from its different species (Zou et al 2010). Intensive DNA marker-aided selection in offspring ensuing from intercrossing first generation lines may assist increasing the exotic subgenomic components in further generations.…”

Section: Polyploid Heterosismentioning

confidence: 99%

Heterosis and Interspecific Hybridization

Ríos

2015

Plant Breeding in the Omics Era

View full text Add to dashboard Cite

Broadening the avenue of intersubgenomic heterosis in oilseed Brassica

Cited by 81 publications

References 32 publications

Patterns of Heterosis in Three Distinct Inbred Populations of Spring Brassica napus Canola

Patterns of Heterosis in Three Distinct Inbred Populations of Spring Brassica napus Canola

Characterization of interploid hybrids from crosses between Brassica juncea and B. oleracea and the production of yellow-seeded B. napus

Heterosis and Interspecific Hybridization

Contact Info

Product

Resources

About