Effect of Recurrent Selection on Combining Ability in Maize Breeding Populations

Abiotic and biotic constraints have widespread yield reducing effects on maize and should receive high priority for maize breeding research. Molecular Breeding offers opportunities for plant breeders to develop cultivars with resilience to such diseases with precision and in less time duration. The term molecular breeding is used to describe several modern breeding strategies, including marker-assisted selection, marker-assisted backcrossing, marker-assisted recurrent selection and genomic selection. Recent advances in maize breeding research have made it possible to identify and map precisely many genes associated with DNA markers which include genes governing resistance to biotic stresses and genes responsible for tolerance to abiotic stresses. Marker assisted selection (MAS) allows monitoring the presence, absence of these genes in breeding populations whereas marker assisted backcross breeding effectively integrates major genes or quantitative trait loci (QTL) with large effect into widely grown adapted varieties. For complex traits where multiple QTLs control the expression, marker assisted recurrent selection (MARS) and genomic selection (GS) are employed to increase precision and to reduce cost of phenotyping and time duration. The biparental mapping populations used in QTL studies in MAS do not readily translate to breeding applications and the statistical methods used to identify target loci and implement MAS have been inadequate for improving polygenic traits controlled by many loci of small effect. Application of GS to breeding populations using high marker densities is emerging as a solution to both of these deficiencies. Hence, molecular breeding approaches offers ample opportunities for developing stress resilient and high-yielding maize cultivars.

Download Full-text

Evaluation of tolerance to high plant densities and plant efficiency of maize breeding populations developed by recurrent selection for grain yield

10.31274/rtd-180816-1350 ◽

1978 ◽

Author(s):

Theodore M. Crosbie

Keyword(s):

Grain Yield ◽

Recurrent Selection ◽

Maize Breeding ◽

Breeding Populations ◽

Plant Densities ◽

Selection For ◽

Plant Efficiency

Download Full-text

Improvement of effectiveness in maize breeding

Acta Agronomica Hungarica ◽

10.1556/aagr.54.2006.3.10 ◽

2006 ◽

Vol 54 (3) ◽

pp. 351-358 ◽

Cited By ~ 2

Author(s):

P. Pepó

Keyword(s):

Recurrent Selection ◽

Genetic Manipulation ◽

Field Testing ◽

Tissue Cultures ◽

Maize Breeding ◽

Breeding Programmes ◽

Speed Up ◽

Selection For

Plant regeneration via tissue culture is becoming increasingly more common in monocots such as maize (Zea mays L.). Pollen (gametophytic) selection for resistance to aflatoxin in maize can greatly facilitate recurrent selection and the screening of germplasm for resistance at much less cost and in a shorter time than field testing. In vivo and in vitro techniques have been integrated in maize breeding programmes to obtain desirable agronomic attributes, enhance the genes responsible for them and speed up the breeding process. The efficiency of anther and tissue cultures in maize and wheat has reached the stage where they can be used in breeding programmes to some extent and many new cultivars produced by genetic manipulation have now reached the market.

Download Full-text

Effects of Two Cycles of Recurrent Selection for Combining Ability in an Open‐Pollinated Variety of Corn 1

Agronomy Journal ◽

10.2134/agronj1955.00021962004700070010x ◽

1955 ◽

Vol 47 (7) ◽

pp. 319-323 ◽

Cited By ~ 5

Author(s):

D. P. McGill ◽

J. H. Lonnquist

Keyword(s):

Combining Ability ◽

Recurrent Selection ◽

Selection For

Download Full-text

Commercial Utilization of the Products of Recurrent Selection for Specific Combining Ability in Maize 1

Crop Science ◽

10.2135/cropsci1972.0011183x001200050015x ◽

1972 ◽

Vol 12 (5) ◽

pp. 602-604 ◽

Cited By ~ 3

Author(s):

E. S. Horner ◽

W. H. Chapman ◽

H. W. Lundy ◽

M. C. Lutrick

Keyword(s):

Combining Ability ◽

Recurrent Selection ◽

Specific Combining Ability ◽

Selection For

Download Full-text

Identification of Heterotic Pairs by Full-Sib Reciprocal Recurrent Selection in Maize Synthetic Populations on Turda CompositeA(B)(2) x Turda CompositeB(A)(2)

Bulletin of University of Agricultural Sciences and Veterinary Medicine Cluj-Napoca Agriculture ◽

10.15835/buasvmcn-agr:9585 ◽

2013 ◽

Vol 70 (1) ◽

pp. 208-213

Author(s):

Andreea Daniela ONA ◽

Ioan HAÈ˜ ◽

Ivan ILARIE ◽

Voichița HAÈ˜ ◽

Nicolae TRITEAN ◽

...

Keyword(s):

Recurrent Selection ◽

Inbred Lines ◽

Heterotic Group ◽

Yield Potential ◽

Reciprocal Recurrent Selection ◽

Maize Breeding ◽

Gene Effects ◽

Synthetic Populations ◽

Additive Gene ◽

Selection Test

In the last 40 years, pre-breeding works induced, in more and more centers of maize breeding, full-sib reciprocal recurrent selection programmes to identify some heterotic pairs which can be sources for obtaining performance inbred lines. The aim is to identify the heterotic pairs with the best results according to the yield potential of maize, the breaking and falling resistance, and the grains moisture at the harvesting time. The creation programme of A and B composite population started at ARDS Turda in 1985. Inside of A composite came the next inbred lines: B73, A632, M117, TC209, T291, being from the B SSS heterotic group, and inside of B composite came the inbred lines Mo17, C103, TC 208, T248, W633, appreciated by us or being related to Lancaster Sure Crop heterotic group. The experimentation was done in two orientation comparative cultures, each one with 49 variants, in 4 repetitions; the comparative culture was a balanced quadratic grid of 7x7 type. From each culture were chosen the first six variants, which were evaluated according to the next characters: production potential, breaking and falling resistance, grains moisture at harvest. The presented results are a part from the second cycle of full-sib reciprocal recurrent selection. Test crosses and self-pollinations were made on plants from the two composites which had two cobs; on the first cob from A Composite realised the cross with the corresponding plant from the B Composite, and from the plant panicle of the B Composite was collected pollen to pollinate the chosen plant from the A Composite. At the both plants from the crossing, the second cob was self-pollinated and kept in reserve until 2010, when the test crosses was experimented and were selected the pairs with the best results according to the above characters. Using the full-sib reciprocal recurrent selection, we can successfully harnessing, simultaneously, the additive and non-additive gene effects.

Download Full-text

Inheritance of Physico-chemical Seed Characters Related to Culinary Quality in Dry Bean

Journal of the American Society for Horticultural Science ◽

10.21273/jashs.115.3.492 ◽

1990 ◽

Vol 115 (3) ◽

pp. 492-499 ◽

Cited By ~ 16

Author(s):

N.N. Wassimi ◽

G.L. Hosfield ◽

M.A. Uebersax

Keyword(s):

Combining Ability ◽

Recurrent Selection ◽

Weight Coefficient ◽

Additive Variance ◽

Dry Bean ◽

Mean Values ◽

Culinary Quality ◽

Physico Chemical ◽

Diallel Mating Design ◽

San Fernando

Culinary quality in dry bean (Phaseolus vulgaris L.) depends on attributes of seeds prevailing at harvest and is determined by the genetic architecture of cultivars and by unpredictable environmental factors. Variation among genotypes for culinary quality has been shown to be heritable; however, the efficacy of selection depends on a knowledge of the genetic control of the measured traits. A diallel mating design was used to estimate the combining ability of parents and determine the inheritance of nine culinary quality traits important to processors and consumers. Genetic variability among eight parents, 56 F2, and 56 F3 progenies was confirmed by significant mean squares from analyses of variance. Significant variability detected between F2 and F3 progenies for soaked bean weight (SBWT), soaked bean water content (SBWC), and clumps (CLMP) was due to inbreeding effects. General combining ability (GCA) components were highly significant and overshadowed specific combining ability (SCA) components in the F2 and F3 for SBWT, SBWC, split beans (SPLT), and the washed-drained weight coefficient (WDWTR), indicating that additive variance predominated. Ratios of GCA: SCA components were equal to or less than unity for CLMP, washed-drained weight (WDWT), and texture (TEXT), indicating that both additive and nonadditive effects contributed to trait expression. Significant SCA effect variances were noted for `Sanilac', `San Fernando', `Nep-2', and `A-30' for WDWT and TEXT, implying that progeny from crosses of these parents had higher or lower mean values for the traits titan the average expected on the basis of GCA. Graphs of the regression of Vr on Wr showed that genes controlling WDWT and TEXT were completely dominant in most cases. Recurrent selection, which seeks to concentrate favorable alleles with additive effects in populations, may he an effective breeding procedure to improve the culinary quality of dry beans. It is not feasible to breed for TEXT and WDWT simultaneously because of a negative correlation between the traits.

Download Full-text