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Methodologies for estimating the sample size required for genetic conservation of outbreeding crops (1989)

Crossa, J.

Springer

Theoretical and applied genetics 77 (1989), S. 153-161

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ISSN: 1432-2242

Keywords: Seed regeneration ; Sample size ; Random genetic drift ; Effective population size ; Allele frequency

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary The main purpose of germplasm banks is to preserve the genetic variability existing in crop species. The effectiveness of the regeneration of collections stored in gene banks is affected by factors such as sample size, random genetic drift, and seed viability. The objective of this paper is to review probability models and population genetics theory to determine the choice of sample size used for seed regeneration. A number of conclusions can be drawn from the results. First, the size of the sample depends largely on the frequency of the least common allele or genotype. Genotypes or alleles occurring at frequencies of more than 10% can be preserved with a sample size of 40 individuals. A sample size of 100 individuals will preserve genotypes (alleles) that occur at frequencies of 5%. If the frequency of rare genotypes (alleles) drops below 5%, larger sample sizes are required. A second conclusion is that for two, three, and four alleles per locus the sample size required to include a copy of each allele depends more on the frequency of the rare allele or alleles than on the number. Samples of 300 to 400 are required to preserve alleles that are present at a frequency of 1%. Third, if seed is bulked, the expected number of parents involved in any sample drawn from the bulk will be less than the number of parents included in the bulk. Fourth, to maintain a rate of breeding (F) of 1 %, the effective population size (N e) should be at least 150 for three alleles, and 300 for four alleles. Fifth, equalizing the reproductive output of each family to two progeny doubles the effective size of the population. Based on the results presented here, a practical option is considered for regenerating maize seed in a program constrained by limited funds.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00266180

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Statistical genetic considerations for maintaining germ plasm collections (1993)

Crossa, J. ; Hernandez, C. M. ; Bretting, P. ; [et al.]

Springer

Theoretical and applied genetics 86 (1993), S. 673-678

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ISSN: 1432-2242

Keywords: Genetic resources conservation ; Sample size ; Allele frequency ; Probability models ; Core subsets

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract One objective of the regeneration of genetic populations is to maintain at least one copy of each allele present in the original population. Genetic diversity within populations depends on the number and frequency of alleles across all loci. The objectives of this study on outbreeding crops are: (1) to use probability models to determine optimal sample sizes for the regeneration for a number of alleles at independent loci; and (2) to examine theoretical considerations in choosing core subsets of a collection. If we assume that k-1 alleles occur at an identical low frequency of p0 and that the kth allele occurs at a frequency of 1-[(k-1)p0], for loci with two, three, or four alleles, each with a p0 of 0.05, 89–110 additional individuals are required if at least one allele at each of 10 loci is to be retained with a 90% probability; if 100 loci are involved, 134–155 individuals are required. For two, three, or four alleles, when p0 is 0.03 at each of 10 loci, the sample size required to include at least one of the alleles from each class in each locus is 150–186 individuals; if 100 loci are involved, 75 additional individuals are required. Sample sizes of 160–210 plants are required to capture alleles at frequencies of 0.05 or higher in each of 150 loci, with a 90–95% probability. For rare alleles widespread throughout the collection, most alleles with frequencies of 0.03 and 0.05 per locus will be included in a core subset of 25–100 accessions.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00222655

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Analysing yield stability of maize genotypes using a spatial model (1988)

Crossa, J. ; Westcott, B. ; Gonzalez, C.

Springer

Theoretical and applied genetics 75 (1988), S. 863-868

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ISSN: 1432-2242

Keywords: Spatial model ; Stability ; Maize

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary The yield stability of some CIMMYT tropical maize (Zea mays L.) populations of early and intermediate maturity, measured by the performance of varieties derived from them, was determined. Results of the stability analyses, conducted over international environments from 1980 to 1983, indicated that selections from Mezcla Amarilla exhibited good stability in high yielding sites. Varieties derived from Antigua-Republica Dominicana tended to be more stable in unfavourable environments, whereas selections from Blanco Cristalino-1 and Blanco Dentado-2 were stable in both low and high production sites. The combination of enviromental factors in the specific test locations, namely Poza Rica (Mexico), Tocumen (Panama), Islamabad (Pakistan), and Ferkessedougou (Ivory Coast), allowed selection of varieties that are very stable in other regions of the world. The varieties formed on the basis of multilocational data do not seem to be any more stable than those formed using data from a single location.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00258046

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AMMI adjustment for statistical analysis of an international wheat yield trial (1991)

Crossa, J. ; Fox, P. N. ; Pfeiffer, W. H. ; [et al.]

Springer

Theoretical and applied genetics 81 (1991), S. 27-37

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ISSN: 1432-2242

Keywords: Wheat ; Multilocation trials ; Predictive accuracy ; Cluster analysis ; Stability

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Multilocation trials are important for the CIMMYT Bread Wheat Program in producing high-yielding, adapted lines for a wide range of environments. This study investigated procedures for improving predictive success of a yield trial, grouping environments and genotypes into homogeneous subsets, and determining the yield stability of 18 CIMMYT bread wheats evaluated at 25 locations. Additive Main effects and Multiplicative Interaction (AMMI) analysis gave more precise estimates of genotypic yields within locations than means across replicates. This precision facilitated formation by cluster analysis of more cohesive groups of genotypes and locations for biological interpretation of interactions than occurred with unadjusted means. Locations were clustered into two subsets for which genotypes with positive interactions manifested in high, stable yields were identified. The analyses highlighted superior selections with both broad and specific adaptation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00226108

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The area under the function: an index for selecting desirable genotypes (1993)

Hernandez, C. M. ; Crossa, J. ; Castillo, A.

Springer

Theoretical and applied genetics 87 (1993), S. 409-415

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ISSN: 1432-2242

Keywords: Genotype x environment interaction ; Adaptation ; Stability ; Desirability index

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract The linear regression approach has been widely used for selecting high-yielding and stable genotypes targeted to several environments. The genotype mean yield and the regression coefficient of a genotype's performance on an index of environmental productivity are the two main stability parameters. Using both can often complicate the breeder's decision when comparing high-yielding, less-stable genotypes with low-yielding, stable genotypes. This study proposes to combine the mean yield and regression coefficient into a unified desirability index (D i). Thus, D i is defined as the area under the linear regression function divided by the difference between the two extreme environmental indexes. D i is equal to the mean of the i th genotype across all environments plus its slope multiplied by the mean of the environmental indexes of the two extreme environments (symmetry). Desirable genotypes are those with a large D i. For symmetric trials the desirability index depends largely on the mean yield of the genotype and for asymmetric trials the slope has an important influence on the desirability index. The use of D i was illustrated by a 20-environments maize yield trial and a 25-environments wheat yield trial. Three maize genotypes out of nine showed values of D i 's that were significantly larger than a hypothetical, stable genotype. These were considered desirable, even though two of them had slopes significantly greater than 1.0. The results obtained from ranking wheat genotypes on mean yield differ from a ranking based on D i .

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00215085

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