Abstract
Genetic diversity is the foundation of any crop improvement program, but the most cultivated Upland cotton [Gossypium hirsutum L., 2n = 52, genomic formula 2(AD)1] has a very narrow gene pool resulting from its evolutionary origin and domestication history. Cultivars of this cotton species (G. hirsutum L.) are prized for their combination of exceptional yield, other agronomic traits, and good fiber properties, whereas the other cultivated 52-chromosome species, G. barbadense L. [2n = 52, genomic formula 2(AD)2], is widely regarded as having the opposite attributes. It has exceptionally good fiber qualities, but generally lower yield and less desirable agronomic traits. Breeders have long aspired to combine the best attributes of G. hirsutum and G. barbadense, but have had limited success. F1 hybrids are readily created and largely fertile, so the limited success may be due to cryptic biological and technical challenges associated with the conventional methods of interspecific introgression. We have developed a complementary alternative approach for introgression based on chromosome substitution line, followed by increasingly sophisticated genetic analyses of chromosome-derived families to describe the inheritance and breeding values of the chromosome substitution lines. Here, we analyze fiber quality traits of progeny families from a partial diallel crossing scheme among selected chromosome substitution lines (CS-B lines). The results provide a more detailed and precise QTL dissection of fiber traits, and an opportunity to examine allelic interaction effects between two substituted chromosomes versus one substituted chromosome. This approach creates new germplasm based on pair wise combinations of quasi-isogenic chromosome substitutions. The relative genetic simplicity of two-chromosome interactions departs significantly from complex or RIL-based populations, in which huge numbers of loci are segregating in all 26 chromosome pairs. Data were analyzed according to the ADAA genetic model, which revealed significant additive, dominance, and additive-by-additive epistasis effects on all of the fiber quality traits associated with the substituted chromosome or chromosome arm of CS-B lines. Fiber of line 3-79, the donor parent for the substituted chromosomes, had the highest Upper Half Mean length (UHM), uniformity ratio, strength, elongation, and lowest micronaire among all parents and hybrids. CS-B16 and CS-B25 had significant additive effects for all fiber traits. Assuming a uniform genetic background of the CS-B lines, the comparative analysis of the double-heterozygous hybrid combinations (CS-B × CS-B) versus their respective single heterozygous combinations (CS-B × TM-1) demonstrated that interspecific epistatic effects between the genes in the chromosomes played a major role in most of the fiber quality traits. Results showed that fiber of several hybrids including CS-B16 × CS-B22Lo, CS-B16 × CS-B25 and CS-B16 × TM-1 had significantly greater dominance effects for elongation and hybrid CS-B16 × CS-B17 had higher fiber strength than their parental lines. Multiple antagonistic genetic effects were also present for fiber quality traits associated with most of the substituted chromosomes and chromosome arms. Results from this study highlight the vital importance of epistasis in fiber quality traits and detected novel effects of some cryptic beneficial alleles affecting fiber quality on the 3-79 chromosomes, whose effects were not detected in the 3-79 parental lines.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adams G (2006) Cotton’s global market. In: Proceedings of Beltwide Cotton Conference, pp 2347–2350
Bowman DT, Gutierrez OA (2003) Sources of fiber strength in the U.S. Upland cotton from 1980 to 2000. J Cot Sci 7:164–169
Bowman DT, May OL, Calhoun DS (1996) Genetic base of upland cotton cultivars released between 1970 and 1990. Crop Sci 36:577–581
Boykin JC (2006) Gross monetary returns for conventionally processed cotton cultivars from Mississippi. J Cot Sci 10:284–289
Bradow JM, Davidonis GH (2000) Quantification of fiber quality and the cotton production–processing interface: a physiologist perspective. J Cot Sci 4:34–64
Gingle AR, Yang H, Chee PW, May OL, Rong J, Bowman DT, Lubbers EL, Day JL, Paterson AH (2006) An integrated web resource for cotton. Crop Sci 46:1998–2007
He DH, Lin ZX, Zhang XL, Nie YC, Guo XP, Zhang YX, Wu L (2007) QTL mapping for economic traits based on a dense genetic map of cotton with PCR-based markers using the interspecific cross of Gossypium hirsutum × Gossypium barbadense. Euphytica 153:181–197
He DH, Lin ZX, Zhang XL, Zhang YX, Li W, Nie YC, Guo XP (2008) Dissection of genetic variance in advanced generations from an interspecific cross of Gossypium hirsutum and G. barbadense. Plant Br 127:286–294
Hutchinson JB, Silow RA, Stephens SG (1947) The evolution of Gossypium and the differentiation of the cultivated cottons. Oxford University Press, London
Jenkins JN, Wu J, McCarty JC, Saha S, Gutierrez OA, Hayes R, Stelly DM (2006) Genetic effects of thirteen Gossypium barbadense L. chromosome substitution lines in topcrosses with Upland cotton cultivars: I. Yield and yield components. Crop Sci 46:1169–1178
Jenkins JN, Wu J, McCarty JC, Saha S, Gutierrez OA, Hayes R, Stelly DM (2007) Genetic effects of thirteen Gossypium barbadense L. chromosome substitution lines in topcrosses with Upland Cotton cultivars: II fiber quality traits. Crop Sci 47:561–570
Jiang CX, Wright RJ, El-Zik K, Paterson AH (1998) Polyploid formation created unique avenues for response to selection in Gossypium (cotton). Proc Natl Acad Sci USA 95:4419–4424
Jiang C, Wright RJ, Woo SS, DelMonte TA, Paterson AH (2000) QTL analysis of leaf morphology in tetraploid Gossypium (cotton). Theor Appl Genet 100:409–418
Kohel RJ, Richmond TR, Lewis CF (1970) Texas Marker-1. Description of a genetic standard for Gossypium hirsutum L. Crop Sci 10:670–671
Lacape JM, Nguyen TB, Courtois B, Belot JL, Giband M, Gourlot JP, Gawryziak G, Roques S, Hau B (2005) QTL analysis of cotton fiber quality using multiple Gossypium hirsutum × Gossypium barbadense backcross generations. Crop Sci 45:123–140
McCarty JC, Jenkins JN (2005) Registration of 14 primitive derived cotton germplasm lines with improved fiber strength. Crop Sci 45:2668–2669
McCarty JC Jr, Jenkins JN, Tang B, Watson CE (1996) Genetic analysis of primitive cotton germplasm accession. Crop Sci 36:581–585
McCarty JC Jr, Wu J, Jenkins JN (2007) Use of primitive derived cotton accessions from agronomic and fiber traits improvement: variance components and genetic effects. Crop Sci 47:100–110
McKenzie WH (1970) Fertility relationships among interspecific hybrid progenies of Gossypium. Crop Sci 10:571–574
Meredith WR (1984) Quantitative genetics. In: Kohel RJ, Lewis CF (eds) Cotton. ASA-CSSA-SSSA, Madison, pp 131–150
Miller RG (1974) The jackknife: a review. Biometrika 61:1–15
Osborn CT, Kramer C, Graham E, Braun CJ (2007) Insight and inoovations from wide crosses: examples from Canola and Tomato. Crop Sci 47(S3):S228–S237
Paterson AH, Saranga Y, Menz M, Jiang CX, Wright RJ (2003) QTL analysis of genotype X environment interactions affecting cotton fiber quality. Theor Appl Genet 106:384–396
Paterson AH, Boman RK, Brown SM, Chee PW, Gannaway JR, Gingle AR, May OL, Smith CW (2004) Reducing the genetic vulnerability in cotton. Crop Sci 44:1900–1901
Patterson DD (1939) Statistical technique in agricultural research. McGraw Hill, New York
Percy RG, Cantrell RG, Zhang J (2006) Genetic variation for agronomic and fiber properties in an introgressed recombinant inbred population of cotton. Crop Sci 46:1311–1317
Reinisch AJ, Dong J, Brubaker CL, Stelly DM, Wendel JF, Paterson AH (1994) A detailed RFLP map of cotton, Gossypium hirsutum × Gossypium barbadense: chromosome organization and evolution in a disomic polyploid genome. Genetics 138:829–847
Rong J, Abbey C, Bowers JE, Brubaker CL, Chang C, Chee PW, Delmonte TA, Ding X, Garza JJ, Marler BS, Park C, Pierce GJ, Rainey KM, Rastogi VK, Schulze SR, Trolinder NL, Wendel JF, Wilkins TA, Williams-Coplin TD, Wing RA, Wright RJ, Zhao X, Zhu L, Paterson AH (2004) A 3347-locus genetic recombination map of sequence-tagged sites reveals features of genome organization, transmission and evolution of cotton (Gossypium). Genetics 166:389–417
Rong J, Feltus FA, Waghmare VN, Pierce GJ, Chee PW, Draye X, Saranga Y, Wright RJ, Wilkins TA, May OL, Smith CW, Gunnway JR, Wendel JF, Paterson AH (2007) Meta-analysis of polyploidy cotton QTLs shows unequal contributions of subgenomes to a complex network of genes clusters implicated in lint fiber development. Genetics 176:2577–2588
Saha S, Wu J, Jenkins JN, McCarty JC Jr, Gutierrez OA, Stelly DM (2004) Effect of chromosome substitutions from Gossypium barbadense L. 3-79 into G. hirsutum L. TM-1 on agronomic and fiber traits. J Cot Sci 8:162–169
Saha S, Jenkins JN, Wu J, McCarty JC, Gutierrez OA, Percy RG, Cantrell RG, Stelly DM (2006) Effects of chromosome-specific introgression in Upland cotton on fiber and agronomic traits. Genetics 172:1927–1938
Saha S, Jenkins JN, Wu J, McCarty JC, Stelly DM (2008a) Genetic analysis of agronomic and fiber traits using four interspecific chromosome substitution lines in cotton. Plant Br 127:612–618
Saha S, Wu J, Jenkins JN, McCarty JC, Stelly DM (2008b) Chromosome substitution lines (CS-B) revealed the presence of cryptic beneficial alleles in G. barbadense with potential to increase lint and seedcotton yield in Upland cotton. In: Proceedings of Belt Cotton Conference, p 831
Saha S, Wu J, Jenkins JN, McCarty JC, Hayes R, Stelly DM (2010) Genetic dissection of chromosome substitution lines discovered novel alleles in Gossypium barbadense L. with potential for improving agronomic traits including yield. Theor Appl Genet 120:193–1205
SAS Institute (2001) SAS User’s Guide, Version 8. SAS Institute, Cary
Smith CW, Coyle GG (1997) Association of fiber quality parameters and within boll yield components in Upland cotton. Crop Sci 37:1775–1779
Stelly DM, Saha S, Raska DA, Jenkins JN, McCarty JC, Gutierrez OA (2005) Registration of 17 Upland (Gossypium hirsutum) germplasm lines disomic for different G. barbadense chromosome or arm substitutions. Crop Sci 45:2663–2665
Stephens SG (1949) The cytogenetics of speciation in Gossypium. I. Selective elimination of the donor parent genotype in interspecific backcrosses. Genetics 34:627–637
Ulloa M, Meredith WR Jr, Shappley ZW, Kahler AL (2002) RFLP genetic linkage maps from four F2.3 populations and a joinmap of Gossypium hirsutum L. Theor Appl Genet 104:200–208
USDA Economic Research Service (2009) Cotton: market outlook. http://www.ers.usda.gov/briefing/Cotton/2005baseline.htm
USDA-NASS (2002) 2002 Census of agriculture. USDA-National Agricultural Statistics Service, Washington. http://www.nass.usda.gov/Census_of_Agriculture/index.asp
Wendel JF, Olson PD, Stewart JM (1989) Genetic diversity, introgression, and independent domestication of Old World cultivated cottons. Am J Bot 76:1795–1806
Wu J, Jenkins JN, McCarty JC, Wu D (2006) Variance component estimation using the ADAA model when genotypes vary across environments. Crop Sci 46:174–179
Wu J, Jenkins JN, McCarty JC, Saha S, Percy R (2008) Genetic association of lint yield with its components in cotton chromosome substitution lines. Euphytica 164:199–207
Zeng L, Meredith WR Jr (2009) Association among lint yield components and fiber properties in an introgressed population of cotton. Crop Sci 49:1647–1654
Zhu J (1989) Estimation of genetic variance components in the general mixed model. Dissertation, North Carolina State University
Zhu J (1993) Methods of predicting genotype value and heterosis for offspring of hybrids (Chinese). J Biomath 8(1):32–44
Acknowledgments
We thank Ms. Lillie Hendrix for helping in field research. We acknowledge partial support from the following sources: Cotton Inc., Texas State Support Committee, and Texas Dept. Agriculture Food & Fiber Research Grant Program. Joint publication of USDA/ARS, Mississippi Agricultural and Forestry Experiment Station, South Dakota State University, and Texas A & M University. Approved for publication as Journal Article No. J-11897 of the Mississippi Agricultural and Forestry Experiment Station.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by B. Friebe.
Mention of trademark or proprietary product does not constitute a guarantee or warranty of the product by the United States Department of Agriculture and does not imply its approval to the exclusion of other products that may also be suitable.
Rights and permissions
About this article
Cite this article
Saha, S., Wu, J., Jenkins, J.N. et al. Delineation of interspecific epistasis on fiber quality traits in Gossypium hirsutum by ADAA analysis of intermated G. barbadense chromosome substitution lines. Theor Appl Genet 122, 1351–1361 (2011). https://doi.org/10.1007/s00122-011-1536-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00122-011-1536-5