Principles of Plant Genetics and Breeding. George Acquaah
Читать онлайн.| Название | Principles of Plant Genetics and Breeding |
|---|---|
| Автор произведения | George Acquaah |
| Жанр | Биология |
| Серия | |
| Издательство | Биология |
| Год выпуска | 0 |
| isbn | 9781119626695 |
2 Edwardson, J.R. (1970). Cytoplasmic male sterility. Botanical Review 36: 341–420.
3 Franklin‐Tong, V.E.E. (2008). Self‐Incompatibility in Flowering Plants Evolution Diversity and Mechanisms. Berlin/Heidelberg: Springer‐Verlag.
4 Franklin‐Tong, N.V. and Franklin, F.C. (2003). Gametophytic self‐incompatibility inhibits pollen tube growth using different mechanisms. Trends in Plant Science 8: 598–605.
5 Holsinger, K.E. (2000). Reproductive systems and evolution in vascular plants. Proceedings of the National Academy of Sciences of the United States of America 97: 7037–7042.
6 Horandl, E. (2010). The evolution of self‐fertility in apomictic plants. Sexual Plant Reproduction 23: 73–86.
7 Kiesselbach, T.A. (1999). The Structure and Reproduction of Corn. Cold Spring Habor: CSHL Press. 50th anniversary edition.
8 Lasa, J.M. and Bosemark, N.O. (1993). Male sterility. In: Plant Breeding (eds. M.D. Hayward, N.O. Bosemark, I. Romagosa and M. Cerezo), 213–228. Dordrecht: Springer.
9 Laughnan, J.R. and Gabby‐Laughnan, S. (1983). Cytoplasmic male sterility in maize. Annual Review of Genetics 17: 27–48.
10 Mable, B.K. (2008). Genetic causes and consequences of the breakdown of self‐incompatibility: case studies in the Brassicaceae. Genetics Research 90: 47–60.
11 Mihr, C., Baumgärtner, M., Dieterich, J.H. et al. (2001). Proteomic approach for investigation of cytoplasmic male sterility (CMS) in Brassica. Journal of Plant Physiology 158: 787–794.
12 Pearson, O.H. (1981). Nature and mechanism of cytoplasmic male sterility in plants: a review. Hort Science 16: 482–487.
13 Pelletier, G. and Budar, F. (2007). The molecular biology of cytoplasmically inherited male sterility and prospects for its engineering. Current Opinion in Biotechnology 18: 121–125.
14 Schnable, P.S. and Wise, R.P. (1998). The molecular basis of cytoplasmic male sterility and fertility restoration. Trends in Plant Science 3: 175–180.
15 Stephens, J.C. and Holland, P.F. (1954). Cytoplasmic male sterility for hybrid sorghum seed production. Agronomy Journal 46: 20–23.
16 Stern, K.R. (1997). Introductory Plant Biology, 7e. Wm. C Brown Publishers.
17 Zhang, X., Wang, X., Jiang, P., and Zhu, W. (2010). Inheritance of fertility restoration for cytoplasmic male sterility in a new Gossypium barbadense restorer. Agricultural Sciences in China 9 (4): 472–480.
Outcomes assessment
Part A
Please answer the following questions true or false:
1 Biennial plants complete their lifecycle in two growing seasons.
2 A staminate flower is a complete flower.
3 Self‐pollination promotes heterozygosity of the sporophyte.
4 The union of egg and sperm is called fertilization.
5 A branched raceme is called a panicle.
6 The carpel is also called the androecium.
Part B
Please answer the following questions:
1 Plants reproduce by one of two modes, …………………….. or …………………
2 Distinguish between monoecy and dioecy.
3 …………………… is the transfer of pollen grain from the anther to the stigma of a flower.
4 What is self‐incompatibility?
5 Distinguish between heteromorphic self‐incompatibility and homomorphic self‐incompatibility.
6 What is apomixis?
7 Distinguish between apospory and displospory as mechanisms of apomixis
Part C
Please write a brief essay on the following topics:
1 Discuss the genetic and breeding implications of self‐pollination.
2 Discuss the genetic and breeding implications of cross‐pollination.
3 Fertilization does not always follow pollination. Explain.
4 Discuss the constraints of sexual biology in plant breeding.
5 Discuss how cytoplasmic male sterility (CMS) is used in a breeding program.
6 Discuss how genetic male sterility is used in a breeding program.
Purpose and expected outcomes
One of the principal techniques of plant breeding is artificial mating (crossing) of selected parents to produce new individuals that combine the desirable characteristics of the parents. This technology is restricted to sexually reproducing species that are compatible. However, in the quest for new desirable genes, plant breeders sometimes attempt to mate individuals that are biologically distantly related. In such interspecific crosses pre‐ and post‐fertilization barriers may occur. It is important for the breeder to understand the problems associated with making a cross, and how barriers to crossing, where they exist, can be overcome. After studying this chapter, the student should be able to:
1 Define sexual hybridization and discuss its genetic consequences.
2 Define a wide cross and discuss its objectives and consequences.
3 Discuss the challenges to wide crosses and techniques for overcoming them.
6.1 Concept of gene transfer and hybridization
Crop improvement typically involves the transfer of genes from one source or genetic background to another, or combining genes from different sources that complement each other, with the hope that the new cultivar will combine the best of both parents, while being distinct from both. When a plant breeder has decided on the combination of traits that he wishes to be incorporated in the new cultivar to be developed, the next crucial step is to find one or more sources of the appropriate gene(s) for such characters. In flowering species, the conventional method of gene transfer or gene combination is by crossing or sexual hybridization. This procedure causes genes from the two parents to be assembled into a new genetic matrix. It follows that if parents are not genetically compatible, gene transfer by sexual means cannot occur at all, or at best, may be fraught with complications. The product of hybridization is called a hybrid.
Sexual hybridization can occur naturally through agents of pollination. Even though self‐pollinating species may be casually viewed as “self‐hybridizing,” the term hybridization is reserved for crossing between unidentical parents (the degree of divergence is variable). Artificial sexual hybridization is the most common conventional method of generating a segregating population for selection in breeding flowering species. In some breeding programs, the hybrid (F1) is the final product of plant breeding (see hybrid breeding in Chapter 19). However, in most situations, the F1 is selfed (to give an F2) to generate recombinants (as a result of recombination of the parental genomes) or a segregating population, in which selection is practiced. In clonally propagated crops the F1 usually segregates sufficiently, and its clonally produced descendants will be submitted to selection without further crossing or selfing.
The tools of modern biotechnology now enable the