Further analysis of such differential interactions has shown that there is a precise genetic relationship between the two partners. The pioneering study was done by Harold Flor, who analyzed the genetics of host resistance and pathogen virulence using flax rust, Melampsora lini, as a model. Flor showed that for each host gene conferring resistance, there is a complementary gene in the pathogen determining virulence. This finding has become widely known as the gene‐for‐gene theory of host–pathogen interactions. On the basis of Flor's theory, the possible interactions between a pair of alleles governing resistance in a plant and the corresponding pair determining virulence in the pathogen can be shown as a quadratic check (Figure 2.7). In this scheme, a resistant reaction occurs only where an allele for resistance in the host plant interacts with an allele for avirulence in the pathogen.
Table 2.3 Hypothetical interaction between four host cultivars and four pathogen races
Host | Pathogen | |||
Race 1 | Race 2 | Race 3 | Race 4 | |
Cultivar 1 | + | − | − | − |
Cultivar 2 | − | + | − | − |
Cultivar 3 | − | − | + | − |
Cultivar 4 | − | − | − | + |
+ = compatible disease reaction (host susceptible, pathogen virulent).
− = incompatible disease reaction (host resistant, pathogen avirulent).
Figure 2.7 The quadratic check, showing interactions between alleles of a host resistance gene and a pathogen gene for avirulence. Resistance (R) and avirulence (A) are usually dominant.
More recent analysis of mechanisms of pathogenicity in some necrotrophic fungi has shown that host susceptibility can in some cases be determined by the interaction of a pathogen toxin with a plant receptor causing sensitivity to this toxin. In such cases, susceptibility is the dominant trait, and the interaction has been described as an “inverse gene‐for‐gene” model (see Chapter 10, Figure 10.10).
The gene‐for‐gene theory has important practical implications. The sequential introduction of new host cultivars which differ in resistance genes has been accompanied by corresponding changes in pathogen populations, whereby new races have successively come to predominate. The implications of this will be discussed further in Chapter 12. The gene‐for‐gene theory is also an important starting point for molecular models of host–pathogen specificity. Where single genes determine the outcome of a particular interaction, identification of the gene products involved should clarify how host–pathogen recognition occurs. Progress toward this goal is described in Chapter 10.
Further Reading
Books
1 Nash, A., Dalziel, R., and Fitzgerald, J. (2015). Mims Pathogenesis of Infectious Disease. Washington, DC: Academic Press.
2 Smith, S.E. and Read, D.J. (2010). Mycorrhizal Symbiosis, 3e. Washington, DC: Academic Press.
Articles
1 Andrivon, D. (1993). Nomenclature for pathogenicity and virulence: the need for precision. Phytopathology 83: 889–890. (and subsequent correspondence. See Phytopathology 85: 518–519, 1995).
2 Cooke, R.C. and Whipps, J.M. (1980). The evolution of modes of nutrition in fungi parasitic on terrestrial plants. Biological Reviews 55: 341–362.
3 Crute, I.R. (1994). Gene‐for‐gene recognition in plant‐pathogen interactions. Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences 346: 345–349.
4 Delaye, L., García‐Guzmán, G., and Heil, M. (2013). Endophytes versus biotrophic and necrotrophic pathogens – are fungal lifestyles evolutionarily stable traits? Fungal Diversity 60 (1): 125–135. https://doi.org/10.1007/s13225‐013‐0240‐y.
5 Hartung, J.S., Beretta, J., Brinasky, R.H. et al. (1994). Citrus variegated chlorosis bacterium: axenic culture, pathogenicity, and serological relationships with other strains of Xylella fastidiosa. Phytopathology 84: 591–597.
6 Kabbage, M., Yarden, O., and Dickman, M.B. (2015). Pathogenic attributes of Sclerotinia sclerotiorum: switching from a biotrophic to necrotrophic lifestyle. Plant Science 233: 53–60. https://doi.org/10.1016/j.plantsci.2014.12.018.
7 Pariaud, B., Ravigné, V., Halkett, F. et al. (2009). Aggressiveness and its role in the adaptation of plant pathogens. Plant Pathology 58: 409–424.
8 Simpson, A.J.G., Reinach, F.C., Arruda, P. et al. (2000). The genome sequence of the plant pathogen Xylella fastidiosa. Nature 406 (6792): 151–157.
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