An analysis of the costs and benefits of the cyanogenic system in Trifolium repens L.

Summary

The effect of the cyanogenic glucosides linamarin and lotaustralin and their hydrolyzing enzyme linamarase was studied in a B₂ generation segregating for the genes Ac and Li. Plants containing the glucosides are protected against grazing by snails both in the seedling stage and as adult plants. In seedlings, however, there is a direct effect on survival, whereas in adult plants the leaf area of plants containing linamarin/lotaustralin is less reduced under intense grazing. Linamarase has no effect on grazing by snails, possibly as a result of the presence of β-glucosidase activity in the gut of these animals. The genes Ac and Li, or genes tightly linked to them, have other effects as well: plants possessing one dominant Ac allele produce fewer flowers than homozygous ac plants. I compared this difference in flower production to the metabolic cost of producing the cyanogenic glucosides. The energy content of the difference in flower head production far exceeded the metabolic cost of cyanoglucoside production in Acac plants. It is possible that the cost of maintaining a certain level of cyanoglucosides is much more important for the plant than the initial cost of biosynthesis. The importance of the effects of Ac and Li in the maintenance of cyanogenic polymorphism in white clover is discussed.

References

1. Berenbaum MR, Zangerl AR, Nitao IK (1986) Constraints on chemical coevolution: Wild parsnibs and the parsnib webworm. Evolution 40:1215–1228

2. Boersma P, Kakes P, Schram AW (1983) Linamarase and β-glucosidase activity in natural populations of Trifolium repens. Acta Bot Neerl 32:39–47

3. Burdon JJ (1980) Intraspecific diversity in a natural population of Trifolium repens. J Ecol 68:717–735

4. Butler GW, Butler BG (1960) Biosynthesis of linamarin and lotaustralin in white clover. Nature 1987:780–781

5. Chew FS, Rodman JE (1979) Plant resources for chemical defense. In: Rosenthal GA, Janzen DH (eds): Herbivores. Academic Press, New York, pp 271–307

6. Coley PD (1986) Costs and benefits of defense by tannins in a neotropical tree. Oecologia 70:238–241

7. Daday H (1954 a) Gene frequencies in wild populations of Trifolium repens L. I. Distribution by latitude. Heredity 8:61–78

8. Daday H (1954 b) Gene frequencies in wild populations of Trifolium repens L. II. Distribution by altitude. Heredity 8:377–384

9. Daday H (1965) Gene frequencies in wild populations of Trifolium repens L. IV. Mechanisms of natural selection. Heredity 20:355–365

10. Dirzo R, Harper JL (1982 a) Experimental studies on slug-plant interactions III. Differences in the acceptability of individual plants of Trifolium repens to slugs and snails. J Ecol 70:101–117

11. Dirzo R, Harper JL (1982 b) Experimental studies on slug-plant interactions IV. The performance of cyanogenic and acyanogenic morphs of Trifolium repens in the field. J Ecol 70:119–138

12. Dommée B, Brakefield PM, Macnair MR (1980) Differential root growth of the cyanogenic phenotypes of Trifolium repens. Oecol Plant 1:367–370

13. Ennos RA (1981 a) Manifold effects of the cyanogenic loci in white clover. Heredity 45:127–132

14. Ennos RA (1981 b) Detection of selection in populations of white clover. Biol J Linn Soc 15:75–82

15. Ennos RA (1982) Association of the cyanogenic loci in white clover. Genet Res 40:65–72

16. Foulds W, Grime JP (1972) The response of cyanogenic and acyanogenic phenotypes of Trifolium repens to soil moisture supply. Heredity 28:181–187

17. Hanover JW (1966) Genetics of terpenes I. Gene control of monoterpene levels in Pinus monticola Dougl. Heredity 21:73–84

18. Horrill JC, Richards AJ (1986) Differential grazing by the Mollusc Arion hortensis Fér. on cyanogenic and acyanogenic seedlings of the white clover, Trifolium repens L. Heredity 56:277–281

19. Hughes MA, Conn EE (1976) Cyanoglucoside biosynthesis in white clover (Trifolium repens). Phytochemistry 15:697–701

20. Hughes MA, Stirling JD (1982) A study of dominance at the locus controlling cyanoglucoside production in Trifolium repens. Euphytica 3:477–483

21. Hughes MA, Stirling JD, Colinge DB (1984) The inheritance of cyanoglucoside content in T. repens. Biochem Genet 22:139–151

22. Kakes P (1987) On the polymorphism for cyanogenesis in natural populations of Trifolium repens L. in the Netherlands. I. Distribution of the genes Ac and Li. Acta Bot Neerl 36:59–69

23. Lieberei R, Selmar D, Biehl B (1985) Metabolization of cyanogenic glucosides in Hevea braziliensis. Plant Syst Evol 150:49–63

24. Maher EP, Hughes MA (1973) Studies on the nature of the Li locus in Trifolium repens. Biochem Genet 8:113–126

25. Phillipson J (1964) A miniature bomb calorimeter for small biological samples. Oikos 15:130–139

26. Simms EL, Rausher MD (1987) Costs and benefits of a plant resistant to herbivory. Am Nat 130:570–581

27. Till-Bottraud I, Kakes P, Dommée B (1988) Variable phenotypes and stable distribution of the cyanotypes of Trifolium repens in Southern France. Oecologia Plant (in press)

28. Van den Berg P, Matzinger DF (1970) Genetic diversity and heterosis in Nicotiana. III. Crosses among tobacco introductions and flue cured varieties. Crop Sci 10:437–440

29. Ware WM (1925) Experiments and observations on forms and strains of Trifolium repens. J Agric Sci 15:47–67