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Morphology of white clover (Trifolium repens L.) plants in pastures under intensive sheep grazing

Published online by Cambridge University Press:  27 March 2009

J. L. Brock
Affiliation:
Grasslands Division, DSIR, Palmerston North, New Zealand
M. J. M. Hay
Affiliation:
Grasslands Division, DSIR, Palmerston North, New Zealand
V. J. Thomas
Affiliation:
Applied Mathematics Division, DSIR, Palmerston North, New Zealand
J. R. Sedcole
Affiliation:
Applied Mathematics Division, DSIR, Palmerston North, New Zealand

Summary

There has been little study on the growth and morphology of individual plants constituting the population of white clover in mixed swards under grazing. Such information is required if the mechanisms governing plant productivity and persistence are to be understood.

Intact white clover plants were sampled from intensively sheep-grazed pastures under set stocking, rotational grazing, and a combination of both systems, by taking turves (250 × 250 mm), and washing out the plants, every month for a year. Characters measured for every stolon of each plant were: presence of a growing point; numbers of leaves, roots and axillary buds; stolon length. Total plant leaf and stolon dry weight were also recorded. Plants were classified according to degree of branching, and the contribution of each branching order to the population determined.

There were strong seasonal variations in plant size (leaf and stolon dry weight, stolon length, and numbers of stolons and leaves per plant) which showed a significant decrease in spring with recovery over the following summer. This was paralleled by a rapid increase in the proportion of less branched plants (1st and 2nd branching order) in the population from 60 to 80% in spring, as higher-order plants broke up into smaller- and lower-ordered plants at this time. Numbers of roots per plant increased over winter to peak in early spring then declined in the following summer-autumn. While system of grazing management had no significant effect on branching structure of plants, it had a large effect on plant dry weight; rotationally grazed plants were 2·5 times larger than set stocked plants (0·182 cf. 0·073 g respectively).

Other general features of plant morphology were that each successive order of branch stolons was shorter and length before branching was less than that of their preceding parent stolon. The highest branching order observed was 6th order. There was no relationship between branching and numbers of roots; in branched plants only 55% of stolons were rooted regardless of plant order, but rooted stolons accounted for 85% of total stolon length and carried 62, 48 and 90% of the leaves, growing points and axillary buds per plant, respectively.

Comparison with other studies suggests that the processes outlined in this report may be common to white clover growth under grazing over a wide range of favourable environments.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1988

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References

Brereton, A. J., Carton, O. T. & Conway, A. (1985). The effect of grass tiller density on the performance of white clover. Proceedings of the 15th International Grassland Congress, Kyoto, pp. 756757.Google Scholar
Briseño de, la Hoz U. M. & Wilman, D. (1981). Effects of cattle grazing, sheep grazing, cutting and sward height on a grass-white clover sward. Journal of Agricultural Science, Cambridge 97, 699706.CrossRefGoogle Scholar
Brougham, R. W. (1958). Leaf development in swards of white clover (Trifolium repens L.). New Zealand Journal of Agricultural Research 1, 707718.CrossRefGoogle Scholar
Brougham, R. W. (1962). The leaf growth of Trifolium repens as influenced by seasonal changes in the light environment. Journal of Ecology 50, 449459.CrossRefGoogle Scholar
Carlson, G. E. (1966 a). Growth of clover leaves – developmental morphology and parameters at ten stages. Crop Science 6, 293294.CrossRefGoogle Scholar
Carlson, G. E. (1966 b). Growth of white clover leaves, after leaf removal. Proceedings of the 10th International Grassland Congress, pp. 134136.Google Scholar
Chapman, D. F. (1983). Growth and demography of Trifolium repens stolons in grazed hill pastures. Journal of Applied Ecology 20, 597608.CrossRefGoogle Scholar
Chapman, D. F. & Clark, D. A. (1984). Pasture responses to grazing management in hill country. Proceedings of the New Zealand Grassland Association 45, 168176.CrossRefGoogle Scholar
Curll, M. L. & Wilkins, R. J. (1982). Frequency and severity of defoliation of grass and clover by sheep at different stocking rates. Grass and Forage Science 37, 291297.CrossRefGoogle Scholar
Curll, M. L. & Wilkins, R. J. (1985). The effect of cutting for conservation on a grazed perennial ryegrasswhite clover pasture. Grass and Forage Science 40, 1930.CrossRefGoogle Scholar
Davies, A. & Evans, M. E. (1982). The pattern of growth in swards of two contrasting varieties of white clover in winter and spring. Grass and Forage Science 37, 199207.CrossRefGoogle Scholar
Erith, A. G. (1924). White Clover (Trifolium repens L.). A Monograph. London: Duckworth.Google Scholar
Frame, J. & Newbould, P. (1986). Agronomy of white clover. Advances in Agronomy 40, 188.CrossRefGoogle Scholar
Harper, J. L. (1977). Population Biology of Plants. London: Academic Press.Google Scholar
Harris, W. & Brougham, R. W. (1968). Some factors affecting change in botanical composition in a ryegrass–white clover pasture under continuous grazing. New Zealand Journal of Agricultural Research 11, 1538.CrossRefGoogle Scholar
Harris, W. & Thomas, V. J. (1973). Competition among pasture plants. 3. Effects of frequency and height of cutting on competition between white clover and two ryegrass cultivars. New Zealand Journal of Agricultural Research 16, 4958.CrossRefGoogle Scholar
Hay, M. J. M. (1983). Seasonal variation in the distribution of white clover Trifolium repens L. stolons among 3 horizontal strata in 2 grazed swards. New Zealand Journal of Agricultural Research 26, 2934.CrossRefGoogle Scholar
Hay, M. J. M. (1985). Seasonal variation in the vertical distribution of white clover (Trifolium repens L.) stolons in two contrasting pastures. Proceedings of the New Zealand Grassland Association 46, 195198.CrossRefGoogle Scholar
Hay, M. J. M., Brock, J. L. & Fletcher, R. H. (1983). Effect of sheep grazing management on distribution of white clover stolons among 3 horizontal strata in ryegrass/white clover swards. New Zealand Journal of Experimental Agriculture 11, 215218.CrossRefGoogle Scholar
Hay, M. J. M., Chapman, D. F., Hay, R. J. M., Pennell, C. G. L., Woods, P. W. & Fletcher, R. H. (1987). Seasonal variation in the vertical distribution of white clover stolons in grazed swards. New Zealand Journal of Agricultural Research 30, 18.CrossRefGoogle Scholar
Haycock, R. (1984). Dry-matter distribution and seasonal yield changes in five contrasting genotypes of white clover. Journal of Agricultural Science, Cambridge 102, 333340.CrossRefGoogle Scholar
Hoglund, J. H. (1985). Grazing intensity and soil nitrogen accumulation. Proceedings of the New Zealand Grassland Association 46, 6569.CrossRefGoogle Scholar
Hoglund, J. H. & Brock, J. L. (1978). Regulation of nitrogen fixation in a grazed pasture. New Zealand Journal of Agricultural Research 21, 7382.CrossRefGoogle Scholar
Hollington, P. A. & Wilman, D. (1985). Effects of white clover and fertilizer nitrogen on clover and grass leaf dimensions, percentage cover and number of leaves and tillers. Journal of Agricultural Science, Cambridge 104, 595607.CrossRefGoogle Scholar
Hollowell, E. A. (1966). White clover Trifolium repens L., annual or perennial? Proceedings of the 10th International Grasslands Congress, Helsinki, pp. 184187.Google Scholar
Kershaw, K. A. (1959). An investigation of the structure of a grassland community. II. The pattern of Dactylis glomerata, Lolium perenne and Trifolium repens. Journal of Ecology 47, 3143.CrossRefGoogle Scholar
Korte, C. J. & Parsons, A. J. (1984). Persistence of a largeleaved white clover variety under sheep grazing. Proceedings of the New Zealand Grassland Association 45, 118123.CrossRefGoogle Scholar
Pascoe, W. B. (1973). Effects of grazing on the growth and development of white clover (Trifolium repens L.). M.Ag.Sc. thesis, Massey University, New Zealand.Google Scholar
Stevenson, C. A. & Laidlaw, A. S. (1985). The effect of moisture stress on stolon and adventitious root development in white clover (Trifolium repens L.) Plant and Soil 85, 249257.CrossRefGoogle Scholar
Ueno, M. & Yoshihara, K. (1968). Studies on the root of herbage legumes. 5. Effect of some environmental factors on the penetration of the adventitious roots of white clover to the soil. Journal of the Japanese Society of Grassland Science 14, 100103.Google Scholar
Wilman, D. & Asiegbu, J. E. (1982 a). The effects of clover variety, cutting interval and nitrogen application on herbage yields, proportions and heights in perennial ryegrass-white clover swards. Grass and Forage Science 37, 113.CrossRefGoogle Scholar
Wilman, D. & Asiegbu, J. E. (1982 b). The effects of variety, cutting interval and nitrogen application on the morphology and development of stolons and leaves of white clover. Grass and Forage Science 37, 1527.CrossRefGoogle Scholar
Yeates, G. W. (1975). Nematode genera from some New Zealand pastures. New Zealand Soil Bureau Scientific Report 21, pp. 122.Google Scholar