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Crop and Pasture Science Crop and Pasture Science Society
Plant sciences, sustainable farming systems and food quality
RESEARCH ARTICLE

Annual clovers (Trifolium spp.) have different reproductive strategies to achieve persistence in Mediterranean-type climates

Hayley C. Norman A B E , Philip S. Cocks A C and Nick W. Galwey A D
+ Author Affiliations
- Author Affiliations

A School of Plant Biology and Centre for Legumes in Mediterranean Agriculture, The University of Western Australia, Crawley, WA 6009, Australia.

B CSIRO Livestock Industries, Private Bag 5, Wembley, WA 6913, Australia.

C Present address: CRC for the Plant Based Management of Dryland Salinity, University of Western Australia, Nedlands, WA 6907, Australia.

D Present address: New House, George Green, Little Hallingbury, Bishop's Stortford, Hertfordshire, CM22 7PP, UK.

E Corresponding author. Email: Hayley.Norman@csiro.au

Australian Journal of Agricultural Research 56(1) 33-43 https://doi.org/10.1071/AR03236
Submitted: 12 November 2003  Accepted: 29 November 2004   Published: 31 January 2005

Abstract

The aim of this work was to determine whether different species of annual clover (Trifolium spp.), obtained from the same environment, have different reproductive strategies (combinations of reproductive traits) to achieve ecological success. A better understanding of the traits that improve persistence should allow agronomists to narrow the selection criteria for new clover cultivars for ley-farming systems in southern Australia. Seeds of 18 annual clover species were obtained from 3 Australian and 6 Mediterranean sites and were subsequently grown in a common garden in Western Australia. Reproductive traits, including time of flowering, weight per seed, fecundity, pollen to ovule ratio, and pattern of seed softening, were observed.

Accessions of different clover species from the same site of collection had different reproductive strategies. Across a range of collection sites, accessions of the same species demonstrated the same broad reproductive strategy; however, some traits, e.g. the timing of flowering, varied within species across collection sites. Principal component analysis suggested that there are 3 broad reproductive strategies demonstrated by these clover species. At one extreme were the relatively large-seeded clovers (T. subterraneum, T. clypeatum, and T. stellatum). The associated cost of these large seeds is reduced fecundity. The large-seeded clovers do not have high long-term hardseededness (the predominant form of seed dormancy in clovers). The relatively small-seeded clovers were all characterised by high fecundity. Many of the small-seeded clovers have high levels of long-term hardseededness, which allow the risk of failure to be spread across seasons (T. spumosum, T. hirtum, T. lappaceum, T. angustifolium, and T. tomentosum). Some of the small-seeded clovers (T. glomeratum, T. nigrescens, T. campestre, T. cernuum, and T. suffocatum) are generalists, producing as many seeds as possible in each season, with very little hardseededness.

There are several possible explanations for the apparent success of such different reproductive strategies among clover accessions of different species at the same site. A plant may achieve the same goal by trading one reproductive trait for another. For example, it may either produce many small seeds to spread the risk of failure or produce fewer large seeds with an inherent competitive advantage. Alternatively, temporal and spatial variation may favour clovers with a number of different reproductive strategies. It is likely that a mixture of species with different reproductive strategies will maximise production and persistence of legume-based pastures in ley-farming systems.

Additional keywords: fitness, evolution, ruderal, ley farming, pollen : ovule ratio, natural selection.


Acknowledgments

The authors thank Angelo Loi (Agriculture WA), Brad Nutt (Agriculture WA), Patrick Smith (CSIRO Sustainable Ecosystems), and staff from the School of Plant Biology and the University Research Station (University of WA). Fiona Maley and John Norman provided technical and field assistance. Thank you to Richard Snowball of the Trifolium Genetic Resource Centre, for access to his database and seed. We appreciate the input from the anonymous AJAR referees. The Grains Research and Development Corporation funded this work through a Junior Research fellowship to H. Norman.


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