Tropical pasture legumes in southern Africa : A review

Cracking clay soils or vertisols occur in large areas of the subhumid regions of north-eastern Australia and frequently contain appreciable levels of salt in their subsoils. The comparative salt tolerance of some tropical pasture legumes was studied in pots with NaCl added to a clay soil to achieve electrical conductivities (saturated extract, ECe) over the range 2.0- 20.0 dS m-1. Tolerance, based on EC, at 50% of maximum growth (in parentheses) was in the order: Macroptilium atropurpureum cv. Siratro (10.6)> Macroptilium lathyroides cv. Murray (9.9) > Vigna trilobata (9.7) > Indigofera spicata (9.5) > Desmanthus subulatus (9.3) > Arachis pintoi (7.9) > Clitoria ternatea (6.4) > Stylosanthes scabra (5.6) > Indigofera schimperi (5.4) > Psoralea tenax (5.3) > Rhynchosia minima (5.1). The grass Panicum coloratum cv. Bambatsi was markedly more tolerant than any of the legumes studied, with 50% yield at an EC, of 16.4 dS m-1. Patterns of Na+ and Cl- uptake with increasing level of salt differed between species, but were not related to the degree oftolerance observed. The results are discussed in terms of the reported salinity tolerance of legumes generally and their implications to the search for persistent legumes for clay soils.

Download Full-text

Some factors affecting the field establishment of sub‐tropical pasture legumes in Rhodesia.

Proceedings of the Annual Congresses of the Grassland Society of Southern Africa ◽

10.1080/00725560.1976.9648786 ◽

1976 ◽

Vol 11 (1) ◽

pp. 97-102 ◽

Cited By ~ 1

Author(s):

P. J. Grant

Keyword(s):

Tropical Pasture ◽

Factors Affecting ◽

Pasture Legumes

Download Full-text

Polysaccharides of tropical pasture herbage. III. The distribution of the major polysaccharide components of Townsville lucerne (Stylosanthes humilis) during growth

Australian Journal of Chemistry ◽

10.1071/ch9711041 ◽

1971 ◽

Vol 24 (5) ◽

pp. 1041 ◽

Cited By ~ 1

Author(s):

CP Way ◽

GN Richards

Keyword(s):

Gas Chromatography ◽

Medicago Sativa ◽

Monosaccharide Composition ◽

Tropical Pasture ◽

Stages Of Growth ◽

Pasture Legumes ◽

Pectic Substances ◽

Stylosanthes Humilis ◽

Stem Leaf ◽

Pasture Legume

Stylosanthes humilis, the predominant pasture legume in North Queensland, has been collected at three different stages of growth, viz. flowering, seeded, and senescence. The plants have been divided into stem, leaf, root, seed, and pod and each fraction has been analysed for the following types of polysaccharide components: water- solubles, pectic substances, hemicelluloses, and cellulose. The absolute monosaccharide composition of each of these fractions has been determined by hydrolysis and gas chromatography. Most of the polysaccharide components are similar in nature to those previously found in temperate pasture legumes (e.g. Medicago sativa), but the seeds are unusual among legumes in containing no galactomannan and there is evidence of the presence of a glucomannan in all parts of the plant.

Download Full-text

Seasonal changes in growth and nodulation of perennial tropical pasture legumes in the field. II. Effects of controlled defoliation levels on nodulation of Desmodium uncinatum and Phaseolus atropurpureus

Australian Journal of Agricultural Research ◽

10.1071/ar9700207 ◽

1970 ◽

Vol 21 (2) ◽

pp. 207 ◽

Cited By ~ 9

Author(s):

PC Whiteman

Keyword(s):

Field Experiment ◽

Seasonal Changes ◽

Plant Age ◽

The Other ◽

Tropical Pasture ◽

Nodule Number ◽

Pasture Legumes ◽

Tropical Legumes ◽

Young Leaves ◽

Nodule Population

In a field experiment comparing the effects of varying levels of defoliation on the nodulation of two tropical legumes, D. intortum cv. Greenleaf and P. atropurpureus cv. Siratro, five treatments were imposed: (1) control, (2) cutting at 3 in., (3) removal of all leaves and petioles, (4) removal of half the leaves, taking the young leaves, (5) removal of half the leaves, taking the old leaves. The defoliation treatments were imposed twice, at plant age 73 and 103 days, and sampled twice, at 18 and 26 days, after each defoliation. The effects of defoliation were not evident for at least 18 days, but subsequently the nodule weight per plant was reduced by defoliation, the reduction being related to the severity of the initial defoliation. Cutting reduced both the nodule number and weight per nodule in both species. In P. atropurpureus removing all leaves had a similar effect to cutting. In the other defoliation treatments in both species, the weight per nodule declined even though the nodule number increased, and thus the nodule weight per plant increased or remained constant. This provided evidence that changes in nodule weight induced by defoliation were related to a loss of part of the original nodule population and initiation of new nodules.

Download Full-text