Tagasaste

Tagasaste
Scientific classification
Kingdom:	Plantae
(unranked):	Angiosperms
(unranked):	Eudicots
(unranked):	Rosids
Order:	Fabales
Family:	Fabaceae
Subfamily:	Faboideae
Tribe:	Genisteae
Genus:	Chamaecytisus
Species:	C. palmensis
Binomial name
Chamaecytisus palmensis

Tagasaste (Chamaecytisus palmensis), or Tree Lucerne, is a small spreading evergreen tree that grows 3-4m high. It is a member of the Fabaceae (pea) family^[1] and is indigenous to the dry volcanic slopes of the Canary Islands^[2], but it is now grown in Australia, New Zealand and many other parts of the world as fodder crop.

Biology

Tagasaste is an evergreen shrub that has rough yellow-grey bark and velvety hairy young growth. Its leaves are composed of 3 greyish green equal sized leaflets, which are slightly paler on the underside. Its scented, creamy white flowers form in small clusters in the leaf axils. Its flat pea-like pods are green, ripening to black. The seeds are tiny (45,000/kg)^[2], shiny and black. Tagasaste is considered to be a promiscuous legume. It will nodulate with a wide range of rhizobia.

Tagasaste is suited to sandy, well drained soils of pH range 5-7. On deep, freely drained soils its roots can extend down to at least 10 metres. Any physical or chemical barrier in the soil that restricts root growth will reduce the productivity and survival of tagasaste. It is very susceptible to root rot fungus on poorly drained soils^[1]. It will tolerate winter temperatures as low as -9°C^[2]. Tagasaste leaves will be burnt by frost and seedlings can be killed at temperatures below 0°C. Growth of mature trees will slow at winter temperatures below 20°C. Tagasaste can tolerate temperatures up to 50°C, but above 36°C leaves close up from stress.

Tagasaste has two types of roots. There are a few large 'sinker' roots that can extend down to at least 10 metres. These are used to extract moisture from that depth during the long dry summers. There are also many 'feeder' roots that are mostly confined to the top 1¹⁄₂ metres. These can extend out at least 15 metres from the trunk. They extract mineral nutrients from the soil, and also water in winter. In summer the soil water can be taken up at depth by the sinker roots, drawn into the shallow feed roots and then pumped into the soil. This 'hydrolic lift' allows the tagasaste to keep extracting nutrients from the shallow soil which would otherwise be too dry. This hydrolic lift is also seen in the native banksia shrubs that grow naturally on these soils and have a similar root design.

When tagasaste is planted in rows that run north - south it has been found that both the shoots and the roots grow twice as fast on the west side of the plant as on the east side of the plant.

History of introduction into Australia

The potential of tagasaste as a Spanish fodder was identified by Dr Perez, a medical practitioner, based on La Palma island in the Canary Islands in the 1870s, and Spanish cattle farmers. He wrote to the Spanish authorities promoting tagasaste as a fodder shrub but could not get them interested. He then sent seed to Kew Gardens in England. Kew Gardens tested tagasaste and then sent seed to all its colonies around the world. In Australia, tagasaste's potential was promoted by a number of individuals over the next century (e.g. Dr Schomburge in South Australia and Dr Laurie Snook in Western Australia) but was not adopted on a large scale until the 1980s in Western Australia.

The first 2 ha of tagasaste in the West Midlands was planted by John Cook on his farm near Dandaragan in 1982. The success of this small paddock excited the interest of other local farmers and researchers. Before this the farming systems in the region were totally based on annual pastures and crops. The region has strongly winter dominant rainfall, with up to 8 months without rain over some summers. Until the development of tagasaste it was believed it was not possible to grow perennial pastures in this region.

In 1984 the 'Martindale Research Project" was started by the University of Western Australia with a large grant from Sir James McCusker. This project encouraged the participation of local farmers and the Western Australia Department of Agriculture in the research and development. Farmers such as John Cook and Bob Wilson at Lancelin developed seeding and mechanical cutting equipment that allowed tagasaste to be sown and managed cheaply by farmers on a broadacre scale. The Martindale Research Project resolved many issues relating to the agronomy, animal production and economics that resulted in a reliable package that farmers could adopt with confidence. The Western Australia Department of Agriculture also conducted trials on their Badgingarra Research Station and at Bob Wilson's farm at Lancelin. Local farmers and researchers formed the West Midlands Fodder Shrub Improvement Group. This later evolved into the Evergreen Group (http://www.evergreen.asn.au/index.htm), which expanded its interests to include a range of other shrubs, grasses and perennial legumes.

There are now about 100,000 ha planted to tagasaste in Western Australia. In WA it is mostly grown on deep, infertile sands in regions nearer the coast with 350 to 600 mm rainfall. Most of the tagasaste in Western Australia is in the West Midlands sand plain to the north of Perth.

Food fodder

As a fodder crop Tagasaste delivers between 23 and 27% crude protein (14 - 30% in Western Australia) and 18-24% crude indigestible fibre. With proper application of fertiliser it can maintain these levels even when grown on poor soils^[3].

Phosphorus is particularly important both for the growth of tagasaste and for the growth of the animals grazing on it. Higher levels of phosphorus are required for the maximum growth of the animals than for maximum plant growth. Fertiliser will also reduce the level of phenolic compounds (similar to tannins) that increase in autumn when the plants are moisture stressed. These phenolic compounds make the tagasaste less palatable and reduce the animals' feed intake. The phenolics suppress the utilisation of protein in the rumen, and as a result feed intake. Despite the crude protein always being above 14%, supplementing with a high protein feed like lupin seed stimulates animal feed intake when phenolics are high in tagasaste.

Flowering also changes the palatability of tagasaste. In Western Australia tagasaste will commence flowering in winter (~ June). The seeds are mature and shed in early summer (first warm day in December). In the summer following flowering the palatability changes in different parts of the plant. In tagasaste that has not flowered the leaves will be grazed and bark on the stems ignored. After flowering the leaf becomes less palatable and the bark more palatable. This results in stock stripping bark off the trunk. Also the growth rate of the plant slows and leaves will be shed. The grazing management is all designed to prevent flowering and keep tagasaste in the vegetative state. Trials have shown that if tagasaste is heavily grazed and / or mechanically cut in the any one of the first 6 months of the year it will not flower in the second half of the year. Occasionally when mechanically cutting one limb on a plant can be missed. This limb will go on to flower, and show all the other problems, while the rest of the plant is maintained in a vegetative state.

Initially tagasaste was developed so that it was used to replace hand feeding sheep in autumn, when feed supplies were normally very low. This involved locking the tagasaste up for 11 months and then grazing it with 100 sheep per hectare for 1 month. As the tagasaste grows to about 3 metres height in 11 months, it must be mechanically cut while the sheep are in the paddock. Sheep can not be set stocked on tagasaste as this can lead to plant deaths.

A break through came with the discovery that cattle can be set stocked on tagasaste. Cattle tongues are too large to pick off the new shoot buds, and some leaves always remain on the plant. Sheep can remove every leaf from tagasaste but this does not cause plant deaths. The removal of new buds by sheep, that appear about 6 weeks after grazing, can lead to plant deaths. Today the majority of tagasaste is used for cattle grazing with plantations able to be grazed at any time of year. Though it can grow up to 4 to 5 metres in height though when managed for grazing it is kept to less than 2 metres in height.

On the poor white sands in Western Australia tagasaste has increased the animal carrying capacity from 1 to 2 Dry Sheep Equivalents with annual pastures to 8 - 10 Dry Sheep Equivalents (~ 1 cow) per hectare with mature tagasaste. The yield of edible dry matter (leaves and fine stems) in the West Midlands is mostly in the range of 3 - 5 tonnes per hectare. It also prevents the wind erosion and excessive ground water recharge that were major environmental problems before. Recently it has been found that tagasaste can sequester carbon at the rate of about 6 tonnes CO₂ equivalent per hectare per year. About half the CO₂ being stored is as organic carbon in the soil and half is in the wood of the branches, trunk and roots.

References

Trees portal

1. ^ ^{a b} R.C. Gutteridge (1998). "Other Species of Multipurpose Forage Tree Legumes". Forage Tree Legumes in Tropical Agriculture. Department of Agriculture, University of Queensland. http://www.fao.org/ag/AGP/AGPC/doc/Publicat/Gutt-shel/x5556e0c.htm#chamaecytisus%20palmensis,%20tagasaste%20or%20tree%20lucerne. Retrieved 2006-09-26. 
2. ^ ^{a b c} "Tagasaste, Chamaecytisus palmensis". The Nitrogen Fixing Tree Association. http://fadr.msu.ru/rodale/agsieve/txt/vol2/9/art7.html. Retrieved 2006-09-26. 
3. ^ "Fodder shrubs for goats - Tagasaste". Boer Briefs (13). http://boergoat.une.edu.au/technical%20articles/issue13_tagasaste.pdf.