Showing posts with label Agricultural. Show all posts
Showing posts with label Agricultural. Show all posts

Unique Acacia Tree Could Nourish Soils and Life in Africa

[ScienceNology] - Scientists said today (24 August 2009) at the 2nd World Congress of Agroforestry that a type of acacia tree with an unusual growth habit-unlike virtually all other trees-holds particular promise for farmers in Africa as a free source of nitrogen for their soils that could last generations.

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With its nitrogen-fixing qualities, the tall, long-lived acacia tree, Faidherbia albida (Mgunga in Swahili) could limit the use of fertilizers; provide fodder for livestock, wood for construction and fuel wood, and medicine through its bark, as well as windbreaks and erosion control to farmers across sub-Saharan Africa. The tree illustrates the benefits of growing trees on farms, said the scientists at today's meeting, and is adapted to an incredibly wide array of climates and soils from the deserts to the humid tropics.

"The future of trees is on farms," said Dennis Garrity, Director General of the World Agroforestry Centre, or ICRAF, one of 15 centers supported by the Consultative Group on International Agricultural Research (CGIAR). The Center is hosting the Congress, which has convened about 800 global experts to discuss the importance of growing trees on farms for humanity's survival.

"Growing the right tree in the right place on farms in sub-Saharan Africa-and worldwide- has the potential to slow climate change, feed more people, and protect the environment. This tree, as a source of free, organic nitrogen, is an example of that. There are many other examples of solutions to African farming that exist here already."

African farmland is severely degraded and African farmers, on average, apply only 10 percent of soil nutrients used in the rest of the world. Low-cost options are critical to reversing the continent's declining farm productivity, the scientists said, as sharply increasing fertilizer prices further limit the choices African farmers have to improve farm yields while protecting forests from further clearing.

The Faidherbia acacia tree has the quality of "reverse leaf phenology," which drives the tree to go dormant and shed its nitrogen-rich leaves during the early rainy season-when seeds are being planted and need the nitrogen-and then to re-grow its leaves when the dry season begins and crops are dormant. This makes it highly compatible with food crops because it does not compete with them for light-only the bare branches of the tree's canopy spread overhead while crops grow to maturity. Their leaves and pods provide a crucial source of fodder in the dry season for livestock when other plants have dried up.

Research on the tree began over 60 years ago when scientists observed that farmers throughout the Sahelian region of Africa were retaining the trees in their sorghum and millet fields. It is a frequent component of farming systems of Senegal, Mali, Burkina Faso, Niger, Chad, Sudan, and Ethiopia, and in parts of northern Ghana, northern Nigeria, and northern Cameroon. The tree is growing on over 4.8 million hectares of land in Niger. Half a million farmers in Malawi and in the southern highlands of Tanzania grow the tree on their maize fields.

In Malawi, maize yields were increased up to 280 percent in the zone under the tree canopy compared with the zone outside the tree canopy. In Zambia, recent unpublished observations showed that unfertilized maize yields in the vicinity of the Faidherbia trees averaged 4.1 tonnes per hectare, compared to 1.3 tonnes nearby but beyond the tree canopy. Yield increases have also been documented in unfertilized millets grown under the tree in West Africa, for sorghum in Ethiopia, other parts of Africa, and in India, in addition to groundnuts and cotton. Often, millet and sorghum exhibit no further response to artificial fertilizers beyond that provided by the tree's leaf fall.

Currently, the Departments of Agriculture in both Malawi and Zambia are seeking to double maize production with the use of the tree. They recommend that farmers establish 100 Faidherbia trees on each hectare of maize that is planted.

Scientists at today's conference noted some 700 published references to the tree's history, ecology, and growing habits. "Knowledge of this tree is farmer-driven," said Garrity. "We are now combining the scientific knowledge base with the farmer knowledge base. There is sufficient research on both sides to warrant dramatically scaling-up the planting of this tree on farms across Africa through extension programs. The risks to farmers are low; it requires very little labor, and delivers many benefits."

"Thus far we have failed to do enough to refine, adapt and extend the unique properties of these trees to the more than 50 million food crop farmers who desperately need home-grown solutions to their food production problems," he continued.



A Press Release from World Agroforestry Center , 24 August 2009

Plant Essential Oil Eyed as Mosquito, Ant Repellent

[ScienceNology] - Agricultural Research Service (ARS) scientists have teamed up with researchers from a company in American Samoa to investigate the chemical makeup of a mosquito- and ant-repellent essential oil from a native Samoan plant.

The ARS scientists and researchers at Agro Research, Inc., in Pago Pago, American Samoa, discovered that the oil from a local plant repelled mosquitoes and pest ants in preliminary studies, which were conducted under a material transfer agreement. The isolation and identification of the active component (or components) will be done as part of a recently established one-year cooperative research and development agreement.

The plant is one of the 540 native species of flowering plants in American Samoa, a U.S. island territory in the South Pacific.

ARS chemists Robert Vander Meer and Ulrich Bernier at the agency’s Center for Medical, Agricultural and Veterinary Entomology in Gainesville, Fla., are working with Agro Research, Inc.’s Pemerika Tauiliili to identify the active ingredients in the plant essential oil.

Two mosquito species—Aedes aegypti and Anopheles albimanus—were used to evaluate the essential oil’s repellency. A. aegypti transmits viruses that cause yellow fever, dengue and chikungunya. A. albimanus transmits malaria parasites and is not as susceptible to repellents as many other mosquito species.

The essential oil was also tested on the red imported fire ant, Solenopsis invicta. Significant repellency was observed with concentrations diluted more than 100-fold, and the active components are likely a small fraction of the total oil.

While American Samoa is malaria-free, mosquitoes pose significant problems for the Samoan population due to transmission of dengue virus.

Exploration for new active ingredients among botanical extracts has value because it can lead to the discovery of new synthetic analogs with unique and useful properties.

By: Sharon Durham



A News Release from the United States Department of Agriculture , 24 August 2009

Honey Bees with Colony Collapse Disorder Show their Genes

[ScienceNology] - The first hard evidence of what is happening physiologically inside bees during Colony Collapse Disorder (CCD) has been published in a new study by Agricultural Research Service (ARS) and University of Illinois scientists in the Proceedings of the National Academy of Sciences. The study also looked at differences in activity levels of critical genes in CCD and healthy bee colonies.

Using a tool called a genome-wide microarray, the scientists found a large amount of abnormal ribosomal RNA (rRNA) fragments in the guts of honey bees in CCD colonies. Ribosomes are the cellular factories in which proteins are made, guided by rRNA, and a large amount of abnormal rRNA fragments means the protein construction system is compromised. This indicates that honey bees in colonies diagnosed with CCD had reduced ability to synthesize new proteins.

The gut is the primary entry point for pathogens and pesticides in honey bees. Honey bees' stress response systems also can be measured in the bee's gut. The honey bee has two separate response systems: one to environmental stresses such as pesticides, and a different one reacting to pathogens such as viruses.

This was the first time RNA levels have been measured in honey bees as a way of tracking whether it is honey bees' pesticide response system or their pathogen immune response system that is reacting in CCD, according to ARS geneticist Jay Evans, who works in the Bee Research Laboratory at the ARS Henry A. Wallace Beltsville (Md.) Agricultural Research Center. Evans was part of a team that included entomologists May R. Berenbaum, Reed M. Johnson and Gene E. Robinson from the University of Illinois.

In CCD colonies, the genes involved in the pathogen/immune response systems showed no single clear pattern of activity, although there was commonly more activation of these genes and the bees had a higher overall level of viruses and other pathogens than non-CCD colonies.

Almost all CCD colonies had a higher level of picorna-like viruses, which attack the ribosome. Picorna-like viruses that attack honey bees include deformed wing virus and Israeli acute paralysis virus. The varroa mite, a major honey bee parasite, is known to transmit picorna-like viruses.

Bees in CCD colonies did not show significantly active pesticide response genes.

The loss of ribosomal function would explain many of the phenomena associated with CCD, according to Berenbaum. If the bees' ribosomes are compromised, then they can't overcome exposure to pesticides, fungal infections or bacteria or inadequate nutrition because the ribosome is central to the survival of any organism.

The study did not establish a direct cause-and-effect link between the abnormal rRNA and CCD. But colony surveillance by assays of rRNA and other markers expressed by bees could provide the earliest indication of CCD found so far, perhaps in time for beekeepers to take actions that might reduce losses, Evans suggested.

By: Kim Kaplan


A News Release from the United States Department of Agriculture , 24 August 2009