MORINGA LEAVES COULD TREAT AT LEAST 300 DISEASES.

Imagine a tree in your backyard that will meet all your nutritional needs, take care of you medicinally, and purify your water for you. This tree actually exists. For centuries, the natives of northern India and many parts of Africa have known of the many benefits of Moringa oleifera. Its uses are as unique as the names it is known by, such as clarifier tree, horseradish tree and drumstick tree (referring to the large drumstick shaped pods) and in East Africa it is called "mother's best friend”. Virtually every part of the tree can be used. Native only to the foothills of the Himalayas, it is now widely cultivated in Africa, Central and South America, Sri Lanka, India, Malaysia and the Philippines. This tree, though little known in the Western world, is nutritional dynamite. There are literally hundreds of uses for this tree.

According to researchers, Moringa leaves could treat at least 300 diseases. Let's name just a benefits that Moringa leaves bring:

1. gives a feeling of wellness and promotes energy, yet this is not a sugar based energy
2. increases natural body defense and stimulates metabolism
3. stimulates the cell structure of the body
4. rich in vitamin A, provides nourishment to the eyes and brain
5. balances level of cholesterol
6. balances level of sugar
7. rich in anti-oxidants, beautifies the skin and lowers the appearance of fine lines and wrinkles
8. improves functioning of kidney and liver
9. promotes healthy digestion
10. promotes body's immune system
11. promotes circulatory system and controls blood pressure
12. promotes anti-inflammatory features, heals arthritis pain
13. heals tumors and ulcers
14. balances hormone and gland system
15. detoxify body from poisons
16. helps relax and promotes good night sleep
17. purifies water
18. Takes care of low sperm count.
19. Increases fertility in women
20. Increase a woman's milk production
The list is endless.

Other Benefits.
• Rejuvenates the brain, lungs, bones, the entire body.
• Builds the immune system and helps to eliminate excessive hunger.
• Purifies and restores all the bodily organs, cleanses the bloodstream
• Flushes the body of acid and mucus congestion in the form of cysts,
tumors, yeast, fungi, bacteria, and vaginal discharge.
• Lubricates the colon to ease elimination and old impacted waste
from the large and small intestines

High/Low Blood Pressure, Diabetes, Fever, Headaches, Migraines, malnutrition,
inflammation, Arthritis, Tumors, Ulcers, Impotency, Menstrual Disorder, Parasites,
(Moringa is known to treat over 300 diseases – it is known as The Miracle Tree of Life)

Moringa products has reached several countries throughout the world, particularly in the following countries. NEWS FROM AROUND THE WORLD.

THE FACTS ABOUT HUNGER, POVERTY AND HOW AGRICULTURE CAN HELP.

How much do you know about agriculture in the developing world? Did you know, for example, that agriculture accounts for about 70 percent of the labor force in sub-Saharan Africa? Or that if we hope to feed 9 billion mouths on Earth we’ll need to boost agricultural output by 70 percent by 2050?

The number of hungry people in the world has reached the 1 billion mark, and global food prices that were beginning to fall last July—signaling some relief—are starting to creep up again. According to estimates, small farmers in South Asia and sub-Saharan Africa can double or almost triple their crop yields, respectively, in the next 20 years, translating into roughly 400 million people lifting themselves out of poverty.


Norman Borlaug, a Nobel Peace Prize winner for his work with what’s called “The Green Revolution” credited with saving one billion people from starvation, once said, “Without food, all other components of social justice are meaningless.” The time to act is now.


In advance of the keynote speech by Bill Gates  at the International Fund for Agricultural Development (IFAD), one of the three Rome-based UN agencies working to fight hunger and poverty, we put the call out for powerful facts about agricultural development to help us in our own work.


We reached out to our partners, organizations such as Borlaug Global Rust, Conservation International, and International Rice Research Institute (IRRI),  to send us some facts of their own. Below is a quick rundown of some of the tweets we highlighted this week. BY LUIS MONTERO.

SCIENTISTS ENGINEER SUGARCANE TO PRODUCE BIODIESEL, MORE SUGAR FOR ETHANOL

A multi-institutional team led by the University of Illinois have proven sugarcane can be genetically engineered to produce oil in its leaves and stems for biodiesel production. Surprisingly, the modified sugarcane plants also produced more sugar, which could be used for ethanol production.

The dual-purpose bioenergy crops are predicted to be more than five times more profitable per acre than soybeans and two times more profitable than corn. More importantly, sugarcane can be grown on marginal land in the Gulf Coast region that does not support good corn or soybean yields.


"Instead of fields of oil pumps, we envision fields of green plants sustainably producing biofuel in perpetuity on our nation's soil, particularly marginal soil that is not well suited to food production," said Stephen Long, Gutgsell Endowed Professor of Plant Biology and Crop Sciences. Long leads the research project Plants Engineered to Replace Oil in Sugarcane and Sweet Sorghum (PETROSS) that has pioneered this work at the Carl R. Woese Institute for Genomic Biology at Illinois.


"While fuel prices may be considered low today, we can remember paying more than $4 per gallon not long ago," Long said. "As it can take 10-15 years for this technology to reach farmers' fields, we need to develop these solutions to ensure our fuel security today and as long as we need liquid fuels into the future."


Published in Biocatalysis and Agricultural Biotechnology, this paper analyzes the project's first genetically modified sugarcane varieties. Using a juicer, the researchers extracted about 90% of the sugar and 60% of the oil from the plant; the juice was fermented to produce ethanol and later treated with organic solvents to recover the oil. The team has patented the method used to separate the oil and sugar.


They recovered 0.5 and 0.8 percent oil from two of the modified sugarcane lines, which is 67% and 167% more oil than unmodified sugarcane, respectively. "The oil composition is comparable to that obtained from other feedstocks like seaweed or algae that are being engineered to produce oil," said co-author Vijay Singh, Director of the Integrated Bioprocessing Research Laboratory at Illinois.


"We expected that as oil production increased, sugar production would decrease, based on our computer models," Long said. "However, we found that the plant can produce more oil without loss of sugar production, which means our plants may ultimately be even more productive than we originally anticipated."


To date, PETROSS has engineered sugarcane with 13 percent oil, 8 percent of which is the oil that can be converted into biodiesel. According to the project's economic analyses, plants with just 5 percent oil would produce an extra 123 gallons of biodiesel per acre than soybeans and 350 more gallons of ethanol per acre than corn. BY CARL R.

BARLEY GENOME SEQUENCED

A team of researchers at the University of California, Riverside may have you covered. They are among a group of 77 scientists worldwide who have sequenced the complete genome of barley, a key ingredient in beer and single malt Scotch. The research, 10 years in the making, was just published in the journal Nature.

"This takes the level of completeness of the barley genome up a huge notch," said Timothy Close, a professor of genetics at UC Riverside. "It makes it much easier for researchers working with barley to be focused on attainable objectives, ranging from new variety development through breeding to mechanistic studies of genes."

The research will also aid scientists working with other "cereal crops," including rice, wheat, rye, maize, millet, sorghum, oats and even turfgrass, which like the other food crops, is in the grass family, Close said.

Barley has been used for more than 10,000 years as a staple food and for fermented beverages, and as animal feed.

It is found in breakfast cereals and all-purpose flour and helps bread rise. Malted barley gives beer color, body, protein to form a good head, and the natural sugars needed for fermentation. And single malt Scotch is made from only water and malted barley.

The report in Nature provides new insights into gene families that are key to the malting process. The barley genome sequence also enabled the identification of regions of the genome that have been vulnerable to genetic bottlenecking during domestication, knowledge that helps to guide breeders to optimize genetic diversity in their crop improvement efforts.

Ten years ago, the International Barley Genome Sequencing Consortium, which is led by Nils Stein of the Leibniz Institute of Plant Genetics and Crop Plant Research in Germany, set out to assemble a complete reference sequence of the barley genome.

This was a daunting task, as the barley genome is almost twice the size of the human genome and 80 percent of it is composed of highly repetitive sequences, which cannot be assigned accurately to specific positions in the genome without considerable extra effort.

Multiple novel strategies were used in this paper to circumvent this fundamental limitation. Major advances in sequencing technology, algorithmic design and computing made it possible. Still, this work kept teams around the world -- in Germany, Australia, China, Czech Republic, Denmark, Finland, Sweden, Switzerland, United Kingdom and the United State -- occupied for a decade. This work provides knowledge of more than 39,000 barley genes.

Alcoholic beverages have been made from malted barley since the Stone Age, and some even consider this to be a major reason why humankind adopted plant cultivation, at least in the Fertile Crescent, where barley was domesticated.

During malting, amylase proteins are produced by germinated seeds to decompose energy-rich starch that is stored in dry grains, yielding simple sugars. These sugars then are available for fermentation by yeast to produce alcohol. The genome sequence revealed much more variability than was expected in the genes that encode the amylase enzymes.

Barley is grown throughout the world, with Russia, Germany, France, Canada, and Spain being among the top producers. In the United States, barley is mainly grown in the northwest. Idaho, Montana, and North Dakota are the leading producers. SOURCE UNIVERSITY OF CARLIFORNIA.

COMMON PESTICIDE DAMAGE HONEY BEES ABILITY TO FLY.

Biologists at the University of California San Diego have demonstrated for the first time that a widely used pesticide can significantly impair the ability of otherwise healthy honey bees to fly, raising concerns about how pesticides affect their capacity to pollinate and the long-term effects on the health of honey bee colonies.

Previous research has shown that foraging honey bees that ingested neonicotinoid pesticides, crop insecticides that are commonly used in agriculture, were less likely to return to their home nest, leading to a decrease in foragers.


A study published April 26 in Scientific Reports by UC San Diego postdoctoral researcher Simone Tosi, Biology Professor James Nieh, along with Associate Professor Giovanni Burgio of the University of Bologna, Italy, describes in detail how the neonicotinoid pesticide thiamethoxam damages honey bees. Thiamethoxam is used in crops such as corn, soybeans and cotton. To test the hypothesis that the pesticide impairs flight ability, the researchers designed and constructed a flight mill (a bee flight-testing instrument) from scratch. This allowed them to fly bees under consistent and controlled conditions.


Months of testing and data acquisition revealed that typical levels of neonicotinoid exposure, which bees could experience when foraging on agricultural crops -- but below lethal levels -- resulted in substantial damage to the honey bee's ability to fly.


"Our results provide the first demonstration that field-realistic exposure to this pesticide alone, in otherwise healthy colonies, can alter the ability of bees to fly, specifically impairing flight distance, duration and velocity" said Tosi. "Honey bee survival depends on its ability to fly, because that's the only way they can collect food. Their flight ability is also crucial to guarantee crop and wild plant pollination."

Long-term exposure to the pesticide over one to two days reduced the ability of bees to fly. Short-term exposure briefly increased their activity levels. Bees flew farther, but based upon other studies, more erratically.


"Bees that fly more erratically for greater distances may decrease their probability of returning home," said Nieh, a professor in UC San Diego's Division of Biological Sciences.

This pesticide does not normally kill bees immediately. It has a more subtle effect, said Nieh.
"The honey bee is a highly social organism, so the behavior of thousands of bees are essential for the survival of the colony," said Nieh." We've shown that a sub-lethal dose may lead to a lethal effect on the entire colony."


Honey bees carry out fundamentally vital roles in nature by providing essential ecosystem functions, including global pollination of crops and native plants. Declines in managed honey bee populations have raised concerns about future impacts on the environment, food security and human welfare.
Neonicotinoid insecticides are neurotoxic and used around the world on broad varieties of crops, including common fruits and vegetables, through spray, soil and seed applications. Evidence of these insecticides has been found in the nectar, pollen and water that honey bees collect.

"People are concerned about honey bees and their health being impaired because they are so closely tied to human diet and nutrition," said Nieh. "Some of the most nutritious foods that we need to consume as humans are bee-pollinated. "SOURCE- University of Carlifornia.