Tag Archives: colony collapse

BigBang, Environs

Helping the Honeybees

Agricultural biotechnology giant Monsanto is joining efforts to help the honeybee. Honeybees the world over have been suffering from a widespread and catastrophic condition often referred to a colony collapse disorder.

From Technology Review:

Beekeepers are desperately battling colony collapse disorder, a complex condition that has been killing bees in large swaths and could ultimately have a massive effect on people, since honeybees pollinate a significant portion of the food that humans consume.

A new weapon in that fight could be RNA molecules that kill a troublesome parasite by disrupting the way its genes are expressed. Monsanto and others are developing the molecules as a means to kill the parasite, a mite that feeds on honeybees.

The killer molecule, if it proves to be efficient and passes regulatory hurdles, would offer welcome respite. Bee colonies have been dying in alarming numbers for several years, and many factors are contributing to this decline. But while beekeepers struggle with malnutrition, pesticides, viruses, and other issues in their bee stocks, one problem that seems to be universal is the Varroa mite, an arachnid that feeds on the blood of developing bee larvae.

“Hives can survive the onslaught of a lot of these insults, but with Varroa, they can’t last,” says Alan Bowman, a University of Aberdeen molecular biologist in Scotland, who is studying gene silencing as a means to control the pest.

The Varroa mite debilitates colonies by hampering the growth of young bees and increasing the lethality of the viruses that it spreads. “Bees can quite happily survive with these viruses, but now, in the presence of Varroa, these viruses become lethal,” says Bowman. Once a hive is infested with Varroa, it will die within two to four years unless a beekeeper takes active steps to control it, he says.

One of the weapons beekeepers can use is a pesticide that kills mites, but “there’s always the concern that mites will become resistant to the very few mitocides that are available,” says Tom Rinderer, who leads research on honeybee genetics at the U.S. Department of Agriculture Research Service in Baton Rouge, Louisiana. And new pesticides to kill mites are not easy to come by, in part because mites and bees are found in neighboring branches of the animal tree. “Pesticides are really difficult for chemical companies to develop because of the relatively close relationship between the Varroa and the bee,” says Bowman.

RNA interference could be a more targeted and effective way to combat the mites. It is a natural process in plants and animals that normally defends against viruses and potentially dangerous bits of DNA that move within genomes. Based upon their nucleotide sequence, interfering RNAs signal the destruction of the specific gene products, thus providing a species-specific self-destruct signal. In recent years, biologists have begun to explore this process as a possible means to turn off unwanted genes in humans (see “Gene-Silencing Technique Targets Scarring”) and to control pests in agricultural plants (see “Crops that Shut Down Pests’ Genes”).  Using the technology to control pests in agricultural animals would be a new application.

In 2011 Monsanto, the maker of herbicides and genetically engineered seeds, bought an Israeli company called Beeologics, which had developed an RNA interference technology that can be fed to bees through sugar water. The idea is that when a nurse bee spits this sugar water into each cell of a honeycomb where a queen bee has laid an egg, the resulting larvae will consume the RNA interference treatment. With the right sequence in the interfering RNA, the treatment will be harmless to the larvae, but when a mite feeds on it, the pest will ingest its own self-destruct signal.

The RNA interference technology would not be carried from generation to generation. “It’s a transient effect; it’s not a genetically modified organism,” says Bowman.

Monsanto says it has identified a few self-destruct triggers to explore by looking at genes that are fundamental to the biology of the mite. “Something in reproduction or egg laying or even just basic housekeeping genes can be a good target provided they have enough difference from the honeybee sequence,” says Greg Heck, a researcher at Monsanto.

Read the entire article here.

Image: Honeybee, Apis mellifera. Courtesy of Wikipedia.

Technica

Beware! RoboBee May Be Watching You

History will probably show that humans are the likely cause for the mass disappearance and death of honey bees around the world.

So, while ecologists try to understand why and how to reverse bee death and colony collapse, engineers are busy building alternatives to our once nectar-loving friends. Meet RoboBee, also known as the Micro Air Vehicles Project.

From Scientific American:

We take for granted the effortless flight of insects, thinking nothing of swatting a pesky fly and crushing its wings. But this insect is a model of complexity. After 12 years of work, researchers at the Harvard School of Engineering and Applied Sciences have succeeded in creating a fly-like robot. And in early May, they announced that their tiny RoboBee (yes, it’s called a RoboBee even though it’s based on the mechanics of a fly) took flight. In the future, that could mean big things for everything from disaster relief to colony collapse disorder.

The RoboBee isn’t the only miniature flying robot in existence, but the 80-milligram, quarter-sized robot is certainly one of the smallest. “The motivations are really thinking about this as a platform to drive a host of really challenging open questions and drive new technology and engineering,” says Harvard professor Robert Wood, the engineering team lead for the project.

When Wood and his colleagues first set out to create a robotic fly, there were no off the shelf parts for them to use. “There were no motors small enough, no sensors that could fit on board. The microcontrollers, the microprocessors–everything had to be developed fresh,” says Wood. As a result, the RoboBee project has led to numerous innovations, including vision sensors for the bot, high power density piezoelectric actuators (ceramic strips that expand and contract when exposed to an electrical field), and a new kind of rapid manufacturing that involves layering laser-cut materials that fold like a pop-up book. The actuators assist with the bot’s wing-flapping, while the vision sensors monitor the world in relation to the RoboBee.

“Manufacturing took us quite awhile. Then it was control, how do you design the thing so we can fly it around, and the next one is going to be power, how we develop and integrate power sources,” says Wood. In a paper recently published by Science, the researchers describe the RoboBee’s power quandary: it can fly for just 20 seconds–and that’s while it’s tethered to a power source. “Batteries don’t exist at the size that we would want,” explains Wood. The researchers explain further in the report: ” If we implement on-board power with current technologies, we estimate no more than a few minutes of untethered, powered flight. Long duration power autonomy awaits advances in small, high-energy-density power sources.”

The RoboBees don’t last a particularly long time–Wood says the flight time is “on the order of tens of minutes”–but they can keep flapping their wings long enough for the Harvard researchers to learn everything they need to know from each successive generation of bots. For commercial applications, however, the RoboBees would need to be more durable.

Read the entire article here.

Image courtesy of Micro Air Vehicles Project, Harvard.