Georgia Tech researchers found many types of bacteria, include E.coli, in the middle to upper regions of the troposphere. (Photo: USDA)

Scientists have discovered a considerable number of living microorganisms, including bacteria, in the middle to upper regions of the troposphere, the region of our atmosphere that’s about seven to 20 kilometers above the Earth’s surface.

Researchers from the Georgia Institute of Technology said their findings might help other scientists learn more about the role microorganisms play in forming ice that may impact weather and climate.

Health and medical experts studying the transmission of disease could also benefit by gaining new insight into long-distance transport of bacteria.

Conditions in the troposphere cannot support most other forms of life without the aid of special equipment. Temperatures there can drop to as low as -55° C and the air pressure and density are considerably lower than on earth.

Microorganisms, such as bacteria, are plentiful and can be found everywhere on the Earth and in the sea.

These hardy little forms of life not only survive but actually thrive in some of the harshest conditions known to man. They live within other forms of life, such as the human body; in the soil and the air surrounding us; in scalding hot springs; the great depths of the ocean; and inside rocks deep within the Earth’s crust.

A view outside the window of a DC-8 aircraft as air samples are gathered for a NASA study. Georgia Tech scientists found living microorganisms in the samples. (Photo: NASA)

The microorganisms  documented by Georgia Tech scientists were gathered from air samples recovered as part of NASA’s 2010 Genesis and Rapid Intensification Processes (GRIP) program, which studies low- and high-altitude air masses associated with tropical storms.

NASA gathered the air samples from aboard a DC-8 aircraft that flew over both land and ocean, including the Caribbean Sea and portions of the Atlantic Ocean during and after two major tropical hurricanes in 2010, Earl and Karl.

Attaching a special filter system developed by the Georgia Tech team to the aircraft’s outside air sampling probes, researchers were able to collect numerous particles, including the microorganisms.

Once the air samples were taken, the filters were removed from the aircraft and sent to researchers for examination.

Rather than resorting to conventional cell-culture techniques to make their analysis, the researchers instead used genomic techniques, including polymerase chain reaction (PCR) – a biochemical technology used in molecular biology that magnifies a piece of DNA, allowing scientists to generate millions of copies of the DNA sequence, as well as gene sequencing to spot and estimate the quantities of microorganisms contained within the air samples.

The researchers found more bacteria than fungi among the microorganisms.

“We did not expect to find so many microorganisms in the troposphere, which is considered a difficult environment for life,” said one of the study’s authors, Kostas Konstantinidis, an assistant professor at Georgia Tech. “There seems to be quite a diversity of species, but not all bacteria make it into the upper troposphere.”

Terry Lathem, a graduate student in Georgia Tech’s School of Earth and Atmospheric Sciences, aboard a NASA DC-8 aircraft while gathering samples of microorganisms in the atmosphere. (NASA)

The living bacterial cells found made up about 20 percent of the total particles detected within the size range of 0.25 to 1 microns in diameter.

Air samples taken over the ocean were found to contain mostly marine bacteria, while primarily terrestrial bacteria was found in samples taken above land.

The researchers also found that hurricanes had a major impact on the distribution and dynamics of microorganism populations.

Kostas Konstantinidis joins us for this weekend’s radio edition of Science World.  He’ll tell us how these findings could help advance research in climatology and medicine.

Check out the right column for scheduled air-times or listen now to the interview below.

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A juvenile Gobidon (goby) fish is shown on an Acropora coral. These fish spend their entire lives with the same coral, protecting it from encroaching seaweed. (Photo: Georgia Tech/Joao Paulo Krajewski)

Coral reefs provide one of the world’s most vital ecosystems and some of these reefs are in danger of being destroyed.

While people are to blame for much of the destruction, nature also plays a role. Encroaching species of seaweed with poisonous compounds on their surfaces are one of nature’s threats.

The toxic seaweed begins its lethal damage upon contact with the coral, killing its tissue within two to three days of contact.

But now scientists at the Georgia Institute of Technology have found that one species of coral near the Fiji Islands  doesn’t sit around waiting to  destroyed; it actually sends out a call for help when it’s threatened by poisonous seaweed.

Small fish, known as gobies, which are about two centimeters long and spend their entire lives in the crevices of the coral, respond to the coral’s alarm within minutes.

The gobies go after the seaweed, chewing and mowing it away from the coral. Not only do the little fish protect their homes, but some species also use the toxic substances from the seaweed to build up their own protective arsenal.

Mark Hay, a biology professor at Georgia Tech and colleague Danielle Dixson conducted the research and published their findings in Science.

Hay said two species of goby serve as coral bodyguards.  One species simply chews away at the harmful seaweed and then spits it out, but the other type of fish actually ingests the poisonous substance. This enhances the fish’s already toxic characteristics, increasing its ability to protect itself from predators.

Coral protector Gobidon histrio (goby) in its living space on the coral Acropora nasuta. The coral is in contact with the toxic green alga Chlorodesmis fastigiata. (Photo: Georgia Tech/Danielle Dixson)

Researchers were unable to determine whether the fish were saving up the lethal seaweed compounds to use on enemies, or if they were already making their own poisons, and using the noxious material to build up their resistance to the poisons.

Not all fish possess the gobies’ protective instincts. Scientists also studied two other species of small fish that live in the coral.

According to Hay, these damsel fish simply swim away, moving on to other coral, when their homes are threatened.

“They just abandon it, say ‘It’s going to die, we’re out of here,’” Hay says.

Interestingly enough, the gobies are only protective when their particular species of coral is under attack.  The scientists placed the gobies within another closely-related species of coral and found that the little bodyguards did not respond or protect their new home when it was under a similar threat.

Hay hopes to study other species of coral in the future to see if they too are also aided by rapid responding protective fish.

Mark Hay joins us this weekend on the radio edition of Science World.  Tune in (see right column for scheduled times) or check out the interview below.

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The Mobile Music Touch is a wireless, musical glove which may improve sensation and motor skills for people with paralyzing spinal cord injuries. (Photo: Georgia Institute of Technology)

Researchers in Georgia have developed a glove which seems to improve touch sensation and motor skills for people with severe spinal cord injuries.

The Mobile Music Touch (MMT) looks like a regular workout glove, except for the small box mounted on the back.

Along with a piano keyboard, the glove is used to help people with spinal cord injuries learn to play the piano by vibrating the player’s fingers to show which keys they should play.

Some people who used the musical glove for these specialized piano lessons experienced improved sensation in their fingers after their  sessions.

Researchers at Georgia Tech – the Georgia Institute of Technology – along with Atlanta’s Shepard Center, worked with volunteers with spinal cord injuries over eight weeks.

The volunteers suffered their injury at least a year before this study and had very little feeling or movement in their hands.

The  participants were required to practice playing the piano for a half hour, three times a week for eight weeks.  Half of them used the MMT glove to practice and the other half did not.

Researchers also had the participants wear the glove at home after or before practice, for two hours a day, five days a week, feeling only the vibration from the device.

The researchers hoped the volunteers would receive some rehabilitative effects from passively wearing the device while doing regular, everyday activities.

“After our preliminary work in 2011, we suspected that the glove would have positive results for people with SCI,” said Tanya Markow, the project leader. “But we were surprised by how much improvement they made in our study. For example, after using the glove, some participants were able to feel the texture of their bed sheets and clothes for the first time since their injury.”

(Video: Georgia Institute of Technology)

Along with the specially-equipped glove, the Mobile Music Touch system works with a computer, MP3 player or smart phone.

The system is then programmed with a song which is wirelessly linked to the glove.  As the song plays, its musical notes are illuminated on the piano keys and the device then sends vibrations to “tap” the corresponding fingers.

After the eight weeks, the researchers had their volunteers perform a number of grasping and sensation tests so they could measure for any improvement.

The researchers found that those who used the MMT system performed significantly better than the others who just learned the piano normally.

“Some people were able to pick up objects more easily,” said Markow. “Another said he could immediately feel the heat from a cup of coffee, rather than after a delay.”

Markow believes the increased motor abilities are due to renewed brain activity that sometimes can become dormant in people with spinal cord injuries.

She thinks that the vibrations produced by the MMT system might trigger activity in the hand’s sensory cortex, which leads to firing in the brain’s motor cortex.

Markow would like to take her research with the MMT further to include functional MRI results.