Researchers make bacteria to produce useful proteins

September 7, 2009 By Leave a Comment

Washington, Sep 7 (ANI): Researchers at the University of British Columbia have turned the bacterium Caulobacter crescentus into a protein production factory by adapting a single protein on its surface, thus making useful proteins that can act as vaccines and drugs.

C. crescentus is a harmless bacterium that has a single protein layer on its surface.

Led by Dr. John Smit, the researchers adapted the system that secretes this protein, which self-assembles into a structure called the “S-layer”, to secrete instead many proteins that are useful for vaccines and other therapeutic purposes.

In other words, by keeping the S-layer protein intact and genetically inserting new things inside it, they produce a very dense display of useful proteins on the cell surface.

The researchers are now hoping to use the entire bacterium in a therapeutic application.

Bacteria are commonly used in biotechnology to produce useful protein products.

If the bacteria secrete the protein rather than keep it contained within the cell, purification costs are greatly lowered.

The researchers have developed a commercially available kit based on this technology, which could be especially useful in developing countries as it might be used to manufacture HIV-blocking agents very cheaply and with little specialist expertise.

“This S-layer system is very efficient at producing and secreting proteins – we can make the bacterium into a protein pump, secreting over half of all the protein it makes as engineered S-layer protein,” said Smit.

He added: “Applications of S-layer display that we are currently developing include anti-cancer vaccines, an HIV infection blocker and agents to treat Crohn’s and colitis, and diarrhoea in malnourished populations”.

Smit presented the findings at the Society for General Microbiology’s meeting at Heriot-Watt University, Edinburgh. (ANI)

Filed Under: Science News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Mozart ‘killed by superbug like MRSA, not poison’

August 18, 2009 By Leave a Comment

London, Aug 18 (ANI): Austrian composer Wolfgang Amadeus Mozart was killed by a bacterial infection akin to MRSA, claim Dutch researchers.

Mozart died at age 35 – young by even 18th century standards. His untimely death has remained a mystery ever since he passed away in the early hours of 5 December 1791.

Some claimed he was poisoned, others said he simply wore himself out by composing more than 600 pieces during his short life.

Now, a group of boffins has suggested that he died from a bacterial infection spread by soldiers which was rife in Vienna at the time, reports The Telegraph.

The researchers, who studied the city’s death register, found that the three most common causes of death among men of his age were tuberculosis, severe weight loss and a condition called ‘oedema’ or ‘dropsy’ – an accumulation of fluids causing the body to swell up.

And, Mozart’s symptoms match the last of the three, according to Dr Richard Zeger, from the Academic Medical Centre in Amsterdam, who said it could have been caused by a bacterial infection.

He said: “I think you can compare this to a superbug like MRSA or C.difficile.”

Mozart’s sister-in-law Sophie Haibel, who saw him days before he died, said he was covered in a rash – consistent with a bacterial infection – and severely swollen – consistent with oedema or dropsy.

At the time Vienna was full of soldiers from the Austro-Turkish war who had been struck down by disease.

Zeger said: “Austria was at war at the time so people were living in a bad condition and most of the deaths were among soldiers. You can see there was clearly an epidemic and we found that it started in a military hospital. There was some kind of inflammatory disease that almost everyone contracted and some people died. It was an epidemic of oedema, which is a collection of fluid.

“When your kidneys fail, they can’t secrete body fluids so fluid accumulates in your body, which causes people to swell up and get worse and worse.”

This kind of a condition could have been caused by being infected with bacteria from the Staphylococcus aureus (SA) family, or which MRSA is a more recent member.

“Mozart’s body had swollen up so badly he was not able to turn around any more in his bed, showing he had post-streptococcal complications,” said Zeger.

In those times, antibiotics like penicillin were nowhere present, so strictly speaking the bacteria would not have been a ‘super’ bug as it could not have developed any resistance in the way that methicillin-resistant Staphylococcus aureus (MRSA) has done.

Zeger postulated: “We still see the streptococcal infection today in close communities like schools and armies so that would be a good reason behind the epidemic.

“In Mozart’s time, several soldiers in the army were also musicians who might have performed in Vienna, where Mozart might have contracted it.” (ANI)

Filed Under: International News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

New discovery can help thwart Parkinson’s disease

July 8, 2009 By Leave a Comment

Washington, July 8 (ANI): Scientists from King’s College London say that blocking the release of chemical glutamate in the brain may help prevent Parkinson’s disease.

Dr. Susan Duty said that one of the contributing factors to nerve cell death is an excess of the chemical glutamate in the motor control pathways in the brain.

An excess of this chemical changes the way these pathways operate, and makes movement even less well controlled.

She said that stimulating ‘trigger points’ responsible for the release of a chemical that can kill brain cells can help thwart Alzheimer’s.

“The way we hope to achieve this is by stimulating protein targets on the nerve cell called metabotropic glutamate receptors. Certain types of these receptors, when stimulated, are known to prevent release of glutamate in other brain regions,” said Duty.

“We, and others, have now taken these ideas into regions relevant to Parkinson’s disease in the hope of reversing both the clinical signs and cell death associated with this condition.

“We, and others, have now taken these ideas into regions relevant to Parkinson’s disease in the hope of reversing both the clinical signs and cell death associated with this condition,” she added.

Duty said that current drugs could only treat the symptoms but not the underlying cause of the disease.

“They provide relief of symptoms by replacing the chemical, dopamine, which the dying cells would normally secrete in order to maintain proper control of movement,” she said.

“However, they do little to combat the ongoing progressive cell death meaning that symptoms get worse, higher doses of drug are needed to control the worsening symptoms, the result being appearance of disabling side-effects such as involuntary flailing limb movements and painful twisting of joints.

“Given the disease is progressive in nature, the continued death of cells in the substantia nigra leads to gradual worsening of symptoms and decline in patients’ quality of life over time.

“Finding drugs that can provide protection or repair to the dying cells – as well as relieve the clinical signs of Parkinson’s – is therefore a key area of interest in this field,” she added.

The study was presented at The British Pharmacological Society’s Summer Meeting in Edinburgh. (ANI)

Filed Under: Uncategorized Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Plants saved planet Earth from freezing over during last ice age

July 2, 2009 By Leave a Comment

Washington, July 2 (ANI): In a new research, scientists have suggested that plants may have played a crucial role in putting a limit on the last ice age.

When glaciers advanced over much of the Earth’s surface during the last ice age, the planet did not freeze over entirely.

This has been a puzzle to climate scientists because leading models have indicated that over the past 24 million years geological conditions should have caused carbon dioxide levels in the atmosphere to plummet, possibly leading to runaway “icehouse” conditions.

Now, scientists report on the missing piece of the puzzle – plants.

“Atmospheric CO2 concentrations have been remarkably stable over the last 20 or 25 million years despite other changes in the environment,” said research co-author Ken Caldeira of the Carnegie Institution’s Department of Global Ecology.

“We can look to land plants as the primary buffering agent that’s held CO2 in such a narrow range during this time,” he added.

The research team, led by Mark Pagani of Yale University, found that the critical role of plants in the chemical breakdown and weathering of rocks and soil gave them a strong influence on carbon dioxide levels.

It was a link that earlier studies had missed.

The rise of the Andes, Himalayas, Tibetan Plateau, and mountain ranges in western North America over the past 25 million years would have been expected to have cause faster weathering and erosion, and therefore a faster burial of carbon drawn from the atmosphere.

But the stability of carbon dioxide levels indicate that this didn’t happen.

This is where the plants come in.

“The rates of weathering reactions are largely controlled by plants. Their roots secrete acids that dissolve minerals, they hold soils, and they increase the amount of carbon dissolved in groundwater,” said Caldeira.

“But when levels of carbon dioxide get too low, the plants basically suffocate and the weathering slows down. That means less sediment is eroded from the uplands and less carbon can be buried. It’s a negative feedback on the system that has kept carbon dioxide levels from dropping too low,” he added.

Extremely low carbon dioxide levels would have reduced the atmosphere’s ability to retain heat, putting the planet into a deep freeze.

“So you could say that by limiting the drawdown of CO2 by chemical weathering and sedimentation, plants saved the planet from freezing over,” said Caldeira. (ANI)

Filed Under: Science News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Why diabetics have high blood glucose levels

April 8, 2009 By Leave a Comment

Washington, April 8 (ANI): A research team, including an Indian-origin boffin, has shed light on why people with diabetes have high blood glucose levels.

Researchers at Joslin Diabetes Center have shown for the first time that insulin plays a significant role in suppressing levels of glucagon, a hormone involved in carbohydrate metabolism and regulating blood glucose levels.

According to researchers, the new findings could lead to development of a drug aimed at targeting glucagon levels.

“This is a very important finding because until now scientists have only speculated that insulin may be involved in keeping glucagon levels in check,” said Rohit N. Kulkarni, M.D., Ph.D., Principal Investigator in the Joslin Section on Cellular and Molecular Physiology and senior author of the study

Produced by the alpha cells in the pancreas, glucagon acts on the liver to help raise blood glucose when it becomes low. It has the opposite effect on the liver as insulin, which is released from pancreatic beta cells to lower blood glucose when it is high.

In a healthy individual, the two counter each other to keep blood glucose levels balanced. In individuals with long-standing type 1 or type 2 diabetes, inappropriate glucagon secretion can increase the chances of hypoglycemia (low blood glucose levels) and can interfere with insulin therapy.

The finding suggests that for people with either type 1 or type 2 diabetes, a therapeutic approach could be developed to target insulin receptors or proteins in alpha cells in order to suppress glucagon secretion.

In addition, the research may also help in the understanding of why patients with type 1 diabetes in particular, who are required to inject insulin on a regular basis, are at risk for hypoglycemia.

Kulkarni said that it was thought that this increased risk was linked in some way to insulin receptors in the alpha cells, an idea that today’s study suggests is in fact the case.

“This gives us some insight into the cause of hypoglycemia, the most common complication in patients with type 1 diabetes,” he said.

“Injecting insulin leads to a decrease in blood glucose. If it starts to go too low, glucagon normally kicks in to prevent hypoglycemia. But, what happens in diabetes is the alpha cells become desensitized by repeated insulin injections over many years and they start to behave abnormally. We believe this is linked to insulin receptor function,” he added.

In the study, researchers created a genetically engineered mouse model in which pancreatic alpha cells – those that secrete glucagon – were modified so that they did not contain insulin receptors. The idea was to explore the role of insulin in regulating glucagon secretion.

The modified mice exhibited elevated glucagon levels and also showed impaired glucose tolerance, as is seen in diabetes.

“This is the first genetic model wherein we provide definitive proof that insulin is able to suppress glucagon in mammals,” Kulkarni said.

The study is published in the April issue of Cell Metabolism. (ANI)

Filed Under: Science News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Scientists solve origin of ocean’s mysterious ‘green glow’

April 2, 2009 By Leave a Comment

Washington, April 2 (ANI): Researchers at Scripps Institution of Oceanography at UC (University of California) San Diego have uncovered key clues about bioluminescent worms in the sea that produce a green glow and the biological mechanisms behind their light production.

Research conducted by Scripps marine biologists Dimitri Deheyn and Michael Latz reveals that marine fireworms use bioluminescence to attract suitors in an undersea mating ritual.

The report provides insights into the function of fireworm bioluminescence and moves scientists closer to identifying the molecular basis of the light.

“This is another step toward understanding the biology of the bioluminescence in fireworms, and it also brings us closer to isolating the protein that produces the light,” said Deheyn.

“If we understand how it is possible to keep light so stable for such a long time, it would provide opportunities to use that protein or reaction in biomedical, bioengineering and other fields-the same way other proteins have been used,” he added.

The fireworms used in the study (Odontosyllis phosphorea) are seafloor-dwelling animals that inhabit tropical and sub-tropical shallow coastal areas.

During summer reproductive events known as “swarming,” females secrete a luminous green mucus-which often draws the attention of human seafarers-before releasing gametes into the water.

The bright glow attracts male fireworms, which also release gametes into the bright green cloud.
The precisely timed bioluminescent displays have been tracked like clockwork in Southern California, the Caribbean and Japan, peaking one to two days before each quarter moon phase, 30 to 40 minutes after sunset and lasting approximately 20 to 30 minutes.

Deheyn and Latz collected hundreds of specimens from San Diego’s Mission Bay for their study, allowing them to not only examine live organisms but also produce the fireworms’ luminous mucus for the first time in an experimental setting.

The achievement provided a unique perspective and framework for examining the biology behind the worm’s bioluminescent system.

A central finding is that the fireworms’ bioluminescent light appears to play a role beyond attracting mates.

The researchers found that juveniles produce bioluminescence as flashes, leading to a determination that the light also may serve as a defensive mechanism, intended to distract predators.

Through experiments that included hot and cold testing and oxygen depletion studies, Deheyn and Latz found that the bioluminescence is active in temperatures as low as minus 20 degrees Celsius.

Based on these tests, the researchers believe the chemical process responsible for the bioluminescence may involve a specific light-producing protein-also called a “photoprotein.”

Further identification and isolation will be pursued in future studies. (ANI)

Filed Under: Science News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Some coral colonies can “live” for more than 4000 years

March 24, 2009 By Leave a Comment

London, March 24 (ANI): A new study has discovered that some coral colonies can “live” for more than 4000 years, as old as the pyramids, smashing the previous lifespan estimates of 70 years, and showing that the animals grow far more slowly than was thought.

It is this extremely slow growth that is the secret of the corals’ long life, Brendan Roark, at Texas A and M University, told New Scientist.

Whilst other studies had estimated their age at a few hundred years at most, Roark argues that what had been considered “annual” growth rings actually take much longer to form.

The polyps that form coral are able to create massive reefs of the mineral calcium carbonate (CaCO3) over long time periods by adding successive thin layers to the base of the “cups” in which they live.

Using high-resolution radiocarbon dating, his team first studied Hawaiian corals for traces of “bomb-carbon” – a radioactive carbon isotope produced during nuclear tests in the 1950s.

They found it only in wafer-thin (10-micrometre) layers on the outermost part of corals’ skeleton. This suggests that even these tiny accretions took decades to build up.

Further carbon-dating measurements from layers deep inside the corals then revealed the oldest Gerardia samples to be 2742 years old, while the Leiopathes had been growing for a whopping 4265 years.

This doesn’t mean that the individual animals that secrete the coral themselves live for so long, just that the hollow “skeletons” they grow.

“On a human timescale, there is no sustainable harvest of these animals,” said Roark. “We know next to nothing about how they spawn, settle and regenerate, but I have seen very few younger and smaller colonies, so even slow regeneration might not be a very likely option,” he added.

Roark also hopes that preserving the coral could be useful for humans.

“Given their slow growth, we may be able to use them as high-resolution records of past climate change,” he said. (ANI)

Filed Under: Science News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Pak’s Adiala jail to get satellite courts, security cell for Mumbai attackers

February 23, 2009 By Leave a Comment

Rawalpindi, Feb 23 (ANI): Satellite courtrooms and a security cell are likely to be built at Adiala Jail here to overcome security risks involved in transporting terrorists involved in the Mumbai terror attacks to court and monitor their movement day and night.

Sources said that suspects in high-profile terrorism cases including the Mumbai attacks, Benazir Bhutto assassination, etc were being kept at Adiala Jail. The development is being linked with shifting of suspects of Mumbai terrorist attacks to this jail.

They said law enforcement and intelligence agencies had prepared a report seeking the Interior Ministry to build the satellite courtrooms and security cell at Adiala Jail, the Daily Times reported.

“Satellite courtrooms and security cell will reduce security risks attached to movements of accused in high-profile cases,” sources said.

They surveillance cameras would directly connect the jail inmates with courts and headquarters of security agencies, enabling investigators and judges to question prisoners as per requirement without moving them out of the jail.

Security officials had also been deputed at Adiala Jail to ensure security of suspects of the Mumbai terrorist attacks. Sources said a special monitoring room would be built for investigation and court proceedings with no interruption.

“Adiala Jail authorities hope that the system would be established as soon as possible. Satellite towers, boosters, cameras, computers, LCDs and other accessories would come to jail shortly. Secrete agencies will send their IT experts to assemble the entire system,” they said.

The sources said the satellite system would also provide some relief to jail authorities and local police. (ANI)

Filed Under: International News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Parasitic butterflies trick hosts using ant music

February 7, 2009 By Leave a Comment

London, Feb 06 (ANI): Infant blue butterflies dupe ants into protecting themselves by mimicking the tune of their queen, a new study has found.

Researchers at the University of Oxford have found that the larvae and pupae of Maculinea rebeli – a parasitic butterfly native to western Europe, though threatened with extinction – imitate red ants so faithfully that worker ants worship them as if they were queens, caring for the developing caterpillar even at the expense of their own lives.

“They appeared to be treating the caterpillars as if they were the holiest of holiest, the pinnacle of power, the queen ant,” New Scientist quoted Jeremy Thomas, an entomologist at the University of Oxford, who led the new study, as saying.

As young caterpillars, M. rebeli spend their days gorging on leafy greens. When they’re nearly ready to begin their transformation into a butterfly, the caterpillars descend to the forest floor and secrete ant-like chemicals.

Duped worker ants carry the caterpillar to its colony, where it is accepted as another ant, based on its smell alone. However, Thomas found that the interlopers seem to get particularly special treatment.

When he disturbed a laboratory colony, workers sacrificed their own kin to save the butterfly larvae – much as they would if a queen ant were threatened.

“There must be some form of communication by the butterflies that make the ants think they’re royal, and at the same time we were pretty damn sure they weren’t by chemicals,” he said.

The researchers thought whether a mysterious ticking sound emitted by blue butterfly larvae and pupae could explain this privileged treatment.

The ants produce a song of their own, with subtle differences between queen and worker.

The researchers captured the tunes made by queen and worker ants, as well as by the butterfly larvae and pupae using miniature microphones hooked up to an MP3 recorder.

Auditory analysis showed similarities in key acoustic features of the ant and butterfly sounds, such as resonant frequency.

The researchers then used Lilliputian speakers to audition the various songs to workers. When they listened to their own songs, the workers perked up.

“Instead of running away or acting with aggression, the speakers attracted the worker ants to them and they tapped them with their antennae with great interest,” said Thomas.

The recording of a queen’s song inspired even more interest. Workers surrounded the speaker and refused to budge.

The researchers identified nearly the same behaviour when they played the butterfly songs to the ants – suggesting that auditory mimicry is the key to the butterflies’ ascendancy.

David Nash, an entomologist at the University of Copenhagen, said: “This use of sound potentially solves the mystery of how they mimic the queen even though they don’t smell like the queen.”

The study is published in the Journal Science. (ANI)

Filed Under: Science News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Scientists uncover how metastatic cancer cells plan their ”relocation”

January 7, 2009 By Leave a Comment

Washington, Jan 6 (ANI): Researchers at the Stanford University School of Medicine have discovered how metastatic cancer cells select their next site of infection.

Cancer biologist Amato Giaccia, PhD., the Jack, Lulu and Sam Willson Professor and professor of radiation oncology at Stanford, is the senior author of the research,

“Metastasis is not a passive process. Cells don”t just break off the primary tumor and lodge someplace else. Instead the cells actually secrete substances to precondition target tissue and make it more amenable to subsequent invasion,” said Giaccia.

This means that cells plan ahead by first sending molecular emissaries to orchestrate a breach in the body”s natural defenses. Blocking this cascade of events in mice hobbled the cells” migration and prevented the metastatic cancer that developed in control animals.

The researchers are hopeful that a similar tactic will be equally successful in humans.

Already, scientists know that certain primary cancers metastasize preferentially to other organs – for example, breast cancer often spreads to the lungs. This is in part due to the patterns of blood flow in the body.

Also, it was known that such future colonization sites, called pre-metastatic niches, harbour large numbers of cells derived from the bone marrow that somehow facilitate the cancer cells” entry.

However, they didn”t know how the bone-marrow-derived cells were summoned, and what, if any, role the primary tumour cells played in site selection.

Thus, the researchers focussed on a substance that they had previously shown to be involved in metastasis: a protein called lysyl oxidase, or LOX.

LOX expression increases in cancer cells deprived of oxygen – a condition called hypoxia that begins to occur when blood vessels fail to reach the inner cells of a growing tumour mass. Inhibiting LOX expression decreases tumour cell invasion and metastasis in the lungs of mice implanted with human breast cancer cells.

The researchers wanted to know how LOX affected metastasis.

In the new study, they found that blocking LOX expression in the mice not only prevented metastases, it also kept the bone-marrow-derived cells necessary for niche formation from flocking to the site.

When LOX was present, it accumulated in the lungs of the mice and was associated with one particular type of bone-marrow-derived cell known as a CD11b cell, which in turn, secreted a protein that breaks apart collagen and provides a handy entry point for the soon-to-arrive cancer cells.

“We”ve never really understood before how normal tissues are modified to allow metastases to target and successfully invade them. Now we know that LOX goes to the target tissue and attracts CD11b and other bone-derived cells to the pre-metastatic niche. If the mouse data is transferable to humans, and we have reasons to think it will be, we really believe way may have found an effective way to treat human disease,” said Giaccia.

The study is published in the latest issue of Cancer Cell. (ANI)

Filed Under: Health News Tagged With: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,