Bacterial response to oxidation studied as toxin barometer

At the 233rd American Chemical Society national meeting in Chicago March 25-29, researchers from Virginia Tech and the Edward Via Virginia College of Osteopathic Medicine (VCOM) will report their work on a bacteria biosensor prototype and correlations to brain tissue damage.

Many environmental toxins in water, such as pesticides, heavy metals, and PCBs, kill through oxidative stress mechanisms, said Bev Rzigalinski, a pharmacologist with VCOM. Oxidative stress is caused by unbalanced molecules called free radicals and other oxidation-promoting molecules that damage cells and genetic material by removing electrons.

Gram negative heterotrophic bacteria “spit” potassium in the presence of oxidative stress, said Nancy Love, a professor in civil and environmental engineering and an adjunct in biology at Virginia Tech.

“More like ‘sweat’ potassium,” said Kaoru Ikuma of Nishinomiya, Japan, an environmental engineering graduate student at Virginia Tech.

However you describe the process for the non-scientist, the bacteria’s response of pushing potassium out of their cells in the presence of oxidative stress is called the glutathione-gated potassium efflux (GGKE) response. “Typical bacterial you find anywhere will have this response, but these particular bacteria really spew potassium,” said Love.

And Rzigalinski was pleased to hear it. Perhaps the GGKE response could be used to predict potential damage to animal and human cells. “But bacteria are different from mammalian cells,” said Rzigalinski, who is focused on neuroscience, particularly brain injury and aging, and nanotechnology.

“We wanted to see if the same type of marker would work with human cells, particularly brain cells. We used the bacteria to calibrate a sensor,” she said. “The bacteria are easier to prepare and more robust than using mammalian cells, such as rat brain tissue. Brain tissue is the most sensitive to toxins. We wanted to relate the bacteria response to cell response, like a barometer.”

“And we saw that it corresponds well,” said Ikuma. “Something that sets the bacteria off also sets the cells off.

Using the toxin, N-ethylmaleimide, as a constant, Ikuma and Rzigalinski are taking measurements and seeing correlations of GGKE response to mitochondrial damage in cell cultures.

“If we can create a library of cellular response, we might have either a generic or a specific predictor,” said Brian Love, professor of materials science and engineering at Virginia Tech. “We don’t know yet because we haven’t tested other cell types.”

Brian Love has been assisting with the research team’s attempts to immobilize the sentinel bacteria as part of a biosensor design strategy.

Nancy Love began her work with microbes by finding organisms that could be used to digest waste in wastewater treatment plants. When she noticed that the useful organisms were being put out of commission by various toxins in the water, she and a student went to a conference of microbiologists who work with stress systems. “We saw a connection between what they were seeing in food processing and what we were seeing in wastewater systems.”

She discovered that the ubiquitous Gram negative heterotrophic bacteria were being used to monitor food processing systems – so why not wastewater?

After doing work to develop what Brian Love describes as “bacterial canaries” as an early warning system to protect the microbes in wastewater systems, Nancy Love began to look for other applications, from water monitoring in general to specific health monitoring in other biological systems in the environment, and met Rzigalinski, who is focused on neuroscience, particularly brain injury and aging, and nanotechnology.

“It is a good sensor because it measures biological effect rather than concentrations,” Rzigalinski said. “So we can measure oxidative damage when we stick the sensor in the water, not individual concentrations of individual chemicals. It also announces the presence of an oxidative toxin you haven’t identified.”

“We don’t have to have 20 sensors for 20 toxins. We can sense the presence of any oxidative toxin,” Love said.

Ikuma, who was an undergraduate biology student at Virginia Tech when she began working with Love, has now come full circle from a biology student working on a civil engineering research project to an engineering student working on a biology project.

Source: Virginia Tech

Life-extending protein can also have damaging effects on brain cells
Proteins widely believed to protect against aging can actually cause oxidative damage in mammalian brain cells, according to a new report in the July Cell Metabolism, a publication of Cell Press. The findings suggest that the proteins can have both proaging and protective functions, depending on the circumstances, the researchers said.
Biologists identify key protein in cell's 'self-eating' function
Molecular biologists at the University of California, San Diego have found one piece of the complex puzzle of autophagy, the process of “self-eating” performed by all eukaryotic cells -- cells with a nucleus -- to keep themselves healthy.
Innate immune system targets asthma-linked fungus for destruction
A new study shows that the innate immune system of humans is capable of killing a fungus linked to airway inflammation, chronic rhinosinusitis and bronchial asthma. Researchers at Mayo Clinic and the Virginia Bioinformatics Institute (VBI) have revealed that eosinophils, a particular type of white blood cell, exert a strong immune response against the environmental fungus Alternaria alternata. The groundbreaking findings, which shed light on some of the early events involved in the recognition of A. alternata by the human immune system, were published recently in the Journal of Immunology.
Clinical study to examine role of vitamin D in kidney disease
Vitamin D is the key to preventing rickets and osteoporosis, but Rockefeller University scientists suspect it may also play a role in heading off atherosclerosis in people with chronic kidney disease.
Infections linked to premature births more common than thought
Previously unrecognized and unidentified infections of amniotic fluid may be a significant cause of premature birth, according to researchers at the Stanford University School of Medicine.
New study shows health benefits of probiotic could extend to the entire body
Data from a recent study demonstrate the anti-inflammatory and pathogen protection benefits of Bifidobacterium infantis 35624 a probiotic bacterial strain of human origin. Gastrointestinal benefits of probiotics have been well-documented, but more and more research is revealing that probiotic benefits extend to the entire body. The report was published in the August issue of the Public Library of Science (PLoS) Pathogens.
Accumulated bits of a cell's own DNA can trigger autoimmune disease
A security system wired within every cell to detect the presence of rogue viral DNA can sometimes go awry, triggering an autoimmune response to single-stranded bits of the cell's own DNA, according to a report in the August 22nd issue of the journal Cell, a Cell Press publication. The source of that single-stranded DNA is so-called endogenous retroelements—genetic elements accounting for a substantial portion of the genome that can move to new locations using a "copy and paste" mechanism, according to the researchers.
Study on salmonella self-destruction
ETH Zurich biologists, led by Professors Martin Ackermann and Wolf-Dietrich Hardt, in collaboration with Michael Doebeli of the University of British Colombia in Vancouver (CN), have been able to describe how random molecular processes during cell division allow some cells to engage in a self-destructive act to generate a greater common good, thereby improving the situation of the surviving siblings.

Bacterial response to oxidation studied as toxin barometer

Related stories:

News discussion: