Newswise, September 21, 2015--By measuring how worms move
toward an appealing, food-like scent, researchers at the Salk Institute were
able to predict whether the worms would be long-lived.
The finding, publishing September 22, 2015 in the journal eLife,
shows how nematodes (Caenorhabditis elegans) process information about
the environment and how circuits in the brain change as an animal ages.
“We’re not saying that your ability to smell is going to make
you live longer,” says Sreekanth Chalasani, an assistant professor in Salk’s
Molecular Neurobiology Laboratory.
“But this odor behavior is likely indicative of some kind of
underlying physiology.”
The small C. elegans has 12 pairs of
specialized neurons in its brain that detect stimuli in the environment.
Scientists had previously identified individual pairs of these neurons as
required for the animals to respond to attractive odors.
Chalasani and his colleagues wanted to understand this entire
process in more detail. In their new work, the researchers measured the responses
of all 24 neurons asC. elegans was exposed to benzaldehyde—a
chemical that gives off a pleasant, almond-like smell. Surprisingly, rather
than the individual pairs that had been previously shown, they found that
additional neurons were also involved.
Interestingly, these cells were divided into primary and
secondary neurons. Primary neurons showed activity in response to the
benzaldehyde, while secondary neurons responded to signals sent by the primary
neurons. By having a neural circuit structured like this, the team
hypothesizes, the worm can get better information on the strength or
concentration of a smell.
“If you have multiple different cells that are all detecting a
stimulus, you can use the combination of them to get more dynamic information,”
says Sarah Leinwand, a graduate student in the Chalasani lab and first author
of the new paper.
“Using this strategy allows an animal to generate flexible
behavioral responses to its environment.” For instance, some behaviors could
only be triggered when a smell is strong enough to cause activity in particular
combinations of neurons.
The researchers speculate that other species with larger
brains may use similarly structured neural circuits to represent sensory
information and fine-tune their behaviors.
Since they knew that worms (like other animals and people) often begin to lose their sense of smell with age, Chalasani and Leinwand next measured how the circuit composed of primary and secondary neurons changes as C. elegansgets older.
Since they knew that worms (like other animals and people) often begin to lose their sense of smell with age, Chalasani and Leinwand next measured how the circuit composed of primary and secondary neurons changes as C. elegansgets older.
While the primary neurons don’t show a decline in activity,
they found, secondary neurons become less active with age. This suggests that
communication between neurons could be degraded as animals age, Chalasani says,
a phenomenon which might also hold true in other neural circuits in many
different species.
The scientists went on to show a correlation between poor
performance on a smell-based test (moving toward a point source of
benzaldehyde), the activity of secondary neurons and the animal’s lifespan.
Older animals that were more successful in finding the odor lived about 16%
longer than animals that were less good at moving toward the smell.
“Even though all these animals are siblings and have similar
genomes, if you look at neuron activity, behavioral performance, or lifespan,
there are significant differences,” says Chalasani. “Perhaps that’s because
some animals have better signaling between primary and secondary cells.”
If the signaling between neurons ends up being important in
how other organisms —including humans — age, then manipulating the nervous
system may prove a fruitful way to minimize the effects of aging or rejuvenate
brain functions, he says.
“There are a lot of questions that remain about what exactly
is changing as an animal ages,” says Leinwand. “We want to keep looking at what
is changing to cause some animals to have better functioning nervous systems
and to live longer.”
Other researchers on the study were Claire Yang of the Salk Institute, Daphne Bazopoulou and Nikos Chronis of the University of Michigan, and Jagan Srinivasan of the Worcester Polytechnic Institute.
Other researchers on the study were Claire Yang of the Salk Institute, Daphne Bazopoulou and Nikos Chronis of the University of Michigan, and Jagan Srinivasan of the Worcester Polytechnic Institute.
The work and the researchers involved were supported by the
Rita Allen Foundation, the W.M. Keck Foundation, the National Institutes of
Health, Achievements Rewards for College Scientists and the National Science
Foundation.
About the Salk Institute for Biological Studies:
The Salk Institute for Biological Studies is one of the world's preeminent basic research institutions, where internationally renowned faculty probes fundamental life science questions in a unique, collaborative and creative environment.
The Salk Institute for Biological Studies is one of the world's preeminent basic research institutions, where internationally renowned faculty probes fundamental life science questions in a unique, collaborative and creative environment.
Focused both on discovery and on mentoring future generations
of researchers, Salk scientists make groundbreaking contributions to our
understanding of cancer, aging, Alzheimer's, diabetes and infectious diseases
by studying neuroscience, genetics, cell and plant biology and related
disciplines.
Faculty achievements have been recognized with numerous
honors, including Nobel Prizes and memberships in the National Academy of
Sciences. Founded in 1960 by polio vaccine pioneer Jonas Salk, MD, the
Institute is an independent nonprofit organization and architectural landmark.
No comments:
Post a Comment