Potential
malarial vaccine produced from edible algae
http://zeenews.india.com/news/health/exclusive/potential-malarial-vaccine-produced-from-algae_17013.html
Washington: Biologists have successfully engineered algae to produce
potential candidates for a vaccine that would prevent transmission of the
parasite that causes malaria. Initial proof-of-principle experiments suggest
that such a vaccine could prevent malaria transmission. The achievement could
pave the way for the development of an inexpensive way to protect billions of
people from one of the world’s most prevalent and debilitating diseases.
Malaria is a mosquito-borne disease caused by infection with protozoan parasites from the genus Plasmodium. It affects more than 225 million people worldwide in tropical and subtropical regions, resulting in fever, headaches and in severe cases coma and death. While a variety of often costly anti-malarial medications are available to travellers in those regions to protect against infections, a vaccine offering a high level of protection from the disease does not yet exist.
Malaria is a mosquito-borne disease caused by infection with protozoan parasites from the genus Plasmodium. It affects more than 225 million people worldwide in tropical and subtropical regions, resulting in fever, headaches and in severe cases coma and death. While a variety of often costly anti-malarial medications are available to travellers in those regions to protect against infections, a vaccine offering a high level of protection from the disease does not yet exist.
The new development resulted from an unusual interdisciplinary
collaboration between two groups of biologists at University of California, San
Diego—one from the Division of Biological Sciences and San Diego Center for
Algae Biotechnology, which had been engineering algae to produce bio-products
and biofuels, and another from the Center for Tropical Medicine and Emerging
Infectious Diseases in the School of Medicine that is working to develop ways
to diagnose, prevent and treat malaria.
Part of the difficulty in creating a vaccine against malaria is that it requires a system that can produce complex, three-dimensional proteins that resemble those made by the parasite, thus eliciting antibodies that disrupt malaria transmission. Most vaccines created by engineered bacteria are relatively simple proteins that stimulate the body’s immune system to produce antibodies against bacterial invaders. More complex proteins can be produced, but this requires an expensive process using mammalian cell cultures, and the proteins those cells produce are coated with sugars due to a chemical process called glycosylation.
Part of the difficulty in creating a vaccine against malaria is that it requires a system that can produce complex, three-dimensional proteins that resemble those made by the parasite, thus eliciting antibodies that disrupt malaria transmission. Most vaccines created by engineered bacteria are relatively simple proteins that stimulate the body’s immune system to produce antibodies against bacterial invaders. More complex proteins can be produced, but this requires an expensive process using mammalian cell cultures, and the proteins those cells produce are coated with sugars due to a chemical process called glycosylation.
“Malaria is caused by a parasite that makes complex proteins, but for
whatever reason this parasite doesn’t put sugars on those proteins,” said
Stephen Mayfield, a professor of biology at UC San Diego who headed the
research effort.
“If you have a
protein covered with sugars and you inject it into somebody as a vaccine, the
tendency is to make antibodies against the sugars, not the amino acid backbone
of the protein from the invading organism you want to inhibit. Researchers have
made vaccines without these sugars in bacteria and then tried to refold them
into the correct three-dimensional configuration, but that’s an expensive
proposition and it doesn’t work very well,” he stated. Instead, the biologists
looked to produce their proteins with the help of an edible green alga,
Chlamydomonas reinhardtii, used widely in research laboratories as a genetic
model organism, much like the fruit fly Drosophila and the bacterium E. coli. Two
years ago, a UC San Diego team of biologists headed by Mayfield, who is also
the director of the San Diego Center for Algae Biotechnology, a research
consortium seeking to develop transportation fuels from algae, published a
landmark study demonstrating that many complex human therapeutic proteins, such
as monoclonal antibodies and growth hormones, could be produced by
Chlamydomonas. That got James Gregory, a postdoctoral researcher in Mayfield’s
laboratory, wondering if a complex protein to protect against the malarial
parasite could also be produced by Chlamydomonas. Two billion people live in
regions where malaria is present, making the delivery of a malarial vaccine a
costly and logistically difficult proposition, especially when that vaccine is
expensive to produce.
So the UC San
Diego biologists set out to determine if this alga, an organism that can
produce complex proteins very cheaply, could produce malaria proteins that
would inhibit infections from malaria.
“It’s too
costly to vaccinate two billion people using current technologies.
Realistically, the only way a malaria vaccine will ever be used is if it can be produced at a fraction of the cost of current vaccines. Algae have this potential because you can grow algae any place on the planet in ponds or even in bathtubs,” explained Mayfield. Collaborating with Joseph Vinetz, a professor of medicine at UC San Diego and a leading expert in tropical diseases who has been working on developing vaccines against malaria, the researchers showed that the proteins produced by the algae, when injected into laboratory mice, made antibodies that blocked malaria transmission from mosquitoes. “It’s hard to say if these proteins are perfect, but the antibodies to our algae-produced protein recognize the native proteins in malaria and, inside the mosquito, block the development of the malaria parasite so that the mosquito can’t transmit the disease,” said Gregory.
Realistically, the only way a malaria vaccine will ever be used is if it can be produced at a fraction of the cost of current vaccines. Algae have this potential because you can grow algae any place on the planet in ponds or even in bathtubs,” explained Mayfield. Collaborating with Joseph Vinetz, a professor of medicine at UC San Diego and a leading expert in tropical diseases who has been working on developing vaccines against malaria, the researchers showed that the proteins produced by the algae, when injected into laboratory mice, made antibodies that blocked malaria transmission from mosquitoes. “It’s hard to say if these proteins are perfect, but the antibodies to our algae-produced protein recognize the native proteins in malaria and, inside the mosquito, block the development of the malaria parasite so that the mosquito can’t transmit the disease,” said Gregory.
The scientists,
who filed a patent application on their discovery, said the next steps are to
see if these algae proteins work to protect humans from malaria and then to
determine if they can modify the proteins to elicit the same antibody response
when the algae are eaten rather than injected.
http://www.sciencedaily.com/releases/2012/05/120516174437.htm
Biologists
Produce Potential Malarial Vaccine from Algae
ScienceDaily (May 16, 2012) — Biologists at the
University of California, San Diego have succeeded in engineering algae to
produce potential candidates for a vaccine that would prevent transmission of
the parasite that causes malaria, an achievement that could pave the way for
the development of an inexpensive way to protect billions of people from one of
the world's most prevalent and debilitating diseases. Initial
proof-of-principle experiments suggest that such a vaccine could prevent
malaria transmission.
Malaria is a mosquito-borne disease caused by infection with
protozoan parasites from the genus Plasmodium. It affects more than 225 million
people worldwide in tropical and subtropical regions, resulting in fever,
headaches and in severe cases coma and death. While a variety of often costly
antimalarial medications are available to travelers in those regions to protect
against infections, a vaccine offering a high level of protection from the
disease does not yet exist.
The use of algae to produce malaria proteins that elicited
antibodies against Plasmodium
falciparum in laboratory mice and prevented malaria transmission
was published May 16 in the online, open-access journal PLoS ONE. The development
resulted from an unusual interdisciplinary collaboration between two groups of
biologists at UC San Diego -- one from the Division of Biological Sciences and
San Diego Center for Algae Biotechnology, which had been engineering algae to
produce bio-products and biofuels, and another from the Center for Tropical
Medicine and Emerging Infectious Diseases in the School of Medicine that is
working to develop ways to diagnose, prevent and treat malaria.
Part of the difficulty in creating a vaccine against malaria is
that it requires a system that can produce complex, three-dimensional proteins
that resemble those made by the parasite, thus eliciting antibodies that
disrupt malaria transmission. Most vaccines created by engineered bacteria are
relatively simple proteins that stimulate the body's immune system to produce
antibodies against bacterial invaders. More complex proteins can be produced,
but this requires an expensive process using mammalian cell cultures, and the
proteins those cells produce are coated with sugars due to a chemical process
called glycosylation.
"Malaria is caused by a parasite that makes complex proteins,
but for whatever reason this parasite doesn't put sugars on those
proteins," said Stephen Mayfield, a professor of biology at UC San Diego
who headed the research effort. "If you have a protein covered with sugars
and you inject it into somebody as a vaccine, the tendency is to make antibodies
against the sugars, not the amino acid backbone of the protein from the
invading organism you want to inhibit. Researchers have made vaccines without
these sugars in bacteria and then tried to refold them into the correct
three-dimensional configuration, but that's an expensive proposition and it
doesn't work very well."
Instead, the biologists looked to produce their proteins with the
help of an edible green alga, Chlamydomonas
reinhardtii, used widely in research laboratories as a genetic
model organism, much like the fruit fly Drosophila
and the bacterium E. coli.
Two years ago, a UC San Diego team of biologists headed by Mayfield, who is
also the director of the San Diego Center for Algae Biotechnology, a research
consortium seeking to develop transportation fuels from algae, published a
landmark study demonstrating that many complex human therapeutic proteins, such
as monoclonal antibodies and growth hormones, could be produced by Chlamydomonas.
That got James Gregory, a postdoctoral researcher in Mayfield's laboratory,
wondering if a complex protein to protect against the malarial parasite could
also be produced by
Chlamydomonas. Two billion people live in regions where malaria is
present, making the delivery of a malarial vaccine a costly and logistically difficult
proposition, especially when that vaccine is expensive to produce. So the UC
San Diego biologists set out to determine if this alga, an organism that can
produce complex proteins very cheaply, could produce malaria proteins that
would inhibit infections from malaria.
"It's too costly to vaccinate two billion people using
current technologies," explained Mayfield. "Realistically, the only
way a malaria vaccine will ever be used is if it can be produced at a fraction
of the cost of current vaccines. Algae have this potential because you can grow
algae any place on the planet in ponds or even in bathtubs."
Collaborating with Joseph Vinetz, a professor of medicine at UC
San Diego and a leading expert in tropical diseases who has been working on
developing vaccines against malaria, the researchers showed that the proteins
produced by the algae, when injected into laboratory mice, made antibodies that
blocked malaria transmission from mosquitoes.
"It's hard to say if these proteins are perfect, but the antibodies
to our algae-produced protein recognize the native proteins in malaria and,
inside the mosquito, block the development of the malaria parasite so that the
mosquito can't transmit the disease," said Gregory.
"This paper tells us two things: The proteins that we made
here are viable vaccine candidates and that we at least have the opportunity to
produce enough of this vaccine that we can think about inoculating two billion
people," said Mayfield. "In no other system could you even begin to think
about that."
The scientists, who filed a patent application on their discovery,
said the next steps are to see if these algae proteins work to protect humans
from malaria and then to determine if they can modifiy the proteins to elicit
the same antibody response when the algae are eaten rather than injected.
Other UC San Diego scientists involved in the discovery were
Fengwu Li from Vinetz's laboratory and biologists Lauren Tomosada, Chesa Cox
and Aaron Topol from Mayfield's group. The basic technology that led to the
development was supported by the Skaggs family. The research was supported by
grants from the National Institute of Allergy and Infectious Diseases and the
San Diego Foundation. The California Energy Commission supported work on
recombinant protein production for biofuels use, and this technology helped
enabled these studies.
No comments:
Post a Comment