| Press Images
In this composite photograph, a rock pigeon preening its
feathers is superimposed on a closeup image of a rock pigeon
feather with lice trying to hide between feather branches
to escape preening.
To
download high-resolution click here:
Credit: Dale H. Clayton and Sarah E. Bush, University of
Utah |
December 8, 2003 -- University of Utah biologists
twirled louse-infested bird feathers on an electric fan and flew
pigeons and doves like kites on strings in a study that found
small lice stick to small birds and big lice prefer big birds.
The study also showed why size matters to parasites: Lice infest
bird species with feathers that are just the right size so the
insects can hide between individual “barbs” –
the hair-like branches that extend from the shaft of each feather.
When lice can hide in the feathers, the birds cannot preen them
off with their beaks.
Why should anyone care? More than half of all species on Earth
are parasites, or bacteria and viruses that act like parasites.
The great diversity of parasites is tied to the fact that many
parasite species evolved so each usually infests only one species
of host organism.
The study “is one of the best demonstrations to date of
why parasites are often specific to a single species of host and
under what conditions they jump hosts,” said evolutionary
ecologist Dale H. Clayton, the study’s first author and
an associate professor of biology at the University of Utah. “This
is of strong interest to the public, particularly when it concerns
parasites such as SARS and the West Nile virus.”
“Sometimes parasites from domestic animals switch to humans
and sometimes they don’t,” says biology doctoral student
Sarah E. Bush, a co-author of the study. “So looking at
how parasites on birds switch to other species of birds may help
us understand how parasites from mammals switch to humans.”
The study is being published online the week of Dec. 8, 2003,
by the journal Proceedings of the National Academy of Sciences.
It was conducted by Clayton; Bush; former biology undergraduate
Brad Goates, now a University of Utah medical student; and former
postdoctoral researcher Kevin Johnson, now at the Illinois Natural
History Survey.
SARS (severe acute respiratory syndrome), which killed 916 people
worldwide in a 2003 outbreak, is caused by a coronavirus that
is believed to have jumped to humans from civets, which are nocturnal,
cat-shaped creatures. The West Nile virus is spread from birds
and mosquitoes to humans.
While the new study is not immediately relevant to SARS and West
Nile, “if we know why parasites use some hosts and not other
hosts, then we can begin to predict what hosts may get hit in
the future by a given parasite,” Clayton says.
Genealogy for lice and birds
In one part of the study, the researchers analyzed genetic material
from 19 species of lice and 24 species of pigeons and doves. That
allowed them to construct evolutionary family trees for the lice
and the birds, showing how each species was related to or descended
from other species during the last 30 million years.
Those evolutionary trees revealed that louse species evolved in
concert with various species of pigeons and doves they infest.
As a result, “big birds have big lice, small birds have
small lice,” says Bush.
“We have shown that something as simple as the changing
size of a parasite’s environment – the bird feather
– can cause new species of lice to form,” Clayton
says.
“Our research suggests that humans don’t pick up lice
from chimps and baboons because those lice evolved to hang onto
to coarser hair. On an even broader level, the study suggests
size matters in terms of what parasites infest a host. Size is
one of the most fundamental properties of all living organisms.
Something as simple as size even may be dictating what cells can
be invaded by parasites like those that cause malaria.”
Experiments to learn why bird size matters to lice
After making measurements to confirm bigger birds have bigger
feathers and smaller birds have smaller feathers, the researchers
conducted three sets of experiments to learn why big lice could
only survive on birds with big feathers.
Five species of birds were captured in Arizona, Utah, Oregon and
Texas in accordance with federal and state permits: rock pigeons
(average weight 21 ounces), which are the common pigeons seen
in city streets worldwide; band-tailed pigeons (21 ounces); white-tipped
doves (6 ounces); mourning doves (4 ounces); and common ground
doves (1 ounce).
One louse species was used: the slender wing louse that normally
infests rock pigeons.
-- The first experiment disproved the hypothesis that lice couldn’t
eat feathers of incompatibly sized birds.
Some abdominal feathers were plucked from all five species, weighed,
and incubated for a month in test tubes with 10 lice per tube.
Then the feathers were removed and weighed, revealing that the
lice ate the same, no matter what size bird the feathers came
from.
-- A second set of experiments disproved the hypothesis that large
lice would have trouble clinging to the small feathers of a small
bird. The hypothesis is basically that “if you have evolved
to shimmy up telephone poles, then you might have trouble climbing
redwood trees or a clothesline pole,” Clayton explains.
Bush tested that idea by cutting a small, square piece of feather
from each wing of several rock pigeons. On one wing, she used
fabric glue to transplant a piece of feather from another rock
pigeon. This was the control. On the other wing, she grafted a
piece of feather from one of the other four pigeon and dove species.
Then she placed two live lice on each feather graft.
“The idea was to see if rock pigeon lice can hang onto feathers
from different species of birds,” Bush says.
Bush placed each bird on a tether made of fishing line and, one
at a time, let them fly above a University of Utah football field
until they landed. In a related experiment, she painlessly removed
feathers with the transplanted feather piece and taped them to
an electric fan rotating at 50 mph for 20 minutes.
Both parts of the experiment showed most of the rock pigeon lice
stuck to feathers, no matter what species of bird was the source
of the feather transplant.
“I had one louse on the fan for seven hours,” Bush
says. “I gave up before it did.”
-- The third and conclusive experiment revealed why a bird’s
size matters to the lice that infest it. The experiment showed
that lice of just the right size were able to hide in the feathers
and escape being picked off when the bird used its beak to preen
its feathers.
The researchers started with louse-free birds. Then they transferred
25 lice that normally infest rock pigeons onto each bird of four
other species of pigeons and doves.
Some birds were allowed to keep their normal preening ability.
Preening was blocked in other birds by placing a harmless C-shaped
plastic bit – somewhat like a horse’s bit –
between the upper and lower parts of the beak. Those birds couldn’t
completely close their beaks. They could eat, but were unable
to use the overhang of the upper beak to remove lice.
Normally, a bird’s beak “is like a guillotine,”
Bush says. “It chops off parts of the lice and crushes or
slices them to remove them.”
After two months, the scientists counted the number of lice on
each bird, and found big lice couldn’t survive on small
birds because they couldn’t hide in the feathers.
“This study suggests that birds and lice co-evolve in an
arms race over time, with lice changing size as birds, their beaks
and feathers also change size,” Clayton says.
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