Nanobacteria, extremely tiny “microorganisms” that have
sparked controversy and may cause disease, have been declared dead. Again.
Some say the nanobacteria were never really alive. Once touted as the world’s
smallest living organisms, and even an entirely new form of life, the entities
are actually nothing more than sub-microscopic balls of minerals and proteins,
independent teams of scientists in Taiwan
and France
report.
Surviving the nanobacteria is their “father,” Robert Folk, a geologist from the
University of Texas
at Austin, who discovered them in deposits from
Italian hot springs
in the early 1990s. Folk and his colleagues have since found the objects, which
are a thousandth the size of common bacteria such as E. coli, in sedimentary
mineral deposits ranging from limestone to iron oxides to silicates. The microbes
may be major players in eroding rocks to make soil, Folk believes.
Initial evidence for nanobacteria sparked excitement among many
microbiologists, geologists and other researchers. Some experts were skeptical
that the ingredients to make a living cell could be crammed into such a tiny
package. DNA is 2 nanometers wide, and some proteins are as large as the
proposed size of nanobacteria, 80 to 500 nanometers. But nanobacteria have been
cultured in laboratories and seen to grow in number, albeit slowly.
Finnish researchers found nanobacteria in human and cow blood about the time
that Folk discovered the organisms in rocks. Since then, nanobacteria have been
linked to kidney stone and gallstone formation (SN: 8/1/98, p. 75),
polycystic kidney diseases, rheumatoid arthritis, some cancers, co-infection
with HIV, Alzheimer’s disease and chronic prostatitis. They have also been
implicated in hardening of the arteries and aging.
The discovery of what appeared to be evidence of nanobacteria in a Martian meteorite
(SN: 8/10/96 p. 84) sparked extreme reactions from people who were
excited about a new form of life (especially one that might have lived on Mars)
and people who doubted the existence of nanoscale living organisms.
“It had the optimists turning cartwheels and the naysayers enraged, and it’s
stayed the same ever since,” Folk says.
John Ding-E Young of Chang Gung University in Taiwan believed in nanobacteria so
much that he and graduate student Jan Martel embarked on a series of
experiments to prove that the microorganisms couldn’t be just mineral deposits.
“I really wanted these people to be right,” Young says. Instead, the team found
just the opposite.
Calcium minerals (found in seashells, eggshells and marble) and calcium
phosphate (the stuff that bones are made of) are thought to compose
nanobacteria’s crusty exterior. When the researchers made calcium carbonate in
a solution used to nourish cells, the mineral formed round particles that
looked like the nanobacteria found in blood and rocks. Some of the particles
even resembled bacteria in the act of reproducing.
Then the researchers made the calcium carbonate particles grow by seeding the
solution with human blood serum—a common ingredient in solutions used to grow
cells—and incubating the solution with carbon dioxide. More tiny calcium
particles formed over the next few days, similar to the slow reproduction time
of nanobacteria.
A protein called albumin in the blood serum seems to seed nanoparticles but
keeps the calcium carbonate from forming crystals, Young and Martel reported in
the April 8 Proceedings of the National Academy of Sciences.
Working independently, a group of researchers in France also showed that
nanobacteria aren’t living organisms.
“These things can be replicated, but we quickly found that they aren’t bacteria
at all,” says Didier Raoult, a microbiologist at the NationalCenter for Scientific Research in Marseille, France.
In a study published February 15 in the online journal PLoS Pathogens,
Raoult and his colleagues described nanobacteria as complexes of minerals and a
protein called fetuin. Fetuin prevents minerals from forming crystals but may
aid in clumping calcium molecules into the hollow spheres characteristic of
nanobacteria.
But the particles can “infect” other solutions, producing more nanobacteria.
“There is something transmissible,” Raoult says. “I don’t know why, and I don’t
know what it is. It’s not living.” He theorizes that nanobacteria, which he
dubbed nanons, may work like infectious proteins called prions, which cause mad
cow disease, scrapie in sheep and several human brain diseases.
This is not the first time the bell has tolled for nanobacteria. A report in
2000 showed that the entities lack DNA. “In fact, there’s no nucleic acid at
all,” Raoult says.
Folk concedes that the two groups “did a good job” of showing that the
particular nanobacteria they studied are nonliving. But the organisms are so
diverse that “one explanation is obviously not going to fit all.” If the groups
had investigated some of the nanobacteria that he has collected, they would
find a different story, he says.
“Some are shaped like kidney beans. These are not shapes that minerals take.
It’s clearly biological,” Folk says.
But even researchers who believe nanobacteria may cause disease had already
started edging away from the idea that they are minuscule bacteria, even before
the latest publications.
“For me it’s not important if they are living or not,” says Andrei Sommer of
the University of Ulm in Germany. “It’s more important to
focus on their clear link to disease and how to eliminate them.” Wrangling over
whether nanobacteria are alive or dead is “only blocking the brain and blocking
action,” Sommer says.
Sommer and his colleague Dan Zhu isolated nanobacteria from fluid found in the
joints of people with arthritis. The researchers described their technique in
an article that appeared online April 2 in Environmental Science &
Technology.
Those who study nanobacteria are used to controversy. “We hear, ‘You’re
studying something that doesn’t exist,’” says Virginia Miller, a physiologist
at the MayoClinicMedicalSchool
in Rochester, Minn., who studies “self-replicating
calcifying nanoparticles” and their link to disease. Others have called the
particles living nanovesicles or nanobiota.
“We’re just beginning to understand how particles at the nanoscale interact
with cells,” Miller says. “It would be a very sad thing if these two papers
capped that avenue of research. We’re just on the brink of understanding how
these particles participate in disease.”
Young isn’t ready to bury nanobacteria yet, either. “My thinking is that these
structures are not only real, but they are important,” he says.
But if the particles aren’t itty-bitty bacteria, scientists have to decide what
to call them. “It’s nonsense to use the name nanobacteria,” Sommer says. “At
the same time, it’s unfair not to use it because it would be cutting off a
whole history of research.”
