Bacteria
are as individual as people, according to new research by Professor Peter Young
and his team in the Department of Biology at the University of York. Bacteria
are essential to health, agriculture and the environment, and new research
tools are starting to shed more light on them.
The
York team dug up a square meter of roadside verge on the University’s campus in
search of a bacterium called Rhizobium leguminosarum. The name means
"root dweller of the legumes," and these bacteria are natural
fertilizer factories that extract nitrogen from the air and make it available
to peas, beans, clover and their wild relatives.
In
the laboratory, the team extracted the bacteria from the plant roots and
established 72 separate strains. They determined the DNA sequence of the genome
of each strain. Their research, published in Open Biology, shows that
each of those 72 strains is unique -- each has different genes and is capable
of growing on different food sources.
People
are unique because each of us inherits half our genes from our mother and half
from our father, but bacteria reproduce by binary fission, making two identical
daughters. What bacteria are good at, though, is passing packages of genes from
one cell to another. It is this process of horizontal gene transfer that made
every rhizobium unique.
"We
can think of the bacterial genome as having two parts," says Professor
Young. "The core genome does the basic housekeeping and is much the same
in all members of the species, while the accessory genome has packages of genes
that are not essential to the operation of the cell, but can be very useful in
coping with aspects of the real world.
"Bacteria
are like smartphones. Each phone comes out of the factory with standard
hardware and operating system (core genome), but gains a unique combination of
capabilities through apps (accessory genes) downloaded through the internet (by
horizontal gene transfer)."
We
increasingly recognize the vital roles played by bacterial communities, such as
those in our gut or on the roots of plants. Many researchers have used
variation in a standard core gene to draw up lists of the species in a
community, but the new research shows that a list of names is not sufficient.
"There
may be 300 people called Baker in your city, but you can't assume that there
are 300 people baking bread," explains Professor Young.
It
is possible, with more sequencing effort, to look at all the genes in a
bacterial community -- an approach called "metagenomics" -- but to
understand how they are functioning, we also need to know which genes occur
together in the same bacterium. This new study helps us to understand the way
in which bacterial genomes are assembled.
Story
Source: University of York.
Journal
Reference:
Nitin
Kumar, Ganesh Lad, Elisa Giuntini, Maria E. Kaye, Piyachat Udomwong, N. Jannah
Shamsani, J. Peter W. Young, Xavier Bailly. Bacterial genospecies that are not
ecologically coherent: population genomics of Rhizobium leguminosarum. Open
Biology, January 2015 DOI: 10.1098/rsob.140133Posted by Tim Sandle
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