A research team led by a molecular plant pathologist at the University
of California, Riverside has discovered the mechanism by which an
aggressive fungal pathogen infects almost all fruits and vegetables.
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| The fungal pathogen Botrytis cinerea causes mold on strawberries. (Credit: University of California, Riverside) |
The team discovered a novel "virulence mechanism" -- the mechanism by which infection takes place -- of Botrytis cinerea.
This pathogen can infect more than 200 plant species, causing serious
gray mold disease on almost all fruits and vegetables that have been
around, even at times in the refrigerator, for more than a week.
Study results appear in the Oct. 4 issue of the journal Science.
Many bacterial, fungal and oomycete pathogens deliver protein
effectors -- molecules the pathogens secrete -- into the cells of hosts
to manipulate and, eventually, compromise host immunity.
The new study represents the first example of a fungal pathogen
delivering RNA effectors, specifically small RNA effector molecules,
into host cells to suppress host immunity and achieve infection of the
host plant.
"To date, almost all the pathogen effectors studied or discovered
have been proteins," said lead author Hailing Jin, a professor of plant
pathology and microbiology. "Ours is the first study to add the RNA
molecule to the list of effectors. We expect our work will help in the
development of new means to control aggressive pathogens."
Small RNAs guide gene silencing in a wide range of eukaryotic organisms. In the case of Botrytis cinerea,
small RNAs silence the expression of host defense genes, resulting in
the host plant cells being less able to resist the fungal attack. The
process is similar to how protein effectors weaken host immunity in the
case of most pathogens.
"What we have discovered is a naturally-occurring cross-kingdom RNAi
phenomenon between a fungal pathogen and a plant host that serves as an
advanced virulence mechanism," Jin said.
RNA interference or RNAi is a conserved gene regulatory mechanism
that is guided by small RNAs for silencing (or suppressing) genes.
Next, Jin and colleagues plan to continue investigating if the novel
mechanism they discovered also exists in other aggressive pathogens.
Source : sciencedaily.com
