Understanding wheat stripe rust through studies on host and pathogen metabolism
Abstract
Wheat stripe rust, caused by the biotrophic
Basidiomycete fungus Puccinia striiformis f. sp. tritici (Pst),
is one of the most important crop diseases worldwide. Pst has a
complex lifecycle with an asexual cycle and a sexual cycle,
consisting of five possible spore types. The asexual cycle, which
is the economically damaging phase on wheat, occurs repeatedly
throughout the growing season through the germination of
urediniospores, vegetative growth of the fungus and ultimate
sporulation. During colonization, urediniospores germinate on the
upper leaf surface and penetrate it via stomata. Vegetative
growth starts when infectious hyphae branch off from a
substomatal vesicle and ramify throughout the intercellular
spaces. When the tip of a growing hypha touches a mesophyll cell,
the fungus can develop an invasive structure called the
haustorium. This specialized structure penetrates the cell wall
but not the plasma membrane, expresses nutrient transporters and
is the main site for secretion of virulence effector proteins. At
this point the biotrophic growth starts. This stage If sufficient
nutrients are available the fungus is able to complete the
asexual cycle by developing spore-forming pustules that erupt
from the leaf epidermis releasing millions of urediniospores
(sporulation). Here I used physiological, molecular biology,
metabolomics, and transcriptomics approaches to provide a broad
view of metabolic processes during the infection. I measured the
chitin content of infected wheat tissue as a proxy for fungal
biomass, as chitin content is the major component of the fungal
wall. Using this technique, I found that the Pst asexual
lifecycle can be divided into two main phases. In the early part
of Pst cycle from two to eight days after infection, it has
limited requirements for nutrients, whereas the second phase from
9 to 15 dai leading to sporulation has high nutrient
requirements. As all fungal nutrients are derived from the host,
I measured aspects of carbon and nitrogen metabolic pathways. In
the first phase, most photosynthesis parameters were unaffected.
During the second phase, the high nutrient demand caused by the
infection shifted the metabolic status of the infected tissue
from source to strong sink. This conclusion was derived from the
fact that all photosynthesis parameters related to carbon
fixation and chlorophyll content decreased by at least half
compared to healthy leaves. Moreover, genes related to asparagine
and sucrose metabolism were up regulated in non-inoculated leaves
while head weights were reduced. These data are consistent with a
model in which the Pst infection induces nutrients reallocation
from healthy to infected tissue in the second phase of infection
to meet the sporulation phase demands. The second aspect that I
studied was the relationship between plant development and Pst
growth. One approach was to investigate the phenomenon of Adult
Plant Resistance (APR), in this case conferred by the hexose
transporter gene, Yr46. The Yr46 resistance is manifested as
reduced production of Pst spores on the infected flag leaves of
adult plants. I found that Yr46 seems to prevent the flag leaf
from acting as sink tissue, possibly by accumulating sugars in
the apoplast. This mechanism may reduce the cytoplasmic nutrients
available for uptake by the haustoria. I suggest that immunity
and plant development should be studied together, and observe
that systemic responses provide additional information to
understand the infection. I propose that in addition to the
recognition of pathogen molecules, plant immunity may also
concern the detection of pathogen manipulation of host metabolic
pathways.
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