Foot and Root Rot 2016 PDF

Summary

This document discusses fungal diseases, particularly foot and root rots, affecting cereal crops. It covers various types of diseases like Fusarium, Bipolaris, Gaeumannomyces, Peudocercosporella, and Rhizoctonia and their impact on plants, including yield loss and discolouration.

Full Transcript

Fungal Diseases –
Foot and Root rots
Dr. Josephine Brennan,
Department of Agriculture, Fisheries & Food, Celbridge, Kildare.
[email protected]

07/11/2016
 Types
Cereal Foot of
anddiseases
Root Rots
Seed
Caused by fungi including –
Diseases Fusarium, Bipolaris,
Loose/Covered smut, Bunt, Seedling
Gaeumannomyces, Peudocercosporella, Rhizoctonia
blight
Seed/Soil borne fungi
Foliar Diseases – Rhyncosporium, Ramularia, Net blotch,
Initial infection usually occurs at the roots or base of the
plant Brown rust, Yellow rust, P. Mildew, Septoria

Stem
The fungi cause based
the stemdiseases – Eyespot,
base and roots Fusarium
to rot causing the
leaves to become discoloured.

The rot at the base of the plant spreads up the
main stem discolouring that as well. If the disease
progresses the plant collapses completely
 Types
Cereal Foot of
anddiseases
Root Rots
Caused by fungi including Fusarium, Bipolaris,
Foot/Root diseases –
Gaeumannomyces, Peudocercosporella, Rhizoctonia
Take-all, Fusarium

Seed/Soil borne fungi
Ear diseases - Fusarium, Ergot.
Initial infection usually occurs at the roots or base of the
(Foliar diseases can also effect the ear include – Septoria,
plant
Yellow/Brown rust, P. Mildew)
The fungi cause the stem base and roots to rot causing the
Viral Diseases -
leaves to become discoloured. BYDV

The rot at the base of the plant spreads up the
main stem discolouring that as well. If the disease
progresses the plant collapses completely
 WhatCereal Foot and Root Rots
are rusts?
Caused by fungi including Fusarium, Bipolaris,
What is a haustoria?
Gaeumannomyces, Peudocercosporella, Rhizoctonia
Function?
Seed/Soil borne fungi
What is a biotroph?
Initial infection usually occurs at the roots or base of the
plant

What
The fungi isthe
cause anstem
obligate
base andparasite?
roots to rot causing the
leaves to become discoloured.

What
The rot at the base
is aofHeteroecious
the plant spreads up the
parasite?
main stem discolouring that as well. If the disease
progresses the plant collapses completely
 What are smuts?
Cereal Foot and Root Rots
Caused by fungi including Fusarium, Bipolaris,
Gaeumannomyces, Peudocercosporella, Rhizoctonia
What is covered smut?
Seed/Soil borne fungi
Initial infection usually occurs at the roots or base of the
plant What is loose smut?
The fungi cause the stem base and roots to rot causing the
leaves to become discoloured.
What is bunt?
The rot at the base of the plant spreads up the
main stem discolouring that as well. If the disease
progresses the plant collapses completely
 Cereal Foot and Root Rots

The fungus is normally introduced into an area by the
introduction of a plant which is already infected although it
can be bought in on implements and machinery.

Once in the soil, Foot and Root
rot diseases can over winter for
several years as spores. It is very
difficult, if not impossible to
remove it completely.
 Foot & Root Rot Diseases
Fusarium Foot Rot Complex - F.culmorum,
F.avenaceum and F.graminearum, F. poae &
M.nivale.

Take-All Disease - Gaeumannomyces graminis

Sharp Eyespot & True Eyespot –
Rhizoctonia cerealis
Peudocercosporella herpotrichoide

Common Root Rot - Bipolaris sorokiniana
Fusarium foot rot complex
 Fusarium foot rot complex
There are many species of Fusarium that
affect cereals.
– F.culmorum, M.nivale, F.avenaceum and
F.graminearum & F. poae

–These fungi form a complex of diseases on
seeds, seedlings and adult plants.

–The seed-borne pathogen Microdochium
nivale (formally known as Fusarium nivale) is
also usually included in this group of fungi.
 Fusarium
Species
Fusarium avenaceum,
F. culmorum, F.
Seedling blight graminearum, F. poae,
Microdochium nivale

Consequences
Foot rot Yield loss
Loss in grain quality

Diseased

Head blight
(FHB) Mycotoxin contamination
Healthy
 Fusarium disease complex

Seedling blight

Head blight
(FHB)

Foot rot
 Symptoms
The most common symptom of a serious attack of Fusarium
is very poor plant establishment, i.e a very thin crop.

This occurs because of pre-emergence
and post-emergence seedling blights -
the most important phase of the disease.

Root rotting, brown foot rot and leaf blotching
(usually following some other form of damage),
glume blotch and ear blights can all be caused by
these fungi.
 Severe foot rot, usually affecting plants under stress
(especially moisture stress) can result in premature
ripening and whiteheads'.
What is a mycotoxin?
A mycotoxin is a toxic secondary metabolite produced certain fungi.

Mycotoxins are poisonous chemical compounds produced by certain
fungi

“ The term 'mycotoxin' is usually reserved for the toxic chemical
products produced by fungi that readily colonize crops”.

DON
 TABLE 1. MYCOTOXINS IN GRAINS AND SEEDS.
Mycotoxin Commodity Fungal source(s) Effects of ingestion
Fusarium graminearum Human toxicoses India,
wheat, maize, barley Fusarium crookwellense China, Japan, and Korea.
deoxynivalenol/nivalenol
reported from Toxic to animals, especially
Fusarium culmorum
pigs
zearalenone maize, wheat F. graminearum Identified by the
F. culmorum International Agency for
F. crookwellense Research on Cancer
(IARC) as a possible
human carcinogen. Affects
reproductive system in
female pigs
ochratoxin A barley, wheat, and many Aspergillus ochraceus Suspected by IARC as
other commodities Penicillium verrucosum human carcinogen.
Carcinogenic in laboratory
animals and pigs

fumonisin B1 maize Fusarium moniliforme plus Suspected by IARC as
several less common human carcinogen. Toxic to
species pigs and poultry. Cause of
equine
eucoencephalomalacia
(ELEM), a fatal disease of
horses
Aflatoxin B1, and naturally
occurring mixtures of
aflatoxins, identified as
maize, peanuts, and many
aflatoxin B1, B2 Aspergillus flavus potent human carcinogens
other commodities
by IARC. Adverse effects in
various animals, especially
chickens
Trichothecene Mycotoxins

Deoxynivalenol (DON)
DON

Adverse effect on
Human & Animal Health
Plant Health

Inhibitors of protein synthesis
What range of mycotoxin producing
Fusarium species do we have in
Ireland?
DNA-based detection of Fusarium species
and GC-MS-based detection of mycotoxins

– M. nivale
– F. avenaceum (enniatins, beauvericin,
moniliformin)
– F. graminearum (trichothecenes,
DON zearalenone)
– F. culmorum (trichothecenes,
zearalenone)
– F. poae (trichothecenes)
 Legislation imposes a limit for the level of certain
mycotoxins in grain
e.g. DON for human consumption of 1250ppb

The presence of Fusariun ear blight is not a good
indication of likely mycotoxin risk in cereal crops

DON
 Seedling blight is a fungal infection that
causes the seed or seedling to rot and die. Seedling Blight
Seedlings are attacked before or shortly
after emergence

There may be brown spots on the
coleoptile, roots

It can be characterized by patches in
the field that fail to germinate. If the
seedlings do manage to germinate, they
may not emerge, or they may emerge
and then become brown, pinched, and
die.
 Other symptoms include stunted and yellow growth, or reduced
root growth with brown spots on the roots and coleoptile

There are many fungi present in the soil that can cause seedling
death. Among these fungi are Pythium spp., Fusarium spp., and
Rhizoctonia spp. Most infection is soil borne, but it can also be seed
borne.

M. nivale is the primary pathogen in the
fusarium group which causes seedling blight
resulting in seedling death and thinning of the
plant stand..
 Life Cycle
The most important source of Microdochium nivale for wheat crops is the
seed.

In seasons where weather conditions are wet during flowering and grain
formation, ear infection is common and can result in very high levels of seed-
borne infection.

In such seasons seed-borne infection can pose a serious threat to crop
establishment unless seed is treated to control the disease.

Many true Fusarium species are common in soil but these play little part in
seedling blight.

Most have competitive saprophytic abilities which allow them to colonise
debris and stubble in soil and they play a part in Fusarium foot rot and
Fusarium ear diseases.
 Fusarium complex
The most important source of Fusarium for wheat crops is the
seed but the fungus can also survive on debris in the soil.

In seasons where weather conditions are wet during
flowering and grain formation, spores are splashed from lower
in the canopy causing earblights and seed-borne infection.

In such seasons seed-borne infection can pose a serious
threat to crop establishment unless seed is treated to control
Fusarium.

All the cereal Fusarium species are common in soil.

Most have competitive saprophytic abilities which allow
them to colonise debris and stubble in soil. Volunteers may
also act as a source of inoculums.
 Economic Importance
Disease development:
Spores in the soil infect the growing roots and crowns and
cause a discrete lesion or discoloured infected spot.

The more spores there are in the soil the more lesions will
appear.

When many lesions are present on the crown and root system,
the plant is weakened and yield reduced.

New infections continue to arise throughout the growing
season, so that crown roots and side tillers also become
infected. These lesions can lead to complete decay of the
root system.
 Control

Because the fungus is present within the seed coat, rather than
as a superficial contaminant on the seed surface, seed-borne
infection is not easily controlled by surface-acting fungicides.
Despite this, fungicides are used to give acceptable control.

Fungicides applied for the control of other diseases can give
good control of stem base Fusarium infection.

Cultural control
 Foot & root rot diseases
Fusarium foot rot complex - F.culmorum,
F.avenaceum and F.graminearum, F. poae &
M.nivale.

Take-all disease - Gaeumannomyces graminis

Sharp eyespot & True eyespot –
Rhizoctonia cerealis
Peudocercosporella herpotrichoides

– Common root rot - Bipolaris sorokiniana
 Gaeumannomyces graminis - Take-All
Take all is a root & foot rot disease of cereals &
grasses caused by the fungus
Gaeumannomyces graminis.

All varieties of wheat and barley are
susceptible.

Usually more destructive on winter crops,
and is favoured by conditions of intensive
production and exacerbated by
monoculture.
–when the same crop is grown year after
year in a site. It survives in the infected
residues of one crop, then invades the
roots of the following crop, progressively
destroying the root system.

In exceptional cases it can kill the whole crop;
hence the name "take-all".
 Take-all
Take-all is a cereal disease that infects the plant's roots,
– blocking the conductive tissue and reducing water uptake.
– Early signs of the disease include stunting and yellowing.

Plants mature earlier, may have fewer tillers and can be recognised
by the characteristic ‘white heads’ that appear within a healthy crop.

The fungus attacks the plant roots at any growth stage, early infections
causing stunting and yellowing.
Affected roots are blackened, sometimes severely. After earing in spring
patches of the crop appear stunted.

In severe attacks the worst affected plants are bleached and
dead even before flowering. These symptoms give rise to an
alternative name for the disease, "whiteheads".

Yield loss levels of 40 to 50 % are often recorded in
severe attacks.
 The disease can affect plants without causing obvious
symptoms.

However, infection can limit root development over
winter, which restricts canopy development and carbohydrate
accumulation. Where infections occur, patches of whiteheads
(bleached ears) may be seen as grain fills.
Early signs
The fungus attacks the plant roots at any growth
stage, early infections causing stunting and
yellowing.

Early signs of the disease include stunting and
yellowing. Large circular patches of premature white
heads are often seen.
 Roots can be seen to be
blackened and rotten and have a
"rat-tail" appearance.
In severe outbreaks the base
of infected plants may also
show blackening.

Affected plants are easy to pull
out of the ground due to poor root
development
Above ground symptoms are seen as
patches of stunted plants and white
heads ("bleached" ears) in mature
plants. White-heads generally contain
small grains or, occasionally, no grain at
all.
Ascospores
Gaeumannomyces graminis - Take-All
 Life cycle:
Take-all survives the winter primarily as mycelium on roots or
stubble debris, volunteer cereals, early autumn-sown crops and
some grass weeds.

Primary infection occurs in autumn from inoculums in the soil.

Secondary (root-to-root) infection occurs mostly in spring and
summer.
The disease spreads from infected seedling roots to developing
crown roots. As the disease progresses during the season, the root
area lost to the disease increases and the ability of the plant to
absorb water and nutrients from the soil declines.
When root rotting is severe plants are unable to absorb water
and nutrients. As a result the plants ripen prematurely, resulting in
white-heads and often poor grain filling.
 Early sown crops are more prone to infection. Take-all survives in
the soil on infected cereal and grass residues. The fungus on these
residues then infects the root tissue of young plants.

Take-all can also form hyphae which spread the disease
through the soil between plants, and for this reason the
disease is often seen in patches.

Disease levels build up where successive cereal crops are
grown or if grass weed control is poor. Grass control in
preceding crops should occur early to give root residues an
adequate chance of breaking down.

Summer rainfall can enhance decomposition of root matter in
the soil provided volunteer weeds are controlled throughout this
period.
Gaeumannomyces graminis - Take-All
 Gaeumannomyces graminis - Take-All
Importance
Take-all survives in the infected residues of one crop then invades the roots of
the following crop, progressively destroying the root system. Potentially the most
damaging wheat disease and, at its most severe, can result in no harvestable
grain, hence the name “take-all”.

Take-all is arguably the most important disease of wheat,
partly because it cannot be fully controlled chemically and relies on
rotational strategies for control.

Losses of 10-20% are common in second and third wheat crops.

Grain from plants showing whiteheads is usually small and
shrivelled or, in severe attacks, there may be no grain present in the ear.

The disease is usually most severe in the third or fourth
successive cereal crop, but generally declines in
importance in continuous cereals.
 Continuous Wheat Trial

Avatar - 105 JB Diego - 104 KWS Lumos -105

(C =10.6 t/ha/ 4.3 t/ac)
KWS Croft-87 /(C =9.7 t/ha/ 3.9 t/ac) SY Epson - 94
Take-All – What are the consequences?
It reduces yield by blocking water and nutrient uptake in
infected roots. Severity depends on weather and other factors
including soil type.

Phases of infection
– Primary infection occurs in autumn from inoculum
in the soil. There is usually very little inoculum after a non-susceptible crop,
– Secondary (root-to-root) infection occurs mostly in
spring and summer. The disease spreads from infected seedling roots to
developing crown roots. High levels of primary infection lead to increased
secondary infection, especially when soils are warm and moist.
Affected plants have
black lesions on roots.
 Importance

Take-all is a serious soil-borne disease of cereals.

It is estimated thathalf of UK wheat crops are affected and that they
suffer averageyield losses of 5–20%.

More than half of the crop can be lost when disease is severe.

The cost to farmers is estimated to be up to £60 million a year.

The take-all fungus, Gaeumannomyces graminis var. tritici, infects
winter wheat roots (also barley, rye and triticale but not oats) in the
autumn. Another strain of the fungus, var. avenae, affects oats as
well as other cereals but is currently very rare.
 Factors influencing take-all
Environmental
Weather
Regional differences in take-all relate to weather, soil
type and cropping systems.

Soil type
Crops on light soils (sand, sandy loams and loams),where the
fungus spreads more easily, tend to have most disease.

Management:
Crop rotation
A well-managed one-year break normally controls take-all in a following cereal.
Cultivations
Ploughing - buries most of the take-all inoculum, which is in the top 10cm of
soil at harvest, and brings less infective soil to the surface.
Min-till - of first wheat stubble leaves highly
infective soil near the surface allowing a second
wheat to be infected more rapidly but has the
advantage that it leaves a firmer seedbed than
ploughing.
Volunteer cereals and grass weeds:
Cereal volunteers carry the take-all fungus through break crops.
In first wheats the risk of take-all increases in
proportion to the density of volunteers or weeds.

Varieties:

Drilling date:
Take-all inoculum starts to decrease soon after harvest. Therefore, risk to the
next crop decreases.

Seed rate:
Take-all can develop more quickly and become more severe at higher seed
rates, which allow more primary and secondary infection because of greater
root density. Reducing seed rates can increase yield where take-all is severe but
this may not be practical with later-sown at-risk crops.
Crop nutrition:
Maintaining correct nutrition is important in minimising take-all and its effects;
deficiency of any nutrient should be avoided.

Seed treatment fungicides: can help reduce the
effect in conjunction with cultural control methods.
 Control

Treat seed with seed treatment

Avoid sowing into previous grass-based ground

Utilise rotations to avoid growing consecutive cereal
crops
 Foot & root rot diseases
Fusarium foot rot complex - F.culmorum,
F.avenaceum and F.graminearum, F. poae &
M.nivale.

Take-all disease - Gaeumannomyces graminis

Sharp eyespot & True eyespot –
Rhizoctonia cerealis
Peudocercosporella herpotrichoides

Common root rot - Bipolaris sorokiniana
Sharp eye spot - Rhizoctonia cerealis

Sharp eyespot of wheat is caused by the
soil-borne fungus Rhizoctonia cerealis.

The name "sharp eyespot" comes from the
characteristic symptoms that occur on the
lower wheat stems.

Rhizoctonia cerealis produces no spores
but has mycelium branching at right angles
 Symptoms
Sharply defined lesions on the outer leaf
sheaths.

Young lesions have a sharply defined
dark margin and frequently have
shredding of the epidermis within the
lesion.

Later in the season lesions on the stem have a pale cream
centre with a dark brown, sharply defined edge. Sharp eyespot
lesions are often superficial, but severe sharp eyespot is not
uncommon and can cause whiteheads or lodging.
Eyespot reduces yield and grain quality by restricting
water and nutrient uptake.

Yield losses may be large 10-30 %

Severe eyespot can cause lodging from weakened
stems.
 Rhizoctonia cerealis – Life cycle

The fungus overwinters primarily as mycelium on infected stubble
with volunteers and some grass weeds acting as sources
of inoculum.

Rhizoctonia cerealis produces no spores, but lives on
crop residues and in the soil as mycelium and as small
resistant structures called sclerotia.

This fungus differentiates into hardened mycelial masses or
sclerotia, on host plants and in culture. The sclerotia, which
are very small and irregular in shape, germinate to form
mycelia.
 Rhizoctonia cerealis is the name given to the asexual state of this
fungus, characterized by white to brown mycelium, the presence
of sclerotia and the absence of spores.

The damage due to infection by Rhizoctonia cerealis is very
dependent on environment.

Observations indicate that wet, cold conditions favor disease
development.

Infections are most serious when they are initiated on
seedlings. Seedlings may be killed out right, but most survive
through the growing season some of which then die before
maturity and produce white heads.
Rhizoctonia cerealis – Life cycle
 The fungus overwinters primarily as mycelium on infected stubble with volunteers
and some grass weeds acting as sources of inoculum.

The fungus can also produce sclerotia which may act as overwintering structures.
Infection may occur at any time during the growing season, but the disease is
favoured by temperatures of around 9OC. Dry and sandy soils and early sowing favour
the disease. Cool autumn or spring temperatures may result in early infection by the
fungus which can lead to severe disease.

Rhizoctonia cerealis produces no spores, but lives on crop residues and in the soil as
mycelium and as small resistant structures called sclerotia.

This fungus differentiates into hardened mycelial masses or sclerotia, on host plants
and in culture.

The sclerotia, which are very small and irregular in shape, germinate to form mycelia.
 Rhizoctonia cerealis is the name given to the asexual state of this fungus, characterized
by white to brown mycelium, the presence of sclerotia and the absence of spores. This
fungus has been found to have a sexual stage, known as Ceratobasidium, but the
Ceratobasidium stage is not important in the disease cycle.

While Rhizoctonia cerealis is common in the soil and on host debris as mycelium and
sclerotia, the damage due to infection is very dependent on environment.

The exact conditions under which the disease is important have not been determined,
but observations indicate that protracted wet, cold conditions favour disease
development.

Infections are most serious when they are initiated on seedlings. Seedlings may be
killed out right, but most survive through the growing season some of which then die
before maturity and produce white heads.
 Importance

Sharp eyespot is of little economic importance.

Infections are most serious when they are initiated on seedlings.

Seedlings may be killed out right, but most survive through the
growing season some of which then die before maturity and
produce white heads.
 Control
Because sharp eyespot is of little economic importance, no
specific recommendations are made for its control.

Management practices which favor good, vigorous growth of
the wheat plant generally limit damage due to sharp eyespot.

Proper seed bed preparation, good soil drainage, balanced
fertility and crop rotation are considered most important.
 Foot & root rot diseases
Fusarium foot rot complex - F.culmorum,
F.avenaceum and F.graminearum, F. poae & M.nivale.

Take-all disease - Gaeumannomyces graminis

Sharp eyespot & True eyespot –
Rhizoctonia cerealis
Peudocercosporella herpotrichoides

Common root rot - Bipolaris sorokiniana
 True eyespot - Peudocercosporella herpotrichoides

Eyespot is an important fungal disease
caused by the fungus
Pseudocercosporella herpotrichoides W-
type [anamorph - asexual])
and Pseudocercosporella herpotrichoides
R-type.

It is also called

It is more severe where the wheat is grown continuously and the
weather is cool and moist.

It can reduce the yield up to 40%.
 True eyespot - Peudocercosporella herpotrichoides

Eyespot is one of a number of diseases
that can affect the stem base of
cereals.

Under Irish conditions, true
eyespot is the most damaging of
these stem base diseases, and
potentially the biggest yield robber

The host range of eyespot includes wheat, barley,
oats, rye and many grass species, but it is most
damaging on winter and spring wheat and winter
barley.
 Symptoms
Early symptoms can be confused with
sharp eyespot and Fusarium spp.
Frequently all that is visible is a brown
smudge on the leaf sheath at the
stem-base.
If crops are early-sown
eyespot lesions may penetrate one or
two leaf sheaths, making identification
more conclusive.

Later in the season eyespot
symptoms become more distinct
and appear as an eye-shaped
lesion with a dark margin, usually
below the first node. Later still, the
margin of the eyespot lesion is
often dark and diffuse with a
central black 'pupil' occasionally
visible.
Colonisation of the stem by the eyespot fungus weakens
the stem and can cause lodging, which is the most obvious
and serious consequence of severe eyespot.
 In severe attacks of
eyespot,whiteheads
("bleached" ears) are
commonly seen scattered
through the crop, later in
the season these may
become colonized by
sooty moulds.
Flattened Crops - evidence of poor
eyespot control in the past.
Lesions usually
occur below the
first node and at
GS 31/32 it is difficult to
identify
clear symptoms.
Lesions are often
indistinct and
usually consist of
a brown, smudgy
lesion
In the eyespot
lesion the fungus
grows inside the
plant and stem
tissues and clogs
up the plant 's
plumbing system.
This disrupts the
flow of nutrients
and water to the
plant and reduces
yield.
 True eyespot disease

There are two fungi involved in the eyespot disease.
Pseudocercosporella herpotrichoides W-type (Tapesia
Yallundae),
and Pseudocercosporella herpotrichoides R-type (Tapesia acuformis).
R-type (Oculimacula acuformis) and the W-type (O. yallundae).
The W-type was the dominant type until the late 1980s,
at which time there was a shift in the Irish eyespot populations to the
R-type. The reason for the shift is being attributed to the widespread
use of triazoles.

The R-type is still the dominant species and recent work carried out at
Teagasc, Oakpark Calow showed that over 70% of the eyespot isolates
found are of the R-type. It was originally thought that the W-types were
more aggressive and patho-genic than the R-types but recent research
shows that both types are equally damaging.
Life cycle of Peudocercosporella herpotrichoides
The fungus overwinters on infected stubble, volunteers and grass weeds can also act as
sources of inoculum.

It can survive on stubble for as long as 3 years which is why a one year break from
cereals does not necessarily reduce eyespot risk in following crops.

Spores are produced throughout the autumn and winter, posing a threat to early-sown
crops. Infection occurs at temperatures above 5OC and during wet periods. Spores are
rain splashed short distances from infected stubble. The development of symptoms
following infection normally takes 6-8 weeks, depending upon environmental conditions.
Eyespot can be a serious problem in continuous cereals, where inoculum may build up
from year to year.

The sexual stage of both eyespot fungi, play an important part in the pathogen life cycle.
This stage of the fungus is produced on stubble at the end of the season and after
harvest, ascospores may travel long distances and infect emerging or young plants.
 Economic importance
Yield reduction can be 10% to 15% when eyespot is severe.

Colonisation of the stem by the eyespot fungus weakens
the stem and can cause lodging, which is the most obvious
and serious consequence of severe eyespot.

If lodging is widespread, then yield losses can be
greater than 35%.
 Control of True eyespot

The optimum growth stage for controlling the W types is.

Because the R types sporulate slightly later than the W
types, the optimum time to control these is GS 32, which
coincides well with Septoria control measures.

There are major difficulties in deciding whether or not eyespot
control is necessary in a particular crop.

In the UK, treatment is recommended if 20% or more of
–the tillers are affected by eyespot at GS 30/31.
 Control of True eyespot

The only guide that a grower has as to whether or not his crop
is at risk from eyespot is to evaluate thevarious risk factors.

Winter wheat, winter barley and spring wheat are the crops at
greatest risk. If there has not been a two-year non-cereal
break, then the risk is increased.

Early sowing, as well as wet weather in winter and spring, will
increase the chances of infection.

Variety is also important, as there are some differences in
varietal susceptibility.
 Foot & root rot diseases
Fusarium foot rot complex - F.culmorum,
F.avenaceum and F.graminearum, F. poae &
M.nivale.
Take-all disease - Gaeumannomyces graminis
Sharp eyespot & True eyespot –
Rhizoctonia cerealis
Peudocercosporella herpotrichoides

Common root rot - Bipolaris sorokiniana
 Bipolaris sorokiniana – Common Root Rot

Common root rot is caused by the fungus Bipolaris
sorokiniana

Bipolaris sorokiniana is a saprophyte

Hosts include barley, spring wheat, rye, and
weed and grass species.

Wheat and barley are the most
economically important hosts

Common root rot occurs in cereal-
growing areas, and is prevalent in the
warmer cereal-growing regions.
 Symptoms
» Initial symptoms originate on young
seedlings from inoculum carried on
the seed or from infections
originating from soilborne conidia
near the seedling.

»Dark brown lesions appear on
the outer coleoptile tissue and/or
on the leaf base. Lesions may
coalesce into long areas of
necrotic brown tissue.
»In extreme cases, the
entire seedling may die.
In most cases, however,
the seedling will survive
but growth of the
developing plant may
be stunted.
Symptoms
Plants with common root rot
produce fewer tillers and fewer
kernels per ear.

For example grain yield losses
due to common root rot and
seedling blight for Canada,
Scotland, and Brazil have been
estimated at 15, 10, and 20%,
respectively

White heads can result from
plant stress associated with
root disease
 Conidia of Bipolaris
sorokiniana

Conidiophore and conidia of
Bipolaris sorokiniana
Dark lesions on the coleoptile
and leaf bases.

Stunting of seedlings
infected by the
common root rot
organism
Dark fungal conidia and conidiophores of
Bipolaris sorokiniana on leaf blade
Spot blotch on Barley leaves caused by Bipolaris sorokiniana
 Life cycle
Bipolaris sorokiniana is a saprophyte and survives primarily as
thick-walled conidia.

It can also survive as mycelium in soil or crop debris.

The sexual stage (Cochliobolus sativus) is not important in the
disease cycle.

Primary inoculum includes mycelium from infected seed, conidia
in the soil, and conidia on the seed surface.

Conidia germinate in the presence of susceptible hosts and initiate
primary infection on the coleoptile, or primary roots.

B. sorokinana penetrates the host tissue either
directly through the epidermis, or through natural
openings or wounds.
 Appressoria and dome-shaped infection cushions are formed prior to
penetration. Infection pegs form beneath the appressoria and infection
cushions. Infection continues from the epidermis to the cortex and
endodermis, resulting in disintegration of the tissue. Colonization of infected
plant parts progresses by the spread of conidia.

Environmental factors play an important role in the severity of disease
caused by B. sorokinana and other root rot fung.
Warm soil temperatures favor growth of B. sorokinana. Moist
soils during planting promote infection and colonization by
soilborne inoculum as well.

Any movement of soil by wind, water, and implements can move
inoculum of the pathogen. Infested seed can also serve as a means of
dissemination of the pathogen over long distances.

Dissemination of secondary inoculum is not important for continued
disease development below ground, but provides inoculum for
subsequent crops.
 Control of root rot

Seed treatment

Historically, cultural methods, especially crop
rotation, have been important in the control of
eyespot.

The importance of cultural control of eyespot is now
increasing because more non-cereal break crops
are being grown and fungicide use is declining.
 White-head - prematurely ripened ears of cereals often caused by
pathogens attacking the roots or stem base
Lodging - when a standing crop is caused to lean or bend due to
adverse weather or soil conditions
Mycelium - the mass of hyphae forming the body of a fungus
Inoculum - micro-organisms or virus particles which act as a source of
infection
Sclerotia - compact mass of fungal hyphae e.g. ergot, capable of
being dormant for long periods, and giving rise to fruiting bodies or
mycellium
Saprophytic = grow & live on dead organic matter such as fallen
trees, dead leaves, and even dead insects and animals. These fungi
have enzymes that work to "rot" or "digest" the cellulose and lignin
found in the organic matter.
Anamorph - the imperfect or asexual stage of a fungus
Teleomorph - the sexual or so-called perfect growth stage or phase in
fungi
 Take All Shary eyespot Common root
rot
Causal organism

Symptoms

spores
References:

https://cereals.ahdb.org.uk/

AHDH publications

Diseases of Small Grain
Cereal Crops: A Colour
Handbook
By T.D. Murray, David W.
Parry, Nigel D. Cattlin