Fungal isolates obtained from soils

Fungal isolates obtained from soils of rubber growing areas in
the study exhibited variable inhibitory potentials on mycelial
growth of Rigidoporus lignosus. Significant mycelial inhibition
was recorded in the dual inoculation of fungal antagonists inoculated
24 h before inoculation of R. lignosus. This showed
that fungal antagonists are more effective when they are introduced
before infection takes place. This finding is in line
with earlier study by Jayasuriya & Thennakoon (2007) in which
they indicated that the most effective way to control infection
by white root rot is to identify the infection at a very early
stage and treat accordingly.
Some of the Hypocrea spp used in the study contained anamorphic
state of Trichoderma spp. and are thus taxonomically
related species (CABI Identification Services Report 2010).
Hypocrea jecorina contained the anamorphic state, Trichoderma
reesei E.G. Simmons.; Hypocrea virens contained the anamorphic
state Trichoderma virens.; Hypocrea lixii contained the anamorphic
state Trichoderma harzianum Rifai. (CABI Identification
Services Report 2010). Report in the study agreed with earlier
findings that Trichoderma species are fungitoxic in the management
of R. lignosus (Osando & Waudo 1994; Jayasuriya &
Deacon 1995; Kaewchai et al. 2010). Kaewchai et al. (2010) reported
that Trichoderma hamatum and Trichoderma harzianum
inhibited mycelial growth of R. lignosus over 50 % and rapidly
over grew the pathogen within days. Shaigan et al. (2008) reported
that Trichoderma viridae, T. harzianum, and Trichoderma
longibrachiatum prevented mycelium growth of Sclerotium rolfsii
by 60.8 %, 54.8 %, and 54.4 % respectively. Osando & Waudo
(1994) used various isolates of Trichoderma species to control
Armillaria root rot fungus of tea. In this study, different isolates
of Trichoderma species exhibited different level of antagonism
against Armillaria root rot fungus.
To distinguish differences in the use of fungal antagonists
on R. lignosus, the study was undertaken to approach natural.
Insertion of inoculum created artificial system and greatly enhanced
infection (Nandris et al. 1987).
Effectiveness of fungal antagonists against R. lignosus was
estimated at thetermination of the experiment 150dafter inoculation
which corresponded to the end of the sequence of the
substrate decay (inoculum medium) events (Merrill & Shigo
1979). This study showed that the percentage of Plant death
and Presence of rhizomorph recorded at 2 m after inoculation
for early stage of infection were higher than that recorded at
the termination of 5mexperimental period after inoculation.
All treatments developed rhizomorph at the surface of
their tap roots with significant reduction recorded in the control
at both 60 d and at the termination of 150 d experimental
period. This demonstrated that relationship exhibited between
pathogenicity and the capacity to produce rhizomorph.
Previous works have demonstrated that rhizomorphogenesis
and initial penetration of R. lignosus occur during the first
two months (Nicole et al. 1983; Nandris et al. 1987) after inoculation.
In this study presence of rhizomorph was significantly
higher at 60 d after inoculation compared to that at the termination
of 150 d experimental. This could have been as a result
of the high trophic reserves in the substrate of the inoculum at
the early stage of the experiment.
Seedlings in the H. jecorina treatment were healthier (lowest
plant death, highest length of stem, and length of tap rot,
and least foliar symptom) compared to seedlings in the Negative
control experiment. The H. virens treatment resulted in
healthier seedlings compared to seedlings in R. lignosus control
(plant death, reactional rhizogenesis, root penetration, and foliar
symptoms). At 150 d after inoculation seedlings in the H.
virens treatment were healthier (length of stem, length of tap
root, plant death, and foliar symptom) compared to the seedlings
in the Negative control. Seedlings in the H. jecorina treatment
were healthier than seedlings in the R. lignosus control.
Decline in mortality rate (plant death) from the third
months onward suggests a reduction in fungal activity of R.
lignosus due to exhaustion of trophic reserves in the substrate
of the inoculum. This contributed to the reduction in the presence
of rhizomorph observed at the termination of the experiment
150 d after inoculation. Similar results had been
described in earlier work with rubber seedlings artificially inoculated
by R. lignosus (Nandris et al. 1983). Hypocrea jecorina
compared more to the control (stem length, plant death, and
foliar symptom) 60 d after inoculation; while at 150 d after inoculation,
H. virens compared more to the control.
Some farmers practice biological control without knowing
it. The use of sulphur as soil amendment during planting of
rubber seedling in the field is an indirect biological control
(Cook & Baker 1983). Sulphur is non-fungicidal to R. lignosus
in laboratory tests; the mechanism of control is attributed to
the build-up of antagonists, especially species of Trichoderma
and Penicillium, in sulphur-amended soils due to a reduction
in pH (Ismail & Azaldin 1985).
The use of Hypocrea spp. or Trichoderma spp. as biocontrol
agents in this studyfor themanagement of R. lignosus is encouraged.
Besides pollution of the environment by uses of synthetic
fungicides, there are reports of development of resistance in
pests and diseases (Verheye 2010). Use of biological controls
in plant disease management assumes special significance by
being an ecofriendly and cost effective strategy, which can be
used in integration with each other or other control strategies
for a greater levels of protection with sustained crop yields.