4. DiscussionThe dependence on fung

4. Discussion
The dependence on fungicides for controlling banana leaf spot
disease has led to a problem of fungicide resistance. The fungi
Mycosphaerella fijiensis (Smith, 1988) and Mycosphaerella musicola
(Knight et al., 2002) have become resistant to fungicides such as
benimidazoles and strobilurins (azoxystrobin) which were previously
reported as highly effective in suppressing the leaf spot diseases
(Smith, 1988; Knight et al., 2002). Also, overuse of these
fungicides might result in leaving chemical residues in banana
plants and their environments, which will become a serious public
concern. Therefore, for the sustainable banana production, it is
necessary to develop eco-friendly methods, which will reduce
fungicide usage drastically in the management of banana leaf spot
diseases. Among different non-chemical methods of disease management,
the use of natural plant products in controlling plant
diseases is a promising environmentally friendly strategy (Daayf
et al., 1995; Akila et al., 2011). Therefore, in the present study, we
made an attempt to find an effective plant species for the management
of Eumusae leaf spot disease of banana, which is becoming
very serious in different banana growing states of India.
Among 33 plant species screened, the medicinal plant Zimmu
(Interspecific hybrid between Allium cepa
Allium sativum)
showed complete inhibition of mycelial growth and spore germination
at all concentrations tested under in vitro conditions.
Similarly, Satya et al. (2007) reported that the leaf extract of Zimmu
was effective in inhibiting the growth of several agronomically
important fungal and bacterial pathogens including Aspergillus
flavus, Curvularia lunata, Alternaria solani, Xanthomonas oryzae pv.
oryzae, Xanthomonas campestris pv. malvacearum and Xanthomonas
axonopodis pv. citri. Besides, Satya et al. (2005) also reported that
among the plant extracts tested, the leaf extract of Zimmu and
Snake wood (Strychnos nuxvomica Linn.) showed the highest antifungal
activity against R. solani. The crude extract of Eucalyptus
citriodora also inhibited the mycelial growth of R. solani, Sclerotium
rolfsii, Phytophthora spp., Alternaria alternata and Colletotrichum
graminicola (Schwan-Estrada et al., 1998). A possible explanation
for the effective inhibition of mycelial growth of the above said
pathogens by different plant extracts might be due to the presence
of antifungal compounds present in the leaf extracts (Ghosh et al.,
2002; Kagale et al., 2004).
The Zimmu leaf extract, which showed effective inhibition of
pathogen M. eumusae under in vitro conditions, was further evaluated
for its efficacy in suppressing Eumusae leaf spot disease
under field conditions in cv. Grand Naine. The result of the field
study showed that the Zimmu leaf extract sprayed four times at
a 20-day interval at the vegetative stage immediately after the
onset of the disease resulted in 55% reduction of disease severity
under field condition. Besides, the applications also increased the
value of YLS-0 (which indicates the number of green leaves indirectly)
by 60.5% and the yield by 46.8% as compared to untreated
control plants. It is very important to note that the effect of Zimmu
leaf extract in suppressing the leaf spot disease severity and
increasing the number of green leaves was comparable with the
fungicide Propioconazole 25% EC (0.1%) at flowering stage and
slightly better than the fungicide Propioconazole 25% EC (0.1%) for
yield parameters such as the number of fingers and bunch weight.
Several authors have also reported the efficacy of plant products in
reducing the disease severity caused by different pathogens in
different crops. Satya et al. (2007) have also reported that the
application of 10% concentration of Zimmu leaf extract recorded
maximum reduction in the number of lesions (73%) in cotton plants
affected by bacterial blight caused by Xanthomonas campesteris pv.
malvacearum as compared to untreated control plants. Foliar
application of 50 EC formulation of Zimmu extract at 3 ml l1
concentration on 60, 75 and 90 days after sowing significantly
increased the grain hardness and reduced the incidence of grain
mould under field conditions (Karthikeyan et al., 2007). Similarly,
Singh et al. (1995) demonstrated that ajoene, a constituent of garlic
(A. sativum), significantly controlled powdery mildew of pea under
glasshouse conditions. Bowers and Locke (2004) showed that
treatment of soil infested with Phytophthora nicotianae with 10%
aqueous emulsions of pepper extractemustard oil formulation and
cassia extract formulations and synthetic cinnamon oil formulation
significantly reduced the population densities of P. nicotianae and
suppressed Phytophthora blight in Periwinkle up to 96.7% compared
with control.
In order to identify the principle compound present in the
Zimmu leaf extract, the extract was subject to solvent extraction,
purification by TLC followed by GCeMS analysis. From these analyses,
two lipid compounds exhibiting significant effect on the
mycelial growth and spore germination of the pathogen
M. eumusae were purified and the GCeMS analysis of these
compounds indicated the presence of up to six different
components and the further research work on these components
is in progress for the wide use of this plant extract. Muthukumar
et al. (2010) also reported the presence of 22 compounds in
Zimmu leaf extract and opined that among these, the lipid compound
n-Hexadecanoic acid may be responsible for the inhibition
of the growth of test pathogen Pythium aphanidermatum. Conversely,
Satya et al. (2005) reported that the phenolic compounds