This study was conducted to examine

This study was conducted to examine the integration between some microorganisms which known to
have potential as biocontrol agents against nematodes, bionematicides (containing egg-parasitic fungi,
Paecilomyces lilacinus and rhizobacteria, Bacillus subtilis) and biofertilizers (containing phosphate solubilizing
fungus VAM, Glomus fasciculatum; N2-fixing bacteria, Azospirillium sp. and Azotobacter sp. and the
potassium solubilizing bacteria, Bacillus circulanes) to manage potato production grown in field naturally
infested with Meloidogyne arenaria.
Materials and Methods
This experiment was conducted to manage potato production crop cv. Diamond grown in the
Research Station of National Research Centre in Nubaryia, Beheira governorate in field naturally infested with
Meloidogyne arenaria using an integration between some biocontrol agents and biofertilizers as mentioned in
Table (1). The experimental field was divided into plots each comprises rows of 15 m long and 75cm apart and
the distance between plants was 50cm. The experiment was set up in a completely randomized block design
with four treatments and 90 replicates (plants) for each one. The cattle manure was incorporated to soil before
planting potato eyes with leaving one row without addition in each plot to serve as control, all plots were
irrigated immediately. Two weeks later potato eyes were treated by each of the biocontrol and biofertilizer
products as seed dressing as labeled for potato cultivation and planted in hills at 50cm apart. Meloidogyne
arenaria second stage juveniles (J2) initial soil population was determined prior to incorporation the cattle
manure and at harvest time from each treatment. Nematodes were extracted from 200g soil according to Barker
(1985). 1 g roots from each treatment was incubated in water for one week according to Young (1954).Four
months later at harvest time five plants chosen at random from every row were carefully uprooted and potato
tubers were hand-harvested and yield was determined for each treatment. The following data were recorded,
number of root galls, egg masses, females as well as the hatched M. arenaria J2/1g roots. The final nematode
populations were expressed as nematodes/kg soil. Data were subjected to analyses of variance and means were
tested statistically. Percentage nematode reduction in soil was determined according to Handerson and Tilton
formula (Puntener, 1981) as follows:
Nematode reduction (%) = [1-( PCA
PCB X
PTB
PTA
)] X 100
Where:
PTA= Population in the treated plot after application,
PTB= Population in the treated plot before application,
PCB= Population in the check plot before application and
PCA= Population in the check plot after application.
Table 1: List of commercial bioproducts used in controlling Meloidogyne arenaria infesting potato cv. Diamond under field conditions.
No. Commercial Name Bioagents Source Rates/Concentrations
1 Stanes Symbion VAM plus Glomus fasciculatum Gaara Company 15g/plant 2x102 infective propagates
2 Nitrobein Azospirillium sp.
+ Azoobacter sp
Agric. Res. Centre, Giza,
Egypt
300g/ treatment
3 Potassiumag Bacillus circulanes Agric. Res. Centre, Giza,
Egypt
5L/600L water /feddan
4 Stanes Sting Bacillus subtilis Gaara Company 1x109 cells/1ml
5 Stanes Bionematone Paecilomyces lilacinus Gaara Company 1x109 cfu/1ml
1L/500L Water/feddan
Results and Discussion
In general, our results revealed a promising effect of the tested treatments in reducing final population of M.
arenaria J2 in soil and improving potato yield production by different rates, as compared with the untreated
control treatment (Tables 2&3).
Data showed that application of the three biofertlizers (Stanes Symbion VAM plus, Nitrobien and
Potassiumag induced a significant reduction in final nematode population up to 48.8% and increased potato
yield by 20.5% as compared to untreated control (Table 2). These are in accordance with results obtained by
Bagyaraj et al. (1979) who stated that Glomus intraradices has the potential to improve plant growth of
nematode-infected plants by reducing nematode multiplication and altering physiology of the roots, including
the exudates responsible for chemotactic attraction of nematodes and offset yield loss normally caused by them.
Increasing the uptake of phosphorous and other nutrients leading to improvement of plant vigor growth as
reported by Hussey and Roncadori (1982). Kirkpatrick et al. (1964) reported that the greater availability of
Middle East J. Agric. Res., 4(1): 37-41,2015
39
phosphorus made the host plant strong enough to tolerate pathogen attack and also phosphorus itself played a
vital role in building self defense of plants against nematodes. Cohen (1980) found that both dry weight and
nitrogen contents in corn increased by 50-100% when corn seeds were inoculated with Azospirillium sp. before
planting. Data in Table (2) also, showed that the highest percentage decrease in nematode soil population 83.4%
was associated with the application of biofertilizers plus B. subtilis and improved potato yield by 60.1%, as
compared to untreated control treatment. Such findings are in agreement with that of Vasudeva et al. (1958)
who found that B. subtilis was able to produce the antibiotic bulbiformin which directly affected nematodes and
that of Brodbent et al. (1977) who reported that, the use of B. subtilis improve plant growth by suppressing
parasitic root pathogens or by the production of biologically active substances and transform the unavailable
mineral and organic compounds in forms available to plants. Also, (Lin et al., 2005, Dawar et al., 2008 and
Aranjo and Marchest, 2009) stated that application of Bacillus spp. significantly reduced larval hatching and
reproduction of Meloidogyne javanica and promoted the growth of tomato plants. Good biocontrol was also
achieved in tomato plants by B. subtilis with over 60% reduction in numbers of galls and over 70% reduction in
numbers of eggmasses (Adam et al., 2014).Other protocols including B. subtilis with soil fertilizers such as cow
manure showed significant protection of Phaseolus vulgaris against root knot nematode. The gall index was
found to be 1.6 in the combination treatment compared with 4.5 in the control group (Wepuhkhulu et al., 2011).
Table 2: Effects of some biocontrol and biofertilizer products against Meloidogyne arenaria infecting potato cv. Diamond and yield
production under field conditions.
Treatments Initial J2/1kg
soil
Final
J2/1kg soil
% Red. Potato yield
Ton /Feddan
% inc.
Control 3740 3682a* - 3.7 c* -
Cattle manure + biofertilizers(Stanes Symbion VAM
plus +Nitrobein+Potassiumag) 2180 1098 b 48.8 4.5 bc 20.5
Cattle manure+ biofertilizers(Stanes Symbion VAM
plus +Nitrobein +Potassiumag) +Stanes Sting 1950 318 b 83.4 6.0 ab 60.1
Cattle manure + biofertilizers(Stanes Symbion VAM
plus +Nitrobein +Potassiumag)+Stanes Bionematone 2052 843 b 58.3 6.3 a 68.7
*The mean difference is significant at 0.05 level according to Duncan’s Multiple Range Test.
% decrease according to Handerson and Tilton formula (Puntener, 1981).
Table 3: Effects of some biocontrol and biofertilizer products on Meloidogyne arenaria J2, root galls, egg masses and females in 1g root of
potato cv. Diamond under field conditions.
Treatments
No. of
M. arenaria
J2/ 1g root
%
Red.
No. of
galls /
1g root
%
Red.
No. of
egg masses
/ 1g root
%
Red.
No. of
females /
1g root
%
Red.
Control 4858 -- 193 -- 344 -- 249 --
Cattle manure + biofertilizers (Stanes
Symbion VAM plus +Nitrobein+
Potassiumag)
2304 52.6 92 52.3 94 72.7 96 61.5
Cattle manure+ biofertilizers(Stanes
Symbion VAM plus +Nitrobein +
Potassiumag) + Stanes Sting
1769 63.6 94 51.3 114 66.9 117 53.0
Cattle manure + biofertilizers(Stanes
Symbion VAM plus +Nitrobein +
Potassiumag) +Stanes Bionematone
2747 43.5 37 80.8 43 87.5 54 78.3
Regarding the application of the egg parasitic fungus P. lilacinus plus the biofertilizers, it resulted in 58.3%
reduction in nematode soil population and 68.7% increase in potato production as compared to untreated control
(Table 2). Also, this combination (fungus and biofertilizers) recorded the highest percentages reduction, 80.8,
87.5 and 78.3% in the number of root galls, egg masses and females, respectively. While the highest percentage
reduction in hatched J2 was 63.6% achieved by the application of B. subtilis and biofertilizers (Table 3). Jatala et
al. (1980) found that potato plants grown in plots inoculated with fungus P. lilacinus had a significant lower
root galling index than those grown in plots to which organic matter and nematicides had been applied. Also,
Jatala, (1986) suggested that the use of P. lilacinus as a promising and practicable biocontrol agents against
different stages (eggs, juveniles and adult females).
From our results and others previous studies we can conclude that, application of biocontrol agents that
proved potent nematicidal activity in combination with biofertilizers characterized by nitrogen fixation as well
as potassium and phosphorus properties may be a good management of root knot nematode infecting potato
crops. However further researches are recommended to isolate new bioactive races of bacteria and fungus for
optimum integration protocols.