African Journal of Biotechnology
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African Journal of Biotechnology Vol. 2 (7), pp. 198–201, July 2003 ISSN 1684-5315 © 2003 Academic Journals
Full Length Research Paper Nodulation and nitrogen fixation of field grown common bean (Phaseolus vulgaris) as influenced by fungicide seed treatment Ndeye
Fatou Diaw GUENE, Adama DIOUF and Mamadou GUEYE*
*Corresponding
author; phone: +221-8493321, fax: +221-8321675; e-mail: Mamadou.Gueye@ird.sn |
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| Abstract | |||||||||||||||||||||||||||||||||||||||||||||||||
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A field
experiment was conducted at Bel Air station, in Dakar using 15N
isotope dilution technique and the non nodulating soybean (Glycine max) variety m129 as reference plant to test the
compatibility of Dichlorofenthion-thiram
(DCT) fungicide to the inoculation of common bean (Phaseolus vulgaris) Paulista variety with both Rhizobium etli
ISRA 353 and R. tropici strain ISRA 554. Nodulation
was not induced with R. etli ISRA 353 and nitrogen fixation did not
occur. With R. tropici ISRA 554,
a decrease in nodulation was observed, but nitrogen fixation was not
significantly different compared to that of the non DCT-treated common
bean. Key words: Common bean, fungicides, isotope dilution, 15N, nitrogen fixation, nodulation, Phaseolus vulgaris, Rhizobium.
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| Introduction | |||||||||||||||||||||||||||||||||||||||||||||||||
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In Senegal, common bean (Phaseolus vulgaris) needs to be inoculated with elite Rhizobium strains in the growing area called Niayes zone (Diouf et al., 1999). Usually, seeds of common bean supplied to farmers are often treated with fungicide to prevent losses due to seed-borne pathogens. Studies on compatibility of rhizobial strains with fungicides are currently controversial. Application of Captan, Pentachloronitrobenzene (Curley and Burton, 1975), and Apron (Rivellin et al., 1993), on soybean (Glycine max) seeds reduced the viability of Bradyrhizobium japonicum by 18, 75 and 61%, respectively, after 1 h exposure. Graham et al. (1980) observed that less than 10% of R. phaseoli strains survived on Thiram-treated seeds of common bean. By contrast, no detrimental effect was found on the compatibility of Apron with R. japonicum applied tosoybean seeds (Diatloff, 1986) or with R. meliloti on alfalfa seeds (Edmisten et al., 1988). Since compatibility between rhizobial inoculants and fungicides has not been so far studied in Senegal, our objective was to examine effect of inoculation of fungicide-treated seeds of a common bean variety, Paulista which is one of the most commonly grown varieties in Senegal, in relationship to growth and grain yield, nodulation and nitrogen fixation.
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| Materials and Methods | |||||||||||||||||||||||||||||||||||||||||||||||||
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A
field experiment was carried out in Dakar, at Bel-Air experimental
station. The soil was a sandy type (94% of sand) containing approximately
100 native Rhizobium/g, counted
by infection test method (Brockwell, 1982; Vincent,
1970) using common
bean seedlings. The pH of the soil was 7.0 with 0.025% nitrogen (Bremner, 1965), and 40 ppm available phosphorus (Olsen et al.,
1954). The seeds of
common bean variety, Paulista, and that of non nodulating soybean variety
m129 used as non-fixing control plant were hand sown in a randomised
completed bloc design with four replicates. The size of each plot was 1.35
x 2.55 m, with 15 cm and 45 cm within and between rows respectively. There
were four treatments: (i) seeds of common bean treated with
Dichlorofenthion-thiram(DCT) fungicide and inoculated with R. etli strain
ISRA 353 (Diouf et al., 2000); (ii) seeds of common bean non treated with
DCT and inoculated with R. etli strain ISRA 353; (iii) seeds of
common bean treated with DCT and inoculated with R. tropici strain
ISRA 554 (Diouf et al., 2000); (iv) seeds of common bean non-treated with
DCT and inoculated with R. tropici strain ISRA 554. Rhizobial
inoculants were applied as peat slurry containing 107 Rhizobium/g.
The rhizobial strains ISRA 353 and ISRA 554 were selected at MIRCEN
rhizobial culture collection for their high nitrogen fixing potential in
association with common bean (Guene, 2002). Within each plot, a 0.60 X
0.45 m microplot was delimitated for the application of 15N-labelled
fertilizer solution, (15NH4)2SO4
containing 5 atom % 15N excess to supply 20 kg N ha-1.
Unlabelled (NH4)2SO4 was applied at the
same rate to the remaining plots. To all plots a basal fertilizer was
added and consisted of 60 kg P ha-1 as a triple superphosphate
and 120 kg K ha-1 as KCl. At
60 days after sowing, all plants were harvested from the microplots. The
harvested plants were separated into different parts. Nitrogen content
(%N) and atom % 15N excess (%15Nae) for individual
plant part were determined at the laboratory of soil biochemistry in
ISRA-IRD centre of Dakar, Bel Air. Nitrogen fixation (%Ndfa) was estimated
using the isotope dilution equation (Fried and Middelboe, 1977):
Data
were statistically analysed using the Newman and Keuls test. |
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| Results | |||||||||||||||||||||||||||||||||||||||||||||||||
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Use of Rhizobium strain ISRA 353 That the seeds were treated or not with the DCT, there were a good vegetative development of the plants and a good production of pods. There was however no significant difference on shoot dry weight and pod yield between the plants from DCT-treated seeds and that from non DCT-treated seeds. Averaged shoot dry weight and pod yield were 1.3 Mg ha-1 and 1.2 Mg ha-1 respectively (Table 1). On the other hand, no nodule was found on the roots of plants derived from DCT-treated seeds. Consequently nitrogen fixation did not occur in these plants, whereas average of 31.5 mg plant-1 of dry nodules recorded on the plants derived from non DCT-treated seeds (Table 1) resulted in 18 and 35% as the proportion of nitrogen derived from fixation (%Ndfa) in the shoot and in the pods, respectively. Corresponding amounts of nitrogen derived from fixation (Ndfa) were 6 kg N ha-1 and 15.4 kg N ha-1 (Table 2). Table 1. Shoot (SDW) and nodule (Nod. DW) dry weights and pod yield of field grown common bean (P. vulgaris) Paulista variety cultivated at Bel Air experimental station, inoculated with Rhizobium strains ISRA 353 and ISRA 554 and treated with Dichlorofenthion-thiram (DCT) fungicide.
In each column, for each Rhizobium strain, values followed by the same letter do not differ significant at p = 0.05
Use
of Rhizobium strain ISRA 554 The plants
were also well developed. No significant difference was observed on the
shoot dry weight between plants from treated and non DCT-treated seeds
with an average of 2.45 Mg/ha. The pod yield was however decreased
(-19.7%) by treating the seeds with DCT (Table 1). Although
nodulation of plants was not inhibited by the DCT, nodules dry weight was
decreased in the plants from DCT-treated seeds in comparison to that of
plants from non DCT-treated seeds, 59.2 mg plant-1 vs 86.2 mg
plant-1 (Table 1). No
difference was however observed in both the %Ndfa and Ndfa between the two
treatments: 38.2%
and 18.5 kg N ha-1 respectively in the shoot, 54% and 48.9 kg N
ha-1 in the pods (Table 2).
Table 2. Nitrogen content (%N) and total nitrogen (Total N), atom %15N excess (%15Nae), proportion (%Ndfa) and amount (Ndfa) of nitrogen derived from atmosphere of field grown common bean (P. vulgaris) Paulista variety cultivated at Bel Air experimental station, inoculated with Rhizobium strains ISRA 353 and ISRA 554 and treated with Dichlorofenthion-thiram (DCT) fungicide.
In each
column, for each Rhizobium
strain and for each plant organ, values followed by the same letter do not
differ
significant at p
= 0.05 |
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| Discussion | |||||||||||||||||||||||||||||||||||||||||||||||||
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Organic
fungicides are usually used in agriculture in order to protect seeds to
diseases caused by fungi. The main known fungicides are however toxic to
rhizobia (Diatloff, 1970; Hofer, 1958). In
most cases, the rhizobia remain viable, but are not able to nodulate the
host plants or their ability to fix nitrogen is reduced
(Fisher, 1976; Staphorst and Strijdom, 1976).
DCT is derived from thiram (tetramethyl-thiram-disulphide), one of the
less toxic fungicide to rhizobia. We have tested the compatibility of DCT
to the inoculation of Paulista variety with Rhizobium strains ISRA
353 and ISRA 554. In the first case there is incompatibility: no
nodulation was induced and nitrogen fixation did not occur. In the second
case, there is compatibility with less nodulation, and equivalent fixed
nitrogen compared to that of plants from non DCT-treated seeds. In
addition to the results of Hashem et al. (1997) indicating difference in
compatibility with fungicides between peanut (Arachis hypogaea) and
Bradyrhizobium inoculants, our results reflect and reactualize the
discussion on inoculation of fungicides-treated seeds because the
discrepancy between ISRA 353 and ISRA 554 rhizobial strains may be due to
the difference of Rhizobium species, that is, R etli and R.
tropici. Considerable differences in tolerance among species and
strains of rhizobia to different fungicides have been reported by Tesfai
and Mallik (1986). The
effect of DCT on the nodulation of common bean Paulista variety inoculated
with Rhizobium strain ISRA 353 was similar to that observed with Cicer
arietinum (Thomas and Vyas, 1984; Welty et al., 1988), Glycine max
(Tesfai and Mallik, 1986) and Pigeon pea (Rennie et al.,
1985) treated
with different fungicides. Although effect of fungicide application on the
viability of Rhizobium strains has been already reported by several
authors, the difference in nodulation of the Paulista variety by the Rhizobium
strains ISRA 353 and ISRA 554 as influenced by DCT-treated seeds justify
the necessity to study the variability of effect of fungicides on the
legume–rhizobia symbiosis. Apron fungicide reduces the viability of Bradyrhizobium
japonicum (- 61%) on soybean seeds after 1 h incubation (Revellin et
al. 1993). Similarly, Captan and pentachloronitrobenzene fungicides reduce
the viable B. japonicum, - 18% and - 78% respectively, after 1 h
exposure (Curley and Burton, 1975). Graham et al. (1980) have observed on
Captan-treated seeds that only 10% of Rhizobium phaseoli had
survived after 24 h contact with fungicide whereas 90% of the strains had
survived on the non treated seeds after the same time contact.
Nevertheless developing fungicide-resistant rhizobial strains remains one
approach to overcome this current constraint for delivering inoculants (Tesfai
and Mallik, 1986; Hashem et al., 1997). ACKNOWLEDGEMENTS This research was supported by the FAO/IAEA-RAF project no 5-045. The authors thank Mr. Oumar Toure and Daouda Cisse for their valuable technical assistance and Mrs. Marie Claire DaSilva for performing the statistical analysis. They also gratefully acknowledge the assistance of Mr Saliou Faye and Mrs. Fatou Gueye at the laboratory of soil biochemistry in ISRA-IRD centre of Dakar, Bel Air, for performing the nitrogen and isotopic analyses on plant samples. | ||||||||||||||||||||||||||||||||||||||||||||||||
| References | |||||||||||||||||||||||||||||||||||||||||||||||||
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