VII. Alps-Adria Scientific WorkshopStara Lesna, Slovakia, 2008
occurrence of soil and plant nematodes in soybean under cereal rotation
Marija IVEZIĆ1 –Ivana MAJIĆ1 –MarijaVRATARIĆ 2– Emilija RASPUDIĆ1 – Mirjana BRMEŽ 1
1Department of Plant Protection, Faculty of Agriculture, J.J.StrossmayerUniversity of Osijek,
Trg Sv. Trojstva 3, Osijek, Croatia,
2 Agricultural Institute Osijek
Abstract: Nematodes are widely distributed in soil and directly under environmental and anthropogenic influences. The objectives of this study were to determine thepopulation fluctuation of five trophic groups for two vegetation periods (2005 and 2006)and to observe the differences between the same trophic groups compared by month between the years. Soil samples were takentwice in soybean vegetative growth stage and once in reproductive growth stage on 7 cultivars. Total of 39 nematode genus were identified. The most dominant genus in trophic groups were: Pratylenchus, Aphelenchoides, Rhabditis, Dorylaimus and Mononchus.The population fluctuation differed for all trophic groups depending on the month and the year. Significant differencesbetween the years were found among the same trophic groupsdepending on the month whileall groupsexcept plant parasites significantly differed in October. The significant difference between the years of total populatuin of nematodes occured in June and October. Overall, plant parasites increased population in both years indicating soybean as good host plant while the environmental and human factor probably was the most important influencing factor for the other trophic groups.
Keywords:nematode structure, trophic group, plant parsites, soybean
Introduction
Nematodes represent an important part of the soil microfauna and directly are affected by environmental and anthropogenic disturbances. According to their feeding strategy, nematodes could be classified into five the most important trophic groups: plant parasites (PP), bacterial (BF) and fungal feeders (FF), omnivores (OM) and predators (PR) (Yeates et al., 1993).Nematodes can be used as bioindicators of conservation or disturbance, nutrient enrichment and pollution of soils this is particulary important role since environmental concerns are rising (Beres and Husti, 2006; Dobo et al., 2006; Várallyay, 2006; Brmez et al., 2007).In response to a human intervention, the structure of nematode comunity becomes dominated by bacterivores however increase in numbers of fungivores indicates association of FF with fungal root degradation in soil (Berkelmans et al., 2003).Soybean (Glycine max L. Merr.) is a globally important oilseed crop and source of high quality protein and among the various constraints, plant parasitic nematodes pose treat to demanding high yield production (Sikora and Greco, 1990; Sudaric et al., 2007).Use of soybean resistant cultivars has been exploited successfully to control to the most important nematodes of soybean Meloidogyne spp. (root-knot nematode) and Heterodera spp. (cyst nematode). However resistant cultivars are still not released for the second most important plant parasitic genus, Pratylenchus spp.(root lesion nematode)which proved to be pathogenic to soybean, since it has suppressed yields up to about 31% (Schmitt and Barker, 1981).The objectives of this study were to determinethe population fluctuation of nematode trophic groups in soybean for two vegetation periods (2005 and 2006). Furthermore, to determine the differences between the same trophic groups compared by month between the years.
Materials and methods
The research was conducted in 2005 and 2006 at the Agricultural Insitute Osijek, Croatiaand set as randomized complete block design.Soil samples were collected in four replicateson fields (3.5 ha) planted with 7 soybean cultivars.The sampling was done in June and July in soybean vegetative growth stagesand in October during the reproductive growth stage.The climate of this region in 2005 was characterized in excess of rainfall during early vegetation period and very dry in October, while in 2006 precipitation was normal to dry. The type of soil was hypogley hydromeliorated soil (pH 6-6.5; humus 2.2%; 27.4 mg K2O 100 gsoil-1; 18.4 mg P2O5 100 g soil-1). The research fields in 2005 and 2006 were rotated with cereals for two years prior to soybean planting. Extraction of nematodes from soilwas processed following the Erlenmeyer method (Seinhorst, 1955). Nematodes were identified to the genus level according to Bongers (1994) and classified into the trophic groups after Yeates et al.(1993).The data of nematode population were log10 transformed and subjected to the Duncan’s multiple range tests (P < 0.05).The differences between the population of thesame trophic groups by the month and by the year were tested by the analysis of variance using the GLM procedure of SAS (SAS Institute Inc., 2000).
Results and discussion
In 168 analyses of soil samples, 39 genus of nematodes were identified and classified into five trophic groups. Their population fluctuation is showed in Fig 1. and Fig. 2. The PP appeared as the most dominant group present in 2005 while BF was the most dominant in 2006. In October 2005 and 2006, the population of plant parasites (PP) reached the highest peak.This coud indicate that the same conditions that favor soybean growth are also favorable for PP development. The genus Pratylenchus was the most dominant in all soil samples for two years and should be monitored continuously in order to prevent possible yield losses(Schmitt and Barker, 1981).
Figure 1. Population fluctuation of five trophic groups in 2005
The population of BF, with the most abundant genus Rhabditis peaked in October indicating their association with environmental factors and anthropogenic influence (Brmez et al., 2007). As opposed to the PP and BF, the final population of FF and OM in October decreased if compared to the initial population in June 2005 and 2006. Decline might be associated to the low fungal degradation of root tissues prior the harvest for FF (Gomes et al., 2002) and the possibility of human intervention in the field prior to the sampling since dorylaimidsare sensitive to agricultural practices (Brmez et al., 2006). Nematodes from genus Aphelenchoides comprised the major group of FF while Dorylaimus was the most dominant genus amon OM. The PR (Mononchus as the most dominant genus) population levels were low and stable for the whole vegetation period, except for peak in October 2005.
Figure 2.Population fluctuation of five trophic groups in 2006
Significant differences were found in October between the same trophic group between the years for population of all trophic groups except PP (Tab. 1).
Table 1.Comparisons of the same trophic group and total population of nematodes between the months and the years
Trophic group / June / July / October2005 / 2006 / 2005 / 2006 / 2005 / 2006
PP / 1.65a / 1.69a / 1.48a / 1.79b / 1.98a / 1.97a
FF / 1.40a / 1.09a / 0.98a / 0.78a / 0.91a / 0.47b
BF / 2.10a / 1.60b / 1.64a / 1.44b / 2.32a / 1.60b
OM / 1.17a / 1.41a / 1.19a / 1.24a / 0.76a / 1.06b
PR / 0.36a / 0.10b / 0.05a / 0.09a / 0.68a / 0.09b
TOTAL / 2.39a / 2.18b / 2.10a / 2.10a / 2.56a / 2.29b
*PP – Plant parasites; FF – Fungal feeders; BF – Bacterial feeders; OM – Omnivores; PR – Predators; Row values within column followed by the same letter are not significantly different as determined by Duncan’s multiple range test (P > 0.05)
Population of BF was significantly different in all months between two years and this might be due to agricultural practices and due to different soil humidity between the years since it was very dry period in October 2005 while in the same period 2006 precipitation was normal. The significant difference between the years was found in July for PP, when it was extremely wet in 2005 while in 2006it was dry period. Since, PP are associated with plant growth,here it might indicate that plants could have been under drought stress in 2005 and weaken their natural plant defense mechanism that enabled PP to feed and reproduce intensively. In addition, increase of PP during the vegetation period suggests susceptibility of soybean to the most dominant group of PP.Total number ofnematodes significantly differed between the years in June and October when population of nematodes were higher in 2005 compared to the same period in 2006.
Conclusions
Since the population of PP had an increasing tendency towards the end of vegetation and their reproductive ratio (population final/population initial) was positive it suggests that soybean cultivars have been good host plant to the most dominant PP genus Pratylenchus. Environmental effect as well as human intervention in the fields might be the most important factor influencing population of other trophic groups but it remains speculative since these effects were not studied in this research.
Acknowledgements
This research was conducted within the project financed by the Ministry of Science, Education and Sport of Republic of Croatia.
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DOI: 10.1556/CRC.36.2008.Suppl.1