Influence of pre-infectional and post-infectional nematode resistance mechanisms in crop rotation sequences on population densities of meloidogyne species and soil health

Abstract

Plant-parasitic nematodes inflict economic damages on vegetable and field crops due to a lack of suitable crop protection chemicals and integrated crop management practices. Toxic synthetic chemical nematicides were withdrawn from the agro-chemical markets in 2005 due to their damage to the environment and humans. As such, there is continuous need to develop integrated nematode management strategies that are economic, environment friendly yet capable of effectively controlling the pest to alleviate crop loss and food insecurity. Root-knot (Meloidogyne species) nematodes are a major yield- and quality-reducing pest in most potato (Solanum tuberosum L.) producing regions in South Africa. However, little is known about the different plant-parasitic nematode species that are associated with potato in some Provinces. The sustainable production of crops in the absence of nematode resistant genotypes depends on the availability of nematode resistant crops in crop rotation systems. However, the effectiveness of these nematode resistance crops in managing root-knot nematodes in potato-based cropping systems has not been investigated in South Africa. The aim of the study was the development of sustainable cropping sequences for management of population densities of Meloidogyne species in potato production using crops with different mechanisms of nematode resistance. Two main objectives were investigated, but the second objective was sub-divided into three. The objectives of the study were to investigate (1) whether the diversity and abundance of plant-parasitic nematodes associated with potato in Limpopo Province, would be different to those in other potato-producing regions of South Africa, (2) whether (a) monoculturing potato would have any effects on population densities of Meloidogyne species, plant growth and soil health, (b) sequencing potato with a post-infectional nematode resistant crop like Cucumis africanus would have any effects on population densities of Meloidogyne species, plant growth and soil health and (c) sequencing potato with a pre-infectional nematode resistant crop such as sweet stem sorghum would have any effects on population densities of Meloidogyne species, plant growth and soil health. Ten known nematode genera, namely, Scutellonema, Helicotylenchus, Telotylenchus, Rotylenchulus, Paratylenchus, Tylenchorhynchus, Criconema, Nanidorus, Meloidogyne and Pratylenchus species were present in potato production fields in Limpopo Province, South Africa. The study was conducted on 30 farms, located in Mopani, Sekhukhune, Capricorn, and Waterberg districts by randomly collecting 10 core soil samples per hectare in a zigzag-sampling pattern. A total of eight nematode genera except two (Meloidogyne and Pratylenchus species) were recorded for the first time in potato fields in Limpopo Province. Additionally, the sampled districts were predominated by different nematode species. The Meloidogyne species were the most prevalent nematodes associated with potato crops followed by Helicotylenchus and Scutellonema species. In contrast, the Tylenchorhynchus and Nanidorus species were the least prevalent parasitic nematodes in potato production fields in the Limpopo Province. To achieve Objective 2, two field experiments were conducted at the University of Limpopo (UL) and the Agricultural Research Council-Vegetable and Ornamental Plants (ARC-VOP). In Sequence 1, the treatments (sorghum cv. ʹNdendaneʹ, potato cv. ′Mondial G3′, Cucumis africanus and potato (cv. ′Mondial G3′)-(Velum) were laid out in a randomised complete block design. In Sequence 2, potato (cv. ′Mondial G3′) was cultivated on all plots as the successor main crop. In Sequence 3, the treatments were laid out as in Sequence 1, whereas in Sequence 4 sole potato crop was cultivated as in Sequence 2. Therefore, four cropping sequences namely, sorghum-potato, potato monoculture, C. africanus–potato and potato-(Velum)-potato (control) were investigated simultaneously.Generally, post-infectional resistant C. africanus-potato was more effective than pre-infectional nematode resistant sorghum-potato or potato monoculture cropping sequences in reducing the population densities of Meloidogyne species in the soil. This has led to reduced damage to subsequent potato crop providing higher tuber yield, increased shoot mass and nutrients elements accumulation in potato leaf tissues at both sites. The high soil organic carbon content, microbial diversity and enzyme activity observed in C. africanus-potato and sorghum-potato showed that these two cropping sequences enhanced soil health better than the monoculture production system of potato with or without Velum application. The different indices (maturity index, channel index, enrichment index and structure index) collectively demonstrated that the soil was highly disturbed with bacteria dominated decomposition pathways. The nematode faunal profile showed that sorghum-potato was the only cropping sequence that improved soil structure as exhibited by high structure index. Therefore, the inclusion of nematode resistant sweet stem sorghum in potato-based cropping system promoted soil health better than the other cropping sequences. In conclusion, C. africanus-potato sequence could be used to effectively manage root-knot nematode population densities, whereas sorghum-potato sequence could be considered where the aim is to improve soil health.