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Racing to the Roots: Soil Moisture Impacts the Speed of Nematodes
September 14, 2022 - Did you know one of the oldest life forms on Earth can be found in your backyard? Soil nematodes have been thriving in habitats around the world for at least 400 million years. Even though they are only 1/500th of an inch wide and 1/20th of an inch long, these worm-like animals are an important part in almost every ecosystem.
Soil nematodes are grouped by what they eat. They can eat a diet of bacteria, fungi, plants, and more. While most nematodes are good for the soil, the nematodes that eat plants are a concern to farmers around the world. These nefarious nematodes are called plant-parasitic nematodes.
Plant-parasitic nematodes are unwelcome guests in agricultural soils. They attack plants at their roots and use the plant as a food source to support their own reproduction and growth. By stealing the plant’s resources to grow and multiply, nematodes cause yellowing, stunting, wilting, and declines in yield.
Understanding the movement of nematodes through the soil is important to helping farmers protect their crops. How fast do they move? How far can they travel? How does soil moisture affect their movement? Answers to these questions could help prevent crop damage and losses.
Sebastián González Bernal is a researcher at Pontificia Universidad Católica de Valparaíso in Chile. He studies a type of nematode called Meloidogyne ethiopica. This is a highly aggressive plant-parasitic nematode species. His team examined the speed of Meloidogyne ethiopica under different soil moisture conditions.
This study was published in Agronomy Journal, a publication of the American Society of Agronomy.
Using tomato plants, the researchers set up an experiment. The plant-parasitic nematodes were placed into the soil at different soil moisture levels and multiple distances from the plant roots. The researchers then monitored a microscopic race to see how long it would take for the nematodes to reach the tomato plant roots.
The nematodes were given up to 26 days to reach the finish line. “Knowing the speed of migration nematodes has enormous applications for farmers because they can control damage to plants by managing irrigation frequency,” González Bernal explains.
Nematodes in the driest soil were the slowest, showing little to no movement. This indicates that nematodes can’t travel as quickly in soils with less moisture, which is useful information for farmers. “Damage to plants could be controlled through proper management of the frequency of irrigation,” González Bernal says.
Most of the nematodes did not move at all or moved so slowly that the researchers weren’t able to detect their speed. The slow speed is good news. According to González Bernal, this implies that unless the roots were close to the nematode, they will not be infected.
González Bernal is excited about this research and its overall importance to agriculture. “By studying the basic biological behavior of nematodes, we have found a possible management solution for farmers/producers that benefits the plants and their root systems.”
Agronomy Journal is the flagship journal of the American Society of Agronomy. Articles convey original research in agriculture, natural resources, soil science, crop science, agroclimatology, agronomic modeling, production agriculture, and instrumentation.