Saudi Arabia: Crop Science Desert Bacterium Promotes Crop Production in Arid Lands
The bacterium SA187 has been isolated from the root nodules of an indigenous desert plant that grows in Saudi Arabia. A team of King Abdullah University of Science and Technology (Kaust) discovered it has many genes that promote plant growth in stressful environments.
Thuwal/Saudi Arabia — The UN Food and Agriculture Organization estimates farmers will need to produce 70 % more food by 2050 to meet the needs of the world’s growing population. At the same time, 70 % of global annual food production is lost due to challenges from various biotic (pathogens, insects, herbivores) and abiotic (drought, heat, cold) factors.
Crops need to be more stress resistant, but genetic engineering and crop breeding technologies take a long time to develop and they can’t immediately serve the people who need food the most: subsistence farmers who eat what they farm. “So we need fast and low-cost solutions that are affordable and accessible to everyone on the planet,” says says plant scientist Heribert Hirt. The Darwin21 project aims to find bacteria that can help crops become resistant to the most prominent abiotic stresses that are responsible for 60 % of the loss in crop productivity, he says.
Kaust researchers treated five-day-old seedlings of a small flowering plant called Arabidopsis thaliana with the bacterium SA187. The plants were then grown in conditions that tested their tolerance to drought, heat and salt stresses. Plants treated with SA187 grew better than those not treated with the bacterium.
Analyses also showed that SA187 can adapt to diverse and harsh environments; colonize plants and modulate their hormone production, thus promoting growth; and produce enzymes that protect the plant against pathogenic bacteria, insects and fungi.
Significantly, the team compared the genome of SA187 with that of other bacteria and found that it could be a new genus that belongs to the Enterobacteriaceae family of bacteria. Further investigations are required, however, to fully characterize its taxonomic position.
The team was able to analyze the bacterium’s genome in detail and to assess the likely functions of many of its genes using Kaust’s computational pipeline, Automatic Annotation of Microbial/Meta Genomes, says bioinformatician, Intikhab Alam, of the Computational Bioscience Research Center.
Identified genes were added to the Integrated Database of microbial/meta Genomes (Indigo) to provide an easy-to-use platform for biologists to further explore these genes.
Maged Saad, a research scientist with the team, has developed an application that coats plant seeds with the bacteria before they are sown. This gives the bacteria a competitive advantage to establish on the plant before it is exposed to other bacteria in the soil.
Four of Hirt’s students are now establishing a nonprofit company to distribute SA187 to poor subsistence farmers in various parts of the world. “We hope that by increasing the harvest of these farmers, they will be able to buy essential tools, such as tractors, to improve their production and make a sustainable living,” says Hirt.
Andres-Barrao, C., Lafi, F.F., Alam, I., de Zelicourt, A., Eida, A.A., Bokhari, A., Alzubaidy, H., Bajic., V.B., Hirt, H. & Saad, M.M. Complete genome sequence analysis of Enterobacter sp. SA187, a plant multi-stress tolerance promoting endophytic bacterium. Frontiers in Microbiology 8, 2023 (2017).