- Kosty, Melissa;
- Pule-Meulenberg, Flora;
- Humm, Ethan A;
- Martínez-Hidalgo, Pilar;
- Maymon, Maskit;
- Mohammadi, Sophia;
- Cary, Josh;
- Yang, Paul;
- Reddi, Krisanavane;
- Huntemann, Marcel;
- Clum, Alicia;
- Foster, Brian;
- Foster, Bryce;
- Roux, Simon;
- Palaniappan, Krishnaveni;
- Varghese, Neha;
- Mukherjee, Supratim;
- Reddy, TBK;
- Daum, Chris;
- Copeland, Alex;
- Ivanova, Natalia N;
- Kyrpides, Nikos C;
- del Rio, Tajana Glavina;
- Eloe-Fadrosh, Emiley A;
- Hirsch, Ann M
As the world population increases, improvements in crop growth and yield will be needed to meet rising food demands, especially in countries that have not developed agricultural practices optimized for their own soils and crops. In many African countries, farmers improve agricultural productivity by applying synthetic fertilizers and pesticides to crops, but their continued use over the years has had serious environmental consequences including air and water pollution as well as loss of soil fertility. To reduce the overuse of synthetic amendments, we are developing inocula for crops that are based on indigenous soil microbes, especially those that enhance plant growth and improve agricultural productivity in a sustainable manner. We first isolated environmental DNA from soil samples collected from an agricultural region to study the composition of the soil microbiomes and then used Vigna unguiculata (cowpea), an important legume crop in Botswana and other legumes as “trap” plants using the collected soil to induce nitrogen-fixing nodule formation. We have identified drought-tolerant bacteria from Botswana soils that stimulate plant growth; many are species of Bacillus and Paenibacillus . In contrast, the cowpea nodule microbiomes from plants grown in these soils house mainly rhizobia particularly Bradyrhizobium , but also Methylobacterium spp. Hence, the nodule microbiome is much more limited in non-rhizobial diversity compared to the soil microbiome, but also contains a number of potential pathogenic bacteria.