Publication Details |
| Category | Text Publication |
| Reference Category | Journals |
| DOI | 10.1093/aob/mcaf033 |
| Title (Primary) | Drought response of the maize plant–soil–microbiome system is influenced by plant size and presence of root hairs |
| Author | Hartwig, R.P.; Santangeli, M.; Würsig, H.; Martín Roldán, M.; Yim, B.; Lippold, E.
; Tasca, A.; Oburger, E.; Tarkka, M.; Vetterlein, D.; Bienert, P.; Blagodatskaya, E.; Smalla, K.; Hause, B.; Wimmer, M.A. |
| Source Titel | Annals of Botany |
| Year | 2025 |
| Department | BOOEK; BOSYS |
| Language | englisch |
| Topic | T5 Future Landscapes |
| Keywords | Zea mays; root exudation; root hairs; drought; enzyme activity; rth3; soil; microbiome |
| Abstract | Background and aims We have abundant knowledge on drought responses of plants or soil microorganisms individually. However, there is a severe lack of knowledge regarding interactions in the plant–soil–microbiome continuum, and specifically root–soil interface traits including the role of root hairs. Here we investigated how water limitation propagates in a plant–soil–microbiome system upon stopping irrigation. We used two Zea mays genotypes [rth3 and its isogenic wild type (WT), B73], differing in root hair formation, to elucidate the effect of rhizosphere extension under water limitation. Methods For 22 d, WT and rth3 plants were grown in a climate chamber, with irrigation stopped for drought treatment during the last 7 d. Daily measurements included soil water status, plant evapotranspiration and gas exchange. At harvest, root exudates, shoot relative water content, osmolality and nutrients, root morphological traits and transcriptomics, and soil microbial β-diversity and enzyme activity were determined. Key Results In line with a larger plant size, drought stress developed more rapidly and the number of differentially expressed genes was higher in the WT compared with rth3. Under water limitation, root exudation rates increased and soil enzyme activities decreased more strongly in the WT rhizosphere. In both genotypes, water level significantly altered microbial β-diversity in the bulk soil, particularly affecting fungi more than bacteria/ archaea. The genotype affected only bacteria/archaea and was more pronounced in rhizosphere than in bulk soil. Conclusions This interdisciplinary study assessed how a short drought stress manifested in a plant–soil–microbiome system. Water limitation altered microbial (fungal) diversity in distance from the root surface. Genotype-specific stress-induced increases in exudation rates modified microbial activity in root proximity, possibly pointing to root hair functions under water limitation. Less intense drought responses of rth3 were confirmed at all levels of investigation and may be due at least in part to its smaller plant size. |
| Persistent UFZ Identifier | https://www.ufz.de/index.php?en=20939&ufzPublicationIdentifier=31154 |
| Hartwig, R.P., Santangeli, M., Würsig, H., Martín Roldán, M., Yim, B., Lippold, E., Tasca, A., Oburger, E., Tarkka, M., Vetterlein, D., Bienert, P., Blagodatskaya, E., Smalla, K., Hause, B., Wimmer, M.A. (2025): Drought response of the maize plant–soil–microbiome system is influenced by plant size and presence of root hairs Ann. Bot. 10.1093/aob/mcaf033 |
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