Markus Liedgens scite author profile

Deep rooting has been identified as strategy for desiccation avoidance in natural vegetation as well as in crops like rice and sorghum. The objectives of this study were to determine root morphology and water uptake of four inbred lines of tropical maize (Zea mays L.) differing in their adaptation to drought. The specific questions were i) if drought tolerance was related to the vertical distribution of the roots, ii) whether root distribution was adaptive or constitutive, and iii) whether it affected water extraction, water status, and water use efficiency (WUE) of the plant. In the main experiment, seedlings were grown to the V5 stage in growth columns (0.80 m high) under well-watered (WW) and water-stressed (WS) conditions. The depth above which 95 % of all roots were located (D 95 ) was used to estimate rooting depth. It was generally greater for CML444 and Ac7729/ TZSRW (P2) compared to SC-Malawi and Ac7643 (P1). The latter had more lateral roots, mainly in the upper part of the soil column. The increase in D 95 was accompanied by increases in transpiration, shoot dry weight, stomatal conductance and relative water content without adverse effects on the WUE. Differences in the morphology were confirmed in the V8 stage in large boxes: CML444 with thicker (0.14 mm) and longer (0.32 m) crown roots compared to SCMalawi. Deep rooting, drought sensitive P2 showed markedly reduced WUE, likely due to an inefficient photosynthesis. The data suggest that a combination of high WUE and sufficient water acquisition by a deep root system can increase drought tolerance.

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Legume cover crops as living mulches for winter wheat: Components of biomass and the control of weeds

Hiltbrunner

Liedgens

Bloch³

et al. 2007

European Journal of Agronomy

130

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QTLs for the elongation of axile and lateral roots of maize in response to low water potential

Ruta¹,

Liedgens²,

Fracheboud

et al. 2009

Theor Appl Genet

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Changes in root architecture and the maintenance of root growth in drying soil are key traits for the adaptation of maize (Zea mays L.) to drought environments. The goal of this study was to map quantitative trait loci (QTLs) for root growth and its response to dehydration in a population of 208 recombinant inbred lines from the International Maize and Wheat Improvement Center (CIMMYT). The parents, Ac7643 and Ac7729/TZSRW, are known to be drought-tolerant and drought-sensitive, respectively. Roots were grown in pouches under well-watered conditions or at low water potential induced by the osmolyte polyethylene glycol (PEG 8000). Axile root length (L (Ax)) increased linearly, while lateral root length (L (Lat)) increased exponentially over time. Thirteen QTLs were identified for six seedling traits: elongation rates of axile roots (ER(Ax)), the rate constant of lateral root elongation (k (Lat)), the final respective lengths (L (Ax) and L (Lat)), and the ratios k (Lat)/ER(Ax) and L (Lat)/L (Ax.) While QTLs for lateral root traits were constitutively expressed, most QTLs for axile root traits responded to water stress. For axile roots, common QTLs existed for ER(Ax) and L (Ax). Quantitative trait loci for the elongation rates of axile roots responded more clearly to water stress compared to root length. Two major QTLs were detected: a QTL for general vigor in bin 2.02, affecting most of the traits, and a QTL for the constitutive increase in k (Lat) and k (Lat)/ER(Ax) in bins 6.04-6.05. The latter co-located with a major QTL for the anthesis-silking interval (ASI) reported in published field experiments, suggesting an involvement of root morphology in drought tolerance. Rapid seedling tests are feasible for elucidating the genetic response of root growth to low water potential. Some loci may even have pleiotropic effects on yield-related traits under drought stress.

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Growth, yield, and yield components of winter wheat and the effects of tillage intensity, preceding crops, and N fertilisation

Rieger¹,

Richner

Streit

et al. 2008

European Journal of Agronomy

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Are seeding densities an opportunity to increase grain yield of winter wheat in a living mulch of white clover?

Hiltbrunner¹,

Streit²,

Liedgens³

2007

Field Crops Research

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Markus Liedgens

Rooting depth and water use efficiency of tropical maize inbred lines, differing in drought tolerance

Legume cover crops as living mulches for winter wheat: Components of biomass and the control of weeds

QTLs for the elongation of axile and lateral roots of maize in response to low water potential

Growth, yield, and yield components of winter wheat and the effects of tillage intensity, preceding crops, and N fertilisation

Are seeding densities an opportunity to increase grain yield of winter wheat in a living mulch of white clover?

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