Root navigation by self inhibition

Falik, Omer; Reides, Perla; Gersani, Mordechai; Novoplansky, Ariel

doi:10.1111/j.1365-3040.2005.01304.x

Cited by 124 publications

(119 citation statements)

References 59 publications

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“…It appears that primary root length maybe a self/ non-self response as it was independent of the identity of non-self secretions. Falik et al 31 and Gruntman and Novoplansky, 32 suggest the possibility of gradients or oscillating levels of chemicals produced by roots that may allow for a self/non-self recognition rather than a unique chemical cue for individual plants.…”

Section: Methodsmentioning

confidence: 99%

The role of ABC transporters in kin recognition inArabidopsis thaliana

Biedrzycki

Lakshmanan²,

Bais³

2011

Plant Signaling & Behavior

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Section: Methodsmentioning

confidence: 99%

The role of ABC transporters in kin recognition inArabidopsis thaliana

Biedrzycki

Lakshmanan²,

Bais³

2011

Plant Signaling & Behavior

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“…However, when partitions (either as plastic or mesh barriers) were present to separate the root systems of the two plants, plant performance increased in the presence of the activated carbon. Physical obstacles may restrict root growth and the addition of activated carbon or potassium permanganate (a strong oxidizer of organic compounds) can alleviate this restriction (Falik et al 2005) suggesting a role for root-released compounds in regulating root growth. However, while activated carbon addition has been widely used in root interactions investigations (see Mahall and Callaway 1992;Semchenko et al 2007;Kulmatiski and Beard 2006), the results need to be treated with caution and appropriate controls included, as activated carbon can result in a number of other modifications to the substrate and/or plant.…”

Section: Overproduction Of Roots In Response To Another Plant's Rootsmentioning

confidence: 99%

Plant Root Interactions

Hodge

2011

Biocommunication of Plants

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The modular structure of plant root systems enables a high degree of flexibility (or plasticity) in responding to prevailing conditions in the soil, including resource distribution. However, more recently, it has been suggested that root-root interactions are more sophisticated than simply being driven by resource availability alone. Some evidence suggests that plant roots may be able to recognise their own roots from those of other plants even when the other plant is a genetically identical individual, while other studies suggest plants may be able to identify related individuals (kin) from non-related individuals and modify their competitive interactions as a result. The results of these studies together with their limitations will be reviewed here.

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“…Roots show a high morphological and physiological plasticity in response to the physical and chemical properties of soil. They are able to avoid obstacles, toxins and roots of other plants by guiding the direction of root-tip growth and by controlled withering of tips that grow towards an obstacle (Falik et al 2005). Moreover, plants can quickly respond to nutrient-rich patches by specifically proliferating into the patch and by increasing local nutrient uptake rates in newly formed root tips (Hutchings and De Kroon 1994;De Kroon et al 2005).…”

Section: Differences and Similarities Between Roots And Shootsmentioning

confidence: 99%

Chemical communication between roots and shoots: towards an integration of aboveground and belowground induced responses in plants

Dam¹,

Bezemer²

Chemical Ecology

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Abstract. Induced responses in plants occur in response to both aboveground (AG) and belowground (BG) herbivores and pathogens. So far, the majority of studies have focused on AG induced responses. Possible interactions between AG and BG induced responses have only recently received scientific attention. On the one hand, induction in one plant part may result in systemically induced responses in other parts. On the other hand, simultaneously occurring AG and BG induced responses may interfere, for example, when the activities of root feeders alter the effectiveness of induced responses against leaf feeders. In both cases, AG-BG interactions between induced responses may affect the amount of damage to a plant and therefore constitute an important selection pressure in the evolution of optimal plantdefence strategies.Here we present a new concept for the integration of AG and BG induced responses in current optimal-defence theory. First, we will consider differences in physiology and morphology between roots and shoots, which relate to their different roles in resource acquisition and which are important in interactions with their environment. Then, we will evaluate how general principles emerging from current theories and mathematical models of optimal AG induced plant defences can be applied to BG induced responses, as well as to their interactions with AG responses. Finally, we argue that plants integrate the information that is communicated by roots and shoots to optimize plant fitness in a multitrophic context..

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Root navigation by self inhibition

Cited by 124 publications

References 59 publications

The role of ABC transporters in kin recognition inArabidopsis thaliana

The role of ABC transporters in kin recognition inArabidopsis thaliana

Plant Root Interactions

Chemical communication between roots and shoots: towards an integration of aboveground and belowground induced responses in plants

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