Plant Cell Responses to Arbuscular Mycorrhizal Fungi: Getting to the Roots of the Symbiosis

Gianinazzi‐Pearson, Vivienne

doi:10.2307/3870236

Cited by 130 publications

(83 citation statements)

References 48 publications

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“…However, Frühling et al (39) have determined that a novel leghemoglobin gene is induced in broad bean mycorrhizal roots; its function there is unknown. Bonfante-Fasolo et al (40) have observed that hydroxyproline-rich glycoproteins are found at the interface between the fungus and its host, and Gianinazzi-Pearson (41) reported that ENOD12, which encodes another putative proline-rich protein, is expressed in mycorrhizal roots in cells containing arbuscules.…”

Section: Discussionmentioning

confidence: 99%

Expression of early nodulin genes in alfalfa mycorrhizae indicates that signal transduction pathways used in forming arbuscular mycorrhizae andRhizobium-induced nodules may be conserved

Rhijn

Fang²,

Galili³

et al. 1997

Proc. Natl. Acad. Sci. U.S.A.

180

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Transcripts for two genes expressed early in alfalfa nodule development (MsENOD40 and MsENOD2) are found in mycorrhizal roots, but not in noncolonized roots or in roots infected with the fungal pathogen Rhizoctonia solani. These same two early nodulin genes are expressed in uninoculated roots upon application of the cytokinin 6-benzylaminopurine. Correlated with the expression of the two early nodulin genes, we found that mycorrhizal roots contain higher levels of trans-zeatin riboside than nonmycorrhizal roots. These data suggest that there may be conservation of signal transduction pathways between the two symbioses-nitrogen-fixing nodules and phosphate-acquiring mycorrhizae.Of the two commonly described symbioses of roots-nitrogenfixing nodules in response to members of Rhizobiaceae or Frankiaceae and phosphate-acquiring arbuscular mycorrhizae (AM) between roots and endophytic fungi-the more ancient of the two is AM. Structures identified as arbuscules have been found in Aglaophyton major, an early Devonian land plant, providing evidence for at least a Ͼ400-million-year-old association between terrestrial plants and fungi (1). In contrast, the Rhizobium-legume symbiosis is much younger, having been established no more than 65 to 136 million years ago, when the angiosperms evolved. However, unlike the AM symbiosis, which is found in almost all angiosperm families, Rhizobiuminduced nitrogen-fixing symbioses appear to be restricted to a single subclade of a larger nitrogen-fixing clade (2).LaRue and Weeden (3) proposed that nodulation evolved from the more ancient AM association because of certain similarities between the two symbioses. For example, some legumes are Nod Ϫ (absence of nodule formation) as well as Myc Ϫ

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Section: Discussionmentioning

confidence: 99%

Expression of early nodulin genes in alfalfa mycorrhizae indicates that signal transduction pathways used in forming arbuscular mycorrhizae andRhizobium-induced nodules may be conserved

Rhijn

Fang²,

Galili³

et al. 1997

Proc. Natl. Acad. Sci. U.S.A.

180

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“…Irrespective of the mechanism, rapid sugar transport via the arbuscule does not seem feasible after the cross wall in the trunk hypha develops. Circumstantial evidence that arbuscules are not essential for sugar transport comes from the existence of mutants of Pisum sativum (myc -2 ) in which arbuscules are rudimentary, but the fungus is still capable of spreading intercellularly within the roots presumably at the expense of sugars from the plant (Gianinazzi- Pearson 1996).…”

Section: Sugar Transfermentioning

confidence: 99%

Nutrient transfer in arbuscular mycorrhizas: how are fungal and plant processes integrated?

Smith¹,

Dickson²,

Smith³

2001

Functional Plant Biol.

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This review brings together recent work on the coordination of transport processes between fungus and plant symbionts in arbuscular mycorrhizal (AM) symbioses, and focuses on new information on the diversity in structure and function of interfaces and their potential roles in transport processes. We consider the way that fungal activity is polarised to absorb mineral nutrients (especially phosphorus, P) in soil, transport them to the root and release them to the plant. Conversely, the fungal structures within the root appear to be specialised to absorb sugars, which the external mycelium cannot do. The external mycelium depends on a supply of lipid, transported from within the root. High affinity P transporters expressed in the root apices and root hairs of non-mycorrhizal roots, and most probably mycorrhizal roots, absorb P actively. This can result in the development of P depletion zones, so that a low concentration of P at the absorbing surfaces limits further uptake. The external hyphae of AM fungi extend well beyond the depletion zone, accessing supplies of P at a distance and in narrow soil pores, that is absorbed actively by a high affinity P transporter expressed in these small diameter hyphae. Translocation of P within the hyphae and transfer to the plant results in much higher rates of uptake (inflows) by mycorrhizal than non-mycorrhizal roots. The possible role of polyphosphate (polyP) in this process is discussed in the light of new data. Within the root, P is lost from the fungal structures to the interfacial apoplast by an unknown mechanism, and is absorbed by the root cortical cells. The expression of a high affinity P transporter and H + -ATPase in arbuscule-containing cells indicates that these are probably the sites of fungus/plant P transfer. The site of sugar transfer from plant to fungus has not yet been established. At the whole plant level, plant uptake systems located in the youngest regions of the root are positioned to absorb P from undepleted soil, into which the root apex has just grown. In older regions of the roots, colonised by mycorrhizal fungi, the external mycelium will take over the absorptive role and overcome the difficulties posed by the slow diffusion of P in soil.

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“…These species have the capacity to establish atmospheric dinitrogen fixing symbiose with soil bacteria collectively named rhizobia, and to form symbiotic root mycorrhizae with soil fungi, thus facilitating their uptake of phosphate, water and other soil nutrients [1,2]. However, genetic analysis of these processes remains difficult in the major crop legumes due to features such as tetraploidy, large genomes and/or the lack of efficient methods for transgenesis.…”

Section: Introductionmentioning

confidence: 99%

The molecular genetic linkage map of the model legume Medicago truncatula: an essential tool for comparative legume genomics and the isolation of agronomically important genes

et al. 2002

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Background: The legume Medicago truncatula has emerged as a model plant for the molecular and genetic dissection of various plant processes involved in rhizobial, mycorrhizal and pathogenic plant-microbe interactions. Aiming to develop essential tools for such genetic approaches, we have established the first genetic map of this species. Two parental homozygous lines were selected from the cultivar Jemalong and from the Algerian natural population (DZA315) on the basis of their molecular and phenotypic polymorphism.

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Plant Cell Responses to Arbuscular Mycorrhizal Fungi: Getting to the Roots of the Symbiosis

Cited by 130 publications

References 48 publications

Expression of early nodulin genes in alfalfa mycorrhizae indicates that signal transduction pathways used in forming arbuscular mycorrhizae andRhizobium-induced nodules may be conserved

Expression of early nodulin genes in alfalfa mycorrhizae indicates that signal transduction pathways used in forming arbuscular mycorrhizae andRhizobium-induced nodules may be conserved

Nutrient transfer in arbuscular mycorrhizas: how are fungal and plant processes integrated?

The molecular genetic linkage map of the model legume Medicago truncatula: an essential tool for comparative legume genomics and the isolation of agronomically important genes

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