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Brassinosteroids affect the symbiosis between the AM fungus Rhizoglomus irregularis and solanaceous host plants (2019)

Sivers, Lea von [Verfasser] ; Jaspar, Hannah [Verfasser] ; Johst, Bettina [Verfasser] ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

b3kat_BV045678572

Format: 1 Online-Ressource

Language: English

URN: urn:nbn:de:kobv:11-110-18452/20938-9

URL: Volltext (kostenfrei)

Author information: Bitterlich, Michael 1981-

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Brassinosteroids and sucrose transport in mycorrhizal tomato plants (2020)

Hansch, Franziska ; Jaspar, Hannah ; von Sivers, Lea ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_22240

Format: 1 Online-Ressource (6 Seiten)

Content: Silencing of SlSUT2 expression in tomato plants leads to a dwarfed phenotype, reduced pollen vitality and reduces pollen germination rate. Male sterility of flowers, together with a dwarfed growth behavior is reminiscent to brassinosteroid defective mutant plants. Therefore we aimed to rescue the SlSUT2 silencing phenotype by local brassinosteroid application. The phenotypical effects of SlSUT2 down-regulation could partially be rescued by epi-brassinolide treatment suggesting that SlSUT2 interconnects sucrose partitioning with brassinosteroid signaling. We previously showed that SlSUT2 silenced plants show increased mycorrhization and, this effect was explained by a putative sucrose retrieval function of SlSUT2 at the periarbuscular membrane. More recently, we reported that the symbiotic interaction between Solanaceous hosts and AM fungi is directly affected by watering the roots with epi-brassinolide. Here we show that the SlSUT2 effects on mycorrhiza are not only based on the putative sucrose retrieval function of SlSUT2 at the periarbuscular membrane. Our analyses argue that brassinosteroids as well as SlSUT2 per se can impact the arbuscular morphology/architecture and thereby affect the efficiency of nutrient exchange between both symbionts and the mycorrhizal growth benefit for the plant.

Content: Peer Reviewed

Note: This article was supported by the Open Access Publication Fund of Humboldt-Universität zu Berlin.

In: Austin, Tex. : Landes Bioscience, 15,2

Language: English

DOI: 10.18452/21515

DOI: 10.1080/15592324.2020.1714292

URN: urn:nbn:de:kobv:11-110-18452/22240-5

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Salt Stress Tolerance of Dark Septate Endophytes Is Independent of Melanin Accumulation (2020)

Gaber, Dalia A. ; Berthelot, Charlotte ; Camehl, Iris ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_25643

Format: 1 Online-Ressource (14 Seiten)

Content: Dark septate endophytes (DSEs) represent a diverse group of root-endophytic fungi that have been isolated from plant roots in many different natural and anthropogenic ecosystems. Melanin is widespread in eukaryotic organisms and possesses various functions such as protecting human skin from UV radiation, affecting the virulence of pathogens, and playing a role in development and physiology of insects. Melanin is a distinctive feature of the cell walls of DSEs and has been thought to protect these fungi from abiotic stress. Melanin in DSEs is assumed to be synthesized via the 1,8-dihydroxynaphthalene (DHN) pathway. Its function in alleviation of salt stress is not yet known. The aims of this study were: (i) investigating the growth responses of three DSEs (Periconia macrospinosa, Cadophora sp., and Leptodontidium sp.) to salt stress, (ii) analyzing melanin production under salt stress and, (iii) testing the role of melanin in salt stress tolerance of DSEs. The study shows that the three DSE species can tolerate high salt concentrations. Melanin content increased in the hyphae of all DSEs at 100 mM salt, but decreased at 500 mM. This was not reflected in the RNA accumulation of the gene encoding scytalone dehydratase which is involved in melanin biosynthesis. The application of tricyclazole, a DHN-melanin biosynthesis inhibitor, did not affect either salt stress tolerance or the accumulation of sodium in the hyphae. In addition, melanin biosynthesis mutants of Leptodontidium sp. did not show decreased growth performance compared to the wild-type, especially not at high salt concentrations. This indicates that DSEs can live under salt stress and withstand these conditions regardless of melanin accumulation.

Content: Peer Reviewed

In: Lausanne : Frontiers Media, 11

Language: English

DOI: 10.3389/fmicb.2020.562931

DOI: 10.18452/24961

URN: urn:nbn:de:kobv:11-110-18452/25643-2

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Arbuscular Mycorrhiza Improves Substrate Hydraulic Conductivity in the Plant Available Moisture Range Under Root Growth Exclusion (2018)

Bitterlich, Michael ; Franken, Philipp ; Graefe, Jan

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_21881

Format: 1 Online-Ressource (11 Seiten)

Content: Arbuscular mycorrhizal fungi (AMF) proliferate in soils and are known to affect soil structure. Although their contribution to structure is extensively investigated, the consequences of those processes for soil water extractability and transport has, so far, gained surprisingly little attention. Therefore we asked, whether AMF can affect water retention and unsaturated hydraulic conductivity under exclusion of root ingrowth, in order to minimize plant driven effects. We carried out experiments with tomato inoculated with Rhizoglomus irregulare in a soil substrate with sand and vermiculite that created variation in colonization by mixed pots with wild type (WT) plants and mycorrhiza resistant (RMC) mutants. Sampling cores were introduced and used to assess substrate moisture retention dynamics and modeling of substrate water retention and hydraulic conductivity. AMF reduced the saturated water content and total porosity, but maintained air filled porosity in soil spheres that excluded root ingrowth. The water content between field capacity and the permanent wilting point (6–1500 kPa) was only reduced in mycorrhizal substrates that contained at least one RMC mutant. Plant available water contents correlated positively with soil protein contents. Soil protein contents were highest in pots that possessed the strongest hyphal colonization, but not significantly affected. Substrate conductivity increased up to 50% in colonized substrates in the physiologically important water potential range between 6 and 10 kPa. The improvements in hydraulic conductivity are restricted to substrates where at least one WT plant was available for the fungus, indicating a necessity of a functional symbiosis for this effect. We conclude that functional mycorrhiza alleviates the resistance to water movement through the substrate in substrate areas outside of the root zone.

Content: Peer Reviewed

In: Lausanne : Frontiers Media S.A., 9

Language: English

DOI: 10.3389/fpls.2018.00301

DOI: 10.18452/21133

URN: urn:nbn:de:kobv:11-110-18452/21881-2

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Arbuscular Mycorrhizas: A Promising Component of Plant Production Systems Provided Favorable Conditions for Their Growth (2018)

Bitterlich, Michael ; Rouphael, Youssef ; Graefe, Jan ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_21882

Format: 1 Online-Ressource (6 Seiten)

Content: Arbuscular mycorrhizal (AM) fungi have become an attractive target as biostimulants in agriculture due to their known contributions to plant nutrient uptake and abiotic stress tolerance. However, inoculation with AM fungi can result in depressed, unchanged, or stimulated plant growth, which limits security of application in crop production systems. Crop production comprises high diversity and variability in atmospheric conditions, substrates, plant species, and more. In this review, we emphasize that we need integrative approaches for studying mycorrhizal symbioses in order to increase the predictability of growth outcomes and security of implementation of AM fungi into crop production. We briefly review known mechanisms of AM on nutrient uptake and drought tolerance of plants, on soil structure and soil hydraulic properties. We carve out that an important factor for both nutrient availability and drought tolerance is yet not well understood; the AM effects on soil hydraulic properties. We gave special emphasis to circular references between atmospheric conditions, soil hydraulic properties and plant nutrient and water uptake. We stress that interdisciplinary approaches are needed that account for a variability of atmospheric conditions and, how this would match to mycorrhizal functions and demands in a way that increased plant nutrient and water uptake can be effectively used for physiological processes and ultimately growth. Only with integrated analyses under a wide range of growing conditions, we will be able to make profound decisions whether or not to use AM in particular crop production systems or can adjust culture conditions in ways that AM plants thrive.

Content: Peer Reviewed

In: Lausanne : Frontiers Media S.A., 9

Language: English

DOI: 10.3389/fpls.2018.01329

DOI: 10.18452/21134

URN: urn:nbn:de:kobv:11-110-18452/21882-8

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