INVESTIGADORES
MENENDEZ Ana Bernardina
artículos
Título:
1. Phenotypic plasticity with respect to salt stress response by Lotus glaber: the role of its AM fungal and rhizobial symbionts
Autor/es:
ECHEVERRIA MARIELA; SCAMBATO AGUSTINA; SANNAZZARO ANALÍA; MAIALE SANTIAGO; RUIZ OSCAR; MENÉNDEZ ANA
Revista:
MYCORRHIZA
Editorial:
Spriger
Referencias:
Lugar: Heidelberg; Año: 2008 vol. 18 p. 317 - 329
ISSN:
0940-6360
Resumen:
Our hypothesis is that Lotus glaber (a glycophytic
species, highly tolerant to saline?alkaline soils) displays a
plastic root phenotypic response to soil salinity that may be
influenced by mycorrhizal and rhizobial microorganisms.
Uninoculated plants and plants colonised by Glomus intraradices
plastic root phenotypic response to soil salinity that may be
influenced by mycorrhizal and rhizobial microorganisms.
Uninoculated plants and plants colonised by Glomus intraradices
species, highly tolerant to saline?alkaline soils) displays a
plastic root phenotypic response to soil salinity that may be
influenced by mycorrhizal and rhizobial microorganisms.
Uninoculated plants and plants colonised by Glomus intraradices
plastic root phenotypic response to soil salinity that may be
influenced by mycorrhizal and rhizobial microorganisms.
Uninoculated plants and plants colonised by Glomus intraradices
Lotus glaber (a glycophytic
species, highly tolerant to saline?alkaline soils) displays a
plastic root phenotypic response to soil salinity that may be
influenced by mycorrhizal and rhizobial microorganisms.
Uninoculated plants and plants colonised by Glomus intraradices
plastic root phenotypic response to soil salinity that may be
influenced by mycorrhizal and rhizobial microorganisms.
Uninoculated plants and plants colonised by Glomus intraradices
?alkaline soils) displays a
plastic root phenotypic response to soil salinity that may be
influenced by mycorrhizal and rhizobial microorganisms.
Uninoculated plants and plants colonised by Glomus intraradicesGlomus intraradices
or Mesorhizobium loti were exposed to either 150 or
0 mM NaCl. General plant growth and root architectural
parameters (morphology and topology) were measured and
phenotypic plasticity determined at the end of the salt treatment
period. Two genotypes differing in their salt tolerance
capacity were used in this study. G. intraradices and M. loti
0 mM NaCl. General plant growth and root architectural
parameters (morphology and topology) were measured and
phenotypic plasticity determined at the end of the salt treatment
period. Two genotypes differing in their salt tolerance
capacity were used in this study. G. intraradices and M. loti
Mesorhizobium loti were exposed to either 150 or
0 mM NaCl. General plant growth and root architectural
parameters (morphology and topology) were measured and
phenotypic plasticity determined at the end of the salt treatment
period. Two genotypes differing in their salt tolerance
capacity were used in this study. G. intraradices and M. lotiG. intraradices and M. loti
reduced the total biomass of non-salinised, sensitive plants,
but they did not affect that of corresponding tolerant ones.
Root morphology of sensitive plants was greatly affected by
salinity, whereas mycorrhiza establishment counteracted
salinity effects. Under both saline conditions, the external
link length and the internal link length of mycorrhizal saltsensitive
plantswere higher than those of uninoculated control
and rhizobial treatments. The topological trend (TT) was
strongly influenced by genotype × symbiosis interaction.
Under non-saline conditions, nodulated root systems of the
sensitive plant genotype had a more herringbone architecture
than corresponding uninoculated ones. At 150 mM NaCl,
nodulated root systems of tolerant plants were more dichotomous
and those of the corresponding sensitive genotype
more herringbone in architecture. Notwithstanding the absence
of a link between TTs and variations in plant growth, it
is possible to predict a dissimilar adaptation of plants with
different TTs. Root colonisation by either symbiotic microorganisms
reduced the level of root phenotypic plasticity in
the sensitive plant genotype. We conclude that root plasticity
could be part of the general mechanism of L. glaber salt
tolerance only in the case of non-symbiotic plants.
tolerance only in the case of non-symbiotic plants.
L. glaber salt
tolerance only in the case of non-symbiotic plants.