The influence of Pb, with or withou

The influence of Pb, with or without AMF inoculation, in the
chemical composition of lemon grass EO varied according to the
different Pb levels used in the experiment. Non-inoculated AMF
plants, as the Pb levels in the soil increased from 0, 50, 100, 500
to 1000 mg Pb kg−1, the geranial content increased at 1.6; 13.31;
43.66; 47.37 and 62.95%, respectively (Table 2).
The AMF inoculation under Pb levels did not considerably alter
the chemical composition of EO in comparison with soils without
AMF inoculation. This suggests that the AMF can stabilize geranial,
the major compound, even under increasingly levels of Pb, as
observed in Table 2, where geranial ranged from 39.27 to 58.97%.
Lemon grass with AMF inoculation, though without Pb (0 mg kg−1
soil), showed an increased content of geranial (58.97%) and linalool
oxide (19.22%) in comparison with the control group (without Pb
and AMF), which showed a reduced content of geranial (1.60%) and
non-linalool oxide (Table 2). Andrade et al. (2009) found geranialto
be a major component of EO in lemon grass cultivated in Northern
Brazil, with contents ranging from 40% to 50% (relatively similar to
the present study).
The chemical composition of EO from lemon grass plants was
altered as the Pb levels increased. Without Pb and AMF inoculation,
the major component of EO was citral, with contents ranging from
45.08 to trace (Table 2). However, under Pb additions in the soil, and
withor withoutAMF,themajor component of EO was geranial, with
contents ranging from 1.6 to 62.95% (Table 2). This suggests that
the plants manifested defense mechanisms, such as the increased
production of secondary metabolites; in this case, geranial.
In treatments without Pb in the soil, the AMF inoculation stimulated
the production of geranial (from 1.6 to 58.97%). In the other
hand, in treatments with Pb levels applied to the soil and AMF inoculation,
no considerable variations were observed in the production
of geranial with the increasing levels of Pb in the soil (Table 2), sug-gesting the protection of the major component by the AMF. The
EO of lemon grass plants that were inoculated with AMF presented
19.22% linalool oxide. However, under increased Pb levels in the
soil, linalool oxide content decreased to 2.07% (Table 2).
The citral was a major component of the EO in the absence of
AMF and Pb levels in the soil (45.08%). However, the citral production
decreased to trace under the increasing levels of Pb in the
soils without AMF (Table 2). The AMF inoculation did not affect
the production of citral. High levels of citral and geranial are economically
importantto the aroma and perfume industries (Barbosa
et al., 2008). Moreover,the synthesis of ionone and vitamin A is also
accomplished with citral (Lemos et al., 2013).
Geranial has a strong lemon aroma. It is an aromatic substance
widely used in the perfume industry because the citric aroma and is
also used in the food industry to complement the EO from lemons.
Geranial alsohas antimicrobial and insecticide benefits that create a
pheromone effectin insects. Some industries have a high interestin
this type of substance;itis worth investing in theAMFmanagement
to increase the production of citral and geranial with lemon grass
(Robacker and Hendry, 1977; Onawunmi, 1989).
Freitas et al. (2004) observed that M. arvensis increased the total
content of EO to 88% when the plants were inoculated with AMF.
The menthol content of EOs also increased at 89% in the treatments
without P, in comparison with the control. However, no increase in
EO ormenthol was observed withAMF inoculation when increasing
levels of P were applied to the soil. Little knowledge is available for
understanding the influence of AMF in the synthesis of EO in aromatic
plants.According to Smith and Read (2008), plants inoculated
with AMF present metabolic, physiological and anatomic changes
and produce various secondary metabolites as gibberellins, which
accumulate in high amounts in these plants. Gibberellins belong to