1. IntroductionSoil and groundwater

1. Introduction
Soil and groundwater pollution by heavy metals (HMs), derived
from industrial activities, is a severe problem. The search for
alternative methods of excavation and incineration to clean
polluted sites resulted in the application of bioremediation
techniques. Arbuscular mycorrhizal fungi (AMF) are such as a
possible tool for enhancing plant tolerance to environmental stress
conditions and restoration of naturally or industrially metalcontaminated
soils (Gianinazzi et al., 2010).
Heavy metals like cadmium (Cd) and lead (Pb) are tolerable to a
certain extent and their excess result in biological toxicity by
affecting several physiological and biochemical processes in plants.
The activity of antioxidant defence system is reduced due to
reactive oxygen species generated in a result of heavy metal stress
(Bano and Ashfaq, 2013). Alleviation of metal toxicity can be
ascribed to the impact of AMF to metal distribution at the soil–
fungus–plant interface (Meier et al., 2012). Mycorrhizal structures
may stabilize metals in the soil, reduce their uptake and minimise
the risk of toxicity to crops growing in polluted substrates
(González-Chávez et al., 2009; Azcon et al., 2010). Metal tolerant
AMF isolated from polluted soils cope better with metal toxicity
than those isolated from unpolluted soils (Cornejo et al., 2013).
Concerning Ferrol et al. (2009), isolation of indigenous and
presumably adapted AM fungi, more suitable for phytostabilisation
purposes than laboratory strains, can be a potential biotechnological
tool for successful restoration of degraded ecosystems.
The potential of AMF to enhance plant growth and reducing
heavy metal stress is well recognized, but not exploited to the
fullest extent, particularly in economically important cultures as
Calendula officinalis L. On the other site pot marigold is well known