Sorghum (Sorghum bicolor Linn.) see

Sorghum (Sorghum bicolor Linn.) seedlings were grown in pots using Pakchong soil from Nakhon
Ratchasima province. Ten species of native Arbuscular mycorrhizal (AM) fungi:Glomus sp. 1,Glomus sp. 2,
Glomus sp. 3, Glomus aggregatum,Glomus fasciculatum, Acaulospora longula,Glomus occultum, Acaulospora
scrobiculata, Acaulospora spinosa and Scutellospora sp., were used to inoculate sorghum seedlings. The
sorghum growth and uptake of several major nutrients were evaluated at the harvesting stage. The
results revealed that sorghum inoculated with A. scrobiculata produced the greatest biomass, grain dry
weight and total nitrogen uptake in shoots. The highest phosphorus uptake in shoots was found in
A. spinosa-inoculated plants, followed by Glomus sp. and A. scrobiculata, whereas Scutellospora sp.-
inoculated plants showed the highest potassium uptake in shoots followed by A. scrobiculata. Overall,
the most efficient AM fungi for improvement of nutrient uptake, biomass and grain dry weight in sorghum were A. scrobiculata.
Introduction
Arbuscular mycorrhizal (AM) fungi are among the most ubiquitous soil microorganisms, forming mutualistic associations with
80e90% of vascular plant species in ecosystems throughout the
world (Harrison, 1997; Smith and Read, 1997). Previous research
has indicated that inoculation with AM fungi enhances growth and
the nutrient uptake of phosphorus (McArthur and Knowlos, 1993)
and nitrogen (Barea et al., 1987; Azco'n Aguilar et al., 1993). Inoculation with AM fungi increased the percentage of nitrogen uptake
and fruit yield of green peppers in high P soil (Douds and Reider,
2003), and promoted plant biomass and enhanced P, K, Ca, Fe,
Mn and Cu uptake in chickpea plants in pot experiments using soil
with high levels of available P and K (Farzaneh et al., 2011).
Moreover, AM fungi increased the activities of soil enzymes such as
phosphatase which can degrade organic phosphate (i.e. phytate) to
available phosphate (Dodd et al., 1987; Kothari et al., 1990; Vazquez

et al., 2000). Oxalic acid released from AM fungi reacts with unavailable phosphate, converting it into available phosphate (Beever
and Burns, 1980). However, in addition, AM fungal mycelia
effectively increased the total absorption surface of inoculated
plants and thus improved plant access to nutrients such as P, Cu and
Zn (Lambert et al., 1979; George et al., 1994; Ortas et al., 1996). AM
fungi extended the absorbing network beyond the nutrientdepletion zones of the rhizosphere which allowed access to a
larger volume of soil than for roots not colonized by AM fungal
mycelium. There is additional evidence showing that AM fungi
helped plants to acquire nutrients including P, Zn, N, Cu and K
(Marschner and Dell, 1994; Cavagnaro, 2008; Lehmann et al., 2014).
Research by Cavagnaro et al. (2015) showed that AM fungi had the
ability to reduce nutrient loss from the soil by enlarging the
nutrient interception zone and preventing nutrient loss after raininduced leaching events.
Many reports found that plants hosting AM fungi symbiosis in
root systems are tolerant to drought and plant pathogenic microorganisms (Bethlenfalvay and Linderman, 1992; Tobar et al., 1994;
Subramanian et al., 1995). Auge (2001)
found that AM fungi
enhanced water relations and improved the soil structure (Miller
and Jastrow, 2000). Thus effective utilization of AM fungal symbiosis should benefit crop production systems, pest control and alternatives to chemical fertilizers.
ICRISAT (2009) summarized some global statistics on sorghum.
It is the fifth most important cereal crop after wheat, rice, maize
and barley and is the dietary staple of more than 500 million