The metaflumizone, which belongs to

The metaflumizone, which belongs to the class of voltage-dependent sodium channel blockers, was registered
to control Spodoptera exigua on vegetables in China in 2009. The present study revealed S. exigua
has developed high resistance to this novel chemistry insecticide shortly after 2–3 years application in
Guangdong Province of China. The metabolic mechanisms for metaflumizone resistance in this insect
were analysed. The inhibitor of esterases greatly potentiates the toxicity of this chemical against the field
resistant populations. The synergism ratio is 5.7 and 3.4-fold for S. exigua collected from Huizhou, Guangdong
Province in 2011 and 2012, respectively. The activity of esterases in field populations (HZ12) is also
significantly greater than that in the susceptible strain, and further significantly increased by challenge
with metaflumizone for 3 generations. However, the inhibitor of P450s or GSTs only has slight synergism
on metaflumizone toxicity against resistant populations, and there are no obvious differences in activities
of P450s or GSTs between resistant populations and the susceptible strain. These results suggest that
esterases might take pivotal role in conferring metabolic resistance to metaflumizone in the field populations
of S. exigua, and P450s or GSTs are not involved in this resistance. Moreover, flavin-dependent
monooxygenases (FMOs) are discovered to involve in metaflumizone resistance in the field populations
of S. exigua. The FMO inhibitor, methimazole, potentiates metaflumizone toxicity in resistant larva of this
species substantially. The synergism ratios for methimazole in resistant populations HZ11 and HZ12 were
3.1 and 1.9, respectively. Enzymatic assays also revealed higher FMO activities in resistant populations
than in the susceptible strain, and successive selection with metaflumizone further increased the FMO
activity in the field resistant population, but not significantly. The higher FMO activities in the older larval
stages and in the larval midgut signify the importance of FMO in the detoxification of xenobiotic from
food sources. The synergism assay and FMO activity analysis suggest that FMO contributes to metaflumizone
detoxification in resistant populations of S. exigua and conferred metaflumizone resistance in
S. exigua. A novel mechanism for insecticide resistance by insect was proposed.
 2014 Elsevier Inc. All rights reserved.
1. Introduction
Insecticides have been the primary agent to control vectorborne
diseases and insect pests in agricultural crops for decades.
However, pests have evolved resistance through strong selection
imposed by frequent insecticide application. Insects adopt various
defence mechanisms to survive insecticide exposure, and the
insecticide arsenal must be expanded with novel chemistries to
combat resistance. Despite intensive on-going research, the number
of commercially available insecticide chemistries is limited;
maintaining the efficacy of currently available insecticides is critical.
Moreover, understanding the physiological and molecular
basis of insecticide resistance provides useful information on
improving pest control [1].
The beet armyworm, Spodoptera exigua, is a key insect species
present in many crops, including vegetables, ornamentals, and cotton
[2]. Insecticides must be used extensively to prevent damage,
and field-evolved resistances to conventional insecticides have
been reported in China [3–6] and other countries [7–12]. Some
populations have developed resistance to newer insecticides,
including chlorantraniliprole [22], spinosad [13], indoxacarb [14],
tebufenozide [15], and emamectin benzoate [16]. The development
of insecticide resistance by field populations has resulted in control
failures [16], and the need for novel insecticides. Metaflumizone is
a novel sodium channel blocking insecticide (SCBIs), which binds
selectively to the slow-inactivated state of the sodium channel
and provides excellent control of lepidopterous pests [17–19].
http://dx.doi.org/10.1016/j.pestbp.2014.06.010
0048-3575/ 2014 Elsevier Inc. All rights reserved.
⇑ Corresponding author.
E-mail address: sjy@njau.edu.cn (J. Su).
Pesticide Biochemistry and Physiology 113 (2014) 8–14
Contents lists available at ScienceDirect
Pesticide Biochemistry and Physiology
journal homepage: www.elsevier.com/locate/pest