Cloning and characterization of Methoprene-tolerant(Met)and Kruppel homolog 1(Kr-h1)genes in the wheat blossom midge,Sitodiplosis mosellana

Juvenile hormone(JH),a growth regulator,inhibits ecdysteroid-induced meta-morphosis and controls insect development and diapause.Methoprene-tolerant(Met)and Krippel homolog I(Kr-h1)are two proteins involved in JH action.To gain some insight into their function in development of Sitodiplosis mosellana,an insect pest undergoing obligatory larval diapause at the mature 3rd instar stage,we cloned full-length complemen-tary DNAs of Met and Kr-h1 from this specics.SmMet encoded a putative protein,which contained three domains typical of the bHLH-PAS family and eight conserved amino acid residues important for JH binding.SmKr-h1 encoded a protein showing high sequence homology to its counterparts in other specics,and contained all eight highly conserved Zn-finger motifs for DNA-binding.Expression patterns of SmMet and SmKr hl were de-velopmentally regulated and JH III responsive as well.Their mRNA abundance increased as larvae entered carly 3rd instar,pre-diapause and maintenance stages,and peaked during post-diapause quiescence,a pattern correlated with JH titers in this species.Different from reduced expression of SmMer,SmKr-h1 mRNA increased at mid-to-late period of post-diapause development.Topical application of JH II on diapausing larvac also induced the two genes in a dose-dependent manner.Expression of SmuMer and SmKr-h1 clearly declined in the pre-pupal phase,and was significantly higher in female adults than male adults.These results suggest that JH-responsive SmMet and SmKr-h1 might play key roles in diapause induction and maintenance as well as in post-diapause quiescence and adult reproduction,whereas metamorphosis from larvae to pupac might be correlated with their reduced expression.

Molecular and functional characterization of three odorant-binding proteins from the wheat blossom midge,Sitodiplosis mosellana

Sitodiplosis mosellana,a periodic but devastating wheat pest,relies on wheat spike volatiles as a cue in sclecing hosts for oviposition.Insect odorant-binding proteins(OBPs)are thought to play essential roles in filtering,binding and transporting hydropho-bic odorant molecules to specific receptors.To date,the molecular mechanisms underlying S.mosellana olfaction are poorly understood.Here,three S.mosellana antenna-specific OBP genes,SmosOBPII,16 and 21,were cloned and bacterially expressed.Binding properties of the recombinant proteins to 28 volatiles emitted from wheat spikes were in-vestigated using fluorescence competitive binding assays.Sequence analysis suggested that these SmosOBPs belong to the Classic OBP subfamily.Ligand-binding analysis showed that all three SmosOBPs preferentially bound alcohol,ester and ketone com-pounds,and SmosOBP11 and 16 also selectively bound terpenoid compounds.In par-ticular,the three SmosOBPs had high binding affinities(Ki<20μmol/L)to 3-hexanol and cis-3-hexenylacetate that elicited strong electroantennogram(EAG)response fromfemale antennae.In addition,SmosOBP11 displayed significantly higher binding(Ki<8μmo/L)than SmosOBP16 and 21 to l-octen-3-ol,D-panthenol,a-pinene and heptyl acetate which elicited significant EAG response,suggesting that SmosOBP11 plays a ma-jor role in recognition and transportation of these volatiles.These findings have provided important insight into the molecular mechanism by which S.mosellana specifically rec-ognizes plant volatiles for host selection,and have facilitated identification of effective volatile attractants that are potentially useful for pest monitoring and trapping.