4-Vinylanisole is an aggregation phenomone in locusts., Guo, X.J., Yu, Q.Q., Chen, D.F., Wei, J.N., Yang, P.C., Yu, J., Wang, X.H., Kang, L., 2020
Piwi/piRNAs control food intake by promoting neuropeptide F expression in locusts., Wang, H.M., Jiang, F., Liu, X., Liu, Q., Fu, Y.Y., Li, R., Hou, L., Zhang, J., He, J., Kang, L., 2022
Variation of TNF modulates cellular immunity of gregarious and solitary locusts against fungal pathogen Metarhizium anisopliae., Wang, Y.D., Tong, X.W., Yuan, S.L., Yang, P.C., Li, L., Zhao, Y., Kang, L., 2022
Locust density shapes energy metabolism and oxidative stress resulting in divergence of flight traits., Du, B.Z., Ding, D., Ma, C., Guo, W., Kang, L., 2022
Phenylacetonitrile in locusts facilitates an antipredator defense by acting as an olfactory aposematic signal and cyanide precursor., Wei, J.N., Shao, W.B., Cao, M.M., Ge, J., Yang, P.C., Chen, L., Wang, X.H., Kang, L., 2019
A β-carotene-binding protein carrying a red pigment regulates body-color transition between green and black in locusts., Yang, M.L., Wang, Y.L., Liu, Q., Liu, Z.K., Jiang, F., Wang, H.M., Guo, X.J., Zhang, J.Z., Kang, L., 2019
Dop1 enhances conspecific olfactory attraction by inhibiting miR-9a maturation in locusts., Guo, X.J., Ma, Z.Y., Du, B.Z., Li, T., Li, W.D., Xu, L.L., He, J., Kang, L., 2018
Genetic variation in PTPN1 contributes to metabolic adaptation to high-altitude hypoxia in Tibetan migratory locusts., Ding, D., Liu, G.J., Hou, L., Gui, W.Y., Chen, B., Kang, L., 2018
Transposable Element-Mediated Balancing Selection at Hsp90 Underlies Embryo Developmental Variation., Chen B., Zhang B., Xu L.L., Li Q., Jiang F., Yang P.C., Xu Y.N., Kang L., 2017
miR-71 and miR-263 Jointly Regulate Target Genes Chitin synthase and Chitinase to Control Locust Molting., Yang M.L., Wang Y.L., Jiang F., Song T.Q., Wang H.M., Liu Q, Zhang J., Zhang J.Z., Kang L., 2016
Molecular mechanisms of phase change in locusts., Wang, X.H., Kang, L., 2014
Locust genome sequence provides insight into swarm formation and long-distance flight., Wang, X.H., Fang, X.D., Yang, P.C., Jiang, X.T., Jiang, F., Zhao, D.J., Li B., Cui, F., Wei, J.N., Ma, C., Wang, Y.D., He, J., Luo Y., Wang, Z.F., Guo, X.J., Guo W., Wang X., Zhang Y., Yang M.L., Hao S.G., Chen B., Ma Z.Y., Yu D., Xiong Z., Zhu Y., Fan D., Han L., Wang B., Chen Y., Wang J., Yang L., Zhao W., Feng Y., Chen G., Lian J., Li Q., Huang Z., Yao X., Lv N., Zhang G., Li Y., Wang J., Wang, J., Zhu B. Kang, L., 2014
Metabolomic analysis reveals that carnitines are key regulatory metabolites in phase transition of the locusts., Wu, R., Wu, Z.M., Wang, X.H., Yang, P.C., Yu, D., Zhao, C.X., Xu, G.W., and Kang, L., 2012
Modulation of behavioral phase changes of the migratory locust by the catecholamine metabolic pathway., Ma, ZY, Guo, XJ, Guo, W, Wang, XH, Kang, L., 2011
CSP and takeout genes modulate the switch between attraction and repulsion during behavioral phase change in the migratory locust., Guo, W, Wang, XH, Ma, Z.Y., Xue, L., Han, J.Y., Yu, D., and Kang, L., 2011
Ecological trade-offs between jasmonic acid-dependent direct and indirect plant defences in tritrophic interactions., Wei, J.N., Wang, L.Z., Zhao, J.H., Li, C.Y., Ge, F. and Kang, L., 2011
A k-mer scheme to predict piRNAs and characterize locust piRNAs., Zhang, Y., Wang, X.H., and Kang, L., 2011
Roles of Thermal Adaptation and Chemical Ecology in Liriomyza Distribution and Control., Kang, L., Chen, B., Wei, J.N. and Liu, T.X., 2009
Characterization and transcriptomes of small RNAs in two phases of locust., Wei, Y.Y., Chen, S., Yang P.C., Kang, L., 2009
Grassland ecosystems in China: Review of current knowledge and research advancement., Kang, L., Han, X.G., Zhang, Z.B. and Sun, O. J., 2007
The analysis of large-scale gene expression correlated to the phase changes of the migratory locust., Kang, L., Chen, X.Y., Zhou, Y., Zheng, W., Li R.Q., Wang, J. and Yu, J., 2004
