Xianchun Li

Xianchun Li

Professor, Entomology
Professor, Entomology / Insect Science - GIDP
Professor, BIO5 Institute
Primary Department
Department Affiliations
Contact
(520) 626-1749

Work Summary

Xianchun Li's research aims to use genetics to shed light on the defense signaling of plants and the counterdefense of herbivorous insects, which may result in the design of new insecticides for crops like corn, in defense against the corn earworm. Additionally, Dr. Li's research is to define, globally, the regulatory triangle between nuclear receptors (NRs), their ligands, and cytochrome P450s (P450s) in Drosophila melanogaster, and to investigate the molecular mechanisms of Bt and conventional insecticide resistance.

Research Interest

Xianchun Li, PhD, is interested in understanding the physiological, biochemical, molecular and evolutionary bases of fundamental processes in the life history of insects such as embryonic polarity, metamorphosis, developmental commitment, host usage and environmental adaptation. One focus of his research is to elucidate the reciprocal signaling interactions between plants and insects, and the resulted on-going defense (in the case of plants) / counterdefense (in the case of herbivorous insects) phenotypic arm race over ecological time scale, with emphasis on the genetic machinery that percepts and transduces the reciprocal cues into genome and regulate defense / counterdefense phenotypes. Working systems include Helicoverpa zea, the corn earworm, a polyphagous noctuide of economic importance, and Drosophila melanogaster, the fruit fly, a model organism. State of arts and traditional techniques are combining to identify the cues and to uncover the signaling transduction cascade that links environmental cues, gene expression and the resulted defense/counterdefense phenotypes. This research may lead to characterization of genes for designing new insecticides and/or genetically modifying crops. The second focus of Dr. Li’s research is to define, globally, the regulatory triangle between nuclear receptors (NRs), their ligands, and cytochrome P450s (P450s) in Drosophila melanogaster. Nuclear receptors (NRs) constitute a transcription factor superfamily that has evolved to sense and bind endogenous (e.g., hormones) and/or exogenous (e.g., naturally-occurring or synthetic xenobiotics) signal compounds, resulting in differential expression of particular target genes, which underlies a range of fundamental biological processes, including growth, development, reproduction, behavior, host usage, and environmental adaptation. Many of those cue chemicals, namely NR ligands, are synthesized and/or metabolized by members of the P450s gene superfamily, whose expression may be regulated by certain NRs. Bioinformatics analyses as well as systematic functional genomic techniques such as microarray, X-ChIP, mutation and ectopic expression will be combined to define the genome-wide regulatory interaction loops between NRs and P450s as well as to assign, at least partially, functions of individual NRs and P450s in the life history of fruit fly. Given the evolutionary conservations of homologous NRs and P450s between vertebrates and invertebrates, the results obtained in this project are expected to provide insights into the reciprocal regulatory interactions between NRs and P450s in other animals including humans as well as to provide great insights into new avenue for human NR ligand identification and NR-related drug design. The third focus of his research is to investigate the molecular mechanisms of Bt and conventional insecticide resistance, which is a major threat in current IPM system. In collaboration with Dr. Bruce Tabashnik, Timothy Dennehy, and Yves Carriere in our Department, Dr. Li is going to compare Bt toxin binding affinity and other defects of natural (s, r1, r2, r3) and artificial mutant PBW (Pink Bollworm) cadherin proteins and thus define the key functional domains of PBW cadherin.

Publications

Brévault, T., Heuberger, S., Zhang, M., Ellers-Kirk, C., Xinzhi, N. i., Masson, L., Xianchiun, L. i., Tabashnik, B. E., & Carrière, Y. (2013). Potential shortfall of pyramided transgenic cotton for insect resistance management. Proceedings of the National Academy of Sciences of the United States of America, 110(15), 5806-5811.

PMID: 23530245;PMCID: PMC3625267;Abstract:

To delay evolution of pest resistance to transgenic crops producing insecticidal proteins from Bacillus thuringiensis (Bt), the "pyramid" strategy uses plants that produce two or more toxins that kill the same pest. In the United States, this strategy has been adopted widely, with two-toxin Bt cotton replacing one-toxin Bt cotton. Although two-toxin plants are likely to be more durable than one-toxin plants, the extent of this advantage depends on several conditions. One key assumption favoring success of two-toxin plants is that they kill insects selected for resistance to one toxin, which is called "redundant killing." Here we tested this assumption for a major pest, Helicoverpa zea, on transgenic cotton producing Bt toxins Cry1Ac and Cry2Ab. Selection with Cry1Ac increased survival on two-toxin cotton, which contradicts the assumption. The concentration of Cry1Ac and Cry2Ab declined during the growing season, which would tend toexacerbate this problem. Furthermore, analysis of results from 21 selection experiments with eight species of lepi-dopteran pests indicates that some cross-resistance typically occurs between Cry1A and Cry2A toxins. Incorporation of empirical data into simulation models shows that the observed deviations from ideal conditions could greatly reduce the benefits of the pyramid strategy for pests like H. zea, which have inherently low susceptibility to Bt toxins and have been exposed extensively to one of the toxins in the pyramid before two-toxin plants are adopted. For such pests, the pyramid strategy could be improved by incorporating empirical data on deviations from ideal assumptions about redundant killing and cross-resistance.

Zhang, C., Luo, X., Xinzhi, N. i., Zhang, Y., & Xianchun, L. i. (2010). Functional characterization of cis-acting elements mediating flavone-inducible expression of CYP321A1. Insect Biochemistry and Molecular Biology, 40(12), 898-908.

PMID: 20854909;Abstract:

How plant allelochemicals elicit herbivore counterdefense genes remains largely unknown. To define the cis-acting elements for flavone inducibility of the allelochemical-metabolizing CYP321A1 from Helicoverpa zea, functions of varying length of CYP321A1 promoter are examined in H. zea fatbody cells. Progressive 3' deletions reveal presence of positive elements in the 5' untranslated region (UTR). Progressive 5' deletions map out regions of one essential element, four enhancers, and two silencers. Further progressive 5'deletions localize the essential element to a 36-bp region from -109 to -74. This essential element, designated as xenobiotic response element to flavone (XRE-Fla), contains a 5' AT-only TAAT inverted repeat, a GCT mirror repeat and a 3' antioxidant response element-like element. Internal deletions and substitution mutations show that the TAAT repeat is only necessary for the maximal flavone inducibility, whereas the other two components are necessary for the basal and flavone-induced expression of CYP321A1. Electrophoresis mobility shift assays demonstrate that XRE-Fla specifically binds to H. zea fatbody cell nuclear extracts and flavone treatment increases the nuclear concentrations of the yet-to-be characterized transcription factors binding to XRE-Fla. Taken together, CYP321A1 expression is regulated primarily by XRE-Fla and secondarily by other cis elements scattered in its promoter and 5' UTR. © 2010.

Xianchun, L. i., Berenbaum, M. R., & Schuler, M. A. (2002). Plant allelochemicals differentially regulate Helicoverpa zea cytochrome P450 genes. Insect Molecular Biology, 11(4), 343-351.

PMID: 12144700;Abstract:

Four cytochrome P450 genes, CYP6B8, CYP6B9, CYP6B27 and CYP6B28, exist in the Helicoverpa zea genome as two pairs of paralogs that evolved from gene duplication and 5′-polar gene conversion events. RT-PCR gel blot analyses have shown that all of these genes are expressed constitutively in midguts of all larval instars, suggesting that they have primary roles in the detoxification of plant allelochemicals. Among these, CYP6B9 is expressed only in midgut tissue whereas its paralog, CYP6B27, is expressed primarily in midgut and secondarily in fat body and ovary. CYP6B28 is expressed in midgut, fat body and, to lesser extents in ovary and integument whereas its paralog, CYP6B8, is expressed in midgut and to some extent in fat body. Comparison of the expression levels induced by eight plant allelochemicals, one drug (phenobarbital), and an insecticide (α-cypermethrin) indicates that, for the most part, the four P450s respond individually to these inducers, with all four induced strongly by chlorogenic acid, a shikimate pathway intermediate and a lignin biosynthesis intermediate present in a wide variety of plants, and indole-3-carbinol, a glucobrassicin breakdown product present in the Brassicaceae. The multiple levels at which these P450 genes are apparently diverging (e.g. transcriptional responses, protein sequences) support the suggestion that gene conversion events facilitate gene evolution by allowing duplicated copies greater time to acquire selectable differences in both coding and promoter sequences.

Ma, L., Dai, W., Li, X., Zhang, Y., & Zhang, C. (2015). Molecular cloning and expression analysis of soluble and membrane-bound trehalase genes in the cotton bollworm, Helicaverpa armigera. JOURNAL OF ASIA-PACIFIC ENTOMOLOGY, 18(2), 187-195.
Chiel, E., Kelly, S. E., Harris, A. M., Gebiola, M., Li, X. -., Zchori-Fein, E., & Hunter, M. S. (2014). Characteristics, phenotype and transmission of Wolbachia in the sweet potato whitefly, Bemisia tabaci (Hemiptera: Aleyrodidae), and its parasitoid Eretmocerus sp. nr. emiratus (Hymenoptera: Aphelinidae). Environmental Entomology.