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United States Department of Agriculture

Agricultural Research Service

Related Topics

Qin-Bao Li
Chemistry Research
Molecular Biologist

Phone: (352) 374-5758
Fax: (352) 374-5818

1600-1700 SW 23RD DRIVE
GAINESVILLE , FL 32608


Publications (Clicking on the reprint icon Reprint Icon will take you to the publication reprint.)
Transposon elements in maize white seedling 3, allele w3-8686, w3-kermicle-1 and w3-88-89-3563-33 -
Homogentisate solanesyl transferase (HST) cDNA’s in maize -
Isolation, characterization, and expression analyses of plant elicitor peptides (pep) genes in maize -
Li, Q., Huffaker, A., Teal, P.E. 2016. Isolation, characterization, and expression analyses of plant elicitor peptides (pep) genes in maize. Genbank. KR606067-KR606070.
Seed filling in domesticated maize and rice depends on SWEET-mediated hexose transport -
Maize white seedling 3 results from disruption of homogentisate solanesyl transferase -
The auxin-deficient defective kernel18 (dek18) mutation alters the expression of seed-specific biosynthethic genes in maize -
Bernardi, J., Li, Q., Gao, Y., Zhao, Y., Battaglia, R., Marocco, A., Chourey, P.S. 2016. The auxin-deficient defective kernel18 (dek18) mutation alters the expression of seed-specific biosynthethic genes in maize. Journal of Plant Growth Regulation. 35(3):770-777.
Seed filling in domesticated maize and rice depends on SWEET-mediated hexose transport -
Sosso, D., Luo, D., Li, Q., Sasse, J., Yang, J., Gendrot, G., Suzuki, M., Koch, K., Mccarty, D., Chourey, P., Rogowsky, P., Ross-Ibarra, J., Yang, B., Frommer, W. 2015. Seed filling in domesticated maize and rice depends on SWEET-mediated hexose transport. Nature Genetics. 47(12):1489-1496.
Isolation, characterization, and expression analyses of tryptophan aminotransferase genes in a maize dek18 mutant -
Isolation, characterization, and expression analyses of tryptophan -
Bernardi, J., Li, Q., Marocco, A., Chourey, P. 2016. Isolation, characterization, and expression analyses of tryptophan. Genbank. KT447512-KT447514.
Isolation, characterization, and expression analyses of plant elicitor peptides (Pep) genes in maize -
Li, Q., Huffaker, A., Teal, P.E. 2015. Isolation, characterization, and expression analyses of plant elicitor peptides (Pep) genes in maize. Genbank. KR606060-66, KR149244.
Isolation, characterization, and expression analyses of ecdysone receptor 1, ecdysone receptor 2 and ultraspiracle genes in varroa destructor mite -
Li, Q., Cabrera Cordon, A.R., Teal, P.E., Shirk, P.D. 2015. Isolation, characterization, and expression analyses of ecdysone receptor 1, ecdysone receptor 2 and ultraspiracle genes in varroa destructor mite. Genbank. KR230042-46,KR363132.
Distinct function of COAR and B3 domains of maize VP1 in induction of ectopic gene expression and plant developmental phenotypes in Arabidopsis -
Suzuki, M., Wu, S., Li, Q., Mccarty, D.R. 2014. Distinct function of COAR and B3 domains of maize VP1 in induction of ectopic gene expression and plant developmental phenotypes in Arabidopsis. Plant Molecular Biology. 85:179-191.
Proteomic comparison of basal endosperm in maize miniature1 mutant and its wild-type Mn1 -
Silva-Sanchez, C., Chen, S., Zhu, N., Li, Q., Chourey, P.S. 2013. Proteomic comparison of basal endosperm in maize miniature1 mutant and its wild-type Mn1. Frontiers in Plant Science. 4:1-16.
Impaired auxin biosynthesis in the defective endosperm18 mutant is due to mutational loss of expression in the ZmYuc1 gene encoding endosperm-specific YUCCA1 protein in maize. -
Bernardi, J., Lanubile, A., Li, Q., Kumar, D., Kladnick, A., Marocco, A., Chourey, P.S., Cook, S.D., Ross, J.J. 2012. Impaired auxin biosynthesis in the defective endosperm18 mutant is due to mutational loss of expression in the ZmYuc1 gene encoding endosperm-specific YUCCA1 protein in maize.. Plant Physiology. 160:1318-1328.
Pleiotropy and its limited dissection through a metabolic gene Miniature1 (Mn1) that encodes a cell wall invertase in developing seeds of maize. -
Chourey, P.S., Li, Q., Cevallos-Cevallos, J. 2011. Pleiotropy and its limited dissection through a metabolic gene Miniature1 (Mn1) that encodes a cell wall invertase in developing seeds of maize. Plant Science. 184:45-53.
Cytokinins in developing maize caryopsis and their possible role in seed size determination -
Rijavec, T., Li, Q., Dermastia, M., Chourey, P.S. 2012. Cytokinins in developing maize caryopsis and their possible role in seed size determination. Plant Physiology. 13:293-308.
Gene-dose dependent control of seed mass by endosperm-specific Miniature1 (Mn1)-encoded cell wall invertase (CWI), which also affects embryo mass and embryo sugar physiology. -
Discovery of Genes Expressed In Basal Endosperm Transfer Cells in Maize Using 454 Transcriptome Sequencing Reprint Icon -
Xiong, Y., Li, Q., Kang, B., Chourey, P.S. 2011. Discovery of Genes Expressed In Basal Endosperm Transfer Cells in Maize Using 454 Transcriptome Sequencing. Plant Molecular Biology Reporter. 29:835-847.
Sugar - hormone crosstalk in seed development: Two redundant pathways of IAA biosynthesis are regulated differentially in the invertase-deficient miniature1 (mn1) seed mutant in maize -
Chourey, P.S., Li, Q., Kumar, D. 2010. Sugar - hormone crosstalk in seed development: Two redundant pathways of IAA biosynthesis are regulated differentially in the invertase-deficient miniature1 (mn1) seed mutant in maize. Molecular Plant. 3:1026-1036.
Cloning and expression analyses of Sucrose non-fermenting-1-Related Kinase 1 (SnRK1b) gene during development of sorghum and maize endosperm, and its implicated role in sugar-to-starch metabolic transition -
Jain, M., Li, Q., Chourey, P.S. 2008. Cloning and expression analyses of Sucrose non-fermenting-1-Related Kinase 1 (SnRK1b) gene during development of sorghum and maize endosperm, and its implicated role in sugar-to-starch metabolic transition. Physiologia Plantarum. 134:161-173.
Expression profiles of cytokinin (CK)genes in the miniature-1 (mn1)-associated genotypes with variable levels if cell wall invertase (CWI)activity in developing seeds of maize -
Expression of cell wall invertase and several other genes of sugar metabolism in relation to seed development in sorghum (Sorghum bicolor) -
Mukesh, J., Chourey, P.S., Li, Q., Pring, D.R. 2008. Expression of cell wall invertase and several other genes of sugar metabolism in relation to seed development in sorghum (Sorghum bicolor). Journal of Plant Physiology. 165(3): 331-344.
GENETIC CONTROL OF CELL WALL INVERTASES IN DEVELOPING ENDOSPERM OF MAIZE -
Chourey, P.S., Jain, M., Li, Q., Carlson, S.J. 2005. Genetic control of cell wall invertases in developing endosperm of maize. Planta. 223:159-167.
Last Modified: 5/2/2016
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