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Volume 34 Issue 6
Jun.  2007
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Analysis of Codon Usage Between Different Poplar Species

doi: 10.1016/S1673-8527(07)60061-7
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  • Corresponding author: E-mail address: jshi@njfu.edu.cn (Jisen Shi)
  • Received Date: 2006-07-28
  • Accepted Date: 2006-09-14
  • Available Online: 2007-06-27
  • Publish Date: 2007-06-20
  • Codon usage is the selective and nonrandom use of synonymous codons to encode amino acids in genes for proteins. The analysis of codon usage may improve the understanding of codon preferences between different species and allow to rebuild the codons of exogenous genes to increase the expression efficiency of exogenous genes. Here, codon DNA sequence (CDS) of four poplar species, including Populus tremuloides Michx., P. tomentosa Carr., P. deltoides Marsh., and P. trichocarpa Torr. & Gray., is used to analyze the relative frequency of synonymous codon (RFSC). High-frequency codons are selected by high-frequency (HF) codon analysis. The results indicate that the codon usage is common for all four poplar species and the codon preference is quite similar among the four poplar species. However, CCT encoding for Pro, and ACT coding for Thr are the preferred codons in P. tremuloides and P. tomentosa, whereas CCA coding for Pro, and ACA coding for Thr are preferred in P. deltoides and P. trichocarpa. The codons such as TGC coding for Cys, TTC coding for Phe, and AAG coding for Lys, are preferred in the poplar species except P. trichocarpa. GAG coding for Glu is preferred only in P. deltoides, while the other three poplar species prefer to use GAA. The commonness of preferred codon allows exogenous gene designed by the preferred codon of one of the different poplar species to be used in other poplar species.
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  • [1]
    Grantham, R, Gautier, et al. Codon frequencies in 119 individual genes confirm consistent choices of degenerate bases according to genome type Nucleic Acids, 8 (1980),pp. 1893-1912
    [2]
    Lu, H, Zhao, et al. Acta Biochimica et Biophysica Sinica, 37 (2005),pp. 1-10
    [3]
    Holm, L Codon usage and gene expression Nucleic Acids, 14 (1986),pp. 3075-3087
    [4]
    Coghlan, A, Wolfe, et al. Relationship of codon bias to mRNA concentration and protein length in Saccharomyces cerevisiae Yeast, 16 (2000),pp. 1131-1145
    [5]
    Akashi, H Translational selection and yeast proteome evolution Genetics, 164 (2003),pp. 1291-1303
    [6]
    Liu, QP, Tan, et al. Synonymous codon usage bias in the rice cultivar 93-11 (Oryza sativa L. ssp indica) Acta Genetica Sinica, 30 (2003),pp. 335-340
    [7]
    Zhang, Y, Zhang, et al. Poplar as a model for forest tree in genome research Chinese Bulletin of Botany, 23 (2006),pp. 286-293
    [8]
    Sharp, PM, Cowe, et al. Synonymous codon usage in Saccharanyces cerevisiae Yeast, 7 (1991),pp. 657-678
    [9]
    Hu, GB, Zhang, et al. Analysis of codon usage between different Citrus species Journal of South China Agricultural University, 27 (2006),pp. 13-16
    [10]
    Lin, T, Ni, et al. Highfrequency codon analysis and its application in codon analysis of tobacco Journal of Xiamen University, 41 (2002),pp. 551-554
    [11]
    Frank, W The effective number of codons usage used in a gene Gene, 87 (1990),pp. 23-29
    [12]
    Zhao, X, Li, et al. Synonymous codon usage in Yarrowia lipolytica Journal of Fudan University (Natural Science), 38 (1999),pp. 510-516
    [13]
    Duret, L, Mouchiroud, et al. Expression pattern and, surprisingly, gene length shape codon usage in Caenorhabditis, Drosophila, and Arabidopsis Proc Natl Acad Sci USA, 96 (1999),pp. 4482-4487
    [14]
    Liu, QP, Xue, et al. Codon usage in the chloroplast genome of rice (Oryza sativa L. ssp japonica) Acta Agronomica Sinica, 30 (2004),pp. 1220-1224
    [15]
    Campbell, WH, Gowri, et al. Codon in higher plants, green algae, and Cyanobacteria Plant Physiol., 92 (1990),pp. 1-11
    [16]
    Panahi, M, Alli, et al. Recombinant protein expression plasmids optimized for industrial E.coli fermentation and plant systems produced biologically active human insulin-like growth factor-1 in transgenic rice and tobacco plants Transgenic Res., 13 (2004),pp. 245-259
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