A novel gene organization: intronic snoRNA gene clusters from Oryza sativa

doi:10.1093/nar/gkf426

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Nucleic Acids Research, 2002, Vol. 30, No. 14 3262-3272
© 2002 Oxford University Press

A novel gene organization: intronic snoRNA gene clusters from Oryza sativa

Dan Liang, Hui Zhou, Peng Zhang, Yue-Qin Chen, Xiao Chen, Chun-Long Chen and Liang-Hu Qu^*

Key Laboratory of Gene Engineering of Education Ministry, Biotechnology Research Center, Zhongshan University, Guangzhou 510275, People’s Republic of China

*To whom correspondence should be addressed. Tel: +86 20 84112399; Fax: +86 20 84036551; Email: lsbrc04{at}zsu.edu.cn
⁺AJ320255, AJ320256, AJ307912–AJ307932, AJ320263, AJ320264, AJ315478, AJ315479

Based on the analysis of structural features and conserved elements,27 novel snoRNA genes have been identified from rice. All ofthem belong to the C/D box-containing snoRNA family except forone that belongs to the H/ACA box type. The newly found genesfall into six clusters that comprise at least three snoRNA genes,and in one case as many as nine genes. Interestingly, four ofthe six clusters are located within the largest intron of aprotein coding gene. The majority of intronic snoRNA gene clustersare simply formed by multiple copies of the same species ofsnoRNA gene that possess the identical functional elements.This implies a possible mechanism of duplication for the originof repeating snoRNA coding regions in one intron. However, afew intronic snoRNA gene clusters consisting of different snoRNAsspecies were also observed. Polycistronic precursors from twoindependently transcribed clusters were demonstrated by RT–PCRand individual snoRNAs processed from the polycistronic precursorswere positively determined by reverse transcription assay. Analysesof the intergenic spacers in the clusters showed that, in additionto a very high AT content, the processing signals in rice snoRNApolycistronic transcripts might be different from those of yeast.Our results demonstrate that, in both plants and mammals, numeroussnoRNAs can be produced simultaneously from an mRNA precursorof a host gene despite the different arrangements. The intronicsnoRNA gene cluster is a novel gene organization, which is sofar unique to plants. The conservation of intronic snoRNA geneclusters in plants was further demonstrated by the study ofa similar snoRNA gene organization in the first intron of aHsp70 gene from wild rice and Zizania caduciflora.

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