The Evolution of CONSTANS-Like Gene Families in Barley, Rice, and Arabidopsis

doi:10.1104/pp.102.016188

The Evolution of CONSTANS-Like Gene Families in Barley, Rice, and Arabidopsis

Simon Griffiths , Roy P. Dunford , George Coupland , and David A. Laurie ^*

John Innes Centre, Norwich Research Park, Colney, Norwich NR4 7UH, United Kingdom

^* Corresponding author; email: david.laurie{at}bbsrc.ac.uk.

The CO (CONSTANS) gene of Arabidopsis has an important rolein the regulation of flowering by photoperiod. CO is part ofa gene family with 17 members that are subdivided into threeclasses, termed Group I to III here. All members of the familyhave a CCT (CO, CO-like, TOC1) domain near the carboxy terminus.Group I genes, which include CO, have two zinc finger B-boxesnear the amino terminus. Group II genes have one B-box, andGroup III genes have one B-box and a second diverged zinc finger.Analysis of rice (Oryza sativa) genomic sequence identified16 genes (OsA-OsP) that were also divided into these three groups,showing that their evolution predates monocot/dicot divergence.Eight Group I genes (HvCO1-HvCO8) were isolated from barley(Hordeum vulgare), of which two (HvCO1 and HvCO2) were highlyCO like. HvCO3 and its rice counterpart (OsB) had one B-boxthat was distantly related to Group II genes and was probablyderived by internal deletion of a two B-box Group I gene. Sequencehomology and comparative mapping showed that HvCO1 was the counterpartof OsA (Hd1), a major determinant of photoperiod sensitivityin rice. Major genes determining photoperiod response have beenmapped in barley and wheat (Triticum aestivum), but none correspondedto CO-like genes. Thus, selection for variation in photoperiodresponse has affected different genes in rice and temperatecereals. The peptides of HvCO1, HvCO2 (barley), and Hd1 (rice)show significant structural differences from CO, particularlyamino acid changes that are predicted to abolish B-box2 function,suggesting an evolutionary trend toward a one-B-box structurein the most CO-like cereal genes.

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