The recent isolation of a number of plant box C/D small nucleolar (sno)RNAs demonstrates theconservation in plants of sequence and structural elements of processed box C/D snoRNAs. Boxes C andD, and terminal inverted repeats are known to be essential for accumulation and processing in vertebratesand yeast. Processing of vertebrate box C/D snoRNAs was examined by expression of various mousehsc70 intron 5-U14 constructs in tobacco protoplasts. Full-length U14 and internally deleted U14 accumu-lated in the plant cells. Human U3 and U8 fragments, consistent with processing to internal box C/C′sequences, also accumulated in the plant cells. The similarity of processing behaviour of the vertebratebox C/D constructs in tobacco protoplasts and Xenopus oocytes suggests the mechanism of processing,involving recognition and association of proteins, is conserved in plants.Keywords: small nucleolar RNA; box C/D small nucleolar RNA; small nucleolar RNA processing; U14.Eukaryotic nuclei contain two major classes of small nucleo- dependent manner (Kiss and Filipowicz, 1995; Cavaille´andlar RNAs (snoRNAs): box C/D and box H/ACA snoRNAs (re- Bachellerie,1996; Kiss et al., 1996). Processing is likely to in-viewed in Maxwell and Fournier, 1995; Tollervey and Kiss, volve exonucleolytic digestion of 5′and 3′sequences flanking1997; Smith and Steitz, 1997). Some box C/D snoRNAs, for the snoRNA, following debranching of the intron lariat (Kissexample, U3, U8, U13, U14 and U22 are involved in processing and Filipowicz, 1995; Cavaille´and Bachellerie, 1996; Kiss etsteps required in the production of mature 18S, 5.8S and 28S al., 1996). In Xenopus oocytes, where processing of U16 andribosomal RNA (rRNA; Maxwell and Fournier, 1995; Tollervey U18 occurs by initial endonucleolytic cleavage in the flankingand Kiss, 1997; Peculis and Steitz, 1994; Tycowski et al., 1994; intron sequences, processing to the mature snoRNA is againBeltrame and Tollervey, 1995; Liang and Fournier, 1995; Ca- likely to be exonucleolytic (Caffarelli et al., 1996).vaille´et al., 1996a). Other box C/D snoRNAs, including U14, Maturation of intronic box C/D and box H/ACA small nucle-contain sequences which are complementary to 18S and 28S olar ribonucleoprotein particles (snoRNPs) requires blockage ofrRNAs and act as guide RNAs to specify sites of 2′-O-ribose exonucleolytic digestion by snoRNP formation via binding ofmethylation of rRNAs (Bachellerie et al., 1995; Cavaille´et al., specific proteins to the snoRNA. The intronic box C/D snoRNAs1996b; Kiss-La´szlo´et al., 1996; Nicoloso et al., 1996; Tykow- contain the conserved box C and D sequences near their 5′andski et al., 1996a, b). The box H/ACA snoRNAs, E3 and U17, 3′termini, respectively, usually flanked by terminal inverted re-are involved in the 5′external transcribed spacer cleavage in peats. The formation of a stem between the inverted repeats and/precursor rRNA (pre-rRNA; Enright et al., 1996). E1 and E2 or the secondary structure of the snoRNA bring the boxes C andare needed for 18S rRNA production and E3 appears to be in- D into juxtaposition, and binding of proteins to the snoRNA andvolved in cleavage at or near the 5′end of 5.8S rRNA (Mishra more particularly to the stem-box C/D structure serves to blockand Eliceiri, 1997) and in yeast snR10 and snR30 are required exonucleolytic degradation (Tycowski et al., 1993; Cafarrelli etfor normal rRNA processing and cell growth (Tollervey, 1987; al., 1996; Watkins et al., 1996; Xia et al., 1997). These se-Morrisey and Tollervey, 1993). However, the majority of box quences/structure have been shown to be sufficient for efficientH/ACA snoRNAs are predicted to be involved in defining sites processing (Caffarelli et al., 1996; Cavaille´ and Bachellerie,of pseudouridylation in rRNAs again involving base-pairing in- 1996; Watkins et al., 1996; Xia et al., 1997). In addition, pro-teractions (Bousquet-Antonelli et al., 1997; Ganot et al., teins including fibrillarin have been shown to associate with the1997a, b; Ni et al., 1997). snoRNA prior to processing (Caffarelli et al., 1996; Watkins etAlthough U3, U8 and U13 are expressed from their own al., 1996). Box H/ACA snoRNAs are also protected from exo-promoters (Dahlberg and Lund, 1988; Tyc and Steitz, 1989), the nucleolytic digestion by virtue of stem-loop structures in the 5′majority of vertebrate box C/D and box H/ACA snoRNAs are and 3′halves of the molecules and by the association of proteins,encoded in introns of protein coding genes (Maxwell and Four- such as Gar1p. The protein components of box H/ACA snoRNPsnier, 1995; Tollervey and Kiss, 1997). The intronic snoRNAs probably bind the conserved box H and ACA sequences whichare produced by processing of the intron in a largely splicing- are essential for accumulation and processing (Kiss and Filipo-wicz, 1995; Kiss et al., 1996; Balakin et al., 1996; Bousquet