Abstract
In Chlamydomonas chloroplasts, atpB pre-mRNA matures through a two-step process. Initially, endonuclease cleavage occurs 8-10 nt downstream of the mature 3' end, which itself lies at the end of a stem-loop-forming inverted repeat (IR) sequence. This intermediate product is then trimmed by a 3' -->5' exonuclease activity. Although the initial endonucleolytic cleavage by definition generates two products, the downstream product of atpB pre-mRNA endonucleolytic processing cannot be detected, even transiently. This product thus appears to be highly unstable, and it can be hypothesized that specific mechanisms exist to prevent its accumulation. In experiments described here, the atpB 3' maturation site was placed upstream of reporter genes in vivo. Constructs containing both the IR and endonuclease cleavage site (ECS) did not accumulate the reporter gene mRNA, whereas constructs containing only the IR did accumulate the reporter mRNA. The ECS alone gave an intermediate result, suggesting that the IR and ECS act synergistically. Additional secondary structures were used to test whether 5' -->3' and/or 3' -->5' exonuclease activities mediated degradation. Because these structures did not prevent degradation, rapid endonucleolytic cleavages most likely trigger RNA destruction after ECS cleavage. On the other hand, fragments resulting from cleavage within the endogenous atpB mRNA could occasionally be detected as antisense transcripts of the adjacent reporter genes. Because endonuclease cleavages are also involved in the 5' maturation of chloroplast mRNAs, where only the downstream cleavage product accumulates, it appears that chloroplast endoribonuclease activities have evolved mechanisms to selectively stabilize different ECS products.
Highlights
Maturation of mRNA can involve multiple steps in both prokaryotic and eukaryotic systems, and results in functional transcripts with a stability and subcellular localization appropriate to their functions
Our laboratory has focused on 5Ј end and 3Ј end maturation of chloroplast mRNAs, using both vascular plants and the unicellular green alga Chlamydomonas reinhardtii as models
ϪIRECS antisense uidA mRNA seen in Fig. 2B because the probe has homology to sequences inserted into the ϩ25 position of the uidA reporter gene, as well as to the 5Ј end of this antisense transcript
Summary
GCCCCAAGGCATTCATA CAAAATTCTCCACCAGC CCAGAACAAGCATTCTACTTAGTAGG CCTACTAAGTAGAATGCTTGTTCTGG XbaI-CTGTATCTCGTGGACGAC TAATACGACTCACTATAGGGGGCTCGTGAAGCGGTTATCG AATTAACCCTCACTAAAGGGGTTATTTGCCAACTACCTTA BglII-ATTTGGACACCATTAAGTTG BglII-CAGGTAGCCGAAGGGG CCCCTTCCCCTTCGGGACGTCC GGGAAAGGTGCAACTACGTGGG SmaI-ACTGACATATTTATTTATCCGTTAA BglII-TTTTTTAGCATGTAAACATTAGAAATAC CTAAAATAATCTGTCCGG GACAAGCTTTACATCCC cleavage site (ECS) was placed between two stem-loops or when the artificial transcript was labeled at its 3Ј end. This suggested that some mechanism rapidly degraded the downstream cleavage product, unlike the unprocessed pre-mRNA or matured atpB fragment, both of which were relatively stable in the in vitro system. We show that cleavage at the atpB ECS potentiates rapid degradation of the downstream fragment in vivo, even if it is a coding region or flanked by protective RNA structures. Our data suggest the activity is an endonuclease that acts as part of a targeted RNA recycling mechanism
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