Abstract
Deep sequencing of viral or bacterial nucleic acids monitors the presence and diversity of microbes in select populations and locations. Metagenomic study of mammalian viromes can help trace paths of viral transmissions within or between species. High throughput sequencing of patient and untreated sewage microbiomes showed many sequences with no similarity to genomic sequences of known function or origin. To estimate the distribution of functional RNAs in these microbiomes, we used the hammerhead ribozyme (HHR) motif to search for sequences capable of assuming its three-way junction fold. Although only two of the three possible natural HHR topologies had been known, our analysis revealed highly active ribozymes that terminated in any of the three stems. The most abundant of these are type II HHRs, one of which is the fastest natural cis-acting HHR yet discovered. Altogether, 13 ribozymes were confirmed in vitro, but only one showed sequence similarity to previously described HHRs. Sequences surrounding the ribozymes do not generally show similarity to known genes, except in one case, where a ribozyme is immediately preceded by a bacterial RadC gene. We demonstrate that a structure-based search for a known functional RNA is a powerful tool for analysis of metagenomic datasets, complementing sequence alignments.
Highlights
RNAs fulfill diverse biological roles, including regulation and catalysis
In vitro selection experiments have identified a variety of self-cleaving ribozymes (13), including the hammerhead motif, which was found independently several times (14)
Hammerhead ribozymes were originally discovered in plant viroids and virusoids, where they function in the processing of rolling circle transcripts (21)
Summary
Sample Preparation—Raw samples from various virome studies were collected from the environment or with patient consent in the case of blood and bodily fluid collection. Scheme 1 shows an example of a descriptor for a type II hammerhead ribozyme requiring strict Watson-Crick base pairing in the helical regions. The cleavage site can consist of any nucleotide except G in element s4 In this descriptor, we require 9-nt regions flanking the 5Ј and 3Ј ends of the ribozyme motif (s1 and s7, respectively). Forward primers included the T7 RNA polymerase promoter followed by “gggaga” to facilitate transcription, except in the cases in which the 5Ј end of the construct was G-rich. The following is the construct designed for one of the type II HHRs shown in Fig. 1: SewS1_01145s-1, ribozyme construct, 5Ј-gggaga GGA CUU GGU CUU CUA ACG AGU ACG CGA AAC CCU GGU ACG CCC ACC CAG GGU CGC CGG GAA AUC GGC CCG GCC UGA UGA GCG AUA UUC ACU-3Ј. GenBank accession numbers for each ribozyme are listed under Identity
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
