An internal tRNA-like structure regulates the life cycle of a plus-sense RNA virus
by McCormack, John Crisler, Iii, Ph.D., UNIVERSITY OF MARYLAND, COLLEGE PARK, 2007, 195 pages; 3297378

Abstract:

Turnip crinkle virus (TCV) is a 4054 b plus-sense RNA virus that belongs to the genus Carmovirus in the Family Tombusviridae. The 3' terminal 200 b of TCV are predicted to fold into 5 hairpins labeled in the 3' to 5' direction as the promoter (Pr), hairpin 5 (H5), hairpin 4b (H4b), hairpin 4a (H4a), and hairpin 4 (H4), using 3' UTR phylogenetic comparisons with other carmoviruses and the RNA structural prediction program, mfold. H5 was found to be a highly-conserved structure containing a large symmetrical loop (LSL) that formed a tertiary interaction between the 3' side of the LSL and the 3' terminal nucleotides using compensatory mutational analysis in vivo. In plants, LSL mutations resulted in a mutation frequency that was increased by as much as 12-fold without inducing error catastrophe. The original mutations frequently reverted and led to second site alterations biased for uridylate to cytidylate and adenylate to guanylate changes. These results suggest that H5 may function as a chaperone to properly fold the RdRp.

The TCV 5' UTR, which binds 40S ribosomal subunits, contains two short segments exhibiting IRES activity that function synergistically with the 3' terminal region to enhance cap-independent translation in vivo. In the TCV 3' UTR, H4a, H4b, H5, and flanking sequences, form an internal tRNA-like structure (iTLS) that binds 60S ribosomal subunits and the P-site of salt washed 80S ribosomes. The iTLS may therefore mediate assembly of 80S ribosomes, which are then transported to the 5' end for translation of virally-encoded proteins.

Phylogenetic comparisons of carmovirus 3' UTRs revealed that Cardamine chlorotic fleck virus (CCFV) and Japanese iris necrotic ring virus (JINRV) are capable of forming the 5 elemental features comprising the iTLS. Ribosome binding and plant cell culture assays showed that only the CCFV iTLS bound 80S ribosomes and could functionally replace the TCV iTLS. These results suggest that closely-related members of the same viral genus may utilize different strategies for cap-independent translation.

 
AdviserAnne E. Simon
SchoolUNIVERSITY OF MARYLAND, COLLEGE PARK
SourceDAI/B 69-02, p. , May 2008
Source TypeDissertation
SubjectsMolecular biology; Genetics; Virology
Publication Number3297378
Adobe PDF Access the complete dissertation:
 

» Find an electronic copy at your library.
  Use the link below to access a full citation record of this graduate work:
  http://gateway.proquest.com/openurl%3furl_ver=Z39.88-2004%26res_dat=xri:pqdiss%26rft_val_fmt=info:ofi/fmt:kev:mtx:dissertation%26rft_dat=xri:pqdiss:3297378
  If your library subscribes to the ProQuest Dissertations & Theses (PQDT) database, you may be entitled to a free electronic version of this graduate work. If not, you will have the option to purchase one, and access a 24 page preview for free (if available).

About ProQuest Dissertations & Theses
With over 2.3 million records, the ProQuest Dissertations & Theses (PQDT) database is the most comprehensive collection of dissertations and theses in the world. It is the database of record for graduate research.

The database includes citations of graduate works ranging from the first U.S. dissertation, accepted in 1861, to those accepted as recently as last semester. Of the 2.3 million graduate works included in the database, ProQuest offers more than 1.9 million in full text formats. Of those, over 860,000 are available in PDF format. More than 60,000 dissertations and theses are added to the database each year.

If you have questions, please feel free to visit the ProQuest Web site - http://www.proquest.com - or call ProQuest Hotline Customer Support at 1-800-521-3042.