Novel Genomic and Evolutionary Perspective of Cyanobacterial tRNAs.

Transfer RNA (tRNA) plays a central role in protein synthesis and acts as an adaptor molecule between an mRNA and an amino acid. A tRNA has an L-shaped clover leaf-like structure and contains an acceptor arm, D-arm, D-loop, anti-codon arm, anti-codon loop, variable loop, Ψ-arm and Ψ-loop. All of these arms and loops are important in protein translation. Here, we aimed to delineate the genomic architecture of these arms and loops in cyanobacterial tRNA. Studies from tRNA sequences from 61 cyanobacterial species showed that, except for few tRNAs (tRNA^Asn, tRNA^Leu, tRNA^Gln, and tRNA^Met), all contained a G nucleotide at the 1st position in the acceptor arm. tRNA^Leu and tRNA^Met did not contain any conserved nucleotides at the 1st position whereas tRNA^Asn and tRNA^Gln contained a conserved U1 nucleotide. In several tRNA families, the variable region also contained conserved nucleotides. Except for tRNA^Met and tRNA^Glu, all other tRNAs contained a conserved A nucleotide at the 1st position in the D-loop. The Ψ-loop contained a conserved U¹-U²-C³-x-A⁵-x-U⁷ sequence, except for tRNA^Gly, tRNA^Ala, tRNA^Val, tRNA^Phe, tRNA^Thr, and tRNA^Gln in which the U⁷ nucleotide was not conserved. However, in tRNA^Asp, the U⁷ nucleotide was substituted with a C⁷ nucleotide. Additionally, tRNA^Arg, tRNA^Gly, and tRNA^Lys of cyanobacteria contained a group I intron within the anti-codon loop region. Maximum composite likelihood study on the transition/transversion of cyanobacterial tRNA revealed that the rate of transition was higher than the rate of transversion. An evolutionary tree was constructed to understand the evolution of cyanobacterial tRNA and analyses revealed that cyanobacterial tRNA may have evolved polyphyletically with high rate of gene loss. [ABSTRACT FROM AUTHOR]