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Mitochondrial replication origin stability and propensity of adjacent tRNA genes to form putative replication origins increase developmental stability in Lizards

2006; Wiley; Volume: 306B; Issue: 5 Linguagem: Inglês

10.1002/jez.b.21095

1552-5015

Hervé Seligmann, Neeraja M. Krishnan,

RNA modifications and cancer

Secondary structure stability of mitochondrial origins of light-strand replication (OL) presumably reduces delayed formation of light-strand initiating replication forks on the heavy strand. Delayed replication initiation prolongs single strandedness of the heavy strand. More mutations accumulate during the prolonged time spent single stranded. Presumably, delayed replication initiation and excess mutations affect mitochondrial biochemical processes and ultimately morphological outcomes of development at the whole-organism level. This predicts that developmental stability increases with OL secondary structure stability and with formation of OL-like structures by the five tRNA genes flanking recognized OLs. Stable OLs and high percentages of OL-resembling secondary structures of adjacent tRNA genes (predicted by Mfold) correlate positively with developmental stability in three lizard families (Anguidae, Amphisbaenidae, and Polychrotidae). Accounting for effects of the regular OL, Sfold-predicted OL-like propensity of the entire tRNA gene cluster (not of individual genes) correlates with increased developmental stability in Anguidae, also across the entire free-energy range of Boltzmann's distribution of secondary structures. In the fossorial Amphisbaenidae, the OL-like structure-forming propensity of tRNA genes correlates positively with developmental stability for the distribution's sub-optimally stable regions, and negatively for its optimally stable regions, suggesting the thermoregulated functioning of OL vs. flanking tRNA genes as replication origins. Results for polychrotid tRNA genes are intermediate. Anguid tRNA genes possibly function in addition to the regular OL. Mitochondrial tRNA genes may thus frequently acquire and lose the alternative OL function, without sequence (gene) duplication and loss of their primary function. J. Exp. Zool. (Mol. Dev. Evol.) 306B, 2006. © 2006 Wiley-Liss, Inc.