Natural terminal nucleotide sequence

There are three possible models to account for the data which indicate the existence of both inverted and natural terminal nucleotide sequence repetition in the population of purified AAV DNA molecules (Fig. 4). One possible structure would be that the terminal nucleotide sequence repetition is symmetrical. This possibility would be in accord with the fact that the lengths determined for both types of terminal repetition are similar. Two other alternatives are possible. The first is that the inverted and natural terminal repetitions occupy different positions along the genome. In that case the data of Berns and Kelly would probably tend to overestimate the length of the inverted nucleotide sequence repetition if it were subterminal. Likewise the estimate of the length of the natural terminal repetition (1%) by Gerry et al. would be too great if the natural terminal repetition were subterminal. An unlikely third alter-... 

HARRIS, T.J.R. and BROWN, F. 3 -terminal nucleotide sequences in the genomic RNA of picomaviruses. Nature (London), (1978), In Press. 

The current model of the purified DNA is that it is a linear single polynucleotide chain containing a limited number of nucleotide sequence permutations, the start points of which occur within a region representing less than 6% of the genome, and also containing a terminal nucleotide sequence repetition (either inverted, natural, or both). 

The Determination of Nucleotide Sequences In DNA and RNA.—DNA. The methods developed by Sanger and co-workers, reported in the last volume, which use specific chain-terminators (dideoxyribonucleoside triphosphates) have proved particularly valuable when applied to single-stranded DNA. However, the scope of the method was limited to naturally occurring single-stranded DNA or to duplex DNA in which strands could be readily separated. 

Fig. 4. A model of the nucleotide sequence arrangement contained within AAV DNA, Two nucleotide sequence permutations are illustrated. Plus and minus strands may anneal to form duplex linear monomers with (3 and 4) or without cohesive 3 or 5 termini (1 and 2). Duplex linear monomers with cohesive termini can then form duplex circular monomers or duplex linear oligomers. In the figure the terminal repetitions are depicted as symmetrical nucleotide sequences. In the inset two alternative types of terminal repetitions are illustrated the first has the inverted repetition subterminal to the natural repetition, the second illustrates the possibility that a strand may have either an inverted or a natural terminal repetition...

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