Abstract
Using a synthetic telomere DNA template and whole cell extracts, we have identified proteins capable of synthesizing the telomere complementary strand. Synthesis of the complementary strand required a DNA template consisting of 10 repeats of the human telomeric sequence d(TTAGGG) and deoxy- and ribonucleosidetriphosphates and was inhibited by neutralizing antibodies to DNA polymerase alpha. No evidence for RNA-independent synthesis of the lagging strand was observed, suggesting that a stable DNA secondary structure capable of priming the lagging strand is unlikely. Purified DNA polymerase alpha/primase was capable of catalyzing synthesis of the lagging strand with the same requirements as those observed in crude cell extracts. A ladder of products was observed with an interval of six bases, suggesting a unique RNA priming site and site-specific pausing or dissociation of polymerase alpha on the d(TTAGGG)10 template. Removal of the RNA primers was observed upon the addition of purified RNase HI. By varying the input rNTP, the RNA priming site was determined to be opposite the 3' thymidine nucleotide generating a five-base RNA primer with the sequence 5'-AACCC. The addition of UTP did not increase the efficiency of priming and extension, suggesting that the five-base RNA primer is sufficient for extension with dNTPs by DNA polymerase alpha. This represents the first experimental evidence for RNA priming and DNA extension as the mechanism of mammalian telomeric lagging strand replication.
Highlights
Semiconservative discontinuous bidirectional DNA replication presents the “end problem” for replication of linear genomes [1]
The first involves RNA priming and DNA extension followed by removal of RNA primers and ligation of the Okazaki-like fragments [3, 4], presumably using the same enzymatic machinery employed for lagging strand synthesis at a replication fork [5, 6]
The structure generated must present a 3Ј-hydroxyl for DNA polymerase1 catalyzed extension for synthesis of the lagging strand followed by a nucleolytic processing reaction to generate a terminal 3Ј-hydroxyl to enable telomerase extension in the round of replication
Summary
(Received for publication, January 8, 1997, and in revised form, February 18, 1997). From the Department of Biochemistry and Molecular Biology, Wright State University School of Medicine, Dayton, Ohio 45435. Purified DNA polymerase ␣/primase was capable of catalyzing synthesis of the lagging strand with the same requirements as those observed in crude cell extracts. The addition of UTP did not increase the efficiency of priming and extension, suggesting that the five-base RNA primer is sufficient for extension with dNTPs by DNA polymerase ␣. This represents the first experimental evidence for RNA priming and DNA extension as the mechanism of mammalian telomeric lagging strand replication. The structure generated must present a 3Ј-hydroxyl for DNA polymerase (pol) catalyzed extension for synthesis of the lagging strand followed by a nucleolytic processing reaction to generate a terminal 3Ј-hydroxyl to enable telomerase extension in the round of replication. The goal of this study was to identify proteins in mammalian whole cell extracts and determine the mechanism for copying a synthetic mammalian telomeric substrate
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