Base stacking and even/odd behavior of hairpin loops in DNA triplet repeat slippage and expansion with DNA polymerase.

Repetitions of CAG or CTG triplets in DNA can form intrastrand hairpin loops with combinations of normal and mismatched base pairs that easily rearrange. Such loops may promote primer-template slippage in DNA replication or repair to give triplet-repeat expansions like those associated with neurodegenerative diseases. Using self-priming sequences (e.g. (CAG)(16)(CTG)(4)), we resolve all hairpin loops formed and measure their slippage and expansion rates with DNA polymerase at 37 degrees C. Comparing CAG/CTG loop structures with GAC/GTC structures, having similar hydrogen bonding but different base stacking, we find that CAG, CTG, and GTC triplets predominantly form even-membered loops that slip in steps of two triplets, whereas GAC triplets favor odd-numbered loops. Slippage rates decline as hairpin stability increases, supporting the idea that slippage initiates more easily in less stable regions. Loop stabilities (in low salt) increase in the order GTC < CAG < GAC < CTG, while slippage rates decrease in the order GTC > CAG approximately GAC > CTG. Loops of GTC compared with CTG melt 9 degrees C lower and slip 6-fold faster. We interpret results in terms of base stacking, by relating melting temperature to standard enthalpy changes for doublets of base pairs and mispairs, considering enthalpy-entropy compensation.

Analysis of strand slippage in DNA polymerase expansions of CAG/CTG triplet repeats associated with neurodegenerative disease.

Lengthy expansions of trinucleotide repeats are found in DNA of patients suffering severe neurodegenerative age-related diseases. Using a synthetic self-priming DNA, containing CAG and CTG repeats implicated in Huntington's disease and several other neurological disorders, we measure the equilibrium distribution of hairpin folding and generate triplet repeat expansions by polymerase-catalyzed extensions of the hairpin folds. Expansions occur by slippage in steps of two CAG triplets when the self-priming sequence (CTG)16(CAG)4 is extended with proofreading-defective Klenow fragment (KF exo-) from Escherichia coli DNA polymerase I. Slippage by two triplets is 20 times more frequent than by one triplet, in accordance with our finding that hairpin loops with even numbers of triplets are 1-2 kcal/mol more stable than their odd-numbered counterparts. By measuring triplet repeat expansions as they evolve over time, individual rate constants for expansion from 4 to 18 CAG repeats are obtained. An empirical expression is derived from the data, enabling the prediction of slippage rates from the ratio of hairpin CTG/CTG interactions to CAG/CTG interactions. Slippage is initiated internally in the hairpin folds in preference to melting inward from the 3' terminus. The same triplet expansions are obtained using proofreading-proficient KF exo+, provided 10-100-fold higher dNTP concentrations are present to counteract the effect of 3'-exonucleolytic proofreading.

Structural organization and developmental expression of the protein isoaspartyl methyltransferase gene from Drosophila melanogaster.

A protein carboxyl methyltransferase activity (PCMT) with a specificity for age-damaged protein D-aspartyl and L-isoaspartyl residues (E.C. 2.1.1.77) has been identified and cloned in Drosophila. The Drosophila gene was localized by chromosome in-situ hybridization to region 83AB of the third chromosome. The methyltransferase coding sequence is distributed among four exons within a 1.4-kb segment of the genome; it predicts a polypeptide of 226 amino acids that is 55% identical to the mouse enzyme. When expressed in bacteria, the Drosophila protein exhibits PCMT activity. A single 1.4-kb Pcmt transcript is detected in RNA preparations from embryos, larvae, pupae and adults. The abundance of the transcript, which is lowest in larvae and highest in adults, parallels the specific activity of the enzyme measured in extracts from the same developmental stages. It has been proposed that the PCMT initiates the repair of structurally damaged cellular proteins. The constitutive expression of PCMT and the relatively high level of expression in postmitotic adult cells suggest that PCMT activity is required through development, but acquires additional significance in aging tissues.