A method for high-throughput production of sequence-verified DNA libraries and strain collections.

The low costs of array-synthesized oligonucleotide libraries are empowering rapid advances in quantitative and synthetic biology. However, high synthesis error rates, uneven representation, and lack of access to individual oligonucleotides limit the true potential of these libraries. We have developed a cost-effective method called Recombinase Directed Indexing (REDI), which involves integration of a complex library into yeast, site-specific recombination to index library DNA, and next-generation sequencing to identify desired clones. We used REDI to generate a library of ~3,300 DNA probes that exhibited > 96% purity and remarkable uniformity (> 95% of probes within twofold of the median abundance). Additionally, we created a collection of ~9,000 individually accessible CRISPR interference yeast strains for > 99% of genes required for either fermentative or respiratory growth, demonstrating the utility of REDI for rapid and cost-effective creation of strain collections from oligonucleotide pools. Our approach is adaptable to any complex DNA library, and fundamentally changes how these libraries can be parsed, maintained, propagated, and characterized.

Base excision repair in early zebrafish development: evidence for DNA polymerase switching and standby AP endonuclease activity.

The base excision repair (BER) pathway recognizes and repairs most nonbulky lesions, uracil and abasic (AP) sites in DNA. Several participants are embryonic lethals in knockout mice. Since the pathway has never been investigated during embryogenesis, we characterized the first three steps of BER in zebrafish extracts from unfertilized eggs, embryos at different developmental stages, and adults. Using a 45-mer double-stranded substrate with a U/G mispair at position 21, we showed that extracts from all stages are capable of performing BER. Before 3 days postfertilization (dpf), aphidicolin-sensitive polymerases perform most nucleotide insertion. In fact, eggs and early stage embryos lack DNA polymerase-beta protein. After the eggs have hatched at 3 dpf, an aphidicolin-resistant polymerase, probably DNA polymerase-beta, becomes the primary polymerase. Previously, we showed that when the zebrafish AP endonuclease protein (ZAP1) level is knocked down, embryos cease dividing after the initial phase of rapid proliferation and die without apoptosis shortly thereafter. Nevertheless, extracts from embryos in which ZAP1 has been largely depleted process substrate as well as extracts from control embryos. Since apex1 and apex2 are both strongly expressed in early embryos relative to adults, these data indicate that both may play important roles in DNA repair in early development. In brief, the major differences in BER performed by early stage embryos and adults are the absence of DNA polymerase-beta, leading to predominance of replicative polymerases, and the presence of backup Mg(2+)-dependent endonuclease activity in early stage embryos. The switch to normal, adult BER occurs fully when the embryos hatch from the chorionic membrane and encounter normal oxidative stress.

Mutagenic specificity of endogenously generated abasic sites in Saccharomyces cerevisiae chromosomal DNA.

Abasic [apurinic/apyrimidinic (AP)] sites are common, noncoding DNA lesions. Despite extensive investigation, the mutational pattern they provoke in eukaryotic cells remains unresolved. We constructed Saccharomyces cerevisiae strains in which chromosomal AP sites were generated during normal cell growth by altered human uracil-DNA glycosylases that remove undamaged cytosines or thymines. The mutation target was the URA3 gene inserted near the ARS309 origin to allow defined replication polarity. Expression of the altered glycosylases caused a 7- to 18-fold mutator effect in AP endonuclease-deficient (deltaapn1) yeast, which depended highly on the known translesion synthesis enzymes Rev1 and DNA polymerase zeta. For the C-glycosylase, GC>CG transversions were the predominant mutations, followed by GC>AT transitions. AT>CG transversions predominated for the T-glycosylase. These results support a major role for Rev1-dependent dCMP insertion across from AP sites and a lesser role for dAMP insertion. Unexpectedly, there was also a significant proportion of dTMP insertions that suggest another mutational pathway at AP sites. Although replication polarity did not strongly influence mutagenesis at AP sites, for certain mutation types, there was a surprisingly strong difference between the transcribed and non-transcribed strands of URA3. The basis for this strand discrimination requires further exploration.