A catalogue of biochemically diverse CRISPR-Cas9 orthologs.

Bacterial Cas9 nucleases from type II CRISPR-Cas antiviral defence systems have been repurposed as genome editing tools. Although these proteins are found in many microbes, only a handful of variants are used for these applications. Here, we use bioinformatic and biochemical analyses to explore this largely uncharacterized diversity. We apply cell-free biochemical screens to assess the protospacer adjacent motif (PAM) and guide RNA (gRNA) requirements of 79 Cas9 proteins, thus identifying at least 7 distinct gRNA classes and 50 different PAM sequence requirements. PAM recognition spans the entire spectrum of T-, A-, C-, and G-rich nucleotides, from single nucleotide recognition to sequence strings longer than 4 nucleotides. Characterization of a subset of Cas9 orthologs using purified components reveals additional biochemical diversity, including both narrow and broad ranges of temperature dependence, staggered-end DNA target cleavage, and a requirement for long stretches of homology between gRNA and DNA target. Our results expand the available toolset of RNA-programmable CRISPR-associated nucleases.

Substrate cooperativity in marine luciferases.

Marine luciferases are increasingly used as reporters to study gene regulation. These luciferases have utility in bioluminescent assay development, although little has been reported on their catalytic properties in response to substrate concentration. Here, we report that the two marine luciferases from the copepods, Gaussia princeps (GLuc) and Metridia longa (MLuc) were found, surprisingly, to produce light in a cooperative manner with respect to their luciferin substrate concentration; as the substrate concentration was decreased 10 fold the rate of light production decreased 1000 fold. This positive cooperative effect is likely a result of allostery between the two proposed catalytic domains found in Gaussia and Metridia. In contrast, the marine luciferases from Renilla reniformis (RLuc) and Cypridina noctiluca (CLuc) demonstrate a linear relationship between the concentration of their respective luciferin and the rate of light produced. The consequences of these enzyme responses are discussed.

Transcription of a donor enhances its use during double-strand break-induced gene conversion in human cells.

Homologous recombination (HR) mediates accurate repair of double-strand breaks (DSBs) but carries the risk of large-scale genetic change, including loss of heterozygosity, deletions, inversions, and translocations. Nearly one-third of the human genome consists of repetitive sequences, and DSB repair by HR often requires choices among several homologous repair templates, including homologous chromosomes, sister chromatids, and linked or unlinked repeats. Donor preference during DSB-induced gene conversion was analyzed by using several HR substrates with three copies of neo targeted to a human chromosome. Repair of I-SceI nuclease-induced DSBs in one neo (the recipient) required a choice between two donor neo genes. When both donors were downstream, there was no significant bias for proximal or distal donors. When donors flanked the recipient, we observed a marked (85%) preference for the downstream donor. Reversing the HR substrate in the chromosome eliminated this preference, indicating that donor choice is influenced by factors extrinsic to the HR substrate. Prior indirect evidence suggested that transcription might increase donor use. We tested this question directly and found that increased transcription of a donor enhances its use during gene conversion. A preference for transcribed donors would minimize the use of nontranscribed (i.e., pseudogene) templates during repair and thus help maintain genome stability.

Gene conversion and deletion frequencies during double-strand break repair in human cells are controlled by the distance between direct repeats.

Homologous recombination (HR) repairs DNA double-strand breaks and maintains genome stability. HR between linked, direct repeats can occur by gene conversion without an associated crossover that maintains the gross repeat structure. Alternatively, direct repeat HR can occur by gene conversion with a crossover, or by single-strand annealing (SSA), both of which delete one repeat and the sequences between the repeats. Prior studies of different repeat structures in yeast and mammalian cells revealed disparate conversion:deletion ratios. Here, we show that a key factor controlling this ratio is the distance between the repeats, with conversion frequency increasing linearly with the distances from 850 to 3800 bp. Deletions are thought to arise primarily by SSA, which involves extensive end-processing to reveal complementary single-strands in each repeat. The results can be explained by a model in which strand-invasion leading to gene conversion competes more effectively with SSA as more extensive end-processing is required for SSA. We hypothesized that a transcription unit between repeats would inhibit end-processing and SSA, thereby increasing the fraction of conversions. However, conversion frequencies were identical for direct repeats separated by 3800 bp of transcriptionally silent or active DNA, indicating that end-processing and SSA are not affected by transcription.

Gene conversion tracts in Saccharomyces cerevisiae can be extremely short and highly directional.

Gene conversion is a common outcome of double-strand break (DSB) repair in yeast. Prior studies revealed that DSB-induced gene conversion tracts are often short (<53 bp), unidirectional, and biased toward promoter-proximal (5') markers. In those studies, broken ends had short, non-homologous termini. For the present study we created plasmid x chromosome, chromosomal direct repeat and allelic recombination substrates in which donor alleles carried mutant HO sites (HOinc--not cleaved) at the same position as cleavable HO sites in recipient alleles. In these substrates, broken ends are almost completely homologous to donor alleles, differing only at the three HOinc mutations. These mutations serve as markers very close to, or within, the four-base overhang produced by HO nuclease. We identified extremely short tracts (<12 bp) and many tracts were highly directional, extending <2 bp on one side of the DSB. We thought that terminal homology would promote bidirectional tracts, but found instead that unidirectional tracts were more frequent. Interestingly, substrates with terminal homology displayed enhanced 3' conversion, and in several cases conversion bias was reversed toward 3' markers. These results are discussed in relation to factors that may influence tract length and directionality, including heteroduplex DNA formation, transcription, replication and mismatch repair.