Author Correction: Improved genome recovery and integrated cell-size analyses of individual uncultured microbial cells and viral particles.

The original version of this Article contained errors in the units of concentration of three reagents listed in the Methods. These errors have all been corrected in both the PDF and HTML versions of the Article.

Improved genome recovery and integrated cell-size analyses of individual uncultured microbial cells and viral particles.

Microbial single-cell genomics can be used to provide insights into the metabolic potential, interactions, and evolution of uncultured microorganisms. Here we present WGA-X, a method based on multiple displacement amplification of DNA that utilizes a thermostable mutant of the phi29 polymerase. WGA-X enhances genome recovery from individual microbial cells and viral particles while maintaining ease of use and scalability. The greatest improvements are observed when amplifying high G+C content templates, such as those belonging to the predominant bacteria in agricultural soils. By integrating WGA-X with calibrated index-cell sorting and high-throughput genomic sequencing, we are able to analyze genomic sequences and cell sizes of hundreds of individual, uncultured bacteria, archaea, protists, and viral particles, obtained directly from marine and soil samples, in a single experiment. This approach may find diverse applications in microbiology and in biomedical and forensic studies of humans and other multicellular organisms.Single-cell genomics can be used to study uncultured microorganisms. Here, Stepanauskas et al. present a method combining improved multiple displacement amplification and FACS, to obtain genomic sequences and cell size information from uncultivated microbial cells and viral particles in environmental samples.

In vitro evolution of phi29 DNA polymerase using isothermal compartmentalized self replication technique.

Compartmentalized self replication (CSR) is widely used for in vitro evolution of thermostable DNA polymerases able to perform PCR in emulsion. We have modified and adapted CSR technique for isothermal DNA amplification using mezophilic phi29 DNA polymerase and whole genome amplification (WGA) reaction. In standard CSR emulsified bacterial cells are disrupted during denaturation step (94-96°C) in the first circles of PCR. Released plasmid DNA that encodes target polymerase and the thermophilic enzyme complement the emulsified PCR reaction mixture and start polymerase gene amplification. To be able to select for mezophilic enzymes we have employed multiple freezing-thawing cycles of emulsion as a bacterial cell wall disruption step instead of high temperature incubation. Subsequently WGA like plasmid DNA amplification could be performed by phi29 DNA polymerase applying different selection pressure conditions (temperature, buffer composition, modified dNTP, time, etc.). In our case the library of random phi29 DNA polymerase mutants was subjected to seven selection rounds of isothermal CSR (iCSR). After the selection polymerase variant containing the most frequent mutations was constructed and characterized. The mutant phi29 DNA polymerase can perform WGA at elevated temperatures (40-42°C), generate two to five times more of DNA amplification products, and has significantly increased half-life at 30 and 40°C, both in the presence or the absence of DNA substrate.