Complete Genome Sequence of Alkaliphilus metalliredigens Strain QYMF, an Alkaliphilic and Metal-Reducing Bacterium Isolated from Borax-Contaminated Leachate Ponds.

Alkaliphilus metalliredigens strain QYMF is an anaerobic, alkaliphilic, and metal-reducing bacterium associated with phylum Firmicutes QYMF was isolated from alkaline borax leachate ponds. The genome sequence will help elucidate the role of metal-reducing microorganisms under alkaline environments, a capability that is not commonly observed in metal respiring-microorganisms.

Magnetic bead purification of labeled DNA fragments for high-throughput capillary electrophoresis sequencing.

We have developed an automated purification method for dye-terminator-based DNA sequencing products using a magnetic bead approach. This 384-well protocol generates sequence fragments that are essentially free of template DNA, salt, and excess dye-terminator products. In comparison with traditional ethanol precipitation protocols, this method uses no centrifugation, is rapid, completely automated, and increases the phred-20 read length by an average of 40 bases. To date, we have processed over 4 million samples with 94% averaging 641 phred-20 bases on the MegaBACE 1000 and 4000 and the ABI PRISM 3700 capillary instruments.

High-throughput plasmid purification for capillary sequencing.

The need for expeditious and inexpensive methods for high-throughput DNA sequencing has been highlighted by the accelerated pace of genome DNA sequencing over the past year. At the Joint Genome Institute, the throughput in terms of high-quality bases per day has increased over 20-fold during the past 18 mo, reaching an average of 18.3 million bases per day. To support this unprecedented scaleup, we developed an inexpensive automated method for the isolation and purification of double-stranded plasmid DNA clones for sequencing that is tailored to meet the more stringent needs of the newer capillary electrophoresis DNA sequencing machines. The protocol is based on the magnetic bead method of solid phase reversible immobilization that has been automated by using a CRS-based robotic system. The method described here has enabled us to meet our increases in production while reducing labor and materials costs significantly.