Removal of PCR error products and unincorporated primers by metal-chelate affinity chromatography.

Immobilized Metal Affinity Chromatography (IMAC) has been used for decades to purify proteins on the basis of amino acid content, especially surface-exposed histidines and "histidine tags" genetically added to recombinant proteins. We and others have extended the use of IMAC to purification of nucleic acids via interactions with the nucleotide bases, especially purines, of single-stranded RNA and DNA. We also have demonstrated the purification of plasmid DNA from contaminating genomic DNA by IMAC capture of selectively-denatured genomic DNA.

Large-scale, nonchromatographic purification of plasmid DNA.

A large-scale approach to the purification of plasmid DNA has been developed that overcomes many of the limitations of current chromatography-based processes. The process consists of a scaleable lysis using recombinant lysozyme and a rapid heating and cooling step followed by a selective precipitation with cetyltrimethylammonium bromide (CTAB). Calcium silicate batch adsorption is then utilized to remove residual genomic DNA, linear plasmid, open circular plasmid, endotoxin, detergents, and proteins.

Compaction agent protection of nucleic acids during mechanical lysis.

Mechanical lysis is an efficient and widely used method of liberating the contents of microbial cells, but the sensitivity of large nucleic acids to shear damage has prevented the application of mechanical lysis to DNA purification. It is demonstrated that polycationic compaction agents can protect DNA from shear damage and allow chromosomal and plasmid DNA purification by mechanical lysis. In addition to being substantially protected during mechanical lysis, the compacted DNA can be separated with the insoluble cell debris, washed, and selectively resolubilized, yielding a substantially purified DNA product.

Separation of genomic DNA from plasmid DNA by selective renaturation with immobilized metal affinity capture.

In contrast to proteins, many nucleic acids can undergo reversible modification of their conformations, and this flexibility can be used to facilitate purification. Selective renaturation with capture is a novel method of removing contaminating genomic DNA from plasmid samples. Plasmid DNA quickly renatures after thermal denaturation and cooling (or alkaline denaturation followed by neutralization), whereas genomic DNA remains locally denatured after rapid cooling in mismatch-stabilizing high ionic strength buffer.

Monitoring of RNA clearance in a novel plasmid DNA purification process.

As the field of plasmid DNA-based vaccines and therapeutics matures, improved methods for impurity clearance monitoring are increasingly valuable for process development and scale-up. Residual host-cell RNA is a major impurity in current large-scale separation processes for the production of clinical-grade plasmid DNA. Current RNA detection technologies include quantitative rtPCR, HPLC, and fluorescent dye-based assays.

Nucleic acid separations utilizing immobilized metal affinity chromatography.

Immobilized metal affinity chromatography (IMAC) is widely used for protein purification, e.g., in the isolation of proteins bearing the well-known hexahistidine affinity tag.

Compaction agent clarification of microbial lysates.

Recombinant proteins are often purified from microbial lysates containing high concentrations of nucleic acids. Pre-purification steps such as nuclease addition or precipitation with polyethyleneimine or ammonium sulfate are normally required to reduce viscosity and to eliminate competing polyanions before anion exchange chromatography. We report that small polycationic compaction agents such as spermine selectively precipitate nucleic acids during or after Escherichia coli lysis, allowing DNA and RNA to be pelleted with the insoluble cell debris.

Spermine compaction is an efficient and economical method of producing vaccination-grade DNA.

Plasmid DNA inoculations can induce both humoral and cellular immunity, and this technique is now being employed in developing vaccination regimens for a large number of applications. DNA vaccination studies require the preparation of large amounts of purified plasmid DNA with low endotoxin contamination, and the cost burden for multiple injections, multiple animal or large animal studies is significant. We recently reported that selective compaction with spermine can be used to purify large quantities of DNA.

Enhancement of anion-exchange chromatography of DNA using compaction agents.

The use of adsorptive chromatography for preparative nucleic acid separations is often limited by low capacity. The possibility that the adsorbent surface area sterically accessible to nucleic acid molecules could be increased by reducing their radius of gyration with compaction agents has been investigated. The equilibrium adsorption capacity of Q Sepharose anion-exchange matrix for plasmid DNA at 600 mM NaCl was enhanced by up to ca.