Synthetic single-framework antibody library integrated with rapid affinity maturation by VL shuffling.

Affinity maturation is often applied to improve the properties of antibodies isolated from universal antibody libraries in vitro. A synthetic human scFv antibody library was constructed in single immunoglobulin framework to enable rapid affinity maturation by updated Kunkel's mutagenesis. The initial diversity was generated predominantly in the V(H) domain combined with only 36 V(L) domain variants yielding 3 × 10(10) unique members in the phage-displayed library. After three rounds of panning the enriched V(H) genes from the primary library selections against lysozyme were incorporated into a ready-made circular single-stranded affinity maturation library containing 7 × 10(8) V(L) gene variants. Several unique antibodies with 0.8-10 nM (K(d), dissociation constant) affinities against lysozyme were found after panning from the affinity maturation library, contrasted by only one anti-lysozyme scFv clone with K(d) <20 nM among the clones panned from the primary universal library. The presented single-framework strategy provides a way to convey significant amount of functional V(H) domain diversity to affinity maturation without bimolecular ligation leading to a diverse set of antibodies with binding affinities in the low nanomolar range.

Molecular genetic and structural modeling studies of Staphylococcus aureus RNA polymerase and the fitness of rifampin resistance genotypes in relation to clinical prevalence.

The adaptive and further evolutionary responses of Staphylococcus aureus to selection pressure with the antibiotic rifampin have not been explored in detail. We now present a detailed analysis of these systems. The use of rifampin for the chemotherapy of infections caused by S. aureus has resulted in the selection of mutants with alterations within the beta subunit of the target enzyme, RNA polymerase. Using a new collection of strains, we have identified numerous novel mutations in the beta subunits of both clinical and in vitro-derived resistant strains and established that additional, undefined mechanisms contribute to expression of rifampin resistance in clinical isolates of S. aureus. The fitness costs associated with rifampin resistance genotypes were found to have a significant influence on their clinical prevalence, with the most common clinical genotype (H481N, S529L) exhibiting no fitness cost in vitro. Intragenic mutations which compensate for the fitness costs associated with rifampin resistance in clinical strains of S. aureus were identified for the first time. Structural explanations for rifampin resistance and the loss of fitness were obtained by molecular modeling of mutated RNA polymerase enzymes.