Femtomolar Fab binding affinities to a protein target by alternative CDR residue co-optimization strategies without phage or cell surface display.

In therapeutic or diagnostic antibody discovery, affinity maturation is frequently required to optimize binding properties. In some cases, achieving very high affinity is challenging using the display-based optimization technologies. Here we present an approach that begins with the creation and clonal, quantitative analysis of soluble Fab libraries with complete diversification in adjacent residue pairs encompassing every complementarity-determining region position. This was followed by alternative recombination approaches and high throughput screening to co-optimize large sets of the found improving mutations. We applied this approach to the affinity maturation of the anti-tumor necrosis factor antibody adalimumab and achieved ~500-fold affinity improvement, resulting in femtomolar binding. To our knowledge, this is the first report of the in vitro engineering of a femtomolar affinity antibody against a protein target without display screening. We compare our findings to a previous report that employed extensive mutagenesis and recombination libraries with yeast display screening. The present approach is widely applicable to the most challenging of affinity maturation efforts.

Retinoic acid induces prostatic bud formation.

Formation of prostatic buds from the urogenital sinus (UGS) to initiate prostate development requires localized action of several morphogenetic factors. This report reveals all-trans-retinoic acid (RA) to be a powerful inducer of mouse prostatic budding that is associated with reciprocal changes in expression of two regulators of budding: sonic hedgehog (Shh) and bone morphogenetic protein 4 (Bmp4). Localization of retinoid signaling and expression of RA synthesis, metabolism, and receptor genes in the UGS on embryonic days 14.5-17.5 implicate RA in the mechanism of bud initiation. In UGS organ culture, RA increased prostatic budding, increased Shh expression, and decreased Bmp4. Prostatic budding was stimulated in the absence of RA by recombinant SHH, by blocking BMP4 signaling with NOGGIN, or by combined treatment with SHH and NOGGIN in UGS organ culture media. These observations suggest that reciprocal changes in hedgehog and BMP signaling by RA may regulate bud initiation.

Modified oligonucleotides as tools for allele-specific amplification.

Allele-specific polymerase chain reaction (PCR), a method that reports nucleotide variations through either the presence or the absence of a DNA product obtained through PCR amplification, holds the promise to combine target amplification and analysis in one single step. Recently, it has been reported that the selectivity of allele-specific PCR can be significantly increased through the employment of chemically modified primer probes. Here, we report on significant developments of primer probe design and synthesis along this line.

Directed DNA polymerase evolution: effects of mutations in motif C on the mismatch-extension selectivity of thermus aquaticus DNA polymerase.

The selectivity of DNA polymerases for processing the canonical nucleotide and DNA substrate in favor of the noncanonical ones is the key to the integrity of the genome of every living species and to many biotechnological applications. The inborn ability of most DNA polymerases to abort efficient extension of mismatched DNA substrates adds to the overall DNA polymerase selectivity. DNA polymerases have been grouped into families according to their sequence. Within family A DNA polymerases, six motifs that come into contact with the substrates and form the active site have been discovered to be evolutionary highly conserved. Here we present results obtained from amino acid randomization within one motif, motif C, of thermostable Thermus aquaticus DNA polymerase. We have identified several distinct mutation patterns that increase the selectivity of mismatch extension. These results might lead to direct applications such as allele-specific PCR, as demonstrated by real-time PCR experiments and add to our understanding of DNA polymerase selectivity.

Genotyping--from genomic DNA to genotype in a single tube.

Nucleotide variations in the human genome, such as single-nucleotide polymorphisms, have been researched more intensively since it became apparent that these deviations are linked to various diseases and also several side effects of drugs. The investigation of genomic DNA in the laboratory requires routine methods that are time-, labour-, and cost-effective. These criteria are fulfilled by so-called closed-tube methods, which are applied directly to isolated genomic DNA without any preamplification.

Increased single-nucleotide discrimination of PCR by primer probes bearing hydrophobic 4'C modifications.

We report on significantly increased selectivity of real-time PCR through employment of primer probes that bear hydrophobic 4'C modifications at the 3'-terminal nucleotide. The primer probes were designed to bind the target sequences in such a way that the 3'-terminal nucleotide defines whether a matched or a single mismatched basepair is present depending on the respective target sequence. Several commercially available thermostable DNA polymerases belonging to different DNA polymerase families were tested for their efficacy in discriminating between PCR amplification of matched substrates and duplexes that contain a single mismatch. It turned out that, depending on the 4'C modification and the employed DNA polymerase, significantly increased differentiation between single matches and mismatches could be observed with real-time PCR. The degrees of the observed effects varied with the employed 4'C modification and the sequence context studied. The system is robust enough to work faithfully under several buffer conditions. Our approach should be useful for the direct diagnosis of single nucleotide variations within genes, like single nucleotide polymorphisms or mutations, by PCR without the need for further time- and cost-intensive post-PCR analysis.

Application of the C4'-alkylated deoxyribose primer system (CAPS) in allele-specific real-time PCR for increased selectivity in discrimination of single nucleotide sequence variants.

This study describes a quantitative real-time PCR-based approach for discrimination of single nucleotide sequence variants, called CAPS (C4' alkylated primer system). To increase the discrimination potential of DNA polymerases against competing sequence variants of single nucleotides, 3'-terminally modified primers were designed carrying a methyl residue bound to the C4' of the thymidylate deoxyribose. In a model sequence system positional dependencies of modified thymidylate (at -1, -2, -3) were tested for their influence on discrimination. Highest discrimination factors were obtained with the modification at the ultimate 3'-position. In a comparison between Taq and Pwo DNA polymerases, substantial better results were obtained by Taq DNA polymerase. In contrast to conventional PCR methods for discrimination of sequence variants, achieving a maximum discrimination potential of about 20, CAPS is capable of obtaining sequence-specific amplifications of a desired target among discriminated templates with a dynamic range of 1:100. Therefore, CAPS is a method able to quantitatively discriminate two sequence variants only differing in a single base (e.g., SNP alleles or point mutations). The range of applications of this easy to perform, fast and reliable technique reaches from medical diagnostics, transplantation medicine, molecular and cell biology to human genetics. Targeting of SNPs assures a universal exertion of this method, since these markers are gender-independent, highly abundant and ubiquitous.

Implications of active site constraints on varied DNA polymerase selectivity.

DNA polymerase selectivity often varies significantly depending on the DNA polymerase. The origin of this varying error propensity is elusive. It is assumed that DNA polymerases form nucleotide binding pockets that differ in properties such as shape and tightness. We tested this prediction and studied HIV-1 RT by employment of size-augmented nucleotides and site-directed mutagenesis of the enzyme. New valuable insights into the mechanism of DNA polymerase fidelity were obtained. The presented study provides experimental evidence that variations of steric constraints within the nucleotide binding pocket of at least two DNA polymerases cause variations in nucleotide incorporation selectivity. Thus, our results support the concept of active site tightness as a causative in differential fidelity among DNA polymerases.

Exploring the effects of active site constraints on HIV-1 reverse transcriptase DNA polymerase fidelity.

To examine the concept of polymerase active site tightness as a criteria for DNA polymerase fidelity, we performed pre-steady-state single nucleotide incorporation kinetic analyses with sugar modified thymidine 5'-triphosphate (TTP) analogues and human immunodeficiency virus (HIV-1) reverse transcriptase (RT). The employed TTP analogues (T(R)TP) are modified at the 4'-position of the sugar moiety with alkyl groups, gradually expanding their steric demand. Introduction of a methyl group reduces the maximum rate of nucleotide incorporation by about 200-fold for RT(WT) and about 400-fold for RT(M184V). Interestingly, the affinity of RT for the modified nucleotide is only marginally affected. Increasing the size to an ethyl group leads to further reduction of the rate of incorporation and first effects on binding affinities are observed. Finally, substitution for an isopropyl group results not only in a further reduction of incorporation rates but also in a dramatic loss of binding affinity for the nucleotide analogue. By increasing the steric demand the effects on RT(M184V) in comparison with RT(WT) become progressively more pronounced. Misincorporation of either TTP or T(Me)TP opposite a template G causes additional decline in incorporation rates accompanied by a drastic decrease in binding affinities. This results in relative incorporation efficiencies [(k(pol)/K(d))(incorrect)/(k(pol)/K(d))(TTPcorrect)] of 4.1 x 10(-5) for TTP and 3.4 x 10(-6) for T(Me)TP in case of RT(WT) and 1.4 x 10(-5) for TTP and 2.9 x 10(-8) for T(Me)TP in case of RT(M184V).