LigAmp for sensitive detection of single-nucleotide differences

We developed the LigAmp assay for sensitive detection and accurate quantification of viruses and cells with single-base mutations. In LigAmp, two oligonucleotides are hybridized adjacently to a DNA template. One oligonucleotide matches the target sequence and contains a probe sequence. If the target sequence is present, the oligonucleotides are ligated together and detected using real-time PCR. LigAmp detected KRAS2 mutant DNA at 0.01% in mixtures of different cell lines. KRAS2 mutations were also detected in pancreatic duct juice from patients with pancreatic cancer. LigAmp detected the K103N HIV-1 drug resistance mutation at 0.01% in plasmid mixtures and at approximately 0.1% in DNA amplified from plasma HIV-1. Detection in both systems is linear over a broad dynamic range. Preliminary evidence indicates that reactions can be multiplexed. This assay may find applications in the diagnosis of genetic disorders and the management of patients with cancer and infectious diseases.     

Engineering M13 for phage display

Phage display is achieved by fusing polypeptide libraries to phage coat proteins. The resulting phage particles display the polypeptides on their surfaces and they also contain the encoding DNA. Library members with particular functions can be isolated with simple selections and polypeptide sequences can be decoded from the encapsulated DNA. The technology's success depends on the efficiency with which polypeptides can be displayed on the phage surface, and significant progress has been made in engineering M13 bacteriophage coat proteins as improved phage display platforms. Functional display has been achieved with all five M13 coat proteins, with both N- and C-terminal fusions. Also, coat protein mutants have been designed and selected to improve the efficiency of heterologous protein display, and in the extreme case, completely artificial coat proteins have been evolved specifically as display platforms. These studies demonstrate that the M13 phage coat is extremely malleable, and this property can be used to engineer the phage particle specifically for phage display. These improvements expand the utility of phage display as a powerful tool in modern biotechnology.     

Use of phage display to select novel cystatins specific for Acanthoscelides obtectus cysteine proteinases

Cysteine proteinases from larvae of the common bean weevil, Acanthoscelides obtectus (Coleoptera: Bruchidae), were isolated by ion exchange affinity chromatography on a CM-Cellulose column and used to select mutant cystatins from a library made with the filamentous M13 phage display system. The library contained variant cystatins derived from the nematode Onchocerca volvulus cystatin through mutagenesis of loop 1, which contains the QVVAG motif that is involved in binding to proteinases. After three rounds of selection, the activity of variant cystatins against papain and cysteine proteinases from A. obtectus was assayed by ELISA. Two different variant cystatins (presenting amino acids DVVSA and NTSSA at positions 65-69) bound to A. obtectus cysteine proteinases more tightly than to papain. In contrast, the wild type had similar affinity for A. obtectus proteinases and for papain. These two selected variants cystatins have greater specificity towards A. obtectus cysteine proteinases than the original sequence and could represent good candidate genes for the production of transgenic plants resistant to this insect pest.     

Ethnic differences in the linkage disequilibrium and distribution of single-nucleotide polymorphisms in 35 candidate genes for cardiovascular diseases

Single-nucleotide polymorphisms (SNPs) are commonly used to study genetics for common diseases and predict pharmacological response. The selection of likely informative SNPs in association studies depends on their allele frequencies and on the linkage disequilibrium (LD) between SNPs, both of which may show interethnic differences. Among three populations consisting of 207 Chinese, 858 French, and 395 Spanish, we compared the allele frequency distributions of 64 intragenic SNPs of 35 candidate genes for cardiovascular diseases. Twenty-eight of these SNPs from 12 genes were also examined for intragenic LD. About 20% of SNPs were restricted to Europeans, being monomorphic in Chinese, among them mostly nonsynonymous coding SNPs and noncoding SNPs. Only 1.6% of SNPs were specific in Chinese, commensurate with the detection of these SNPs almost exclusively in Caucasians. Similarly, these SNPs were more often rare (<0.1 minor allele frequency) in Chinese (44.3%) than in Europeans (31.1%). The variant allele frequencies and intermarker LDs in terms of D' and Delta(2) were highly correlated between French and Spanish populations (r = 0.98-0.99, p < 0.001). However, only moderate correlations of allele frequencies and D' were found between the Chinese and the European populations (r = 0.7 and 0.3, respectively) despite a high correlation of Delta(2) values (r = 0.8). These results suggest that ethnic considerations are important in the selection of SNPs for association studies of candidate genes, as this may affect the power of the study as well as the likelihood of asking relevant questions and getting medically meaningful answers.     

Automation of phage display for high-throughput antibody development

Antibodies are important tools for the detection of diagnostic markers and are the most well-known examples of specific molecular interactions. We have developed automated technology that enables the selection of antibodies and other interacting molecules from large recombinant libraries. The physical link between phenotype and genotype in phage display allows selective isolation and amplification of a particular phage encoding a desired antibody fragment. Successive rounds of phage selection, amplification and screening are performed at high throughput, using a pin-based magnetic particle processor. The integration of this with existing DNA and protein array technology enables industrial screening of complex libraries and opens up a new level of functional genomic analysis.     

Concepts in antibody phage display.

This paper introduces the reader to antibody phage display and its use in combinatorial biochemistry. The focus is on overviewing phage display formats, library design and selection technology, which are the prerequisites for the successful isolation of specific antibody fragments against a diverse set of target antigens.     

The scope of phage display for membrane proteins

Numerous examples of phage display applied to soluble proteins demonstrate the power of the technique for protein engineering, affinity reagent discovery and structure-function studies. Recent reports have expanded phage display to include membrane proteins (MPs). The scope and limitations of MP display remain undefined. Therefore, we report data from the phage display of representative types of membrane-associated proteins including plasma, nuclear, peripheral, single and multipass. The peripheral MP neuromodulin displays robustly with packaging by conventional M13-KO7 helper phage. The monotopic MP Nogo-66 can also display on the phage surface, if packaged by the modified M13-KO7⁺ helper phage. The modified phage coat of KO7⁺ can better mimic the zwitterionic character of the plasma membrane. Four examples of putatively α-helical, integral MPs failed to express as fusions to an anchoring phage coat protein and therefore did not display on the phage surface. However, the β-barrel MPs ShuA (Shigella heme uptake A) and MOMP (major outer membrane protein), which pass through the membrane 22 and 16 times, respectively, can display surprisingly well on the surfaces of both conventional and KO7⁺ phages. The results provide a guide for protein engineering and large-scale mutagenesis enabled by the phage display of MPs.     

Use of in vivo phage display to engineer novel adenoviruses for targeted delivery to the cardiac vasculature

We performed in vivo phage display in the stroke prone spontaneously hypertensive rat, a cardiovascular disease model, and the normotensive Wistar Kyoto rat to identify cardiac targeting peptides, and then assessed each in the context of viral gene delivery. We identified both common and strain-selective peptides, potentially indicating ubiquitous markers and those found selectively in dysfunctional microvasculature of the heart. We show the utility of the peptide, DDTRHWG, for targeted gene delivery in human cells and rats in vivo when cloned into the fiber protein of subgroup D adenovirus 19p. This study therefore identifies cardiac targeting peptides by in vivo phage display and the potential of a candidate peptide for vector targeting strategies.     

A large semi-synthetic single-chain Fv phage display library based on chicken immunoglobulin genes

Background

Antibody fragments selected from large combinatorial libraries have numerous applications in diagnosis and therapy. Most existing antibody repertoires are derived from human immunoglobulin genes. Genes from other species can, however, also be used. Because of the way in which gene conversion introduces diversity, the naïve antibody repertoire of the chicken can easily be accessed using only two sets of primers.

Results

With in vitro diagnostic applications in mind, we have constructed a large library of recombinant filamentous bacteriophages displaying single chain antibody fragments derived from combinatorial pairings of chicken variable heavy and light chains. Synthetically randomised complementarity determining regions are included in some of the heavy chains. Single chain antibody fragments that recognise haptens, proteins and virus particles were selected from this repertoire. Affinities of three different antibody fragments were determined using surface plasmon resonance. Two were in the low nanomolar and one in the subnanomolar range. To illustrate the practical value of antibodies from the library, phage displayed single chain fragments were incorporated into ELISAs aimed at detecting African horsesickness and bluetongue virus particles. Virus antibodies were detected in a competitive ELISA.

Conclusion

The chicken-derived phage library described here is expected to be a versatile source of recombinant antibody fragments directed against a wide variety of antigens. It has the potential to provide monoclonal reagents with applications in research and diagnostics. For in vitro applications, naïve phage libraries based on avian donors may prove to be useful adjuncts to the selectable antibody repertoires that already exist.

     

Use of psoralen for detecting the conjugated damage to 2 chains in irradiated phage PM2 DNA

Using psoralen for the photochemical cross-linking of DNA chains the authors have demonstrated the formation of conjugated lesions, of both opposite and non-opposite types, in X-irradiated superhelical DNA of PM2 phage. It is suggested that these lesions result from hitting a DNA molecule by a spur.     

Harnessing phage and ribosome display for antibody optimisation

Therapeutic antibodies have become a major driving force for the biopharmaceutical industry; therefore, the discovery and development of safe and efficacious antibody leads have become competitive processes. Phage and ribosome display are ideal tools for the generation of such molecules and have already delivered an approved drug as well as a multitude of clinical candidates. Because they are capable of searching billions of antibody variants in tailored combinatorial libraries, they are particularly applicable to potency optimisation. In conjunction with targeted, random or semi-rational mutagenesis strategies, they deliver large panels of potent antibody leads. This review introduces the two technologies, compares them with respect to their use in antibody optimisation and highlights how they can be exploited for the successful and efficient generation of putative drug candidates.     

A filamentous phage display system for N-linked glycoproteins

We have developed a filamentous phage display system for the detection of asparagine-linked glycoproteins in Escherichia coli that carry a plasmid encoding the protein glycosylation locus (pgl) from Campylobacter jejuni. In our assay, fusion of target glycoproteins to the minor phage coat protein g3p results in the display of glycans on phage. The glyco-epitope displayed on phage is the product of biosynthetic enzymes encoded by the C. jejuni pgl pathway and minimally requires three essential factors: a pathway for oligosaccharide biosynthesis, a functional oligosaccharyltransferase, and an acceptor protein with a D/E-X₁-N-X₂-S/T motif. Glycosylated phages could be recovered by lectin chromatography with enrichment factors as high as 2 × 10⁵ per round of panning and these enriched phages retained their infectivity after panning. Using this assay, we show that desired glyco-phenotypes can be reliably selected by panning phage-displayed glycoprotein libraries on lectins that are specific for the glycan. For instance, we used our phage selection to identify permissible residues in the −2 position of the bacterial consensus acceptor site sequence. Taken together, our results demonstrate that a genotype–phenotype link can be established between the phage-associated glyco-epitope and the phagemid-encoded genes for any of the three essential components of the glycosylation process. Thus, we anticipate that our phage display system can be used to isolate interesting variants in any step of the glycosylation process, thereby making it an invaluable tool for genetic analysis of protein glycosylation and for glycoengineering in E. coli cells.     

Use of phage display to probe the evolution of binding specificity and affinity in integrins

The specific binding of RGD-containing proteins to integrin is a function of both the conformation of and the local sequence surrounding the RGD motif. To study the effect of these factors on integrin binding affinity and specificity, we obtained RGD-containing ligands specific for different integrins presented on the same protein scaffold. The beta-turn region between two anti-parallel beta-strands on the loop I of tendamistat, an inhibitor of alpha-amylase, was extended by two residues and randomized in a phagemid library. This library and two subsequently constructed RGD-containing loop I libraries were biopanned with purified integrins alphaIIbbeta3, alphaVbeta3 and alphaVbeta5 individually. The sequence analysis of selected tendamistat variants and characterization by phage ELISA revealed that phage adhesion is mediated exclusively by an RGD motif located at only two out of four possible positions on loop I. Further, sequences flanking the RGD motif were specific for different integrin targets. Interestingly, selected tendamistat variants mimic natural integrin ligands, both in sequence similarity and in integrin binding specificity, indicating that various ligand specificity patterns can be generated by driving towards maximum affinity in the integrin-ligand complexes.     

An improved helper phage system for efficient isolation of specific antibody molecules in phage display

Phage display technology has been applied in many fields of biological and medical sciences to study molecular interactions and especially in the generation of monoclonal antibodies of human origin. However, extremely low display level of antibody molecules on the surface of phage is an intrinsic problem of a phagemid-based display system resulting in low success rate of isolating specific binding molecules. We show here that display of single-chain antibody fragment (scFv) generated with pIGT3 phagemid can be increased dramatically by using a genetically modified Ex-phage. Ex-phage has a mutant pIII gene that produces a functional wild-type pIII in suppressing Escherichia coli strains but does not make any pIII in non-suppressing E.coli strains. Packaging phagemids encoding antibody-pIII fusion in F⁺ non-suppressing E.coli strains with Ex-phage enhanced the display level of antibody fragments on the surfaces of recombinant phage particles resulting in an increase of antigen-binding reactivity >100-fold compared to packaging with M13KO7 helper phage. Thus, the Ex-phage and pIGT3 phagemid vector provides a system for the efficient enrichment of specific binding antibodies from a phage display library and, thereby, increases the chance of obtaining more diverse antibodies specific for target antigens.     

Use of non-radioactive biotin-labelled probes for detecting hepatitis A virus]

The biotin-labeled DNA probes were constructed on the basis of the hybrid bacteriophage M13nip 9 single-stranded DNA containing the fragments of the hepatitis A viral cDNA. The probes were biotin treated by chemical modification of the DNA by the peraminating reagent or photochemically. The labeled DNA probes were used in molecular hybridization experiments with the nuclear acids fixed on the nitrocellulose filters. The biotin treated DNA was determined by the avidin-gold colloid conjugate with the subsequent physical silver amplification or by the streptavidin-alkaline phosphatase conjugate. The sensitivity of both probes was identical and permitted the determination of 5 x 10(-11)-5 x 10(-12) g of the control DNA and 10(-9) g of the hepatitis A virus. The developed test systems were used for detection of the viral RNA in blood from patients.     

新型噬菌体表面呈现载体的构建

作为抗体库筛选的一个有效方法,噬菌体表面呈现技术在单链抗体的研制和中得到广泛的应用。以噬菌粒pCANTAB5E和pHB为基础。利用PCR和DNA重组方法,构建了一个新型的用于单链抗体噬菌体表面呈现的噬菌粒载体,随后用一株对大肠杆菌细胞有毒性的人源化单链抗体（1HSCFV）对其呈现单链抗体的效果进行了初步的评价。结果表明新型噬菌粒系统具有更好的呈现能力。     

A helper phage to improve single-chain antibody presentation in phage display

We show here that the number of single-chain antibody fragments (scFv) presented on filamentous phage particles generated with antibody display phagemids can be increased by more than two orders of magnitude by using a newly developed helper phage (hyperphage). Hyperphage have a wild-type pIII phenotype and are therefore able to infect F(+) Escherichia coli cells with high efficiency; however, their lack of a functional pIII gene means that the phagemid-encoded pIII-antibody fusion is the sole source of pIII in phage assembly. This results in an considerable increase in the fraction of phage particles carrying an antibody fragment on their surface. Antigen-binding activity was increased about 400-fold by enforced oligovalent antibody display on every phage particle. When used for packaging a universal human scFv library, hyperphage improved the specific enrichment factor obtained when panning on tetanus toxin. After two panning rounds, more than 50% of the phage were found to bind to the antigen, compared to 3% when conventional M13KO7 helper phage was used. Thus, hyperphage is particularly useful in stoichiometric situations, when there is little chance that a single phage will locate the desired antigen.