Construction Of A Synthetic Single Domain Antibody Phage Display Library For Molecular Diagnostic Applications

Antibodi domain telah dieksploitasi secara meluas sebagai perancah untuk penjanaan perpustakaan antibody sintetik kerana saiz tanpa bergantung dengan mekanisma lipatan mudah. Domain antibodies have been widely exploited as a scaffold for the generation of synthetic antibody libraries because of their relatively small size and simple folding mechanism

Sensitive recovery of recombinant antibody clones after their in silico identification within NGS datasets

Recently the analytical power of the latest high throughput next generation DNA sequencing platforms has been used to analyse phage that have been selected from the panning of large combinatorial libraries displaying either peptide or antibody ligands. This process, commonly referred to as next generation phage display (NGPD), allows the researcher to determine the identity of specific phage that are being enriched against an antigen target by analysis of the DNA sequence encoding the displayed ligand. This method bypasses several steps in conventional phage panning that include laborious colony picking and functional ligand screening. A downside of this approach is that the only output from such experiments is the DNA sequence information of such enriched phage particles. In the case of peptides, the peptide sequence can be synthesised directly and used for further screening; however this is more difficult with larger antibody fragments such as ScFvs. In the case of ScFvs, their coding sequence would have to be fully elucidated, synthesised and re-cloned before expression. We describe here the application of an inverse PCR-ligation methodology that enables the specific recovery of ScFvs of interest from enriched sub-libraries of phage clones. Phagemid particles are recovered using sequence information derived from their unique heavy chain CDR3/FR4 domains and specific clones can be recovered irrespective of CDR3 size and at levels of abundance that would be refractory to their discovery during conventional phage panning and screening

Single domain antibodies for the knockdown of cytosolic and nuclear proteins.

Single domain antibodies (sdAbs) from camels or sharks comprise only the variable heavy chain domain. Human sdAbs comprise the variable domain of the heavy chain (VH) or light chain (VL) and can be selected from human antibodies. SdAbs are stable, nonaggregating molecules in vitro and in vivo compared to complete antibodies and scFv fragments. They are excellent novel inhibitors of cytosolic/nuclear proteins because they are correctly folded inside the cytosol in contrast to scFv fragments. SdAbs are unique because of their excellent specificity and possibility to target posttranslational modifications such as phosphorylation sites, conformers or interaction regions of proteins that cannot be targeted with genetic knockout techniques and are impossible to knockdown with RNAi. The number of inhibiting cytosolic/nuclear sdAbs is increasing and usage of synthetic single pot single domain antibody libraries will boost the generation of these fascinating molecules without the need of immunization. The most frequently selected antigenic epitopes belong to viral and oncogenic proteins, followed by toxins, proteins of the nervous system as well as plant‐ and drosophila proteins. It is now possible to select functional sdAbs against virtually every cytosolic/nuclear protein and desired epitope. The development of new endosomal escape protein domains and cell‐penetrating peptides for efficient transfection broaden the application of inhibiting sdAbs. Last but not least, the generation of relatively new cell‐specific nanoparticles such as polymersomes and polyplexes carrying cytosolic/nuclear sdAb‐DNA or –protein will pave the way to apply cytosolic/nuclear sdAbs for inhibition of viral infection and cancer in the clinic. Keywords: intrabodies, single domain antibodies, scFv fragment, cytosolic/nuclear intrabodies, camelid VHHs, shark vNARs, human VH, human V