Characterization of binding mode of action of a blocking anti-platelet-derived growth factor (PDGF)-B monoclonal antibody, MOR8457, reveals conformational flexibility and avidity needed for PDGF-BB to bind PDGF receptor-ß.

Platelet derived growth factor-BB (PDGF-BB) is an important mitogen and cell survival factor during development. PDGF-BB binds PDGF receptor-ß (PDGFRß) to trigger receptor dimerization and tyrosine kinase activation. We present the pharmacological and biophysical characterization of a blocking PDGF-BB monoclonal antibody, MOR8457, and contrast this to PDGFRß. MOR8457 binds to PDGF-BB with high affinity and selectivity, and prevents PDGF-BB induced cell proliferation competitively and with high potency. The structural characterization of the MOR8457-PDGF-BB complex indicates that MOR8457 binds with a 2:1 stoichiometry, but that binding of a single MOR8457 moiety is sufficient to prevent binding to PDGFRß. Comparison of the MOR8457-PDGF-BB structure with that of the PDGFRß-PDGF-BB complex suggested the potential reason for this was a substantial bending and twisting of PDGF-BB in the MOR8457 structure, relative to the structures of PDGF-BB alone, bound to a PDGF-BB aptamer or PDGFRß, which makes it nonpermissive for PDGFRß binding. These biochemical and structural data offer insights into the permissive structure of PDGF-BB needed for agonism as well as strategies for developing specific PDGF ligand antagonists.

High affinity, developability and functional size: the holy grail of combinatorial antibody library generation.

Since the initial description of phage display technology for the generation of human antibodies, a variety of selection methods has been developed. The most critical parameter for all in vitro-based approaches is the quality of the antibody library. Concurrent evolution of the libraries has allowed display and selection technologies to reveal their full potential. They come in different flavors, from naïve to fully synthetic and differ in terms of size, quality, method of preparation, framework and CDR composition. Early on, the focus has mainly been on affinities and thus on library size and diversity. Subsequently, the increased awareness of developability and cost of goods as important success factors has spurred efforts to generate libraries with improved biophysical properties and favorable production characteristics. More recently a major focus on reduction of unwanted side effects through reduced immunogenicity and improved overall biophysical behavior has led to a re-evaluation of library design.

Hepatitis B virus particle formation in the absence of pregenomic RNA and reverse transcriptase.

Cytoplasmic hepatitis B virus (HBV) capsids are not enveloped and secreted unless the packaged RNA pregenome is reverse transcribed. The expression of the capsid protein C, together with envelope proteins in the absence of pregenomic RNA, produced normal amounts of intracellular capsids, but the secretion of virion-like particles was greatly reduced. The I97L C protein mutant, allowing immature nucleocapsid envelopment in the background of an HBV genome, did not promote the envelopment of capsids lacking a pregenome, suggesting that this mutation is not sufficient to induce secretion competence independently of the pregenome.

Mapping of amino acid side chains on the surface of hepatitis B virus capsids required for envelopment and virion formation.

The crystal structure of recombinant hepatitis B virus (HBV) capsids formed by 240 core proteins has recently been published. We wanted to map sites on the surface of the icosahedral 35-nm particle that are important for nucleocapsid envelopment by HBV surface proteins during virion morphogenesis. For this purpose, we individually mutated 52 amino acids (aa) within the N-terminal 140 aa of the 185-aa long core protein displaying their side chains to the external surface of the capsid to alanine residues. The phenotype of the mutations with respect to virion formation was tested by transcomplementation of a core gene-negative HBV genome in transiently cotransfected cells, immunoprecipitation of nucleocapsids from cells and secreted virions from culture media, and detection of the particles by radioactive endogenous polymerase reactions. Thirteen point mutations impeded nucleocapsid detection by endogenous polymerase reactions. Twenty-seven mutations were compatible with virion formation. Among these were all capsid-forming mutations in the upper half of the spike protruding from the particle shell and two additional triple mutations at tip of the spike. Eleven mutations (S17, F18, L60, L95, K96, F122, I126, R127, N136, A137, and I139) allowed nucleocapsid formation but blocked particle envelopment and virion formation to undetectable levels. These mutations map to a ring-like groove around the base of the spike and to a small area at the capsid surface close to the pores in the capsid shell. These residues are candidate sites for the interaction with envelope proteins during virion morphogenesis.