Construction and characterization of a pseudo-immune human antibody library using yeast surface display

Dietary intake of GDF11 delays the onset of several biomarkers of aging in male mice through anti-oxidant system via Smad2/3 pathway

Current studies have generated controversy over the age-related change in concentration of growth differentiation factor 11 (GDF11) and its role in the genesis of rejuvenation conditions. In this study, we displayed rGDF11 on the surface of Yarrowic Lipolytica (Y. lipolytica), and proved the bioavailability of the yeast-displayed rGDF11 by oral delivery in aged male mice. On the basis of these findings, we started to explore the anti-aging activity and underlying mechanisms of displayed rGDF11. It was found that dietary intake of displayed rGDF11 had little influence on the body weight and biochemical parameters of aged male mice, but delayed the occurrence and development of age-related biomarkers such as lipofuscin (LF) and senescence-associated-β-galactosidase, and to some extent, prolonged the lifespan of aged male mice. Moreover, we demonstrated once again that dietary intake of displayed rGDF11 enhanced the activity of anti-oxidant enzymes, including catalase (CAT), superoxide dismutase (SOD) and glutathione peroxidase (GPX), reduced the reactive oxygen species (ROS) level, and slowed down the protein oxidation and lipid peroxidation. Importantly, we showed for the first time that rGDF11 enhanced the activity of CAT, SOD and GPX through activation of the Smad2/3 signaling pathway. Our study also provided a simple and safe route for delivery of recombinant GDF11, facilitating its therapeutic application in the future.

Phage display and other peptide display technologies

Phage display technology, which is based on the presentation of peptide sequences on the surface of bacteriophage virions, was developed over 30 years ago. Improvements in phage display systems have allowed us to employ this method in numerous fields of biotechnology, as diverse as immunological and biomedical applications, the formation of novel materials and many others. The importance of phage display platforms was recognized by awarding the Nobel Prize in 2018 "for the phage display of peptides and antibodies". In contrast to many review articles concerning specific applications of phage display systems published in recent years, we present an overview of this technology, including a comparison of various display systems, their advantages and disadvantages, and examples of applications in various fields of science, medicine, and the broad sense of biotechnology. Other peptide display technologies, which employ bacterial, yeast and mammalian cells, as well as eukaryotic viruses and cell-free systems, are also discussed. These powerful methods are still being developed and improved; thus, novel sophisticated tools based on phage display and other peptide display systems are constantly emerging, and new opportunities to solve various scientific, medical and technological problems can be expected to become available in the near future.

Efficient construct of a large and functional scFv yeast display library derived from the ascites B cells of ovarian cancer patients by three-fragment transformation-associated recombination

Over the past decade, yeast display technology has emerged as a powerful tool for the isolation of high-affinity immunoglobulin fragments with potential utility as clinical diagnostic and therapeutic reagents. Despite significant refinement of the various methodologies underpinning library construction and selections, certain aspects remain challenging and process limiting. We have sought to significantly improve the robustness of the single-chain Fv (scFv) library construction step by overcoming the technical inefficiencies frequently encountered during the PCR-mediated assembly of scFvs from the discrete heavy and light V-domain repertoires. Using a novel primer set designed to provide maximum amplification coverage of the known germ-line V-domain repertoire, we have exploited the potential of the in vivo homologous gap-repair apparatus of Saccharomyces cerevisiae to assemble intact scFvs directly from co-transformed PBMC-derived VH, VL, and linearized vector component fragments. We have successfully applied this three-fragment assembly strategy to construct a large (>10(9)) scFv yeast display library from the ascites immune repertoire of ovarian cancer patients and validated the approach by applying FACS-based sorting to readily isolate scFvs that recognize various tumor marker antigens (TMAs). It is expected that this simplified construction method may find general utility, both for de novo scFv library construction and for subsequent combinatorial affinity maturation manipulations that require more than two fragments.

Selection of Recombinant Human Antibodies

Since the development of therapeutic antibodies the demand of recombinant human antibodies is steadily increasing. Traditionally, therapeutic antibodies were generated by immunization of rat or mice, the generation of hybridoma clones, cloning of the antibody genes and subsequent humanization and engineering of the lead candidates. In the last few years, techniques were developed that use transgenic animals with a human antibody gene repertoire. Here, modern recombinant DNA technologies can be combined with well established immunization and hybridoma technologies to generate already affinity maturated human antibodies. An alternative are in vitro technologies which enabled the generation of fully human antibodies from antibody gene libraries that even exceed the human antibody repertoire. Specific antibodies can be isolated from these libraries in a very short time and therefore reduce the development time of an antibody drug at a very early stage.In this review, we describe different technologies that are currently used for the in vitro and in vivo generation of human antibodies.

Display of active beta-glucosidase on the surface of Schizosaccharomyces pombe cells using novel anchor proteins

Here, we demonstrate display of beta-glucosidase (BGL) on the surface of Schizosaccharomyces pombe cells using novel anchor proteins. A total of four candidate anchor proteins (SPBC21D10.06c, SPBC947.04, SPBC19C7.05, and SPBC359.04c) were selected from among almost all of S. pombe membrane proteins. The C-terminus of each anchor protein was genetically fused to the N-terminus of BGL, and the fusion protein was expressed using S. pombe as a host. The highest cell surface-associated BGL activity (107 U/10(5) cells was achieved with SPBC359.04c serving as the anchor, followed by SPBC947.04 (44 U/10(5) cells) and SPBC21D10.06c (38 U/10(5) cells). S. pombe displaying BGL with SPBC359.04c as an anchor showed the highest growth on 2 % cellobiose (10.7 × 10(7) cells/mL after 41 h of cultivation from an initial density of 0.1 × 10(7) cells/mL). Additionally, culturing BGL-displaying S. pombe in medium containing cellobiose as the sole carbon source did not affect protein expression, and ethanol fermentation from cellobiose was successfully demonstrated using BGL-displaying S. pombe. This is the first report describing a cell surface display system for the functionalization of S. pombe.

Transferring the characteristics of naturally occurring and biased antibody repertoires to human antibody libraries by trapping CDRH3 sequences

Antibody repertoires are characterized by diversity as they vary not only amongst individuals and post antigen exposure but also differ significantly between vertebrate species. Such plasticity can be exploited to generate human antibody libraries featuring hallmarks of these diverse repertoires. In this study, the focus was to capture CDRH3 sequences, as this region generally accounts for most of the interaction energy with antigen. Sequences from human as well as non-human sources were successfully integrated into human antibody libraries. Next generation sequencing of these libraries proved that the CDRH3 lengths and amino acid composition corresponded to the species of origin. Specific CDRH3 sequences, biased towards the recognition of a model antigen either by immunizing mice or by selecting with phage display, were then integrated into another set of libraries. From these antigen biased libraries, highly potent antibodies were more frequently isolated, indicating that the characteristics of an immune repertoire is transferrable via CDRH3 sequences into a human antibody library. Taken together, these data demonstrate that the properties of naturally or experimentally biased repertoires can be effectively harnessed for the generation of targeted human antibody libraries, substantially increasing the probability of isolating antibodies suitable for therapeutic and diagnostic applications.

Generation of bivalent and bispecific kringle single domains by loop grafting as potent agonists against death receptors 4 and 5

Bivalent or bispecific binding activity of proteins has been mainly achieved by assembling two or more domains in a single molecule. Here we report bivalent/bispecific single-domain proteins based on the kringle domain (KD), which has a cystine knot structural motif and is highly tolerant of sequence modifications. KD has seven loops protruding from the core fold into two largely opposite directions, dubbed loop cluster regions (LCRs) 1 and 2. Mutational analysis of previously isolated agonistic KD variants against human death receptors (DRs) 4 and 5 revealed that they can simultaneously recognize two target molecules of DR4 and/or DR5 via the two independent binding sites of LCR1 and LCR2. Binding loop mapping of yeast-surface-displayed KD mutants identified high-affinity target binding loops in LCR2, which were then grafted into conformationally compatible loops located on the opposite side of LCR1 within the same or different KD variants to generate bivalent/bispecific KD variants against DR4 and/or DR5 with improved affinity. The loop-grafted bivalent/bispecific KD variants showed enhanced cell-death-inducing activity of tumor cells compared with their monovalent/monospecific and bivalent/monospecific counterparts, demonstrating an advantage of bispecific targeting to both DR4 and DR5 over the targeting of only one of the two pro-apoptotic receptors. Our results suggest that the KD with the two independent binding surfaces for target recognition is an appropriate scaffold for the development of bivalency and/or bispecificity by loop grafting on the single domain, which offers a distinct advantage over other protein scaffolds with a single binding surface.

Engineering of a human kringle domain into agonistic and antagonistic binding proteins functioning in vitro and in vivo

Here, we report the development of target-specific binding proteins based on the kringle domain (KD) ( approximately 80 residues), a ubiquitous modular structural unit occurring across eukaryotic species. By exploiting the highly conserved backbone folding by core residues, but using extensive sequence variations in the seven loop regions of naturally occurring human KDs, we generated a synthetic KD library on the yeast cell surface by randomizing 45 residues in the loops of a human KD template. We isolated KD variants that specifically bind to anticancer target proteins, such as human death receptor 4 (DR4) and/or DR5, and that function as agonists to induce apoptotic cell death in several cancer cell lines in vitro and inhibit tumor progression in mouse models. Combined treatments with KD variants possessing different recognition sites on the same target protein exerted synergisitic tumoricidal activities, compared to treatment with individual variants. In addition to the agonists, we isolated an antagonistic KD variant that binds human tumor necrosis factor-alpha (TNFalpha) and efficiently neutralizes TNFalpha-induced cytotoxicity in vitro and in vivo. The KD scaffold with seven flexible loops protruding from the central core was strongly sequence-tolerant to mutations in the loop regions, offering a potential advantage of distinct binding sites for target recognition on the single domain. Our results suggest that the KD scaffold can be used to develop target-specific binding proteins that function as agonists or antagonists toward given target molecules, indicative of their potential use as biotherapeutics.

An improved yeast transformation method for the generation of very large human antibody libraries

Antibody library selection by yeast display technology is an efficient and highly sensitive method to identify binders to target antigens. This powerful selection tool, however, is often hampered by the typically modest size of yeast libraries (approximately 10(7)) due to the limited yeast transformation efficiency, and the full potential of the yeast display technology for antibody discovery and engineering can only be realized if it can be coupled with a mean to generate very large yeast libraries. We describe here a yeast transformation method by electroporation that allows for the efficient generation of large antibody libraries up to 10(10) in size. Multiple components and conditions including CaCl(2), MgCl(2), sucrose, sorbitol, lithium acetate, dithiothreitol, electroporation voltage, DNA input and cell volume have been tested to identify the best combination. By applying this developed protocol, we have constructed a 1.4 x 10(10) human spleen antibody library essentially in 1 day with a transformation efficiency of 1-1.5 x 10(8) transformants/microg vector DNA. Taken together, we have developed a highly efficient yeast transformation method that enables the generation of very large and productive human antibody libraries for antibody discovery, and we are now routinely making 10(9) libraries in a day for antibody engineering purposes.

Gene silencing by cell-penetrating, sequence-selective and nucleic-acid hydrolyzing antibodies

Targeting particular mRNAs for degradation is a fascinating approach to achieve gene silencing. Here we describe a new gene silencing tool exploiting a cell-penetrating, nucleic-acid hydrolyzing, single-domain antibody of the light-chain variable domain, 3D8 VL. We generated a synthetic library of 3D8 VL on the yeast surface by randomizing residues located in one of two β-sheets. Using 18-bp single-stranded nucleic acids as target substrates, including the human Her2/neu-targeting sequence, we selected 3D8 VL variants that had ∼100–1000-fold higher affinity and ∼2–5-fold greater selective hydrolyzing activity for target substrates than for off targets. 3D8 VL variants efficiently penetrated into living cells to be accumulated in the cytosol and selectively decreased the amount of target sequence-carrying mRNAs as well as the proteins encoded by these mRNAs with minimal effects on off-target genes. In particular, one 3D8 VL variant targeting the Her2 sequence showed more efficient downregulation of Her2 expression than a small-interfering RNA targeting the same Her2 sequence, resulting in apoptotic cell death of Her2-overexpressing breast cancer cells. Our results demonstrate that cell-penetrating 3D8 VL variants with sequence-selective, nucleic-acid-hydrolyzing activity can selectively degrade target mRNAs in the cytosol, providing a new gene silencing tool mediated by antibody.

Efficient recovery of high-affinity antibodies from a single-chain Fab yeast display library

Yeast display is a powerful technology for the isolation of monoclonal antibodies (mAbs) against a target antigen. Antibody libraries have been displayed on the surface of yeast as both single-chain variable fragment (scFv) and antigen binding fragment (Fab). Here, we combine these two formats to display well-characterized mAbs as single-chain Fabs (scFabs) on the surface of yeast and construct the first scFab yeast display antibody library. When expressed on the surface of yeast, two out of three anti-human immunodeficiency virus (HIV)-1 mAbs bound with higher affinity as scFabs than scFvs. Also, the soluble scFab preparations exhibited binding and neutralization profiles comparable to that of the corresponding Fab fragments. Display of an immune HIV-1 scFab library on the surface of yeast, followed by rounds of sorting against HIV-1 gp120, allowed for the selection of 13 antigen-specific clones. When the same cDNA was used to construct the library in an scFv format, a similar number but a lower affinity set of clones were selected. Based on these results, yeast-displayed scFab libraries can be constructed and selected with high efficiency, characterized without the need for a reformatting step, and used to isolate higher-affinity antibodies than scFv libraries.

Alkaline protease gene cloning from the marine yeast Aureobasidium pullulans HN2-3 and the protease surface display on Yarrowia lipolytica for bioactive peptide production

The alkaline protease genes (cDNAALP2 gene and ALP2 gene) were amplified from complementary DNA (cDNA) and genomic DNA of the marine yeast Aureobasidium pullulans HN2-3, respectively. An open reading frame of 1,248 bp encoding a 415-amino acid protein with a calculated molecular weight of 42.9 kDa was characterized. The ALP2 gene contained two introns, which had 54 and 52 bp, respectively. When the cDNAALP2 gene was cloned into the multiple cloning sites of the surface display vector pINA1317-YlCWP110 and expressed in cells of Yarrowia lipolytica, the cells displaying protease could form a clear zone on the double plate containing milk protein and had protease activity. The cells displaying alkaline protease were also found to be able to produce bioactive peptides from different sources of proteins. The peptides produced from single-cell protein of marine yeast strain G7a had the highest angiotensin-converting enzyme inhibitory activity, while the peptides produced from spirulina protein had the highest antioxidant activity. This is the first report that the yeast cells displaying alkaline protease were used to produce bioactive peptides.

Comparative analyses of complex formation and binding sites between human tumor necrosis factor-alpha and its three antagonists elucidate their different neutralizing mechanisms

Tumor necrosis factor-alpha (TNFalpha)-blocking therapy, using biologic TNFalpha antagonists, has been approved for the treatment of several diseases including rheumatoid arthritis, psoriasis and Crohn's disease. There have been few detailed studies of binding characterizations for the complex formation by TNFalpha and clinically relevant antagonists, particularly Infliximab (Remicade) and Etanercept (Enbrel). Here we characterized the binding stoichiometry and size of soluble TNFalpha-antagonist complexes and identified energetically important binding sites on TNFalpha for the three antagonists, Etanercept, Infliximab, and the recently developed humanized TNFalpha neutralizing monoclonal antibody, YHB1411-2. Size-exclusion chromatography and dynamic light scattering analyses revealed that the three antagonists formed distinct thermodynamically stable TNFalpha-antagonist complexes that exhibited differences in their size and composition. Energetically important binding residues on TNFalpha were identified for each antagonist by a sequence of experiments that consisted of competition binding assays, fragmentations, loop mutations, and single-point mutations using yeast surface-displayed TNFalpha, which was further confirmed for solubly purified TNFalpha mutants by surface plasmon resonance technique. Analyses of the binding geometry based on binding site location, spatial constraints, and valency satisfaction allowed us to interpret the thermodynamically stable complexes as follows: one molecule of Etanercept and one molecule of trimeric TNFalpha (Etanercept1-TNFalpha1), Infliximab6-TNFalpha3, and YHB1411-2(4)-TNFalpha2. The distinct features of the soluble antagonist-TNFalpha complex formation among the antagonists may give further insights into their different neutralizing mechanisms and pharmacokinetic profiles.

Yeast surface display for protein engineering and characterization

Yeast surface display is being employed to engineer desirable properties into proteins for a broad variety of applications. Labeling with soluble ligands enables rapid and quantitative analysis of yeast-displayed libraries by flow cytometry, while cell-surface selections allow screening of libraries with insoluble or even as-yet-uncharacterized binding targets. In parallel, the utilization of yeast surface display for protein characterization, including in particular the mapping of functional epitopes mediating protein–protein interactions, represents a significant recent advance.

A human scFv antibody against TRAIL receptor 2 induces autophagic cell death in both TRAIL-sensitive and TRAIL-resistant cancer cells

Tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL) induces apoptotic cell death in a variety of tumor cells without significant cytotoxicity on normal cells. However, many cancer cells with apoptotic defects are resistant to treatment with TRAIL alone, limiting its potential as an anticancer therapeutic. Here, we report on the tumoricidal activity of a human single-chain fragment variable, HW1, which specifically binds to TRAIL receptor 2 (TR2) without competing with TRAIL for the binding. HW1 treatment as a single agent induces autophagic cell death in a variety of both TRAIL-sensitive and TRAIL-resistant cancer cells, but exhibits much less cytotoxicity on normal cells. The HW1-induced autophagic cell death was inhibited by an autophagy inhibitor, 3-methyladenine, or by RNA interference knockdown of Beclin-1 and Atg7. We also show that the HW1-mediated autophagic cell death occurs predominantly via the c-Jun NH(2)-terminal kinase pathway in a caspase-independent manner. Analysis of the death-inducing signaling complex induced by HW1 binding to TR2 exhibits the recruitment of TNF receptor-associated death domain and TNF receptor-associated factor 2, but not Fas-associated death domain, caspase-8, or receptor-interacting protein, which is distinct from that induced by TRAIL. Our results reveal a novel TR2-mediated signaling pathway triggering autophagic cell death and provides a new strategy for the elimination of cancer cells, including TRAIL-resistant tumors, through nonapoptotic cell death.