Lesley A. Pearce

Engineering of an anti‐epidermal growth factor receptor antibody to single chain format and labeling by sortase A‐mediated protein ligation

Sortase‐mediated protein ligation is a biological covalent conjugation system developed from the enzymatic cell wall display mechanism found in Staphylococcus aureus. This three‐component system requires: (i) purified Sortase A (SrtA) enzyme; (ii) a substrate containing the LPXTG peptide recognition sequence; and (iii) an oligo‐glycine acceptor molecule. We describe cloning of the single‐chain antibody sc528, which binds to the extracellular domain of the epidermal growth factor receptor (EGFR), from the parental monoclonal antibody and incorporation of a LPETGG tag sequence. Utilizing recombinant SrtA, we demonstrate successful incorporation of biotin from GGG‐biotin onto sc528. EGFR is an important cancer target and is over‐expressed in human tumor tissues and cancer lines, such as the A431 epithelial carcinoma cells. SrtA‐biotinylated sc528 specifically bound EGFR expressed on A431 cells, but not negative control lines. Similarly, when sc528 was labeled with fluorescein we observed antigen‐specific labeling. The ability to introduce functionality into recombinant antibodies in a controlled, site‐specific manner has applications in experimental, diagnostic, and potentially clinical settings. For example, we demonstrate addition of all three reaction components in situ within a biosensor flow cell, resulting in oriented covalent capture and presentation of sc528, and determination of precise affinities for the antibody–receptor interaction. Biotechnol. Bioeng. 2012; 109:1461–1470.

Design and expression of a stable bispecific scFv dimer with affinity for both glycophorin and N9 neuraminidase

We have designed and produced a stable bispecific scFv dimer (bisFv) by non-covalent association of two hybrid VH-VL pairs derived from an anti-neuraminidase antibody (NC10) and an anti-glycophorin antibody (1C3). The bisFv dimer was demonstrated to have binding activity to the two respective target antigens and was evaluated as a reagent for rapid whole blood agglutination assays. The bisFv was expressed in the periplasm of Escherichia coli, from a secretion vector which comprised two cistrons in tandem under the control of a single lac promoter, inducible with IPTG. Each cistron encoded one of the hybrid VH-VL pairs, with V domains separated by a linker region encoding the five amino acids, Gly4Ser. The short linker region was designed to prevent association of VH and VL regions of the same molecule and favour the formation of dimers. The protein synthesized from each hybrid scFv cistron was directed to the E. coli periplasm by the inclusion of distinctive signal secretion sequences preceding each hybrid gene; from pel B of Erwinia cartovora and from gene III of fd phage. The bisFv was affinity-purified from culture supernatants via the C-terminal tag epitope FLAG and was shown, by FPLC on a Superose 6 column, to be consistent in size with that of a scFv dimer. The bisFv was stable for more than 4 months at 4 degrees C and was shown by BIAcore analysis to bind to either target antigen, human glycophorin, or tern N9 neuraminidase. Simultaneous binding to both target antigens was demonstrated when a pre-formed bisFv-neuraminidase complex was shown to bind to immobilized glycophorin. In whole blood agglutination assays, the bisFv dimer was able to agglutinate red blood cells when crosslinked with an anti-idiotype antibody (3-2G12) binding to the NC10 combining site, but no agglutination occurred on binding the antigen neuraminidase. These results are a function of the topology of the epitopes on neuraminidase and have implications for the use of relatively rigid bifunctional molecules (as bisFv dimers) to cross link two large membrane-anchored moieties, in this case, red blood cell glycophorin and neuraminidase, an M(r) 190,000 tetramer.

Biochemical Characterization of Individual Human Glycosylated pro-Insulin-like Growth Factor (IGF)-II and big-IGF-II Isoforms Associated with Cancer

Background: Aberrant processing of the pro-IGF-II transcript produces pro- and big-IGF-II, which are secreted in a range of cancers. Results: These induce potent receptor activation and cell proliferation and retard ternary complex formation with ALS and IGFBP-3 and -5. Conclusion: They elicit unique biological responses that can be completely different from IGF-II. Significance: Understanding the effects induced by these individual isoforms is crucial to elucidate their role in tumorigenesis. Insulin-like growth factor II (IGF-II) is a major embryonic growth factor belonging to the insulin-like growth factor family, which includes insulin and IGF-I. Its expression in humans is tightly controlled by maternal imprinting, a genetic restraint that is lost in many cancers, resulting in up-regulation of both mature IGF-II mRNA and protein expression. Additionally, increased expression of several longer isoforms of IGF-II, termed “pro” and “big” IGF-II, has been observed. To date, it is ambiguous as to what role these IGF-II isoforms have in initiating and sustaining tumorigenesis and whether they are bioavailable. We have expressed each individual IGF-II isoform in their proper O-glycosylated format and established that all bind to the IGF-I receptor and both insulin receptors A and B, resulting in their activation and subsequent stimulation of fibroblast proliferation. We also confirmed that all isoforms are able to be sequestered into binary complexes with several IGF-binding proteins (IGFBP-2, IGFBP-3, and IGFBP-5). In contrast to this, ternary complex formation with IGFBP-3 or IGFBP-5 and the auxillary protein, acid labile subunit, was severely diminished. Furthermore, big-IGF-II isoforms bound much more weakly to purified ectodomain of the natural IGF-II scavenging receptor, IGF-IIR. IGF-II isoforms thus possess unique biological properties that may enable them to escape normal sequestration avenues and remain bioavailable in vivo to sustain oncogenic signaling.

Germline humanization of a murine Aβ antibody and crystal structure of the humanized recombinant Fab fragment

Alzheimers disease is the most common form of dementia, affecting 26 million people worldwide. The Aβ peptide (39–43 amino acids) derived from the proteolytic cleavage of the amyloid precursor protein is one of the main constituents of amyloid plaques associated with disease pathogenesis and therefore a validated target for therapy. Recently, we characterized antibody fragments (Fab and scFvs) derived from the murine monoclonal antibody WO‐2, which bind the immunodominant epitope (3EFRH6) in the Aβ peptide at the N‐terminus. In vitro, these fragments are able to inhibit fibril formation, disaggregate preformed amyloid fibrils, and protect neuroblastoma cells against oligomer‐mediated toxicity. In this study, we describe the humanization of WO‐2 using complementary determining region loop grafting onto the human germline gene and the determination of the three‐dimensional structure by X‐ray crystallography. This humanized version retains a high affinity for the Aβ peptide and therefore is a potential candidate for passive immunotherapy of Alzheimers disease.

Kinetic screening of antibody-Im7 conjugates by capture on a colicin E7 DNase domain using optical biosensors.

Antibody generation by phage display and related in vitro display technologies routinely yields large panels of clones detected in primary end-point screenings such as enzyme-linked immunosorbent assay (ELISA). However, for the development of clinical lead candidates, rapid determination of secondary characteristics such as kinetics and thermodynamics is of nearly equal importance. Surface plasmon resonance-based biosensors are ideal tools for carrying out such high-throughput secondary screenings, allowing preliminary but confident ranking and identification of lead clones. A key feature of these assays is the stable and reversible capture of antibody fragments from crude samples leading to high-resolution kinetic analysis of library outputs. Here we exploit the high-affinity interaction between the naturally occurring nuclease domain of E. coli colicin E7 (DNaseE7) and its cognate partner, the immunity protein 7 (Im7), to develop a ligand capture system suitable for accurate kinetic ranking of library clones. We demonstrate generic applicability for a range of antibody formats: scFv antibodies, diabodies, antigen binding fragments (Fabs), and shark V(NAR) single domain antibodies. The system is adaptable and reproducible, with comparable results achieved for both the Biacore T100 and ProteOn XPR36 array biosensors.

Structural studies of the tethered N-terminus of the Alzheimer's disease amyloid-beta peptide.

Alzheimers disease is the most common form of dementia in humans and is related to the accumulation of the amyloid‐β (Aβ) peptide and its interaction with metals (Cu, Fe, and Zn) in the brain. Crystallographic structural information about Aβ peptide deposits and the details of the metal‐binding site is limited owing to the heterogeneous nature of aggregation states formed by the peptide. Here, we present a crystal structure of Aβ residues 1–16 fused to the N‐terminus of the Escherichia coli immunity protein Im7, and stabilized with the fragment antigen binding fragment of the anti‐Aβ N‐terminal antibody WO2. The structure demonstrates that Aβ residues 10–16, which are not in complex with the antibody, adopt a mixture of local polyproline II‐helix and turn type conformations, enhancing cooperativity between the two adjacent histidine residues His13 and His14. Furthermore, this relatively rigid region of Aβ (residues, 10–16) appear as an almost independent unit available for trapping metal ions and provides a rationale for the His13‐metal‐His14 coordination in the Aβ1–16 fragment implicated in Aβ metal binding. This novel structure, therefore, has the potential to provide a foundation for investigating the effect of metal ion binding to Aβ and illustrates a potential target for the development of future Alzheimers disease therapeutics aimed at stabilizing the N‐terminal monomer structure, in particular residues His13 and His14, and preventing Aβ metal‐binding‐induced neurotoxicity.Proteins 2013; 81:1748–1758.

Crystallization of an apo form of human arginase: using all the tools in the toolbox simultaneously.

Arginase (EC 3.5.3.1) is an aminohydrolase that acts on L-arginine to produce urea and ornithine. Two isotypes of the enzyme are found in humans. Type I is predominantly produced in the liver and is a homotrimer of 35 kDa subunits. Human arginase (hArginase) I is seen to be up-regulated in many diseases and is a potential therapeutic target for many diverse indications. Previous reports of crystallization and structure determination of hArginase have always included inhibitors of the enzyme: here, the first case of a true apo crystal form of the enzyme which is suitable for small-molecule soaking is reported. The crystals belonged to space group P2(1)2(1)2(1) and have approximate unit-cell parameters a=53, b=67.5, c=250 Å. The crystals showed slightly anisotropic diffraction to beyond 2.0 Å resolution.

Structural characterization by transmission electron microscopy and immunoreactivity of recombinant Hendra virus nucleocapsid protein expressed and purified from Escherichia coli

Abstract Hendra virus (family Paramyxoviridae) is a negative sense single-stranded RNA virus (NSRV) which has been found to cause disease in humans, horses, and experimentally in other animals, e.g. pigs and cats. Pteropid bats commonly known as flying foxes have been identified as the natural host reservoir. The Hendra virus nucleocapsid protein (HeV N) represents the most abundant viral protein produced by the host cell, and is highly immunogenic with naturally infected humans and horses producing specific antibodies towards this protein. The purpose of this study was to express and purify soluble, functionally active recombinant HeV N, suitable for use as an immunodiagnostic reagent to detect antibodies against HeV. We expressed both full-length HeV N, (HeV NFL), and a C-terminal truncated form, (HeV NCORE), using a bacterial heterologous expression system. Both HeV N constructs were engineered with an N-terminal Hisx6 tag, and purified using a combination of immobilized metal affinity chromatography (IMAC) and size exclusion chromatography (SEC). Purified recombinant HeV N proteins self-assembled into soluble higher order oligomers as determined by SEC and negative-stain transmission electron microscopy. Both HeV N proteins were highly immuno-reactive with sera from animals and humans infected with either HeV or the closely related Nipah virus (NiV), but displayed no immuno-reactivity towards sera from animals infected with a non-pathogenic paramyxovirus (CedPV), or animals receiving Equivac® (HeV G glycoprotein subunit vaccine), using a Luminex-based multiplexed microsphere assay.

CD52 glycan binds the proinflammatory B box of HMGB1 to engage the Siglec-10 receptor and suppress human T cell function

Significance Inflammation is a protective response of the body’s immune system against harmful stimuli such as pathogenic microorganisms, toxins, or damaged cells. However, if excessive or prolonged, inflammation may be harmful and therefore has to be regulated. Soluble CD52 is a natural sialoglycopeptide and immune regulator that suppresses inflammatory responses. We elucidated the mechanism of this effect by showing that soluble CD52 first sequesters a mediator of inflammation called HMGB1; in turn, this promotes binding of the sialylated CD52 glycan to an inhibitory receptor, sialic acid-binding immunoglobulin-like lectin (Siglec)-10, present on activated T cells and other immune cells. This concerted antiinflammatory mechanism driven by soluble CD52 may contribute to immune-inflammatory homeostasis and underscores the therapeutic potential of soluble CD52. CD52, a glycophosphatidylinositol (GPI)-anchored glycoprotein, is released in a soluble form following T cell activation and binds to the Siglec (sialic acid-binding Ig-like lectin)-10 receptor on T cells to suppress their function. We show that binding of CD52-Fc to Siglec-10 and T cell suppression requires the damage-associated molecular pattern (DAMP) protein, high-mobility group box 1 (HMGB1). CD52-Fc bound specifically to the proinflammatory Box B domain of HMGB1, and this in turn promoted binding of the CD52 N-linked glycan, in α-2,3 sialic acid linkage with galactose, to Siglec-10. Suppression of T cell function was blocked by anti-HMGB1 antibody or the antiinflammatory Box A domain of HMGB1. CD52-Fc induced tyrosine phosphorylation of Siglec-10 and was recovered from T cells complexed with HMGB1 and Siglec-10 in association with SHP1 phosphatase and the T cell receptor (TCR). Thus, soluble CD52 exerts a concerted immunosuppressive effect by first sequestering HMGB1 to nullify its proinflammatory Box B, followed by binding to the inhibitory Siglec-10 receptor, triggering recruitment of SHP1 to the intracellular immunoreceptor tyrosine-based inhibitory motif of Siglec-10 and its interaction with the TCR. This mechanism may contribute to immune-inflammatory homeostasis in pathophysiologic states and underscores the potential of soluble CD52 as a therapeutic agent.