Robyn Louise Malby

The structure of a complex between the NC10 antibody and influenza virus neuraminidase and comparison with the overlapping binding site of the NC41 antibody

BACKGROUND While it is well known that different antibodies can be produced against a particular antigen, and even against a particular site on an antigen, up until now there have been no structural studies of cross-reacting antibodies of this type. One antibody-antigen complex whose structure is known is that of the influenza virus antigen, neuraminidase, in complex with the NC41 antibody. Another anti-neuraminidase antibody, NC10, binds to an overlapping site on the antigen. The structure of the complex formed by this antibody with neuraminidase is described here and compared with the NC41-containing complex. RESULTS The crystal structure of the NC10 Fab-neuraminidase complex has been refined to a nominal resolution of 2.5A. Approximately 80% of the binding site of the NC10 antibody on neuraminidase overlaps with that of the NC41 antibody. The epitope residues of neuraminidase are often engaged in quite different interactions with the two antibodies. Although the NC10 and NC41 antibodies have identical amino acid sequences within the first complementarity determining region of their heavy chains, this is not the basis of the cross-reaction. CONCLUSIONS The capacity of two different proteins to bind to the same target structure on a third protein need not be based on the existence of identical or homologous amino acid sequences within those proteins. As we have demonstrated, amino acid residues on the common target structure may be in quite different chemical environments, and may also adopt different conformations within two protein-protein complexes.

The three-dimensional structure of N -acetylneuraminate lyase from Escherichia coli

BACKGROUND N-acetylneuraminate lyase catalyzes the cleavage of N-acetylneuraminic acid (sialic acid) to form pyruvate and N-acetyl-D-mannosamine. The enzyme plays an important role in the regulation of sialic acid metabolism in bacteria. The reverse reaction can be exploited for the synthesis of sialic acid and some of its derivatives. RESULTS The structure of the enzyme from Escherichia coli has been determined to 2.2 A resolution by X-ray crystallography. The enzyme is shown to be a tetramer, in which each subunit consists of an alpha/beta-barrel domain followed by a carboxy-terminal extension of three alpha-helices. CONCLUSIONS The active site of the enzyme is tentatively identified as a pocket at the carboxy-terminal end of the eight-stranded beta-barrel. Lys165 lies within this pocket and is probably the reactive residue which forms a Schiff base intermediate with the substrate. The sequence of N-acetylneuraminate lyase has similarities to those of dihydrodipicolinate synthase and MosA (an enzyme implicated in rhizopine synthesis) suggesting that these last two enzymes share a similar structure to N-acetylneuraminate lyase.

Structural insights into the protease-like antigen Plasmodium falciparum SERA5 and its noncanonical active-site serine.

The sera genes of the malaria-causing parasite Plasmodium encode a family of unique proteins that are maximally expressed at the time of egress of parasites from infected red blood cells. These multi-domain proteins are unique, containing a central papain-like cysteine-protease fragment enclosed between the disulfide-linked N- and C-terminal domains. However, the central fragment of several members of this family, including serine repeat antigen 5 (SERA5), contains a serine (S596) in place of the active-site cysteine. Here we report the crystal structure of the central protease-like domain of Plasmodium falciparum SERA5, revealing a number of anomalies in addition to the putative nucleophilic serine: (1) the structure of the putative active site is not conducive to binding substrate in the canonical cysteine-protease manner; (2) the side chain of D594 restricts access of substrate to the putative active site; and (3) the S(2) specificity pocket is occupied by the side chain of Y735, reducing this site to a small depression on the protein surface. Attempts to determine the structure in complex with known inhibitors were not successful. Thus, despite having revealed its structure, the function of the catalytic domain of SERA5 remains an enigma.

Structure of glyceraldehyde-3-phosphate dehydrogenase from Plasmodium falciparum

The malaria parasite Plasmodium falciparum is responsible for about two million deaths annually, making it important to obtain information about enzymes from this organism that represent potential drug targets. The gene for P. falciparum glyceraldehyde-3-phosphate dehydrogenase (PfGAPDH) has been cloned and the protein expressed as a hexahistidine-tagged recombinant protein in Escherichia coli. The recombinant protein has been crystallized and its three-dimensional structure determined. One molecule of the cofactor NAD+ is bound to each of the four subunits in the tetrameric enzyme. The major structural feature distinguishing human GAPDH from PfGAPDH is the insertion of a dipeptide (-KG-) in the so-called S loop. This insert, together with other characteristic single-amino-acid substitutions, alters the chemical environment of the groove that encompasses the R dyad and that links adjacent cofactor-binding sites and may be responsible for the selective inhibition of the enzyme by ferriprotoporphyrin IX.

Phage surface presentation and secretion of antibody fragments using an adaptable phagemid vector.

Phagemid vectors have been developed which promise to supersede hybridoma technology for the selection and production of human antibodies. We have modified an existing phagemid vector to improve the stability of synthesized soluble antibody fragments. The vector allows the antibody fragment to be produced: i) as a soluble protein incorporating a stable carboxyl terminal octapeptide (FLAG) or, ii) on the surface of a bacteriophage fused to a minor coat protein (the gene III protein). The antibody gene encoding the well characterized monoclonal antibody NC10 (an antibody that recognizes the neuraminidase of the influenza strain N9) was inserted as a single chain Fv construct into the phagemid vectors pHFA and pHFA/SacII. Western blotting, ELISA and electron microscopy studies showed that recombinant clones could be manipulated to either synthesize soluble protein into the periplasm or present the protein on the surface of bacteriophage. Cosynthesis of GroEL and GroES chaperonins resulted in complete proteolysis of the scFvNC10-FLAG-gIIIp fusion product and did not improve total phage production. Coexpression of chaperonins should be used with caution for library construction due to the expected selection pressure for protease resistant gene III fusions.

Inhibition of Malaria Parasite Development by a Cyclic Peptide That Targets the Vital Parasite Protein SERA5

ABSTRACT The serine repeat antigen (SERA) proteins of the malaria parasites Plasmodium spp. contain a putative enzyme domain similar to that of papain family cysteine proteases. In Plasmodium falciparum parasites, more than half of the SERA family proteins, including the most abundantly expressed form, SERA5, have a cysteine-to-serine substitution within the putative catalytic triad of the active site. Although SERA5 is required for blood-stage parasite survival, the occurrence of a noncanonical catalytic triad casts doubt on the importance of the enzyme domain in this function. We used phage display to identify a small (14-residue) disulfide-bonded cyclic peptide (SBP1) that targets the enzyme domain of SERA5. Biochemical characterization of the interaction shows that it is dependent on the conformation of both the peptide and protein. Addition of this peptide to parasite cultures compromised development of late-stage parasites compared to that of control parasites or those incubated with equivalent amounts of the carboxymethylated peptide. This effect was similar in two different strains of P. falciparum as well as in a transgenic strain where the gene encoding the related serine-type parasitophorous vacuole protein SERA4 was deleted. In compromised parasites, the SBP1 peptide crosses both the erythrocyte and parasitophorous vacuole membranes and accumulates within the parasitophorous vacuole. In addition, both SBP1 and SERA5 were identified in the parasite cytosol, indicating that the plasma membrane of the parasite was compromised as a result of SBP1 treatment. These data implicate an important role for SERA5 in the regulation of the intraerythrocytic development of late-stage parasites and as a target for drug development.