Kristiina Takkinen

Semliki Forest virus-specific non-structural protein nsP3 is a phosphoprotein.

Antisera were raised in rabbits against fusion proteins consisting of beta-galactosidase and partial amino acid sequences of Semliki Forest virus (SFV)-specific non-structural proteins nsP1, nsP2, nsP3 and nsP4. The antisera were specific since each of them precipitated only one labelled protein of a size expected for nsP1, nsP2, nsP3 or nsP4 from lysates of [35S]methionine-labelled SFV-infected BHK-21 cells. The specific antisera also precipitated p220 (with sequences of nsP1, nsP2 and nsP3), p155 (nsP1 and nsP2) and p135 (nsP3 and nsP4) which have been previously shown to be cleavage products of the polyprotein precursor of the non-structural proteins. nsP1, nsP4 and most of nsP3, together with the virus-specific RNA polymerase activity, were in the mitochondrial pellet (P15) fraction of infected BHK-21 cells whereas nsP2 was evenly distributed between P15 and the supernatant fraction (S15). Only antisera directed against nsP3 sequences precipitated a labelled protein from cells incubated with [32P]orthophosphate during SFV infection. Treatment of the immunoprecipitate with calf alkaline intestinal phosphatase reduced the amount of labelled nsP3 considerably. Immunoprecipitated 32P-labelled nsP3, isolated by SDS-PAGE, was subjected to acid hydrolysis. Both phosphoserine and phosphothreonine but not phosphotyrosine could be identified in the hydrolysate. Approximately twice as much [32P]serine as [32P]threonine was detected in nsP3. P15 and S15 fractions were prepared from [35S]methionine- and 32P-labelled SFV-infected cells and the 35S/32P ratio of nsP3 was determined after immunoprecipitation and SDS-PAGE. The nsP3 in S15 was less heavily phosphorylated (about 50%) than P15-associated nsP3. Anti-nsP3 serum revealed large cytoplasmic vesicles in SFV-infected cells in indirect immunofluorescence microscopy.

Comparison of the lipid-containing bacteriophages PRD1, PR3, PR4, PR5 and L17.

Five broad host range lipid-containing bacteriophages PRD1, PR3, PR4, PR5 and L17 isolated from different parts of the world were compared using biological and structural criteria. Virus morphology as well as genome sizes appeared to be identical. However, these viruses could be distinguished by restriction endonuclease mapping and by their structural protein patterns in SDS--gel electrophoresis. The viruses studied thus form a very close group of lipid-containing bacteriophages. We suggest PRD1 as a model organism for this group and that the group be called the PRD1 phage group.

Transient dimers of allergens.

Background Allergen-mediated cross-linking of IgE antibodies bound to the FcεRI receptors on the mast cell surface is the key feature of the type I allergy. If an allergen is a homodimer, its allergenicity is enhanced because it would only need one type of antibody, instead of two, for cross-linking. Methodology/Principal Findings An analysis of 55 crystal structures of allergens showed that 80% of them exist in symmetric dimers or oligomers in crystals. The majority are transient dimers that are formed at high protein concentrations that are reached in cells by colocalization. Native mass spectrometric analysis showed that native allergens do indeed form transient dimers in solution, while hypoallergenic variants of them exist almost solely in the monomeric form. We created a monomeric Bos d 5 allergen and show that it has a reduced capability to induce histamine release. Conclusions/Significance The results suggest that dimerization would be a very common and essential feature for allergens. Thus, the preparation of purely monomeric variants of allergens could open up novel possibilities for specific immunotherapy.

Replication of the Genome of Alphaviruses

SUMMARY The genome of Semliki Forest virus (SFV) is 11 442 nucleotides with a 5′ cap-structure and a 3′ poly(A) tail of about 100 residues. The genome of the closely related Sindbis virus (SIN) is slightly longer (11 703 nucleotides). The parental RNA is first translated from the 5′ two thirds to yield; nsP1, nsP2, nsP3 and nsP4, which are cleaved from a polyprotein of 2431 amino acids (SFV). The parental genome is copied to a full-length minus strand with poly(U) at the 5′ end. The minus strand is used as template for the synthesis of 42 S RNA in membrane-bound replicative-intermediate (RI) structures. In addition to 42 S RNA, a 3′-coterminal subgenomic 26 S mRNA, coding for the structural proteins, is synthesized by internal initiation at the minus strand. Capping and methylation of both plus-strand RNAs occur concomitantly with their synthesis. Analysis of Sindbis virus temperature-sensitive RNA-negative mutants have shown that one complementation group (B) is specifically associated with the synthesis of minus strands. Another, group F, is involved in the polymerization step of both minus- and plus-strand 42 S RNA, and of the 26 S mRNA. The synthesis of minus strands is normally dependent on protein synthesis. There is a shut off of the minus-strand RNA synthesis at about 3 h post-infection. This is apparently regulated by a virus-specific protein, represented by the complementation group A. The same protein is involved in the regulation of the initiation of 26 S RNA together with a component represented by group G mutants. Comparative analysis of SFV and SIN RNAs and DI RNAs of both viruses suggests that perhaps only 19 nucleotides from the 3′ end and about 150 nucleotides from the 5′ end are needed for replication of the alphavirus RNAs. In some SIN DI RNAs the proposed secondary structure at the 5′ end is replaced by a cellular tRNAASP suggesting that the secondary structure rather than nucleotide sequence is sufficient for the recognition by the viral polymerase. Even when the primary structure of the four non-structural proteins of both SFV and SIN is known, the correlation of the genetic data with the individual proteins has not yet been possible.

Automated Panning and Screening Procedure on Microplates for Antibody Generation from Phage Display Libraries

Antibody phage display technology is well established and widely used for selecting specific antibodies against desired targets. Using conventional manual methods, it is laborious to perform multiple selections with different antigens simultaneously. Furthermore, manual screening of the positive clones requires much effort. The authors describe optimized and automated procedures of these processes using a magnetic bead processor for the selection and a robotic station for the screening step. Both steps are performed in a 96-well microplate format. In addition, adopting the antibody phage display technology to automated platform polyethylene glycol precipitation of the enriched phage pool was unnecessary. For screening, an enzyme-linked immunosorbent assay protocol suitable for a robotic station was developed. This system was set up using human γ-globulin as a model antigen to select antibodies from a VTT naive human single-chain antibody (scFv) library. In total, 161 γ-globulin-selected clones were screened, and according to fingerprinting analysis, 9 of the 13 analyzed clones were different. The system was further tested using testosterone bovine serum albumin (BSA) and β-estradiol-BSA as antigens with the same library. In total, 1536 clones were screened from 4 rounds of selection with both antigens, and 29 different testosterone-BSA and 23 β-estradiol-BSA binding clones were found and verified by sequencing. This automated antibody phage display procedure increases the throughput of generating wide panels of target-binding antibody candidates and allows the selection and screening of antibodies against several different targets in parallel with high efficiency. (Journal of Biomolecular Screening 2009:282-293)

Fine tuning of an anti-testosterone antibody binding site by stepwise optimisation of the CDRs

BACKGROUND We have previously reported specificity improvement of an anti-testosterone monoclonal antibody (3-C4F5) by random mutagenesis of the third complementarity determining regions (CDR3s) and by phage display selection. OBJECTIVES Here we extend the mutagenesis strategy to the other CDRs and select the mutant libraries using two different approaches in order to further fine-tune the binding properties of this recombinant Fab fragment. STUDY DESIGN To improve the affinity the new mutant libraries were selected by using limiting, decreasing concentrations of biotinylated testosterone (TES) in solution and capturing the binders on streptavidin-coated microtiter plate. The specificity was improved by preincubating the mutant libraries in solution with a high concentration of the most problematic cross-reacting steroid, dehydroepiandrosterone sulfate (DHEAS). RESULTS In two different light chain CDR1 mutant clones isolated from the affinity pannings, the relative TES affinity was increased over 10-fold while the cross-reactivities to related steroids were preserved at the same level as in the parental combined CDR3 mutant clone. New heavy chain CDR1 and light chain CDR2 mutants showing slightly decreased cross-reactivities were isolated from specificity selections. By combining compatible mutant CDRs together we were able to create a Fab fragment with over 12-fold higher relative TES affinity and significantly lower cross-reactivity to DHEAS when compared to the original monoclonal antibody 3-C4F5. CONCLUSIONS Our results demonstrate that a high-affinity and selective recombinant Fab fragment working over a wide TES concentration range with clinical samples could be generated by CDR mutagenesis and phage display selection.

Proteolytic processing of semliki forest virus-specific non-structural polyprotein

The processing and stability of the non-structural (ns) proteins of Semliki Forest virus were studied in vivo. Virus-specific proteins from infected cells were identified by immunoprecipitation with monospecific antisera. The complete ns precursor, P1234, translated within 7 to 9 min of the start of translation, was processed before the completion of translation into P123 and nsP4. Pulse-chase experiments showed that the mature ns proteins were relatively stable for at least 2 h. Interestingly, the decrease in the amount of the P34 precursor during chase is accompanied by an increase only in the amount of nsP3, which could explain the observed lower amount of nsP4 in infected cells. In cells infected with SFV RNA- mutants ts4 and ts6 maintained at the restrictive temperature, nsP4 but no nsP1, nsP2 or nsP3 accumulated in addition to the ns precursor proteins P1234, P123, P12 and P34. Translation in vitro of mRNAs from a cDNA clone, encoding P1234 with a deletion in the carboxy-terminal proteinase domain of nsP2, did not yield nsP1, nsP2 or nsP3 but only nsP4, indicating that cleavage at the nsP3/4 sites is independent. Evidently, nsP4 is produced by a nascent cleavage of the growing P1234, catalysed by its own proteinase activity; the proteolytic cleavages at the nsP1/2 and nsP2/3 sites are catalysed by the proteinase moiety of nsP2.

Evolution of Poliovirus During an Outbreak: Sequential Type 3 Poliovirus Isolates from Several Persons Show Shifts of Neutralization Determinants

An outbreak of poliomyelitis in Finland resulted in the widespread circulation of wild-type 3 poliovirus strains that had antigenic properties distinct from the strains used to produce the attenuated and inactivated vaccines. Considerable variation was observed in the ability of broadly reacting monoclonal antibodies directed against type 3 poliovirus to neutralize the 54 strains examined. Sequential isolates from several persons showed an antigenic drift with these monoclonal antibodies and selected human sera. In addition, some faecal specimens were found to contain more than one antigenic variant. Primer extension sequencing of genomic RNAs of three plaque-purified antigenic variants isolated from one patient showed base substitutions in the region coding for the major antigenic site of poliovirus type 3. The resulting difference in the amino acid sequence in the virion protein VP1 could explain the differences observed in the neutralization of these strains by the monoclonal antibodies. Whether the observed changes in the antigenic characteristics of the sequential isolates represent true antigenic drift under immunological pressure or whether the emergence of the new variants is based on other modes of selection during replication is not known.

Hevein-specific recombinant IgE antibodies from human single-chain antibody phage display libraries

IgE antibodies distinctively recognising allergenic epitopes would be ideal reagents in immunodiagnostics to detect and quantify allergens, as well as for the development of allergy diagnostics and therapeutics. We have isolated recombinant human IgE antibodies specific for the major latex allergen, hevein, from antibody phage display libraries using a green fluorescent protein (GFP)-hevein fusion as a selection antigen. Human IgE phage display libraries were constructed by combining the IgE heavy chain genes to kappa and lambda light-chain genes which were isolated from lymphocytes of a latex allergic patient. The screening of antibody libraries resulted in the enrichment of two hevein-binding scFvs designated as 1A4 and 1C2. Both antibodies showed specific binding to the hevein that could be inhibited by both the recombinant GFP-hevein and native hevein isolated from latex examination gloves. The scFvs were prone to aggregate and, thus, for further characterisation, they were converted to Fab fragments with human IgG1 or IgE isotype. Similar hevein-binding properties of the 1A4 and 1C2 Fab fragments and human IgE serum pool, conventionally used in the detection of latex allergens, demonstrate the potential utility of these recombinant antibodies for the analysis of latex allergen.

Efficient secretion of murine Fab fragments by Escherichia coli is determined by the first constant domain of the heavy chain.

Fab fragments of IgG1 and IgG3 subclass antibodies which bind to 2-phenyloxazolone (Ox) were produced in Escherichia coli. The signal sequences of the Fd and L chains were correctly processed, the fragments were secreted into the periplasmic space and released into the culture medium upon prolonged cultivations. The yields of active Ox IgG1 and Ox IgG3 Fab fragments after one-step purification from the culture medium by affinity chromatography were 2 micrograms/ml and 0.5 micrograms/ml, respectively. The majority of the purified Ox IgG1 Fab was properly assembled, but in the case of Ox IgG3, the preparation was found to consist of a complete L chain and C-terminally degraded fragments of the Fd chain. A deletion up to the interchain disulfide bond in the first constant domain (CH1) of the Ox IgG3 Fd chain led to proper assembly of the truncated Fab fragment. The production level of the truncated fragment was comparable to that of the Ox IgG1 Fab and its hapten-binding activity similar to that of the idiotype monoclonal antibody. The temperature stability of the Ox IgG1 Fab was similar to that of the intact antibody. However, both of the Ox IgG3 Fab fragments showed reduced stability, suggesting that the CH1 domain contributes significantly to the thermal stability of the Fab fragment.