Markus Moser

Prion (PrPSc)-specific epitope defined by a monoclonal antibody

Prions are infectious particles causing transmissible spongiform encephalopathies (TSEs). They consist, at least in part, of an isoform (PrPSc) of the ubiquitous cellular prion protein (PrPC). Conformational differences between PrPCand PrPScare evident from increased β-sheet content and protease resistance in PrPSc(refs 1,2,3). Here we describe a monoclonal antibody, 15B3, that can discriminate between the normal and disease-specific forms of PrP. Such an antibody has been long sought as it should be invaluable for characterizing the infectious particle as well as for diagnosis of TSEs such as bovine spongiform encephalopathy (BSE) or Creutzfeldt–Jakob disease (CJD) in humans. 15B3 specifically precipitates bovine, murine or human PrPSc, but not PrPC, suggesting that it recognizes an epitope common to prions from different species. Using immobilized synthetic peptides, we mapped three polypeptide segments in PrP as the 15B3 epitope. In the NMR structure of recombinant mouse PrP, segments 2 and 3 of the 15B3 epitope are near neighbours in space, and segment 1 is located in a different part of the molecule. We discuss models forthe PrPSc-specific epitope that ensure close spatial proximity of all three 15B3 segments, either by intermolecular contacts in oligomeric forms of the prion protein or by intramolecular rearrangement.

DEVELOPMENTAL EXPRESSION OF THE PRION PROTEIN GENE IN GLIAL CELLS

Replication of prions is dependent on the presence of the host protein PrPc. During the course of disease, PrPc is converted into an abnormal isoform, PrPSc, which accumulates in the brain. Attempts to identify the cell type(s) in which prion replication and PrP conversion occur have reached conflicting results. Although PrP mRNA is present in high amounts in neurons throughout the life of the animal, PrPSc initially accumulates in astrocytes and possibly other glial cells and, later in the course of the disease, spreads diffusely in the tissue, often in white matter. We report here that PrP mRNA is expressed not only in neurons but also in astrocytes and oligodendrocytes throughout the brain of postnatal hamsters and rats. The level of glial Prp mRNA expression in neonatal animals was comparable to that of neurons and increased two-fold during postnatal development. A substantial portion of brain PrP mRNA is therefore contributed by glial cells. Our results provide an explanation for the accumulation of PrPSc in white matter tissue and in the cytoplasm of glial cells and argue for a direct involvement of glia in prion propagation.

Validation of a luminescence immunoassay for the detection of PrPSc in brain homogenate

A luminescence immunoassay (LIA) was developed for the diagnosis of bovine spongiform encephalopathy (BSE) in brain tissue using two different monoclonal antibodies for capture and detection of the protease-resistant fragment of the pathological prion protein (PrP27-30). PrP27-30 currently represents the most reliable marker for the infectious particle (denominated prion) causing transmissible spongiform encephalopathies (TSEs). Internal and official validation studies of this assay are described using brain homogenates from ascertained BSE positive and negative cows. Using more than 300 positive and 1400 negative bovine or ovine samples, an excellent sensitivity and specificity of 100% were demonstrated. More than 1000-fold dilutions of a BSE positive homogenate still resulted in a clear positive signal. In combination with a simple homogenisation procedure for the preparation of the samples, this assay lends itself for large scale screening of cattle and sheep for TSEs using complete automation of the process.

Factors determining the frequency of plasmid cointegrate formation mediated by insertion sequence IS3 from Escherichia coli

SummaryTransposition events mediated by plasmid-borne copies of the insertion sequence IS3 of Escherichia coli are difficult to detect because of a low frequency of cointegrate formation. We found that cointegration activity could be strongly enhanced by using plasmid constructions in which a second IS3 element, disabled by a large deletion, was placed adjacent to an intact IS3 copy. Attempts to construct plasmids containing two adjacent intact IS3 copies were unsuccessful, probably because of instability. Transpositional hyperactivity of tandemly duplicated IS sequences was previously described for spontaneous duplications of IS21 and IS30 and may well be a more general phenomenon. The frequency of cointegration events was also strongly increased in an E. coli strain deficient in Dam methylation, suggesting that IS3, like some other Dam site-containing IS elements, is regulated by the Dam methylation system. Insertion sites were strongly clustered within the target lambda repressor gene; however no sequence specificity determinants could be identified. All insertions analyzed carried the IS element in the same orientation; target sequence duplications were mostly 3 bp, but in some cases 4 by long. To obtain information about the roles of the open reading frames (ORFs) in IS3, we constructed plasmid-borne mutant elements in which potentially functional reading frames were inactivated by site-directed mutations; the mutants were introduced into partial tandem constructions and tested in cointegration assays. Mutations inactivating the putative initiation codons of ORF I and 11 in the intact element reduced insertion activity to less than 4% of the wild type, whereas the introduction of a termination codon into ORF IV had no effect on cointegration frequency. We conclude that translation of ORFs I and II is essential for cointegration activity and that the mutagenized ATG codons most probably serve as the normal initiation codons in the wild-type element. In contrast, ORF IV could either be non-functional or its gene product could be supplied in trans from chromosomal elements.