Human prion diseases

Expression and targeting of Syrian hamster prion protein induced by heat shock in transgenic Drosophila melanogaster

To evaluate the fruit fly as a model for studying neurodegenerative diseases caused by prions, transgenic flies were generated by introducing the Syrian hamster prion protein (SHaPrP) gene into the Drosophila melanogaster germ line by P element-mediated transformation. Nine transgenic lines were isolated; induction of transgenes that had been placed under the control of the Drosophila heat shock promoter, hsp 70, resulted in the synthesis of full-length SHaPrP. The relative molecular weight of the recombinant protein was lower than that of authentic SHaPrP due to incomplete processing of Asn-linked CHOs. To determine the cellular localization of SHaPrP, Drosophila Schneider line 2 cells were transfected with the same constructs used for fly transformation. Heat shock induced SHaPrP was anchored to the surface of S2 cells by a glycolipid, demonstrating that the carboxy-terminal glycolipidation signal of SHaPrP is recognized by this evolutionarily distant host. When SHaPrP was synthesized in transgenic flies constitutively by subjecting them to heat pulses continuously, no difference in their lifespans compared with controls was detected. Furthermore, expression of SHaPrP for 20 days did not produce protease resistant SHaPrP, which is the major and possibly only component of the infectious prion. In contrast to transgenic mice overexpressing SHaPrP, which develop a profound neuromyopathy, no disease phenotype was associated with expression of SHaPrP over the entire lifespan of transgenic flies.

Theoretical studies of sequence effects on the conformational properties of a fragment of the prion protein: implications for scrapie formation

BACKGROUND

Prion diseases are neurodegenerative disorders that appear to be due to a conformational change, involving the conversion of alpha-helices in the normal, cellular isoform of the prion protein (PrPC) to beta-structure in the infectious scrapie form (PrPSc). One form of Gerstmann-Sträussler-Scheinker syndrome (GSS), an inherited prion disease, is caused by mutation of Ala117 of PrPC to Val. We therefore set out to evaluate the effects of this mutation on the stability of the PrPC form.

RESULTS

We have performed molecular dynamics simulations of a portion of the PrPC sequence (residues 109-122, termed H1) that is proposed to figure prominently in the conversion of PrPC to PrPSc. In particular, beginning with H1 in the alpha-helical state, the conformational consequences of sequence changes at position 117 were investigated for six hydrophobic mutations. Of these, only the Val mutation was helix-destabilizing. Portions of this mutant peptide adopted and retained an extended conformation during a 2 ns simulation of the peptide in water.

CONCLUSIONS

The conformational transitions and structures observed in the simulation of the mutant peptide with Val at position 117 provide insight into the possible early steps in the conversion of PrPC to PrPSc.

Prion protein accumulation in the spinal cords of patients with sporadic and growth hormone associated Creutzfeldt-Jakob disease

An immunohistological study of the spinal cord in 20 cases of sporadic and 4 iatrogenic (growth hormone) cases of Creutzfeldt-Jakob (CJD) disease patients was performed to detect the presence of disease specific prion protein using a number of different antisera. Prion protein was present in all the growth hormone recipients and in 11 of the 20 sporadic CJD cases. Plaque-like deposits of prion protein were found in all the growth hormone cases and three of the sporadic cases. This is the first demonstration of the topographic immunolocalisation of prion protein in the spinal cord of CJD patients, a feature which could help elucidate some important aspects of the pathogenesis of CJD.

Proposed three-dimensional structure for the cellular prion protein

Prion diseases are a group of neurodegenerative disorders in humans and animals that seem to result from a conformational change in the prion protein (PrP). Utilizing data obtained by circular dichroism and infrared spectroscopy, computational studies predicted the three-dimensional structure of the cellular form of PrP (PrPc). A heuristic approach consisting of the prediction of secondary structures and of an evaluation of the packing of secondary elements was used to search for plausible tertiary structures. After a series of experimental and theoretical constraints were applied, four structural models of four-helix bundles emerged. A group of amino acids within the four predicted helices were identified as important for tertiary interactions between helices. These amino acids could be essential for maintaining a stable tertiary structure of PrPc. Among four plausible structural models for PrPc, the X-bundle model seemed to correlate best with 5 of 11 known point mutations that segregate with the inherited prion diseases. These 5 mutations cluster around a central hydrophobic core in the X-bundle structure. Furthermore, these mutations occur at or near those amino acids which are predicted to be important for helix-helix interactions. The three-dimensional structure of PrPc proposed here may not only provide a basis for rationalizing mutations of the PrP gene in the inherited prion diseases but also guide design of genetically engineered PrP molecules for further experimental studies.

Homozygosity for prion protein alleles encoding glutamine-171 renders sheep susceptible to natural scrapie

Natural scrapie has been viewed both as a recessive trait and as a contagious disease modulated by a host locus. To address this conundrum, we determined the structure of the sheep prion protein (PrP) gene, which contains three exons and extends over 20 kb of DNA. In the United States 86.4% of scrapie cases occur in Suffolk sheep, and within this breed 49 +/- 6% (+/- S.D., n = 69) of healthy animals carry one or more PrP alleles encoding Arg (R)-171. Four scrapie-affected sheep were homozygous for wild-type PrP open reading frames encoding the alternative Gln (Q)-171 allele. Analysis of additional cases revealed that all were Q/Q-171 homozygotes (n = 31), yielding a probability of 0.000004 that PrP genotype is unrelated to susceptibility. These data imply that homozygosity for Q-171 codons is necessary but not sufficient for the development of natural scrapie, echo reports of recessive manifestation, and parallel over-representation of PRNP codon 129 homozygotes in Creutzfeldt-Jakob disease of humans. Whereas progress has been substantial regarding experimental scrapie in rodents, the occurrence and spread of disease in flocks of sheep has remained enigmatic. Appreciation of the relationship between codon 171 genotype and susceptibility may help define the molecular basis of natural scrapie.