Characteristics of 263K scrapie agent in multiple hamster species.
Transmissible spongiform encephalopathy (TSE) diseases are infectious, fatal, neurodegenerative diseases of the central nervous system that affect a wide variety of mammals, including humans. In the past several decades, 3 new TSE diseases have been identified in different species: chronic wasting disease of deer and elk, bovine spongiform encephalopathy of domestic cattle, and variant Creutzfeldt-Jakob disease of humans. Thus, a better understanding of the process of cross-species transmission is needed.
Recognition of natural cross-species transmission is not straightforward. If a disease that crosses species has clinical or pathologic features similar to those of an already well-characterized TSE disease, it may not be recognized as a cross-species infection. Furthermore, some cross-species events involve slow processes in which the TSE agent adapts over several passages before recognizable clinical disease occurs (1).
The amino acid sequence of the prion protein (PrP) is known to be an influential factor for cross-species transmission of TSE disease to a new host. Multiple single nucleotide polymorphisms resulting in amino acid changes that control susceptibility to TSE disease have been identified in sheep, cervids, humans, and transgenic mice (2-6). Similarly, incubation periods have also been correlated with nonsynonomous single nucleotide polymorphisms in the PrP gene. For example, 2 polymorphic residues at amino acids 108 and 189 are associated with either short (Leu108/Thr189) or long (Phe108/Vall89) incubation periods in mice (7). Even a single point mutation in mice at amino acid position 101 has been shown to alter proteinase K-resistant prion protein (PrPres) deposition in brain, incubation periods, and host range (8).
In this study, we examined molecular and biochemical changes associated with cross-species transmission in 6 hamster species of the rodent subfamily Cricetinae. All animals were handled according to the National Institutes of Health guidelines and protocols approved by the Rocky Mountain Laboratories' (Hamilton, MT, USA) Institutional Animal Care and Use Committee.
Phylogenetic classification of these hamster subspecies is based on DNA sequences of mitochondrial cytochrome b gene and a portion of the NADH dehydrogenase 4 gene (9). These 6 species diverge into 3 genera, mainly Cricetulus (including Armenian and Chinese), Phodopus (including Djungarian and Siberian), and Mesocricetus (including Turkish and Syrian) hamster species (Figure 1). By inoculating each of these hamster species with a well-characterized, stable strain of Syrian hamster scrapie (263K), we were able to compare and analyze molecular and biochemical parameters of cross-species trans mission events. To identify the cross-species transmission event, we looked for recognizable features that may have emerged in the new host. We found that each new host species presented a profile unlike that of the original Syrian hamster host infected with 263K. These profile changes correlated with unique PrP amino acid sequences within the 6 hamster species. This finding suggests that host PrP sequences can change the phenotype presentation of the agent in the host and could thereby confound identification of cross-species transmission events.
[FIGURE 1 OMITTED]
Materials and Methods
Incubation Periods and Titers for Passaged 263K
The original source of 263K hamster agent came from Kimberlin et al. (10) and was passaged 3 times in Syrian hamsters at Rocky Mountain Laboratories. For cross-species transmissions, also referred to as first passage, weanling hamsters from each of the 6 hamster species were intracranially inoculated with 263K stock at a titer of 2 x [10.sup.9] lethal dose for 50% per [micro]L of a 1% brain homogenate. Clinically ill hamsters from each species were killed, and 1% brain homogenate was passaged intracranially into weanling hamster recipients of the same species (second passage). The process was repeated for a third passage. Brain homogenate from clinically ill third-passage hamsters was inoculated intracranially back into Syrian (back-passaged) hamsters.
Each hamster was killed when it had lost [approximately equal to] 30% of its body weight and was no longer able to remain upright and feed itself. We determined endpoint titrations for 263K, first, second, and third hamster passage inocula used in these experiments for all species (except Chinese hamsters) by preparing sequential 1:10 dilutions of a 1% brain homogenate to [10.sup.-8] or [10.sup.-10]. Dilutions were then injected intracranially into 6-8 hamsters for each dilution, and titers were determined as described (Figure 2) (11).
Immunoblot Analysis of Proteinase K-Sensitive Prion Protein and PrPres by Western blot
Proteinase K (PK)-sensitive prion protein (PrPsen) and PrPres were prepared as previously described (12,13). Samples were frozen at -20[degrees]C until they were subjected to electrophoresis on a 16% sodium dodecyl sulfate-polyacrylamide gel (Invitrogen, Carlsbad, CA, USA). Immunoblots were probed by using polyclonal antibody R30 to PrP (89-103 in Syrian hamsters) (14,15), which recognizes PrP from each of the 6 species. Blots were developed by using either enhanced chemiluminescence or enhanced chemifluorescence according to manufacturer's instructions (Amersham-Pharmacia, Uppsala, Sweden). Enhanced chemifluorescence blots were scanned by using a STORM fluorescent detection system (Amersham-Pharmacia) as described previously (16).
Sensitivity of Proteinase K
To demonstrate PrPres sensitivity to PK, we adjusted 20 [micro]L of a 20% (wt/vol) third-passage brain homogenate in 0.01 M Tris, pH 7.3, from each species to 100 mmol/L Tris HCl, pH 8.3, 1% Triton X-100, and 1% sodium deoxycholate. Samples were treated with 25 [micro]g/mL, 100 [micro]g/mL, 400 [micro]g/mL, or 1,600 [micro]g/mL PK in a total volume of 35 [micro]L and incubated at 37[degrees] for 1 h. The reaction was stopped by adding 2 [micro]L of 0.1 M phenylmethylsulfonyl fluoride and placed on ice for 10 min. Samples were then mixed in equal volumes with 2 x sample buffer, boiled 5 min, and subjected to electrophoresis on sodium dodecyl sulfate--polyacrylamide gels. PrP bands were quantitated as described above.
PrP Gene Sequencing
To sequence the PrP gene open reading frame (ORF), we based primers on published regions of sequence homology between the Syrian, Armenian, Chinese hamster; rat; and mouse PrP genes. Primers 7F, S/O(-1), C(-1), S/T(+2), C/O(+2), and 1R are located outside the ORF. The following primers were used: 7F-5'-GCCTTGTTCTTCATTTTGCAGA-3', S/O(-1) 5'-TCATTTTGCAGATCAGCCATC-3', C(-1) 5'TCATTTTGCAGATTAGCCAT-3', S/T(+2) 5'-GTACAA GCAGGGAGGCTTCCTTC-3', C/O(+2) 5'-GTACAAGC AGGGAGGCTTCCCTC-3', and 1R 5'-ACCCCTCCCCC AGCCTAG-3'.
[FIGURE 2 OMITTED]
Immunohistochemistry procedures were conducted as previously described (12). PrPres was detected by using R30 anti-PrP antibody (residues 89-103).
Incubation Periods and Titers
Incubation periods and infectivity titers are among the criteria used to define TSE strains (17,18). Therefore, we compared incubation periods and infectivity titers for 263K in Syrian hamsters with those observed for the 5 other hamster species. Cross-species transmission of Syrian-derived 263K to Turkish hamsters, both members of the genus Mesocricetus (Figure 1), had similar incubation periods (Table). Transmission of 263K to hamsters of the genus Phodopus (Djungarian and Siberian) had incubation periods similar to each other but different from those of the Mesocricetus hamsters. Although Chinese and Armenian hamsters each belong to the genus Cricetulus, after inoculation with 263K, their incubation periods differed from each other and from those of all the other species. In most instances, we observed prolonged incubation periods when Syrian 263K was inoculated into the new hosts. Because all the hamsters received the same inoculum at passage 1, this finding likely reflects the species barrier between the hosts (19) rather than inoculum titer.
Two additional passages from a donor to a recipient of the same species showed that incubation periods in most species differed considerably from those of the original Syrian hamsters (Table). Incubation periods for the new species decreased and then became stable between second and third passage and were considerably different from those of the original Syrian hamsters (Table). Incubation periods for Chinese hamsters were still decreasing between second and third passages. Because a fourth passage was not performed for Chinese hamsters, whether third passage reflects the stable incubation period is unknown. Thus, for Djungarian, Siberian, and Armenian hamsters, evidence was strong for unique incubation periods in the new species by second passage after inoculation with Syrian 263K agent.
To determine whether incubation period differences for each species resulted from differing infectivity concentration in the inocula, we used endpoint titration to determine the brain titers after first, second, and third passages (Table). These determinations were not conducted for Chinese hamsters because the long incubation periods would require several additional years. When comparing first-passage titers with titers in Syrian hamsters infected with 263K, the only decrease in infectivity titer was seen in Armenian hamsters (Table). When comparing second-passage titers with titers in Syrian hamsters infected with 263K, we observed a minimal decrease in Turkish, Siberian, and Armenian hamsters. We observed no notable changes in titers among third passage animals of all 6 species, which suggests stable titers in each species by third passage.
Additional evidence for adaptation of 263K agent to the new host species was obtained by infecting Syrian hamsters with brain homogenates from third-passage hamsters. If the agent had adapted to the new species, we would expect to see differences in incubation periods. In contrast, in the absence of adaptation, we would expect reversion back to the characteristic 263K Syrian incubation period. The only hamster for which third-passage brain homogenate resulted in a decrease in incubation period was the Chinese hamster. Even so, at 168 days this incubation period still differed from the characteristic 80-day incubation period for Syrian hamsters. These results indicate that the 263K agent adapted to the new host and that each 263K-infected hamster species has a unique incubation period (Table).
PrPres glycoform profiles are another criteria used to differentiate TSE strains (20-22). Therefore, we compared PrPres glycoform profiles from each of the 6 hamster species at each passage.
When Western blotting was used to compare percentages between the 3 PrPres bands (Figure 3, panel A), the data clearly showed 2 different PrPres glycoform profiles. The Turkish hamster PrPres glycoform profile shared similarities with that of both Syrian and Chinese hamsters. Siberian, Djungarian, and Armenian hamsters shared a second PrPres glycoform profile. PrPres glycoform patterns from Turkish, Chinese, Siberian, and Djungarian hamsters fluctuated noticeably over the 3 passages, which suggests a lack of stability while adapting to the new species. In contrast, PrPres glycoform patterns from Armenian hamsters did not fluctuate over the 3 passages, which suggests a stable strain in Armenian hamsters (Figure 3, panel A).
We also injected brain homogenates derived from the third-passage hamsters back into Syrian hosts. We found that glycoform patterns in the Syrian recipients were the same as those ordinarily associated with Syrian hamsters (Figure 3, panel B), which suggests, as with incubation periods, that the host had a predominant influence over glycoform patterns.
To investigate the possibility that differences in PrPres glycoform profiles were reflections of different PrPsen characteristics in the various hamster species, we analyzed PrPsen profiles by using Western blot. No differences were found in expression levels or banding patterns among the 6 hamster species (Figure 4, panel A). Bands detected at 37 kDa were proven to be PrPsen because they were competed out (protein signal disappeared) when we preincubated the antibody to PrP with a synthetic peptide specific for the PrP epitope. Bands >37 kDa did not compete out (Figure 4, panel B). All PrPsen samples were PK sensitive (data not shown).
[FIGURE 3 OMITTED]
PrPres resistance to PK digestion has also been used to differentiate TSE strains (23-25). When we compared PrPres resistance to PK from 263K Syrian and third-passage Turkish, Armenian, Chinese, Siberian, and Djungarian hamsters, we found no differences in sensitivity to PK. All samples retained equivalent PrPres signals on Western blots after treatment with 25 and up to 1,600 [micro]g/mL PK (data not shown).
Differentiation of TSE strains has also been based on regional distribution of PrPres and microscopic lesions in brains of infected individuals (18). Therefore, we studied lesion profiles in brain from 5-8 hamsters of each species at each passage. We scored 13 areas from 0 to 4 (none to the highest degree of PrPres distribution or lesions) (Figure 5, Scoring Examples). Averages for each brain region were scored and compared (Figure 5, Regional Brain Scores). A score change >1 between species or passages was considered a notable change for that region (26).
[FIGURE 4 OMITTED]
Microscopic lesion profiles (Figure 5, panels A1-E1) from the 3 passages for each species were compared with those of the 263K Syrian hamsters (stained with hemotoxylin and eosin [H&E]). We found that Djungarian hamster profiles were most similar to 263K Syrian hamster profiles. Second-passage Armenian hamsters had increased vacuolation in the cortex; Turkish, Siberian, and Chinese hamsters differed in multiple regions. Lesion profiles for the 3 passages in each of the new hamster host species, such as Chinese hamsters (Figure 5, H&E Chinese) regions 2 and 3, did not necessarily correlate with PrPres distribution (Figure 5, panel PrPres Chinese) within that host.
When comparing the PrPres deposition profile (Figure 5, PrPres panels [right side]) at each of the 3 passages to the Syrian PrPres deposition profile, we found that the profiles of the Turkish hamsters were the most similar. Because Syrian and Turkish hamsters are closely related phylogenetically and share similar PrPres glycoform patterns, this finding was not surprising. In the other 4 species (Djungarian, Siberian, Armenian, and Chinese), PrPres distribution in the thalamus was increased (region 6) over that in the same region for Syrian hamsters. Further changes were seen in Armenian hamsters; PrPres distribution was increased in the spinal cord (region 5) and olfactory bulb (region 10). PrPres distribution patterns in Chinese hamsters diverged from those in the Syrian hamsters in almost every region except the spinal cord (region 5). In all 6 species, including our original Syrian hamster species, unique pathologic phenotypes developed. Immunohistochemical and glycoform profiles for 2 of the 3 genera were independently unique, which suggests that similar host factors within those genera influenced these TSE characteristics.
[FIGURE 5 OMITTED]
To determine the respective contributions of the agent and host in immunohistochemical patterns, we injected brain homogenate from third-passage hamsters back into Syrian hamsters. When patterns were compared with those of 263K Syrian hamster, only a few differences from 263K Syrian were observed. Specifically, less PrPres was deposited in the posterior colliculus (region 2) in Syrian hamsters inoculated with brain homogenate from Chinese hamsters, and more PrPres was deposited in the thalamus (region 6) of Syrian hamsters inoculated with brain homogenate from Djungarian hamsters (Figure 6, panel A). We also observed a decrease in vacuolation in the hippocampus (region 8) and cortex (region 9) of Syrian hamsters inoculated with brain homogenate from Chinese hamsters (Figure 6, panel B). For all other hamster species inocula, no remarkable differences from 263K Syrian hamster were noted. Therefore, the host appeared to play an important role in determining immunohistochemical patterns. It is not known whether the differences seen in the Chinese and Djungarian hamsters are due to donor species effect (27,28), whereby a temporary change occurs as an agent is passed through a new host species, or whether selection of a new strain has occurred. To answer this question, a second passage through Syrian hamsters is needed. These results suggest that although 263K agent was substantially altered by passage through the new hamster species, in general it was not able to impart molecular characteristics like glycoform or the pathologic patterns established in the new species back to the Syrian hamsters.
Different PrP amino acid sequences have been associated with variation in lesion profiles, incubation periods, and susceptibility to TSE disease in humans and in sheep, cervid, and mouse models. We report the PrP gene sequences for Siberian, Djungarian, and Turkish hamsters. To determine how amino acid sequence might associate with the TSE characteristics we observed here, we compared our new sequences with the published PrP gene ORF of Syrian (29), Chinese, and Armenian hamsters (30,31).
When comparing the new prnp sequences to the Syrian prnp sequence, we found considerable variation in nucleotides. Siberian hamsters had 40 nt changes, and Djungarian hamsters had 41. These nucleotide changes resulted in 10 aa substitutions for both species; only 1 aa acid substitution, I215V, distinguished sequences between Siberian from Djungarian hamsters (Figure 7). Only Turkish and Syrian hamsters had 3 nt differences, resulting in 2 aa substitutions. An amino acid Y-to-F substitution was found at codon 6 in the signal sequence, and a heterozygous base was found at codon 103 (encoding both S and N). In addition, Turkish hamsters have a deletion of 1 octapeptide repeat ([DELTA]81-87) on both alleles, a characteristic shared with African Green monkeys (32). In humans, deletion of 1 octapeptide repeat occurs at a frequency of 0.5% and is not associated with disease (33,34). We found 34 nt changes for Armenian and 37 for Chinese hamsters, resulting in 7 aa substitutions for each hamster species, a finding that agrees with published data (30). The 3 aa differences that distinguish Armenian from Chinese hamsters are located at aa positions 103, 108, and 112 (30).
[FIGURE 6 OMITTED]
Of the 6 hamster species inoculated with a well-defined hamster scrapie source, each species not only was susceptible to the agent but also developed unique PrPres biochemical and pathologic characteristics. These characteristics, which included incubation periods, PrPres glycoform patterns, and PrPres distribution in brain, appeared to segregate into related genera with the exception of the genus Cricetulus (Armenian and Chinese hamsters). Because TSE characteristics were unique for 2 of 3 genera, a role for host factor involvement is implicated. Our data suggest that PrP amino acid sequence is the host factor responsible for the unique characteristics.
Data from our study and another experimental study (30) suggest that not only is the host responsible for determining TSE characteristics such as incubation periods but so is the agent. Our data show that closely related hamsters infected with the same strain of TSE have different incubation periods. These differences cannot be explained by differential expression levels of PrPsen because by Western blot, PrPsen expression was equivalent (Figure 4, panel A). Also, we believe that changes in incubation periods cannot be attributed to differential infectivity titers because only minor variations in titers were found. A second set of experiments showed that the same hamster host inoculated with different strains of TSE had different incubation periods, such as hyper (65 [+ or -] 1) and drowsy (168 [+ or -] 2) (23).
Because incubation periods and altered PrPres deposition in the brain have been linked to polymorphisms in the PrP amino acid sequence (8,35), we investigated the possibility that PrPres biochemical and pathologic changes correlate with different host PrP amino acid sequences. When comparing the PrP gene ORF for each of the 6 hamster species, we found 13 possible amino acid substitutions localized to 2 regions, either the N or the C terminus. Hamsters from 2 genera in this study (Phodopus and Mesocricetus) maintained sequence homogeneity at these 13 residues and had very similar TSE characteristics. Hamsters of the third genus, Cricetulus, differed in PrP gene sequence at 3 amino acids within the N-terminal polymorphic region. These polymorphic changes could explain why Armenian and Chinese hamsters have such different incubation periods, PrPres glycoform patterns, and immunohistochemical profiles from each other as well as from the 2 genera Cricetulus and Phodopus. It is also possible that closely related hamsters have unidentified genes that also influence TSE characteristics.
Our results are consistent with the published data indicating that amino acids 102-139 may control scrapie incubation periods in experimental models (7,30,36). In addition, our data suggest that PrPres glycoform profiles and lesion profiles are also associated with this region. Armenian and Chinese hamsters, both in the genus Cricetulus, show significant differences from each other, having only 3 aa substitutions at residues 103,108, and 112 in this N-terminal polymorphic region. In contrast, amino acid sequences from Djungarian and Siberian hamsters were the same in this region, and those from Turkish hamsters matched those from the Syrian hamsters. These findings suggest a direct role for these residues and the N-terminus in determining TSE characteristics. In addition, all 3 genera differ from each other at residue 139, the same position thought to participate in the hydrophobic core potentially stabilizing PrPsen in mice (37). The unstructured nature of this region has led some investigators to consider this stretch of residues as a potential nucleation site for conversion of PrPsen to PrPres (37). Sequence differences in this position may dramatically affect initial conversion events.
[FIGURE 7 OMITTED]
Certain amino acid substitutions may play only a minor role in TSE strain profiles. For instance, residue V215T is thought to be responsible for the structural differences between mouse and hamster PrPsen by introducing a bend in helix 3 (38). From our data, T215V/I substitutions may have had a minor in vivo effect with respect to TSE characteristics. Djungarian and Siberian hamsters differed only at this amino acid and had similar glycoform and IHC patterns as well as incubation periods.
Amino acid substitutions identified in this study segregated into genera with similar incubation periods, glycoform profiles, and brain pathologic changes. Because we used only 1 TSE agent, these changes can be attributed to the host factors and not to the agent. A previous study of 3 hamster species also concluded that host rather than agent had a predominant role in determining biochemical and molecular PrPres attributes (30). Because host factors seem to play a larger role in determining the TSE profile, identifying the source of infection in cross-species infections may be difficult, which would be especially worrisome when species important to humans (e.g., sheep, cattle, cervids) are involved. These ruminant species are heterogeneous and not nearly as closely related as the hamsters studied here.
Our study links PrP amino acid sequences to biochemical and pathologic profiles of PrPres in multiple hamster species infected with 263K hamster scrapie. To further investigate how specific amino acid substitutions in PrP are associated with specific TSE characteristics, these hamster and similar PrP gene sequences could be expressed in tissue culture assays and protein modeling experiments. The results of these experiments could broaden our understanding of TSE profiles and the role that PrP amino acid residues play, possibly leading to assays that could identify instances of cross-species transmission.
We thank Anita Mora and Gary Hettrick for graphics assistance; Bruce Chesebro, John Portis, and Byron Caughey for reviewing the paper; and Ed Schreckendgust for animal care assistance.
Syrian hamsters (Mesocricetus auratus) were purchased from Charles Rivers, Germantown, MD, USA; Turkish (Mesocricetus brandt), Armenian (Cricetulus migratorius), Chinese (Cricetulus griseus), Djungarian (Phodopus campbelli), and Siberian (Phodopus sungorus) hamsters were a generous gift from John Coe and bred at Rocky Mountain Laboratories animal facility.
This work was supported by the National Institute of Allergy and Infectious Diseases, Division of Intramural Research.
(1.) Race R, Meade-White K, Raines A, Raymond G J, Caughey B, Chesebro BJ. Subclinical scrapie infection in a resistant species: persistence, replication, and adaptation of infectivity during four passages. J Infect Dis. 2002;186(Suppl 2):S166-70. DOI: 10.1086/344267
(2.) Goldmann W, Hunter N, Benson G, Foster JD, Hope JJ. Different scrapie-associated fibril proteins (PrP) are encoded by lines of sheep selected for different alleles of the Sip gene. J Gen Virol. 1991;72:2411-7. DOI: 10.1099/0022-1317-72-10-2411
(3.) Westaway D, Zuliani V, Cooper CM, Da CM, Neuman S, Jenny AL, et al. Homozygosity for prion protein alleles encoding glutamine-171 renders sheep susceptible to natural scrapie. Genes Dev. 1994;8:959-69. DOI: 10.1101/gad.8.8.959
(4.) Bossers A, Schreuder BE, Muileman IH, Belt PB, Smits MA. PrP genotype contributes to determining survival times of sheep with natural scrapie. J Gen Virol. 1996;77:2669-73. DOI: 10.1099/00221317-77-10-2669
(5.) Jewell JE, Conner MM, Wolfe LL, Miller MW, Williams ES. Low frequency of PrP genotype 225SF among free-ranging mule deer (Odocoileus hemionus) with chronic wasting disease. J Gen Virol. 2005;86:2127-34. DOI: 10.1099/vir.0.81077-0
(6.) Meade-White K, Race B, Trifilo M, Bossers A, Favara C, Lacasse R, et al. Resistance to chronic wasting disease in transgenic mice expressing a naturally occurring allelic variant of deer prion protein. J Virol. 2007;81:4533-9. DOI: 10.1128/JVI.02762-06
(7.) Westaway D, Goodman PA, Mirenda CA, McKinley ME Carlson GA, Prusiner SB. Distinct prion proteins in short and long scrapie incubation period mice. Cell. 1987;51:651-62. DOI: 10.1016/00928674(87)90134-6
(8.) Barron RM, Thomson V, King D, Shaw J, Melton DW, Manson JCJ. Transmission of murine scrapie to P101L transgenic mice. J Gen Virol. 2003;84:3165-72. DOI: 10.1099/vir.0.19147-0
(9.) Conroy C J, Cook J. MtDNA evidence for repeated pulses of speciation within arvicoline and murid rodents. J Mamm Evol. 1999;6:22145. DOI: 10.1023/A:1020561623890
(10.) Kimberlin RH, Walker CA. Evidence that the transmission of one source of scrapie agent to hamsters involves separation of agent strains from a mixture. J Gen Virol. 1978;39:487-96. DOI: 10.1099/0022-1317-39-3-487
(11.) Dougherty RM. Animal virus titration techniques. In: Techniques in experimental virology. New York: Academic Press, Inc.; 1964.
(12.) Chesebro B, Trifilo M, Race R, Meade-White K, Teng C, LaCasse R, et al. Anchorless prion protein results in infectious amyloid disease without clinical scrapie. Science. 2005;308:1435-9. DOI: 10.1126/ science. 1110837
(13.) Oldstone MB, Race R, Thomas D, Lewicki H, Homann D, Smelt S, et al. Lymphotoxin-alpha- and lymphotoxin-beta-deficient mice differ in susceptibility to scrapie: evidence against dendritic cell involvement in neuroinvasion. J Virol. 2002;76:4357-63. DOI: 10.1128/JVI.76.9.4357-4363.2002
(14.) Race R, Jenny A, Sutton DJ. Scrapie infectivity and proteinase K-resistant prion protein in sheep placenta, brain, spleen, and lymph node: implications for transmission and antemortem diagnosis. J Infect Dis. 1998;178:949-53. DOI: 10.1086/515669
(15.) Caughey B, Raymond GJ, Ernst D, Race RE. N-terminal truncation of the scrapie-associated form of PrP by lysosomal protease(s): implications regarding the site of conversion of PrP to the protease-resistant state. J Virol. 1991;65:6597-603.
(16.) Race BL, Meade-White KD, Ward A, Jewell J, Miller MW, Williams ES, et al. Levels of abnormal prion protein in deer and elk with chronic wasting disease. Emerg Infect Dis. 2007; 13:824-30.
(17.) Bruce ME. TSE strain variation. Br Med Bull. 2003;66:99-108. DOI: 10.1093/bmb/66.1.99
(18.) Bruce ME. Scrapie strain variation and mutation. Br Med Bull. 1993;49:822-38.
(19.) Scott M, Groth D, Foster D, Torchia M, Yang SL, DeArmond SJ, et al. Propagation of prions with artificial properties in transgenic mice expressing chimeric PrP genes. Cell. 1993;73:979-88. DOI: 10.1016/0092-8674(93)90275-U
(20.) Collinge J, Sidle KC, Meads J, Ironside J, Hill AF. Molecular analysis of prion strain variation and the aetiology of "new variant" CJD. Nature. 1996;383:685-90. DOI: 10.1038/383685a0
(21.) Hill AF, Desbruslais M, Joiner S, Sidle KC, Gowland I, Collinge J, et al. The same prion strain causes vCJD and BSE. Nature. 1997;389:448-50, 526. DOI: 10.1038/38925
(22.) Parchi P, Capellari S, Chen SG, Petersen RB, Gambetti P, Kopp N, et al. Typing prion isoforms. Nature. 1997;386:232-4. DOI: 10.1038/386232a0
(23.) Bessen RA, Marsh RF. Biochemical and physical properties of the prion protein from two strains of the transmissible mink encephalopathy agent. J Virol. 1992;66:2096-101.
(24.) Bessen RA, Marsh RF. Distinct PrP properties suggest the molecular basis of strain variation in transmissible mink encephalopathy. J Virol. 1994;68:7859-68.
(25.) Bessen RA, Koeisko DA, Raymond GJ, Nandan S, Lansbury PT, Caughey B. Non-genetic propagation of strain-specific properties of scrapie prion protein. Nature. 1995;375:698-700. DOI: 10.1038/375698a0
(26.) Fraser H, Dickinson AG. The sequential development of the brain lesions of scrapie in three strains of mice. J Comp Pathol. 1968;78:301-11. DOI: 10.1016/0021-9975(68)90006-6
(27.) Kimberlin RH, Cole S, Walker CAJ. Temporary and permanent modifications to a single strain of mouse scrapie on transmission to rats and hamsters. J Gen Virol. 1987;68:1875-81. DOI: 10.1099/00221317-68-7-1875
(28.) Kimberlin RH, Walker CA, Fraser HJ. The genomic identity of different strains of mouse scrapie is expressed in hamsters and preserved on reisolation in mice. J Gen Virol. 1989;70:2017-25. DOI: 10.1099/0022-1317-70-8-2017
(29.) Basler K, Oesch B, Scott M, Westaway D, Walchli M, Groth DF, et al. Scrapie and cellular PrP isoforms are encoded by the same chromosomal gene. Cell. 1986;46:417-28. DOI: 10.1016/0092-8674 (86)90662-8
(30.) Lowenstein DH, Butler DA, Westaway D, McKinley MP, DeArmond S J, Prusiner SB. Three hamster species with different scrapie incubation times and neuropathological features encode distinct prion proteins. Mol Cell Biol. 1990; 10:1153-63.
(31.) Oesch B, Westaway D, Walchli M, McKinley MP, Kent SB, Aebersold R, et al. A cellular gene encodes scrapie PrP 27-30 protein. Cell. 1985;40:735-46. DOI: 10.1016/0092-8674(85)90333-2
(32.) Schatzl HM, Da CM, Taylor L, Cohen FE, Prusiner SBJ. Prion protein gene variation among primates. J Mol Biol. 1995;245:362-74. DOI: 10.1006/jmbi.1994.0030
(33.) Collinge J, Harding AE, Owen F, Poulter M, Lofthouse R, Boughey AM, et al. Diagnosis of Gerstmann-Straussler syndrome in familial dementia with priori protein gene analysis. Lancet. 1989;2:15-7. DOI: 10.1016/S0140-6736(89)90256-0
(34.) Goldfarb LG, Brown P, McCombie WR, Goldgaber D, Swergold GD, Wills PR, et al. Transmissible familial Creutzfeldt-Jakob disease associated with five, seven, and eight extra oetapeptide coding repeats in the PRNP gene. Proc Natl Acad Sci U S A. 1991;88:10926-30. DOI: 10.1073/pnas.88.23.10926
(35.) Barron RM, Manson JC. A gene-targeted mouse model of P102L Gerstmann-Straussler-Scheinker syndrome. Clin Lab Med. 2003;23:161-73. DOI: 10.1016/S0272-2712(02)00067-7
(36.) Supattapone S, Muramoto T, Legname G, Mehlhorn I, Cohen FE, DeArmond S J, et al. Identification of two prion protein regions that modify scrapie incubation time. J Virol. 2001;75:1408-13. DOI: 10.1128/JVI.75.3.1408-1413.2001
(37.) James TL, Liu H, Ulyanov NB, Farr-Jones S, Zhang H, Donne DG, et al. Solution structure of a 142-residue recombinant prion protein corresponding to the infectious fragment of the scrapie isoform. Proc Natl Acad Sci U S A. 1997;94:10086-91. DOI: 10.1073/ pnas.94.19.10086
(38.) Liu H, Farr-Jones S, Ulyanov NB, Llinas M, Marqusee S, Groth D, et al. Solution structure of Syrian hamster prion protein rPrP(90231). Biochemistry. 1999;38:5362-77. DOI: 10.1021/bi982878x
Author affiliation: National Institute of Allergy and Infectious Diseases, Hamilton, Montana, USA
Address for correspondence: Kimberly D. Meade-White, Laboratory of Persistent Viral Diseases, Rocky Mountain Laboratories, National Institute of Allergy and Infectious Diseases, 903 South Fourth St, Hamilton, MT 59840-2932, USA; email: firstname.lastname@example.org
Use of trade names is for identification only and does not imply endorsement by the Public Health Service or by the U.S. Department of Health and Human Services.
Ms Meade-White is a senior research assistant in the Laboratory of Persistent Viral Diseases, National Institute of Allergy and Infectious Diseases. Her primary interest is infectious diseases of the central nervous system, including transmissible spongiform encephalopathies. Her background includes research in HIV and cyclic neutropenia.
Table. Averaqe incubation period for 263K scrapie * Cross-species 263K Hamster species Titer/50 [micro]L ([dagger]) Dpi [+ or -] SD (1% BH) Syrian 85 2 x [10.sup.9] Turkish 91 [+ or -] 4.9 1 x [10.sup.8.9] Djungarian 155 [+ or -] 23.4 1 x [10.sup.6.4] Siberian 148 [+ or -] 26.5 1 x [10.sup.6.3] Chinese 372 [+ or -] 29.1 ND Armenian 188 [+ or -] 10.4 1 x [10.sup.7.35] Second passage Hamster species Titer/50 [micro]L ([dagger]) Dpi (1% BH) Syrian ND ND Turkish 103 [+ or -] 7.2 1 x [10.sup.6.7] Djungarian 100 [+ or -] 9.0 1 x [10.sup.9.6] Siberian 117 [+ or -] 9.9 1 x [10.sup.7.75] Chinese 233 [+ or -] 17.9 ND Armenian 156 [+ or -] 4.8 1 x [10.sup.7.75] Third passage Back passage Hamster ([double dagger]) species Titer/50 [micro]L ([dagger]) Dpi (1% BH) Dpi Syrian ND ND 79 [+ or -] 5 Turkish 85 [+ or -] 7.6 1 x [10.sup.8.25] 76 [+ or -] 0 Djungarian 99 [+ or -] 7.2 1 x [10.sup.9.7] 97 [+ or -] 7 Siberian 114 [+ or -] 8.3 1 x [10.sup.8.1] 128 [+ or -] 17 Chinese 207 [+ or -] 15.2 ND 168 [+ or -] 7 Armenian 145 [+ or -]7.5 >1 x [10.sup.8.5] 145 [+ or -] 18 * Dpi, days postinoculation; ND, not done; BH, brain homogenate. ([dagger]) 16 hamsters/species. ([double dagger]) In Syrian hamster. Figure 1. Taxonomic classification for 6 hamster species. Phylogenetically, these species are grouped into closely related taxonomic genera (9). Common Subfamily Genus Species name Cricetinae Mesocricetus Auratus Syrian Brandt Turkish Phodopus Campbelli Djhungarian Sungorus Siberian Cricetulus Gnseus Chinese Migratorius Armenian
|Printer friendly Cite/link Email Feedback|
|Author:||Meade-White, Kimberly D.; Barbian, Kent D.; Race, Brent; Favara, Cynthia; Gardner, Don; Taubner, Lar|
|Publication:||Emerging Infectious Diseases|
|Date:||Feb 1, 2009|
|Previous Article:||Seoul virus and hantavirus disease, Shenyang, People's Republic of China.|
|Next Article:||Prospective surveillance of invasive group A streptococcal disease, Fiji, 2005-2007.|