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Chronic wasting disease agents in nonhuman primates.

Chronic wasting disease (CWD) is a transmissible spongiform encephalopathy that can infect mammals in the family Cervidae, which includes deer, elk, and moose, among other species. Initially detected in a captive deer in 1967, the disease is now widespread in the United States, Canada, and South Korea (1). Because cervids are commonly consumed as food by humans and other mammals, the cross-species potential of the causal pathogen must be determined. CWD prions injected intracerebrally have infected agricultural animals and scavengers (2); however, transgenic mice that expressed human prion protein (PrP) were not susceptible (3-6) through this route. We previously analyzed the susceptibility of 2 genera of nonhuman primates to CWD agents by intracerebral and oral routes (7). The results showed a high attack rate in squirrel monkeys (Saimiri sciureus) inoculated intracerebrally but a low attack rate and long incubation periods by those exposed orally. In contrast, no cynomolgus macaques (Macaca fascicularis) showed clinical signs of transmissible spongiform encephalopathy (TSE) when exposed by either route. The long incubation periods observed in squirrel monkeys prompted us to observe the remaining monkeys for >4 additional years. Here we provide an update and report results of new experiments showing that squirrel monkey-adapted CWD (SM-CWD) has an accelerated incubation period on second passage.

The Study

Squirrel monkeys were inoculated intracerebrally or orally with CWD inocula (7). We initially reported that 11/13 intracerebrally infected monkeys were euthanized at 41 months postinoculation (mpi) on average, and disease developed in 2/12 orally infected squirrel monkeys on average of 69 mpi (7). Disease developed in the 2 remaining intracerebrally infected squirrel monkeys at 61 and 75 mpi, respectively, changing the intracerebral attack rate to 100% (Figure 1, Table 1). Of the 10 remaining orally inoculated squirrel monkeys, disease developed in 9, bringing the overall oral attack rate to 92% and the average incubation period to 68 mpi (Figure 1, Table 1). Clinical signs were subtle; the most prominent finding was gradual weight loss (Table 1). A final diagnosis of CWD agent infection was made by using immunoblotting and immunohistochemical testing to determine accumulation of abnormal, disease-associated prion protein (PrPres) in brain tissue (wwwnc.cdc.gov/EID/article/20/5/13-0778Techapp1.pdf).

To compare the neuropathologic changes in intracerebrally and orally infected squirrel monkeys, we analyzed 10 brain regions for spongiform lesion severity and PrPres deposition (Figure 1, panels B, C). No statistically significant differences were noted between the 2 routes of infection (p<0.05). All squirrel monkeys studied had severe spongiform degeneration in the striatum (Figure 1, panel D) and little involvement in cerebellum and occipital lobes (Figure 1, panel E). Spongiform lesions in cortical gray matter were not consistent throughout the brain. Affected areas were commonly observed adjacent to normal regions, most frequently in the frontal, temporal, and parietal lobes (Figure 1, panel F). Except for the striatum, PrPres deposition was generally most prominent in areas that showed severe vacuolation. PrPres deposits appeared in 2 forms: dense punctate extracellular plaques (Figure 1, panel G) and less dense pericellular aggregates. The spleens of CWD agent-infected squirrel monkeys were positive for PrPres in 46% of intracerebrally infected and 60% of orally infected squirrel monkeys (Figure 1, panel H). At least 1 lymph node was positive in 30% of intracerebrally infected squirrel monkeys and in 40% of orally infected squirrel monkeys (Figure 1, panel J; Technical Appendix).

Of the squirrel monkeys under study, 3 PRNP genotypes were represented (7). In the group of orally infected squirrel monkeys, 3 had a unique heterozygous genotype that encoded either 4 or 5 octapeptide repeats. Two of these monkeys were the last orally infected monkeys to be euthanized because of clinical disease (80 and 107 mpi), and the third heterozygote was clinically normal at 108 mpi. Heterozygosity within the PRNP gene has been shown to delay or prevent prion disease (8) and may play a role in this study.

We inoculated cynomolgus macaques as another nonhuman primate model for cross-species transmission of CWD. Compared with squirrel monkeys, cynomolgus macaques are biologically closer to humans, and cynomolgus macaque PrP is more homologous to human PrP (7). Nine cynomolgus macaques were inoculated orally and 6 were inoculated intracerebrally with 1 of 3 CWD pools as described (7). Our first report included negative data from 1 cynomolgus macaque euthanized at 49 mpi (7). Since then, we have euthanized and screened 6 cynomolgus macaques for TSE (Table 2). No evidence of prion infection was detected by immunoblot and immunohistochemical methods (data not shown).

[FIGURE 1 OMITTED]

The lack of CWD transmission during >10 years suggests that a substantial species barrier exists between cervids and cynomolgus macaques. In most TSE animal models, PrPres can be detected by 1/3-1/2 of the known incubation periods. If we extrapolate this to the cynomolgus macaques in this study, negative test results at 9 years would suggest that the incubation period would be >18 years. Other prion studies of cynomolgus macaques reported clinical disease within 2-3 years after inoculation with variant Creutzfeldt-Jakob disease agents (9), 3 years after inoculation with bovine spongiform encephalopathy agents (10,11), and 5 years after inoculation with sporadic Creutzfeldt-Jakob disease agents (9,12). In contrast, our findings indicate that CWD is unlikely to develop in cynomolgus macaques.

The cause of susceptibility to CWD agents in squirrel monkeys and resistance to them in cynomolgus macaques is uncertain. Prnp/PRNP gene sequence variation has been linked to disease susceptibility (8), and differences in the PRNP genes of cynomolgus macaques and the genes of squirrel monkeys could play a major role. Comparison of PRNP sequences among cynomolgus macaques and squirrel monkeys showed differences exist at 5 codons (56, 100, 108, 159, and 182) (7). It is not clear which difference or combination of changes might confer protection to cynomolgus macaques, or if resistance is caused by other factors. Of the 5 codon differences described above, those of cynomolgus macaques and humans are identical at positions 56, 159, and 182.

Two SM-CWD brain samples were inoculated into squirrel monkeys and cynomolgus macaques to verify that SM-CWD was infectious, test for further adaptation, and to see if SM-CWD was infectious to a broader range of nonhuman primates. Two squirrel monkeys inoculated intracerebrally with SM-CWD brain homogenates (SMP2CWD) were euthanized at 23-24 mpi (Table 1). These incubation periods decreased by >11 months compared with that of the donor squirrel monkey. Neurologic signs in the 2 SMP2-CWD were more pronounced than observed during the first passage; however, weight loss was reduced. Neuropathologic examination and Western blot for PrPres confirmed TSE in both squirrel monkeys. In contrast to SM-CWD infections, the SMP2-CWD-infected brains had spongiform lesions and PrPres deposition in the occipital lobe (Figure 2, panels A, B). Biochemical comparison of glycoform patterns among CWD, SM-CWD, and SMP2-CWD were made by using 3 different anti-PrP antibodies (L42, 6H4, and 3F4) (Technical Appendix).

In all cases, SM2-CWD had a greater proportion of unglycosylated PrPres and a lower proportion of double glycosylated PrPres than did SM-CWD (Figure 2, panel C). The decreased time of manifestation of disease, differences in glycoform patterns, and distribution of PrPres in brain tissue suggested that the CWD agent was still adapting within the squirrel monkey. However, similar to CWD, SM-CWD had not caused prion disease in cynomolgus macaques by 72 mpi (Table 2).

[FIGURE 2 OMITTED]

Conclusion

Our studies have shown that squirrel monkeys, but not cynomolgus macaques, were susceptible to CWD. Although these nonhuman primates are not exact models of human susceptibility, they support the data from transgenic mouse studies (3-6), in vitro experiments (13), and epidemiologic evidence (14,15) that suggest humans are at a low risk of contracting CWD. Nevertheless, it remains sensible to minimize exposure to tissues potentially contaminated with the CWD agent.

http://dx.doi.org/10.3201/eid1210.060019

Acknowledgments

We thank Byron Caughey, Kim Hasenkrug, and James Carroll for critical review of the manuscript; Nancy Kurtz, Lori Lubke, and Dan Long for assistance with histology preparation; Don Gardner and Dana Scott for necropsy assistance and lesion interpretation; Ed Schreckendgust, Rocky Rivera, Michael Wagner, Leslie Trail, and Richard Cole for animal husbandry; Michael Parnell, Douglas Brining, and RMVB staff for assistance with nonhuman primate inoculations and health care; and Mike Miller, Terry Kreeger, Jean Jewell, and Lynn Creekmore for CWD-agent positive and negative cervid tissues.

This research was supported by the Intramural Research Program of the NIH, NIAID.

Dr Race is a staff scientist in the Laboratory of Persistent Viral Diseases, National Institute of Allergy and Infectious Diseases. His research interests are infectious diseases of humans and animals.

References

(1.) Saunders SE, Bartelt-Hunt SL, Bartz JC. Occurrence, transmission, and zoonotic potential of chronic wasting disease. Emerg Infect Dis. 2012;18:369-76. http://dx.doi.org/10.3201/eid1803.110685

(2.) Gilch S, Chitoor N, Taguchi Y, Stuart M, Jewell JE, Schatzl HM. Chronic wasting disease. Top Curr Chem. 2011;305:51-77. http://dx.doi.org/10.1007/128_2011_159

(3.) Kong Q, Huang S, Zou W, Vanegas D, Wang M, Wu D, et al. Chronic wasting disease of elk: transmissibility to humans examined by transgenic mouse models. J Neurosci. 2005;25:7944-9. http://dx.doi.org/10.1523/JNEUROSCI.2467-05.2005

(4.) Tamguney G, Giles K, Bouzamondo-Bernstein E, Bosque PJ, Miller MW, Safar J, et al. Transmission of elk and deer prions to transgenic mice. J Virol. 2006;80:9104-14. http://dx.doi.org/10.1128/JVI.00098-06

(5.) Sandberg MK, Al-Doujaily H, Sigurdson CJ, Glatzel M, O'Malley C, Powell C, et al. Chronic wasting disease prions are not transmissible to transgenic mice overexpressing human prion protein. J Gen Virol. 2010;91:2651-7. http://dx.doi.org/10.1099/vir.0.024380-0

(6.) Wilson R, Plinston C, Hunter N, Casalone C, Corona C, Tagliavini F, et al. Chronic wasting disease and atypical forms of bovine spongiform encephalopathy and scrapie are not transmissible to mice expressing wild-type levels of human prion protein. J Gen Virol. 2012;93:1624-9. http://dx.doi.org/10.1099/vir.0.042507-0

(7.) Race B, Meade-White KD, Miller MW, Barbian KD, Rubenstein R, LaFauci G, et al. Susceptibilities of nonhuman primates to chronic wasting disease. Emerg Infect Dis. 2009;15:1366-76. http://dx.doi. org/10.3201/eid1509.090253

(8.) Lloyd S, Mead S, Collinge J. Genetics of prion disease. Top Curr Chem. 2011;305:1-22. http://dx.doi.org/10.1007/128_2011_157

(9.) Herzog C, Riviere J, Lescoutra-Etchegaray N, Charbonnier A, Leblanc V, Sales N, et al. PrPTSE distribution in a primate model of variant, sporadic, and iatrogenic Creutzfeldt-Jakob disease. J Virol. 2005;79:14339-45. http://dx.doi.org/10.1128/JVI.79.22. 14339-14345.2005

(10.) Lasmezas CI, Deslys JP, Demaimay R, Adjou KT, Lamoury F, Dormont D, et al. BSE transmission to macaques. Nature. 1996;381: 743-4. http://dx.doi.org/10.1038/381743a0

(11.) Ono F, Terao K, Tase N, Hiyaoka A, Ohyama A, Tezuka Y, et al. Experimental transmission of bovine spongiform encephalopathy (BSE) to cynomolgus macaques, a non-human primate. Jpn J Infect Dis. 2011;64:50-4.

(12.) Brown P, Gibbs CJ Jr, Rodgers-Johnson P, Asher DM, Sulima MP, Bacote A, et al. Human spongiform encephalopathy: the National Institutes of Health series of 300 cases of experimentally transmitted disease. Ann Neurol. 1994;35:513-29. http://dx.doi.org/10.1002/ ana.410350504

(13.) Raymond GJ, BossersA, Raymond LD, O'Rourke KI, McHolland LE, Bryant PK III, et al. Evidence of a molecular barrier limiting susceptibility of humans, cattle and sheep to chronic wasting disease. EMBO J. 2000;19:4425-30. http://dx.doi.org/10.1093/ emboj/19.17.4425

(14.) Belay ED, Maddox RA, Williams ES, Miller MW, Gambetti P, Schonberger LB. Chronic wasting disease and potential transmission to humans. Emerg Infect Dis. 2004;10:977-84. http://dx.doi. org/10.3201/eid1006.031082

(15.) MaWhinney S, Pape WJ, Forster JE, Anderson CA, Bosque P, Miller MW. Human prion disease and relative risk associated with chronic wasting disease. Emerg Infect Dis. 2006;12:1527-35.

Address for correspondence: Brent Race, Laboratory of Persistent Viral Diseases, Rocky Mountain Laboratories, National Institute of Allergy and Infectious Diseases, 903 South 4th St, Hamilton, MT 59840, USA; email: raceb@niaid.nih.gov

Brent Race, Kimberly D. Meade-White, Katie Phillips, James Striebel, Richard Race, and Bruce Chesebro

Author affiliation: National Institute of Allergy and Infectious Diseases, National Institutes of Health, Hamilton, Montana, USA

DOI: http://dx.doi.org/10.3201/eid2005.130778
Table 1. Squirrel monkeys inoculated with CWD or
squirrel monkey-adapted CWD agents *

Disease       Inoculum      Route of         Titer
incidence     ([double     inoculation    inoculated
([dagger])    dagger])                    ([section])

13/13         MD-1,2,3    Intracerebral      1.3 x
             Elk-1,2,3                    [10.sup.5]-
              WTD-1,2                        1.0 x
                                          [10.sup.7]

11/12 (#)      MD-1,3         Oral           9.6 x
             Elk-1,2,3                    [10.sup.7]-
              WTD-1,2                        1.5 x
                                          [10.sup.9]

2/2            SM-CWD     Intracerebral       NA

0/1          Normal elk   Intracerebral       NA

0/1            Buffer         Oral            NA
              control

0/1          Normal elk       Oral            NA

Disease       Incubation      Weight
incidence        days,        change
([dagger])   range, (avg)     range,
             ([paragraph])   % (avg,%)

13/13         33-75 (46)       -8 to
                                -43
                              (-29.5)

11/12 (#)     59-107 (68)      -8 to
                                -41
                               (-28)

2/2          23-24 (23.5)      -8 to
                                -21
                              (-14.5)

0/1              82 NS           0

0/1              >108           -6

0/1             123 NS          +7

* An early version of some of these data is shown in
Tables 1, 2 of (7). Since that time more infected animals
have been euthanized and the data have been updated.
CWD, chronic wasting disease; MD, mule deer;
WTD, white-tailed deer; NA, not applicable; NS, no clinical
transmissible spongiform encephalopathy signs.

([dagger]) Number of monkeys in which prion disease
developed/number inoculated.

([double dagger]) Several different inocula were used for
this study. Each individual animal was inoculated with 1
inoculum. Detailed descriptions can be found in (7).

([section]) Infectivity titers were determined by using
endpoint dilution titer in transgenic deer PrP mice and are
listed as 50% infectious dose/gram of brain.

([paragraph]) The range of incubation periods observed is
shown as months postinoculation followed with the average
incubation period of the group in parentheses. Monkeys listed
as NS did not show any clinical signs compatible with
transmissible spongiform encephalopathy.

(#) Three monkeys from this group are not included in this
calculation because they were euthanized before 45 months
postinoculation for reasons unrelated to transmissible
spongiform encephalopathy disease. The sole remaining animal
in this group appeared normal at 108 months postinoculation.

Table 2. Cynomolgus macaques inoculated with CWD
or squirrel monkey-adapted CWD agents *

Disease          Inoculum          Route of
incidence   ([double dagger])     inoculation
([dagger])

0/6         MD-1, Elk-1, WTD-1   Intracerebral

0/8 (#)     MD-1, Elk-1, WTD-1       Oral

0/2               SM-CWD         Intracerebral
0/1             Normal elk       Intracerebral

Disease             Titer                Screening       Current
incidence   inoculated ([section])   mpi ([paragraph])     mpi
([dagger])

0/6          3.2 x [10.sup.5]-2.5     49, 79, 88, 94       124
                 x [10.sup.6]
0/8 (#)       2.5 x [10.sup.8]-2        97,106,106         124
                 x [10.sup.9]
0/2                   NA                    NA             72
0/1                   NA                    96             NA

* An early version of some of these data are shown in
Table 3 of (7). CWD, chronic wasting disease; mpi,
months post-inoculation; MD, mule deer; WTD, white-tailed deer;
SM, squirrel monkey; NA, not applicable.

([dagger]) Number of monkeys in which prion disease developed
over number inoculated.

([double dagger]) Several different inocula were used for this
study. Each individual animal was inoculated with 1 inoculum.
Detailed descriptions can be found in (7).

([section]) Infectivity titers were determined by using endpoint
dilution titer in transgenic mice expressing deer prion protein
(PrPres) and are listed as 50% infectious dose per gram of brain.

([paragraph]) Several monkeys were euthanized during the course
of the experiment for conditions unrelated to prion infection such
as diabetes, neoplasia, hypocalcemia, and behavioral issues. Brain,
spleen, and lymph nodes from these animals were screened for PrPres
by using Western blot and immunohistochemical methods. No
PrPres-positive tissues were detected.

(#) One monkey from the original oral inoculation group was
euthanized at 1 mpi because of a colonic torsion and has been
removed from this group.
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Title Annotation:DISPATCHES
Author:Race, Brent; Meade-White, Kimberly D.; Phillips, Katie; Striebel, James; Race, Richard; Chesebro, Br
Publication:Emerging Infectious Diseases
Article Type:Report
Date:May 1, 2014
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