Institute for Animal Health, Neuropathogenesis Unit, West Mains Road, Edinburgh EH9 3JF, UK1
Institute for Animal Health, Compton, Newbury, Berkshire RG20 7NN, UK2
Author for correspondence: Nora Hunter. Fax +44 131 668 3872. e-mail nora.hunter{at}bbsrc.ac.uk
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Abstract |
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Introduction |
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The TSE disease-associated form of the prion protein (PrPSc) of the neuronal glycoprotein PrPC is often used as a marker for infectivity. Using a sensitive Western blotting technique, no PrPSc was detected in the buffy coat from one vCJD patient (Wadsworth et al., 2001 ). Although a novel method for detection of PrPSc in scrapie sheep blood has been described (Schmerr et al., 1997
), the study was limited by a low number of samples and the technique requires further validation. Other investigators using the more conventional method of immunocytochemistry failed to demonstrate PrPSc in peripheral blood leucocytes of scrapie-infected sheep (Herrmann et al., 2002
).
An alternative to PrPSc detection is direct bioassay of infectivity by inoculation of material into hosts of the same or different species. In laboratory rodents experimentally infected with TSE, a number of investigators have demonstrated infectivity in blood and blood components during the pre-clinical and clinical phases of infection (Brown et al., 1998 ; Diringer, 1984
; Manuelidis et al., 1978
). However, infectivity has not been isolated, so far, from blood components of natural animal hosts of TSEs (Hadlow et al., 1982
; Marsh et al., 1973
). Isolated reports of transmission of CJD to laboratory rodents by whole blood or buffy coat from human patients have been questioned for a variety of reasons (Brown, 1995
). A large-scale study conducted by the National Institutes of Health failed to demonstrate infectivity in blood from 13 patients with CJD, using either highly susceptible primates or rodents as bioassay hosts (Brown et al., 1994
). With vCJD, no infectivity was detected in blood from two patients using mouse bioassays (Bruce et al., 2001
). Many of these studies could have failed to reveal low levels of infectivity in blood because of the use of rodents as bioassay hosts, thus limiting the sensitivity by crossing a species barrier. Also, in most cases, the intracerebral (i.c.) route of inoculation was used, because it is the most efficient, but this severely limits the volume of blood that can be assayed. Thus, where transmission from blood has been successful, infectivity was usually concentrated in some way, for example, by the use of buffy coat fractions. Transmission by the intravenous (i.v.) route has been shown to be up to seven times less efficient than following i.c. infection (Brown et al., 1999
), but there have been very few attempts to transmit TSEs by whole blood transfusion. Units of whole blood from three CJD cases were transfused into chimpanzees with negative results (Brown et al., 1994
) and pooled blood from three terminally ill TSE-infected mice produced disease in 1 of 20 transfusion recipients (Brown et al., 1999
).
Sheep infected orally with BSE show widespread deposition of PrPSc in the lymphoreticular system (LRS) (Foster et al., 1996a , 2001b
), similar to that seen in human vCJD patients. In contrast, in cases of sporadic human CJD and cattle BSE, peripheral pathogenesis does not appear to involve the LRS (Hill et al., 1999
; Wells et al., 1998
). Sheep were chosen as a model in which to study transmission of TSEs by blood transfusion because of the similarity of the pathogenesis with vCJD and because large volumes of blood can be transferred in the absence of a species barrier.
We have transfused whole blood and buffy coat from BSE-infected sheep and natural scrapie-infected sheep into susceptible but scrapie-free recipient animals. In the first report on these experiments (Houston et al., 2000 ), we described a single case of BSE infection via blood transfusion. The significance of this finding in a single animal has been questioned. However, the present report gives details of further successful transmissions from BSE and natural scrapie cases, the latter being the first conclusive demonstration of infectivity in blood of naturally infected individuals. Although still incomplete, our study indicates a frequency of transmission of TSEs in at least 10% of the transfusion recipients. We have decided to provide an update of our results because of the potential importance of the study for human health. In addition, in the two BSE transfusion cases examined so far, deposition of PrPSc in peripheral tissues appears rather limited when compared with sheep infected by the oral route. The potential implications of this observation for pre-clinical diagnosis and screening are discussed.
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Methods |
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Sheep have one of the most complex blood grouping systems known (Tizard, 1992 ) and therefore exact cross-matching of donors and recipients was not possible. Single transfusions only were made between animals that were checked for compatibility using a simple agglutination test (mixing recipient serum and donor erythrocytes and vice versa).
Genotypes of all sheep were confirmed by sequencing the region coding of the PrP gene (Foster et al., 2001a ) and are presented in three-codon format with each codon (136, 154 and 171) in turn for each allele in turn. The single letter amino acid code is used as follows: A, alanine; H, histidine; R, arginine; Q, glutamine; V, valine; X, any of the known polymorphisms at that position.
BSE blood transfusions.
The experimental BSE incubation period is controlled in sheep by the PrP gene codons 136 and 171, with no major effect of codon 154. BSE has the shortest incubation period in AXQ/AXQ sheep and extremely long incubation periods in heterozygote animals expressing AXQ with the ARR or VRQ alleles (Foster et al., 2001a and unpublished observations). Of the 18 donor sheep (all genotype AXQ/AXQ), 17 were taken from the NPU Cheviot flock negative line (not affected by natural scrapie) and were infected with 5 g cattle BSE brain homogenate by the oral route as part of a separate series of experiments. Five of the donor animals developed BSE at 559761 days (mean±SD=640±78 days) post-challenge, three are still alive at more than 1500 days post-challenge; however, the other donors (n=9) were culled during the pre-clinical phase as part of a serial cull pathogenesis experiment.
Due to a shortage of clinical BSE cases in the orally infected group, an ARQ/ARQ Cheviot sheep (DEFRA/SF) that was showing clinical signs following intracerebral inoculation of 0·05 g cattle BSE brain homogenate (incubation period 671 days) was used to provide blood for the final transfusion in the group.
The 24 recipients for the BSE blood transfusions were sheep of ARQ/ARQ genotype from the DEFRA scrapie-free flock of New Zealand origin (DEFRA/SF sheep). Six donors were used to provide both whole blood and buffy coat transfusions but these were transfused into separate recipient sheep.
Natural scrapie transfusions.
Natural scrapie occurs in the NPU Cheviot flock positive line in carriers of the VRQ allele (Hunter et al., 1996 ) and the 11 donors from this group were of VRQ encoding genotypes: ten VRQ/VRQ and 1 VRQ/ARQ. Transmission is believed to occur perinatally and clinical cases develop at 23 years of age. Four of the donors developed natural scrapie at 10801484 days of age, five are still alive at 7001081 days of age and two were culled for welfare reasons before signs of scrapie were expected (349 and 975 days of age). The 21 recipients for the natural scrapie blood transfusions were sheep of VRQ/VRQ genotype from the DEFRA/SF flock. Ten donors donated blood for both whole blood and buffy coat transfusions but single transfusions per recipient were carried out.
Negative control transfusions.
Negative controls for the BSE blood transfusions consisted of seven healthy donors of AXQ/AXQ genotype of ages ranging from 497 to 1676 days from the NPU Cheviot flock negative line. They provided blood and/or buffy coat for transfusion into 12 ARQ/ARQ genotype sheep from the DEFRA/SF flock. None of the donors has developed TSE to date, although two were culled at 580 days of age as part of a serial cull pathogenesis study. One sheep died of intercurrent disease (not scrapie) at 865 days of age and the other four donors are alive at the time of writing, at 10962170 days of age.
To act as negative controls for the natural scrapie blood transfusions, eight VRQ/VRQ genotype sheep of ages ranging from 211 to 629 days from the scrapie-free DEFRA/SF flock provided blood and/or buffy coat for transfusion into 16 VRQ/VRQ genotype animals also from the DEFRA/SF flock. None of the donor sheep has developed TSE to date and are alive and healthy at 699821 days of age.
Intravenous route/positive controls.
When this study was set up, it was unknown whether BSE or scrapie could be transmitted by the i.v. route. A negative result from the transfusions could have meant that the i.v. route was particularly ineffective. Positive control sheep were therefore infected by the i.v. route with BSE cattle brain homogenate, which is known to infect sheep successfully by both oral and i.c. routes. The ten challenged animals were of ARQ/AXQ genotypes and were infected by the i.v. route with the equivalent of 0·2 g BSE-affected cattle brain homogenate, obtained from DEFRA. Initially, four sheep were infected by i.v. inoculation of 2 ml 10% brain homogenate. However, following a severe adverse reaction in one animal, which was removed from the study, the remaining seven animals were inoculated by the i.v. route with 20 ml 1% brain homogenate and treated with a non-steroidal anti-inflammatory drug, ketoprofen (Ketofen, 10%), before inoculation to try to prevent shock.
Blood transfusion method.
Blood was collected from the jugular vein of sedated sheep into 500 ml sterile blood transfusion bags containing sodium citrate. From donors that were about to be necropsied, two units of whole blood (900 ml total) were collected. From donors that were to be left alive until clinical signs developed, separate collections of a single unit of blood were made at least 28 days apart. In either case, one unit was transfused as whole blood and the other was used to prepare the buffy coat. Buffy coat fractions were produced by spinning down whole blood and withdrawing the white cell component under aseptic conditions, according to standard protocols employed by the Scottish National Blood Transfusion Service. Whole blood packs were stored at 4 °C (buffy coats were stored at 20 °C) prior to use, usually on the following day (always within 3 days of collection). Blood was given to transfusion recipients via a single-use disposable blood administration set and an i.v. catheter placed in the jugular vein, at a rate of approximately 200300 ml/h.
PrPSc detection by immunocytochemistry and Western blot.
PrPSc immunocytochemistry was carried out as described previously (Foster et al., 2001b ). The primary antibody, BG4, was a monoclonal antibody (mAb) raised in mice against recombinant bovine PrP, binding to epitopes in the regions of aa 4757 and 8999 (courtesy of TSE Resource Centre, IAH, Compton, UK). The secondary antibody was biotinylated rabbit anti-mouse IgG, which was linked to streptavidin peroxidase with 3-amino-9-ethylcarbazole as the chromogen. Comparisons of PrPSc distribution were made with sheep infected with BSE (by oral or i.c. routes) and with animals naturally infected with scrapie in the NPU Cheviot flock, using methods published previously (Foster et al., 2001a
, b
).
For Western blotting to detect PrPSc, extraction procedures were used as described previously (Hope et al., 1986 ; Towbin et al., 1979
). PNGase-treated PrPSc was prepared using the method described by Collinge et al. (1996)
. For Fig. 1(A
, B
), mAb 6H4 (Prionics) was used to detect of PrPSc and was visualized with a chemiluminescence substrate (Roche). For Fig. 1(C)
, mAb 8H4 was used (Zanusso et al., 1998
).
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Results |
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Of the 21 animals transfused with blood taken from natural scrapie-infected animals, four animals have been culled with clinical signs of scrapie to date. Blood was collected from the donors (61x75, 61x68, 59x27 and 59x28) at time-points of 761, 764, 1138 and 1080 days of age. The donors developed clinical signs of scrapie at 1324, 1112, 1484 and 1080 days of age, respectively, making the blood donations at 57, 69, 77 and 100% (clinical phase) of donor survival time, respectively. Scrapie developed in recipients (F144, F153, F141 and F143) at 614, 624, 571 and 737 days post-transfusion, respectively. Of the 17 remaining recipients, one died of unrelated causes (not TSE) at 364 days post-transfusion and the others remain healthy, although 13 animals are at <600 days post-transfusion and could still potentially develop scrapie. Three of the scrapie-positive transfusions made with whole blood came from donors that also donated buffy coat samples for transfusion into different recipients, which all remain healthy at 701 days post-transfusion. However, one positive transmission occurred in a sheep (F143) transfused with buffy coat taken at the clinical end-point from the donor, showing that this blood fraction can transmit infection, at least at the clinical phase of disease. Unfortunately, insufficient blood was collected from this donor to perform a whole blood transfusion in another recipient for comparison of incubation periods. This part of the study gives a minimum transmission rate by blood transfusion of 4 of 21 or 19% for natural scrapie.
The negative controls for these experiments are currently at slightly earlier stages post-transfusion, the result of limited availability of DEFRA/SF sheep. The 12 negative controls for the BSE study are alive and healthy at 482903 days post-transfusion. There has been one intercurrent death (not TSE) among the negative controls for the scrapie study at 464 days post-transfusion. The other 15 recipients are alive and healthy in two groups at 38103 (n=6) and 516537 (n=9) days post-transfusion. It should be noted that both the BSE- and scrapie-negative controls are at a relatively early stage of the possible incubation time and we must wait until the study is complete before it can be confirmed that the controls are free of TSEs.
Positive controls were given a dose of 0·2 g BSE-affected cattle brain homogenate by the i.v. route to provide evidence that the i.v. route allows infection by TSE challenge in sheep, not established previously. Of ten animals (AXQ/AXQ genotype) challenged by the i.v. route, two animals were culled with clinical signs of BSE at 605 and 655 days post-challenge and three additional animals are showing early clinical signs at the time of writing, at 626702 days post-challenge.
PrPSc detection by Western blot
Glycoform analysis of PrPSc by Western blot is one means by which strains of TSEs may be identified (Collinge et al., 1996 ). PrPSc samples were prepared from the brains of affected sheep for analysis and comparison with animals known to be infected with BSE or scrapie. Fig. 1(A
, lanes 5 and 6) shows PrPSc extracted from the BSE transfusion cases D505 and F19, respectively. The glycoform pattern is dominated by the high molecular mass isoform of PrPSc, as expected for BSE. For comparison, proven transmissions of BSE to sheep in Fig. 1(A
, lanes 2 and 9) (i.c. challenge) and Fig. 1(A
, lanes 3 and 11) (oral challenge) show characteristic predominance of high molecular mass glycoforms. The donor for D505 survived until clinical signs of BSE developed. The Western blot also shows the BSE glycoform pattern in the donor (J2599) at clinical phase (Fig. 1A
, lane 8). The donor for F19 (J2746) was culled at the time of blood donation, 282 days post-challenge, in the absence of clinical signs of BSE. A brain sample taken from J2746 at the same time as the blood donation showed no sign of PrPSc (Fig. 1A
, lane 12). In contrast, natural scrapie PrPSc (Fig. 1A
, lanes 1, 4, 7 and 10) shows a clearly different glycoform pattern typical of UK natural scrapie (Hope et al., 1999
).
An additional characteristic of BSE is the band shift seen in the lowest, unglycosylated isoform of PrPSc, which is of lower apparent molecular mass than that seen in natural scrapie (Hope et al., 1999 ; A. Chong, unpublished observations). As this feature was not clear from the blots in Fig. 1(A)
, PNGase treatment was used to remove the carbohydrates from the PrPSc protein. As shown in Fig. 1(B)
, in all BSE cases, the resulting band sizes have a slightly lower apparent molecular mass than is seen in natural scrapie.
Fig. 1(C) shows the glycoform analysis of one of the scrapie blood transfusion cases (F141) (Fig. 1C
, lane 3) and the corresponding donor sheep (59x27) at clinical phase (Fig. 1C
, lane 2), compared with another natural scrapie case (Fig. 1C
, lane 1) and an experimental sheep BSE case (Fig. 1C
, lane 4). The transfusion case clearly shows a PrPSc pattern typical of scrapie rather than that of BSE. Murine transmissions are being set up to confirm the identity of the TSE agent in the transfusion cases but the genotypes of affected animals (ARQ/ARQ for BSE and VRQ/VRQ for scrapie) and the PrPSc Western blot patterns strongly support the conclusion of successful transmission of both BSE and scrapie by blood transfusion.
Immunocytochemistry
The distribution and intensity of PrPSc immunostaining in two of the BSE transfusion cases has been compared with our extensive data on sheep infected with BSE by other routes (oral and i.c.) and with natural scrapie. For simplicity, only two sheep from each group are described (Table 1). Selected areas of the brain were scrutinized for PrPSc immunostaining, including the dorsal motor nucleus of the vagus (DMNV) in the medulla oblongata and thalamic nuclei of the diencephalon, which we have shown previously to stain positively in natural scrapie (Foster et al., 1996b
) and in sheep orally dosed with BSE (Foster et al., 2001b
). Peripheral lymphoid tissues were also collected, although reporting here has been restricted to the tonsil, spleen, mesenteric lymph node and Peyers patches of the gut.
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Both orally dosed BSE cases (Table 1, sheep 5 and 6) demonstrated clearly observable immunostaining in all peripheral lymphoid areas tested, with sheep 6 having strong tonsillar staining (Fig. 5
). Both natural scrapie cases (Table 1
, sheep 7 and 8) had intense immunostaining in the mesenteric lymph node (Fig. 6
) and tonsil, as well as retropharyngeal, ileocaecal, prescapular and submandibular lymph nodes (data not shown).
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Discussion |
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Whole blood transfusion (400450 ml) cases are presenting incubation periods of around 600 days, which is very similar to those resulting from i.v. injection of 0·2 g BSE cattle brain homogenate. The transfusions might be expected to be more efficient because they are a sheep-to-sheep transmission with no species barrier, which contrasts with the i.v. brain infections, which is a cattle-to-sheep transmission. A full titration of the inoculum used in the cattle BSE brain i.v. controls is under way in mice but is incomplete at the time of writing. Accurate estimation of the levels of infectivity in blood will require i.v. titration in sheep; however, the results presented here suggest that they are significantly higher than suspected previously. Another important consideration is the distribution of infectivity among different blood components. Perhaps surprisingly, most positive transmissions so far have followed transfusion of whole blood rather than buffy coat, whereas previous studies have tended to find infectivity concentrated in the buffy coat fraction. As we now have a clinical case of scrapie resulting from transfusion of buffy coat, it is clear that, in our model, infectivity is also carried by the cells in this fraction. However, these preliminary results suggest that infectivity is not confined to the buffy coat fraction and that there may also be significant levels of infectivity in the plasma and/or red cell fractions.
The presence of infectivity in blood suggests that it should be possible to detect PrPSc or other surrogates of infectivity by alternative methods, with obvious benefits for development of ante-mortem diagnostic tests. Early reports of the use of capillary electrophoresis to detect PrPSc in the blood of scrapie-infected sheep showed some promise (Schmerr et al., 1997 ); however, a recent study could not detect PrPSc in peripheral blood leucocytes of scrapie-infected sheep using immunocytochemistry (Herrmann et al., 2002
). PrPC is known to be expressed only on peripheral blood mononuclear cells in sheep, in contrast to humans where it is also found on platelets and, at low levels, on erythrocytes (Barclay et al., 2002
; Herrmann et al., 2001
; Holada et al., 1998
). Since tissues that express PrPC do not always equate with areas that accumulate PrPSc and infectivity during disease, the distribution of infectivity in blood fractions of different species clearly merits more detailed analysis.
Immunocytochemical detection of PrPSc in peripheral tissues of two of the BSE transfusion cases has shown a greatly reduced involvement of lymphoid tissues, including tonsil, in the peripheral pathogenesis compared with NPU Cheviot sheep orally infected with BSE or natural scrapie (Foster et al., 2001a ). A recent report has shown that a proportion of Romney sheep in the late pre-clinical stages of infection with BSE following oral dosing (22 months post-infection) have PrPSc deposits in the CNS in the absence of any detectable involvement of peripheral lymphoid tissues (Jeffrey et al., 2001
). This study also noted the relatively late and variable onset of PrPSc accumulation in the lymphoid tissues of BSE-infected sheep. A more detailed study of BSE and scrapie transfusion cases, and positive controls, will be undertaken to determine whether lack of involvement of the LRS is a consistent feature in animals infected by the i.v. route; the results will be published at a later date. If our preliminary observations are confirmed, there may be implications for human patients with the misfortune to have received blood products from vCJD cases, because a negative tonsil biopsy as a means of reassurance might very well be unreliable. On the other hand, it also may mean that if a human patient became infected with vCJD by the i.v. route, then the peripheral tissues and blood of this secondary case may not themselves be highly infectious.
In conclusion, our results so far indicate that, with more than 10% of transfusions resulting in disease in the recipients, blood transfusion represents an appreciable risk for transmission of TSEs in sheep and, by extension, of vCJD in human beings. The relatively short and consistent incubation periods seen in positive cases suggests that levels of infectivity in the blood may be higher than suspected previously, even in the pre-clinical stages of infection, and/or that transmission by the i.v. route is highly efficient. From these preliminary results, it would appear that measures taken to safeguard the blood supply in the UK are fully justified. However, further work, in particular a thorough investigation of the distribution of infectivity in different blood fractions, is required before a reliable estimate of the risks associated with contaminated blood products can be made.
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Acknowledgments |
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References |
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Received 16 May 2002;
accepted 9 July 2002.