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Scrapie

Scrapie is a fatal, (TSE) that primarily affects sheep and , caused by the accumulation of abnormally folded proteins (PrP^Sc) in the , leading to spongiform degeneration, neuronal loss, and . The disease features a long typically ranging from two to five years, during which infected animals remain clinically normal before exhibiting progressive neurological symptoms such as intense pruritus prompting self-mutilation through rubbing against objects (hence the name "scrapie"), , tremors, , and eventual recumbency and death within weeks to months of onset. Transmission occurs primarily through oral ingestion of infected , uterine fluids, or environmental contamination with infected tissues, with from ewe to lamb also common; genetic factors at the PRNP locus strongly influence susceptibility, with certain alleles conferring resistance. First documented in in the early , scrapie exists in classical and atypical forms, with the latter sporadically occurring without evident horizontal spread; unlike , scrapie poses no confirmed zoonotic risk to humans despite historical concerns. Modern eradication programs, including selective breeding for resistant genotypes and , have significantly reduced incidence in many countries, though challenges persist due to the disease's insidious nature and persistence in the environment. The identification of s as the causative agent in the revolutionized understanding of protein-only infectious agents, challenging conventional views on disease causation by demonstrating transmissibility without nucleic acids.

History

Early Observations and Recognition

Scrapie was first described in around 1730, based on accounts of sheep displaying compulsive rubbing against posts, trees, and other objects to alleviate intense pruritus, which often led to loss, abrasions, and secondary infections; this characteristic behavior gave rise to the disease's name, derived from the English term for scraping. Early observers in and other parts of , including (where it was termed tremblante or "trembling") and (Traberkrankheit), documented symptoms such as progressive , tremors, , and eventual recumbency, with affected animals typically dying within months of onset. These empirical descriptions from shepherds and rudimentary veterinary records emphasized the disease's nature and its occurrence in mature sheep, often 2–5 years old, without recognition of a specific . In the 18th and 19th centuries, scrapie outbreaks were noted in specific regions of , such as the Borders area, and extended across , coinciding with expanded and for wool production. Familial patterns were commonly observed, with the disease recurring in lineages of affected flocks, leading contemporaries to hypothesize hereditary transmission or inherent flock weaknesses, exacerbated by practices that prioritized fine-wool breeds. Regional epidemics, sometimes devastating entire flocks, prompted early regulatory measures like and , though without isolating a transmissible agent; some accounts suggested via or shared pastures, but these were anecdotal and unverified experimentally. By the early 20th century, veterinary reports in and linked scrapie persistence to particular breeds, such as and sheep, which showed higher incidence rates, and to contaminated lands where the disease recurred even after flock replacement. These observations underscored environmental persistence, with cases reported on pastures grazed by affected sheep years prior, but the underlying cause—whether microbial, toxic, or genetic—remained elusive, fueling debates between infectious and hereditary theories without resolution.

Scientific Investigations and Prion Discovery

Experimental transmission of scrapie was first demonstrated in the 1930s through intracerebral inoculation of brain tissue from affected sheep into healthy ones, establishing its infectious nature despite earlier views favoring a purely genetic etiology. This shift was reinforced inadvertently in 1935 when a louping-ill vaccine, prepared using formalin-fixed brains from scrapie-infected sheep, transmitted the disease to approximately 7% of 18,000 vaccinated sheep in Scotland. Further investigations in the 1940s confirmed transmissibility via injection, with incubation periods often exceeding a year, distinguishing scrapie from conventional infections. By the 1960s, studies revealed the scrapie agent as filterable through membranes retaining most viruses and resistant to ultraviolet radiation and chemical treatments that inactivate nucleic acids, challenging viral hypotheses and suggesting a non-nucleic acid infectious particle. In 1982, Stanley Prusiner's group reported the purification of a protease-resistant protein, , from scrapie-infected brains, co-purifying with infectivity and lacking detectable nucleic acids, leading to the hypothesis that a misfolded protein alone propagates the disease. This was bolstered in 1993 by experiments showing mice resisted scrapie infection, remaining asymptomatic for over 13 months post-inoculation while wild-type controls succumbed within 6 months, indicating PrPC necessity for replication and pathogenesis.

Etiology

Prion Protein Mechanism

Scrapie arises from the conformational conversion of the normal cellular prion protein (PrPC), a glycosylphosphatidylinositol-anchored glycoprotein expressed primarily on neuronal cell membranes, into its pathogenic scrapie isoform (PrPSc). PrPC adopts an alpha-helical structure, whereas PrPSc features a high beta-sheet content, rendering it insoluble and prone to aggregation into amyloid fibrils that deposit in the central nervous system, contributing to spongiform encephalopathy. This misfolding propagates via a template-directed mechanism, wherein PrPSc acts as a seed to catalyze the refolding of additional PrPC molecules, amplifying the infectious conformer without requiring nucleic acids. Biochemical distinctions between PrPC and PrPSc provide empirical validation of this model. PrPSc exhibits partial resistance to digestion, yielding a characteristic 27-30 kDa core fragment after enzymatic treatment, while PrPC is fully degraded under similar conditions. Differences in patterns further differentiate the isoforms, with PrPSc displaying altered glycoform ratios that correlate with strain-specific . These properties enable detection and purification of PrPSc, confirming its role as the causal agent in scrapie through serial transmission experiments maintaining infectivity. Alternative etiologies involving viruses or have been refuted by the absence of detectable genetic material in purified prion preparations and the successful propagation of infectivity in acellular systems, such as protein misfolding cyclic assays that amplify PrPSc solely through iterative cycles of and with PrPC. Knockout of the PRNP encoding PrPC renders mice resistant to scrapie challenge, underscoring the necessity of the host protein for disease causation without invoking extraneous pathogens. This protein-only hypothesis aligns with first-principles of self-sustaining conformational replication, supported by decades of biochemical and genetic data.

Classical versus Atypical Forms

Classical scrapie, the historically recognized form, is characterized by horizontal transmissibility within flocks, with endemic occurrence linked to environmental contamination and oral uptake, particularly in . It features prominent vacuolation in the and other CNS regions, alongside accumulation of disease-associated protein (PrPSc) in lymphoid tissues. The typically spans 2–7 years, with clinical signs emerging between 2 and 5 years of age in affected sheep. In contrast, atypical scrapie, also known as Nor98, was first identified in in and presents as a sporadic condition with minimal evidence of contagious spread, often occurring as isolated cases in flocks rather than outbreaks. Pathologically, it shows intraneuronal vacuolation predominantly in the , , and , with reduced or absent brainstem spongiform changes compared to classical forms. Affected animals are usually older, and PrPSc deposition appears as fine punctate to granular patterns in both gray and . Biochemical differentiation relies on Western immunoblot analysis, where classical scrapie PrPSc exhibits a typical triplet pattern with higher molecular weight glycoforms, whereas PrPSc displays a distinct profile including a prominent low-molecular-weight band at 11–12 kDa and up to five bands overall. Histopathological and immunohistochemical evaluations further confirm these distinctions, with atypical cases showing lower intra-flock prevalence and no strong to highly susceptible PRNP alleles typical of classical scrapie.
FeatureClassical ScrapieAtypical (Nor98) Scrapie
EpidemiologyEndemic, horizontally transmissible, flock outbreaks commonSporadic, non-contagious, typically single cases per flock
Primary Lesion SitesBrainstem vacuolation prominent; spongiform encephalopathy widespread, hippocampus; minimal brainstem involvement
PrPSc ProfileTriplet bands on ; detectable in lymphoid tissuesFive bands including 11–12 fragment; limited lymphoid accumulation
Incubation/Onset2–7 years; signs at 2–5 yearsTypically older animals; less defined due to sporadic nature

Genetic Susceptibility

PRNP Gene Polymorphisms

Susceptibility to classical scrapie in sheep is primarily determined by polymorphisms in the PRNP gene at codons 136, 154, and 171, which encode amino acid variations in the prion protein (PrP^C) that affect its conversion to the disease-associated isoform (PrP^Sc). The most common alleles include ARQ (Ala^{136}Arg^{154}Gln^{171}), which confers moderate susceptibility; VRQ (Val^{136}Arg^{154}Gln^{171}), associated with high susceptibility and often linked to shorter incubation periods; and ARR (Ala^{136}Arg^{154}Arg^{171}), which provides strong resistance by impeding PrP^C misfolding and propagation. These variations influence the efficiency of PrP^Sc templating, with empirical data from genotype-phenotype correlations showing VRQ carriers developing clinical disease more readily upon exposure compared to ARR carriers. Homozygous ARR/ARR genotypes exhibit near-complete to classical scrapie, as validated in experimental oral and intracerebral studies where such sheep failed to develop detectable PrP^Sc or clinical signs even after prolonged , unlike susceptible ARQ/ARQ counterparts. Heterozygous combinations like ARR/VRQ confer partial , with reduced PrP^Sc accumulation and extended times observed in controlled infections. In goats, a parallel polymorphism—the K222 (lysine at codon 222)—similarly blocks PrP^C conversion, with experimental s in 2012 demonstrating that goats heterozygous or homozygous for K222 remained free of scrapie and PrP^Sc after oral with classical isolates, contrasting with wild-type controls that succumbed. Population-level allele frequencies in sheep breeds explain regional and breed-specific variations in scrapie incidence independent of exposure levels. For instance, often carry higher proportions of susceptible VRQ and ARQ , correlating with elevated case rates in affected flocks, whereas breeds in closed herds show scrapie restricted to genotypes encoding at codon 136 (e.g., VRQ or ARQ with V136), with ARR-enriched lines displaying inherent resistance in natural outbreaks. These genetic distributions, shaped by historical selection pressures, underscore how PRNP variability modulates host response without altering prion transmission fundamentals.

Implications for Breeding and Resistance

Selective breeding programs leverage polymorphisms in the PRNP gene, particularly favoring homozygous ARR/ARR genotypes in , to enhance to classical scrapie, as these alleles inhibit propagation and correlate strongly with reduced susceptibility. regulations, stemming from Decision 2003/100/EC, mandated national and breeding initiatives from the mid-2000s, requiring that used for or natural service in affected breeds possess at least one ARR allele, with full ARR/ARR preferred to minimize outbreak risks. These efforts have genotyped thousands of sheep annually—over 5,000 per year in some programs from 2006 to 2008—prioritizing resistant sires to shift flock genotypes toward lower susceptibility over generations. In targeted flocks adhering to these protocols, has achieved substantial reductions in scrapie incidence, with EU-wide surveillance data showing a statistically significant 10-year decline in cases per 10,000 tests through 2021, attributable in part to higher proportions of resistant genotypes exceeding critical thresholds that model scrapie die-out. For instance, programs estimating values for relative scrapie susceptibility enable prediction and selection that prevent outbreaks by maintaining resistant frequencies, though efficacy depends on consistent implementation across breeds. In , where scrapie remains endemic despite culling since 1978, the 2022 identification of ARR resistance alleles in approximately 130 native sheep has enabled targeted , potentially rendering up to 80% of flocks scrapie-free within five years by amplifying these protective genes through . However, intensive selection for introduces trade-offs, including risks of from reduced in closed nucleus flocks, as monitored in breeds like sheep where PRNP fixation narrows overall variability. Strategies to mitigate this, such as balancing selection with restrictions, preserve effective sizes while pursuing elimination, with empirical data indicating that benefits—near-zero incidence in resistant cohorts—outweigh diversity losses in high-prevalence regions.

Transmission

Natural and Oral Routes

Vertical transmission of classical scrapie occurs primarily through the and , with infected ewes shedding prions at high concentrations in placental tissues and fluids during the periparturient period, facilitating prenatal of . Experimental evidence confirms that and milk from scrapie-affected ewes transmit the to orally dosed , achieving high rates in genetically susceptible VRQ/VRQ sheep. This maternal route predominates in classical scrapie outbreaks, where epidemiological data indicate elevated risk to offspring of infected dams compared to atypical forms, which show negligible vertical spread. Horizontal transmission in natural settings involves oral uptake of prions excreted in , , and feces from infected sheep, contaminating pastures and enabling indirect spread within flocks. Prions detectable in these secretions support field observations of persistence through environmental exposure, with experimental models demonstrating infectivity via fecal contamination and oral . Low oral infective doses suffice for in susceptible hosts, as evidenced by successful experimental infections mirroring natural horizontal dynamics. In endemic flocks with susceptible PRNP genotypes, these routes sustain multi-generational cycles, with outbreak analyses revealing sustained incidence through combined maternal and lateral contacts until genetic selection intervenes. Conversely, breeds homozygous for resistant alleles (e.g., ARR/ARR) exhibit negligible natural transmission, halting endemic patterns observed in vulnerable populations. Field underscores that classical scrapie relies on these pathways for persistence, absent in controlled resistant herds.

Environmental and Iatrogenic Pathways

Scrapie prions demonstrate remarkable environmental stability, persisting in for extended periods and complicating efforts. Studies have shown that scrapie-infected material buried in garden remained infectious for at least three years, with prions binding to minerals and retaining viability despite reduced recovery rates over time. In field conditions, pastures contaminated with scrapie remained infective for a minimum of 16 years, as evidenced by to lambs grazing on sites where affected sheep had been housed decades prior. Experimental models further indicate persistence exceeding 29 months in , where contaminated substrates maintained high levels of upon to . This arises from prions' resistance to degradation, adsorption to clay particles, and protection within matrices, enabling low-dose environmental exposure to sustain in grazing flocks. Beyond soil, prions associate with farm vectors and surfaces, amplifying indirect spread. Hay mites collected from scrapie-endemic Icelandic farms transmitted the agent upon injection into mice, with preliminary assays detecting in mite preparations from affected premises. and airborne particles on contaminated farms have also harbored detectable prions, circulating within buildings and potentially facilitating or contact exposure. and bedding in contact with infected sheep act as reservoirs, as objects exposed to scrapie-affected environments retained transmissible prions capable of infecting naive . Low-level chronic shedding via , , , and placental tissues contributes to this persistence, with fecal-oral routes modeled as key drivers of flock-level epidemics under high-density conditions. Iatrogenic transmission has occurred through contaminated biologics and reproductive technologies. In the , a louping-ill derived from spinal cords, brains, and spleens of scrapie-exposed sheep induced the disease in over 1,500 recipients, marking one of the earliest documented iatrogenic outbreaks. poses theoretical risks, particularly from pre-natal infection, though empirical data indicate negligible transmission when embryos from resistant genotypes (e.g., homozygous ARR at PRNP) are used and standard protocols followed. These pathways underscore the challenges of decontamination, as no reliable methods fully eliminate environmental reservoirs, necessitating stringent to mitigate human-mediated dissemination.

Pathogenesis

Prion Propagation and Tissue Distribution

In scrapie, the disease-associated isoform of the protein, PrPSc, propagates through a templated conformational conversion of the host-encoded cellular protein, PrPC, leading to self-sustaining amplification in infected tissues. This process begins post-infection with early PrPSc accumulation in gut-associated lymphoid tissues (GALT), particularly Peyer's patches of the , detectable as early as 2-3 months in susceptible sheep following oral exposure. Replication occurs primarily within and macrophages in these sites, facilitating initial systemic dissemination via the lymphoreticular system. From GALT, PrPSc spreads centrifugally to secondary lymphoid organs, including , tonsils, and mesenteric lymph nodes, where it accumulates in lymphoid follicles before neuroinvasion. Neuroinvasion proceeds via efferent autonomic nerves innervating lymphoid tissues, transporting prions centripetally to the (CNS), with entry typically at the . Empirical autopsy data from natural and experimental cases map this progression: PrPSc appears in the region of the (dorsal motor nucleus of the vagus) as an early CNS marker, preceding widespread cerebral involvement. Strain-specific tropism influences distribution patterns. In classical scrapie, PrPSc exhibits broad lymphoreticular involvement and favors nuclei during early CNS phases, progressing to and . Conversely, (Nor98) scrapie shows minimal to absent accumulation in lymphoid tissues, with primary deposition in , , and , reflecting distinct propagation kinetics and reduced peripheral replication. Modeling and immunohistochemical studies confirm these tissue preferences as causal determinants of spread, independent of host genotype effects on susceptibility.

Incubation Period and Progression

The of classical scrapie in sheep generally spans 2 to 5 years from to the onset of clinical signs, though durations up to 7 years have been documented depending on strain, route of , and host factors. In experimental intracerebral inoculations, incubation times can be markedly shorter, averaging around 4 to 7 months in highly susceptible genotypes like VRQ/VRQ, reflecting accelerated propagation under high-dose conditions. Natural oral , more representative of field transmission, extend this period due to lower effective doses, with longitudinal in affected flocks confirming variability influenced by early-life , where lambs exposed near birth may not show signs until maturity. Atypical scrapie exhibits distinct temporal dynamics, often manifesting in older sheep and (typically over 5 years of age) during routine , suggesting either spontaneous onset or prolonged subclinical phases without clear transmissibility patterns akin to classical forms. Experimental transmissions of atypical prions have yielded shorter periods, sometimes mere months in susceptible models, contrasting with the extended timelines of classical disease and highlighting strain-specific propagation rates. Host PRNP profoundly modulates these intervals: susceptible alleles (e.g., VRQ or ARQ) correlate with reduced incubation times and higher attack rates, while resistant variants (e.g., ARR) can extend periods indefinitely or confer outright protection, as evidenced in breeding cohorts where homozygous resistant animals remain unaffected despite exposure. Once s accumulate to a critical threshold in neural tissues, particularly the , clinical progression ensues irreversibly, with behavioral and neurological deficits intensifying over weeks to months until , driven by unchecked conformational conversion of PrP^C^ to PrP^Sc^. Higher infectious doses consistently abbreviate by hastening this accumulation, underscoring dose-dependent causality in outbreak modeling, while no interventions halt propagation post-threshold due to the self-perpetuating of prion misfolding. In , similar patterns hold, with experimental data indicating modifiable via pre-treatments or strains, though field progression mirrors sheep in its fatal, unrelenting course.

Clinical Signs and Pathology

Behavioral and Neurological Symptoms

Classical scrapie primarily affects sheep aged 2 to 5 years, following an typically ranging from 2 to 7 years, during which infected animals remain . Initial behavioral changes include heightened nervousness, aggression toward flock members, and from the group, reflecting early dysfunction. A defining clinical feature is severe pruritus, manifesting as compulsive rubbing and scraping against objects, which leads to loss, skin excoriations, and secondary infections, especially over the dorsum, flanks, and head. This intense itching, absent in many other ovine conditions, correlates with degeneration empirically observed in affected regions. Neurological symptoms progress to include fine head and neck tremors, teeth grinding (), and gait disturbances such as forelimb hypermetria or hindlimb "bunny-hopping." In later stages, pronounced , , and recumbency predominate, culminating in death usually within 2 to 6 months of onset. These motor impairments link to vacuolar degeneration and in brainstem nuclei, including the dorsal vagal complex, as verified through histopathological analysis of clinical cases.

Gross and Microscopic Lesions

Gross examination of scrapie-affected sheep and goats typically reveals no specific focal lesions in the central nervous system, with the brain appearing grossly normal despite advanced disease. Common findings include emaciation due to chronic wasting, wool loss from pruritus-induced rubbing, and secondary infections, but these are nonspecific and attributable to the prolonged clinical course rather than direct prion pathology. Microscopically, classical scrapie is characterized by non-inflammatory spongiform , featuring intraneuronal and vacuolation, astrocytic , and variable neuronal loss, predominantly in the obex region including the dorsal vagal nucleus. These vacuoles form microcystic spaces in gray matter, confirming through with progression in autopsied cases. Pathological prion protein (PrPSc) is detected via as diffuse synaptic or perineuronal aggregates, supporting lesion attribution to accumulation. In atypical scrapie, microscopic lesions differ, showing milder spongiform changes with predominantly intraneuronal vacuoles in the cerebellar folia, hippocampus, and frontal cortex, rather than the brainstem emphasis of classical forms. PrPSc immunostaining reveals fine granular or particulate patterns in neuronal perikarya and cerebellar molecular layers, contrasting the coarser deposits in classical scrapie. Lesion profiles remain consistent across breeds and species affected, though severity is modulated by PRNP genotype, with susceptible alleles correlating to more pronounced vacuolation in experimental challenges.

Diagnosis

Ante-Mortem Testing Methods

Ante-mortem testing for scrapie primarily involves detection of the disease-associated isoform of the prion protein (PrPSc) in lymphoid tissues from live animals, using techniques such as immunohistochemistry (IHC), enzyme-linked immunosorbent assay (ELISA), and Western blotting for confirmation. Rectal mucosa-associated lymphoid tissue (RALMT) biopsy is the most commonly validated method in sheep, with IHC demonstrating sensitivities of 82% for a single sample and up to 99% when three or more samples are tested sequentially in clinically affected animals. In subclinical sheep, sensitivity drops to around 36-48% on initial biopsy, improving slightly with repeat sampling, while specificity approaches 100% due to the rarity of false positives in validated protocols. Alternative sites like third-eyelid lymphoid tissue yield comparable but variable sensitivities of 72-89%, depending on anatomical sampling precision. ELISA-based rapid tests on biopsy extracts offer faster processing for surveillance but require IHC or Western blot validation to confirm PrPSc accumulation, as they detect protease-resistant PrP aggregates with similar but slightly lower sensitivities in early preclinical stages. Blood-based assays, including PMCA (protein misfolding cyclic amplification) or sPMCA on or , have been explored for PrPSc detection but remain experimental, with detection limits insufficient for routine ante-mortem use due to inconsistent sensitivity below 50% in naturally infected sheep during . These methods target peripheral PrPSc dissemination but often fail in early infection phases when prions are confined to the or limited lymphoid sites. Genetic testing of the PRNP gene, focusing on polymorphisms at codons 136, 154, and 171, serves as an indirect rather than a direct diagnostic for . Sheep with ARR/ARR exhibit near-complete to classical scrapie, while VRQ alleles confer high ; heterozygous combinations like ARR/VRQ indicate . This informs programs but cannot distinguish infected from uninfected carriers within susceptible genotypes, as environmental exposure determines actual disease onset. All ante-mortem PrPSc detection methods suffer from false negatives, particularly during the prolonged (2-5 years), when lymphoid involvement is absent or minimal; validation studies report detection rates under 50% in preclinical surveillance flocks, necessitating confirmatory post-mortem testing for eradication programs. Negative results thus require cautious interpretation, often combined with epidemiological tracing rather than standalone reliance.

Post-Mortem Confirmation and Surveillance

Definitive post-mortem confirmation of scrapie requires necropsy examination of the brainstem at the level of the obex, where histopathological analysis reveals intraneuronal vacuolation consistent with spongiform encephalopathy, and immunodetection confirms the presence of disease-associated prion protein (PrPSc). The World Organisation for Animal Health (WOAH) Terrestrial Manual specifies that classical scrapie diagnosis relies primarily on immunohistochemistry (IHC) for PrPSc in fixed brainstem tissue, with enzyme-linked immunosorbent assay (ELISA) or Western blotting as confirmatory or screening methods when IHC is unavailable. Histopathology alone is supportive but not definitive without PrPSc detection, as vacuolar changes can occur in other conditions. Active surveillance programs systematically sample tissues from apparently healthy sheep and at abattoirs, from fallen , and during regulatory culls to monitor and detect subclinical cases. In the United States, the USDA and Service (APHIS) National Scrapie Surveillance Plan, part of the National Scrapie Eradication Program established in 2001, targets over 40,000 samples annually from slaughter (approximately 70% of total) and fallen to achieve detection thresholds below 0.1% . These efforts have identified atypical scrapie cases, which occur at low within-flock incidences often below 1% and are distinguished by distinct PrPSc molecular profiles via . Passive surveillance integrates farmer and veterinarian reports of clinically suspect animals, which undergo post-mortem testing to verify cases and initiate epidemiological tracing for flock exposure sources. WOAH standards recommend combining active and passive approaches to classify scrapie status, with confirmed positives triggering genotype and trace-back investigations to map transmission pathways. In regions with historically low prevalence, such as the where no widespread atypical outbreaks have occurred, surveillance detects sporadic cases, informing risk-based adjustments like intensified monitoring in affected holdings.

Control Measures

Breeding and Culling Programs

programs for scrapie resistance focus on the protein (PRNP), prioritizing sheep homozygous for the ARR allele, which confers strong resistance to classical scrapie strains by inhibiting propagation. In the , the National Scrapie Plan (NSP), initiated in 2001, promotes voluntary of breeding rams to identify and select those with low-risk genotypes (e.g., ARR/ARR or ARR/ARQ), restricting use of high-risk VRQ-carrying rams in affected flocks. By 2011, this effort increased the national ARR to 52.3% across sampled breeds, with modeling indicating a 1.15% annual rise in ARR prevalence from 2002 onward, correlating with reduced scrapie incidence in monitored flocks. Culling strategies target infected flocks and their progeny to eliminate sources of horizontal and vertical transmission, as prions persist in the environment and placenta. In Iceland, where scrapie has been endemic since the 1950s, mandatory culling of entire affected flocks—followed by premises disinfection and restocking from certified scrapie-free sources after 2–3 years—has been the primary control measure since 1978, reducing outbreak frequency through iterative depopulation of positives identified via active surveillance. Between 1978 and 2004, this approach eradicated scrapie from multiple farms, with empirical data showing flock-level clearance rates exceeding 90% when combined with movement restrictions, though subclinical infections in lymphoid tissues occasionally delayed full elimination. Comparative efficacy data from models demonstrate that genetic selection outperforms in sustaining long-term reductions, as for ARR resistance breaks cycles without recurrent depopulation of unaffected animals. Selective paired with (e.g., removing VRQ carriers from high-risk flocks) achieves faster outbreak termination than total flock slaughter, with NSP simulations projecting scrapie elimination in susceptible breeds within 10–15 years versus indefinite cycling under alone. Cost analyses confirm 's superiority, estimating flock-level savings of up to 40% over 20 years by averting future infections, as initial costs (£10–20 per ram) yield persistent unlike the high recurring expenses of culls (e.g., £5,000–10,000 per flock). In , recent integration of native ARR carriers into post-2022 has augmented 's impact, potentially accelerating eradication to 2044.

Regulatory Frameworks and Eradication Efforts

In the , Regulation (EC) No 260/2003, adopted on 12 February 2003, revised scrapie eradication protocols by mandating of sheep based on the protein gene (PRNP) to identify susceptible animals (e.g., those with VRQ, ARQ, or ARR/VRQ alleles), restricting movements of high-risk genotypes to slaughter or destruction, and imposing holding quarantines until clearance. Complementing this, Regulation (EC) No 1874/2003, effective 24 October 2003, applied movement restrictions to holdings receiving ovine or caprine animals, , embryos, or ova from scrapie-affected sources, requiring official veterinary oversight and compensatory to break chains. These measures, building on scrapie's notifiable status since 1 January 1993, have reduced classical scrapie incidence through , though implementation varies by member state with ongoing post-2003 amendments for thresholds. In the United States, the National Scrapie Eradication Program (NSEP), launched in 2001 as a federal-state-industry initiative, emphasizes , , and certification to achieve scrapie-free status. By 2019, the program classified most states as low-risk under Stage II protocols, with no confirmed classical cases from May 2016 to August 2018 and only isolated detections thereafter, enabling accelerated phase-down of intensive monitoring. Revised Scrapie Program Standards, effective 25 April 2019, updated risk designations for exposed animals and flocks, prioritizing via official ear tags and to facilitate rapid traceback and containment. Eradication faces hurdles from atypical scrapie variants (e.g., Nor98-like), which evade classical controls and necessitate adjusted , as their sporadic occurrence resists standard efficacy. gaps, including incomplete records from unregistered movements, have delayed responses, while undetected illegal imports of susceptible breeds undermine progress in border-vulnerable regions. Regulatory compliance has mitigated trade disruptions; for example, lifted its scrapie-related ban on lamb imports in March 2017 after verified control measures restored , valued at approximately £15 million annually. Similar lifts in other markets followed demonstrable low-prevalence status, though residual barriers persist in nations requiring scrapie risk evaluations for live exports, influencing global sheep genetics and meat trade volumes.

Public Health and Economic Impact

Zoonotic Risk Evaluation

Despite extensive historical exposure through consumption of scrapie-affected sheep and , no epidemiological evidence links classical or atypical scrapie to human diseases. Scrapie has been documented in since the , with widespread occurrence in small populations consumed by humans, yet of human transmissible spongiform encephalopathies (TSEs) worldwide has identified no cases attributable to scrapie prions under natural conditions. Laboratory transmission studies underscore a robust species barrier. Intracerebral inoculation of classical scrapie prions into cynomolgus macaques resulted in after prolonged periods of approximately 10 years, four times longer than for (BSE), with efficiency remaining low even after serial passage. In humanized transgenic mice expressing human prion protein (PrP), certain classical scrapie isolates demonstrated limited propagation, but adaptation was inefficient and not consistently observed across strains, contrasting with the higher transmissibility of BSE to s. Strain-specific variations further modulate potential. Classical scrapie exhibits marginally higher zoonotic potential in rodent models compared to atypical (Nor98) scrapie, where humanized mice showed very low susceptibility to a panel of atypical isolates, with only rare adaptation in one case suggesting negligible risk. A 2024 assessment confirmed atypical scrapie's limited ability to infect human PrP-expressing models, attributing this to phenotypic differences in prion strains that hinder cross-species conversion. At the molecular level, incompatibility arises from sequence divergences in PrP^C between sheep/goats and humans, particularly at residues influencing conformational conversion. Key polymorphisms, such as those at ovine positions 136, 154, and 171 (defining scrapie susceptibility genotypes), differ from human PrP^C equivalents, impeding efficient seeding of human PrP^C misfolding by ovine prions, as evidenced by structural and barrier studies. This barrier, combined with field absence of cases, indicates scrapie poses minimal zoonotic threat despite theoretical lab-based potentials.

Agricultural and Trade Consequences

Scrapie inflicts substantial agricultural losses on sheep and industries via fatal infections, mandatory culls of exposed s, diminished breeding stock viability, and elevated disposal expenses. In the United States, producers incur annual economic damages estimated at $20–25 million, stemming from reduced productivity, disposal fees, and foregone breeding opportunities. These impacts arise causally from the disease's progressive neurodegeneration, which curtails and yields in affected herds while necessitating the slaughter of genetically susceptible animals to curb . Smaller operations face disproportionate strain, as protocols can decimate limited s, exacerbating vulnerability in regions with high scrapie prior to intensified . Trade consequences amplify these losses through international restrictions enforced by the (WOAH), which classifies exporting countries by scrapie risk levels—negligible, controlled, or infected—dictating barriers on live animal, semen, embryo, and meat shipments. Scrapie-endemic nations encounter export prohibitions from scrapie-free markets such as and , resulting in millions of dollars in forfeited revenue for U.S. exporters alone. Attainment of certified low-risk status, via rigorous and , enables partial lifting of these bans, as evidenced by progressive WOAH recognitions that restore access to global markets and bolster industry resilience against ongoing endemic threats. In the , pre-reform compulsory flock culls under schemes like the Compulsory Scrapie Flock Scheme historically devastated herds, with low compensation relative to market values (e.g., cull payments trailing £85-per-ewe sales in 2007), compounding economic fallout from isolation.