Rabies as a threat to wildlife.

The impact of infectious disease may become progressively more harmful to a species' survival as a wild population approaches an 'extinction vortex'. This risk is especially relevant for pathogens that spread rapidly and result in high mortality rates. Rabies, a virus that infects many mammalian species, can be efficiently transmitted through infected saliva, and is fatal without prior vaccination or rapid post-exposure prophylaxis (in humans). The authors conducted an extensive literature review to identify all wild mammal species reported to have been infected with rabies virus. They found reports of infection in 190 mammalian species, including 16 with elevated risk of extinction and two for which rabies is a direct conservation threat: the Ethiopian wolf (Canis simensis) and the African wild dog (Lycaon pictus). This paper discusses selected examples in which rabies has contributed to the population decline of a species of conservation concern. In addition, the authors note the importance of the transmission of rabies virus (RABV) from domestic dogs to wildlife, and the many challenges associated with the vaccination of wild animals. With this in mind, they present potential solutions to reduce the burden of rabies on wildlife. Once stable control of RABV is achieved in domestic dogs, remaining rabies threats to wildlife conservation can be addressed more effectively.

L'impact des maladies infectieuses peut constituer une menace croissante pour la survie d'espèces animales sauvages dès lors que leurs populations sont entraînées dans la « spirale de l'extinction ¼. Ce risque se pose plus particulièrement lorsqu'il s'agit d'agents pathogènes qui se propagent rapidement et induisent un taux de mortalité élevé. Le virus de la rage affecte un grand nombre d'espèces de mammifères et se transmet facilement par contact avec de la salive infectée ; l'infection virale entraîne la mort en l'absence d'une vaccination préalable ou, chez l'être humain, d'une prophylaxie post-exposition administrée rapidement. Les auteurs ont procédé à un examen exhaustif de la littérature afin d'inventorier les espèces de mammifères sauvages chez qui l'infection rabique a été rapportée. Des cas ont été notifiés chez 190 espèces de mammifères, dont 16 présentant un risque élevé d'extinction et deux directement menacées d'extinction en raison de la rage : le loup d'Abyssinie (Canis simensis) et le lycaon (Lycaon pictus). Les auteurs apportent des précisions sur un nombre choisi d'espèces vulnérables ou en danger dont le déclin des populations est en partie imputé à la rage. En outre, ils soulignent l'importance de la transmission du virus de la rage des chiens domestiques aux animaux sauvages et décrivent les nombreuses difficultés liées à la vaccination de la faune sauvage. Ces éléments établis, ils présentent quelques solutions envisageables pour réduire le fardeau de la rage dans la faune sauvage. Une fois le virus de la rage contrôlé de manière pérenne chez le chien domestique il sera possible de lutter plus efficacement contre les autres menaces que la rage fait peser sur la conservation de la faune.

Una enfermedad infecciosa puede tener efectos cada vez más dañinos en la supervivencia de una especie a medida que una población silvestre se va aproximando a un «vórtice de extinción¼. Este riesgo tiene especial importancia en el caso de patógenos que se propagan con rapidez y causan elevadas tasas de mortalidad. La rabia, enfermedad provocada por un virus que infecta a muchas especies de mamíferos y puede transmitirse eficazmente a través de saliva infectada, resulta letal en ausencia de vacunación previa o de rápidas medidas de profilaxis tras la exposición (en el ser humano). Los autores realizaron un amplio estudio bibliográfico para determinar todas aquellas especies de mamíferos silvestres en que se hubiera descrito una infección por el virus de la rabia. Encontraron infecciones descritas en 190 especies de mamíferos, de las que 16 presentan un elevado riesgo de extinción y dos cuya conservación se ve directamente amenazada por la rabia: el lobo etíope (Canis simensis) y el licaón, o perro salvaje africano (Lycaon pictus). Los autores exponen una serie de ejemplos en los que la rabia ha contribuido al declive demográfico de una especie cuya pervivencia está en mayor o menor peligro. Los autores señalan además la importancia que reviste la transmisión del virus de la rabia de los perros domésticos a la fauna silvestre y los numerosos problemas que presenta la vacunación de los animales silvestres. Teniendo presente esta dificultad, exponen posibles soluciones para reducir la carga de rabia en la fauna silvestre. Una vez se logre estabilizar el control del virus rábico en el perro doméstico, será posible combatir más eficazmente la amenaza que representa para la conservación de las especies silvestres.

Rabies outbreak in Greece during 2012-2014: use of Geographical Information System for analysis, risk assessment and control.

The objectives of this work were (i) geographical analysis of the 2012-2014 outbreak of rabies in Greece using GIS and (ii) comparative analysis of animal cases with data of potential human exposure to rabies together with environmental data, in order to provide information for risk assessment, effective monitoring and control. Most animal cases (40/48) involved red foxes, while domestic animals were also diagnosed with rabies. Overall, 80% of the cases were diagnosed in central northern Greece; 75% of the cases were diagnosed in low altitudes (<343·5 m), within a distance of 1 km from human settlements. Median distance from livestock farms was 201·25 m. Most people potentially exposed to rabies (889/1060) presented with dog bite injuries. Maximum entropy analysis revealed that distance from farms contributed the highest percentage in defining environmental niche profiles for rabid foxes. Oral vaccination programmes were implemented in 24 administrative units of the country during 2013 and 2014, covering a total surface area of ~60 000 km2. Rabies re-occurrence in Greece emphasizes the need for ongoing surveillance in cross-border areas and in areas with intense human activity.

The status of tularemia in Europe in a one-health context: a review.

The bacterium Francisella tularensis causes the vector-borne zoonotic disease tularemia, and may infect a wide range of hosts including invertebrates, mammals and birds. Transmission to humans occurs through contact with infected animals or contaminated environments, or through arthropod vectors. Tularemia has a broad geographical distribution, and there is evidence which suggests local emergence or re-emergence of this disease in Europe. This review was developed to provide an update on the geographical distribution of F. tularensis in humans, wildlife, domestic animals and vector species, to identify potential public health hazards, and to characterize the epidemiology of tularemia in Europe. Information was collated on cases in humans, domestic animals and wildlife, and on reports of detection of the bacterium in arthropod vectors, from 38 European countries for the period 1992-2012. Multiple international databases on human and animal health were consulted, as well as published reports in the literature. Tularemia is a disease of complex epidemiology that is challenging to understand and therefore to control. Many aspects of this disease remain poorly understood. Better understanding is needed of the epidemiological role of animal hosts, potential vectors, mechanisms of maintenance in the different ecosystems, and routes of transmission of the disease.

The relationship between socioeconomic indices and potentially zoonotic pathogens carried by wild Norway rats: a survey in Rhône, France (2010-2012).

Leptospira interrogans, hantaviruses (particularly Seoul virus), hepatitis E virus (HEV), and Toxoplasma gondii are rat-associated zoonoses that are responsible for human morbidity and mortality worldwide. This study aimed to describe the infection patterns of these four pathogens in wild rats (Rattus norvegicus) across socioeconomic levels in neighbourhoods in Lyon, France. The infection or exposure status was determined using polymerase chain reaction or serology for 178 wild rats captured in 23 locations; additionally, confirmatory culture or mouse inoculation was performed. Multivariate logistic regression analyses were used to investigate whether morphological and socioeconomic data could predict the infection status of the rats. This study revealed that the rat colony's age structure may influence the prevalence of L. interrogans, hantavirus, and HEV. In addition, areas with high human population densities and low incomes may be associated with a greater number of infected rats and an increased risk of disease transmission.

Sustainable control of zoonotic pathogens in wildlife: how to be fair to wild animals?

Wildlife may harbour infectious pathogens that are of zoonotic concern. However, culling such reservoir populations to mitigate or control the transmission of these pathogens to humans has proved disappointingly inefficient. Alternatives are still in an experimental stage of development. They include vaccination, medication, contraception and environmental manipulation, including fencing and biosecurity measures. This review examines the general concepts involved in the control of wildlife diseases and presents relevant case studies. Since wildlife disease control inevitably involves interfering with wildlife ecology, this is a complex goal whose attempts at realisation should be supervised by a scientific organisation. Most approaches within natural ecosystems should first be carefully tested in trials that are progressively extended to a larger scale. Finally, all measures that aim to prevent infection in humans (such as personal hygiene or vaccination) or that encourage us to avoid infectious contacts with wildlife should be recommended.

Outbreaks of highly pathogenic avian influenza in Europe: the risks associated with wild birds.

The infection of wild birds by highly pathogenic strains of avian influenza (Al) virus was virtually unknown--apart from one instance of the disease appearing in common terns in South Africa in 1961--before the Asian strain of highly pathogenic AI virus (AIV), H5N1, began to expand across the world. Outbreaks of clinical disease in Eurasia have resulted in visible mortality among populations of free-ranging wild birds in a multitude of species. The circulation pattern of influenza viruses in natural ecosystems results from a selection pressure towards strains which are indirectly transmitted by droppings from water birds and contaminated fomites, and which exhibit low pathogenicity. Some of these viruses, of the subtypes H5 or H7, can mutate into highly pathogenic strains after being introduced into domestic poultry farms. The maintenance of highly pathogenic AIV (HPAIV) H5N1 in several parts of the world exposes wild birds to infected poultry, resulting in long-distance virus transmission. There is great concern that these wild birds may, in turn, propagate these HPAIV or introduce them into domestic birds. Rigorous disease control and biosecurity measures to protect poultry farms are the only solution presently available to mitigate such a risk.

What is the future of wildlife rabies control in Europe?

Over the last fifteen years or so, classical rabies in terrestrial wildlife has been eliminated from large areas of Western Europe. Over the next few years, terrestrial rabies is likely to occur only east of a line from the Baltic Sea to the Black Sea; the overall aim is to eliminate terrestrial rabies from the whole European Union. Elimination of rabies from the less rich countries of Eastern Europe, and the protection of Europe against a resurgence of rabies in the longer term requires modifications to existing OIE and WHO strategies. Here we discuss the options available to eliminate rabies in wildlife while taking account of financial cost, and how to maintain a 'cordon sanitaire' along the eastern boundary of the EU in order to protect the rabies-free areas from rabies incursion. Minimising financial costs at the national level is obviously essential, considering the competing priorities for development and health. This could be achieved either by increasing external funding (for example by the EU) and/or by changing the currently agreed vaccination strategy to reduce costs; any such change must not substantially reduce the chances of rabies elimination. A cordon sanitaire might be placed outside the economic area of the EU, to protect the whole of the EU, or it might be placed within the easternmost countries to ensure logistical consistency of vaccination. Policy must also anticipate an emergency due to rabies breaking out in a previously freed region. Strategic planning may be complicated by the increasing range and abundance of the raccoon dog, an introduced species that is increasingly important as a host for fox rabies. It is argued here that models help to evaluate altemative strategies, exploring options for optimising costs by minimising bait density and frequency or by reducing the vaccination area.

Spatial and temporal patterning of bank vole demography and the epidemiology of the Puumala hantavirus in northeastern France.

Epidemiological data from bank voles, Myodes glareolus, naturally infected by the hantavirus Puumala (PUUV) were collected by a capture-mark-recapture protocol from 2000 to 2002 in the French department of Ardennes. Four monitored trapping sites were established in two forests located in two cantons (Flize and Monthermé). We captured 912 bank voles corresponding to 557 different individuals during 8820 trapping nights for an overall trapping success of 10.34%. The average PUUV seroprevalence was 22.4%. Characteristics of the system reported in North European countries are confirmed in France. PUUV seroprevalence and abundance of rodents appeared weakly linked. Adult voles were more frequently antibody-positive, but no difference between sexes was established. Anti-PUUV seropositive voles were captured and high seroprevalence was observed from both forests, without human infection reported in Flize canton during the study. One site among the four exhibited peculiar infection dynamics, where vole weight and infection risk were negatively correlated.

[Wildlife and emerging diseases]. / La faune sauvage et les maladies émergentes.

This article reviews the conditions that allow an infectious or parasitic pathogen to migrate from a wild reservoir to domestic animals and/or humans, and examines the possibility of a new disease emerging as a result. The review presents epidemiological mechanisms grouped into three principal models, illustrating them with examples: the intentional or accidental release of the reservoir host or pathogen; the exceeding of a numerical, ecological or behavioural threshold in the host populations and/or increased exposure of humans and domestic animals due to changes in behaviour; and lastly, an "adaptive" leap that ensures that a new host species finally succumbs to the pathogen and that it spreads among the conquered population. The authors examine the lessons to be drawn from such occurrences in terms of surveillance, prophylaxis and prevention.

Incidence and persistence of classical swine fever in free-ranging wild boar (Sus scrofa).

Although veterinary authorities aim to limit persistence of classical swine fever (CSF) in wild boar (Sus scrofa), to avoid potential transmission to pigs, factors influencing CSF transmission and persistence are not clearly understood. Here we analyse incidence and persistence in a CSF epidemic that occurred in the French Vosges Forest. Higher incidence was found in large forests compared to smaller isolated ones, being highest near the starting point of the epidemic, but poorly related to the local density. We hypothesize that the spatial and social structure of wild boar populations may be responsible for this variability of incidence over space. Persistence was highest near the starting point of the epidemic and where initial density was highest. We hypothesize that persistence was favoured by the abundance of young wild boar, itself encouraged by CSF. Our results allow us to propose management measures aimed at limiting CSF persistence.

Seoul hantavirus in Europe: first demonstration of the virus genome in wild Rattus norvegicus captured in France.

Although rats (Rattus rattus or Rattus norvegicus) worldwide have been found to carry Seoul hantavirus, there are at present only a very few reports of confirmed human Seoul hantavirus infections outside Asia, where the virus, in certain areas, is responsible for approximately 25% of the human hantavirus infections. In Europe, no confirmed human infections outside laboratories have been described, and although rats occasionally have been found to be antibody positive, the viral genome has not been demonstrated in these animals. The present report describes the first confirmed finding of Seoul hantavirus in R. norvegicus captured in Europe.

The role of wildlife in emerging and re-emerging zoonoses.

There are huge numbers of wild animals distributed throughout the world and the diversity of wildlife species is immense. Each landscape and habitat has a kaleidoscope of niches supporting an enormous variety of vertebrate and invertebrate species, and each species or taxon supports an even more impressive array of macro- and micro-parasites. Infectious pathogens that originate in wild animals have become increasingly important throughout the world in recent decades, as they have had substantial impacts on human health, agricultural production, wildlife-based economies and wildlife conservation. The emergence of these pathogens as significant health issues is associated with a range of causal factors, most of them linked to the sharp and exponential rise of global human activity. Among these causal factors are the burgeoning human population, the increased frequency and speed of local and international travel, the increase in human-assisted movement of animals and animal products, changing agricultural practices that favour the transfer of pathogens between wild and domestic animals, and a range of environmental changes that alter the distribution of wild hosts and vectors and thus facilitate the transmission of infectious agents. Two different patterns of transmission of pathogens from wild animals to humans are evident among these emerging zoonotic diseases. In one pattern, actual transmission of the pathogen to humans is a rare event but, once it has occurred, human-to-human transmission maintains the infection for some period of time or permanently. Some examples of pathogens with this pattern of transmission are human immunodeficiency virus/acquired immune deficiency syndrome, influenza A, Ebola virus and severe acute respiratory syndrome. In the second pattern, direct or vector-mediated animal-to-human transmission is the usual source of human infection. Wild animal populations are the principal reservoirs of the pathogen and human-to-human disease transmission is rare. Examples of pathogens with this pattern of transmission include rabies and other lyssaviruses, Nipah virus, West Nile virus, Hantavirus, and the agents of Lyme borreliosis, plague, tularemia, leptospirosis and ehrlichiosis. These zoonotic diseases from wild animal sources all have trends that are rising sharply upwards. In this paper, the authors discuss the causal factors associated with the emergence or re-emergence of these zoonoses, and highlight a selection to provide a composite view of their range, variety and origins. However, most of these diseases are covered in more detail in dedicated papers elsewhere in this Review.

Expression of the nucleoprotein of the Puumala virus from the recombinant Semliki Forest virus replicon: characterization and use as a potential diagnostic tool.

Puumala virus (Bunyaviridae family, Hantavirus genus) causes a mild form of hemorrhagic fever with renal syndrome (HFRS) called nephropathia epidemica in northern and central Europe. Serological tests are used for diagnosis, but antigen production is difficult because the virus grows poorly in tissue culture. We expressed the N protein (nucleoprotein) of Puumala virus via the Semliki Forest virus (SFV) replicon in mammalian cells and compared its antigenic properties with those of the native antigen derived from Puumala virus-infected cells. Detection of immunoglobulin G or immunoglobulin M by enzyme-linked immunosorbent assay (ELISA), micro -capture ELISA, and indirect immunofluorescence assay was (at least) as effective with the recombinant antigen as with the native antigen when HFRS patient sera or organ washes from wild rodents were tested. No nonspecific reaction was observed. Thus, the SFV-expressed N protein of Puumala virus appears as a valid antigen, specific and sensitive for serological investigations.

Puumala hantavirus infection in humans and in the reservoir host, Ardennes region, France.

We compared the occurrence of nephropathia epidemica cases, over a multi-annual population cycle, in northeastern France with the hantavirus serology for bank voles captured in the same area. We discuss hypotheses to explain the pattern of infection in both humans and rodents and their synchrony.

Classical swine fever (hog cholera) in wild boar in Europe.

Classical swine fever (CSF) is of increasing concern in Europe where wild boar appear to play an important epidemiological role. In most parts of the continent, demographic trends are on the increase, due to improvement in game management. As a result of higher densities, populations become more susceptible to various infectious diseases, among which CSF is cause for particular concern. Wild boar do not appear to be a classic reservoir in most cases, but nevertheless may perpetuate foci of infection over the long term, constituting a real threat for the pig farming industry. Since the infection does not appear to spread easily in natural populations of free-ranging wild boars, control of the disease may be feasible. However, most of the appropriate measures, such as banning hunting, are not considered acceptable. Consequently, the expertise of wildlife disease specialists is required to help solve the problem when it occurs.

Emerging infectious diseases in wildlife.

The processes which give rise to emerging infectious diseases of wildlife can be categorised as follows: ecosystem alterations of anthropogenic or natural origin; movement of pathogens or vectors, via human or natural agency; and changes in microbes or in the recognition of emerging pathogens due to advances in the techniques of epidemiology. These are simplistic divisions because factors influencing the emergence of diseases of wild animals generally fall into more than one category. Mycoplasmosis among passerines is related to habitat changes and artificial feeding resulting in increased bird densities and subsequent disease transmission. The origin of this strain of Mycoplasma gallisepticum is not known. Hantavirus infections in rodents have emerged due to human-induced landscape alterations and/or climatic changes influencing population dynamics of hantavirus reservoir hosts, with disease consequences for humans. Movement of pathogens or vectors is a very important process by which diseases of wildlife expand geographic range. Although the origin of caliciviruses of rabbits and hares is somewhat obscure, their movement by humans, either deliberately or accidentally, has greatly expanded the distribution of these viruses. Rabies is an ancient disease, but geographic expansion has occurred by both natural and anthropogenic movements of wild animals. Human movement of amphibians may explain the distribution of the highly pathogenic chytrid fungus around the world. Newly recognised paramyxoviruses may reflect both changes in these pathogens and the development of techniques of identification and classification. Many more such examples of emerging diseases will arise in the future, given the extensive alterations in landscapes world-wide and movements of animals, vectors and pathogens. Those who study and diagnose diseases of wildlife must be alert for emerging diseases so that the impact of such diseases on wild animals, domestic animals and humans can be minimised.

Surveillance and monitoring of wildlife diseases.

It is now recognised that those countries which conduct disease surveillance of their wild animal populations are more likely to detect the presence of infectious and zoonotic diseases and to swiftly adopt counter measures. The surveillance and monitoring of disease outbreaks in wildlife populations are particularly relevant in these days of rapid human and animal translocation, when the contact between wild and domestic animals is close and the threat of a bioterrorist attack is very real. The authors describe the problems inherent in wildlife disease surveillance and stress the importance of the establishment of national strategies for disease detection. The various sampling methods employed for monitoring outbreaks of disease and mortality in wildlife populations are discussed and their strengths and weaknesses described. A major advantage of an efficient disease monitoring programme for wildlife is the early detection of new and 'emerging' diseases, some of which may have serious zoonotic and economic implications. The authors conclude that wildlife disease monitoring programmes that are integrated within national animal health surveillance infrastructures should have the capacity to respond promptly to the detection of unusual wildlife mortality and to institute epizootiological research into new and emerging wildlife diseases.

Control of infectious diseases of wildlife in Europe.

During the last 30 years, new epidemiological patterns have emerged as free-ranging wildlife have become progressively more involved in the epidemiology of both common and emerging infectious diseases of humans and domestic animals. This has been seen in rabies, bovine tuberculosis and more recently in wild-boar classical swine fever. Emerging diseases are of interest to veterinarians as well as public health officials but attempts to control these diseases have not always been successful as in wildlife populations control of either host or pathogen can present particular problems. Lessons should be learnt from previous experiences to help in the management of new emerging diseases in the future.

Parasite richness and abundance in insular and mainland feral cats: insularity or density?

Hosts living on islands carry few parasite species, and the prevalence and intensity of directly transmitted parasites are often higher in insular than in mainland populations. However, it is unclear whether density or other features of insular populations can be responsible for the pattern observed. We compared the parasite richness, prevalence and intensity of parasites between 2 feral populations of cats living either at low density on an island (Kerguelen) or at high density on the mainland (Lyon). Parasite richness was higher in Lyon than in Kerguelen, where only Toxocara cati was found. T. cati egg prevalence was higher in Kerguelen (71.1%) than in Lyon (58.0%). Because cat density cannot explain this pattern, we propose that the low number of parasite species, the diet and/or immunity of cats act to increase prevalence in Kerguelen. Moreover, prevalence, intensity and variance-to-mean ratio increased with age and body mass in Kerguelen whereas, in Lyon, prevalence decreased with age and body mass. We hypothesize that the pattern of exposure differs between populations, and that density-dependent parasite mortality is lower in Kerguelen than in Lyon. We discuss the consequences concerning the influence of parasites on insular host populations.