Your browser doesn't support javascript.
loading
Show: 20 | 50 | 100
Results 1 - 20 de 40
Filter
Add more filters

Publication year range
1.
Nature ; 613(7943): 340-344, 2023 01.
Article in English | MEDLINE | ID: mdl-36384167

ABSTRACT

During recent decades, pathogens that originated in bats have become an increasing public health concern. A major challenge is to identify how those pathogens spill over into human populations to generate a pandemic threat1. Many correlational studies associate spillover with changes in land use or other anthropogenic stressors2,3, although the mechanisms underlying the observed correlations have not been identified4. One limitation is the lack of spatially and temporally explicit data on multiple spillovers, and on the connections among spillovers, reservoir host ecology and behaviour and viral dynamics. We present 25 years of data on land-use change, bat behaviour and spillover of Hendra virus from Pteropodid bats to horses in subtropical Australia. These data show that bats are responding to environmental change by persistently adopting behaviours that were previously transient responses to nutritional stress. Interactions between land-use change and climate now lead to persistent bat residency in agricultural areas, where periodic food shortages drive clusters of spillovers. Pulses of winter flowering of trees in remnant forests appeared to prevent spillover. We developed integrative Bayesian network models based on these phenomena that accurately predicted the presence or absence of clusters of spillovers in each of the 25 years. Our long-term study identifies the mechanistic connections between habitat loss, climate and increased spillover risk. It provides a framework for examining causes of bat virus spillover and for developing ecological countermeasures to prevent pandemics.


Subject(s)
Chiroptera , Ecology , Ecosystem , Hendra Virus , Horses , Animals , Humans , Australia , Bayes Theorem , Chiroptera/virology , Climate , Horses/virology , Public Health , Hendra Virus/isolation & purification , Natural Resources , Agriculture , Forests , Food Supply , Pandemics/prevention & control , Pandemics/veterinary
2.
Epidemiol Infect ; 147: e240, 2019 01.
Article in English | MEDLINE | ID: mdl-31364577

ABSTRACT

Hendra virus (HeV) continues to cause fatal infection in horses and threaten infection in close-contact humans in eastern Australia. Species of Pteropus bats (flying-foxes) are the natural reservoir of the virus. We caught and sampled flying-foxes from a multispecies roost in southeast Queensland, Australia on eight occasions between June 2013 and June 2014. The effects of sample date, species, sex, age class, body condition score (BCS), pregnancy and lactation on HeV antibody prevalence, log-transformed median fluorescent intensity (lnMFI) values and HeV RNA status were assessed using unbalanced generalised linear models. A total of 1968 flying-foxes were sampled, comprising 1012 Pteropus alecto, 742 P. poliocephalus and 214 P. scapulatus. Sample date, species and age class were each statistically associated with HeV RNA status, antibody status and lnMFI values; BCS was statistically associated with HeV RNA status and antibody status. The findings support immunologically naïve sub-adult P. alecto playing an important role in maintaining HeV infection at a population level. The biological significance of the association between BCS and HeV RNA status, and BCS and HeV antibody status, is less clear and warrants further investigation. Contrary to previous studies, we found no direct association between HeV infection and pregnancy or lactation. The findings in P. poliocephalus suggest that HeV exposure in this species may not result in systemic infection and virus excretion, or alternatively, may reflect assay cross-reactivity with another (unidentified) henipavirus.


Subject(s)
Chiroptera/virology , Disease Outbreaks/statistics & numerical data , Disease Transmission, Infectious/statistics & numerical data , Hendra Virus/isolation & purification , Henipavirus Infections/epidemiology , Horse Diseases/epidemiology , Age Factors , Animals , Antibodies, Viral/blood , Australia/epidemiology , Body Composition , Female , Horses , Humans , Pregnancy , Prevalence , Queensland/epidemiology , RNA, Viral/analysis , Real-Time Polymerase Chain Reaction/methods , Risk Assessment , Seasons
3.
J Gen Virol ; 96(Pt 6): 1229-1237, 2015 Jun.
Article in English | MEDLINE | ID: mdl-25667321

ABSTRACT

Hendra virus (HeV) is lethal to humans and horses, and little is known about its epidemiology. Biosecurity restrictions impede advances, particularly on understanding pathways of transmission. Quantifying the environmental survival of HeV can be used for making decisions and to infer transmission pathways. We estimated HeV survival with a Weibull distribution and calculated parameters from data generated in laboratory experiments. HeV survival rates based on air temperatures 24 h after excretion ranged from 2 to 10 % in summer and from 12 to 33 % in winter. Simulated survival across the distribution of the black flying fox (Pteropus alecto), a key reservoir host, did not predict spillover events. Based on our analyses we concluded that the most likely pathways of transmission did not require long periods of virus survival and were likely to involve relatively direct contact with flying fox excreta shortly after excretion.


Subject(s)
Chiroptera/virology , Hendra Virus/genetics , Hendra Virus/isolation & purification , Henipavirus Infections/veterinary , Horses/virology , Animals , Henipavirus Infections/transmission , Henipavirus Infections/virology , Microbial Viability , Models, Statistical , Seasons
4.
BMC Public Health ; 14: 182, 2014 Feb 20.
Article in English | MEDLINE | ID: mdl-24552445

ABSTRACT

BACKGROUND: After the 2011 cluster of Hendra virus cases in horses in Australia, public health targeted education initiatives at people in the equine industry to reduce human exposure to potentially infected horses. 'Horse owners and Hendra Virus: A Longitudinal cohort study To Evaluate Risk' aims to enhance public health measures through improved understanding of Hendra virus risk perception and risk mitigation strategies among horse owners and horse care providers. This paper describes the stakeholder consultation that was undertaken to ensure the cohort study outcomes were relevant to diverse groups who play a role in Hendra virus policy development and implementation. METHODS: A two-round modified Delphi study with online questionnaires was conducted. In round one, stakeholders identified priority research areas. In round two, stakeholders rated and ranked topics that emerged from thematic analysis of the round one responses. Round two data were analysed using logistic regression. RESULTS: Of the 255 stakeholders contacted, 101 responded to round one. Over 450 topics were proposed. These were organized into 18 themes. Approximately two thirds of the round one respondents participated in round two. 'Hendra virus-related risk awareness and perception', 'personal health and safety', 'emergency preparedness', 'risk prevention, mitigation, and biosecurity', and 'Hendra virus vaccination in horses--attitudes/uptake' were the top five areas identified according to probability of being ranked extremely important. CONCLUSIONS: In this study, a modified Delphi approach was effective in guiding research into Hendra virus, a zoonotic disease of animal and human health significance. The findings support the notion that stakeholders should be engaged in zoonotic disease research priority setting. Such consultation will help to ensure that research initiatives are relevant and useful to stakeholders in the position to make use of new findings.


Subject(s)
Biomedical Research , Delphi Technique , Henipavirus Infections , Zoonoses , Animals , Australia , Cohort Studies , Hendra Virus/isolation & purification , Henipavirus Infections/prevention & control , Henipavirus Infections/transmission , Horses , Humans , Logistic Models , Male , Middle Aged , Zoonoses/prevention & control , Zoonoses/transmission
5.
Vet Clin North Am Equine Pract ; 30(3): 579-89, 2014 Dec.
Article in English | MEDLINE | ID: mdl-25281398

ABSTRACT

Hendra virus infection of horses occurred sporadically between 1994 and 2010 as a result of spill-over from the viral reservoir in Australian mainland flying-foxes, and occasional onward transmission to people also followed from exposure to affected horses. An unprecedented number of outbreaks were recorded in 2011 leading to heightened community concern. Release of an inactivated subunit vaccine for horses against Hendra virus represents the first commercially available product that is focused on mitigating the impact of a Biosafety Level 4 pathogen. Through preventing the development of acute Hendra virus disease in horses, vaccine use is also expected to reduce the risk of transmission of infection to people.


Subject(s)
Hendra Virus/isolation & purification , Henipavirus Infections/veterinary , Horse Diseases/virology , Animals , Australia/epidemiology , Chiroptera/virology , Henipavirus Infections/epidemiology , Henipavirus Infections/virology , Horse Diseases/epidemiology , Horses , Humans , Zoonoses/epidemiology , Zoonoses/virology
6.
Curr Top Microbiol Immunol ; 359: 179-96, 2012.
Article in English | MEDLINE | ID: mdl-22481141

ABSTRACT

Since the last major review on diagnosis of henipavirus infection about a decade ago, significant progress has been made in many different areas of test development, especially in the development of molecular tests using real-time PCR and many novel serological test platforms. In addition to provide an updated review of the current test capabilities, this review also identifies key future challenges in henipavirus diagnosis.


Subject(s)
Hendra Virus/isolation & purification , Henipavirus Infections/diagnosis , Nipah Virus/isolation & purification , Animals , Cell Line , Enzyme-Linked Immunosorbent Assay , Hendra Virus/genetics , Hendra Virus/pathogenicity , Henipavirus Infections/blood , Henipavirus Infections/cerebrospinal fluid , Henipavirus Infections/virology , Humans , Immunohistochemistry , Microscopy, Electron , Molecular Typing , Neutralization Tests , Nipah Virus/genetics , Nipah Virus/pathogenicity , Real-Time Polymerase Chain Reaction
7.
Curr Top Microbiol Immunol ; 359: 25-40, 2012.
Article in English | MEDLINE | ID: mdl-22752412

ABSTRACT

All seven recognized human cases of Hendra virus (HeV) infection have occurred in Queensland, Australia. Recognized human infections have all resulted from a HeV infected horse that was unusually efficient in transmitting the virus and a person with a high exposure to infectious secretions. In the large outbreak in Malaysia where Nipah virus (NiV) was first identified, most human infections resulted from close contact with NiV infected pigs. Outbreak investigations in Bangladesh have identified drinking raw date palm sap as the most common pathway of NiV transmission from Pteropus bats to people, but person-to-person transmission of NiV has been repeatedly identified in Bangladesh and India. Although henipaviruses are not easily transmitted to people, these newly recognized, high mortality agents warrant continued scientific attention.


Subject(s)
Disease Outbreaks , Hendra Virus/isolation & purification , Henipavirus Infections/epidemiology , Horse Diseases/epidemiology , Nipah Virus/isolation & purification , Animals , Arecaceae/virology , Australia/epidemiology , Bangladesh/epidemiology , Chiroptera/virology , Fruit/virology , Hendra Virus/pathogenicity , Henipavirus Infections/transmission , Henipavirus Infections/virology , Horse Diseases/transmission , Horse Diseases/virology , Horses/virology , Humans , India/epidemiology , Malaysia/epidemiology , Nipah Virus/pathogenicity , Phylogeography
8.
Curr Top Microbiol Immunol ; 359: 11-23, 2012.
Article in English | MEDLINE | ID: mdl-22476530

ABSTRACT

Hendra virus, a novel and fatally zoonotic member of the family Paramyxoviridae, was first described in Australia in 1994. Periodic spillover from its natural host (fruit bats) results in catastrophic disease in horses and occasionally the subsequent infection of humans. Prior to 2011, 14 equine incidents involving seven human cases (four fatal) were recorded. The year 2011 saw a dramatic departure from the sporadic incidents of the previous 16 years, with a cluster of 18 incidents in a single 3-month period. The fundamental difference in 2011 was the total number of incidents, the geographic clustering, and the expanded geographic range. The 2011 cluster more than doubled the total number of incidents previously reported, and poses the possibility of a new HeV infection paradigm. Epidemiologic evidence suggests that compelling additional host and/or environmental factors were at play.


Subject(s)
Disease Outbreaks , Hendra Virus/pathogenicity , Henipavirus Infections/epidemiology , Henipavirus Infections/veterinary , Horse Diseases/epidemiology , Zoonoses/epidemiology , Animals , Australia/epidemiology , Chiroptera/virology , Ecosystem , Hendra Virus/isolation & purification , Henipavirus Infections/virology , Horse Diseases/virology , Horses/virology , Humans , Phylogeography , Zoonoses/virology
9.
Article in English | MEDLINE | ID: mdl-22782307

ABSTRACT

Until the Nipah outbreak in Malaysia in 1999, knowledge of human infections with the henipaviruses was limited to the small number of cases associated with the emergence of Hendra virus in Australia in 1994. The Nipah outbreak in Malaysia alerted the global public health community to the severe pathogenic potential and widespread distribution of these unique paramyxoviruses. This chapter briefly describes the initial discovery of Nipah virus and the challenges encountered during the initial identification and characterisation of the aetiological agent responsible for the outbreak of febrile encephalitis. The initial attempts to isolate Nipah virus from the bat reservoir host are also described.


Subject(s)
Disease Outbreaks , Disease Reservoirs/veterinary , Encephalitis, Viral/diagnosis , Encephalitis, Viral/epidemiology , Henipavirus Infections/diagnosis , Henipavirus Infections/epidemiology , Nipah Virus/isolation & purification , Animals , Australia/epidemiology , Chiroptera/virology , Chlorocebus aethiops , Encephalitis, Viral/cerebrospinal fluid , Encephalitis, Viral/virology , Hendra Virus/isolation & purification , Hendra Virus/pathogenicity , Henipavirus Infections/cerebrospinal fluid , Henipavirus Infections/virology , Humans , Malaysia/epidemiology , Nipah Virus/pathogenicity , Vero Cells
10.
Curr Top Microbiol Immunol ; 359: 41-58, 2012.
Article in English | MEDLINE | ID: mdl-22552699

ABSTRACT

Nipah (NiV) and Hendra (HeV) viruses comprise the genus Henipavirus and are highly pathogenic paramyxoviruses, which cause fatal encephalitis and respiratory disease in humans. Since their respective initial outbreaks in 1998 and 1994, they have continued to cause sporadic outbreaks resulting in fatal disease. Due to their designation as Biosafety Level 4 pathogens, the level of containment required to work with live henipaviruses is available only to select laboratories around the world. This chapter provides an overview of the molecular virology of NiV and HeV including comparisons to other, well-characterized paramyxoviruses. This chapter also describes the sequence diversity present among the henipaviruses.


Subject(s)
Genome, Viral , Hendra Virus/genetics , Nipah Virus/genetics , Viral Proteins/genetics , Animals , Chiroptera/virology , Encephalitis, Viral/complications , Encephalitis, Viral/virology , Genetic Variation , Genome Size , Hendra Virus/classification , Hendra Virus/isolation & purification , Henipavirus Infections/complications , Henipavirus Infections/virology , Horses/virology , Humans , Nipah Virus/classification , Nipah Virus/isolation & purification , Phylogeny , Reverse Genetics , Virus Replication
11.
Arch Virol ; 157(8): 1605-9, 2012 Aug.
Article in English | MEDLINE | ID: mdl-22585045

ABSTRACT

A novel antigen-capture sandwich ELISA system targeting the glycoproteins of the henipaviruses Nipah virus (NiV) and Hendra virus (HeV) was developed. Utilizing purified polyclonal antibodies derived from NiV glycoprotein-encoding DNA-immunized rabbits, we established a system that can detect the native antigenic structures of the henipavirus surface glycoproteins using simplified and inexpensive methods. The lowest detection limit against live viruses was achieved for NiV Bangladesh strain, 2.5 × 10(4) TCID(50). Considering the recent emergence of genetic variants of henipaviruses and the resultant problems that arise for PCR-based detection, this system could serve as an alternative rapid diagnostic and detection assay.


Subject(s)
DNA, Viral/immunology , Enzyme-Linked Immunosorbent Assay/methods , Hendra Virus/isolation & purification , Henipavirus Infections/diagnosis , Animals , Antibodies, Viral/immunology , Cell Line , Chiroptera/virology , Hendra Virus/genetics , Hendra Virus/immunology , Membrane Glycoproteins/immunology , Nipah Virus/genetics , Nipah Virus/immunology , Rabbits , Sensitivity and Specificity , Viral Envelope Proteins/analysis , Viral Envelope Proteins/immunology
12.
Emerg Infect Dis ; 17(12): 2232-8, 2011 Dec.
Article in English | MEDLINE | ID: mdl-22172152

ABSTRACT

Hendra virus (HeV) is a highly pathogenic zoonotic paramyxovirus harbored by Australian flying foxes with sporadic spillovers directly to horses. Although the mode and critical control points of HeV spillover to horses from flying foxes, and the risk for transmission from infected horses to other horses and humans, are poorly understood, we successfully established systemic HeV disease in 3 horses exposed to Hendra virus/Australia/Horse/2008/Redlands by the oronasal route, a plausible route for natural infection. In 2 of the 3 animals, HeV RNA was detected continually in nasal swabs from as early as 2 days postexposure, indicating that systemic spread of the virus may be preceded by local viral replication in the nasal cavity or nasopharynx. Our data suggest that a critical factor for reducing HeV exposure risk to humans includes early consideration of HeV in the differential diagnosis and institution of appropriate infection control procedures.


Subject(s)
Hendra Virus , Henipavirus Infections/veterinary , Horse Diseases/virology , Animals , Australia , Chiroptera/virology , Communicable Diseases, Emerging/diagnosis , Communicable Diseases, Emerging/transmission , Communicable Diseases, Emerging/veterinary , Communicable Diseases, Emerging/virology , Female , Hendra Virus/genetics , Hendra Virus/isolation & purification , Hendra Virus/physiology , Henipavirus Infections/diagnosis , Henipavirus Infections/transmission , Henipavirus Infections/virology , Horse Diseases/diagnosis , Horse Diseases/transmission , Horses , Humans , Queensland , Viral Load , Virus Replication , Virus Shedding , Zoonoses/transmission , Zoonoses/virology
13.
Ann Trop Med Parasitol ; 105(1): 1-11, 2011 Jan.
Article in English | MEDLINE | ID: mdl-21294944

ABSTRACT

Hendra virus (HeV) was first isolated in 1994, from a disease outbreak involving at least 21 horses and two humans in the Brisbane suburb of Hendra, Australia. The affected horses and humans all developed a severe but unidentified respiratory disease that resulted in the deaths of one of the human cases and the deaths or putting down of 14 of the horses. The virus, isolated by culture from a horse and the kidney of the fatal human case, was initially characterised as a new member of the genus Morbillivirus in the family Paramyxoviridae. Comparative sequence analysis of part of the matrix protein gene of the virus and the discovery that the virus had an exceptionally large genome subsequently led to HeV being assigned to a new genus, Henipavirus, along with Nipah virus (a newly emergent virus in pigs). The regular outbreaks of HeV-related disease that have occurred in Australia since 1994 have all been characterised by acute respiratory and neurological manifestations, with high levels of morbidity and mortality in the affected horses and humans. The modes of transmission of HeV remain largely unknown. Although fruit bats have been identified as natural hosts of the virus, direct bat-horse, bat-human or human-human transmission has not been reported. Human infection can occur via exposure to infectious urine, saliva or nasopharyngeal fluid from horses. The treatment options and efficacy are very limited and no vaccine exists. Reports on the outbreaks of HeV in Australia are collated in this review and the available data on the biology, transmission and detection of the pathogen are summarized and discussed.


Subject(s)
Chiroptera/virology , Disease Outbreaks , Hendra Virus/pathogenicity , Henipavirus Infections/epidemiology , Henipavirus Infections/virology , Horse Diseases/virology , Animals , Australia/epidemiology , Disease Outbreaks/statistics & numerical data , Hendra Virus/genetics , Hendra Virus/isolation & purification , Henipavirus Infections/mortality , Henipavirus Infections/transmission , Horse Diseases/epidemiology , Horse Diseases/transmission , Horses , Humans , Immunohistochemistry , Nipah Virus/pathogenicity , Zoonoses/epidemiology , Zoonoses/virology
14.
Emerg Infect Dis ; 16(2): 338-40, 2010 Feb.
Article in English | MEDLINE | ID: mdl-20113576

ABSTRACT

To determine the epidemiologic and clinical features of a 2008 outbreak of Hendra virus infection in a veterinary clinic in Australia, we investigated the equine case-series. Four of 5 infected horses died, as did 1 of 2 infected staff members. Clinical manifestation in horses was predominantly neurologic. Preclinical transmission appears likely.


Subject(s)
Disease Outbreaks/veterinary , Hendra Virus/isolation & purification , Henipavirus Infections/veterinary , Horse Diseases/mortality , Animals , Australia/epidemiology , Henipavirus Infections/mortality , Horse Diseases/virology , Horses , Humans , Immunohistochemistry , Mortality
15.
Virol J ; 7: 115, 2010 Jun 03.
Article in English | MEDLINE | ID: mdl-20525276

ABSTRACT

BACKGROUND: Outbreaks of Hendra (HeV) and Nipah (NiV) viruses have been reported starting in 1994 and 1998, respectively. Both viruses are capable of causing fatal disease in humans and effecting great economical loss in the livestock industry. RESULTS: Through screening of hybridomas derived from mice immunized with gamma-irradiated Nipah virus, we identified two secreted antibodies; one reactive with the nucleocapsid (N) protein and the other, the phosphoprotein (P) of henipaviruses. Epitope mapping and protein sequence alignments between NiV and HeV suggest the last 14 amino acids of the carboxyl terminus of the N protein is the target of the anti-N antibody. The anti-P antibody recognizes an epitope in the amino-terminal half of P protein. These monoclonal antibodies were used to develop two antigen capture ELISAs, one for virus detection and the other for differentiation between NiV and HeV. The lower limit of detection of the capture assay with both monoclonal antibodies was 400 pfu. The anti-N antibody was used to successfully detect NiV in a lung tissue suspension from an infected pig. CONCLUSION: The antigen capture ELISA developed is potentially affordable tool to provide rapid detection and differentiation between the henipaviruses.


Subject(s)
Antibodies, Monoclonal/analysis , Antigens, Viral/analysis , Enzyme-Linked Immunosorbent Assay/methods , Hendra Virus/isolation & purification , Henipavirus Infections/veterinary , Henipavirus Infections/virology , Nipah Virus/isolation & purification , Swine Diseases/virology , Animals , Antibodies, Monoclonal/immunology , Antigens, Viral/immunology , Cell Line , Epitope Mapping , Hendra Virus/immunology , Henipavirus Infections/immunology , Humans , Mice , Mice, Inbred BALB C , Nipah Virus/immunology , Nucleocapsid Proteins/analysis , Nucleocapsid Proteins/immunology , Phosphoproteins/analysis , Phosphoproteins/immunology , Swine , Swine Diseases/immunology
16.
PLoS One ; 15(5): e0232339, 2020.
Article in English | MEDLINE | ID: mdl-32374743

ABSTRACT

Habitat-mediated global change is driving shifts in species' distributions which can alter the spatial risks associated with emerging zoonotic pathogens. Many emerging infectious pathogens are transmitted by highly mobile species, including bats, which can act as spill-over hosts for pathogenic viruses. Over three years, we investigated the seroepidemiology of paramyxoviruses and Australian bat lyssavirus in a range-expanding fruit bat, the Grey-headed flying fox (Pteropus poliocephalus), in a new camp in Adelaide, South Australia. Over six, biannual, sampling sessions, we quantified median florescent intensity (MFI) antibody levels for four viruses for a total of 297 individual bats using a multiplex Luminex binding assay. Where appropriate, florescence thresholds were determined using finite mixture modelling to classify bats' serological status. Overall, apparent seroprevalence of antibodies directed at Hendra, Cedar and Tioman virus antigens was 43.2%, 26.6% and 95.7%, respectively. We used hurdle models to explore correlates of seropositivity and antibody levels when seropositive. Increased body condition was significantly associated with Hendra seropositivity (Odds ratio = 3.67; p = 0.002) and Hendra virus levels were significantly higher in pregnant females (p = 0.002). While most bats were seropositive for Tioman virus, antibody levels for this virus were significantly higher in adults (p < 0.001). Unexpectedly, all sera were negative for Australian bat lyssavirus. Temporal variation in antibody levels suggests that antibodies to Hendra virus and Tioman virus may wax and wane on a seasonal basis. These findings suggest a common exposure to Hendra virus and other paramyxoviruses in this flying fox camp in South Australia.


Subject(s)
Chiroptera/virology , Hendra Virus/isolation & purification , Lyssavirus/isolation & purification , Animals , Chiroptera/blood , Chiroptera/immunology , Chiroptera/physiology , Female , Hendra Virus/immunology , Lyssavirus/immunology , Male , Reproduction , Seroepidemiologic Studies
17.
Neuropathol Appl Neurobiol ; 35(3): 296-305, 2009 Jun.
Article in English | MEDLINE | ID: mdl-19473296

ABSTRACT

AIM: To study the pathology of two cases of human Hendra virus infection, one with no clinical encephalitis and one with relapsing encephalitis. METHODS: Autopsy tissues were investigated by light microscopy, immunohistochemistry and in situ hybridization. RESULTS: In the patient with acute pulmonary syndrome but not clinical acute encephalitis, vasculitis was found in the brain, lung, heart and kidney. Occasionally, viral antigens were demonstrated in vascular walls but multinucleated endothelial syncytia were absent. In the lung, there was severe inflammation, necrosis and viral antigens in type II pneumocytes and macrophages. The rare kidney glomerulus showed inflammation and viral antigens in capillary walls and podocytes. Discrete necrotic/vacuolar plaques in the brain parenchyma were associated with antigens and viral RNA. Brain inflammation was mild although CD68(+) microglia/macrophages were significantly increased. Cytoplasmic viral inclusions and antigens and viral RNA in neurones and ependyma suggested viral replication. In the case of relapsing encephalitis, there was severe widespread meningoencephalitis characterized by neuronal loss, macrophages and other inflammatory cells, reactive blood vessels and perivascular cuffing. Antigens and viral RNA were mainly found in neurones. Vasculitis was absent in all the tissues examined. CONCLUSIONS: The case of acute Hendra virus infection demonstrated evidence of systemic infection and acute encephalitis. The case of relapsing Hendra virus encephalitis showed no signs of extraneural infection but in the brain, extensive inflammation and infected neurones were observed. Hendra virus can cause acute and relapsing encephalitis and the findings suggest that the pathology and pathogenesis are similar to Nipah virus infection.


Subject(s)
Brain/pathology , Encephalitis, Viral/pathology , Hendra Virus , Henipavirus Infections/pathology , Adult , Antigens, Viral/analysis , Brain/blood supply , Brain/immunology , Brain/virology , Coronary Vessels/pathology , Encephalitis, Viral/immunology , Encephalitis, Viral/virology , Ependyma/pathology , Ependyma/virology , Female , Hendra Virus/isolation & purification , Henipavirus Infections/immunology , Henipavirus Infections/virology , Humans , Kidney/blood supply , Kidney/pathology , Kidney/virology , Lung/blood supply , Lung/pathology , Lung/virology , Macrophages , Male , Microglia , Middle Aged , Myocardium/pathology , Neurons/pathology , Neurons/virology , RNA, Viral/metabolism , Recurrence , Vasculitis/immunology , Vasculitis/pathology , Vasculitis/virology
18.
Transbound Emerg Dis ; 66(2): 921-928, 2019 Mar.
Article in English | MEDLINE | ID: mdl-30576076

ABSTRACT

Hendra virus (HeV) and Nipah virus (NiV), belonging to the genus Henipavirus, are among the most pathogenic of viruses in humans. Old World fruit bats (family Pteropodidae) are the natural reservoir hosts. Molecular and serological studies found evidence of henipavirus infection in fruit bats from several African countries. However, little is known about the potential for spillover into domestic animals in East Africa, particularly pigs, which served as amplifying hosts during the first outbreak of NiV in Malaysia and Singapore. We collected sera from 661 pigs presented for slaughter in Uganda between December 2015 and October 2016. Using HeV G and NiV G indirect ELISAs, 14 pigs (2%) were seroreactive in at least one ELISA. Seroprevalence increased to 5.4% in October 2016, when pigs were 9.5 times more likely to be seroreactive than pigs sampled in December 2015 (p = 0.04). Eight of the 14 ELISA-positive samples reacted with HeV N antigen in Western blot. None of the sera neutralized HeV or NiV in plaque reduction neutralization tests. Although we did not detect neutralizing antibodies, our results suggest that pigs in Uganda are exposed to henipaviruses or henipa-like viruses. Pigs in this study were sourced from many farms throughout Uganda, suggesting multiple (albeit rare) introductions of henipaviruses into the pig population. We postulate that given the widespread distribution of Old World fruit bats in Africa, spillover of henipaviruses from fruit bats to pigs in Uganda could result in exposure of pigs at multiple locations. A higher risk of a spillover event at the end of the dry season might be explained by higher densities of bats and contact with pigs at this time of the year, exacerbated by nutritional stress in bat populations and their reproductive cycle. Future studies should prioritize determining the risk of spillover of henipaviruses from pigs to people, so that potential risks can be mitigated.


Subject(s)
Hendra Virus/isolation & purification , Henipavirus Infections/veterinary , Nipah Virus/isolation & purification , Swine Diseases/epidemiology , Animals , Enzyme-Linked Immunosorbent Assay , Female , Henipavirus Infections/epidemiology , Henipavirus Infections/virology , Male , Prevalence , Risk Factors , Seroepidemiologic Studies , Sus scrofa , Swine , Swine Diseases/virology , Uganda/epidemiology
19.
J Virol Methods ; 149(1): 12-9, 2008 Apr.
Article in English | MEDLINE | ID: mdl-18313148

ABSTRACT

There are currently no antiviral drugs approved for the highly lethal Biosafety Level 4 pathogens Nipah and Hendra virus. A number of researchers are developing surrogate assays amenable to Biosafety Level 2 biocontainment but ultimately, the development of a high throughput screening method for directly quantifying these viruses in a Biosafety Level 4 environment will be critical for final evaluation of antiviral drugs identified in surrogate assays, in addition to reducing the time required for effective antiviral drug development. By adapting an existing immunoplaque assay and using enzyme linked immunodetection in a microtitre plate format, the current experiments describe a simple two step assay protocol involving an overnight virus inoculation of Vero cell monolayers (with or without antiviral drug treatment) at Biosafety Level 4, followed by cell fixation and virus inactivation enabling removal of plates from the Biosafety Level 4 laboratory and a subsequent immunodetection assay using a chemiluminescent horse radish peroxidase substrate to be performed at Biosafety Level 2. The analytical sensitivity (limit of detection) of this assay is 100 tissue culture infectious dose50/ml of either Nipah or Hendra virus. In addition this assay enables linear quantitation of virus over three orders of magnitude and is unaffected by dimethyl sulfoxide concentrations of 1% or less. Intra-assay coefficients of variation are acceptable (less than 20%) when detecting a minimum of 1000 tissue culture infectious dose50/ml of either virus although inter-assay variation is considerably greater. By an assessment of efficacies of the broad spectrum antiviral Ribavirin and an experimental fusion inhibitory peptide, this assay reveals a good correlation with previously published fluorescent immunodetection assays. The current experiments describe for the first time, a high throughput screening method amenable for direct assessment of live henipavirus antiviral drug activity.


Subject(s)
Antiviral Agents/pharmacology , Hendra Virus/isolation & purification , Immunoassay/methods , Luminescent Measurements/methods , Nipah Virus/isolation & purification , Animals , Chlorocebus aethiops , Hendra Virus/drug effects , Nipah Virus/drug effects , Sensitivity and Specificity , Vero Cells
20.
J Wildl Dis ; 53(1): 111-120, 2017 01.
Article in English | MEDLINE | ID: mdl-27723384

ABSTRACT

Bats of the genus Pteropus (Pteropodidae), colloquially known as flying foxes, are recognized as the natural reservoir of Hendra virus, a zoonotic paramyxovirus responsible for mortality in horses and humans. Some previous studies have suggested that physiologic and ecologic factors promote Hendra virus infection in flying foxes, and by extension, spillover to horses and humans. However, the impact of Hendra virus infection on relevant physiologic biomarkers in flying foxes has not been measured. Over 12 mo in eastern Australia, we captured and sampled 446 individual black flying foxes ( Pteropus alecto ), a putative primary reservoir host species, and measured a suite of hematologic, plasma biochemistry, and urinary biomarkers. All mean hematologic and biochemical values in both Hendra virus-positive and virus-negative cohorts were within the published reference ranges for black flying foxes. We found no association between Hendra virus infection (as indicated by PCR detection of Hendra virus RNA) and biomarkers for nutritional stress, reproductive stress, or extreme metabolic demand. However, we identified associations between several other biomarkers and Hendra virus infection, which may partly elucidate the physiologic effects of Hendra virus infection in flying foxes. Our findings highlight the need for critical evaluation of putative risk factors for infection in flying foxes and provide insights for future epidemiologic studies of Hendra virus and related viruses in the Pteropus species.


Subject(s)
Chiroptera/virology , Hendra Virus/isolation & purification , Henipavirus Infections/veterinary , Animals , Australia , Biomarkers
SELECTION OF CITATIONS
SEARCH DETAIL