Henipavirus
Hendra Virus
Nipah Virus
Ephrin-B3
Chiroptera
Ephrin-B2
Paramyxovirinae
Late clinical and magnetic resonance imaging follow up of Nipah virus infection. (1/135)
The Nipah virus is a newly identified paramyxovirus responsible for an outbreak of fatal encephalitis in Malaysia and Singapore. This paper reports the follow up clinical and magnetic resonance imaging findings in 22 affected subjects. Of 13 patients with encephalitis, one died, one was lost to follow up, and seven recovered. Among the four remaining patients, one had residual sixth nerve palsy, another suffered from severe clinical depression, and a third patient had evidence of retinal artery occlusion. One patient with delayed onset Horner syndrome had a single lesion in the cervical spinal cord. The brain magnetic resonance findings were stable or improved in nine patients over 18 months of follow up. Among a second group of nine asymptomatic seropositive abattoir workers, magnetic resonance examination in seven subjects revealed discrete small lesions in the brain; similar to those detected in encephalitis patients. These findings suggest that in addition to encephalitis, the newly discovered Nipah virus affects the spinal cord and the retina. Late clinical and radiological findings can occur in Nipah virus infections as with other paramyxoviruses. (+info)A golden hamster model for human acute Nipah virus infection. (2/135)
A predominantly pig-to-human zoonotic infection caused by the novel Nipah virus emerged recently to cause severe morbidity and mortality in both animals and man. Human autopsy studies showed the pathogenesis to be related to systemic vasculitis that led to widespread thrombotic occlusion and microinfarction in most major organs especially in the central nervous system. There was also evidence of extravascular parenchymal infection, particularly near damaged vessels (Wong KT, Shieh WJ, Kumar S, Norain K, Abdullah W, Guarner J, Goldsmith CS, Chua KB, Lam SK, Tan CT, Goh KJ, Chong HT, Jusoh R, Rollin PE, Ksiazek TG, Zaki SR, Nipah Virus Pathology Working Group: Nipah virus infection: Pathology and pathogenesis of an emerging paramyxoviral zoonosis. Am J Pathol 2002, 161:2153-2167). We describe here a golden hamster (Mesocricetus auratus) model that appears to reproduce the pathology and pathogenesis of acute human Nipah infection. Hamsters infected by intranasal or intraperitoneal routes died within 9 to 29 days or 5 to 9 days, respectively. Pathological lesions were most severe and extensive in the hamster brain. Vasculitis, thrombosis, and more rarely, multinucleated endothelial syncytia, were found in blood vessels of multiple organs. Viral antigen and RNA were localized in both vascular and extravascular tissues including neurons, lung, kidney, and spleen, as demonstrated by immunohistochemistry and in situ hybridization, respectively. Paramyxoviral-type nucleocapsids were identified in neurons and in vessel walls. At the terminal stage of infection, virus and/or viral RNA could be recovered from most solid organs and urine, but not from serum. The golden hamster is proposed as a suitable model for further studies including pathogenesis studies, anti-viral drug testing, and vaccine development against acute Nipah infection. (+info)Nipah virus: vaccination and passive protection studies in a hamster model. (3/135)
Nipah virus, a member of the paramyxovirus family, was first isolated and identified in 1999 when the virus crossed the species barrier from fruit bats to pigs and then infected humans, inducing an encephalitis with up to 40% mortality. At present there is no prophylaxis for Nipah virus. We investigated the possibility of vaccination and passive transfer of antibodies as interventions against this disease. We show that both of the Nipah virus glycoproteins (G and F) when expressed as vaccinia virus recombinants induced an immune response in hamsters which protected against a lethal challenge by Nipah virus. Similarly, passive transfer of antibody induced by either of the glycoproteins protected the animals. In both the active and passive immunization studies, however, the challenge virus was capable of hyperimmunizing the vaccinated animals, suggesting that although the virus replicates under these conditions, the immune system can eventually control the infection. (+info)Reactivity of anti-Nipah virus monoclonal antibodies to formalin-fixed, paraffin-embedded lung tissues from experimental Nipah and Hendra virus infections. (4/135)
The immunohistochemical reactivity of seven clones of mouse monoclonal antibodies raised to Nipah virus antigens were investigated using formalin-fixed, paraffin embedded porcine and equine lung tissues from experimental Nipah and Hendra virus infection, respectively. Either microwave irradiation or enzymatic digestion effectively unmasked the viral antigens in formalin-fixed, paraffin-embedded tissue sections. Four clones showed positive reaction to both Nipah virus-infected porcine lung tissue and Hendra virus-infected equine lung tissue. Two clones (11F6 and 13A5) reacted with Nipah virus-infected porcine lung tissue, but not with Hendra virus-infected equine lung tissue. These Nipah virus-specific monoclonal antibodies may therefore be useful for immunohistological diagnosis of Nipah virus infection and for further research on Nipah virus pathogenesis. (+info)Nipah virus encephalitis reemergence, Bangladesh. (5/135)
We retrospectively investigated two outbreaks of encephalitis in Meherpur and Naogaon, Bangladesh, which occurred in 2001 and 2003. We collected serum samples from persons who were ill, their household contacts, randomly selected residents, hospital workers, and various animals. Cases were classified as laboratory confirmed or probable. We identified 13 cases (4 confirmed, 9 probable) in Meherpur; 7 were in persons in two households. Patients were more likely than nonpatients to have close contact with other patients or have contact with a sick cow. In Naogaon, we identified 12 cases (4 confirmed, 8 probable); 7 were in persons clustered in 2 households. Two Pteropus bats had antibodies for Nipah virus. Samples from hospital workers were negative for Nipah virus antibodies. These outbreaks, the first since 1999, suggest that transmission may occur through close contact with other patients or from exposure to a common source. Surveillance and enhancement of diagnostic capacity to detect Nipah virus infection are recommended. (+info)Isolation and molecular identification of Nipah virus from pigs. (6/135)
Nipah viruses from pigs from a Malaysian 1998 outbreak were isolated and sequenced. At least two different Nipah virus strains, including a previously unreported strain, were identified. The findings highlight the possibility that the Malaysia outbreaks had two origins of Nipah virus infections. (+info)Invasion of the central nervous system in a porcine host by nipah virus. (7/135)
Nipah virus, a newly emerged zoonotic paramyxovirus, infects a number of species. Human infections were linked to direct contact with pigs, specifically with their body fluids. Clinical signs in human cases indicated primarily involvement of the central nervous system, while in pigs the respiratory system was considered the primary virus target, with only rare involvement of the central nervous system. Eleven 5-week-old piglets were infected intranasally, orally, and ocularly with 2.5 x 10(5) PFU of Nipah virus per animal and euthanized between 3 and 8 days postinoculation. Nipah virus caused neurological signs in two out of eleven inoculated pigs. The rest of the pigs remained clinically healthy. Virus was detected in the respiratory system (turbinates, nasopharynx, trachea, bronchus, and lung in titers up to 10(5.3) PFU/g) and in the lymphoreticular system (endothelial cells of blood and lymphatic vessels, submandibular and bronchiolar lymph nodes, tonsil, and spleen with titers up to 10(6) PFU/g). Virus presence was confirmed in the nervous system of both sick and apparently healthy animals (cranial nerves, trigeminal ganglion, brain, and cerebrospinal fluid, with titers up to 10(7.7) PFU/g of tissue). Nipah virus distribution was confirmed by immunohistochemistry. The study presents novel findings indicating that Nipah virus invaded the central nervous system of the porcine host via cranial nerves as well as by crossing the blood-brain barrier after initial virus replication in the upper respiratory tract. (+info)Novel innate immune functions for galectin-1: galectin-1 inhibits cell fusion by Nipah virus envelope glycoproteins and augments dendritic cell secretion of proinflammatory cytokines. (8/135)
Galectin-1 (gal-1), an endogenous lectin secreted by a variety of cell types, has pleiotropic immunomodulatory functions, including regulation of lymphocyte survival and cytokine secretion in autoimmune, transplant disease, and parasitic infection models. However, the role of gal-1 in viral infections is unknown. Nipah virus (NiV) is an emerging pathogen that causes severe, often fatal, febrile encephalitis. The primary targets of NiV are endothelial cells. NiV infection of endothelial cells results in cell-cell fusion and syncytia formation triggered by the fusion (F) and attachment (G) envelope glycoproteins of NiV that bear glycan structures recognized by gal-1. In the present study, we report that NiV envelope-mediated cell-cell fusion is blocked by gal-1. This inhibition is specific to the Paramyxoviridae family because gal-1 did not inhibit fusion triggered by envelope glycoproteins of other viruses, including two retroviruses and a pox virus, but inhibited fusion triggered by envelope glycoproteins of the related Hendra virus and another paramyxovirus. The physiologic dimeric form of gal-1 is required for fusion inhibition because a monomeric gal-1 mutant had no inhibitory effect on cell fusion. gal-1 binds to specific N-glycans on NiV glycoproteins and aberrantly oligomerizes NiV-F and NiV-G, indicating a mechanism for fusion inhibition. gal-1 also increases dendritic cell production of proinflammatory cytokines such as IL-6, known to be protective in the setting of other viral diseases such as Ebola infections. Thus, gal-1 may have direct antiviral effects and may also augment the innate immune response against this emerging pathogen. (+info)Henipavirus is a genus of the Paramyxoviridae family, which consists of enveloped, negative-sense, single-stranded RNA viruses. This genus includes two major species that are known to cause severe disease in humans: Nipah virus and Hendra virus. These viruses are primarily hosted by fruit bats (Pteropus spp.), but they can also infect other animals such as pigs, horses, and cats, and can be transmitted to humans through close contact with infected animals or their secretions. Henipaviruses are classified as biosafety level 4 agents due to their high mortality rate and potential for causing severe epidemics. Infection with these viruses can lead to a range of clinical symptoms, including fever, respiratory distress, and encephalitis, which can be fatal in some cases.
Henipavirus infections are caused by two paramyxoviruses, Hendra virus and Nipah virus. These viruses can cause severe illness in both humans and animals, particularly horses and pigs.
The natural hosts for these viruses are fruit bats (Pteropus spp.), also known as flying foxes. Transmission to humans can occur through direct contact with infected animals or their bodily fluids, consumption of contaminated food or drink, or through exposure to an environment contaminated with the virus.
Infection with Hendra virus can cause respiratory and neurological symptoms in humans, with a high fatality rate. Nipah virus infection can cause respiratory illness, fever, headache, dizziness, and altered consciousness, which can progress to encephalitis and coma. The case fatality rate for Nipah virus infection is estimated to be around 40-75%.
There are no specific treatments or vaccines available for henipavirus infections, and prevention efforts focus on reducing exposure to the viruses through public health measures such as avoiding contact with infected animals and their bodily fluids, practicing good hygiene and food safety, and implementing appropriate infection control practices.
Hendra virus (HeV) is an enveloped, negative-sense, single-stranded RNA virus that belongs to the genus Henipavirus in the family Paramyxoviridae. It was initially identified in 1994 during an outbreak of a mysterious disease affecting horses and humans in Hendra, a suburb of Brisbane, Australia. The natural host of this virus is the fruit bat (Pteropus spp.), also known as flying foxes.
HeV infection can cause severe respiratory and neurological diseases in various mammals, including horses, humans, and other domestic animals. Horses are considered the primary source of human infections, as they get infected after direct or indirect contact with body fluids (e.g., urine, saliva, or nasal discharge) from infected fruit bats. Human cases usually occur through close contact with infected horses or their bodily fluids during veterinary care, slaughtering, or other activities.
The incubation period in humans ranges from 5 to 16 days, followed by the onset of nonspecific influenza-like symptoms such as fever, cough, sore throat, and muscle pain. In severe cases, HeV can cause pneumonia, encephalitis, or both, with a high fatality rate (approximately 57%). No specific treatment or vaccine is currently available for humans; however, ribavirin has shown some efficacy in treating HeV infections in vitro and in animal models. Preventive measures include avoiding contact with infected horses and implementing strict biosecurity practices when handling potentially infected animals.
Nipah virus (NiV) is a zoonotic virus (it is transmitted from animals to humans) that causes severe illness in both humans and animals. It was first identified during an outbreak of disease in pigs and people in Malaysia and Singapore in 1998-1999.
The natural host of the virus are fruit bats of the Pteropodidae Family, Pteropus genus. Transmission to humans may occur through direct contact with infected bats or consumption of date palm sap contaminated by excretions or secretions from infected bats. Human-to-human transmission is also possible through close contact with people's secretions and excretions.
Infection with NiV can lead to a range of clinical presentations, from asymptomatic infection to acute respiratory illness and severe encephalitis (inflammation of the brain). The case fatality rate is estimated to be about 40-75% in humans. There is no vaccine available for either humans or animals. Prevention strategies include avoiding consumption of raw date palm sap, wearing protective clothing while handling infected animals or their contaminated materials, and practicing good hygiene.
Ephrin-B3 is a type of protein that belongs to the ephrin family and is involved in cell signaling, particularly during the development and functioning of the nervous system. It is a transmembrane protein, which means it spans the membrane of the cell and has a domain outside the cell and a domain inside the cell.
Ephrin-B3 interacts with Eph receptors on neighboring cells to initiate bidirectional signaling, which means that both the cells that express ephrin-B3 and the cells that express the Eph receptor are affected by this interaction. This signaling is important for various processes such as axon guidance, cell migration, and tissue boundaries formation during development. In addition, ephrin-B3 has been implicated in the regulation of synaptic plasticity and vascular remodeling in adults.
Mutations in the gene that encodes ephrin-B3 have been associated with certain neurological disorders, such as intellectual disability and epilepsy.
Chiroptera is the scientific order that includes all bat species. Bats are the only mammals capable of sustained flight, and they are distributed worldwide with the exception of extremely cold environments. They vary greatly in size, from the bumblebee bat, which weighs less than a penny, to the giant golden-crowned flying fox, which has a wingspan of up to 6 feet.
Bats play a crucial role in many ecosystems as pollinators and seed dispersers for plants, and they also help control insect populations. Some bat species are nocturnal and use echolocation to navigate and find food, while others are diurnal and rely on their vision. Their diet mainly consists of insects, fruits, nectar, and pollen, although a few species feed on blood or small vertebrates.
Unfortunately, many bat populations face significant threats due to habitat loss, disease, and wind turbine collisions, leading to declining numbers and increased conservation efforts.
Ephrin-B2 is a type of protein that belongs to the ephrin family and is primarily involved in the development and function of the nervous system. It is a membrane-bound ligand for Eph receptor tyrosine kinases, and their interactions play crucial roles in cell-cell communication during embryogenesis and adult tissue homeostasis.
Ephrin-B2 is specifically a glycosylphosphatidylinositol (GPI)-anchored protein that is expressed on the cell membrane of various cell types, including endothelial cells, neurons, and some immune cells. Its interactions with Eph receptors, which are transmembrane proteins, lead to bidirectional signaling across the contacting cell membranes. This process regulates various aspects of cell behavior, such as adhesion, migration, repulsion, and proliferation.
In the context of the cardiovascular system, ephrin-B2 is essential for the development and maintenance of blood vessels. It is involved in the formation of arterial-venous boundaries, vascular branching, and remodeling. Mutations or dysregulation of ephrin-B2 have been implicated in various diseases, including cancer, where it can contribute to tumor angiogenesis and metastasis.
Paramyxovirinae is a subfamily of viruses in the family Paramyxoviridae, order Mononegavirales. These viruses are enveloped, negative-sense, single-stranded RNA viruses that cause various diseases in animals and humans. The subfamily includes several important human pathogens such as:
1. Respiratory syncytial virus (RSV): A major cause of respiratory tract infections in infants, young children, and older adults.
2. Human metapneumovirus (HMPV): Another common cause of respiratory illness, particularly in children.
3. Parainfluenza viruses (PIVs): Responsible for upper and lower respiratory tract infections, including croup, bronchitis, and pneumonia.
4. Mumps virus: Causes the infectious disease mumps, characterized by swelling of the salivary glands.
5. Measles virus: A highly contagious virus that causes measles, a serious respiratory illness with characteristic rash.
6. Hendra virus and Nipah virus: Zoonotic viruses that can cause severe respiratory and neurological diseases in humans and animals.
These viruses share common structural and genetic features, such as an enveloped virion with a helical nucleocapsid, and a genome consisting of non-segmented, negative-sense single-stranded RNA. They also utilize similar replication strategies and have related gene arrangements.
Rubulavirus infections refer to a group of viral illnesses caused by members of the Rubulavirus genus, which is part of the Paramyxoviridae family. The most well-known rubulavirus is the mumps virus, which causes mumps, a contagious disease characterized by swelling of the salivary glands, fever, and pain while chewing or swallowing. Other rubulaviruses include parainfluenza viruses 1 and 3, which can cause respiratory illnesses such as bronchitis and pneumonia. Rubulavirus infections are typically spread through respiratory droplets or direct contact with infected individuals. Vaccination is available for some rubulavirus infections, such as mumps.