Virulent Newcastle disease
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|Avian orthoavulavirus 1|
|Avian orthoavulavirus 1 (stained in brown) in the conjunctiva of a chicken|
Avian orthoavulavirus 1
Virulent Newcastle disease (VND), formerly exotic Newcastle disease, is a contagious viral avian disease affecting many domestic and wild bird species; it is transmissible to humans. Though there are rare cases where the disease gives a mild fever and/or conjunctivitis. Its effects are most notable in domestic poultry due to their high susceptibility and the potential for severe impacts of an epizootic on the poultry industries. It is endemic to many countries.
Exposure of humans to infected birds (for example in poultry processing plants) can cause mild conjunctivitis and influenza-like symptoms, but the Newcastle disease virus (NDV) otherwise poses no hazard to human health. No treatment for NDV is known, but the use of prophylactic vaccines and sanitary measures reduces the likelihood of outbreaks.
Newcastle disease was first identified in Java, Indonesia, in 1926, and in Newcastle-upon-Tyne, England, in 1927. However, it may have been prevalent as early as 1898, when a disease wiped out all the domestic fowl in northwest Scotland.
The policy of slaughter ceased in England and Wales on 31 March 1963, except for the peracute form of Newcastle disease and for fowl plague. In Scotland the slaughter policy continued for all types of fowl pest.
Since May 2018, California Department of Food and Agriculture staff and the United States Department of Agriculture have been working on eliminating VND in South California and more than 400 birds have been confirmed to have VND. On February 27, 2019, California State Veterinarian, Dr. Annette Jones, increased the quarantine area in Southern California and on March 15, 2019 and April 5, 2019, cases of VND in Northern California and Arizona respectively.
The causal agent, Newcastle disease virus (NDV), is a variant of avian orthoavulavirus 1, a negative-sense, single-stranded RNA virus. NDV belongs to the subfamily Avulavirinae, which infect birds. Transmission occurs by exposure to faecal and other excretions from infected birds, and through contact with contaminated food, water, equipment, and clothing.
NDV strains can be categorised as velogenic (highly virulent), mesogenic (intermediate virulence), or lentogenic (nonvirulent). Velogenic strains produce severe nervous and respiratory signs, spread rapidly, and cause up to 90% mortality. Mesogenic strains cause coughing, affect egg quality and production, and result in up to 10% mortality. Lentogenic strains produce mild signs with negligible mortality.
Use as an anticancer agent
In 1999, promising results were reported using an attenuated strain of the Newcastle virus, code named MTH-68, in cancer patients by researchers who had isolated the strain in 1968. It appears the virus preferentially targets and replicates in certain types of tumor cells, leaving normal cells almost unaffected. In 2006, researchers from the Hebrew University also succeeded in isolating a variant of the NDV, code named NDV-HUJ, which showed promising results in 14 glioblastoma multiforme patients. In 2011, researchers at the Memorial Sloan–Kettering Cancer Center and the Icahn School of Medicine at Mount Sinai found that NDV modified with the viral protein NS1 had enhanced replication in cancer cell lines overexpressing the antiapoptotic factor Bcl-xL. The researchers suggested in cells that resist the normal inducement of apoptosis when infected will give NDV more time to incubate in cell and spread. Many cancer cells will overexpress antiapoptotic factors as part of tumor development. This mechanism of delaying apoptosis in abnormal cells gives NDV the specificity it needs to be an efficient cancer-fighting oncolytic virus.
History of NDV in cancer therapy
Though the oncolytic effect of NDV was documented already in the 1950s, the main advances of viruses in cancer therapy came with the advent of reverse genetics technologies  With these new possibilities, studies of modified NDV strains with enhanced cancer-treatment properties have been put on the agenda. A study demonstrated the engineered Hitcher B1 NDV/F3aa strain could be modified to express a highly fusogenic F-protein in combination with immunostimulatory molecules such as IFN-gamma, interleukin 2, or tumor necrosis factor alpha. Promising results were discovered with proteins associated to the adaptive immune system, which paved the way for possibilities to use NDV to create a tumor-associated antigen. Another study showed how NDV/F3aa could be modified to express NS1, an influenza virus protein with capability to modulate with the innate immune response, for example, by suppressing the induction of the cellular interferons.
NDV pros and cons in cancer therapy
NDV possesses many unique anticancer properties and thereby provides an excellent base in virotherapy research. NDV has selectivity on oncogenic cells, where it replicates without, or in a less pronounced way, harming normal cells. It binds, fuses into and replicates within the infected cells’ cytoplasm independent of cell proliferation. One of the main issues using NDV treatment is the host/patient immune response against the virus itself, which prior to the time of the reverse genetics technology, decreased the applicability of NDV as a cancer treatment.
NDV-induced mechanisms leading to tumor cell death
The precise way in which the presence of NDV induces tumor cell death remains to be clarified and may show variation regarding the strains of NDV used and which type of cancer is targeted. NDV triggers apoptosis in a wide range of cancer cell types via the mitochondrial/intrinsic pathway, through loss of membrane potential and thereby inducing release of cytochrome c in the tumor cell. The results also indicate the extrinsic pathway is activated by TNF-related, apoptosis-inducing ligand-induced, NDV-mediated apoptosis in a late stage. Another study found a hyperfusogenic NDV/F3aa(L289A) with refined abilities to fuse into somatic cells. NDV has aggregating properties causing syncytia formations of tumor cells, which, apart from amplifying immune-based cell killing, also results in necrosis of cells. This pathway was believed to lead to a considerable boost of immune activation and potentially an antitumor response, which was supported by observations of a significant accumulation of NK-cells and neutrophils following the infusion of NDV/F3aa(L289A) in hepatocellular carcinoma cells. In addition, an increase of CD4+ and CD8+ T-cells occurs within the tumor cells when inducing NDV/F3aa recombined with the cytokine interleukin-2 (IL-2). An NDV/F3aa-IL-2 strain induced the immune system, giving a cytotoxic effect on the tumor cells. A 15-year study on patients with malignant melanoma showed increased numbers of oligoclonal CD8+ T-cells in the blood, suggesting vaccination with NDV oncolysates was associated with prolonged survival among the patients, and CD8+ T-cells played an important role. !
NDV is spread primarily through direct contact between healthy birds and the bodily discharges of infected birds. The disease is transmitted through infected birds' droppings and secretions from the nose, mouth, and eyes. NDV spreads rapidly among birds kept in confinement, such as commercially raised chickens.
High concentrations of the NDV are found in birds' bodily discharges; therefore, the disease can be spread easily by mechanical means. Virus-bearing material can be picked up on shoes and clothing and carried from an infected flock to a healthy one.
NDV can survive for several weeks in a warm and humid environment on birds' feathers, manure, and other materials. It can survive indefinitely in frozen material. However, the virus is destroyed rapidly by dehydration and by the ultraviolet rays in sunlight. Smuggled pet birds, especially Amazon parrots from Latin America, pose a great risk of introducing NDV into the US. Amazon parrots are carriers of the disease, but do not show symptoms, and are capable of shedding NDV for more than 400 days.
The incubation period for the disease ranges from 4 to 6 days. An infected bird may exhibit several signs, including respiratory signs (gasping, coughing), nervous signs (depression, inappetence, muscular tremors, drooping wings, twisting of head and neck, circling, complete paralysis), swelling of the tissues around the eyes and neck, greenish, watery diarrhea, misshapen, rough- or thin-shelled eggs and reduced egg production.
In acute cases, the death is very sudden, and, in the beginning of the outbreak, the remaining birds do not seem to be sick. In flocks with good immunity, however, the signs (respiratory and digestive) are mild and progressive, and are followed after 7 days by nervous symptoms, especially twisted heads.
For routine isolation of NDV from chickens, turkeys, and other birds, samples are obtained by swabbing the trachea and the cloaca. Cotton swabs can be used. The virus can also be isolated from the lungs, brain, spleen, liver, and kidneys.
Prior to shipping, samples should be stored at 4°C (refrigerator). Samples must be shipped in a padded envelope or box. Samples may be sent by regular mail, but overnight is recommended.
Any animals showing symptoms of Newcastle disease should be isolated immediately. New birds should also be vaccinated before being introduced to a flock. An inactivated viral vaccine is available, as well as various combination vaccines. A thermotolerant vaccine is available for controlling Newcastle disease in underdeveloped countries.
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|Wikimedia Commons has media related to Newcastle disease.|
- Current status of Newcastle disease worldwide at OIE. WAHID Interface - OIE World Animal Health Information Database
- Disease card
- Department of Environment, Food and Rural Affairs, UK
- Newcastle Disease, Iowa State University, Center for Food Security and Public Health
- Newcastle Disease in Poultry, Merck Veterinary Manual
- Species Profile—Virulent Newcastle Disease, National Invasive Species Information Center, United States National Agricultural Library. Lists general information and resources for Exotic Newcastle Disease.