Pasteurellosis

Fowl cholera is caused by Pasteurella multocida, an acute fatal septicemia in chickens and turkeys. P. multocida vaccines include bacterins adjuvanted with aluminum hydroxide or oil emulsions, or they may contain attenuated live organisms. Multivalent Pasteurella vaccines usually contain the commonest serotypes 1, 3, and 4. The inactivated vaccines are usually given by injection. The attenuated live vaccines (M9 or PM-1 strains) may be given by the wing web or in drinking water. Protection develops in about two weeks.

Mycoplasmosis

These diseases are caused by several pathogenic Mycoplasmas. The most important are Mycoplasma gallisepticum (MG) and Mycoplasma synoviae (MS). MG causes chronic respiratory disease, whereas MS causes respiratory disease or synovitis. It is generally best to maintain mycoplasma-free flocks, but inactivated, attenuated live and fowlpox-vectored vaccines are available for use in countries where vaccination is permitted. The use of these vaccines is prohibited in some states. Vaccines should only be used in flocks with birds of all ages and where infection is considered inevitable.

Infectious coryza

This is an acute respiratory disease of chickens caused by Avibacterium paragallinarum. It is characterized by nasal discharge, sneezing, conjunctivitis, diarrhea, and facial swelling. Affected hens show a significant drop in egg production. Coryza may be complicated by the simultaneous presence of many other bacteria in addition to infectious bronchitis virus. There are three serovars of A. paragallinarum (A, B, and C). These are not cross-protective so it is essential that any vaccines contain the appropriate serovar for that population of birds. Commercial bacterins are available in the United States and other countries. These generally contain all three serovars. Some vaccines produced by large manufacturers are marketed internationally and contain the most prevalent bacterial strains. However, there are concerns that these may not provide protection against more localized variants.

Colibacillosis

Colibacillosis is caused by avian pathogenic Escherichia coli. This commonly starts as a respiratory infection and eventually leads to colisepticemia, sickness, deaths, and carcass condemnation. Colibacillosis is a leading cause of economic loss in the poultry industry. Vaccination is an obvious solution to this problem and many different inactivated and live vaccines have been developed. However, at the present time there is only a live attenuated vaccine available in the United States. The vaccine contains an aroA-deleted mutant designed for coarse spray or drinking water administration.

Salmonellosis

Salmonellae present the poultry farmer with two potential problems. One is the fact that they may kill large numbers of birds. The other is that they may cause human food poisoning caused by the contamination of eggs and poultry meat with Salmonella enterica serotype Enteritidis. This is of major concern to the poultry industry for both legal and financial reasons. In Europe, for example, 10% to 15% of poultry meat at the retail level may be Salmonella positive. Young chickens may be infected by both vertical and horizontal transfer and they probably acquire the infection soon after hatching. Once established in the intestine, the Salmonellae can prevent colonization by other serovars.

Marek’s disease

Marek’s disease virus (MDV) is a member of the genus Mardivirus, an alphaherpesvirus. It causes a lymphoproliferative and neuropathic disease that affects the nerves, viscera, muscle, and skin of chickens. It is also immunosuppressive. As with other herpesviruses, chickens may become persistently infected without showing any clinical signs. There are three species of MDV: Gallid herpes virus 2 (serotype 1), Gallid herpesvirus 3 (serotype 2), and Meleagrid herpesvirus 1 (serotype 3, also called herpesvirus of turkeys, HVT). Serotype 1 includes all the virulent poultry strains and some attenuated vaccine strains.

Marek’s disease is primarily controlled by vaccination either in ovo at day 18, or by subcutaneous injection at day of hatch. The need for vaccination against MDV has a significant economic impact on the poultry industry.

Bivalent vaccines containing serotypes 1 and 3 or trivalent vaccines containing serotypes 1, 2, and 3 are used. These vaccines contain live virus and although they prevent tumor production they do not generate sterilizing immunity. Vaccinated chickens still get infected and can shed virulent field virus. It is suggested that this has resulted in the increased virulence of field strains of the virus.

Several different modified live virus vaccines are available to control Marek’s disease. Turkey herpesvirus (HVT or MDV-3) is an avirulent virus that can effectively protect chickens against MDV. Strain FC126 of HVT is the most widely used MDV vaccine and commonly given to broilers as a monovalent vaccine and as a polyvalent vaccine in breeders and layers. Serotypes 1 and 2, and HVT are highly cell-associated and must be stored frozen in liquid nitrogen. Thus they must be carefully stored and thawed before use. This includes the use of safety glasses and gloves when removing the vaccine vials from the liquid nitrogen tank. The thawed vaccine is diluted appropriately and mixed well before use. Cell-free vaccines are available in some countries. These are less immunogenic but easier to store.

HVT has an excellent safety record and like other herpesviruses is persistent. Immunity to HTV is not inhibited by maternal antibodies if given on the day of hatch or in ovo. It can also be used as a vector virus for recombinant vaccines against infectious laryngotracheitis, Newcastle disease, infectious bronchitis, avian influenza, and bursal disease. These recombinants are very effective in protecting against systemic disease, but immunity to mucosal infections such as NDV is inconsistent.

MDV-2 strain is another naturally occurring avirulent strain of MDV used in vaccines. It only provides limited protection but it may be used in combination with other strains. There are situations in which HVT alone and MDV-2 alone cannot protect against very virulent strains. However, a combination vaccine containing both HVT and MDV-2 may show a synergistic effect.

Attenuated MDV-1 vaccines have also been generated by serial cell culture passage. Strain CVI988 or Rispens is considered the most efficacious current vaccine (Dr B.H. Rispens was the first to isolate strain CVI 988 in 1972). It was attenuated by serial passage in chicken kidney cells. This vaccine has some residual virulence in susceptible chickens and can spread between birds. It is predominantly used for in ovo vaccination. Higher passage variants are less virulent but also less immunogenic. CVI988 is the vaccine strain of choice against very virulent strains of MDV.

Newcastle disease

The incubation period of NDV lasts from three to six days. Clinical signs are nonspecific, namely depression, ruffled feathers, anorexia, hypothermia, and death. Some birds may develop neurologic disease with torticollis, ataxia, and paralysis. Viscerotropic velogenic ND is the most severe form of the disease resulting in the development of diphtheritic and necrotic, or hemorrhagic lesions along the gastrointestinal tract.

Class II NDVs vary greatly in their virulence for chickens. They are classified as velogenic—rapidly lethal; mesogenic—intermediate; and lentogenic—relatively low virulence, based on their lethality for chick embryos. For example, class II, genotype II strains are so lentogenic that some, such as Hitchner B1 and LaSota, can be used in modified live vaccines.

Because all the strains of NDV belong to a single serotype, proper vaccination should protect against all of them. Immunity is mainly derived from neutralizing antibodies against their hemagglutinin (H) and the fusion (F) glycoproteins. However, cell-mediated immune responses also reduce viral shedding, presumably by killing virus-infected cells. Sterilizing immunity is not achieved with current NDV vaccines. Vaccines prevent clinical disease and mortality, and they may reduce virus shedding and increase the dose of virus needed to infect a bird. Flock immunity is another positive outcome of vaccination although it is estimated that this will only have an impact when greater than 85% of the flock have hemagglutination inhibition titers greater than 8 after two doses of vaccine.

Inactivated vaccines are given by the intramuscular or subcutaneous routes. They are often given to layers or breeders to provide persistent high antibody levels that can be transferred to their chicks. They are usually inactivated with formaldehyde or beta-propiolactone and adjuvanted by emulsification in mineral or vegetable oil. Because birds have to be handled individually, these vaccines are more expensive than the MLV vaccines. Permissible withdrawal times between vaccination and slaughter must also be taken into consideration because of the persistence of vaccine antigen. This may be 21 or 42 days depending upon the vaccine.

Modified live lentogenic or mesogenic strains are used in MLV-NDV vaccines. The live vaccines are usually grown in embryonated chicken eggs or in tissue culture. Lentogenic strains used in these vaccines include B1, C2, LaSota, V4, NDW I2, and mesogenic strains used include Roakin, Mukteswar, and Komarov. The mesogenic vaccines cause mild disease so they are generally used in countries where Newcastle disease is endemic. In countries largely free of ND only lentogenic strains are permitted. These live vaccines are given in drinking water, by coarse sprayer, or by intranasal or intraocular administration. A lentogenic strain is also available for in ovo use. Some mesogenic strains may be given by wing web inoculation.

The severity of vaccine reactions depends on the strain of the virus employed. For example, of the two major vaccine strains of Newcastle disease, the LaSota strain is a good immunogen but may provoke mild adverse reactions. In contrast, the B1 strain is considerably milder but is less immunogenic, especially if given in drinking water. Where disease risks are high, live LaSota vaccine can be given in the drinking water or as a spray at 5 to 6 weeks, followed by another dose at 10 weeks, and an inactivated vaccine at point of lay. It is also important to bleed and test samples of bird sera after vaccination to ensure that they develop protective antibodies.

Recombinant vectored NDV vaccines using turkey herpesvirus or fowlpox vectors incorporating the hemagglutinin gene or the F gene, or both, are also available. Some of these may be appropriate for in ovo vaccination. NDV itself may also be used as a vector for other vaccines such as those against IBD or avian influenza.

Infectious bursal disease

Also called Gumboro disease, the causal agent of IBD is an avibirnavirus.

It infects multiple bird species, but causes clinical disease only in chickens less than 10 weeks of age. The virus destroys B cells within the Bursa of Fabricius resulting in bursal atrophy and subsequent suppression of the antibody responses. This immunodeficiency will result in a poor response to other vaccines and overwhelming secondary infections. There are two serotypes of IBDV but severe bursal disease is only associated with serotype 1. All commercial vaccines are directed against this serotype. There are no reports of clinical disease caused by serotype 2. As with all RNA viruses, IBDV is rapidly evolving and as a result there is much variation in antigenicity and virulence, features that complicate vaccine development.

Many different types of IBD vaccine are available, both monovalent and in combinations. These include live attenuated vaccines, inactivated oil-adjuvanted vaccines, live recombinant vaccines, or even immune-complex vaccines. Because this disease affects very young chicks it is important to exploit maternal immunity by vaccinating hens.

The inactivated vaccines are water-in-oil adjuvanted products. They are mainly used to induce long-term immunity in breeding stock. They are safe to use in young valuable birds with maternal antibodies. They are best used in birds at 16 to 20 weeks that have been primed by live vaccines at 8 weeks of age.

The viral structural protein 2 (VP2) is the major protective antigen in IBVD. This antigen can be expressed in different vector systems such as E. coli, yeast, fowlpox virus, baculovirus, and in plants. Commercially available VP2 recombinant vaccines include those from E. coli, the yeast Pischia pastoris, and baculovirus systems. They are not highly immunogenic and have to be boosted repeatedly. Given that these birds develop antibodies against only VP2, these have the potential to be DIVA vaccines.

Modified live vaccines have been attenuated by serial passage in tissue culture or eggs. Depending on their degree of attenuation, live attenuated IBDV vaccines may be classified as mild, intermediate, or invasive based on their ability to replicate and cause bursal lesions. This also reflects their ability to overcome maternal immunity. Mild vaccines are used to prime broiler breeders before boosting with an inactivated vaccine. If chicks have maternally-derived antibodies, then vaccination should be delayed until this has waned. The mild vaccines show poor efficacy in the presence of maternal antibodies or against very virulent strains of IBDV. The intermediate or hot strains are more immunogenic but may induce bursal lesions. The vaccine is usually given in a spray or in drinking water.

Recombinant vectored vaccines use the herpesvirus of turkeys to express the VP2 antigen of IBDV. As a result, they can be used in a DIVA strategy because they only induce antibodies against VP2 in contrast to whole virus vaccines that induce antibodies against all IBDV proteins. They are designed so that they can be injected either into 18-day eggs or into 1-day-old hatchlings, where they are not inhibited by maternal antibodies.

Infectious bronchitis

Infectious bronchitis is an economically significant respiratory disease of chickens that also causes nephritis, decreased egg production, poor growth, and high morbidity. It is caused by a gammacorona virus, avian infectious bronchitis virus (IBV). The combination of high morbidity, and loss of performance, together with secondary bacterial infections can lead to unsustainable losses. As a result, almost all commercial poultry are vaccinated against this virus. However, the ability to control or prevent infectious bronchitis outbreaks is rendered very difficult by the continuous emergence of new IBV genotypes, serotypes, and variants as a result of mutation and recombination. Over 50 serotypes and hundreds of variants have been identified and more continue to emerge. These variants arise as a result of sequence changes in a hypervariable region of the viral spike (S) glycoprotein. There is also a lack of cross-protection among these genotypes. Thus as variants appear and disappear, they necessitate the continual development of new vaccines. Both inactivated and live attenuated IBV vaccines are available. Currently most of these vaccines contain the Massachusetts strain either alone or in combination with the Arkansas, Connecticut, Georgia, Huyben (Holland), or Delaware strains. They are usually given in combination with Newcastle disease vaccines.

Inactivated vaccines may be used alone or in combination with modified live virus (MLV) vaccines in layer/breeder flocks to induce maternal immunity and thus protect chicks from an early age. As we have seen with other diseases, the inactivated vaccines induce a relatively weak immune response without cell-mediated immunity, and thus require multiple doses and the use of adjuvants. These in turn increase handling costs and may cause significant injection site lesions.

Infectious laryngotracheitis

An economically important respiratory disease caused by gallid herpesvirus 1, ILT affects chickens, peafowl, pheasants, and partridges. The principle lesion is tracheitis and the disease can vary in severity from lethal asphyxiation to very mild or subclinical infection. As with other herpesviruses, infected birds may become healthy carriers. The disease is usually prevented by the use of either live attenuated vaccines or recombinant vectored vaccines.

Modified live vaccine viruses have been attenuated either by prolonged passage in tissue culture or by passage in embryonated chicken eggs. The MLV vaccine may then be administered by spray, eye drops, or in the drinking water. Residual virulence may be an issue with some of these vaccines especially when delivered by spray vaccination. Reversion to virulence may also be an issue. Some recent ILT outbreaks have been attributed to egg adapted vaccines that have regained virulence. The chicken embryo passaged vaccine is the most widely used ILT vaccine. It induces rapid immunity and is easily administered through drinking water. In general, long-lived birds are routinely vaccinated against ILT, but short-lived birds such as broilers are only vaccinated if an outbreak is threatened

As a result of residual virulence in modified live vaccines, efforts have been made to generate safer vaccines by developing viral vectored vaccines. These recombinant ILT vaccines contain either herpesvirus of turkeys (Marek’s serotype 3), or fowlpox virus expressing one or more of the ILT glycoproteins. The fowlpox-vectored vaccine expresses the glycoprotein B and UL32 genes. It may be given in ovo or by wing web puncture to one-day-old commercial layers. There are two HVT vectored vaccines, one expressing glycoproteins I and D, the other expressing glycoprotein B. They induce protective immunity against both ILT and Marek’s disease. They are not transmitted between birds and do not revert to virulence. They are also administered by subcutaneous vaccination to one-day-old chicks or in ovo. They are not as protective as the attenuated vaccines and are less able to prevent shedding.

Avian reoviruses

Avian reoviruses belong to the genus Orthoreoviruses in the Reoviridae family. They cause arthritis/tenosynovitis, proventriculitis, a runting-stunting syndrome, and “blue-wing disease” in broilers. Because these diseases affect very young birds, reovirus vaccines are often administered to breeding hens to stimulate maternal immunity and protect the newly hatched chicks. Both inactivated and modified live vaccines are available.

The inactivated oil-emulsion adjuvanted vaccines may contain multiple strains and different pathotypes. They are used in replacement and breeder hens and are often used in combination with NDV, Marek’s or bronchitis vaccines.

Live vaccines may contain the avirulent 2177 or 1133 strains. Some are given subcutaneously to one-day-old chicks. Others are given in drinking water to birds between 10 and 17 weeks of age. Over the past six years there has been a gradual increase in the number of disease outbreaks in vaccinated flocks. This is a result of changes in the circulating strains of the viruses, and so new, updated vaccines are needed.

Avian influenza

In the United States, the USDA has established the National Veterinary Stockpile in case a decision has to be made regarding avian influenza vaccination. The stockpiled vaccines are primarily inactivated vaccines but a DNA-plasmid vaccine has also been conditionally licensed. If a decision to vaccinate is made, domestic distribution and use will be supervised and controlled by USDA veterinary services as part of an official USDA program. Vaccination may be used in control programs for both HPAI and LPAI. The recent emergence of pandemic influenza A strains such as H7N9 and H5N1, reveals the tremendous challenges to our current influenza control strategies. Better vaccines that provide protection against a wide spectrum of influenza viruses and long-lasting immunity are urgently needed.

Over 95% of all avian influenza virus (AIV) vaccines used in poultry are inactivated, adjuvanted products given by injection. Vaccines containing mineral or vegetable oil based adjuvants generally induce the highest antibody titers. These vaccines are prepared from infectious allantoic fluid that is inactivated with beta-propiolactone or formaldehyde.

Inactivated influenza A vaccines have been used in turkeys in the United States against LPAI and non-H5/H7 influenza A viruses. A vaccine against H1 and H3 swine influenza viruses has also been used in breeder turkeys. Vaccines against H9N2, H7N3, H5N2, H5N1, have been used extensively in Asia in response to specific disease outbreaks.

Advances in molecular biology have allowed Marek’s disease (HVT) vectored vaccines, expressing the influenza virus hemagglutinin (HA), to be sold commercially. As a group, these vectored vaccines can stimulate both cellular and humoral immunity and are effective at preventing clinical disease and reducing virus shedding. All the licensed recombinant vaccines, because they only express the HA, may be used to differentiate vaccinated from infected birds. The vectored vaccines also work well with a prime-boost strategy where the vectored vaccine is given first and birds are revaccinated with a killed adjuvanted vaccine two or three weeks later. The use of a killed vaccine with a homologous hemagglutinin and a heterologous neuraminidase may allow the serologic differentiation of vaccinated and infected birds.

A recombinant fowlpox influenza vaccine (TROVAC-AIV H5) expressing the hemagglutinin of avian influenza H5 has been licensed for use in Mexico, Guatemala, and El Salvador where it is widely employed. It can be administered to one-day-old chicks and serologic tests can readily distinguish vaccinated from naturally infected birds.

Fowlpox

Avian encephalomyelitis

The cause of epidemic tremor, avian encephalomyelitis virus is a picornavirus that affects the central nervous system. In young chickens it induces paralysis, ataxia, and muscular dystrophy. In older chickens, infection is usually subclinical but causes a decline in egg production and hatchability. Several modified live vaccines are available. Some may be combined with fowlpox. Most are administered by wing web vaccination using a double needle applicator. Breeder chickens are vaccinated at 10 to 16 weeks of age, at least 4 weeks before start of lay. The site of inoculation should be examined for “take” at 7 to 10 days postvaccination. A positive take is indicated by a swelling or scab at the site of inoculation. If given to laying flocks this vaccine can cause a serious drop in egg production.

Egg drop syndrome

Egg drop syndrome (EDS) is caused by an adenovirus infection in laying hens. It is characterized by production of soft-shelled and shell-less eggs and also a 10% to 40% drop in egg production. An inactivated vaccine containing EDS’76 virus strain BC14 in a water-in-oil emulsion may be available. It should be administered intramuscularly to layers and breeders no later than 4 weeks before the expected onset of lay.

Coccidiosis

Infection with Eimeria coccidia induces a strong, species-specific protective immunity. As a result, several live coccidial vaccines are used in commercial poultry. These vaccines typically contain live sporulated oocysts from multiple Eimeria species and strains. Some consist of virulent, drug-sensitive organisms administered repeatedly in very low doses of oocysts (trickle infection). Some of these organisms have been attenuated by repeated passage through eggs, but this only works well for Eimeria tenella. Other Eimeria species have been selected for precocity. Precocious strains mature very rapidly (30 hours faster than the parent strain), and, as a result, have less time to replicate, produce fewer oocysts, are less virulent because they cause less tissue damage, yet are highly immunogenic. This precociousness is a stable trait and the parasites do not regain virulence. All of these vaccines provide solid immunity to coccidia when applied carefully under good conditions. Nevertheless, the dose of coccidia vaccine must be carefully controlled, and the vaccines must be harvested from the feces of infected birds. Vaccinated birds shed oocysts that are transmitted to other birds. Because of regional strain variation, vaccination may not be effective in protecting against field strains in all locations.

A transmission blocking subunit vaccine has been developed that contains two purified glycoproteins (Gam56 and Gam82) from the wall-forming bodies of macrogametocytes of Eimeria maxima. It is believed that the antibodies produced inhibit oocyst wall formation. This vaccine (CoxAbic, Netanya, Israel) is administered by injection with an oil-in-water adjuvant. It is given to breeder hens twice before the breeding season to provide maternal immunity to their chicks.