Fowl Play in Bird Flu

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Fowl Play in Bird Flu

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Fri, 05 May 2006 17:01:11 +0100

 

 

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ISIS Press Release 05/05/06

 

Fowl Play in Bird Flu

 

**********************

 

 

There is no evidence that wild migrating birds mixing with

backyard flocks spreads bird flu Transnational factory farms

and the globalised trade in poultry products are to blame

 

Dr. Mae-Wan Ho

 

Sources for this report are available in the ISIS members

site. Full details are availble at

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Bird flu scare hurts the poultry industry

 

*******************************************

 

The European Union is set to approve special funding for

poultry farmers suffering from falling prices and demand as

the spread of the deadly H5N1 bird flu scares consumers away

from chicken, turkey and other fowl [1]. Some 320 000 tonnes

of unmarketable poultry meat are in cold storage across the

25 nation EU. Prices have fallen by 13 percent on average,

but some countries are harder hit than others. Consumption

of poultry products is down 5 percent in Denmark and

Finland, but as much as 40 percent in Cyprus, 50 percent in

Italy and 70 percent in Greece.

 

Germany has 70 000 tonnes of poultry products in storage,

and estimates its sector has suffered damage of around 150

million euros from falling demand and the cost of culling

birds. France with 40 000 tonnes in surplus stocks estimates

it loses 31.9 million euros a month.

 

Wild birds to blame?

 

********************

 

Bird flu is said to have spread from Asia to Europe in

migrating wild birds. The United Nations Food and

Agricultural Organisation (FAO) stated in November 2005 [2]:

" The movement of migratory birds has caused outbreaks to

emerge in several countries and regions simultaneously. "

 

The first infection of commercial stocks was found on a

French turkey farm in March 2006. The EU has ordered

commercial stocks to stay inside or be inoculated, and some

45 countries have issued full or partial bans on poultry

imports from France [1].

 

Meanwhile a fourth Afghan province, Kapisa, has been hit

[3]. The virus had been found already in samples from birds

in Kabul, Logar and Nangarhar provinces. There are strong

suspicions that two other provinces, Laghman and Parwan, are

also affected. Afghanistan is on the migration route for

several species of wild birds. Poultry have been culled and

quarantine measures introduced in affected areas.

 

Nineteen African nations held a five-day conference towards

the end of April 2006 to discuss how they should prepare for

a possible deadly outbreak of bird flu [4]. Nigeria, Niger,

Cameroon, Egypt and Burkina Faso are the five African

countries with confirmed H5N1 bird flu.

 

H5N1 has forced the slaughter of 200 million birds so far,

as the disease spread from Asia to Europe, Africa and the

Middle East. Late last year, thousands of migratory birds

mysteriously dropped dead in central Malawi, though tests

proved negative for H5N1. But the alarm has already hurt the

poultry industry in Malawi, with most importers cancelling

orders.

 

While scientists also say that wild birds are spreading the

deadly bird flu, there are strong dissenting voices. The

Royal Society for the Protection of Birds (RSPB), for

example, told the BBC that the trade in birds and the

movement of poultry products is a more likely cause [5].

Significantly, there are no migration routes that would take

birds from China to Turkey at this time of the year.

 

There is also little direct evidence that migratory birds

carry and transmit H5N1. FAO in collaboration with World

Health Organisation (WHO) had admitted in May 2005 [6], " To

date, extensive testing of clinically normal migratory birds

in the infected countries has not produced any positive

results for H5N1 so far. "

 

After testing hundreds of thousands of wild birds for the

disease, scientists have only rarely identified live birds

carrying the highly pathogenic H5N1. In a test of 13 000

wild birds in marshes within the bird flu infested provinces

of China, the H5N1 virus was found in only 6 ducks [7]. But

the scientists could not bring themselves to conclude that

wild migrating birds are probably not to blame: " Our data

show that H5N1 influenza virus, has continued to spread from

its established source in southern China to other regions

through transport of poultry and bird migration. "

 

The reality is that nearly all the wild birds that have

tested positive for the disease were dead, and in most

cases, found near to outbreaks in domestic poultry [8].

 

The WHO recently said that viruses from Turkey's first two

human cases were virtually identical to those that killed 6

000 migratory birds in a nature reserve, Qinghai, in central

China last year. But RSPB's conservation director Dr. Mark

Avery insists that the trade in wild birds and the movement

of poultry and poultry products, such as chicken manure used

to fertilize fish farms, has led directly to the transfer of

H5N1 across national boundaries [5].

 

" No species migrates from Qinghai, China, west to Eastern

Europe, " BirdLife's Dr. Richard Thomas said. " When plotted,

the pattern of outbreaks follows major road and rail routes,

not flyways [8].

 

 

 

Wild birds are the reservoir for influenza viruses

 

***************************************************

 

Wild fowl and shore birds are believed to form the reservoir

of influenza viruses of type A, (see Box) which cause

diseases in many other species, including humans, pigs,

horses, mink, cats, marine animals and a range of domestic

birds [9].

 

Influenza viruses

 

******************

 

There are 3 types of influenza viruses, A, B and C. The

influenza A virus genome consists of 8 segments of RNA

coding for 11 proteins, and they are further classified by

subtype on the basis of the two main surface glycoproteins

(proteins with complex carbohydrate side chains):

haemagglutinin (HA) and neuraminidase (NA). Only influenza A

viruses infect birds. Humans can be inflected with influenza

types, A, B and C viruses. Subtypes of influenza A currently

circulating among people worldwide include H1N1, H1N2, and

H3N2 [10].

 

Avian influenza A viruses of the subtypes H5 and H7,

including H5N1, H7N7 and H7N3 viruses have been associated

with high pathogenicity, and human infection with these

viruses has r anged from mild (H7N3, H7N7) to severe and

fatal disease (H7N7, H5N1).

 

Wild birds are the natural host for all known subtypes of

influenza A viruses. In wild birds and poultry throughout

the world, influenza A viruses representing 16 HA and 9 NA

subtypes have been detected in numerous combinations, such

as H1N1, H3N3, H16N3 and so on [9]. Typically wild birds do

not become sick when infected.

 

Domestic poultry such as turkeys and chickens can become

very sick and die from avian influenza, and some avian

influenza A viruses also can cause serious disease and death

in wild birds.

 

Avian influenza viruses are designated as low pathenogenic

(LPAI) when they do no cause disease or only mild disease,

and highly pathogenic (HPAI) when they do. The switch from

low to high pathogenicity is not fully understood.

 

The HA protein is synthesized as a single polypeptide

precursor, which is cleaved into HA 1 and HA 2 subunits by

proteases. The switch from low to highly pathogenic avian

virus appears to be associated with basic amino acid

residues introduced into the HA cleavage site, which makes

the protein easier to cleave and facilitates virus

replication.

 

In general, human infection with avian influenza viruses

occurs very infrequently, and has been associated with

direct contact with infected sick or dead domestic poultry.

At least part of the barrier preventing person-to-person

transmission is that the HA protein on the virus' coat must

bind to cell surface receptors in order to gain entry into

cells. This binding is specific for certain carbohydrate

side chains attached to the cell surface receptor proteins.

The HA of the avian virus recognizes carbohydrate side

chains that end in sialic acid linked to galactose in an a -

2,3 chemical bond, i.e., SA- a -2,3-gal, whereas the human

influenza virus HA recognizes an a -2,6 chemical bond: SA- a

-2,6-gal. The HA protein of H5N1 is typical of avian

viruses, which is why the virus cannot replicate

sufficiently in a human host for person-to-person

transmission to take place. However, many scientists believe

that once the H5N1 has mutated its HA to recognize SA- a -

2,6-gal, then human transmission would occur, and a global

pandemic would result

 

Influenza viruses evolve by small point mutations (antigenic

drift) or large changes due to reassortment (antigenic

shift), the mixing of genome segments from different

viruses.

 

Certain birds, particularly water birds, are thought to act

as hosts by carrying the virus in their intestines and

shedding it in saliva, nasal secretions and faeces. However,

the viruses circulating in wild birds are generally not the

highly pathogenic avian influenza (HPAI) strains that cause

deadly bird flu. They do not cause illness in the birds, and

are referred to as low pathogenic avian influenza (LPAI)

viruses. LPAI have been isolated from at least 105 wild bird

species of 26 different families. All subtypes have been

detected in the bird reservoir and in poultry, whereas

relatively few have been detected in other species. Ducks,

geese, swans, gulls, terns and waders are the major LPAI

virus reservoir, where the virus preferentially infects

cells lining the intestinal tract and is excreted in high

concentrations in their faeces. Influenza viruses remain

infectious in lake water for up to 4 days at 22C, and for

more than 30 days at 0C. Faecal to oral transmission is the

most frequent route for transmitting viruses, both of high

and low pathogenicity.

 

The species in which influenza viruses are endemic, such as

ducks, gulls and waders share the same habitat at least part

of the year with other species in which influenza viruses

are frequently detected, including geese, swans, rails,

petrels and cormorants.

 

Wild migrating birds mostly follow routes (flyways) that go

North-South, but some birds have breeding ranges that cross

the Atlantic, and the birds over-winter in the same

geographic area in the south. Migrating birds make frequent

stops en route where different species congregate,

increasing the chances of exchanging viruses among

themselves and distributing LPAI viruses between countries

and continents.

 

Since 1997, more than 16 outbreaks of H5 and H7 influenza

have occurred among poultry in the United States. Highly

pathogenic strains can cause 90 to 100 percent deaths in

poultry. So how do low pathogenic viruses become highly

pathogenic?

 

How highly pathogenic bird flu viruses are created

 

******************************************************

 

The influenza A virus genome is in eight separate segments.

The segmented genome allows the viruses from different

species to mix and exchange segments to create new influenza

viruses. A pig infected with a human virus and a bird virus

at the same time would allow the two viruses to exchange

segments to create a new virus that retained most of the

genes of the human virus but had the avian haemagglutinin

and/or neuraminidase gene(s). The resulting new virus might

be able to infect humans and spread from person to person

(see Box). If this new virus causes serious illness in

humans, then a pandemic would result. This g ene exchange

could even take place in a human infected at the same time

with human and avian flu viruses.

 

In 1997, an HPAI outbreak caused by H5N1 occurred in chicken

farms and live bird markets in Hong Kong. This resulted in

the first reported case of human influenza and death

attributable directly to avian influenza virus. The H5N1

HPAI virus reappeared in 2002 in waterfowl at two parks in

Hong Kong and was also detected in other captive and wild

birds. It resurfaced again in 2003 and devastated the

poultry industry in large parts of Southeast Asia since

2004. In 2005, the virus was isolated during an outbreak

among migratory birds in Qinghai Lake, China, affecting

large numbers of wild birds. This wiped out an estimated 10

percent of the global population of Bar-headed Geese.

Subsequently, the virus reappeared across Asia, Europe and

the Middle East, and in several African countries. Wild bird

deaths have been reported in several of these countries in

Europe, particularly affecting Mute Swans and Whooping

Swans, but also other waterfowl species, and occasionally in

raptors, gulls and herons. So far it has caused mortality in

more than 60 wild bird species [9].

 

But do wild migratory bird carry and spread HPAI as has been

claimed, or are they just the victims of the deadly bird flu

viruses that emerge in domestic fowl?

 

Genetic analysis provide no evidence that wild birds are to

blame

 

**************************************************************

 

Genetic analysis of avian influenza viruses in the public

databases, based on the matrix protein gene M, reveals that

the viruses can be divided into two distinct lineages [9],

Eurasian and American, reflecting the long-term ecological

and geographical separations of the hosts. Both lineages are

also quite separate from human influenza viruses. The H5N1

highly pathogenic influenza viruses form a lineage derived

from the Eurasian lineage.

 

The genetic separation between Eurasian and North American

avian flu viruses is a bit surprising, as the bird fauna of

North America and Eurasia are not absolutely isolated from

each other. Some ducks and shore birds cross the Bering

Strait during migration or have breeding ranges that include

both the Russian Far East and Northwestern North America.

 

There are also other aspects of the virus that would appear

to encourage genetic exchange between the two groups of

avian flu viruses when the host birds meet up, such as the

reassortment of viral genome segments (see above). Apart

from that, the usual process of recombination (exchange of

parts of genome segments) could also occur.

 

Not only do the avian flu viruses of Eurasia and North

America form distinct lineages, the gulls in Eurasia and

North America also each have their own distinct lineage of

viruses. The evidence suggests that there are strong

interspecific barriers to gene exchange, and it is not easy

for viruses to jump species, and that complex adaptations

are needed to achieve sustained transmission of the virus in

a new species [11] (see " What can you believe about the bird

flu pandemic? " this series).

 

The fact remains that HPAI viruses such as H5N1 are not

endemic in wild birds as they are in domestic poultry, and

when wild birds do contract the HPAI viruses, they succumb

in large numbers, and are in no state to further transmit

the disease along their usual migration routes .

 

As the researchers conclude [9]: " For the H5N1 virus, it is

without doubt that domestic waterfowl, specific farming

practices, and agroecological environments played a key role

in the occurrence, maintenance, and spread of HPAI for many

affected countries… Although numerous wild birds have also

become infected, it has been much debated whether they play

an active role in the geographic spread of the disease… "

 

Fowl play in deadly bird flu

 

********************************

 

Wild birds are not the only victims of bird flu; the other

victims are small farmers and ordinary people who keep

domestic fowl in their backyard to supplement their income

or diet.

 

In response to the spread of bird flu, governments around

the world are destroying backyard flocks and making indoor

confinement of poultry mandatory [8, 12]. So far, 16

countries in Europe, Asia and Africa have imposed bans or

restrictions on outdoors poultry farming. Forced confinement

of poultry threatens the livelihood and food security of

small- scale farmers and poor families in countries affected

by bird flu. In Southeast Asia, governments, supported by

the FAO, are encouraging framers to set up mesh screens or

bamboo enclosures for their poultry. The costs, estimated at

US$50-70, are simply beyond the means of Asia's small

farmers, and are forcing them to abandon poultry altogether

[8]. Forced confinement also threatens certified organic

poultry operations, grass-fed pastured poultry and free-

range egg production [12].

 

Quebec in Canada has imposed strict rules that require all

farmers to keep poultry indoors and to keep wild birds out;

despite the fact that the Canadian Cooperative Wildlife

Health Centre survey of wild birds has found no incidence of

HPAI in Canada [13].

 

Factory farms and globalised poultry trade are to blame

 

********************************************************

 

There is growing evidence that HPAI originates in factory

farms and is spread not by migrating wild birds so much as

by the globalised poultry trade. In low-density backyard

flocks, a high pathogenic bird flu virus will simply kill

all the birds quickly without infecting other birds. In a

factory farm with a high density of birds, however, the

virus can spread and multiply rapidly throughout the huge

confined flock, and beyond that, via the global trade in

live birds, eggs, virus-contaminated feed and manure, across

country borders and across continents.

 

There is indeed strong correlation between exposure to

factory farms and incidence of HPAI. Thailand, China and

Vietnam, all have a highly developed poultry industry that

has expanded dramatically. Production of chicken meat in

Southeast Asia - Thailand, Indonesia and Vietnam – jumped

from around 300 000 tonnes in 1971 to 2 440 000 tonnes in

2001 [8]. China's production of chicken tripled during the

1990s to over 9 million tonnes a year. Practically all the

new poultry production has happened on factory farms outside

major cities and is integrated into the transnational

production system. Live birds and eggs are exported to

countries such as Nigeria (where the first HAI outbreak in

Africa occurred), as well as `feed' which often includes

litter (i.e., manure) in the ingredients. Nigeria has a

large and poorly regulated factory poultry sector that is

supplied with chicks from factory farms in China [14]

 

Manure that may contain live virus is spread on surrounding

farmland, or exported as fertilizer and through run-off, may

end up in surface waters where wild birds feed and rest.

Chicken manure is even found in fish farm feed formulations

where it is introduced directly into the aquatic

environment.

 

Wild birds and poultry that have fallen victim to HPAI in

Asia, Turkey and Nigeria appear to have been directly

exposed to HPAI virus originating in the factory farm

system.

 

In Asia, a flock of wild ducks died from HPAI after having

come into contact with the disease at a remote lake where a

fish farm used feed pellets made from poultry litter from a

factory farm [8]. In Turkey, a massive cull of backyard

flocks – and the deaths of three children – took place after

a nearby factory farm sold sick and dying birds to local

peasants at cut-rate prices.

 

Recent genetic evidence suggests that domestic ducks may act

as a reservoir of H5N1 influenza viruses after the virus has

emerged [15]. H5N1 viruses were isolated from apparently

healthy domestic ducks in Mainland China from 1999 to 2002,

and researchers found that the isolates were becoming

progressively more pathogenic for mammals . Twenty-one

viruses isolated were confirmed to be H5N1 subtype and

antigenically similar to the virus that was the source of

the 1997 Hong Kong bird flu haemagglutinin gene. All are

highly pathogenic in chickens, most causing 100 percent

mortality, although the earliest isolates were less lethal.

When tested on mice, however, there was a marked increase in

pathogenicity with time. The earliest seven isolates were

non-pathogenic or of low pathogenicity, the next seven were

more pathogenic and the last four, highly pathogenic. The

results suggest that while circulating in domestic ducks,

H5N1 viruses gradually acquired the characteristics that

make them lethal in mice. One possible explanation is the

transmission of duck H5N1 viruses to humans, the selective

evolution of the viruses in humans, and their subsequent

transmission back to ducks.

 

The presence of H5N1 viruses lethal to chickens from

apparently healthy farmed ducks is another important route

for the virus to spread through trade.

 

Blaming and devastating the victims

 

************************************

 

Numerous papers, statements and documents issued by the

United Nations FAO, WHO, and government agencies have been

silent on the role of industrial poultry farming in the bird

flu crisis, and indeed, have proposed to compensate them

generously for loss profits (see above). Instead, the finger

is pointed at backyard farms, calling for tighter controls

of their operations and greater " restructuring " of the

poultry sector.

 

The big poultry corporations are even trying to use the bird

flu outbreaks to shut down small-scale poultry farming

altogether. " We cannot control migratory birds but we can

surely work hard to close down as many backyard farms as

possible, " declared Margaret Say, Southeast Asian director

for the USA Poultry and Egg Export Council.

 

A team of scientists who analysed the H5N1 epidemic in

Thailand 2004 found that the risks for HPAI infection were

5.3, 5.1 1.5, 32.4 and 2.3 times higher, respectively in

commercial layers, broilers, ducks, quails and geese than in

back yard chickens [16]. This is clear evidence

corroborating other findings that corporate factory farms

are to blame, and not backyard farms. On that basis, we

should be calling for closure of factory farms, not family

farms.

 

Genetic engineering scientists too, are taking this

opportunity to promote their wares: transgenic `flu-

resistant' chickens [8]. " Once we have regulatory approval,

we believe it will take between four and five years to breed

enough [transgenic] chickens to replace the entire world

population, " said Laurence Tiley, Professor of Molecular

Virology at Cambridge University in the UK. Genetic

engineering is the best way to breach species barriers and

to allow viruses to jump species to create pandemics (see

" What can you believe about bird flu? " this series).

 

 

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