Evolutionary biology and dangerous diseases

Just a little point about influenza in humans- transmission is largely before any illness, as the peak of viral shedding occurrs before interferon release and the specific immune response e.g. T-cell response. This curtails viral replication and reduces shedding.

Any person admitted to hospital ill from influenza will have already transmitted the virus to another/s. The epidemic peak is very sharp in human influenza and it is probably the percentage of immune individuals in the population that brings the epidemic to an end. Therefore I don't agree with your evolutionary biology idea.

It may be that the number of immune persons in the population after the circulation of the virus for a year forced changes in the HA molecule to escape from neutralising antibody and this had an effect on the virulence of H1N1 but the reason for the virulence of that virus and why it arose and then changed is I believe not known.

I believe she is incorrect about transmission before any illness. There may be (in human influenza after it is fully adapted to the human species) some slight transmission before symptoms set in. But not much. It would have to be shed by breathing and talking - these are not efficient means of transmission. What are symptoms for? Why do we ccough and sneeze?/ Viruses settle in the upper airways and irritate us precisely in order to get us to cough and sneeze. In certain diseases, measles for instance, you transmit fairly early in the course of the disease, before you're bed-ridden. Measles makes you sneeze. But you are still symptomatic!

Of course, before the disease has adapted to human beings, transmission tends to happen late in the illness, e.g. SARS. Had SARS continued to transmit, it would have adapted to people by becoming a more efficient shedder and spreading earlier in the course of the infection - it would have evolved to mildness like all coronaviruses, which are just common colds in people. It didn't have that chance - it was wiped out before it became efficiently transmissible.

Just read your answer [after I'd sent in second email], and you are absolutely right - except for the bit about the "fair percentage" - I think you are still thinking in population terms.

She is also, I believe, incorrect about the "not known." We have a very good idea why the virulence evolved, and why it diminished over time.
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Perhaps you know this "experimental" incidence (coevolution
of pathogens with hosts):

http://www.rabbit-control-forum.net/Speeches/Kerr.pdf
"Myxoma Virus and Rabbits"

This example was also referred to by our specialist in predicting
the future of H5N1, but he said "there is a tendency like this,
but uncertainties remain". This myxoma virus (though it'a a vector-
mediated) once got less lethal, but regained half-lethal, perhaps
a result of some sort of host-pathogen equilibrium. A frequently
cited example in an ecology textbook.

Yet another - evolution of host-pathogen relation, and
possible emergence of virulence from population structure:

http://www.sciencemag.org/cgi/content/full/303/5659/842
"Large Shifts in Pathogen Virulence Relate to Host Population
Structure"

Here we show that rapid evolution of virulence can occur as
a consequence of bistability in the evolutionary dynamics of
pathogens associated with changes in host social structure.

natural selection doesn't favor very vicious bugs when transmission from sick hosts is difficult, for the hosts literally become dead ends before the bugs can leap to others. In such cases, milder strains tend to become the dominant ones in circulation.

We need a genetic explanation. Like Niman and ProMED, some people
regard the genetic similarity as evidence for migration theory.
My genetic interpretation is completely the reverse. The lack of
genetic variation is a result of "no natural selection" (evolutionary
stasis), i.e. the observed similarity is a genetic proof against wild
birds as vectors. Such a degree of "no natural selection" (as well as
the lack of reassortment) certainly requires artificial environment,
i.e. poultry. Wouldn't that be a breakthrough? What we need is an
expert's verification.

I have been just informed of a domestic TV program tonight,
highlighting "novel transmission ways" of flu. According to the
program, two new ways will be presented: mildly symptomatic people
(less immune reaction) and Tamiflu-treated people (I have read
numerous reports Tamiflu-treated mildly symptomatic people enter
crowds, spreading the virus). The can easily become "transmission
hubs", making the spread easier and more preserving the virulence.

Nah, this doesn't work at all. Mildly symptomatic people will produce mild strains...the disease will move towards mildness. That's the whole point of Ewald's argument. I don't know how much Tamiful treatment changes this picture - very little, I would think. The "less immune reaction" is a complete red herring. Less immune reaction is caused by a less virulent strain. In all cases, having people well enough to walk about will only decrease virulence, not maintain it or add to it. I suspect Tamiful-treated people will just recover more quickly and be less effective transmitters - remember, the virus has got to make you sick - coughing and sneezing- to get itself out and into someone else.

Not all individuals react to the same (or similar) strain in the
same way. While the virus is less virulent to some people, there
still remains a possibility of a higher virulence to the rest.
(We already know the present H5N1 has shown different reactions to
different ages, but the reason is unknown. An asymptomatic crow
infection, with systemic viral replication, is already experimentally
known, which excreted sufficient viral load to infect other birds.
This shows less symptomatic populations in the same species can emerge).

By the way, I am not trying to argue "how dangerous the virus is",
but Ewald's argument expects the "expected mean", not clearly directed
to the "potential upper limit". Predictions assuming some kind of
an equilibrium or "mean field approximation" would fail in certain
conditions, especially there is a background variation (different
responses in populations). This is the very point recently targeted
by the complex network theory or modern numerical ecology.

Yes, this is well-known. This is a famous piece in learning
ecology in terms of natural selection. This is a reason why experts
more fear a long-range transport (either by humans or birds) than
gradual geographical invasion.

But we can't predict exactly, particularly when various species
are involved. We don't even know why LPAIs are so "evolutionary
static" in wild ducks, while they can be so pathogenic to humans
when they happen to enter the human world. The only truth is
"natural selection works", but we may not know or deal with all
factors of natural selection.

> No such special conditions today; so Ewald argues that we won't get a
highly pathogenic human flu today.

As I have (indirectly) heard from flu experts, some argue the virus
will not enter the human world in the HP form, but others' claim
is different -- we (even virologists) don't know how HPAI will behave.

"Most extreme in 1918: First World War"

> No such special conditions today

Wouldn't airplanes, locomotion, population density be special?
We have never met a pandemic strain in such extremely globalized
world -- we don't really have an experience.

> His theory predicts avian flus will be mild in wild birds. Need to have
birds flying to carry the flus, so evolution to mild strains. So, to
me, we do know why LPAIs are "evolutionary static" in wild birds.

Yes, this explains "why". We don't exactly know "how". This
means we don't know exactly how selection pressure works. (Also
we don't know how Zq strain retained high path to natural hosts).
As we haven't seen LPAIs arising from Zq strain, we don't know the
time-scale this process would require (may not be "very quickly").

> High path strains into wild birds, and quickly to low path. Or
extinction.

Most look like to be going extinction (i.e. R0 But planes, crowded conditions etc not enough to him; not so special.
Need to have very sick people - immobile with disease - able to readily
transmit the virus.
Crowding doesn't matter here, if very sick people stay
home/hospitalised.

But flu is already contagious during the incubation period.
Less traffic than in WW I? Less packed people? (imagine Tokyo
trains) Though I can't figure out the effect, all present factors
seem to increase the risk of a more virulent pandemic.

> I'd figure that with wild birds, there's always potential for virulent
flus to evolve.
Spectrum of virulence it seems to me (this from chemistry background,
not viruses): get some higher path, others lower path. Get an
equilibrium, depending on prevailing conditions.
As need flying birds to transmit flu in the wild, the equilibrium is
greatly towards non virulent forms. High path forms stay rare. (This
again from chemistry; some memories from when I did this re systems
reaching equilibrium.)

Thanks! This is much easier to understand. If "random" distribution
of mutated form is close to Gaussian, natural selection would work
in this way (for a specific species). If it is very far from Gaussian,
we can't be sure (because there is no effective average -- this might
explain some of social phenomena like Zipf's law). What if some
populations (due to genetic diversity) are more resistant (not all
infected individuals die, but can excrete substantial amount of the
virus) -- we probably need a more complex view. Natural selection on
incubation period may also occur.

> Could well be that doesn't matter what bird species is: if cram into
captivity, infect with flu, and have substantial chance that birds with
high path forms can transmit flu, then will get evolution towards
higher pathogenic forms.

If this is population density-dependent, how can we be sure our
population density is below a threshold where high path strains can
be sustained for a meaningful (effective transmission to a next
cluster) time? What is the major difference from poultry chickens?
(Well, some of recent pandemic plans from various companies seem to
assume "forced working" of employees with milder symptoms -- they
will mix healthy populations during movement or in taxis -- we may
eventually be poultry chickens ;-)

One more on "equilibrium theory", why we have never seen a human
pandemic strain eventually forming a non-pathogenic form (as in LPAIs
in wild ducks?) What would be the difference between ducks and humans?
(Why "evolutionary stasis" is never reached)

By the way, when considering selection pressure, won't the extensive
use of Tamiflu in pandemic lead to a more virulent strain? Not
necessarily drug resistance, but won't we be selecting a more neurotrophic
strain (since Tamiflu doesn't effectively cross the blood-brain barrier),
I casted this question to a public health expert, but haven't received
a reply. This might be another factor different from past pandemics.

> Seen re flu becoming infectious before symptoms; queried Wendy re this.
How infectious, I wonder, if not coughing/sneezing? How do you transmit
virus without doing these things?

If high path mechanism (replicate without trypsin) indeed works,
we don't necessarily require respiratory organs. Virus replicates
everywhere in the body.

> Wendy notes that 1918 flu did become non-virulent, and still circulates.

The 1918 flu once disappeared (around 1950), reappeared later
(likely from a lab) and now circulating.

What if some
populations (due to genetic diversity) are more resistant (not all
infected individuals die, but can excrete substantial amount of the
virus) -- we probably need a more complex view.

I've noticed that this possibility is a real concern. If such
individuals (or individuals of different species) are sporadic, we
don't need to worry. But if chains of such individuals are
established? -- This corresponds to the "percolation theory".
(You may have read Simon Levin's "Fragile Dominion" or Kauffman's
"At Home in the Universe" in relation to percolation leading to
phase transition and its role in ecosystem).

> Well, not sure if water-borne disease should be more specialised to
this transmission route, between humans. Like cholera.
And like cholera, can't imagine it becoming widespread, but more in few
places w bad sanitation.
Worst SARS outbreak outside hospital (that we know of) was evidently
from sewage (apparently from toilet, somehow reached people's showers,
and several people infected in an apartment block). Looked scary, but
proved isolated.

Natural selection works as if a pathogen is seeking for a higher basic
reproduction number (not plainly necessarily less lethal). If a pathogen
has an ability to spread in a more efficient way, this would become
a primary route of transmission. If the virus replicates in intestines
or kidneys, sewage would be an efficient place for viral adaptation
(much resembling avian infections??).

> As discussed, I don't believe Osterholm is correct re predictions.

> What may happen though, is that if get pandemic - and no matter if it's
relatively mild - panic will lead to problems.
Already too many problems (such as worry, Tamiflu stocking etc), even
in US - where no H5N1, just fear of the disease.

As we know, our existence is dependent on the present biodiversity
-- a product of ecosystem evolution, to which we best adapt.
We don't know when our present existence is threatened how much and
how rapidly biodiversity is degraded, but there should be some number
(not easily predicted). The same is true for our society; our life
is dependent on the present social system -- a product of social
evolution, to which we best adapt. We don't know when our present
world is threatened how much and how rapidly social system is degraded.
These two problems are alike, both arising from a complex adaptive
system. Complex social systems could amplify the effect of a minor
mortality.

Time-scales also play a role. If any change is slow enough, we
can, or ecosystem would adapt to a new form. If the change is rapid
enough, they may fail. There is a simple physical analogy; the
adaptation of gas is limited by the sound speed. If change goes
faster than the sound speed, the gas fails to adapt -- the net result
is a well-known supersonic shock. The same would be true for our
society. If the spread of the pandemic is rapid enough, our system
would fail to adapt. Of course, with the advent of the internet,
we have a better chance of adaptation before the wave comes. But the
expected result of adaptation is so drastically different from the
current social system, the arrival of pandemic flu will trigger
a reaction that looks like to change the world overnight.
I'm skeptical about such a drastic change in social systems could be
done overnight (even officials declare "immediately"), since no one
is accustomed to the change, and expect the situations something
between adapted (with a drastic change) to less-adapted (little
reaction before the wave reaches, and an immediate panic is
triggered).

1. Almost no mainstream press accounts of the bird flu threat discuss anything about the evolution of influenza. This is probably the most important public impact of evolutionary theory today, but we hear almost nothing of the evolutionary modeling of how the virus may change.

2. Ewald is very well known for studying the evolutionary dynamics of disease. He is making an argument that is sound, as far as the dynamics of selection are concerned. Thus, there are good reasons to think that the worst will not happen, and this is a perspective that has been underplayed.

3. So far, the theory has only been tested by a relatively small number of instances -- there just haven't been so many pandemics that we can infer accurately from past events what the future will be like. It could certainly happen that some new influenza strain could violate the model in some unexpected way, and for this reason governments should play it safe rather than assume that no high-virulence pandemic will emerge.

4. A lot of public health scientists are going to be well-employed for as long as the bird flu remains in the public perception. This doesn't mean that they are wrong to convey alarm, but it does mean that they don't benefit by playing down the threat. It's sort of like NASA and the asteroid impact threat --- partly they are more concerned because they know more about the threat and its terrible effects, partly because it's their job to be concerned.

5. There are a lot of biologists who don't use or understand selection.