Bad Genes,
Babies and Bath Water
First published in Double Helix Network News, Fall 1998
by
C.A. Sharp
Everyone has heard the phrase, "Don’t throw out the baby with the bath
water." But do dog breeders ever stop to consider how this admonition applies
to them? Certainly not the novice who righteously declares that he will never,
ever, keep anything that has even the possibility of producing the smallest
genetic defect. Not even the experienced breeder who refuses to consider an
otherwise excellent line because it sometimes throws cataracts. This tendency
toward genetic over-kill not only culls dogs that might have something to
offer, it can exacerbate the very problems breeders are trying to avoid. The
following is a real life example of what can happen when breeders exercise
short-sighted culling in the name of genetic disease control.
About twenty years ago, breeders of Basenjis launched a campaign to wipe out a
fatal genetic disease called pyruvate kinase deficient hemolytic anemia (HA). HA is caused by a recessive gene. Dogs with a
single copy of the gene are healthy, but those with two copies die. A screening
test was developed that would indicate carriers as well as affected animals.
Breeders zealously screened their dogs, eliminating not only affected animals
but the healthy carriers from the breeding population.
Today HA is rare in Basenjis, but the incidence of Progressive Retinal Atrophy
is significantly higher. As is yet another fatal disorder, a kidney problem
called Fanconi’s Disease. Neither of these diseases
has a screening test that will indicate carriers. Had breeders been less
fanatical in their pursuit of HA, they might have retained the healthy carriers
in the breeding population, breeding them only to non-carriers so they could
avoid producing HA-affected puppies. By such a method they could have retained
the good aspects of those carriers, including freedom from genes for PRA or Fanconi, while gradually lowering the incidence of the HA
gene.
Fortunately for the Basenji, there is still a native population of the breed in
In spite of what happened with the Basenji, this should not be viewed as an
indictment of screening tests. The problem wasn’t the HA test, but the drastic
culling process that breeders undertook when using it. If there is a test which
can identify carriers, make use of it. Breeders need to know as much as
possible about the genetic potential of their breeding stock. Ideally, they
should be willing to share the results, whether good or bad, with other
breeders.
Knowledgeable dog people know there is no perfect dog. Even the best of them
have faults. The faults are not only those conformation or behavioral
problems you can readily observe, but also bad genes. Dogs have at least 80,000
genes. No matter how high the standards for selection of breeding stock or how
strict the culling of offspring, every dog will have genes for unwanted traits.
Experts agree that every individual--be he dog, human
or cauliflower--probably carries, three "lethal equivalents." This
may leave you wondering why we aren't seeing dogs and cauliflowers, not to
mention each other, dropping like flies all around us.
Under normal circumstances, lethal genes remain rare. Natural populations breed
randomly, maintaining a varied mix of alleles, or forms, of genes. Only
occasionally will the right combination of bad alleles match up to produce an
affected individual. In addition, the lethal nature of these diseases limits
the ability of affected animals to pass them on to their offspring because
affected individuals often don’t live long enough to reproduce. But the
breeding of purebred livestock, including dogs, is not natural or random. It is
selective based on the wants and needs of breeders. As a result, the number of
lethal equivalents in most breeds exceeds the average of three, the problem
genes having been inadvertently concentrated through the standard inbreeding
practices used to maximize production of desired traits. Two examples in
Australian Shepherds are Pelger-Huet Anomaly and
merle. Genes with lethal effects are only the tip of the iceberg. There are
dozens, if not hundreds, of genes whose effects are anywhere from minor to
extremely bad.
Breeders routinely evaluate breeding stock by studying conformation and/or
performance attributes in minute detail. Virtues are weighed against faults, then compared to the virtues and faults of prospective
mates. If the overall analysis is positive, the breeder will proceed.
Hereditary diseases and defects need to be given the same kind of
consideration, in and of themselves and in combination with all the dog’s other
traits.
Some faults are severe enough to eliminate a dog from breeding consideration
entirely, but even genetic defects and disease may not necessarily fall into
this category, in some circumstances. Remember the case of the Basenjis and HA.
Dogs proven to be carriers of traits in which only homozygotes
(those with two copies of the gene) are affected, can be used if care is taken
never to mate one carrier to another and not to use them extensively.
If the mode of inheritance for a trait is unknown or polygenic, identifying
carriers can be difficult. Individuals which
repeatedly produce traits like hip dysplasia,
epilepsy or thyroid disease should be pulled from further breeding because of
the serious and debilitating nature of those diseases. But their relatives may
be used if care is taken to select mates unlikely to carry the same defect. If
at any point an individual proved to be a repeat producer of the defect, it
could then be removed from the breeding program.
Many faults are variable in expression. This includes such genetic defects as
hip dysplasia (HD) and missing teeth. In Clumber
Spaniels, where HD was once almost universal, elimination of all affected
animals was not an option if the breed was to be preserved. By selecting away from
the most severely affected dogs, Clumber breeders have managed to improve their
overall situation, producing more non-dysplastic dogs
and fewer which are severely affected, even though HD is still common. A
similar situation has occurred with Collies and Collie Eye Anomaly.
In the case of missing teeth, a fault common to show line Australian Shepherds,
something similar could be done. There are sufficient quality dogs available
with full dentition that dogs missing multiple teeth ought not to be bred.
However, those missing one or two teeth could be bred to mates with full
dentition which are out of families with full dentition. Twenty years ago,
missing teeth in Aussies were almost unheard of. Twenty years from now the
situation could be to nearly its starting point if breeders were conscientious
about screening and mate selection--and none of he good traits those dogs have
need be lost along the way.
The overall size of a breeding population must be taken into account before
making final decisions on whether a dog exhibiting or carrying a defects ought to be bred. Australian Shepherds are
numerous, but certain sub-sets of the breed are not. In
In small populations, breeders may have no choice but to use some defective
animals. The only alternative is to resort to increased inbreeding which will
narrow the available gene pool even further and bring other, possibly worse,
defects to the fore. If defective dogs are to be used, breeders should take
special care to avoid subsequently in-breed on those dogs. Neither should such
a dog be bred extensively. Among its offspring, only those which do not exhibit
the defective trait should be considered for further breeding.
If breeders approach genetic disease with an objective eye and if they are
honest with themselves and each other about the potential for producing genetic
diseases and defects in any given cross, they can obtain healthy babies while
the bath water full of bad genes drains slowly away.
Copyright 1998 C. A. Sharp. All rights
reserved. C.A. Sharp
is editor of the "Double Helix Network News", the quarterly
newsletter for those interested in genetics and hereditary disease in the
Australian Shepherd.
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