HEREDITY:
WAS DARWIN WRONG?
April 2011 /
Geneva Coats R.N.,
TheDogPlace.org
Genetics Editor
Heredity
is the means by which traits (distinctive features) are passed on to the
next generation through the genes via the chromosomes.
 Physical
traits include such things as eye shape and color, body size, and coat
color. Behavioral traits involve characteristics like herding or retrieving
instincts. Some traits are not readily apparent, like blood type or
predisposition to a disease but all are inherited.
We talked
about chromosomes in the last issue. Chromosomes are string-like ropes made
up of thousands of genes. Chromosomes occur in pairs; one from each parent
and with the exception of genes composed of extra material created through
mutation or insertion, every gene has a partner on the opposite chromosome.
These partnered pairs of genes determine the traits of an individual but
there are some exceptions such as the female sex chromosome which contains
more genes than the male sex chromosome, so some traits are linked to the
sex of the individual.
But most genes do have partners.
There are many different forms that can exist at any given location and they
are known as "alleles". For example, at one location on the chromosome, a
dog could have a gene for sable, or for tan-point pattern, or for black.
These are three alleles that might be found at that particular location.
Your pup inherits only one allele from one parent and one from the other
parent.
How Genes Evolve and Adapt:
Evolution
How do we know how this all
works? Let's take a brief look backwards at how our knowledge of genetics
developed. Way back in the 1700s, a man named Jean-Baptiste Lamarck
developed some theories about how evolution occurred.
Lamarck observed that organisms
adapted to their environment. He believed that bodily features were gained
or lost through use or disuse. He also believed in something known as "soft
inheritance"- the idea that environmental effects on an individual's
traits could be passed along to their offspring. While this idea has
generally been discounted, science is now beginning to delve into the area
known as "epigenetics". We now know that sometimes environmental
factors (nutrition, toxins, radiation, etc.) can indeed affect the genes
that are passed on to offspring! Lamarck may have been on to something after
all!
In the 1850s and 1860's an
Austrian monk named Gregor Mendel did experimental hybridizing on
thousands of peas. Mendel showed that the inheritance of traits followed
certain patterns and laws. He was the first to postulate that traits could
be dominant or recessive, or in some cases, co-dominant. Mendel also
developed the theory of independent or random assortment of traits. The
importance of his work was not realized during his lifetime, but Mendel is
now regarded as the father of modern genetics.
During this same time frame,
Charles Darwin published his theory of evolution by natural selection.
(Darwin knew nothing of Gregor Mendel or his research). Darwin's
observations led him to the idea that organisms adapt and change through
"survival of the fittest". Darwin's theory of natural selection is widely
accepted today. In the early 20th century the ideas of Mendel and Darwin
were combined to form the basis of genetic science and evolution.
Selecting For Genetic
Evolution
We can see examples of how
evolution occurs in an artificial, man-made manner by looking at the results
of selection in domestic animals. Man can change a species form and function
by selecting for certain traits that we find valuable. Traits less valued
are selected against and do not survive. For example, we rarely see a thirty
pound Pomeranian today....small size has been selected for and the genes
that produce larger body size have almost disappeared from the breed. We
also attempt to produce an almond-shaped eye, small ears, a high tail set
and a relatively short back. Although this is a man-made selection process,
and not "natural" selection, it's a good example of how evolution occurs.
But organisms are not simply the
product of their genes. Scientists are finding that traits determined by
genes can often be greatly influenced by environmental factors. Hip
dysplasia is a good example of this phenomenon. The genes that
predispose to hip degeneration can be influenced by the effects of nutrition
or stress on the joint. Another example is coat color which is determined
by genes but can be changed under the influence of the sun or hair dye.
A non-canine example of
environment affecting expression of genes is the coat color of the Siamese
cat. The Siamese cat has a form of partial albinism due to an enzyme that
blocks melanin, but this enzyme that produces light coat color is
inactivated by cooler body temperature. The coat color of the Siamese cat's
tail, legs, ears and face (which is cooled by the nasal passages) remains
darker than the rest of the body because these regions are not as warm as
the rest of the body. The gene for blocking dark coat color depends on
environmental warmth to be activated and expressed.
Dominant and Recessive Genes
We learned from Mendel that some
genes are "dominant"; others are "recessive", and still others are
co-dominant. But only a few traits are determined by a single gene. Most
traits in complex creatures like animals are created by the actions of
multiple genes. This is what we call a “polygenic” trait; one that is the
product of many genes interacting together. Even a fairly simple trait such
as coat color is produced through the interaction of multiple genes.
Traits like the size and shape
of the ear, or the croup, or the front, are examples of polygenic features.
This makes it difficult to predict with any certainty what sort of offspring
will be produced from any certain mating. Remember, there are literally
millions of different combinations of genes that each animal can possess.
Selection of individuals who possess the traits you wish to perpetuate is
important. This is actually more important than looking back at ancestors in
a pedigree, because some genes that produce certain traits can be lost
through the generations.
Linebreeding and Inbreeding
How can we stack the odds in our
favor to produce the traits that are important to us in our breeding
program? One tried and true method used by dog breeders has been inbreeding
or linebreeding. This system involves breeding together dogs who are closely
related or who descend from a meritorious common ancestor.
Inbreeding and linebreeding help
to preserve certain valuable traits. However, inbreeding may also preserve
undesirable traits at the same time. Another problem with inbreeding is that
any hidden “problem” recessive genes in the admired ancestor stand a
relatively high chance of being doubled up and expressed in the offspring.
Why? Because by inbreeding each related parent has a higher than normal
probability of sharing common genes, good or bad. These problems then become
nearly impossible to eradicate from a line and in some cases from an entire
breed.
It takes knowledge of the
bloodline and astute selection to keep the sought-after virtues while
eradicating genetic faults. Breeds that were founded on only a few
ancestors, or breeds that extensively use a few popular sires will almost
always develop a few problems that become characteristic of that breed.
Another problem with inbreeding
and linebreeding is that along with producing a more uniform type, the
inbreeding process can also result in a lack of variability in the genes
needed for optimal immune system function. Impaired immunity can mean a
greater susceptibility to infection, higher rates of autoimmune diseases,
lower birthrates and decreased lifespan.
Judicious Genetic Outcross
Breeding outside the line, or
“outcrossing” serves to introduce more genetic variability and improves
health and vigor, but the downside is less predictability of type. Most
physical characteristics and even most diseases are produced through the
interaction of multiple genes.
Many disorders of the immune
system such as autoimmunity or allergy may be caused by something as simple
as lack of a variety of genes in the immune complex. Such problems can often
be corrected in the next generation by outcrossing.
An outcross should be carefully
planned for certain features that the breeder wishes to introduce or to
eliminate, and several generations are required to refine those features to
reach a certain goal. This might require more patience than many of us
possess, and there is no guaranteed pot of gold at journey's end. However,
the rewards of improved health and vigor may make your “surprise” outcross
experiment very worthwhile.
DNA Selection For Health
Genes
There are a few diseases
produced by a single, identifiable gene, and some of these can be tracked by
DNA identification of that gene or a closely located “marker”. Carriers of
certain diseases may be identified in this way.
Identification of problematic
genes does not necessarily mean that we should eliminate the carrier from
the gene pool. That animal probably has other very valuable genes to
contribute as well. DNA selection coupled with rigorous testing can result
in a dramatic reduction of expression (incidence) of a genetic health
problem or type fault in future generations. With today’s rapidly expanding
DNA testing, the genetic carrier status is becoming readily identifiable in
the canine.
Breeding
can be similar to a roll of the dice. You may not know exactly what you will
produce, but if you bear in mind some of these basic principles of heredity,
they can help you to reach your breeding goals!
http://www.thedogplace.org/Breeder/Heredity-Darwin-1104_Coats.asp
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