PRA

What is PRA?

Below are extracted pieces of the article,  Breeders Ask Optigen… The Whys and Wherefores of Testing Your Dog for PRA by Mary M. Woodsen. For the purpose of this Web site, it has been condensed and updated for Chesapeake Bay Retrievers.

Chesapeake Bay Retrievers gained access to the first genetic test in 1998. The test is by OptiGen and it detects prcd-PRA (Progressive Retinal Atrophy) in CBRs. The test is now in its third rendition.

What is PRA? Is there any way to treat it? Can I prevent it?

Progressive Retinal Atrophy (PRA–and specifically, the prcd form of PRA) is an inherited eye disease that affects not only Chesapeake Bay Retrievers but several other breeds as well. Dogs with prcd-PRA, over time, go blind.

In most breeds PRA is evident by the time a dog is at least six years old, after it has already been bred. In order to develop PRA, a dog must inherit two copies of the defective prcd-PRA gene: one from its dam, one from its sire. There’s no cure, no treatment; no way to stop it.PRA, however, can be prevented in the next generation even though you can’t treat it in the current generation. Through safe, selective breeding based on a simple DNA test.

Marker-based genetic testing. 

There are two general types of marker tests used in genetic testing, and sometimes they’re confused. Our’s is a marker (linkage) test with No Chance of Recombination. This means that the marker is close enough to the gene that its chance of splitting away from that gene during meiosis (sexual reproduction) and skewing the test is less than one in several billion! (Some types of marker [linkage] tests do allow for recombination, which means that the test can give either false positive or false negative results. In other words, a small percentage of dogs that test as genetic normals could actually be a carrier or affected, and visa versa.)

This test, in fact, designates a dog as genetically normal (clear) with absolute, unequivocal, totally reliable, 100%-no-ifs-ands-or-buts accuracy. And that’s good news, because you can take your otherwise really great dog that happens to test as (probable) carrier or (probable) affected and breed it to a certified (no ifs ands or buts) normal–and know that no pup will ever be affected.

What does “probable” carrier and “probable” affected mean?

The problem with markers is this: way back when the first pup was born with a mutated gene, the gene’s marker didn’t mutate too. Indeed, that pup was the very first carrier. Of course, it still had its parents’ other healthy gene, and passed one or the other of the pair along to each of its pups. Today, dogs testing as carriers and affecteds either carry that ancestral pup’s damaged gene-plus-marker–or they carry that pup’s parent’s normal gene-plus-marker. But which gene, which marker? We can’t tell–we haven’t found the gene yet, and the markers look just alike. We call this look-alike marker a false allele.

This ancestral, normal gene-plus-marker–the false allele–is the wild card. Thus a dog may test as Pattern B (probable carrier) yet carry two normal genes, one of which has those look-alike markers. Likewise a probable affected–a Pattern C dog–may carry one damaged and one normal gene–or less likely, two normal genes. That’s why we use the designations “Pattern B” and “Pattern C”: because some Bs aren’t carriers and some Cs aren’t affected.

The marker for Pattern A has never accompanied a mutated gene and thus could never have a false allele.

Explain, please, what an allele is.

Alleles (say it a-lee-el) are different versions of the same gene. Does your sister have brown eyes, your brother hazel eyes, but yours are blue? In humans, eye color is caused by different alleles of the “eye-color gene.” (Eye color is a bit more complex in dogs.) In the same way, genes for retinal functioning have different forms, or alleles, and the defective gene is one. In fact, even markers have alleles. One of those alleles always accompanies the mutated gene, but in its ancestral form, it sometimes accompanies the normal gene.

How can you offer a test if it isn’t accurate?

Our definition of “accuracy” has to do with the detection of the markers used in the laboratory. The OptiGen test for the markers of PRA is exactly accurate. This means that the test gives clear readings in the laboratory; there is no issue of interpreting what we see–no false positive. (A false allele result is not a false positive result.) Numerous controls–absolute measures of accuracy–are used for every sample we process. The results for every dog will never change with age and will be the same whenever this current test is repeated. (In contrast, a false positive reading can change.) Pattern A dogs will always test as Pattern A. Likewise, Bs will always be Bs and Cs will always be Cs. These are lifetime guarantees–and they are accurate. As scientists we are necessarily bound to this definition of accuracy, and could not state it differently.

So a C dog can be normal, clear?

Yes, that’s possible, if it has two false alleles–two look-alike markers. Then sure, it’s actually normal, but this genetic test can’t prove it normal. It may indeed be normal but the best you dare guess, if you have a normal ERG and the dog is over six years old, is that it’s a carrier. You still need to breed it with caution to certified clears. Don’t worry – within a couple generations you can breed completely clear progeny.

Given that a dog comes back as a B or a C, what is the next best course to follow to determine its true genetic status? Should we test its parents, or perhaps its offspring or grandchildren? How do we find out if the dog really has a false allele and what do we do about it?

The markers to the prcd gene are inherited, just as is the prcd gene itself. If the look-alike false allele is involved in one dog, it will be passed from one generation to the next. Which means that testing parents, offspring or grandpups won’t help you figure out that a false allele is involved. If a dog is Pattern C (probable affected) and is bred to an A (no ifs ands or buts, it’s clear) dog, every one of its progeny will (alas) test as Pattern B (probable carrier). Genetics just doesn’t happen any other way. (Depending on what other dogs have been used as mates in the past, offspring of past matings could test as Pattern C, probable affected).

But until we have an improved prcd test, there’s no unequivocal way to determine the true genetic status for the mutation in Pattern B and C dogs–and thus no way to say that any dog definitely has a false allele. “Normal” eye exams and ERGs, the lack of apparent symptoms into old age, even a seemingly flawless pedigree–none of these unequivocally deny the possibility of having at least one mutated gene.

Why bother to run a test that does not detect the false allele?

If you want to prevent PRA this test will do the job. If you want to eliminate the mutated prcd gene from your lines over a span of two or three generations, this test will do the job–if you follow safe breeding practices, using Bs and Cs wisely so as to retain their other excellent qualities. You should test before breeding and always choose a Pattern A dog as one of the breeding pair. If you want to know beyond any conceivable doubt that your dogs are carriers or affecteds, this test will not do the job.

Understandably, it’s difficult for owners to accept that the frequency of the false allele is unknown. It’s human nature to prefer certainty. But give your Bs and Cs two or three generations; you can breed certainty into your line by breeding them only to A dogs–and likely you’ll be ahead of those who decide to wait for the mutation-based test.

Our breeders are flabbergasted about the amount of B’s and C’s. This just cannot be true–and the results certainly aren’t “occasional!” If these dogs are really B or C, we would have had many more blind dogs or dogs with PRA diagnosis, and we don’t. Why?

Indeed, this situation is being reported more often than “occasionally.” This most likely means that the false allele is more common than we initially predicted based on results from the pedigrees in our research group. If we could rewrite our literature, knowing what we know now, we’d suggest a more frequent occurrence of the false allele–even though we still can’t put a number on that frequency.

Part of this situation is due to prcd-PRA being a recessive disease and part is due to the false allele. Consider:

Part I, Recessive inheritance of prcd-PRA:
– If–for example only–the real, true frequency of PRA in Chessies were something like 5%. In such a case, the expected frequency of carriers in the population-at-large would be 35%. That is just a fact of inheritance based on calculations of gene frequencies of recessive conditions. Even that number might seem high to breeders. To our knowledge, the real frequency of PRA in Chessies isn’t known. We have used 5% only as an example to show that even with a low frequency of prcd-PRA, the carrier frequency would be considerably higher.

Part II, that ignominious false allele:
– The false allele is still hidden among the Pattern Bs and Pattern Cs. We don’t know what percentage of dogs have false alleles, but it surely inflates the actual numbers of Bs and Cs.

Keep in mind, though–the real reason we offered the test in its current form is to identify Pattern As, or genetic normals: those dogs that definitely
– have no prcd gene;
– cannot pass on a prcd gene;
– will never become affected.

This provides the foundation for safe breeding of all dogs. Would we be doing breeders a favor by withholding this test?

Likewise, the test is valuable in reliably identifying Pattern B dogs that will never become affected with PRA.

Why not breed B x B, since B just means that the dog involved is not an affected dog?

It is true that Pattern B means the dog is not affected. But Pattern B dogs have a high risk of being carriers, and B plus B could equal C. Even if you have the best-kept pedigree in town, do you want to take the risk of breeding Cs? Cs can turn out to be affected.

Breedings of B x B yield an average of 1/4 As, 1/2 Bs, 1/4 Cs. So, this breeding can produce Bs at high risk of being carriers and Cs at high risk of being affected.

We were in the process of getting our dog’s championship with the idea of future breeding. She’s a C. Do you recommend terminating this course of action?

We can’t make specific recommendations about how people should handle their dogs. But health-wise and breeding-wise, there’s no absolutely reason to change your plan. Why? Three reasons:

– if your Pattern C dog is between 18 months and 6 years of age and has current and reliable ERG and CERF results, there’s a fair chance she has a false allele and might never get PRA;
– if she does get PRA, she may not be affected significantly before getting her championship, and she will bear that honor for life;
– even if she is affected, she will never produce a PRA-affected pup if bred only to Pattern A dogs–but she could produce a champion.

Analyzing the pedigree of your B or C dog will add information. If your dog has absolutely no prcd-PRA documented in an extensive pedigree that you can trust, chances decrease that it has two true mutant genes. (Keep in mind that in the old days–not that many years ago–owners sometimes didn’t recognize or understand PRA, or may have been afraid to reveal that a dog had it.)

If this test has a large margin of error in diagnosing carriers and affecteds, won’t it limit our gene pool to the point that other problems will become more of an issue?

Whether and how we limit the gene pool is a really important issue. After all, some conditions–hip dysplasia is an example–are so genetically complex that practically every dog has the capacity for some degree of disability, be it so mild it’s almost undetectable or so severe it’s totally disabling. Fortunately, PRA isn’t like that. Clear dogs aren’t mostly clear–they’re clear. The gene isn’t partly recessive–it’s recessive. Carriers and affecteds bred to clears produce disease-free pups.

Indeed, the best thing about the test for prcd-PRA is that it helps keep the gene pool from shrinking. You need to pull a dog with bad hips because scientists don’t know enough about the disease to prevent passing it on. But you’ll never need to pull any dog because of a B or C OptiGen prcd-PRA reading. Bs or Cs bred to As will never produce affected pups.

Often it’s the breeders who suspect they have a problem that test first. If breeders test actively within the breed, they’ll identify increasingly large percentages of As–which will benefit all breeders. In fact, other breed clubs have had exactly that experience. (Each quarter, OptiGen’s website posts the test result percentages.)

How can I use this test to eliminate the defective gene from my line?

Find out everything you can about your dog–then breed or don’t breed according to the absence or presence of traits and health considerations you have no control over. Don’t let the traits you can control dictate your breeding decisions. You now have control over prcd-PRA. An OptiGen-tested Pattern B or C dog can be bred to a Pattern A dog without producing affected offspring. B pups can be bred again to As. This is how you eliminate the defective gene from your line.

Your C dog’s progeny will all be Bs, so you don’t need to test them. (Unsure about how basic genetics works? Check OptiGen’s web site.)

How far away in time and $$ is OptiGen from the new, direct gene test?

The research to solve the false allele is going full steam ahead. It is the main focus of the labs supervised by Drs. Aguirre and Acland. But with research you can’t really say when the result you seek will be found. That’s what research is all about– searching for something that is yet unrevealed. In our case, we know what needs to be done and exactly how to do it, but we don’t know when we’ll get there. All we can say is that every day we are closer because every day more has been done to achieve our goal. That’s why our research needs continued support.

Will the next test be 100% accurate and, if not, what accuracy percentage will it be?

The goal is to develop the next test so that it continues to give the accurate diagnosis of normal, but also gives an absolute (no ifs ands or buts) diagnosis of carrier and affected status–with no false allele problem. The new test will change the categories we attach to dogs, and they will be categorized as Normal, Carrier, or Affected.

How do you sum up the value of this test?

Many beautiful animals over the years developed prcd-PRA and were removed from breeding programs never to be bred again. Now these animals can be used without the fear of producing more blind dogs. The OptiGen prcd-PRA test allows breeders to present their Bs and Cs with pride for all their other prize qualities.

We ask again–would we be doing anyone a favor by withholding this information until the mutated gene is found?

 


For detailed information for the science behind genetic testing, see Mary M. Woodsen’s articles inDog News:

The Genetic Advantage: Baker Institute at Cornell University Releases New Tests for Progressive Retinal Atrophy, May 14, 1999

Marking the Spot: Genetic Testing and the Occasional False-Allele, June 25, 1999

DM

Much of the information below is provided by the American Chesapeake Club,  Teamchesapeake and ChessieInfo.net.


 

What is Degenerative Myelopathy?

Degenerative myelopathy (DM) is a progressive neurological disease that results in destruction of tissue within the spinal cord, usually in middle aged or older dogs. It is similiar to  Amyotrophic Lateral Sclerosis (ALS or Lou Gehrig’s Disease) in humans. The disease’s onset usually occurs between 8 and 14 years of age.

The spinal cord is wrapped in a protecive membrane called the mylin sheath. Like insulation around an electrical cord, it protects the electral pathway of the nerves running down the dog’s spine. When this membrane becomes weak and starts to deterioate, it is known as a myelopathy (myelo=myelin sheath, pathy=disease). Once this protective layer deteriorates, the nerves themselves are at risk of degeneration. DM consists of both myelin and spinal cord nerve fiber degenration.

Since one of the most important functions of the spinal cord is to conduct signals from the brain to the nerves controlling the hind limbs, the principal clinical feature (visible symptom) of degenerative myelopathy is poor control over hindlimb function. Dogs with degenerative myelopathy show a lack of coordination in both hind limbs, together with a degree of muscle weakness.

DM starts slowly and affects the rear legs first. Early signs may go unnoticed by the owner. Slight dragging of a back foot, wearing of the toenails on the affected foot or feet can be an early sign. More advanced signs are dogs that might knuckle over on both paws, cross hind limbs (especially when turning in tight circles) and swing hind limbs wide or take abnormally long strides. Over time, the hindquarters become progressively weaker, until the dog can no longer support its own weight. Eventually, the disease leads to complete paralysis.

It is difficult to accurately diagnose DM as many other conditions can have similiar early symptoms. Injuries, bulging or ruptured vertebral disks, hip dysplasia, cruciate ligament ruptures, and many other things can show as a slight draggng of a hind foot, or wobbling when walking. To properly diagnose DM, all these other issues must be ruled out first before DM is considered. Diagnosis of the disease is only possible through magnetic resonance imaging (MRI) and cerebrospinal fluid (CSF) tap, or through autopsy. Even an MRI diagnosis can be incorrect as it does not pinpoint DM. An MRI only rules out other similiar diseases.

There is currently no available cure for DM. The disease inevitably progresses over a variable period of time – anywhere from 6 months to 3 years. Ultimately, affected dogs lose the ability to walk in both hind limbs and at this point, most owners elect for euthanasia.

 How do Chesapeakes get DM?

DM is an inherited condition, and is polygenic in inheritance. This means that several genes, together with perhaps some environmantal factors, combine to create the disease in dogs. Currently, there is a DNA-based test for DM. It looks at only one of the genes that contributes to DM. The gene it identifies is simple recessive. The inheritance mode(s) of the other gene(s) involved with DM are unknown at this time.

What is a Polygenic Trait?

Polygenic trait:A Polygenic trait is controlled by two or more than two genes (usually by many different genes) at different loci on different chromosomes. These genes are described as polygenes.Every dog, and every human has “good” genes and “bad” genes. When the “good” genes outweigh the “bad” genes, this is considered normal phenotype. When the “bad” genes outweigh the “good” ones, this is considered affected phenotype.Affected dogs still have a certain number of good genes as well. An example of a polygenic trait in dogs is hip dysplasia (HD). HD is caused by many genes that control things like depth of hip socket, bone density, placement and strength of ligaments, tendons and muscles, size of femoral head, length and thickness of femoral neck, and so forth. If a dog has an overall greater number of bad genes for one or more of these traits, that dog will show up as dysplastic on x-ray. However, the dog will also still have some good genes at some of these loci. This is why a dog with bad hips can still produce non-dysplastic offspring, and vice versa, two x-ray normal dogs can still produce dysplastic puppies. A dysplastic dog, simply has fewer good genes to contribute, so it is less likely to produce overall improved hips in its offspring than a radiographically normal dog

A New Problem in Chesapeake Bay Retrievers?

Veterinary neurologists are familiar with DM because it is a common problem inGerman Shepherd dogs. From time to time sporadic cases have also been seen inother breeds. We are now seeing a growing number of Chesapeake BayRetrievers with the condition.

Knowing that this disease is strongly associatedwith particular breeds, it is possible that DM has a strong genetic component inCBRs as well. As yet we do not understand the cause; meaning, we do not haveenough data to ascertain whether the problem is due to a defect within a singlegene or defects in multiple genes acting in concert. More data and pedigrees needto be collected from dogs affected with DM to ascertain whether the problem isworth investigating further to try and locate a genetic component in the CBRbreed.

Trying to Eliminate the Disease

In 2008, a test became available which identifies “one” gene that contributes to DM. Results of the test are reported as clear, carrier, or at risk. At risk dogs are identifed as such, because having this gene alone may not cause the disease. It is an indicator that the dog *may* develop DM at some point, but it is not a certainty. Dogs testing as at risk can still be bred; owners should take into consideration the dog’s overall value as a breeding animal, and the test status of any mates when doing breedings.
Based on test result statistics, the frequency of this allele in Chessies seems high, so eliminating all carriers and all at risk animals would not be feasible. It would result in removing almost 60% of the breeding population. Obviously, this is not realistic. Instead, breeders should strive to reduce the occurrance of affected animals, by knowing their dogs’ testing status, as well as their bloodline’s tendency to actually develop DM symptoms. Carrier and at risk dogs from lines known to develop DM are a higher risk for producing affected offspring than dogs who test carrier or at risk, but are from lines where few or no animals actually develop symptoms.
Research is ongoing into causes and cures for this disease. The University of Missouri is still looking for dogs for its ongoing DM study. Dogs over ten years old, whether symptomatic or not, are needed. This phase of the study is looking for further factors that contribute to DM. Non-symptomatic dogs over the age of ten who have tested At Risk are especially valuable, as they may have factors which prevent development of DM, even when the gene is present. To submit samples for research, contact the University of Missouri.
There is an e-mail support group on Yahoo.com for those who have pets with DM.

 

About Chesapeakes

The History of the Chesapeake Bay Retriever


 

Very few sporting breeds of dogs have had as interesting a history as the Chesapeake Bay Retriever — which in 1964 became the official dog of the State of Maryland.

It is well documented that in the year of 1807, an English ship, trading between Newfoundland and England, was wrecked off of the coast of Maryland. The cargo and crew were rescued by an American ship on its way to Baltimore. Among the cargo taken aboard the American ship CANTON, were two Newfoundland puppies.

The male dog was subsequently named “Sailor,” and the bitch was named “Canton,” after the rescuing vessel.

The dog, which was red in color became the property of John Mercer of West River, Maryland. The bitch which was black and was given to Dr. James Stuart of Sparrows Point, Maryland, in gratitude for the hospitality shown the sailors of the wrecked brig. Both Mercer and Dr. Stuart were ardent hunters of waterfowl and soon discovered that the two dogs were exceptional retrievers.

Their retrieving abilities made their offspring much sought after by local duck hunters. By the mid-1800s the breed was clearly distinguishable. These dogs soon became legendary for their skill and stamina working in the ice-choked waters. Ducks and geese were abundant, but the icy water and rough seas of the Bay area made gunning a tough game.

During the mid to late 1800s the Carroll Island Gun Club, along the Gunpowder River northeast of Baltimore, was host to dignitaries from all over the world. Presidents and statesmen along with wealthy sportsmen who came to shoot over the famous dogs and watch them work. The club members bred “Chesapeakes” exclusively and the Carroll Island Gun Club held the pedigree of the “Chesapeake Bay Dog” for many years. Unfortunately, near the turn of the twentieth century a fire at the club destroyed all of the breeding records.

Many great lines of Chesapeake Bay dogs were taking shape as early as 1880. The breed went by many early names. The Chesapeake Bay Duck Dog, the Brown Winchester, the Otter Dog, the Newfoundland Duck Dog and the Red Chester Ducking Dog were but a few, but by 1887 a definite strain had evolved which were almost always dark brown, shading into a reddish brown. In 1890 the name was finally given as the Chesapeake Bay Retriever. This is when breeding records were started and Baltimore’s Chesapeake Bay Dog Club was formed.

The Chesapeake Bay Retriever was started by chance and developed out of the necessity for a special American purpose. The breed wasn’t developed in a structured breeding program by the wealthy as the Labrador was. Early on it was developed, largely, in an unrecorded, unsophisticated fashion out of the necessity of the times. From the beginning the Chesapeake was subject to rigid selection based solely on his efficiency. The poor specimen was soon discarded and the unsound and weak broke down under the relentless work in all kinds of weather conditions. Only the sound and strong survived to continue this unique American breed.

Puppies

COMMITMENT


Making a commitment to obtain a Chesapeake Bay Retriever puppy shouldn’t be taken lightly. It is a long-term commitment as the average lifespan for a Chesapeake is 8-15 years.

The Chesapeake Bay Retriever is a hardy active breed. As puppies, Chesapeakes requires a lot of socialization, basic obedience, and a firm but honest owner. If you cannot provide these basic items, then a Chesapeake puppy might not be for you.

Chesapeakes are best suited with a job to do – whether it be retrieving the morning paper to retrieving ducks from a blind to obedience work to agility trials. If you aren’t sure whether a Chesapeake Bay Retriever is right for you, but you’d like to learn more, please contact me. I’m happy to help guide you through making the right decision for you and your family.

For more information: [email protected]

SPRING 2022 BREEDING

Sire TBD x Salty

Sire TBD x Pond Hollow Sea Swept to CoolWater

Salty

Pond Hollow Sea Swept to CoolWater

SPRING 2022

OFA Hips: Good EIC: Clear PRA: Clear DM: Clear Salty is a 24″, 85 lb light sedge girl. She has excellent substance, a thick heavily waved coat, great depth of body and sound movement. She is PERSONALITY PLUS-sweet, intelligent, sassy, easy to live with and HAPPY. Salty has never met a stranger and is a HUGE smiler and will regularly Roo Roo Roo when she’s happy had has something to tell you. Salty is a strong swimmer and a fast stylish retriever. She produces puppies with good conformation, excellent bone and substance, great coats and wonderful dispositions. While we do not place puppies based on color, we anticipate all colors will be possible.

Show Report: Jesse

 

CH CoolWater's The Tide is High

Jesse takes Winners Bitch at the regional Specialty in Maryland under breeder judge Robyn Haskin.

This weekend was a Chessie Specialty in Maryland. There was a rather large entry with something like 48 entries. Jessie, Coolwater’s the Tide is High, was entered for ring experience. I really didn’t expect her to do anything as the competition in the Mid-Atlantic/New England area is very tough. I was absolutely thrilled when I received a phone call from Jessie’s co-owner telling me that Jessie took Winners Bitch for a 4 pt. major — and under a breeder judge at that! 

Congratulations to Tom Flores, Jessie’s co-owner and a huge thank you to Judge Robyn Haskin for awarding Jessie the win and Darlene Bergan for handling Jessie so nicely that day!