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“Lapa”
Pushistaya Lapochka

Cardigan Welsh Corgi

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Place of Birth

Russia

Current Location

Richland, Washington, USA

From

Russia

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Registration

Microchip: 643094100766107 RUS

Genetic Breed Result

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Cardigan Welsh Corgi

Though less common than their Pembroke cousins, the Cardigan Welsh Corgi is perfectly suited to move cattle, as well as be a smart, driven companion for the right people. This breed is highly trainable, and often compared to a German Shepherd Dog in drive and attitude. Cardigans have the bark of a much bigger dog!

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Genetic Stats

Predicted Adult Weight

30 lbs

Genetic Age
24 human years

Based on the date of birth provided

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Changes to this dog’s profile
  • On 12/29/2020 changed name from "Lapachka" to "Pushistaya Lapochka"

Would you like more information? You can contact us at:

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Breed Reveal Video

Our algorithms predict this is the most likely family tree to explain Lapa’s breed mix, but this family tree may not be the only possible one.

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Health Summary

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Lapa is at increased risk for one genetic health condition.

And inherited one variant that you should learn more about.

Intervertebral Disc Disease (Type I)

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Lapa inherited both copies of the variant we tested

How to interpret this result

Lapa has two copies of an FGF4 retrogene on chromosome 12. In some breeds such as Beagles, Cocker Spaniels, and Dachshunds (among others) this variant is found in nearly all dogs. While those breeds are known to have an elevated risk of IVDD, many dogs in those breeds never develop IVDD. For mixed breed dogs and purebreds of other breeds where this variant is not as common, risk for Type I IVDD is greater for individuals with this variant than for similar dogs.

What is Intervertebral Disc Disease (Type I)?

Type I Intervertebral Disc Disease (IVDD) is a back/spine issue that refers to a health condition affecting the discs that act as cushions between vertebrae. With Type I IVDD, affected dogs can have a disc event where it ruptures or herniates towards the spinal cord. This pressure on the spinal cord causes neurologic signs which can range from a wobbly gait to impairment of movement. Chondrodystrophy (CDDY) refers to the relative proportion between a dog’s legs and body, wherein the legs are shorter and the body longer. There are multiple different variants that can cause a markedly chondrodystrophic appearance as observed in Dachshunds and Corgis. However, this particular variant is the only one known to also increase the risk for IVDD.

Dilated Cardiomyopathy, DCM2

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Lapa inherited one copy of the variant we tested

What does this result mean?

Research indicates that this genetic variant is not likely to increase the risk that Lapa will develop this condition.

Scientific Basis

Dogs with Lapa’s breed have been included in research studies or have had follow-up by our experts that indicate that this genetic variant is not likely to increase the risk of Lapa developing clinical disease.

Impact on Breeding

This genetic result should not be the primary factor in your breeding decisions.

What is Dilated Cardiomyopathy, DCM2?

DCM is the most common acquired heart disease of adult dogs. The heart has two heavily muscled ventricles that pump blood away from the heart. This disease causes progressive weakening of the ventricles by reducing the muscle mass, which causes the ventricles to dilate. Dilated ventricles do not contract and circulate oxygenated blood well, which eventually leads to heart failure.

Breed-Relevant Genetic Conditions

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Von Willebrand Disease Type I, Type I vWD (VWF)

Identified in Cardigan Welsh Corgis

X-linked Severe Combined Immunodeficiency, X-SCID (IL2RG, Corgi Variant)

Identified in Cardigan Welsh Corgis

Progressive Retinal Atrophy, rcd3 (PDE6A)

Identified in Cardigan Welsh Corgis

Degenerative Myelopathy, DM (SOD1A)

Identified in Cardigan Welsh Corgis

Exercise-Induced Collapse, EIC (DNM1)

Identified in Cardigan Welsh Corgis

Additional Genetic Conditions

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Clinical Tools

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Explore the genetics behind your dog’s appearance and size.

Coat Color

Coat Color

E Locus (MC1R)
No dark mask or grizzle (EE)
K Locus (CBD103)
More likely to have a mostly solid black or brown coat (KBky)
Intensity Loci LINKAGE
No impact on coat pattern (Intermediate Red Pigmentation)
A Locus (ASIP)
Not expressed (atat)
D Locus (MLPH)
Dark areas of hair and skin are not lightened (DD)
Cocoa (HPS3)
No co alleles, not expressed (NN)
B Locus (TYRP1)
Brown hair and skin (bb)
Saddle Tan (RALY)
Not expressed (II)
S Locus (MITF)
Likely to have little to no white in coat (SS)
M Locus (PMEL)
One merle allele; may express merle (M*m)
R Locus (USH2A) LINKAGE
Likely no impact on coat pattern (rr)
H Locus (Harlequin)
No harlequin alleles (hh)
Other Coat Traits

Other Coat Traits

Furnishings (RSPO2) LINKAGE
Likely unfurnished (no mustache, beard, and/or eyebrows) (II)
Coat Length (FGF5)
Likely short or mid-length coat (GG)
Shedding (MC5R)
Likely heavy/seasonal shedding (CC)
Hairlessness (FOXI3) LINKAGE
Very unlikely to be hairless (NN)
Hairlessness (SGK3)
Very unlikely to be hairless (NN)
Oculocutaneous Albinism Type 2 (SLC45A2) LINKAGE
Likely not albino (NN)
Coat Texture (KRT71)
Likely straight coat (CC)
Other Body Features

Other Body Features

Muzzle Length (BMP3)
Likely medium or long muzzle (CC)
Tail Length (T)
Likely normal-length tail (CC)
Hind Dewclaws (LMBR1)
Unlikely to have hind dew claws (CC)
Blue Eye Color (ALX4) LINKAGE
Less likely to have blue eyes (NN)
Back Muscling & Bulk, Large Breed (ACSL4)
Likely normal muscling (CC)
Body Size

Body Size

Body Size (IGF1)
Larger (NN)
Body Size (IGFR1)
Larger (GG)
Body Size (STC2)
Intermediate (TA)
Body Size (GHR - E191K)
Intermediate (GA)
Body Size (GHR - P177L)
Larger (CC)
Performance

Performance

Altitude Adaptation (EPAS1)
Normal altitude tolerance (GG)
Appetite (POMC) LINKAGE
Normal food motivation (NN)
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Through Lapa’s mitochondrial DNA we can trace her mother’s ancestry back to where dogs and people first became friends. This map helps you visualize the routes that her ancestors took to your home. Their story is described below the map.

Haplogroup

A1a

Haplotype

A263

Map

A1a

Pushistaya Lapochka’s Haplogroup

A1a is the most common maternal lineage among Western dogs. This lineage traveled from the site of dog domestication in Central Asia to Europe along with an early dog expansion perhaps 10,000 years ago. It hung around in European village dogs for many millennia. Then, about 300 years ago, some of the prized females in the line were chosen as the founding dogs for several dog breeds. That set in motion a huge expansion of this lineage. It's now the maternal lineage of the overwhelming majority of Mastiffs, Labrador Retrievers and Gordon Setters. About half of Boxers and less than half of Shar-Pei dogs descend from the A1a line. It is also common across the world among village dogs, a legacy of European colonialism.

A263

Pushistaya Lapochka’s Haplotype

Part of the large A1a haplogroup, we see this haplotype most frequently in Cardigan Welsh Corgis and Pembroke Welsh Corgis.

Some other Embark dogs with this haplotype:

Shar Pei dogs think A1a is the coolest!

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The Paternal Haplotype reveals a dog’s deep ancestral lineage, stretching back thousands of years to the original domestication of dogs.

Are you looking for information on the breeds that Lapa inherited from her mom and dad? Check out her breed breakdown and family tree.

Paternal Haplotype is determined by looking at a dog’s Y-chromosome—but not all dogs have Y-chromosomes!

Why can’t we show Paternal Haplotype results for female dogs?

All dogs have two sex chromosomes. Female dogs have two X-chromosomes (XX) and male dogs have one X-chromosome and one Y-chromosome (XY). When having offspring, female (XX) dogs always pass an X-chromosome to their puppy. Male (XY) dogs can pass either an X or a Y-chromosome—if the puppy receives an X-chromosome from its father then it will be a female (XX) puppy and if it receives a Y-chromosome then it will be a male (XY) puppy. As you can see, Y-chromosomes are passed down from a male dog only to its male offspring.

Since Lapa is a female (XX) dog, she has no Y-chromosome for us to analyze and determine a paternal haplotype.

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