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“Tess”
DeWitt’s Majestic Mountain Ridge Lady Contessa

Alaskan Malamute

No bio has been provided yet

Place of Birth
Illinois, USA
Current Location
Virginia, USA
From
Illinois, USA

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Genetic Breed Result

Learn how it’s done

Alaskan Malamute

100.0% Alaskan Malamute
Alaskan Malamute Alaskan Malamute
The Alaskan Malamute is a large, fluffy spitz breed recognized as being one of the most ancient breeds of dogs. The forebears to the modern Malamute crossed the Bering Strait with their owners over 4,000 years ago. Their size, thick coat, and work drive make them ideal dogs for pulling sleds, but they also make amicable companions.
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Genetic Stats


Predicted Adult Weight

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Explore by tapping the parents and grandparents.

Breed Reveal Video

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

Health Summary

Tess has one variant that you should let your vet know about.

ALT Activity

Tess inherited both copies of the variant we tested

Why is this important to your vet?

Tess has two copies of a variant in the GPT gene and is likely to have a lower than average baseline ALT activity. ALT is a commonly used measure of liver health on routine veterinary blood chemistry panels. As such, your veterinarian may want to watch for changes in Tess's ALT activity above their current, healthy, ALT activity. As an increase above Tess’s baseline ALT activity could be evidence of liver damage, even if it is within normal limits by standard ALT reference ranges.

What is ALT Activity?

Alanine aminotransferase (ALT) is a clinical tool that can be used by veterinarians to better monitor liver health. This result is not associated with liver disease. ALT is one of several values veterinarians measure on routine blood work to evaluate the liver. It is a naturally occurring enzyme located in liver cells that helps break down protein. When the liver is damaged or inflamed, ALT is released into the blood stream.

Breed-Relevant Genetic Conditions

Factor VII Deficiency (F7 Exon 5)

Identified in Alaskan Malamutes

Polyneuropathy, NDRG1 Malamute Variant (NDRG1 Exon 4)

Identified in Alaskan Malamutes

Additional Genetic Conditions

Explore the genetics behind your dog’s appearance, size, and genetic diversity.
Coat Color

Coat Color

E Locus (MC1R)
No dark mask or grizzle (EE)
K Locus (CBD103)
More likely to have a patterned haircoat (kyky)
A Locus (ASIP)
Agouti (Wolf Sable) coat color pattern (awat)
D Locus (MLPH)
Dark areas of hair and skin are not lightened (DD)
B Locus (TYRP1)
Black or gray hair and skin (Bb)
Saddle Tan (RALY)
Not expressed (NN)
M Locus (PMEL)
No merle alleles (mm)
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 (GT)
Shedding (MC5R)
Likely heavy/seasonal shedding (CC)
Coat Texture (KRT71)
Likely straight coat (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)
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 (TC)
Body Size

Body Size

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

Performance

Altitude Adaptation (EPAS1)
Normal altitude tolerance (GG)
Appetite (POMC) LINKAGE
Normal food motivation (NN)

Through Tess’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

A1d

Haplotype

A41

Map

A1d

DeWitt’s Majestic Mountain Ridge Lady Contessa’s Haplogroup

This female lineage can be traced back about 15,000 years to some of the original Central Asian wolves that were domesticated into modern dogs. The early females that represent this lineage were likely taken into Eurasia, where they spread rapidly. As a result, many modern breed and village dogs from the Americas, Africa, through Asia and down into Oceania belong to this group! This widespread lineage is not limited to a select few breeds, but the majority of Rottweilers, Afghan Hounds and Wirehaired Pointing Griffons belong to it. It is also the most common female lineage among Papillons, Samoyeds and Jack Russell Terriers. Considering its occurrence in breeds as diverse as Afghan Hounds and Samoyeds, some of this is likely ancient variation. But because of its presence in many modern European breeds, much of its diversity likely can be attributed to much more recent breeding.

A41

DeWitt’s Majestic Mountain Ridge Lady Contessa’s Haplotype

Part of the large A1d haplogroup, we have not spotted this haplotype in village dogs yet. We do see it in 3 breeds: Alaskan Malamutes, Bichon Frises, and Posavac Hounds.

Some other Embark dogs with this haplotype:

The vast majority of Rottweilers have the A1d haplogroup.

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