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Terrazzo13

Terrazzo (formerly known asGranite)
Most Commonly Used Name: Terrazzo
Mode of Genetic Inheritance: Recessive
Morph Type: Single Recessive Mutation
Eye Color:  Black pupil & body ground colored iris

 

This simple recessive mutation was discovered by Craig Boyd from breeding two Rosy Rat Snakes together (an insular race of corns sometimes called Keys Corns) in the early 1990s. Terrazzos were originally marketed as Granite Corns, but in so much as the Terrazzo producers of that time did not frequent Internet chat forums, many of the mainstream corn snake keepers were unaware of this mutation. Despite warnings (along with pictures), members of one of the popular Online Corn Snake chat forums voted to re-assign the name Granite to Diffused Anery corns (former aka: Anery Bloodreds). It was awkward (and confusing) just a few months after this name re-assignment when Bill and Kathy Loves’ Book (Corn Snakes – The Comprehensive Owner’s Guide) was released, featuring a picture identifying a GRANITE CORN, but of course, that tan corn snake looked nothing like the NEW Granites (formerly Anery Bloodreds) that are black and gray. Jeff Galewood re-named the original Granite corns Terrazzos as he was (and still is) the primary producer of this beautiful mutation.
 
I called this the second “striped-type allele” because it IS the second one if you don’t count the striped version of Motley (since it is on the same locus with Motley). Several breeders (myself included) have performed breeding trials to verify that Terrazzos are not allelic to other gene mutations.  So far, evidence points to Terrazzos being a unique single recessive mutation.  I bred a classic Striped Corn mutant to a Key Corn Het for Terrazzo and yielded no mutant corns out of 21 fertile embryos.  We all agree that more trials are necessary to validate unique allele status for this beautiful corn.
Terrazzos have the beautiful tan and gray color scheme common to many of the middle-to-lower Keys Corns, and in typical Keys Corn fashion, their bellies are notably unlike bellies of mainland corns. Rarely is even one black scale found on these mutants, and the bellies are usually completely devoid of pattern or other colors. Some will have random patches of color on their bellies, but not black (this is not to say we won’t someDAY see black on Terrazzos – perhaps via out-crossing them with other mutations). Terrazzos are a lean race of corns, some reaching the length of typical mainland corns, but rarely the girth of common corns.  The absence of black on most Keys corns is primarily the result of captive selective breeding.  In the wild, it’s common to see black on these beautiful insular corns. 
 
 
Note: Not all Key Corns are devoid of black.  Many have black in their pattern AND on their bellies.  I point this out because we don’t yet know if the lack of melanin on the belly of Terrazzos if a feature of the mutation or of the respective race of Key Corns from which it derived.

 

What to expect:
Hatchling Terrazzos are dark-colored when compared to their adult counterparts, and at a glance you would not suspect they would mature to look so much like a Hypo mutant. Except for pattern, some adults have colors identical to the most Hypo mutants (virtually devoid of black). I have bred Keys Corns to Hypo mutants and re-produced Hypo mutants, but that does not always happen. It would be totally understandable that someone thought the Keys Corn they had was a Hypo mutant, and bred it to a Hypo mutant – thereby infusing the Hypo mutation into that family line.

Upon first seeing a Terrazzo, you would understandably think you were seeing a classic Striped mutant. The stripes of Terrazzos are very similar to those of the classic Striped mutants, but there are obvious distinctions. There have not been enough Terrazzos produced to declare a “typical” pattern for them, but so far, the rare and somewhat elusive target for this snake is a totally patternless corn. Some of the first Terrazzos had very little or NO pattern, other than an over-wash of speckles – looking as though the pattern had been shattered to fragments (giving the snake the appearance of GRANITE stone).

We reproduce both the original Boyd line which are more tan and less red than the JMG line.  The JMG line began with the pairing of a Terrazzo X South Dade County corn (many South Dade corns resemble Key Corns), so his line includes both the overall tan color scheme and the tan with reddish stripes scheme.  The latter obviously the throwback colors of the mainland ancestor.  Both are beautiful.  Given the persistence of polygenetic traits, I’m sure many color schemes will manifest through captive breeding projects.

 

SURPLUS section of this web site).  We do not provide pictures of individual hatchling snakes for sale, nor do we recommend that you ever choose a new pet based on an image of its neonatal form.  Corns change so dramatically from hatchling to adult, they will NEVER have the same colors or contrasts throughout maturity.While most of the snakes we produce will mature to resemble the featured adult image(s) on our web site, unlike manufactured products that are respectively clones of each other, the nature of polygenic variation results in each animal being similar but not identical to others of its morph. The snake we select for you may not mature to be identical to the pictured examples, but will be chosen based on our experience of observing which neonates will mature to properly represent their respective morph.  We take this responsibility very seriously, and therefore publish the guarantee that we will exchange your SMR snake if it does not mature to be like our advertised examples.

Striped Tessera 2014

Striped Tessera (no aka)
Most Commonly Used Name: Striped Tessera
Mode of Genetic Inheritance: Dominant
Morph Type: Both Dominant Recessive Gene Mutations
Eye Color:  Black pupil with ground zone-colored iris
 

FIRST, what makes Tesseras so expensive? Other than appearance, the primary (and inherent) value of Tessera-type Corns is their mode of inheritance.  Since they are dominant to wild type, pairing any Tessera Type that is a Visual Het to ANY corn (other than a Tessera-type) will render 50% Tessera mutants in the F1 (first) out-crossed generation.  The results of pairing an Tessera homozygote with ANY corn snake (other than a Tessera-type) will render 100% Tessera mutants.

 
Striped Tesseras are at least homozygotes of the recessively-inherited STRIPE mutation and the dominantly-inherited TESSERA mutation. At this time, there appears to be no direct mutational relationship between those two mutations (when in genetic union), except for the seemingly collateral features that distinguish virtually all Striped Tesseras from simple Striped mutants. The features that are demonstrated in most Striped Tesseras that distinguish them from simple Striped corn mutants are:
 

  • Contiguity of pattern. Striped Tesseras have remarkably continuous striping and if it does break – unlike simple mutant Striped corns – it resumes in the same form – without fading to broken striping and eventually no striped pattern at all, as we see in ALL simple mutant Striped corns.
  • Stripe that extends to the tail and beyond.  I have never seen a simple mutant Striped corn that had a stripe that continued to the tail tip.  I’ve seen nearly full striping in some lines of Striped Motleys, but never in Striped mutants.  When one corn possesses both the STRIPE and the TESSERA mutations, most of these corns have striping that continues to the tip of the tail, regardless of how many stripe breaks there are between the neck and tail tip.  When the striped pattern of Striped corn mutants begins to break up and/or fade, it does not resume in recognizable form.  My reference to “tail pattern” is the dorsal location that is the polar opposite of the cloaca (polar as opposing points on the same vertical plane).
  • Variable stripe width. It is not common, but some of the Striped Tesseras we’ve produced have varying stripe width, which is something seldom observed on simple Striped mutants.  Generally speaking, the striping of Striped Tesseras widens as it extends tail-ward.  Some have intermittent and abrupt changes of width from the neck to the tail, but except for gradual widening of stripe, some have remarkably clean stripes.  The question that can’t help but be asked is, “In STRIPED TESSERAS, is the striped pattern the result of the Striped mutation, the striped version of the Motley mutation; Striped Motley. OR the striped version of the Tessera mutation?”  I don’t know the answer at this time. 

Note the comparison of a Striped Amel (Het Caramel) and a Striped Tessera in this image.

stvsstte4792my11

 
 
 
What to expect:
Striped Tesseras are still fairly rare. So far, the only feature that is atypical – compared to typical corn snake mutations – is that many of the non-mutant siblings of Tessera types seem to have enhanced pattern and color features.  So far, I don’t recognize any traditional markers that are unique to hybrid colubrids, since the collateral sibling features to which I refer are – so far – in the realm of improving existing corn snake features (i.e. some non-Tesseras have better, brighter, cleaner, and/or more consistent colors and markings).  I’m intrigued by the collateral nature of some of the non-Tessera siblings co-incidentally having improved characteristics without changing standard features of the species (i.e. body shape, belly checkering, head pattern, shape and number of markings).
 
As hatchlings, Striped Tesseras generally look like Striped corns, except for the precision of striping and retention of black pigment seen in most Striped Tesseras. Other than the obviously better quality of striping in Striped Tesseras, the primary difference between the closest corn snake phenotype (Striped Motley) and Striped Tesseras  is that of the dominant genetic inheritance of the Tessera.  Naturally, the Stripe and Motley mutations (which are alleles of the Motley locus) are inherited in recessive fashion. Just like all corns, Striped Tesseras gain improved color saturation as they mature. 
 
 
History of the Tessera Mutation:
In 2007, Graham Criglow asked KJ Lodrigue to order a 1.2 trio of Striped Motleys that were advertised on one of the popular Online Classified sites – since Graham’s job prevented him from personally receiving them at that time.  When they arrived, KJ discovered that they constituted a 2.1 reverse trio (two males and one female) instead of the advertised 1.2 trio (one male and two females).  KJ and Kasi recommended that Graham gift the extra male to me, and that’s what Graham did.  Profound thanks to Graham, KJ, and Kasi for that gracious and fortuitous gift.  In 2008, both the Lodrigues and I independently bred our males (Graham’s and mine) to novel (unrelated) corns. I produced about 24 TESSERAS (so named by the Lodrigues for the tessellated lateral markings) from over 50 fertile eggs, but since the Lodrigues were in the middle of a career move to another State, they were less fortunate, producing just four non-mutant Okeetee-looking corns.  My Tesseras were produced by the pairing of the male Tessera to three novel female corns (two F1 Locality Okeetees from Chip Bridges Rhett Butler Line and one Okeetee-ish female, Het for Stripe and Amel).  Imagine my surprise in seeing what we thought were nearly flawless Striped Motleys from three different females, only one of which was Het for a recessive pattern mutation?  After the first brood of 50% Tesseras hatched from the female that was het for Stripe and Amel, except for the perfection of pattern, I was not thinking new dominant mutation, but when both wild-type Okeetees produced the same results, it was obvious that a new mutation was discovered.

Upon receiving the reverse trio from the seller, we all commented on the mutual peculiarity of the phenotypes.  Most appeared to be the most perfectly Striped Motleys ever seen – in so much as their dorsal stripes were nearly contiguous from neck to tail tip (something never before seen in any corn snake pattern mutant) – but that was hardly possible if the admission of the breeder were true – that they were products of pairing a Striped corn with an Okeetee corn.  How could these descendants of a Striped corn bred to an Okeetee be Motley types, instead of Striped?  It is still unclear if those 2.1 Tesseras were F1s (first familial generation) or F2s (the originator of this line is now out of the hobby and difficult to reach – for clarification).  If these three Tesseras are F1s, my deduction is that the striped corn he used in the original pairing was actually Striped AND Tessera.  Even if those three were F2s, the likelihood of the mutant patriarch being a Striped Tessera is strong.

In the 100+ Tessera mutants produced by me as of Fall, 2010, I’m seeing the following features:
The most obvious advantage of having Tesseras in your breeding inventory (aside from their inherent beauty) is that because the mutation is dominantly inherited, 50% of every brood of corns from them will be Tessera mutants. With most other corn snake mutations, one must raise all the Het F1 progeny, and won’t receive any mutants until F2 reproduction (a task that can take four to six years).  In the course of adding Tessera to the myriad current patterns and colors of corns, an entirely new market is now in the making.

Predominantly contiguous dorsal striping is the most unique feature of most Tesseras.  Even when the stripe is broken, it resumes immediately thereafter (unlike Striped and Motley mutants whose dorsal striping never resumes with any degree of renewal). Roughly 1/3 of all that have been produced so far have no stripe breaks.  Another 1/3 or so have two to four stripe breaks, and the other 1/3 can have five to 20+ stripe breaks, but those breaks are merely interruptions of the stripe.  Not unlike very good Striped Motleys, many Tesseras have an interruption of stripe at the girdle (anatomical location – polar to the cloaca), but unlike Striped and Motley mutants, the dorsal stripe almost always continues to the tail tip.  Thus far, fully striped Tesseras have been produced from parents with some-to-many dorsal stripe breaks.  Hence, broken-striped Tesseras can produce fully striped striped Tesseras, even though their stripe is broken.  Incidentally, none of the original 2.1 original Tesseras in this line have complete dorsal striping, but many of their progeny and grand progeny do. 

More than 2/3 of the Tesseras produced by me so far have atypically large amounts of black pigment in their non-ventral pattern — a feature roughly 1% of all Striped and Motley mutants have demonstrated to date.  Less than 1/4 of all Tesseras produced by me have little to no black in their markings, and these are mostly Striped Tesseras.

The belly patterns of most Tesseras that are not also homozygous for other pattern mutations (i.e. Stripe) are all over the charts, but so far, all the bellies on Striped Tesseras have had no pattern at all.  Apparently, the STRIPE mutation trumps what normally occurs on the bellies of Tessera mutants, thereby not allowing belly pattern.

Having grafted another entire branch on the already sprawling corn snake family tree, we think the Tessera mutation will offer genetic flexibility never before possible; mainly in the realm of making Stripe and Motley types without losing the black (white in albinos).  Imagine all the current colors of corns infused with the Tessera, Striped Tessera, and Motley Tessera patterns?

Important Note: 
  These images are not renderings of the actual animals being offered, (except for uniquely offered snakes found in the SURPLUS section of this web site).  We do not provide pictures of individual hatchling snakes for sale, nor do we recommend that you ever choose a new pet based on an image of its neonatal form.  Corns change so dramatically from hatchling to adult, they will NEVER have the same colors or contrasts throughout maturity. While most of the snakes we produce will mature to resemble the featured adult image(s) on our web site, unlike manufactured products that are respectively clones of each other, the nature of polygenic variation results in each animal being similar but not identical to others of its morph. The snake we select for you may not mature to be identical to the pictured examples, but will be chosen based on our experience of observing which neonates will mature to properly represent their respective morph.  We take this responsibility very seriously, and therefore publish the guarantee that we will exchange your SMR snake if it does not mature to be like our advertised examples.

 

Caramel Tessera13

Caramel Tessera (no aka)
Most Commonly Used Name: Caramel Tessera
Mode of Genetic Inheritance: Dominant
Morph Type: Single Dominant Mutation (Tessera) & simple recessive (Caramel)
Eye Color:  Black pupil & body ground colored iris
 
 

FIRST, what makes Tesseras so expensive? Other than appearance, the primary (and inherent) value of Tessera-type Corns is their mode of genetic inheritance.  Since they are dominant to wild type, pairing any Tessera Type that is a Visual Het to ANY corn snake (other than a Tessera-type) will render 50% Tessera mutants in the F1 (first) out-crossed generation.  The results of pairing an Tessera homozygote with ANY corn snake (other than a Tessera-type) will render 100% Tessera mutants.

Adding the Caramel mutation to TESSERA, obviously results in an Caramel Tessera.  Because all Caramel Tesseras are so close to original morph colors, expect to see more gold and brown tones.  
 
History of the Tessera Mutation:
In 2007, Graham Criglow asked KJ Lodrigue to order a 1.2 trio of Striped Motleys that were advertised on one of the popular Online Classified sites – since Graham’s job prevented him from personally receiving them at that time.  When they arrived, KJ discovered that they constituted a 2.1 reverse trio (two males and one female) instead of the advertised 1.2 trio (one male and two females).  KJ and Kasi recommended that Graham gift the extra male to me, and that’s what Graham did.  Profound thanks to Graham, KJ, and Kasi for that gracious and fortuitous gift.  In 2008, both the Lodrigues and I independently bred our males (Graham’s and mine) to novel (unrelated) corns. I produced about 24 TESSERAS (so named by the Lodrigues for the tessellated lateral markings) from over 50 fertile eggs, but since the Lodrigues were in the middle of a career move to another State, they were less fortunate, producing just four non-mutant Okeetee-looking corns.  My Tesseras were produced by the pairing of the male Tessera to three novel female corns (two F1 Locality Okeetees from Chip Bridges Rhett Butler Line and one Okeetee-ish female, Het for Stripe and Amel).  Imagine my surprise in seeing what we thought were nearly flawless Striped Motleys from three different females, only one of which was Het for a recessive pattern mutation?  After the first brood of 50% Tesseras hatched from the female that was het for Stripe and Amel, except for the perfection of pattern, I was not thinking new dominant mutation, but when both wild-type Okeetees produced the same results, it was obvious that a new mutation was discovered.

Upon receiving the reverse trio from the seller, we all commented on the mutual peculiarity of the phenotypes.  Most appeared to be the most perfectly Striped Motleys ever seen – in so much as their dorsal stripes were nearly contiguous from neck to tail tip (something never before seen in any corn snake pattern mutant) – but that was hardly possible if the admission of the breeder were true – that they were products of pairing a Striped corn with an Okeetee corn.  How could these descendants of a Striped corn bred to an Okeetee be Motley types, instead of Striped?  It is still unclear if those 2.1 Tesseras were F1s (first familial generation) or F2s (the originator of this line is now out of the hobby and difficult to reach – for clarification).  If these three Tesseras are F1s, my deduction is that the striped corn he used in the original pairing was actually Striped AND Tessera.  Even if those three were F2s, the likelihood of the mutant patriarch being a Striped Tessera is strong.

 

What to expect:
At this early period in the Tessera’s resume, we still don’t know what phenotypic potentials exist.  So far, the only behavior that is atypical for a corn snake mutation is that many of the non-mutant siblings of Tessera types seem to have enhanced pattern and color features.  So far, I don’t see any hybrid markers, since the collateral sibling features to which I refer are – so far – in the realm of improving existing corn snake features (i.e. some non-Tesseras have better, brighter, cleaner, and/or more consistent colors and markings). 

 

Important Note: 
  These images are not renderings of the actual animals being offered, (except for uniquely offered snakes found in the SURPLUS section of this web site).  We do not provide pictures of individual hatchling snakes for sale, nor do we recommend that you ever choose a new pet based on an image of its neonatal form.  Corns change so dramatically from hatchling to adult, they will NEVER have the same colors or contrasts throughout maturity. While most of the snakes we produce will mature to resemble the featured adult image(s) on our web site, unlike manufactured products that are respectively clones of each other, the nature of polygenic variation results in each animal being similar but not identical to others of its morph. The snake we select for you may not mature to be identical to the pictured examples, but will be chosen based on our experience of observing which neonates will mature to properly represent their respective morph.  We take this responsibility very seriously, and therefore publish the guarantee that we will exchange your SMR snake if it does not mature to be like our advertised examples.

 

 

What to expect:
At this early period in the Tessera’s resume, we still don’t know what phenotypic potentials exist.  So far, the only trait(s) that are atypical for a corn snake mutation is that many of the non-mutant siblings of Tessera types seem to have enhanced pattern and color features.  So far, I don’t see any hybrid markers, since the collateral sibling features to which I refer are – so far – in the realm of improving existing corn snake features (i.e. some non-Tesseras have better, brighter, cleaner, and/or more consistent colors and markings).

 
 
What to expect:
At this early period in the Tessera’s resume, we still don’t know what phenotypic potentials exist.  So far, the only behavior that is atypical for a corn snake mutation is that many of the non-mutant siblings of Tessera types seem to have enhanced pattern and color features.  So far, I don’t see any hybrid markers, since the collateral sibling features to which I refer are – so far – in the realm of improving existing corn snake features (i.e. some non-Tesseras have better, brighter, cleaner, and/or more consistent colors and markings). 

 

Tessera-13

Tessera (no aka)
Most Commonly Used Name: Tessera
Mode of Genetic Inheritance: Dominant
Morph Type: Single Dominant Mutation
Eye Color:  Black pupil & body ground colored iris
 
 

FIRST, what makes Tesseras so expensive? Other than appearance, the primary (and inherent) value of Tessera-type Corns is their mode of inheritance.  Since they are dominant to wild type, pairing any Tessera Type that is a Visual Het to ANY corn snake (other than a Tessera-type) will render 50% Tessera mutants in the F1 (first) out-crossed generation.  The results of pairing an Tessera homozygote with ANY corn snake (other than a Tessera-type) will render 100% Tessera mutants.

 
History of the Tessera Mutation:
In 2007, Graham Criglow asked KJ Lodrigue to order a 1.2 trio of Striped Motleys that were advertised on one of the popular Online Classified sites – since Graham’s job prevented him from personally receiving them at that time.  When they arrived, KJ discovered that they constituted a 2.1 reverse trio (two males and one female) instead of the advertised 1.2 trio (one male and two females).  KJ and Kasi recommended that Graham gift the extra male to me, and that’s what Graham did.  Profound thanks to Graham, KJ, and Kasi for that gracious and fortuitous gift.  In 2008, both the Lodrigues and I independently bred our males (Graham’s and mine) to novel (unrelated) corns. I produced about 24 TESSERAS (so named by the Lodrigues for the tessellated lateral markings) from over 50 fertile eggs, but since the Lodrigues were in the middle of a career move to another State, they were less fortunate, producing just four non-mutant Okeetee-looking corns.  My Tesseras were produced by the pairing of the male Tessera to three novel female corns (two F1 Locality Okeetees from Chip Bridges Rhett Butler Line and one Okeetee-ish female, Het for Stripe and Amel).  Imagine my surprise in seeing what we thought were nearly flawless Striped Motleys from three different females, only one of which was Het for a recessive pattern mutation?  After the first brood of 50% Tesseras hatched from the female that was het for Stripe and Amel, except for the perfection of pattern, I was not thinking new dominantmutation, but when both wild-type Okeetees produced the same results, it was obvious that a new mutation was discovered.

 

Upon receiving the reverse trio from the seller, we all commented on the mutual peculiarity of the phenotypes.  Most appeared to be the most perfectly Striped Motleys ever seen – in so much as their dorsal stripes were nearly contiguous from neck to tail tip (something never before seen in any corn snake pattern mutant) – but that was hardly possible if the admission of the breeder were true – that they were products of pairing a Striped corn with an Okeetee corn.  How could these descendants of a Striped corn bred to an Okeetee be Motley types, instead of Striped?  It is still unclear if those 2.1 Tesseras were F1s (first familial generation) or F2s (the originator of this line is now out of the hobby and difficult to reach – for clarification).  If these three Tesseras are F1s, my deduction is that the striped corn he used in the original pairing was actually Striped AND Tessera.  Even if those three were F2s, the likelihood of the mutant patriarch being a Striped Tessera is strong.


What to expect:
At this early period in the Tessera’s resume, we still don’t know what phenotypic potentials exist.  So far, the only trait(s) that are atypical for a corn snake mutation is that many of the non-mutant siblings of Tessera types seem to have enhanced pattern and color features.  So far, I don’t see any hybrid markers, since the collateral sibling features to which I refer are – so far – in the realm of improving existing corn snake features (i.e. some non-Tesseras have better, brighter, cleaner, and/or more consistent colors and markings).
 

In the 100+ Tessera mutants produced by me as of Fall, 2010, I’m seeing the following features:

 
The most obvious advantage of having Tesseras in your breeding inventory (aside from their inherent beauty) is that because the mutation is dominantly inherited, 50% of every brood of corns from them will be Tessera mutants. With most other corn snake mutations, one must raise all the Het F1 progeny, and won’t receive any mutants until F2 reproduction (a task that can take four to six years).  In the course of adding Tessera to the myriad current patterns and colors of corns, an entirely new market is now in the making.
 

Predominantly contiguous dorsal striping is the most unique feature of most Tesseras.  Even when the stripe is broken, it resumes immediately thereafter (unlike Striped and Motley mutants whose dorsal striping never resumes with any degree of renewal). Roughly 1/3 of all that have been produced so far have no stripe breaks.  Another 1/3 or so have two to four stripe breaks, and the other 1/3 can have five to 20+ stripe breaks, but those breaks are merely interruptions of the stripe.  Not unlike very good Striped Motleys, many Tesseras have an interruption of stripe at the girdle (anatomical location – polar to the cloaca), but unlike Striped and Motley mutants, the dorsal stripe almost always continues to the tail tip.  Thus far, fully striped Tesseras have been produced from parents with some-to-many dorsal stripe breaks.  Hence, broken-striped Tesseras can produce fully striped striped Tesseras, even though their stripe is broken.  Incidentally, none of the original 2.1 original Tesseras in this line have complete dorsal striping, but many of their progeny and grand progeny do.

 

More than 2/3 of the Tesseras produced by me so far have atypically large amounts of black pigment in their non-ventral pattern — a feature roughly 1% of all Striped and Motley mutants have demonstrated to date.  Less than 1/4 of all Tesseras produced by me have little to no black in their markings, and these are mostly Striped Tesseras.

 

te01110953-042411v
The belly patterns are all over the charts.  A precious few have enough belly checkering to qualify them as wild-type common corns — until you flip them over to see their mutant pattern elsewhere.  About 1/3 of them have roughly 15% to 30% of the volume of checkering seen in wild-types, and about 1/3 or more have virtually no belly checkering at all.  Some of the ones with NO belly checkering have organized strings of black markings running the length of both sides of the belly, along the ventral crest.

 

Having grafted another entire branch on the already sprawling corn snake family tree, we think the Tessera mutation will offer genetic flexibility never before possible; mainly in the realm of making Stripe and Motley types without losing the black (or white in albinos).  Imagine all the current colors of corns infused with the Tessera, Striped Tessera, and Motley Tessera patterns?
 
 
 
 
 
 
 
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Important Note:

  These images are not renderings of the actual animals being offered, (except for uniquely offered snakes found in the SURPLUS section of this web site).  We do not provide pictures of individual hatchling snakes for sale, nor do we recommend that you ever choose a new pet based on an image of its neonatal form.  Corns change so dramatically from hatchling to adult, they will NEVER have the same colors or contrasts throughout maturity. While most of the snakes we produce will mature to resemble the featured adult image(s) on our web site, unlike manufactured products that are respectively clones of each other, the nature of polygenic variation results in each animal being similar but not identical to others of its morph. The snake we select for you may not mature to be identical to the pictured examples, but will be chosen based on our experience of observing which neonates will mature to properly represent their respective morph.  We take this responsibility very seriously, and therefore publish the guarantee that we will exchange your SMR snake if it does not mature to be like our advertised examples.

Striped Amber-13

 

Striped Amber (no aka)
Most Commonly Used Name: Striped Amber
Mode of Genetic Inheritance: Recessive

Type: Triple mutation compound (Stripe + Caramel + Hypo)

Eye Color: Black pupil & body ground colored iris (some can be so hypomelanistic, their pupils can be gray to dark red). 

Combining the three recessive gene mutations; Caramel + Hypo = Amber & Stripe renders this beautiful striped yellow corn.  Except for the black pupils, many of our striped ambers look like Striped Butters (red pupils).

What to expect:
Both male and female hatchlings look alike (essentially gold with dark gold or brown linear stripes), but all will mature to be some shade of yellow with gold or light brown stripes.

Important Note:
  These images are not renderings of the actual animals being offered, (except for uniquely offered snakes found in the SURPLUS section of this web site).  We do not provide pictures of individual hatchling snakes for sale, nor do we recommend that you ever choose a new pet based on an image of its neonatal form.  Corns change so dramatically from hatchling to adult, they will NEVER have the same colors or contrasts throughout maturity. While most of the snakes we produce will mature to resemble the featured adult image(s) on our web site, unlike manufactured products that are respectively clones of each other, the nature of polygenic variation results in each animal being similar but not identical to others of its morph. The snake we select for you may not mature to be identical to the pictured examples, but will be chosen based on our experience of observing which neonates will mature to properly represent their respective morph.  We take this responsibility very seriously, and therefore publish the guarantee that we will exchange your SMR snake if it does not mature to be like our advertised examples.

 

 

Diffused13

NOW READY FOR SHIPPING
Diffused (aka: bloodred – see details below)
Note: Expect DIFFUSED and BLOODRED to be used synonymously
Most Commonly mis-used Name: Bloodred See details below
Mode of Genetic Inheritance: Recessive
Morph Type: Single Recessive Mutation
Eye Color: Black pupil & body ground colored iris

 


If you expected to see beautifully diffused corns with saturated red/rust/mahogany colors, click here _____> Bloodred Corn Snaketo see the enhanced version of this color mutation.

A few years ago, due to confusion regarding the heritability of the Bloodred’s base mutation (namely that the namesake snakes were not red and/or diffused), the base mutation name was changed away from Bloodred – to Diffused.  The mechanics of this gene mutation barely diffuse the F1 homozygotesthrough maturity (if at all), so do not expect Diffused corns to look like Bloodreds.  It is currently believed that Bloodred corns are the product of enhancing the base mutation via polygenetic trait modification (selective breeding) to render a red and almost pattern-less (highly diffused) corn snake.  That is not the opinion of this author, but in the absence of empirical evidence to the contrary, the best hobby and market interests are not served by published opposition to popular opinion.  In other words, I’m not in favor of changing the morph name away from the original Bloodred since the new name Diffused is equally incorrect.  Without polygenetic modification, Diffused corns are not diffused.

 

Brief history on Diffused mutants VS Bloodred mutants:

Initially, the corn snake gene mutation, Diffusion (formerly called Bloodred) was described as being recessively inherited, but many of the F1 generational heterozygotes exhibited some of the obvious features of the gene mutation homozygotes.  It is extremely rare for simple recessive F1 heterozygotes to exhibit ANY features of their recessively inherited genetic mutation.  For example, F1 heterozygous Amel corn snakes have no markers that demonstrate a hint of their simple recessive mutation, Amel .  The paradoxical partial-exhibition of the Diffusion mutation in the heterozygotes resulted in the Diffused mutation being re-described as codominant – (codom for short) in heritable function, but was tagged with the descriptor, variable.  At that time, variable codom seemed an accurate and satisfactory genetic description for the radical color and pattern diversity among members of this mutation, but far too many genetic anomalies persisted. Identification of the inheritance of this mutation is once again considered simple recessive, but the Bloodred corn that most of us identify with toDAY is virtually always the aggregate of traits resulting from the Diffused gene mutation PLUS polygenetic traits promoted by selectively breeding toward the highest expressions of pattern reduction, diffusion, and red color saturation.

 

 

What to expect:
As neonates, Diffused corns are often heavily patterned, most of them exhibiting black (or partially black) scales bordering some of the pattern blotches, and most of them have some degree of black belly checkering (something I have NEVER seen on good Bloodreds).  Head patterns are highly variable, but exactly like wild-type corns.

Some Diffused corns may exhibit slight diffusion throughout maturation, but unlike their prestigious BLOODRED cousins, every Diffused adult I’ve seen displayed prominent markings (head, body, and belly).  Many of the early Diffused corns over ten years ago were overly inbred and therefore suffered poor fertility (not to mention – the progeny of many of the first generations were stubbornly lizard lovers – refusing to eat pinky mice).  Thankfully, through out-crossing in our projects to improve or change colors and patterns, Diffused and Bloodred corns no longer rank high in either of those categories;  low ferility or reluctance to eat rodents.   In fact, there are some seasons in which Diffused and Bloodred corns are among the best feeding of our corn snake neonates.

 

 

General Note:
While most of the snakes we produce will mature to resemble the featured adult image(s) on our web site, unlike manufactured products that are respectively identical to each other, the nature of polygenic variation results in no two specimens being exactly the same.  The snake we select for you may not mature to be identical to the pictured examples, but will be chosen based on our experience of observing which neonates will mature to properly represent their respective morph.  We take this responsibility very seriously, and therefore publish the guarantee that we will replace your SMR snake if it does not mature to be like our advertised examples.

 

Okeetee13

NOW READY FOR SHIPPING
 
Okeetee (no aka)
Most Commonly Used Name: Okeetee
Mode of Genetic Inheritance: Dominant (wild-type) + Selective Variation
Morph Type: Selective Variation of wild-type
Eye Color: Black pupil & body ground colored iris

 

Arguably the most famous example of a corn snake morph named for its geographic origins, the Okeeteeis also considered to be the most beautiful non-mutant corn snake in the species. First popularized by Carl Kauffeld in at least two books describing his field discoveries of this beautiful and robust race of corn snake on or near the Okeetee Hunt Club in South Carolina, Okeetees have since been selectively bred for extremely bright and saturated colors. When we say locality Okeetee, we are referring to animals whose genetic origins can be traced to the Jasper County, South Carolina region. There is nothing magic about the Hunt Club that makes only animals in that area outstanding looking. Corns in other states of the Corn Snake’s range can be just as beautiful, but proportionally speaking, the corns from this region outnumber those that have inferior color and pattern.  Okeetees that have been selectively bred for appearance and consequently satisfy a visual hobby standard are sometimes called Okeetee morphs, but more often are called simply Okeeteecorns.

Okeetees (in the hobby) are a premier example of the promotion of polygenic traits through selective breeding. By breeding together specimens with desired characteristics, through generational selection of pairing only the ones with superior target features, it doesn’t take long to render stunning examples of the morph – without the aid of gene mutations. Please, do not attempt to hunt for Okeetee corns on private property. The Okeetee Hunt Club in South Carolina expressly forbids trespassing, and it is possible to be legally prosecuted, if caught on their land without express written permission.

 

What to expect:
Oddly, most of the best Okeetees we produce are the least beautiful – as hatchlings. If you tossed a good Okeetee in a bucket of hatchling common corns, you’d likely not identify it until after several months of maturity. Neonates should show bold black blotch margins, but until one or two sheds, the bright ground colors are not obvious. By that time, blotch colors are beginning to show, and adult Okeetees should have clean (low color freckling) ground and blotch color zones, separated by noticeably broad, black borders. Most of the spectacular examples of this morph are so good, they are sold by other names in the hobby – and are consequently more expensive (i.e. Extreme Okeetees, Buckskin Okeetees, Banded Okeetees). Another notable feature of this morph is its robust size and feeding vigor. Okeetees (which CAN have orange on their bellies – but is relatively rare at this time) have the most spectacular black and white checkered bellies, compared to other wild-type corns.
 
okex007
Do not expect any hatchling/neonate Okeetee to look anything like the adults. This picture shows an adult female Extreme Okeetee with several of her newly hatched babies (no, she was not present when they hatched in the incubator). This adult looked exactly like the babies shown in this image when she was their size.
 

 

 

 

Important Note:
These images are not renderings of the actual animals being offered, (except for uniquely offered snakes found in the SURPLUS section of this web site). We do not provide pictures of individual hatchling snakes for sale, nor do we recommend that you ever choose a new pet based on an image of its neonatal form. Corns change so dramatically from hatchling to adult, they will NEVER have the same colors or contrasts throughout maturity.While most of the snakes we produce will mature to resemble the featured adult image(s) on our web site, unlike manufactured products that are respectively clones of each other, the nature of polygenic variation results in each animal being similar but not identical to others of its morph. The snake we select for you may not mature to be identical to the pictured examples, but will be chosen based on our experience of observing which neonates will mature to properly represent their respective morph. We take this responsibility very seriously, and therefore publish the guarantee that we will exchange your SMR snake if it does not mature to be like our advertised examples.

 

 

 

Motley 103012s

#123012
Motley Corn from Salmon Snow Motley parentage
Male
d.o.h. 2011
35″ long on December 29, 2012

 

Motley (no aka)
Mode of Genetic Inheritance: Recessive
Morph Type: Single Recessive Mutation
Most Commonly Used Name: Motley
Eye Color: Black pupil & body ground colored iris

 

The first description of this corn snake pattern mutation was published by the late Dr. H. Bernard Bechtel in the 1980s.  His breeding trials demonstrated the heritability of this mutation to be simple recessive.  The distinguishing feature of those is belly checkering.  Good Motleys have an orderly and contiguous pattern of spots down the dorsum that represent spaces in what appears to be a continuous, wide stripe of color running from the neck tail-ward.  The size, shape, location, organization, and number of circular pattern interruptions on the back define the grade of individuals, but until recently, the one pattern distinction we could rely upon was that of having no checkers on their belly.  Lately, we’re seeing Motleys with some black checkering, but it’s random and sparse.  I suspect that one DAY we’ll see Motleys with quite a bit of belly checkering.  In fact, certain genetic compounds of Motley have somewhat reliable belly markings (i.e. Sunglow Motley and Lavender Motley).

 

What to expect:
Thankfully, there is little change (if any) in the markings from hatchling to adult, but one characteristic impossible not to notice is that of diffusion of pattern and color throughout maturity.  This essentially does change the pattern appearance, and it certainly does have interesting impacts on color compounds of Motley.  Not unlike the “Diffused” mutation (aka: Bloodred) that diffuses color and pattern, Motleys virtually always enhance any other color or pattern mutation with which they have genetic union.  Do not expect contiguous and orderly dorsal patterning, as Motleys with the best patterns are still in a minority in this morph.  BTW, they are rare, but some non-mutant corns have dorsal pattern that is very similar to Motleys, but still a dependable distinguishing feature is the belly.  If a Motley-looking corn has a busily checkered belly, it should not be a Motley mutant.
 
 

Important Note:
  These images are not renderings of the actual animals being offered, (except for uniquely offered snakes found in the SURPLUS section of this web site).  We do not provide pictures of individual hatchling snakes for sale, nor do we recommend that you ever choose a new pet based on an image of its neonatal form.  Corns change so dramatically from hatchling to adult, they will NEVER have the same colors or contrasts throughout maturity. While most of the snakes we produce will mature to resemble the featured adult image(s) on our web site, unlike manufactured products that are respectively clones of each other, the nature of polygenic variation results in each animal being similar but not identical to others of its morph. The snake we select for you may not mature to be identical to the pictured examples, but will be chosen based on our experience of observing which neonates will mature to properly represent their respective morph.  We take this responsibility very seriously, and therefore publish the guarantee that we will exchange your SMR snake if it does not mature to be like our advertised examples.

 

 

 

 

 

Amel-03-21-13s

DAY032113

 

# 032113

Amel – from Red Mask mutant parent
Male
d.o.h. 2011
31″ long on Mar. 19, 2013
 

 

31″ long 2010 male Amel is from a Red Mask Mutant parent and is eating frozen/thawed hopper mice.

He brumated from December 5th until Mar. 15, 2013 and as you can see he lost very little weight during his winter dormancy.