Monday, 29 September 2014

Understanding Budgerigar Genetics

The Budgerigar is one of the most commonly kept birds in aviculture and many people start bird keeping with a budgie or two.  They come in a vast range of colours representing different mutations and when it comes to breeding a specific one, understanding the different genetics involved can be important to getting the result you want.  So here is a basic introduction to understanding genetics.


Genetics 101

Now I am not trained in genetics so my understanding is only as good as my understanding of what I have read.  However, here goes.

The wild type budgie is the bright green colour that is actually called Light green.  This is a bird whose feathers have three pigments in them eumelanin, psittacin and advanced psittacin.  Eumelanin is a black type of melanin while psittacin is the yellow pigment.  The advanced psittacin is an unusual pigment that parrot produce that allows them some of their more fantastical colours such as red, oranges, peaches and pinks.  When the feathers are exposed to sunlight, only the blue part is reflected by the eumelanin resulting in blue light passing through the yellow pigment layer and creating feathers that appear green.

From this light green form of the budgie have been bed 32 different mutations and many hundreds of variations within them.  These 32 fall into four basic groups; albinism, dilution, Leucism and Melanism.  Albinism, or albinos, are the white birds with red eyes and skin and this is where eumelanin is either partly or totally absent.  Dilution is where eumelanin is reduced and Leucism is where it is reduced in areas.  Finally Melanism is where eumelanin in increased.

The other basic of genetics is the most complicated part; dominance relationships.  This has to do with the parts of gene called the alleles that form into pairs to make chromosomes.  Chromosomes in birds are the same as in humans; there are two types.  There are sex chromosomes that define gender and then there are all the rest.  An allele can be dominant to the other allele, which means whatever it brings out will be the dominant factor in the bird but there are also other degrees of relationships.  There are also sex-linked inheritances where the alleles on the sex chromosomes are the one that define the colour.  Hopefully this will make more sense when applied to the colours and mutations!


Blue series

Skyblue Male
There are two main sets of budgie colours; the greens and the blues.  In a blue bird, the green feathers turn to sky blue while the mask area on the face turns from yellow to white.  Blue birds show this colour because they lack the yellow pigmentation that creates the green feathers in the wild type bird.  Blue mutation birds have been recorded in aviculture dating back to 1878 in Brussels, Belgium.  It was first seen in England in 1910 and remained rare until the 1930s when they could fetch £100 per pair, around the same price as a car.

Genetically, the blue mutation is recessive compared to the wild type allele so when a bird has one blue allele, it will appear as a wild type bird.  Only if the bird has two blue alleles will it look like a blue bird.  When combined with the Dark mutation, the body feathers become a deeper blue.  A blue bird with a single Dark factor is a Cobalt while one with two dark factors is a Mauve.


Dark mutation

The Dark mutation is one that affects the colour of both green and blue birds.  When a budgie has a dark factor, the green bird appears much the same as the wild type but has darker body and tail feathers.  These are darker still in Olives and Mauves but all of the birds have the normal violet cheek patches.

The Dark Green had a body colour the shade of forest green while Cobalt is a deep blue that is like an azure shade.  Olive green is a richer shade of olive, similar to Grey-green but differentiated by the violet cheek patches.  Mauve is a purplish grey that is more muted than the Violet or Cobalt colours.  Violet Cobalt is a composition of blue, dark and violet and is a bright shape of violet.

The dark mutation has an incompletely dominance relationship with the wild type allele.  This means that the dark green has one dark and one wild type while the olive has two dark alleles.  In the blue series, the Cobalt has one dark and one wild type while the Mauve has two dark alleles.  The dark factor is always visibly expressed so no bird is ever split for dark.


Yellowface

There are two varieties of yellowface mutation.  Yellowface I is where the bird appears as a normal Sky blue but the face, where it is normally white, is yellow.  There are also yellow tints to the wing markings and sometimes down the breast a degree.  It can also be found in Cobalt and Mauve variations where the yellow markings remain much the same.
Yellowface I


Yellowface II is the other yellowface mutation and can be combined with blue, opaline or clearwing birds to create the mutation known as rainbow.  A single factor Yellowface II has a bright body colour that is often called sea green or turquoise while those on a Cobalt bird is bottle green and in the Mauve variation are a mixture of mauve and olive.  A double factor Yellowface II is similar to yellowface I but the yellow tends to be brighter.

The genetics are a little confused but it is believed that the mutation doesn’t create a yellow face but reduce the colouring in it and are believed to be part of the blue series of mutations.


Grey

Grey, or dominant grey, is sometimes called the Australian Grey and is the basis for the grey-green and grey standard varieties.  In a dominant grey bird, the light green variety becomes grey green, which is a dull, mustard green, and the blue becomes a light grey, a uniform battleship grey colour.  In both the green and blue birds, the flight and longest tail feathers are black while the cheek patches are a lilac-grey colour.  When combined with the dark mutation, both colours become darker.

This mutation is a dominant one so even over the wild-type bird any bird with one allele of grey will be grey coloured.  It also means that a double factor grey will look no different from a single factor grey.

Anthracite is another grey mutation but this is one is much rarer.  It is similar to the violet mutation but the birds have black or very dark grey feathers with differing degrees of white feathers.  It developed in Germany and most all of the birds are found in the same area but it is also possible that it is related to the now absent English Grey mutation.  Anthracite has an incomplete dominant relationship with the wild type so a different effect presents between single and double factor birds.  In green series Anthracites, the body colour is deeper than a Dark Green while in the blues, the colour is similar to a deep Cobalt.

Slate is another grey shade mutation which in the blue series birds makes a light grey colour with a bluish tone while in green birds is a shade between light green and light grey green.  Dark factor has more an effect with slate than with grey birds where they become very dark.  It is a sex-linked mutation that is carried on the X chromosome and is recessive to the wild type.  This means hens cannot be split for slate and in cocks, the slate allele much be present on both X chromosomes to be the phenotype.


Violet

In any bird with the violet factor, there is a visual effect on their feather colour.  It depends on whether they carry a single or a double factor and other mutation present but there are around 18 different combinations.  Single factor violet light green lack the ribbing on the feathers normally found to give a satin-like appearance while the tail feathers are paler.  Single factor sky blues have a colour between dark sky blue and medium cobalt with navy blue tail feathers.


Dilute

Dilute is one of the main categories of mutations in budgies and comes in several varieties such as light, dark, olive, grey, suffused yellows and grey and suffused whites.  In the wild type bird, the dilute mutation makes the body colour change from green to yellow while the black spots on the wings, head and neck are pale grey.  Cheek patches become a pale lavender and the tail feathers are a pale bluish-grey.  Dilute light greens are often known as light yellows.

In the blue series birds, the yellow turns to white but often suffused with blue to varying degrees.  Dilute sky blues are known as whites or suffused whites when blue is present.  Dilute cobalts and mauves are known as suffused whites also.

Dilute is a recessive mutation to the wild type so if a bird has a single allele of dilute, it will appear as a normal wild-type bird and will be classed as split for dilute. 


Clearwing

Clearwing is a mutation in its own right and also the underlying variety of a number of other mutations such as the yellowwings (combined with green series) and whitewings (combined with blue series).  It combines with the greywing variety to make full-bodied greywings and with yellowface II and opaline to make rainbow.

A clearwing light green has only slightly lighter colours than a normal light green bird but with highly contrasting yellow wings.  Similarly, with a sky blue bird, the colour is similar but the wings are whiter.  There are pale grey shadows on the normal markings while the tail feathers are a smoky-grey colour in the blues and grey-green in the green.  Clearwings split for dilute are slightly paler.


Greywing

Greywing budgies have a body colour that is around half the intensity of a normal variety with wing, neck and head markings reduced from black to mid-grey while the cheek patches are pale violet.  The tail feathers are shades of grey with a bluish tinge.  When combined with the clearwing mutation, the birds are known as full-bodied greywings, which have a darker colour to the body and markings.


Pied

Recessive Pied
There is a range of different pied mutations in budgerigars and here are a few of the more common ones.  Pied budgies all have irregular patches of clear feathers that can show up in random places around the body.  These patches are lacking in melanin pigment so just show the ground colour, which is yellow in green birds and white in blue birds.  The remainder of the feathers are normal coloured.

The recessive pied mutation is the underlying mutation of the Danish pied variety that is also known as the Harlequin.  With recessive pieds, the areas of pied feathers are very extensive and can result in birds that are almost clear, with small patches of pigment.  These patches of colour are often brighter and more vivid in shade than normal.

The Australian pied mutation is the underlying mutation for the Banded pied variety.  These birds have a nape spot, areas on the wings and breast that are clear and pink feet. 


Cinnamon

The cinnamon variety of budgies is one of the 30 or so mutations as well as the underlying mutation, with Ino, for the Lacewing variety.  On a cinnamon bird, all the markings that are normally black appear brown and these are darkest on the male birds.  Body colour and cheek patches tend to be paler by around half and their feathers have a silky appearance.  Their eyes of dark brown with a white iris.  It is a sex-linked mutation that is carried on the X-chromosome and is recessive to the wild type of budgie.


Ino

The ino mutation is the underlying mutation for variations such as the Albino and Lutino as well as a constituent part of the Lacewing variation with cinnamon.  Green series ino birds are known as Lutino and have pale yellow contour feathers along with white or pale yellow flight and tail feathers.  Their cheek patches are silvery-white.  In the blue series, ino become Albino, birds that are pure white with slightly silvery cheek patches.  All ino birds have red eyes and pink legs and feet with the cere on the male bird being grey-purple rather than the normal blue.
Albino (left) and Lutino (right)


Ino mutations are sex linked recessive on the X chromosome and it works by inhibiting the melanin pigment in the feathers.


Opaline

Opaline mutation budgies are known for a range of characteristics that can be present in varying intensity.  These include striations on the top of the head that extend down to the between the wings being much reduced or even absent.  Another sign is that the dark markings on the wings are often absent; being the same colour as the body and giving it the opalescent effect that gives the mutation its name.

Opaline combines with yellowface II and clearwing mutations to produce the rainbow variation.  Opaline is a sex-linked mutation carried on the X chromosome and is recessive to the wild type.


Conclusion


To know what you will get out when you breed a pair of budgies, you need to know exactly what you are putting in and this can take a few generations to achieve.  However once you know the makeup of your birds, there are various calculators out there that will tell you what pairings will produce what type of chicks and allow you to plan going forward.  Alternatively, you can go for blind luck and get a pleasant surprise from each egg.