Introduction 

There are many different types of ichthyosis.  None of them are catching or contagious but they all depend on a small genetic mistake which has often been inherited from ones parents.  There are 3 basic patterns of inheritance but a basic understanding of genetics is needed to understand how this occurs. 

  • We all have billions of genes.  Each gene has a specific function such as to make a protein or fat within the body. 
  • Each gene is made up of tens thousands of building blocks called nucleotides. 
  • When these complicated genes replicate it is not uncommon for there to be very small mistakes.  A single nucleotide (out of many thousands) may be changed or in the wrong position in the gene.  Often this causes no problem or disease at all as the gene can still function. 
  • However if the mistake is in a crucial position in the gene – it may make the gene malfunction so that it can’t produce, for example, a skin protein, and this may lead to a disease such as ichthyosis. 
  • In practice most human beings have a number of small genetic mistakes and these do not cause disease.  Only when these mistakes stop a gene from working normally does a disease arise. 

How do we inherit genes from our parents? 

Every human being has 2 copies of each gene.  However the father’s sperm and the mother’s egg have only 1 copy of each gene.  This means that when the egg and sperm join to make a new baby, the baby will have 2 copies of each gene just like its parents. So on average half your genes come from your mother and half from your father. 

An example of the blood group genes illustrates this: 

 

Mother gene AA - Father  gene BB 

  

Mother’s egg gene A Father’s sperm gene B 

  

Sperm and egg join 

 

Baby gene AB 

 

 Dominant and recessive genes 

As we have mentioned genes come in pairs.  These may be identical genes (eg DD or dd) or non-identical genes eg (Dd).  Let’s say that this gene causes hair colour.  For example gene D may cause black hair and gene d blond hair. 

If gene D is said to be a dominant gene it will dominate over gene d.  This means that anyone with the gene combination DD or Dd would have black hair.  Only those individuals with gene combination dd would have blond hair.  Therefore gene d is called a recessive gene.  2 copies of a recessive gene must be present before it can express itself. 

Example 1 

Mother DD - Father dd 

black hair - blond hair 

  

Either gene can be passed on 

Egg can be only D - Sperm can only be d 

 

Possible combinations for child 

All children will be Dd 

All children will have black hair 

 

Example 2 

 

Mother Dd - Father Dd 

Black hair - black hair 

 

Either gene can be passed on 

 

Egg can be D or d - Sperm can be D or d 

  

Possible combinations for child 

 

25% DD - 50% Dd - 25% dd 

     black hair  -   black hair  -  blond hair 

 

Autosomal dominant disease (eg ichthyosis vulgaris) 

Let’s take the above a step further to see how this fits with disease. 

Say gene h is a normal gene.  Gene H is an abnormal gene with a small mistake that stops it from working normally. 

Example 

Disease gene H is dominant. 

All individuals with Hh or HH will have the disease. 

Individuals with hh will be normal. 

 

Mother Hh - Father hh 

(has disease) - (no disease) 

 

Either gene can be passed on 

 

Egg could be H or h - Sperm can only be h 

 

Possible combinations for child 

50% Hh - 50% hh 

   has disease - no disease 

 

This pattern of inheritance is called autosomal dominant.  It means if one parent is affected there is a 50% chance of a child being affected. 

Autosomal recessive disease (eg lamellar ichthyosis) 

Example 

Disease gene H is recessive (Normal gene h is dominant) 

Only individuals with HH will have the disease. 

All individuals with hh or hH will be normal.  However hH individuals will be carriers for the disease. 

 

Mother hH - Father hH   

 (carrier) -  (carrier) 

 

Either gene can be passed on  

 

           Egg could be H or h  -  Sperm could be H or h 

 

Possible combinations for child 

 

     25% HH                 50% Hh              25% hh 

     have disease           no disease        no disease 

            (is a carrier) 

 

This pattern of inheritance is called autosomal recessive.  Neither parents are affected but both are carriers.  On average 25% of their children will be affected, 25% normal and 50% will be unaffected carriers. 

So how do I know if I am a carrier for a recessive gene? 

You don’t because a carrier does not have the disease.  In fact most people care carriers for a number of recessive genes.  Let’s say you were a carrier for 5 different diseases. This is only 5 genes out of the many millions of genes that you have.  If each individual only carries 5 abnormal recessive genes it is very very unlikely that your partner would have mistakes in the exact genes.  It is therefore extremely unlucky when you have children with somebody who is a carrier for the same condition as this can produce a child with a disease. 

Marrying within your own family (eg a first cousin) increases your chances of your few abnormal genes being the same as your partners and thus increase the chances of producing autosomal recessive disease. 

Sex-linked recessive disease (also called X-linked disease) 

We have already mentioned that all humans carry 2 copies of their genes.  There is one partial exception to this and this involves the sex genes (or sex determining genes). 

Females have 2 X-chromosomes which carry the sex genes.  However, males only have 1 X-chromosome and 1 Y-chromosome.  Therefore they do not have 2 copies of the X-chromosome genes.  This is important if a male has an abnormal gene on the X-chromosome.  Even if this gene is recessive he will have the disease as he doesn’t have a second copy to override this. 

 

Example (X-linked ichthyosis) 

Normal gene T is dominant 

Disease gene t is recessive 

Remember males only have 1 X-chromosome 

 

Mother genes Tt - Fathergene T + “absent second copy”

 no disease              -                   no disease 

                                              (carrier) 

  

    Either gene can be passed on 

 

Egg could be T or t - Sperm is T or “absent second copy” 

Possible combinations for child 

50% girls  -  50% boys  

25% TT         -         25% Tt        -       25% T        -       25%  

 no disease              no disease            no disease           has disease 

                                  (carrier) 

 

So for X-linked recessive conditions females are normal or carriers whereas males are normal or have the disease.  This is why X-linked ichthyosis only occurs in males.  Interestingly if an affected male has children none will be affected so it appears to “skip” a generation.  In fact all his daughters are carriers and all his sons will be normal. 

X-linked dominant disease (eg Conradi-Hünermann syndrome) 

This is extremely rare. 

Here the abnormal gene on the X-chromosome dominates the normal copy.  This causes disease in females and there is a 50% chance of passing this on to their daughters.  This abnormal gene is so severe in males who have no second copy that it appears to be incompatible with life.  Therefore X-linked dominant ichthyosis is not seen in males.  

 

Mothers genes TT - Father gene t + “absent second copy”

   no disease                    -                  has disease  

  Either gene can be passed on 

 

                          Egg can be T only          -         Sperm is t or “absent second copy” 

  Possible combinations for child 

     50% girls    -     50% boys 

  50% Tt      -      50% T 

        no disease         no disease 

         (all carriers) 

 So how do we apply this to ichthyosis? 

The first step is for your doctor to diagnose which type of ichthyosis you have.  Once this is achieved he will explain how this condition is inherited. 

Autosomal dominant conditions 

Ichthyosis vulgaris 

Bullous ichthyosiform erythroderma 

KID syndrome 

Autosomal recessive 

Non-bullous ichthyosiform erythroderma 

Lamellar ichthyosis 

“Limited” lamellar ichthyosis 

Sjögren Larsson syndrome 

Netherton’s syndrome 

Harlequin ichthyosis 

Refsum’s disease 

Trichothiodystrophies   (IDIDS syndrome)

X-linked recessive 

X-linked ichthyosis 

X-linked dominant 

Conradi-Hünermann syndrome    

(also called X-linked dominant ichthyosis, Happle syndrome and chondrodyplasia punctata) 

Conditions can appear in a child when neither parent is affected.  This is usually because the disease gene is newly created (new mutation) and may have occurred when the sperm or egg were produced.  As the mistake is not present in the parents the risks of them having a further affected child are low.   However the affected child has a chance of passing the condition on to their offspring when they are older depending on the affected gene.  This sounds complicated but all this really means it that a genetic mistake has to start somewhere. 

Further help 

There are a number of online forums about Ichthyosis where individuals can share their experiences and detail their own treatment recommendations. Not everything will work for everyone but these forums are a good place both to receive and offer support. 

Contact the Ichthyosis Support Group for information, advice, details on useful products, and to be connected with other people to share experiences and helpful advice. 

Download The Inheritance of Ichthyosis Factsheet

To find out more about the ISG or become a member please get in touch in one of the following ways: 

By Phone

0845 602 9202 

By Email: 

[email protected] 

By Post: 

Ichthyosis Support Group 

PO Box 1242, Yateley GU47 7FL 

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