A unique 'DNA signature', that researchers at Leeds and Bradford have discovered. may be the key to unlocking the egg's fertility which triggers new life.
Dr David Miller and Dr. David Iles from the University of Leeds, in collaboration with Dr Martin Brinkworth at the University of Bradford, have found that sperm writes a DNA signature that can only be recognised by an egg from the same species.
The unique process enables fertilisation and may even explain how a species develops its own unique genetic identity.
Without the right 'key', successful fertilisation either cannot occur, or if it does, development will not proceed normally.
Importantly, disturbances in human sperm DNA packaging are known to cause male infertility and pregnancy failures.
This 'lock and key' mechanism has other profound implications.
Not only does it explain why some otherwise healthy men produce sperm that is sterile, but it also explains how different species evolve and retain their own identity.
"Up until now, Doctors have struggled to understand idiopathic male infertility. Our latest research offers a plausible explanation for why some sperm malfunction or fail to function correctly," said Miller.
If the DNA carried by a sperm cell was unwound and stretched out, it would actually measure more than a metre in length. In order to fit this entire DNA into the microscopic space within the head of the sperm cell, the DNA needs to be very tightly coiled, or packaged.
"There is a definite pattern to the way DNA is packaged in sperm cells and we can see that this pattern is the same in unrelated fertile men. It is different in the sperm of infertile men. This implies that there is a significance to the packaging of DNA that has a direct relevance to male fertility," said Iles.
Detailed analyses of the DNA in the 'open', less tightly packaged conformation, showed this DNA carries much of the information critical for activating genes essential for directing the development of the embryo.
Further investigations showed that the same conformation exists in the sperm of several unrelated human donors and remarkably, highly similar packaging patterns to exist in the sperm of mice.
Thus, DNA regions in the 'open' conformation may be more vulnerable to damaging toxins, such as those in cigarette smoke and certain anti-cancer drugs, than those that are tightly packaged.
Brinkworth said: "This might mean that anything capable of causing genetic damage to sperm could have particular significance for the development of the embryo".
The findings also help explain why inter-species breeding is so rarely successful.
Where the locks and keys of two species do not match, however similar their DNA is, no viable offspring can be born.