one of the embryo’s most beautiful devices: the genetic programme that permits cells, and so tissues and organs, to become different from each other. Homeosis pointed the way to the calculator of fate.
The calculator of fate was first discovered in fruit flies. Flies, like earthworms, are divided into repeating units or segments. These segments are especially obvious in maggots, though metamorphosis obscures some of their boundaries. Many segments in the adult fly are specialised in some way. Head segments carry labial palps (with which the fly feeds) and antennae (with which it smells); thoracic segments carry wings, legs, or small balancing organs called halteres; abdominal segments have no appendages at all. The organs of a given segment are established when the fly is only an embryo, long before they can actually be seen. To put it a bit more abstractly, in the embryo each segment is given an
identity
.
Over the last eighty-odd years,
Drosophila
geneticists have sought and found dozens of mutations that destroy the identities of segments. Some of these mutations cause flies to grow legs instead of antennae on their heads – and make a fly that cannot smell; others cause halteres to become wings – and make a four-winged dipteran that defies its own definition. Yet other mutations cause wings to become halteres – and leave the fly irredeemably earthbound.
These mutations disrupt a series of genes that, in homage to William Bateson, have come to be known as the homeotic genes.There are eight of them, and they have names like Ultrabithorax, Antennapedia or, less euphemistically, ‘deformed’, that recall the strange flies produced when they are disrupted by mutation. They are the variables in a calculation that makes each segment distinct from any other.
The segmental calculator is a thing of beauty. It has the economical boolean logic of a computer programme. Each of the proteins encoded by the homeotic genes is present in certain segments. Some are present in the head, others in the thorax, others in the abdomen. The identity of a segment – the appendages it grows – depends on the precise combination of homeotic proteins present in its cells. The calculation for the third thoracic segment, which normally bears a haltere, looks something like this:
If Ultrabithorax is present
And all other posterior homeotic proteins are absent
Then third thoracic segment: HALTERE.
Which simply implies that Ultrabithorax is necessary if the third thoracic segment is to grow a haltere, that is, to
be
a third thoracic segment. Should the gene be crippled by a mutation, the protein that it encodes, if present at all, will be unable to do its work. The segment’s unique identity is lost; it becomes a second thoracic segment instead and carries wings.
When, in the 1980s, the homeotic genes were cloned and sequenced they proved to encode molecular switches: proteins that turn genes on and off. Molecular switches work by controlling theproduction of messenger RNA. Most genes contain information to make proteins. But this information requires a means of transmission. That is the job of messenger RNA, a molecule much like DNA except that it is neither double nor a helix, but only a long string of nucleotides. Messenger RNA is a copy of DNA, produced by a device that travels down gene sequences rather as a locomotive travels down a track. Molecular switches – or, to give them their proper name, ‘transcription factors’ – control this. Binding to ‘regulatory elements’, small, exact DNA sequences that surround every gene, transcription factors reach over to the molecular engine that makes messenger RNA and attempt to influence its workings. Some transcription factors seek to speed the engine up; others to shut it down. Attached to their regulatory elements, transcription factors face each other over the double helix and dispute for control. Like all negotiations, the outcome depends on the balance of power: the diversity
The calculator of fate was first discovered in fruit flies. Flies, like earthworms, are divided into repeating units or segments. These segments are especially obvious in maggots, though metamorphosis obscures some of their boundaries. Many segments in the adult fly are specialised in some way. Head segments carry labial palps (with which the fly feeds) and antennae (with which it smells); thoracic segments carry wings, legs, or small balancing organs called halteres; abdominal segments have no appendages at all. The organs of a given segment are established when the fly is only an embryo, long before they can actually be seen. To put it a bit more abstractly, in the embryo each segment is given an
identity
.
Over the last eighty-odd years,
Drosophila
geneticists have sought and found dozens of mutations that destroy the identities of segments. Some of these mutations cause flies to grow legs instead of antennae on their heads – and make a fly that cannot smell; others cause halteres to become wings – and make a four-winged dipteran that defies its own definition. Yet other mutations cause wings to become halteres – and leave the fly irredeemably earthbound.
These mutations disrupt a series of genes that, in homage to William Bateson, have come to be known as the homeotic genes.There are eight of them, and they have names like Ultrabithorax, Antennapedia or, less euphemistically, ‘deformed’, that recall the strange flies produced when they are disrupted by mutation. They are the variables in a calculation that makes each segment distinct from any other.
The segmental calculator is a thing of beauty. It has the economical boolean logic of a computer programme. Each of the proteins encoded by the homeotic genes is present in certain segments. Some are present in the head, others in the thorax, others in the abdomen. The identity of a segment – the appendages it grows – depends on the precise combination of homeotic proteins present in its cells. The calculation for the third thoracic segment, which normally bears a haltere, looks something like this:
If Ultrabithorax is present
And all other posterior homeotic proteins are absent
Then third thoracic segment: HALTERE.
Which simply implies that Ultrabithorax is necessary if the third thoracic segment is to grow a haltere, that is, to
be
a third thoracic segment. Should the gene be crippled by a mutation, the protein that it encodes, if present at all, will be unable to do its work. The segment’s unique identity is lost; it becomes a second thoracic segment instead and carries wings.
When, in the 1980s, the homeotic genes were cloned and sequenced they proved to encode molecular switches: proteins that turn genes on and off. Molecular switches work by controlling theproduction of messenger RNA. Most genes contain information to make proteins. But this information requires a means of transmission. That is the job of messenger RNA, a molecule much like DNA except that it is neither double nor a helix, but only a long string of nucleotides. Messenger RNA is a copy of DNA, produced by a device that travels down gene sequences rather as a locomotive travels down a track. Molecular switches – or, to give them their proper name, ‘transcription factors’ – control this. Binding to ‘regulatory elements’, small, exact DNA sequences that surround every gene, transcription factors reach over to the molecular engine that makes messenger RNA and attempt to influence its workings. Some transcription factors seek to speed the engine up; others to shut it down. Attached to their regulatory elements, transcription factors face each other over the double helix and dispute for control. Like all negotiations, the outcome depends on the balance of power: the diversity
Similar Books
