Carl Zimmer, explains the history of Vitamins and their composition and necessity. Incidence of Scurvy Disease among sailors led to the discovery of Vitamin C.
What is the history behind vitamins? And how did we come to realise that these nutrients are vital for us? Carl Zimmer takes us through its story and reveals the intricacies involved.
In 1602, a Spanish fleet was sailing up the Pacific coast of Mexico when the crew became deathly ill. “The first symptom is pain in the whole body that makes it sensitive to touch,” wrote Antonio de la AscensiĆ³n, a priest on the expedition. “Purple spots begin to cover the body, especially from the waist down; then the gums become so swollen that the teeth cannot be brought together, and they can only drink, and finally they die all of a sudden, while talking.”
The crew was suffering from scurvy, a disease that was then both bitterly familiar and deeply mysterious. No one knew why it struck sailors or how to cure it. But on that 1602 voyage, AscensiĆ³n witnessed what he considered a miracle. While the crew was ashore burying the dead, one sick sailor picked up a cactus fruit to eat. He started to feel better, and his crewmates followed his example.
In 1602, a Spanish fleet was sailing up the Pacific coast of Mexico when the crew became deathly ill. “The first symptom is pain in the whole body that makes it sensitive to touch,” wrote Antonio de la AscensiĆ³n, a priest on the expedition. “Purple spots begin to cover the body, especially from the waist down; then the gums become so swollen that the teeth cannot be brought together, and they can only drink, and finally they die all of a sudden, while talking.”
The crew was suffering from scurvy, a disease that was then both bitterly familiar and deeply mysterious. No one knew why it struck sailors or how to cure it. But on that 1602 voyage, AscensiĆ³n witnessed what he considered a miracle. While the crew was ashore burying the dead, one sick sailor picked up a cactus fruit to eat. He started to feel better, and his crewmates followed his example.
“They all began to eat them and bring them back on board so that, after another two weeks, they were all healed,” the priest wrote.
Over the next two centuries, it gradually became clear that scurvy was caused by a lack of fruits and vegetables on long-distance voyages. In the late 1700s, the British navy started supplying its ships with millions of gallons of lemon juice, eradicating scurvy. But it wasn’t until 1928 that Hungarian biochemist Albert Szent-Gyorgyi discovered the ingredient that cured scurvy: Vitamin C.
Szent-Gyorgyi’s experiments were part of a wave of early-20th-century research that pulled back the curtain on vitamins. Scientists discovered that the human body required minuscule amounts of 13 organic molecules. A deficiency of any of the vitamins led to different diseases - a lack of vitamin A to blindness, vitamin B12 to severe anaemia, vitamin D to rickets.
Today, a huge amount of research goes into understanding vitamins, but most of it is focused on how much of them people need to stay healthy. This work does not address a basic question, though; How did we end up so dependent on these peculiar little molecules?
Recent research is providing new answers. It appears that vitamins were essential to life from its earliest stages some 4 billion years ago. Early life-forms could make their own vitamins, but some species - including ours later lost that ability. Species began to depend on each other for vitamins, creating a complex flow of molecules that scientists have named “vitamin traffic.”
A universal chemistry
Every vitamin is made by living cells – either our own, or in other species. Vitamin D is produced in our skin, for example, when sunlight strikes a precursor of cholesterol. A lemon tree makes vitamin C out of glucose. Making a vitamin is often an enormously baroque process. In some species, it takes 22 proteins to craft a vitamin B12 molecule.
While a protein may be made up of thousands of atoms, a vitamin may be made up of just a few dozen. And yet, despite their small size, vitamins expand our chemical versatility. A vitamin cooperates with proteins to help them carry out reactions they couldn’t manage on their own. Vitamin B1, for example, helps proteins pull carbon dioxide from molecules.
Vitamins carry out these chemical reactions not just in our own bodies but in all living things.
The ability we lost
Once the ability to make vitamins evolved, some species became especially good at making them. Plants, for example, evolved into vitamin C factories, packing their leaves and fruits with the molecule. At first, vitamin C probably defended plants against stress – a function it carries out in other species, including us. But over time, the vitamin took on new jobs in plants, like helping control the development of fruit.
Many vertebrates can make vitamin C, and use an identical set of genes to do so. “We should be able to make it, too, since we have all the genes,” said Rebecca Stevens of the French National Institute for Agricultural Research.
Unlike a frog or a kangaroo, however, we have crippling mutations in one of those genes, known as GULO. Unable to make the GULO protein, we cannot produce vitamin C.
“It’s not just us – it goes back a long time,” said Guy Drouin, a molecular evolutionary biologist at the University of Ottawa. He and other researchers have found that apes and monkeys, our closest primate relatives, have disabled GULO genes, with many of the same mutations. Drouin has concluded that the common ancestor we share with those other primates lost the ability to make vitamin C around 60 million years ago.
It wasn’t just us
Now that scientists can scan genomes of thousands of species, they’re discovering many more cases in which vitamin genes have either decayed or disappeared altogether. Sergio Sanudo-Wilhelmy of the University of Southern California and his colleagues recently surveyed the genomes of 400 of the most abundant species of bacteria in the oceans. As they report in a paper to be published in the Annual Review of Marine Science, 24 percent of the bacteria lack genes to make B1, and 63 percent can’t make B12.
These recent studies are especially surprising because bacteria have long been considered self-sufficient when it comes to vitamins. Now scientists need to figure out why many species of bacteria in the ocean aren’t dead from a microbial version of scurvy.
Only recently have scientists made measurements of vitamins in the sea. They are finding some places that are abundant with them and others that are vitamin deserts. It is possible that the difference influences not just bacteria and algae, but the animals that feed on them.
Vitamins flow in complex routes, not just in the ocean, but on land. We humans can’t make our own supply of vitamin B12, for example, so we need to get it from food. One way is to eat meat like beef, which contains B12. It turns out that the cows and other animals that we consume don’t make B12 in their own cells. Instead, the bacteria in their guts manufacture it for them.
We are also home to thousands of species of bacteria, which synthesise vitamins as they eat our food. Does that mean we depend on our internal vitamin traffic? “It’s still theoretical,” said Douwe van Sinderen, a microbiologist at University College Cork in Ireland. “But evidence is building that bacteria can provide some vitamins that we need.”
If that’s so, we may need to think of our bodies as self-contained oceans of vitamin traffic – a continuation of the traffic that has occurred on Earth for 4 billion years.
Over the next two centuries, it gradually became clear that scurvy was caused by a lack of fruits and vegetables on long-distance voyages. In the late 1700s, the British navy started supplying its ships with millions of gallons of lemon juice, eradicating scurvy. But it wasn’t until 1928 that Hungarian biochemist Albert Szent-Gyorgyi discovered the ingredient that cured scurvy: Vitamin C.
Szent-Gyorgyi’s experiments were part of a wave of early-20th-century research that pulled back the curtain on vitamins. Scientists discovered that the human body required minuscule amounts of 13 organic molecules. A deficiency of any of the vitamins led to different diseases - a lack of vitamin A to blindness, vitamin B12 to severe anaemia, vitamin D to rickets.
Today, a huge amount of research goes into understanding vitamins, but most of it is focused on how much of them people need to stay healthy. This work does not address a basic question, though; How did we end up so dependent on these peculiar little molecules?
Recent research is providing new answers. It appears that vitamins were essential to life from its earliest stages some 4 billion years ago. Early life-forms could make their own vitamins, but some species - including ours later lost that ability. Species began to depend on each other for vitamins, creating a complex flow of molecules that scientists have named “vitamin traffic.”
A universal chemistry
Every vitamin is made by living cells – either our own, or in other species. Vitamin D is produced in our skin, for example, when sunlight strikes a precursor of cholesterol. A lemon tree makes vitamin C out of glucose. Making a vitamin is often an enormously baroque process. In some species, it takes 22 proteins to craft a vitamin B12 molecule.
While a protein may be made up of thousands of atoms, a vitamin may be made up of just a few dozen. And yet, despite their small size, vitamins expand our chemical versatility. A vitamin cooperates with proteins to help them carry out reactions they couldn’t manage on their own. Vitamin B1, for example, helps proteins pull carbon dioxide from molecules.
Vitamins carry out these chemical reactions not just in our own bodies but in all living things.
The ability we lost
Once the ability to make vitamins evolved, some species became especially good at making them. Plants, for example, evolved into vitamin C factories, packing their leaves and fruits with the molecule. At first, vitamin C probably defended plants against stress – a function it carries out in other species, including us. But over time, the vitamin took on new jobs in plants, like helping control the development of fruit.
Many vertebrates can make vitamin C, and use an identical set of genes to do so. “We should be able to make it, too, since we have all the genes,” said Rebecca Stevens of the French National Institute for Agricultural Research.
Unlike a frog or a kangaroo, however, we have crippling mutations in one of those genes, known as GULO. Unable to make the GULO protein, we cannot produce vitamin C.
“It’s not just us – it goes back a long time,” said Guy Drouin, a molecular evolutionary biologist at the University of Ottawa. He and other researchers have found that apes and monkeys, our closest primate relatives, have disabled GULO genes, with many of the same mutations. Drouin has concluded that the common ancestor we share with those other primates lost the ability to make vitamin C around 60 million years ago.
It wasn’t just us
Now that scientists can scan genomes of thousands of species, they’re discovering many more cases in which vitamin genes have either decayed or disappeared altogether. Sergio Sanudo-Wilhelmy of the University of Southern California and his colleagues recently surveyed the genomes of 400 of the most abundant species of bacteria in the oceans. As they report in a paper to be published in the Annual Review of Marine Science, 24 percent of the bacteria lack genes to make B1, and 63 percent can’t make B12.
These recent studies are especially surprising because bacteria have long been considered self-sufficient when it comes to vitamins. Now scientists need to figure out why many species of bacteria in the ocean aren’t dead from a microbial version of scurvy.
Only recently have scientists made measurements of vitamins in the sea. They are finding some places that are abundant with them and others that are vitamin deserts. It is possible that the difference influences not just bacteria and algae, but the animals that feed on them.
Vitamins flow in complex routes, not just in the ocean, but on land. We humans can’t make our own supply of vitamin B12, for example, so we need to get it from food. One way is to eat meat like beef, which contains B12. It turns out that the cows and other animals that we consume don’t make B12 in their own cells. Instead, the bacteria in their guts manufacture it for them.
We are also home to thousands of species of bacteria, which synthesise vitamins as they eat our food. Does that mean we depend on our internal vitamin traffic? “It’s still theoretical,” said Douwe van Sinderen, a microbiologist at University College Cork in Ireland. “But evidence is building that bacteria can provide some vitamins that we need.”
If that’s so, we may need to think of our bodies as self-contained oceans of vitamin traffic – a continuation of the traffic that has occurred on Earth for 4 billion years.
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