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11 votes
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The strange clouds of alien worlds
6 votes -
A 1990 experiment to test whether we could discern life on Earth remotely
9 votes -
Tiny robots made from human cells heal damaged tissue (in the lab)
15 votes -
Vavilovian mimicry
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A study on mouse embryos grown in space suggests that the radiation and weightlessness of space might not pose immediate obstacles to mammalian reproduction
9 votes -
The bodily indignities of the space life
21 votes -
Mexican Congress holds second UFO session featuring Peruvian mummies
23 votes -
The Brain Scoop relaunch!
14 votes -
Deep in the Arctic permafrost, the Svalbard Global Seed Vault is protecting Africa's food supply
12 votes -
CDH2 mutation affecting N-cadherin function causes attention-deficit hyperactivity disorder in humans and mice
19 votes -
In defense of the rat
14 votes -
Finns have been fishing for herring for generations, but new reduced EU quotas are threatening the traditional livelihoods of coastal communities
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Rats have an imagination, new research finds
57 votes -
The curious tale of the cancer ‘parasite’ that sailed the seas
17 votes -
The genetic heritage of the Denisovans may have left its mark on our mental health
16 votes -
Long presumed to have no heads at all, sea stars may be nothing but
25 votes -
What causes fainting? Scientists finally have an answer.
22 votes -
Scientists in Sweden have succeeded in extracting and sequencing RNA molecules from an extinct species, a century old Tasmanian tiger known as a thylacine
16 votes -
Six creatures that are actually real-life zombies
18 votes -
Simulating an ocean for 100 days
10 votes -
Human microbiome myths and misconceptions
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Mutations matter
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The world inside you
11 votes -
I’m a microbiologist and here is what (and where) I never eat
27 votes -
We might have accidentally killed any life we collected in samples on Mars nearly fifty years ago
43 votes -
Allergy study on 'dirty' mice challenges the hygiene hypothesis
11 votes -
The pristine Tana River, bordering Norway and Finland, is littered with the rotting corpses of an invasive Pacific salmon species
9 votes -
‘We felt so betrayed’: Indigenous tribe continues activism after decision excluding Morro Bay from US marine sanctuary
23 votes -
Aquaculture is bringing jobs and money to rural Icelandic regions, but a huge escape of farmed fish in August could devastate local salmon populations
7 votes -
Magnifying curiosity with a pocket microscope
9 votes -
Norway wants to begin deep sea mining in the Arctic – here is why it's a bad idea
6 votes -
New vaccine technology could protect from future viruses and variants
The vaccine antigen technology, developed by the University of Cambridge and spin-out DIOSynVax in early 2020, provided protection against all known variants of SARS-CoV-2 – the virus that causes...
The vaccine antigen technology, developed by the University of Cambridge and spin-out DIOSynVax in early 2020, provided protection against all known variants of SARS-CoV-2 – the virus that causes COVID-19 – as well as other major coronaviruses, including those that caused the first SARS epidemic in 2002.
The studies in mice, rabbits and guinea pigs [...] found that the vaccine candidate provided a strong immune response against a range of coronaviruses by targeting the parts of the virus that are required for replication.
Professor Jonathan Heeney from Cambridge’s Department of Veterinary Medicine, who led the research, [said] “We wanted to come up with a vaccine that wouldn’t only protect against SARS-CoV-2, but all its relatives.”
18 votes -
Anti-COVID drug may have led to virus mutations: study
10 votes -
Brainless jellyfish demonstrate learning ability
Veronique Greenwood In the dappled sunlit waters of Caribbean mangrove forests, tiny box jellyfish bob in and out of the shade. Box jellies are distinguished from true jellyfish in part by their...
Veronique Greenwood
In the dappled sunlit waters of Caribbean mangrove forests, tiny box jellyfish bob in and out of the shade. Box jellies are distinguished from true jellyfish in part by their complex visual system — the grape-size predators have 24 eyes. But like other jellyfish, they are brainless, controlling their cube-shaped bodies with a distributed network of neurons.
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That network, it turns out, is more sophisticated than you might assume. On Friday, researchers published a report in the journal Current Biology indicating that the box jellyfish species Tripedalia cystophora have the ability to learn. Because box jellyfish diverged from our part of the animal kingdom long ago, understanding their cognitive abilities could help scientists trace the evolution of learning.
The tricky part about studying learning in box jellies was finding an everyday behavior that scientists could train the creatures to perform in the lab.
- Roots of mangroves
Anders Garm, a biologist at the University of Copenhagen and an author of the new paper, said his team decided to focus on a swift about-face that box jellies execute when they are about to hit a mangrove root. These roots rise through the water like black towers, while the water around them appears pale by comparison. But the contrast between the two can change from day to day, as silt clouds the water and makes it more difficult to tell how far away a root is. How do box jellies tell when they are getting too close?
“The hypothesis was, they need to learn this,” Garm said. “When they come back to these habitats, they have to learn, how is today’s water quality? How is the contrast changing today?”
- Setup
In the lab, researchers produced images of alternating dark and light stripes, representing the mangrove roots and water, and used them to line the insides of buckets about six inches wide. When the stripes were a stark black and white, representing optimum water clarity, box jellies never got close to the bucket walls. With less contrast between the stripes, however, box jellies immediately began to run into them. This was the scientists’ chance to see if they would learn.
After a handful of collisions, the box jellies changed their behavior. Less than eight minutes after arriving in the bucket, they were swimming 50% farther from the pattern on the walls, and they had nearly quadrupled the number of times they performed their about-face maneuver. They seemed to have made a connection between the stripes ahead of them and the sensation of collision.
- “It’s amazing to see how fast they learn,”
Going further, researchers removed visual neurons from the box jellyfish and studied them in a dish. The cells were shown striped images while receiving a small electrical pulse to represent collision. Within about five minutes, the cells started sending the signal that would cause a whole box jellyfish to turn around.
“It’s amazing to see how fast they learn,” said Jan Bielecki, a postdoctoral researcher at the Institute of Physiology at Kiel University in Germany, also an author of the paper.
Researchers who were not involved in the study called the results a significant step forward in understanding the origins of learning. “This is only the third time that associative learning has been convincingly demonstrated in cnidarians,” a group that includes sea anemones, hydras and jellyfish, said Ken Cheng, a professor at Macquarie University in Sydney, Australia, who studies the animals. “And this is the coolest demonstration, replete with physiological data.”
The results also suggest that box jellyfish possess some level of short-term memory, because they can change their behavior based on past experience, said Michael Abrams, a postdoctoral researcher at the University of California, Berkeley, who studies the neuroscience of jellyfish sleep. He wonders how long the box jellies remember what they’ve learned. If they are taken out of the tank for an hour and then returned to it, do they have to learn what to do all over again?
Future work
In future work, researchers hope to identify which specific cells control the box jellyfish’s ability to learn from experience. Garm and his colleagues are curious about the molecular changes that happen in these cells as the animals incorporate new information into their behavior.
They wonder, too, whether the capacity to learn is universal among nerve cells, regardless of whether they are part of a brain. It might explain their peculiar persistence in the tree of life.
“There are organ systems popping up and going away all the time,” Garm said. “But nervous systems — once they are there, they very rarely go away again.”
Perhaps the ability to learn is one reason they are still here.
Seattle Times - Link to the article
9 votes -
Growing living rat neurons to play... DOOM?
20 votes -
Prehistoric fish fills 100 million year gap in evolution of the skull
8 votes -
Human trials of artificial wombs could start soon. Here’s what you need to know
11 votes -
You say tomato, these scientists say evolutionary mystery
6 votes -
For the first time in the United States, research with cephalopods might require approval by an ethics committee
21 votes -
Why does Norway want to extract seabed minerals – an explainer
6 votes -
Will it slip or will it grip: Scientists ask, “what is snail mucus?”
12 votes -
Human ancestors nearly went extinct 900,000 years ago
51 votes -
Scientists grow whole model of human embryo, without sperm or egg
19 votes -
Why are adverts so loud?
17 votes -
New amphibian family tree a leap forward in understanding frogs, shows they evolved tens of millions of years later than previously thought
10 votes -
How deep-sea mining for EV materials could wipe out tuna populations
9 votes -
Iceland allows whaling to resume – activists say that whales will still suffer agonising deaths despite new regulations and monitoring
23 votes -
Live roundworm found in Australian woman's brain in world-first discovery
14 votes -
Scientists release the first complete sequence of a human Y chromosome
19 votes