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Tag Archives: Explanation
Mystery divers rescued near Polish energy sites in the middle of the night offer dubious explanation, and vanish
Coast guards rescued three divers off the northern coast of Poland over the weekend whose dubious explanation of their night-time dive near critical energy infrastructure, along with their mysterious identities, has reportedly sparked a cross-agency investigation. The three men, who told authorities they were Spanish nationals, were rescued near the Polish coastal city of Gdansk on Saturday night after their small motorboat broke down and they couldn’t return to shore.
Since then, doubts over their intentions have mounted. They were rescued not far from the Naftoport facility at the Port of Gdansk, which receives tanker shipments of oil and other and petroleum products. They were also found near an area where there are plans to build a new floating natural gas terminal.
Pomeranian Police
The Maritime Search and Rescue Service SAR told CBS News the rescue operation involved police officers, firefighters, and medical workers. SAR spokesman Rafal Goeck described the rescue operation — at just before 2 a.m. local time — as “rather unnatural.”
“We received a signal from the fire brigade about a vessel in trouble,” Goeck told CBS News, adding that conditions at the time were rough, with strong winds and high seas. The air temperature was only about 43 degrees Fahrenheit, and the water was closer to 37.
“In my 12-year career at the Maritime Search and Rescue Service, I have not experienced anything like that,” he said. “It is a rather unnatural thing to be diving under these conditions.”
Michal Fludra/NurPhoto/Getty
The red, 13-foot pleasure boat broke down about three nautical miles north of Gdansk. The vessel’s crew said they’d been struggling for six hours to get it running again. There was no explanation as to why they might have waited so long, in the dark and cold on a rough sea, to call for help.
Police officials determined that the men were not authorized to operate the boat and had not obtained permission to dive. According to Polish media reports, only one of the men had a Spanish passport, while the others offered only verbal identification.
Another wrinkle was their explanation: The men claimed to have been searching for amber. While the Baltic Sea is famous for its vast deposits of amber, searching for it in the dark is unlikely to be a successful strategy.
Gdansk Maritime Assistance Service (SAR)
Seasoned amber hunters interviewed by Polish media said one more thing didn’t add up: The men had an underwater scooter, used to drag divers swiftly through the water — something that wouldn’t help in a hunt for small objects on the seafloor, especially as such a device’s propeller lifts debris from the bottom, decreasing visibility.
Officers apparently saw nothing suspicious at first in the fact that the men were diving near critical infrastructure at night with no permit and atypical amber-hunting equipment, and the local police did not pursue the matter, releasing the men without further questioning.
They have all reportedly left Poland.
Cezary Przepiorka, deputy captain of the Port of Gdansk, told Polish media that only one of the men had formal identification, and the phone numbers offered by the divers were either incorrect or non-functional.
Police and the Polish Internal Security Agency have begun investigating the matter. Various reports say Poland’s Central Investigation Bureau of Police, a unit that deals with organized crime, is the lead agency. The bureau declined CBS News’ request to comment on the case.
The incident has raised serious concerns about the protection of vital national energy infrastructure as Russia’s ongoing war in Ukraine continues to keep energy prices sky-high. A thorough investigation can be expected, especially so soon after the sabotage attack on the undersea Nordstream 1 gas pipeline just weeks ago.
European and U.S. officials have strongly suggested that Russia was behind the attack on the pipeline.
Poland’s port of Gdansk, which is vital to the country’s energy supplies, sits only about 20 miles from Russia’s far-flung, equally strategic western territory of Kaliningrad.
Scientists offer a new explanation for a mystery surrounding Jupiter’s two massive asteroid swarms
An international team of scientists, including NYU Abu Dhabi researcher Nikolaos Georgakarakos and others from the U.S., Japan, and China, led by Jian Li from Nanjing University, has developed new insights that may explain the numerical asymmetry of the L4 and L5 Jupiter Trojan swarms, two clusters containing more than 10,000 asteroids that move along Jupiter’s orbital path around the sun.
For decades, scientists have known that there are significantly more asteroids in the L4 swarm than the L5 swarm, but have not fully understood the reason for this asymmetry. In the current configuration of the solar system, the two swarms show almost identical dynamical stability and survivability properties, which has led scientists to believe that the differences came about during earlier times of our solar system’s life. Determining the cause of these differences could uncover new details about the formation and evolution of the solar system.
In the paper, “Asymmetry in the number of L4 and L5 Jupiter Trojans driven by jumping Jupiter,” published in the journal Astronomy & Astrophysics, the researchers present a mechanism that can explain the observed number asymmetry.
“We propose that an outward—in terms of distance to the sun—fast migration of Jupiter can distort the configuration of the Trojan swarms, resulting in more stable orbits in the L4 swarm than in the L5 one,” said Li.
“This mechanism, which temporarily induced different evolution paths for the two asteroid groups that share the orbit of Jupiter, provides a new and natural explanation for the unbiased observation, that the L4 asteroids are about 1.6 times more than the asteroids in the L5 swarm.”
The model simulates the orbital evolution of Jupiter, caused by a planetary orbital instability in the early solar system. This led to the outward migration of Jupiter at a very high speed; a migration that the researchers hypothesize was the possible cause of the changes in the stability of the nearby asteroid swarms. Future models could expand on this work by including additional aspects of the evolution of the solar system, which could depict it with improved accuracy. This could include simulating the fast migrations of Jupiter at different speeds, and the effects of nearby planets.
“The characteristics of the current solar system hold as-yet unsolved mysteries into its formation and early evolution,” said Georgakarakos.
“The ability to successfully simulate an event from an early stage of the solar system’s development and apply those results to modern day questions can also be a key tool as astrophysicists and other researchers work to learn more about the dawn of our world.”
More information:
Jian Li et al, Asymmetry in the number of L4 and L5 Jupiter Trojans driven by jumping Jupiter, Astronomy & Astrophysics (2022). DOI: 10.1051/0004-6361/202244443
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Scientists offer a new explanation for a mystery surrounding Jupiter’s two massive asteroid swarms (2023, January 17)
retrieved 18 January 2023
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New measurements of galaxy rotation lean toward modified gravity as an explanation for dark matter
Although dark matter is a central part of the standard cosmological model, it’s not without its issues. There continue to be nagging mysteries about the stuff, not the least of which is the fact that scientists have found no direct particle evidence of it.
Despite numerous searches, we have yet to detect dark matter particles. So some astronomers favor an alternative, such as modified Newtonian dynamics (MoND) or modified gravity model. And a new study of galactic rotation seems to support them.
The idea of MoND was inspired by galactic rotation. Most of the visible matter in a galaxy is clustered in the middle, so you’d expect that stars closer to the center would have faster orbital speeds than stars farther away, similar to the planets of our solar system. What we observe is that stars in a galaxy all rotate at about the same speed. The rotation curve is essentially flat rather than dropping off. The dark matter solution is that galaxies are surrounded by a halo of invisible matter, but in 1983 Mordehai Milgrom argued that our gravitational model must be wrong.
At interstellar distances, the gravitational attraction between stars is essentially Newtonian. So rather than modifying general relativity, Milgrom proposed modifying Newton’s universal law of gravity. He argued that rather than the force of attraction as a pure inverse square relation, gravity has a small remnant pull regardless of distance. This remnant is only about 10 trillionths of a G, but it’s enough to explain galactic rotation curves.
Of course, just adding a small term to Newton’s gravity means that you also have to modify Einstein’s equations, as well. So MoND has been generalized in various ways, such as AQUAL, which stands for “a quadradic Lagrangian.” Both AQUAL and the standard LCDM model can explain observed galactic rotation curves, but there are some subtle differences.
This is where a recent study comes in. One difference between AQUAL and LCDM is in the rotation speeds of inner orbit stars vs. outer orbit stars. For LCDM, both should be governed by the distribution of matter, so the curve should be smooth. AQUAL predicts a tiny kink in the curve due to the dynamics of the theory. It’s too small to measure in a single galaxy, but statistically, there should be a small shift between the inner and outer velocity distributions.
So the author of this paper looked at high-resolution velocity curves of 152 galaxies as observed in the Spitzer Photometry and Accurate Rotation Curves (SPARC) database. He found a shift in agreement with AQUAL. The data seems to support modified gravity over standard dark matter cosmology.
The result is exciting, but it doesn’t conclusively overturn dark matter. The AQUAL model has its own issues, such as its disagreement with observed gravitational lensing by galaxies. But it is a win for the underdog theory, which has some astronomers cheering “Vive le MoND!”
The research is published on the arXiv preprint server.
More information:
Kyu-Hyun Chae, Distinguishing Dark Matter, Modified Gravity, and Modified Inertia with the Inner and Outer Parts of Galactic Rotation Curves, arXiv (2022). DOI: 10.48550/arxiv.2207.11069
Journal information:
arXiv
Provided by
Universe Today
Citation:
New measurements of galaxy rotation lean toward modified gravity as an explanation for dark matter (2022, December 30)
retrieved 31 December 2022
from https://phys.org/news/2022-12-galaxy-rotation-gravity-explanation-dark.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no
part may be reproduced without the written permission. The content is provided for information purposes only.
Elon Musk’s Twitter bans several prominent journalists without explanation
New York
CNN
—
Twitter on Thursday evening banned the accounts of several high-profile journalists from top news organizations without explanation, apparently marking a significant attempt by new owner Elon Musk to wield his unilateral authority over the platform.
The accounts belonging to CNN’s Donie O’Sullivan, The New York Times’ Ryan Mac, The Washington Post’s Drew Harwell and other journalists who have covered Musk aggressively in recent weeks were all abruptly permanently suspended. The account of progressive independent journalist Aaron Rupar was also banned.
Neither Musk nor Twitter responded to a request for comment Thursday evening, and the platform did not explain precisely why the journalists were exiled from the platform. But as the news broke online, Musk tweeted that the “same doxxing rules apply to ‘journalists’ as to everyone else,” in an apparent reference to a now-banned flight tracking Twitter account at the center of recent controversy.
The bans raised a number of questions about the future of the platform, which has been referred to as a digital town square. It also called into serious question Musk’s supposed commitment to free speech.
Musk has repeatedly said he would like to permit all legal speech on the platform; in April, on the same day he announced he would purchase Twitter, he had tweeted: “I hope that even my worst critics remain on Twitter, because that is what free speech means.”
A CNN spokesperson said the company has asked Twitter for an explanation, and it would “reevaluate our relationship based on that response.”
“The impulsive and unjustified suspension of a number of reporters, including CNN’s Donie O’Sullivan, is concerning but not surprising. Twitter’s increasing instability and volatility should be of incredible concern for everyone who uses Twitter,” the spokesperson said.
A New York Times spokesperson called the mass bans “questionable and unfortunate,” adding: “Neither The Times nor Ryan have received any explanation about why this occurred. We hope that all of the journalists’ accounts are reinstated and that Twitter provides a satisfying explanation for this action.”
“Elon says he is a free speech champion and he is banning journalists for exercising free speech,” Harwell told CNN on Thursday. “I think that calls into question his commitment.”
Rupar, too, said he had heard “nothing” from Twitter about the suspension.
The suspensions come after Twitter shut down an account belonging to Mastodon, an emerging competitor, also on Thursday.
The Mastodon account had tweeted earlier in the day that people could follow @ElonJet, the account that tracks Musk’s private plane on its platform, after the billionaire banned @ElonJet from Twitter on Wednesday.
That tweet is likely what ran afoul of Twitter’s rules. In his quest to rid Twitter of @ElonJet, Musk introduced new policies banning accounts that track people’s live locations.
Musk also blocked any account from linking to such information, as Mastodon did by linking to the account on its platform.
The move comes after Musk reinstated previous Twitter rule-breakers and stopped enforcing the platform’s policies prohibiting Covid-19 misinformation.
Several of the journalists banned Thursday had covered the ban of the @ElonJet account, and highlighted the irony of Musk’s self-purported mission to advance free speech.
“Free speech is when the world’s second-richest man threatens legal action against a 20-year-old college student for sharing publicly available data he doesn’t like,” Harwell tweeted before his account was taken down, referring to Jack Sweeney, the college student who runs @ElonJet.
CNN’s O’Sullivan, too, had been covering the story, having interviewed Sweeney and his grandmother about the issue.
“I do think this is very important for the potential chilling impact this can have for freelance journalists, independent journalists around the world, particularly those who cover Elon Musk’s other companies, like Tesla and SpaceX,” O’Sullivan told CNN Thursday after his account was suspended.
As the furor over the account suspensions unfolded, some Twitter users reported the platform had begun intervening when they attempted to post links to their own profiles on alternative social networks, including Mastodon.
Those reports were confirmed Thursday evening by a CNN reporter who was blocked from sharing a Mastodon profile URL and was given an automated error message that said Twitter or its partners had identified the site as “potentially harmful.”
525-Million-Year-Old Fossil Defies Textbook Explanation for Brain Evolution
Summary: The fossil of a 525-million-year-old tiny sea creature with a preserved nervous system may solve a century-long debate about how the brains of arthropods evolved.
Source: University of Arizona
Fossils of a tiny sea creature that died more than half a billion years ago may compel a science textbook rewrite of how brains evolved.
A study published in Science – led by Nicholas Strausfeld, a Regents Professor in the University of Arizona Department of Neuroscience, and Frank Hirth, a reader of evolutionary neuroscience at King’s College London – provides the first detailed description of Cardiodictyon catenulum, a wormlike animal preserved in rocks in China’s southern Yunnan province. Measuring barely half an inch (less than 1.5 centimeters) long and initially discovered in 1984, the fossil had hidden a crucial secret until now: a delicately preserved nervous system, including a brain.
“To our knowledge, this is the oldest fossilized brain we know of, so far,” Strausfeld said.
Cardiodictyon belonged to an extinct group of animals known as armored lobopodians, which were abundant early during a period known as the Cambrian, when virtually all major animal lineages appeared over an extremely short time between 540 million and 500 million years ago.
Lobopodians likely moved about on the sea floor using multiple pairs of soft, stubby legs that lacked the joints of their descendants, the euarthropods – Greek for “real jointed foot.” Today’s closest living relatives of lobopodians are velvet worms that live mainly in Australia, New Zealand and South America.
A debate going back to the 1800s
Fossils of Cardiodictyon reveal an animal with a segmented trunk in which there are repeating arrangements of neural structures known as ganglia. This contrasts starkly with its head and brain, both of which lack any evidence of segmentation.
“This anatomy was completely unexpected because the heads and brains of modern arthropods, and some of their fossilized ancestors, have for over a hundred years been considered as segmented,” Strausfeld said.
According to the authors, the finding resolves a long and heated debate about the origin and composition of the head in arthropods, the world’s most species-rich group in the animal kingdom. Arthropods include insects, crustaceans, spiders and other arachnids, plus some other lineages such as millipedes and centipedes.
“From the 1880s, biologists noted the clearly segmented appearance of the trunk typical for arthropods, and basically extrapolated that to the head,” Hirth said. “That is how the field arrived at supposing the head is an anterior extension of a segmented trunk.”
“But Cardiodictyon shows that the early head wasn’t segmented, nor was its brain, which suggests the brain and the trunk nervous system likely evolved separately,” Strausfeld said.
Brains do fossilize
Cardiodictyon was part of the Chengjiang fauna, a famous deposit of fossils in the Yunnan Province discovered by paleontologist Xianguang Hou. The soft, delicate bodies of lobopodians have preserved well in the fossil record, but other than Cardiodictyon none have been scrutinized for their head and brain, possibly because lobopodians are generally small.
The most prominent parts of Cardiodictyon were a series of triangular, saddle-shaped structures that defined each segment and served as attachment points for pairs of legs. Those had been found in even older rocks dating back to the advent of the Cambrian.
“That tells us that armored lobopodians might have been the earliest arthropods,” Strausfeld said, predating even trilobites, an iconic and diverse group of marine arthropods that went extinct around 250 million years ago.
“Until very recently, the common understanding was ‘brains don’t fossilize,’” Hirth said. “So you would not expect to find a fossil with a preserved brain in the first place. And, second, this animal is so small you would not even dare to look at it in hopes of finding a brain.”
However, work over the last 10 years, much of it done by Strausfeld, has identified several cases of preserved brains in a variety of fossilized arthropods.
A common genetic ground plan for making a brain
In their new study, the authors not only identified the brain of Cardiodictyon but also compared it with those of known fossils and of living arthropods, including spiders and centipedes.
Combining detailed anatomical studies of the lobopodian fossils with analyses of gene expression patterns in their living descendants, they conclude that a shared blueprint of brain organization has been maintained from the Cambrian until today.
“By comparing known gene expression patterns in living species,” Hirth said, “we identified a common signature of all brains and how they are formed.”
In Cardiodictyon, three brain domains are each associated with a characteristic pair of head appendages and with one of the three parts of the anterior digestive system.
“We realized that each brain domain and its corresponding features are specified by the same combination genes, irrespective of the species we looked at,” added Hirth. “This suggested a common genetic ground plan for making a brain.”
Lessons for vertebrate brain evolution
See also
Hirth and Strausfeld say the principles described in their study probably apply to other creatures outside of arthropods and their immediate relatives. This has important implications when comparing the nervous system of arthropods with those of vertebrates, which show a similar distinct architecture in which the forebrain and midbrain are genetically and developmentally distinct from the spinal cord, they said.
Strausfeld said their findings also offer a message of continuity at a time when the planet is changing dramatically under the influence of climatic shifts.
“At a time when major geological and climatic events were reshaping the planet, simple marine animals such as Cardiodictyon gave rise to the world’s most diverse group of organisms – the euarthropods – that eventually spread to every emergent habitat on Earth, but which are now being threatened by our own ephemeral species.”
The paper, “The Lower Cambrian Lobopodian Cardiodictyon Resolves the Origin of Euarthropod Brains” was co-authored by Xianguang Hou at the Yunnan Key Laboratory for Paleontology in Yunnan University in Kunming, China, and Marcel Sayre, who has appointments at Lund University in Lund, Sweden, and at the Department of Biological Sciences at Macquarie University in Sydney.
Funding: Funding for this work was provided by the National Science Foundation, the University of Arizona Regents Fund, and the UK Biotechnology and Biological Sciences Research Council.
About this evolutionary neuroscience research news
Author: Daniel Stolte
Source: University of Arizona
Contact: Daniel Stolte – University of Arizona
Image: The image is credited to Nicholas Strausfeld/University of Arizona
Original Research: Closed access.
“The lower Cambrian lobopodian Cardiodictyon resolves the origin of euarthropod brains” by Nicholas Strausfeld et al. Science
Abstract
The lower Cambrian lobopodian Cardiodictyon resolves the origin of euarthropod brains
For more than a century, the origin and evolution of the arthropod head and brain have eluded a unifying rationale reconciling divergent morphologies and phylogenetic relationships.
Here, clarification is provided by the fossilized nervous system of the lower Cambrian lobopodian Cardiodictyon catenulum, which reveals an unsegmented head and brain comprising three cephalic domains, distinct from the metameric ventral nervous system serving its appendicular trunk. Each domain aligns with one of three components of the foregut and with a pair of head appendages.
Morphological correspondences with stem group arthropods and alignments of homologous gene expression patterns with those of extant panarthropods demonstrate that cephalic domains of C. catenulum predate the evolution of the euarthropod head yet correspond to neuromeres defining brains of living chelicerates and mandibulates.
Science Textbooks Wrong? 525-Million-Year-Old Fossil Defies Common Explanation for Brain Evolution
Artist’s impression of an individual 525-million-year-old Cardiodictyon catenulum on the shallow coastal sea floor, emerging from the shelter of a small stromatolite built by photosynthetic bacteria. Credit: Nicholas Strausfeld/University of Arizona
According to a new study, fossils of a tiny sea creature with a delicately preserved nervous system solve a century-old debate over how the brain evolved in arthropods, the most species-rich group in the animal kingdom.
Fossils of a tiny sea creature that died more than half a billion years ago may compel a science textbook rewrite of how brains evolved.
A new study provides the first detailed description of Cardiodictyon catenulum, a wormlike animal preserved in rocks in China’s southern Yunnan province. Measuring barely half an inch (less than 1.5 centimeters) long and initially discovered in 1984, the fossil had hidden a crucial secret until now: a delicately preserved nervous system, including a brain. Published in the journal Science on November 24, the research was led by Nicholas Strausfeld, a Regents Professor in the University of Arizona Department of Neuroscience, and Frank Hirth, a reader of evolutionary neuroscience at King’s College London.
“To our knowledge, this is the oldest fossilized brain we know of, so far,” Strausfeld said.
Cardiodictyon belonged to an extinct group of animals known as armored lobopodians, which were abundant early during a period known as the Cambrian, when virtually all major animal lineages appeared over an extremely short time between 540 million and 500 million years ago. Lobopodians likely moved about on the sea floor using multiple pairs of soft, stubby legs that lacked the joints of their descendants, the euarthropods – Greek for “real jointed foot.” Today’s closest living relatives of lobopodians are velvet worms that live mainly in Australia, New Zealand, and South America.
The fossilized Cardiodictyon catenulum was discovered in 1984 among a diverse assemblage of extinct creatures known as the Chengjian fauna in Yunnan, China. In this photo, the animal’s head is to the right. Credit: Nicholas Strausfeld/University of Arizona
A debate going back to the 1800s
Fossils of Cardiodictyon reveal an animal with a segmented trunk in which there are repeating arrangements of neural structures known as ganglia. This contrasts starkly with its head and brain, both of which lack any evidence of segmentation.
“This anatomy was completely unexpected because the heads and brains of modern arthropods, and some of their fossilized ancestors, have for over a hundred years been considered as segmented,” Strausfeld said.
According to the authors, the finding resolves a long and heated debate about the origin and composition of the head in arthropods, the world’s most species-rich group in the animal kingdom. Arthropods include insects, crustaceans, spiders, and other arachnids, plus some other lineages such as millipedes and centipedes.
“From the 1880s, biologists noted the clearly segmented appearance of the trunk typical for arthropods, and basically extrapolated that to the head,” Hirth said. “That is how the field arrived at supposing the head is an anterior extension of a segmented trunk.”
“But Cardiodictyon shows that the early head wasn’t segmented, nor was its brain, which suggests the brain and the trunk nervous system likely evolved separately,” Strausfeld said.
Fossilized head of Cardiodictyon catenulum (anterior is to the right). The magenta-colored deposits mark fossilized brain structures. Credit: Nicholas Strausfeld
Brains do fossilize
Cardiodictyon was part of the Chengjiang fauna, a famous deposit of fossils in the Yunnan Province discovered by paleontologist Xianguang Hou. The soft, delicate bodies of lobopodians have preserved well in the fossil record, but other than Cardiodictyon none have been scrutinized for their head and brain, possibly because lobopodians are generally small. The most prominent parts of Cardiodictyon were a series of triangular, saddle-shaped structures that defined each segment and served as attachment points for pairs of legs. Those had been found in even older rocks dating back to the advent of the Cambrian.
“That tells us that armored lobopodians might have been the earliest arthropods,” Strausfeld said, predating even trilobites, an iconic and diverse group of marine arthropods that went extinct around 250 million years ago.
“Until very recently, the common understanding was ‘brains don’t fossilize,’” Hirth said. “So you would not expect to find a fossil with a preserved brain in the first place. And, second, this animal is so small you would not even dare to look at it in hopes of finding a brain.”
However, work over the last 10 years, much of it done by Strausfeld, has identified several cases of preserved brains in a variety of fossilized arthropods.
A common genetic ground plan for making a brain
In their new study, the authors not only identified the brain of Cardiodictyon but also compared it with those of known fossils and of living arthropods, including spiders and centipedes. Combining detailed anatomical studies of the lobopodian fossils with analyses of gene expression patterns in their living descendants, they conclude that a shared blueprint of brain organization has been maintained from the Cambrian until today.
“By comparing known gene expression patterns in living species,” Hirth said, “we identified a common signature of all brains and how they are formed.”
In Cardiodictyon, three brain domains are each associated with a characteristic pair of head appendages and with one of the three parts of the anterior digestive system.
“We realized that each brain domain and its corresponding features are specified by the same combination genes, irrespective of the species we looked at,” added Hirth. “This suggested a common genetic ground plan for making a brain.”
Lessons for vertebrate brain evolution
Hirth and Strausfeld say the principles described in their study probably apply to other creatures outside of arthropods and their immediate relatives. This has important implications when comparing the nervous system of arthropods with those of vertebrates, which show a similar distinct architecture in which the forebrain and midbrain are genetically and developmentally distinct from the spinal cord, they said.
Strausfeld said their findings also offer a message of continuity at a time when the planet is changing dramatically under the influence of climatic shifts.
“At a time when major geological and climatic events were reshaping the planet, simple marine animals such as Cardiodictyon gave rise to the world’s most diverse group of organisms – the euarthropods – that eventually spread to every emergent habitat on Earth, but which are now being threatened by our own ephemeral species.”
Reference: “The Lower Cambrian Lobopodian Cardiodictyon Resolves the Origin of Euarthropod Brains” by Nicholas J. Strausfeld, Xianguang Hou, Marcel E. Sayre and Frank Hirth, 24 November 2022, Science.
DOI: 10.1126/science.abn6264
The paper was co-authored by Xianguang Hou at the Yunnan Key Laboratory for Paleontology in Yunnan University in Kunming, China, and Marcel Sayre, who has appointments at Lund University in Lund, Sweden, and at the Department of Biological Sciences at Macquarie University in Sydney.
Funding for this work was provided by the National Science Foundation, the University of Arizona Regents Fund, and the UK Biotechnology and Biological Sciences Research Council.
525-million-year-old fossil defies textbook explanation for brain evolution
Fossils of a tiny sea creature that died more than half a billion years ago may compel a science textbook rewrite of how brains evolved.
A study published in Science—led by Nicholas Strausfeld, a Regents Professor in the University of Arizona Department of Neuroscience, and Frank Hirth, a reader of evolutionary neuroscience at King’s College London—provides the first detailed description of Cardiodictyon catenulum, a wormlike animal preserved in rocks in China’s southern Yunnan province. Measuring barely half an inch (less than 1.5 centimeters) long and initially discovered in 1984, the fossil had hidden a crucial secret until now: a delicately preserved nervous system, including a brain.
“To our knowledge, this is the oldest fossilized brain we know of, so far,” Strausfeld said.
Cardiodictyon belonged to an extinct group of animals known as armored lobopodians, which were abundant early during a period known as the Cambrian, when virtually all major animal lineages appeared over an extremely short time between 540 million and 500 million years ago. Lobopodians likely moved about on the sea floor using multiple pairs of soft, stubby legs that lacked the joints of their descendants, the euarthropods—Greek for “real jointed foot.” Today’s closest living relatives of lobopodians are velvet worms that live mainly in Australia, New Zealand and South America.
A debate going back to the 1800s
Fossils of Cardiodictyon reveal an animal with a segmented trunk in which there are repeating arrangements of neural structures known as ganglia. This contrasts starkly with its head and brain, both of which lack any evidence of segmentation.
“This anatomy was completely unexpected because the heads and brains of modern arthropods, and some of their fossilized ancestors, have for over a hundred years been considered as segmented,” Strausfeld said.
According to the authors, the finding resolves a long and heated debate about the origin and composition of the head in arthropods, the world’s most species-rich group in the animal kingdom. Arthropods include insects, crustaceans, spiders and other arachnids, plus some other lineages such as millipedes and centipedes.
“From the 1880s, biologists noted the clearly segmented appearance of the trunk typical for arthropods, and basically extrapolated that to the head,” Hirth said. “That is how the field arrived at supposing the head is an anterior extension of a segmented trunk.”
“But Cardiodictyon shows that the early head wasn’t segmented, nor was its brain, which suggests the brain and the trunk nervous system likely evolved separately,” Strausfeld said.
Brains do fossilize
Cardiodictyon was part of the Chengjiang fauna, a famous deposit of fossils in the Yunnan Province discovered by paleontologist Xianguang Hou. The soft, delicate bodies of lobopodians have preserved well in the fossil record, but other than Cardiodictyon none have been scrutinized for their head and brain, possibly because lobopodians are generally small. The most prominent parts of Cardiodictyon were a series of triangular, saddle-shaped structures that defined each segment and served as attachment points for pairs of legs. Those had been found in even older rocks dating back to the advent of the Cambrian.
“That tells us that armored lobopodians might have been the earliest arthropods,” Strausfeld said, predating even trilobites, an iconic and diverse group of marine arthropods that went extinct around 250 million years ago.
“Until very recently, the common understanding was ‘brains don’t fossilize,'” Hirth said. “So you would not expect to find a fossil with a preserved brain in the first place. And, second, this animal is so small you would not even dare to look at it in hopes of finding a brain.”
However, work over the last 10 years, much of it done by Strausfeld, has identified several cases of preserved brains in a variety of fossilized arthropods.
A common genetic ground plan for making a brain
In their new study, the authors not only identified the brain of Cardiodictyon but also compared it with those of known fossils and of living arthropods, including spiders and centipedes. Combining detailed anatomical studies of the lobopodian fossils with analyses of gene expression patterns in their living descendants, they conclude that a shared blueprint of brain organization has been maintained from the Cambrian until today.
“By comparing known gene expression patterns in living species,” Hirth said, “we identified a common signature of all brains and how they are formed.”
In Cardiodictyon, three brain domains are each associated with a characteristic pair of head appendages and with one of the three parts of the anterior digestive system.
“We realized that each brain domain and its corresponding features are specified by the same combination genes, irrespective of the species we looked at,” added Hirth. “This suggested a common genetic ground plan for making a brain.”
Lessons for vertebrate brain evolution
Hirth and Strausfeld say the principles described in their study probably apply to other creatures outside of arthropods and their immediate relatives. This has important implications when comparing the nervous system of arthropods with those of vertebrates, which show a similar distinct architecture in which the forebrain and midbrain are genetically and developmentally distinct from the spinal cord, they said.
Strausfeld said their findings also offer a message of continuity at a time when the planet is changing dramatically under the influence of climatic shifts.
“At a time when major geological and climatic events were reshaping the planet, simple marine animals such as Cardiodictyon gave rise to the world’s most diverse group of organisms—the euarthropods—that eventually spread to every emergent habitat on Earth, but which are now being threatened by our own ephemeral species.”
The paper, “The Lower Cambrian Lobopodian Cardiodictyon Resolves the Origin of Euarthropod Brains” was co-authored by Xianguang Hou at the Yunnan Key Laboratory for Paleontology in Yunnan University in Kunming, China, and Marcel Sayre, who has appointments at Lund University in Lund, Sweden, and at the Department of Biological Sciences at Macquarie University in Sydney.
More information:
Nicholas J. Strausfeld et al, The lower Cambrian lobopodian Cardiodictyon resolves the origin of euarthropod brains, Science (2022). DOI: 10.1126/science.abn6264. www.science.org/doi/10.1126/science.abn6264
Derek E. G. Briggs et al, Putting heads together, Science (2022). DOI: 10.1126/science.add7372
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525-million-year-old fossil defies textbook explanation for brain evolution (2022, November 25)
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Google Play services explanation now directly included in Android
Google Play services powers many key features on Android devices that might not be obvious to end users, and Google is now offering an explanation directly on your phone as part of a new approach.
If you go to Settings > Apps > See all > Google Play services, you’ll see a new “All Services” item as the first thing in the App info list underneath Disable and Force stop. Tapping lets you “See details about the services used on your device.” Google’s high-level explanation of Play services follows:
Google Play services helps to make your device more secure and reliable. It’s an important part of many of the features on your device, and it’s different from the Play Store app.
Keep in mind that turning off services can impact the way your device works.
The last line makes explicit reference to how some people disable it. Google specifically highlights 17 capabilities. Tapping takes you to settings pages, while the Info button next to things takes you to various support/help articles.
Of the devices we checked today, this is only appearing on Android 13 Pixel phones. The capability that lets Play services add this “All services” page to App info requires the latest version of the OS.
Account management: Used for secure sign-in and better control of your Google Account
- Links to settings for: Device phone number and Google Account
Ads: Used to control ad preferences and prevent ad spam
- Lets you: Reset advertising ID, Delete advertising ID, or Enable debug logging for ads
- Also shows device advertising ID
Autofill with Google: Used to fill in your info, such as passwords and payment methods
- Shows settings to enable/disable Autofill with Google
- Links to your saved Personal information, Addresses, Payment methods, and Passwords, as well as Preferences
Contacts: Used to sync your contacts with your Google Account and other devices
- Links to settings for: Google Contacts sync and Restore contacts
Data backup and transfer: Used to back up and restore your data, app settings, and account info
- Links to settings for: Settings > System > Backup
Developer features: Used for features that app developers can include to make their apps better and more reliable
Device connections: Used for connecting to other devices, such as a car, watch, or Chromebook
- Links to settings for: Cast options, Chromebook, Devices, and Nearby Share
Fitness: Used for fitness services in apps, such as workout tracking and sharing data with other fitness apps
- Links to settings for: Connect apps and devices and Manage data
Games: Used for automatic sign-in, leaderboards, achievements, and managing your gamer profile
- Links to settings for: Game Dashboard and Play Games
Location accuracy: Used to improve location accuracy using Wi-Fi, mobile networks, and sensors
- Lets you: Enable/disable Improve Location Accuracy
Location sharing: Used when you share your location with others
- Lets you see active shares
Safety & emergency: Used for emergency notifications and services, such as sharing your location during emergency calls and receiving crisis alerts
- Links to settings for: COVID-19 Exposure Notifications, Earthquake alerts, Emergency Location Service, and Silence notifications while driving
Security: Used for security features such as encrypting passwords, locking your device, blocking spam calls, and locating a lost device
- Links to settings for: Find My Device, Password Manager, SMS verification codes, and Smart Lock
Support: Used for features such as device setup, providing feedback to Google, and contacting Google support
System diagnostics: Used to collect data about your device and services and improve device experience
- Links to settings for: Usage & diagnostics
System management: Used to keep system services up to date and improve device performance
Wallet: Used to pay for purchases made on this device, including contactless payments
Thanks Dee!
Dylan Roussel contributed to this article.
FTC: We use income earning auto affiliate links. More.
Check out 9to5Google on YouTube for more news:
Google Play services explanation now directly included in Android
Google Play services powers many key features on Android devices that might not be obvious to end users, and Google is now offering an explanation directly on your phone as part of a new approach.
If you go to Settings > Apps > See all > Google Play services, you’ll see a new “All Services” item as the first thing in the App info list underneath Disable and Force stop. Tapping lets you “See details about the services used on your device.” Google’s high-level explanation of Play services follows:
Google Play services helps to make your device more secure and reliable. It’s an important part of many of the features on your device, and it’s different from the Play Store app.
Keep in mind that turning off services can impact the way your device works.
The last line makes explicit reference to how some people disable it. Google specifically highlights 17 capabilities. Tapping takes you to settings pages, while the Info button next to things takes you to various support/help articles.
Of the devices we checked today, this is only appearing on Android 13 Pixel phones. The capability that lets Play services add this “All services” page to App info requires the latest version of the OS.
Account management: Used for secure sign-in and better control of your Google Account
- Links to settings for: Device phone number and Google Account
Ads: Used to control ad preferences and prevent ad spam
- Lets you: Reset advertising ID, Delete advertising ID, or Enable debug logging for ads
- Also shows device advertising ID
Autofill with Google: Used to fill in your info, such as passwords and payment methods
- Shows settings to enable/disable Autofill with Google
- Links to your saved Personal information, Addresses, Payment methods, and Passwords, as well as Preferences
Contacts: Used to sync your contacts with your Google Account and other devices
- Links to settings for: Google Contacts sync and Restore contacts
Data backup and transfer: Used to back up and restore your data, app settings, and account info
- Links to settings for: Settings > System > Backup
Developer features: Used for features that app developers can include to make their apps better and more reliable
Device connections: Used for connecting to other devices, such as a car, watch, or Chromebook
- Links to settings for: Cast options, Chromebook, Devices, and Nearby Share
Fitness: Used for fitness services in apps, such as workout tracking and sharing data with other fitness apps
- Links to settings for: Connect apps and devices and Manage data
Games: Used for automatic sign-in, leaderboards, achievements, and managing your gamer profile
- Links to settings for: Game Dashboard and Play Games
Location accuracy: Used to improve location accuracy using Wi-Fi, mobile networks, and sensors
- Lets you: Enable/disable Improve Location Accuracy
Location sharing: Used when you share your location with others
- Lets you see active shares
Safety & emergency: Used for emergency notifications and services, such as sharing your location during emergency calls and receiving crisis alerts
- Links to settings for: COVID-19 Exposure Notifications, Earthquake alerts, Emergency Location Service, and Silence notifications while driving
Security: Used for security features such as encrypting passwords, locking your device, blocking spam calls, and locating a lost device
- Links to settings for: Find My Device, Password Manager, SMS verification codes, and Smart Lock
Support: Used for features such as device setup, providing feedback to Google, and contacting Google support
System diagnostics: Used to collect data about your device and services and improve device experience
- Links to settings for: Usage & diagnostics
System management: Used to keep system services up to date and improve device performance
Wallet: Used to pay for purchases made on this device, including contactless payments
Thanks Dee!
Dylan Roussel contributed to this article.
FTC: We use income earning auto affiliate links. More.
Check out 9to5Google on YouTube for more news:
