WFS

Formation of sedimentary layers of white clay, Tamilnadu, India

Fossil site for wood fossils, Tamilnadu, India

Fossil site in Kerala, India

Fossil wood park maintained by geological survey of India at Tamilnadu

Cretaceous fossil sites india

Fossils in rack:-Cyad

Fossils in rack:-echiniderms

Fossils in rack:-Rastellum sp

Pre-historic seabed, Cretaceous period

A fossilized lizard preserved in amber

March 6th, 2016

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A fossilized lizard preserved in amber and found in Southeast Asia is 99 million years old scientists have determined. That makes it the oldest ever specimen of its kind and could hold the key to a ‘lost ecosystem’.The fossil is about 75 million years older than the previous oldest lizard discovered, researchers at Florida Museum of Natural History said.

“It was incredibly exciting to see these animals for the first time. It was exciting and startling, actually, how well they were preserved,”researcher Edward Stanley said, as quoted by Reuters.

He added that the reptile’s entire body, including its eyes and scales, is preserved in “superb detail.” Usually, reptiles’ bodies decay quickly.

Lizards preserved in mid-Cretaceous Burmese amber. © advances.sciencemag.org

“We can pretty much see how the animals looked when they were alive,” Professor Juan Diego Daza, who led the research, said.

The lizard is thought to have been an infant reptile, living in a tropical forest in territory that is now Myanmar, Southeast Asia.

However, its journey ended when it became trapped in sticky resin.

Other animals trapped in the amber, are a gecko and an arctic lizard, although those are not as ancient as the 99-million-year-old reptile.

What might this amazing discovery lead to?

It could help us learn more about the “lost ecosystem, the lost world” the creatures lived in. Researchers could also find out more about the animals’ modern relatives.

“It’s kind of a missing link,” the professor said, as cited by Reuters.The research was published on Friday in Science Advances journal.

Key: WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society

Oldest fossil land organism identified

March 4th, 2016

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The earliest example of an organism living on land – an early type of fungus – has been identified. The organism, from 440 million years ago, likely kick-started the process of rot and soil formation, which encouraged the later growth and diversification of life on land.

A fossil dating from 440 million years ago is not only the oldest example of a fossilised fungus, but is also the oldest fossil of any land-dwelling organism yet found. The organism, and others like it, played a key role in laying the groundwork for more complex plants, and later animals, to exist on land by kick-starting the process of rot and soil formation, which is vital to all life on land.

Researcher Martin Smith identified fossils of a fungus called Tortotubus protuberans, seen in a highly magnified electron microscope image, that lived 445 to 443 million years ago, making it the oldest fossil land organism known. (Martin R. Smith)

This early pioneer, known as Tortotubus, displays a structure similar to one found in some modern fungi, which likely enabled it to store and transport nutrients through the process of decomposition. Although it cannot be said to be the first organism to have lived on land, it is the oldest fossil of a terrestrial organism yet found. The results are published in the Botanical Journal of the Linnean Society.

“During the period when this organism existed, life was almost entirely restricted to the oceans: nothing more complex than simple mossy and lichen-like plants had yet evolved on the land,” said the paper’s author Dr Martin Smith, who conducted the work while at the University of Cambridge’s Department of Earth Sciences, and is now based at Durham University. “But before there could be flowering plants or trees, or the animals that depend on them, the processes of rot and soil formation needed to be established.”

Working with a range of tiny microfossils from Sweden and Scotland, each shorter than a human hair is wide, Smith attempted to reconstruct the method of growth for two different types of fossils that were first identified in the 1980s. These fossils had once been thought to represent parts of two different organisms, but by identifying other fossils with ‘in-between’ forms, Smith was able to show that the fossils actually represented parts of a single organism at different stages of growth. By reconstructing how the organism grew, he was able to show that the fossils represent mycelium – the root-like filaments that fungi use to extract nutrients from soil.

It’s difficult to pinpoint exactly when life first migrated from the seas to the land, since useful features in the fossil record that could help identify the earliest land colonisers are rare, but it is generally agreed that the transition started early in the Palaeozoic era, between 500 and 450 million years ago. But before any complex forms of life could live on land, there needed to be nutrients there to support them. Fungi played a key role in the move to land, since by kick-starting the rotting process, a layer of fertile soil could eventually be built up, enabling plants with root systems to establish themselves, which in turn could support animal life.

Fungi play a vital role in the nitrogen cycle, in which nitrates in the soil are taken up by plant roots and passed along food chain into animals. Decomposing fungi convert nitrogen-containing compounds in plant and animal waste and remains back into nitrates, which are incorporated into the soil and can again be taken up by plants. These early fungi started the process by getting nitrogen and oxygen into the soil.

Smith found that Tortotubus had a cord-like structure, similar to that of some modern fungi, in which the main filament sends out primary and secondary branches that stick back onto the main filament, eventually enveloping it. This cord-like structure is often seen in land-based organisms, allowing them to spread out and colonise surfaces. In modern fungi, the structure is associated with the decomposition of matter, allowing a fungus colony to move nutrients to where they are needed – a useful adaptation in an environment where nutrients are scarce and unevenly distributed.

In contrast with early plants, which lacked roots and therefore had limited interaction with activity beneath the surface, fungi played an important role in stabilising sediment, encouraging weathering and forming soils.

“What we see in this fossil is complex fungal ‘behaviour’ in some of the earliest terrestrial ecosystems – contributing to soil formation and kick-starting the process of rotting on land,” said Smith. A question, however, is what was there for Tortotubus to decompose. According to Smith, it’s likely that there were bacteria or algae on land during this period, but these organisms are rarely found as fossils.

Additionally, the pattern of growth in Tortotubus echoes that of the mushroom-forming fungi, although unambiguous evidence of mushrooms has yet to be found in the Palaeozoic fossil record. “This fossil provides a hint that mushroom-forming fungi may have colonised the land before the first animals left the oceans,” said Smith. “It fills an important gap in the evolution of life on land.”

Key: WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society

Fossilized Nervous System found

March 2nd, 2016

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Researchers have found one of the oldest and most detailed fossils of the central nervous system yet identified, from a crustacean-like animal that lived more than 500 million years ago. The fossil, from southern China, has been so well preserved that individual nerves are visible, the first time this level of detail has been observed in a fossil of this age.

The findings, published in the Proceedings of the National Academy of Sciences, are helping researchers understand how the nervous system of arthropods – creepy crawlies with jointed legs – evolved. Finding any fossilised soft tissue is rare, but this particular find, by researchers in the UK, China and Germany, represents the most detailed example of a preserved nervous system yet discovered.

The animal, called Chengjiangocaris kunmingensis, lived during the Cambrian ‘explosion’, a period of rapid evolutionary development about half a billion years ago when most major animal groups first appear in the fossil record. C. kunmingensis belongs to a group of animals called fuxianhuiids, and was an early ancestor of modern arthropods – the diverse group that includes insects, spiders and crustaceans.

Complete specimen of Chengjiangocaris kunmingensis from the early Cambrian Xiaoshiba biota of South China. Bottom: Magnification of ventral nerve cord of Chengjiangocaris kunmingensis.Credit: Top: Jie Yang, Bottom: Yu Liu

“This is a unique glimpse into what the ancestral Fossilized Nervous System looked like,” said study co-author Dr Javier Ortega-Hernández, of the University of Cambridge’s Department of Zoology. “It’s the most complete example of a central nervous system from the Cambrian period.”

Over the past five years, researchers have identified partially fossilised nervous systems in several different species from the period, but these have mostly been fossilised brains. And in most of those specimens, the fossils only preserved details of the profile of the brain, meaning the amount of information available has been limited.

C. kunmingensis looked like a sort of crustacean, with a broad, almost heart-shaped head shield, and a long body with pairs of legs of varying sizes. Through careful preparation of the fossils, which involved chipping away the surrounding rock with a fine needle, the researchers were able to view not only the hard parts of the body, but fossilised soft tissue as well.

The vast majority of fossils we have are mostly bone and other hard body parts such as teeth or exoskeletons. Since the nervous system and soft tissues are essentially made of fatty-like substances, finding them preserved as fossils is extremely rare. The researchers behind this study first identified a fossilised central nervous system in 2013, but the new material has allowed them to investigate the significance of these finding in much greater depth.

The central nervous system coordinates all neural and motor functions. In vertebrates, it consists of the brain and spinal cord, but in arthropods it consists of a condensed brain and a chain-like series of interconnected masses of nervous tissue called ganglia that resemble a string of beads.

Like modern arthropods, C. kunmingensis had a nerve cord – which is analogous to a spinal cord in vertebrates – running throughout its body, with each one of the bead-like ganglia controlling a single pair of walking legs.

Closer examination of the exceptionally preserved ganglia revealed dozens of spindly fibres, each measuring about five thousandths of a millimetre in length. “These delicate fibres displayed a highly regular distribution pattern, and so we wanted to figure out if they were made of the same material as the ganglia that form the nerve cord,” said Ortega-Hernández. “Using fluorescence microscopy, we confirmed that the fibres were in fact individual nerves, fossilised as carbon films, offering an unprecedented level of detail. These fossils greatly improve our understanding of how the nervous system evolved.”

For Ortega-Hernández and his colleagues, a key question is what this discovery tells us about the evolution of early animals, since the nervous system contains so much information. Further analysis revealed that some aspects of the nervous system in C. kunmingensis appear to be structured similar to that of modern priapulids (penis worms) and onychophorans (velvet worms), with regularly-spaced nerves coming out from the ventral nerve cord.

In contrast, these dozens of nerves have been lost independently in the tardigrades (water bears) and modern arthropods, suggesting that simplification played an important role in the evolution of the nervous system.

Possibly one of the most striking implications of the study is that the exceptionally preserved nerve cord of C. kunmingensis represents a unique structure that is otherwise unknown in living organisms. The specimen demonstrates the unique contribution of the fossil record towards understanding the early evolution of animals during the Cambrian period. “The more of these fossils we find, the more we will be able to understand how the nervous system – and how early animals – evolved,” said Ortega-Hernández.

Key: WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society

Patagonia: The land of Jurassic-Era

February 29th, 2016

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Paleontologists in Argentina have announced the discovery of a major Jurassic-era fossil site four years after it was first discovered.

The site, which spans 23,000 square miles (60,000 square kilometers) in Patagonia, southern Argentina, came to light this week with the publication of a report in the journal Ameghiniana.

“No other place in the world contains the same amount and diversity of Jurassic fossils,” said geologist Juan Garcia Massini of the Regional Center for Scientific Research and Technology Transfer (CRILAR).

The fossils — between 140 and 160 million years old — lie on the surface because they were recently exposed by erosion, said Garcia Massini, who leads the research team investigating the site.

“You can see the landscape as it appeared in the Jurassic — how thermal waters, lakes and streams as well as plants and other parts of the ecosystem were distributed,” he said.

The fossils were preserved almost immediately, in less than a day in some cases.

“You can see how fungi, cyanobacteria and worms moved when they were alive,” Garcia Massini said of the site that lies along the Deseado Massif mountain range.

Ignacio Escapa of the Egidio Feruglio Paleontology Museum said the researchers had found “a wide range of micro and macro-organisms.”

The fossils are so well preserved, that researchers say each rock extracted from the site could possibly open the door to a new discovery.

Patagonia

Key: WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society

Fukuivenator : New Dinosaur from Japan

February 28th, 2016

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A new kind of dinosaur has been confirmed in Katsuyama, Fukui Prefecture, researchers said Friday, bringing the number of species discovered in Japan to seven.

According to fossil analysis, the new creature was a small theropod that had both primitive and derived features, according to the Fukui Prefectural Dinosaur Museum and Fukui Prefectural University. It has been named Fukuivenator paradoxus, or “paradoxical hunter of Fukui.”

A skeleton model of the new dinosaur species Fukuivenator paradoxus is displayed at the Fukui Prefectural Dinosaur Museum in Katsuyama, where fossil fragments from it were unearthed in 2007. | FUKUI PREFECTURAL DINOSAUR MUSEUM/KYODO

Fukuivenator is a species that existed when theropods began to evolve into birds, according to Yoichi Azuma, a professor at the university. Fukuivenator “failed to become a bird.”

Fukuivenator was about 2½ meters long and weighed about 25 kg, Azuma said.

The discovery emerged from a study of some 160 fossil fragments from an animal found in August 2007 in a stratum from the Lower Cretaceous period, some 120 million years ago. Some 70 percent of its body parts were left in very good condition.

Reconstructed skull of Fukuivenator paradoxus holotype, premaxilla and dentary flipped, and frontal shown in dorsal view (modified from Azuma et al., 2016).

Fukuivenator, which was covered with feathers, had two-forked cervical vertebrae, which are not found in any other theropod. Its hearing was equivalent to that of birds, and the shapes of its scapula and thighbones are similar to those of the primitive Coelurosaur, from which flying animals originated.

In general, theropods, including Tyrannosaurus, are carnivorous. But Fukuivenator, which had a long neck, is believed to have been omnivorous.

Fossils of four new dinosaur species were found in the same stratum where those of Fukuivenator were excavated.

Key: WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society

Pentanogmius fritschi: fossil fish with sail

February 23rd, 2016

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A 90-million-year-old fossil fish, which has been on display at the Perot Museum of Nature and Science in Dallas, turns out to be a new species. Research conducted by Kenshu Shimada, Ph.D., professor at DePaul University in Chicago and research associate of the Sternberg Museum in Kansas, reveals the 5.5-foot-long fossil fish to possess a tuna-like body with a unique ‘hook-shaped sail’ on its back. The fish has been given a new species name,Pentanogmius fritschi, in honor of Joseph Fritsch, a local amateur collector who discovered the fossil, dug it up with the help of another avid fossil collector, Kris Howe, and donated it to the Perot Museum.

“At first glance, the specimen looked like a known Pentanogmius species, but when I began to trace the curved dorsal fin, its front half kept extending backwards far beyond where I thought it would end relative to its rear half. That’s when I realized I have something new to science,” said Dr. Shimada.

A 90-million-year-old fossil fish, currently on display at the Perot Museum of Nature and Science in Dallas, turns out to be a new species. Research conducted by Kenshu Shimada, Ph.D., professor at DePaul University and research associate of the Sternberg Museum, reveals the 5.5-foot-long fossil fish to possess a tuna-like body with a unique ‘hook-shaped sail’ on its back. The fish’s new species name, Pentanogmius fritschi, is in honor of local amateur collector Joseph Fritsch.Credit: Photo by Kenshu Shimada, Ph.D.

The fossil fish is a nearly complete skeleton from the Britton Formation of the Eagle Ford Shale in Dallas County. Dr. Shimada’s study suggests thatPentanogmius fritschi was an active fish in open ocean environments that possibly fed on a variety of small animals like squid and other fish.

Besides its scientific significance, the new study is a success story demonstrating the very function of a collection-based museum and collaboration between amateur fossil collectors and scientists. Anthony Fiorillo, Ph.D., a paleontologist and the Perot Museum’s vice president of research and collections and chief curator, took notice of the remarkable preservation of the fossil fish soon after its discovery. He worked with Fritsch and Howe to make the specimen available to the public and to the scientific community during the developmental stage of the Museum.

Fiorillo had worked closely with Howe years earlier when Howe donated a fossil he unearthed in Grapevine, Texas. Dr. Fiorillo and another Perot Museum paleontologist Ronald Tykoski, Ph.D., determined that the fossil remains represented North America’s oldest fossil bird. They named itFlexomornis howei in Howe’s honor. The fossil is currently on view in the Museum’s Rose Hall of Birds.

“We’re very excited by the discovery of this new fossil fish for two reasons. First, it once again illustrates that the Perot Museum of Nature and Science not only inspires but serves as a resource for those in our community curious about the natural world around them,” said Dr. Fiorillo. “Secondly, this find also demonstrates the dynamic nature of scientific investigation within our T. Boone Pickens Life Then & Now Hall.”

The Museum opened in 2012, but it was not until Dr. Shimada’s visit in 2014 that the fish was found to be new to science. His resulting study — entitled “A new species of the Late Cretaceous ‘sail-finned’ bony fish, Pentanogmius(Actinopterygii: Tselfatiiformes), from Texas, USA” — will appear in a forthcoming issue of the international scientific journal Cretaceous Research.

“The really great thing about this fish is that it was found right here in Dallas County,” said Fritsch, who lives in Carrollton. “People are led to believe that fossils are found in exotic locations not accessible to the general public. The reality is North Texas is full of fossil hunting opportunity for anyone willing to go out and enjoy a walk in nature.”

Citation: www.sciencedaily.com/releases/2016/02/160222151640.htm

Key: WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society

Acanthoteuthis: Jurassic Squid Were Speedy Swimmers

February 21st, 2016

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WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society

Three extremely rare fossil specimens of an extinct squidlike animal provide new evidence of the 10-armed creature’s body structure and suggest that it may have been a swift swimmer, a new study finds.

The fossils represent Acanthoteuthis, a genus of squid relatives that lived during the Jurassic period and measured between 9.8 and 15.7 inches (25 and 40 centimeters) long. What makes the specimens so exceptional is their preservation of soft body parts like the animals’ fins and feeding structures, which are usually lost to time. Now, an analysis of the new material reveals never-before-seen organs, offering scientists their first glimpse of features that suggest how Acanthoteuthis may have lived, millions of years ago.

Squid species

Acanthoteuthis is a cephalopod, part of the ocean-dwelling group that includes modern octopus, squid and cuttlefish, with an evolutionary history spanning 500 million years. But even though cephalopods have been around for a long time, unlike many other extinct animals, they don’t leave much of themselves behind in the fossil record. Their soft bodies don’t preserve well, and the isolated bits that do fossilize tell only a partial story of what the living animal might have looked like.

Acanthoteuthis belongs to a group of cephalopods called belemnites, which are particularly abundant in the fossil record — or at least a small part of them is. Belemnites had tough internal shells capped by hard parts called “rostra,” which preserve well, as roughly bullet-shaped fossils. Rostra fossils are plentiful, and marks on them can even reveal traces of where the belemnites’ fins attached to the mantle, the cone-shaped, muscular part of the body that forces water through a siphon for jet-propelled swimming.

So what kept these specimens in such good condition and preserved so much of their bodies? Christian Klug, co-author of the new study and a curator at the Paleontological Institute and Museum at the University of Zurich, said the reason had to do with the site in Solnhofen, Germany, where the fossils were found.

“Solnhofen and its surroundings are world-renowned for exceptionally preserved fossils,” Klug told Live Science in an email. “These fossils were embedded in fine-grained sediments in more-or-less quiet water lagoons between coral reefs. Additionally, microbial mats stabilized the sediments, guaranteeing perfectly flat bedding.” Rapid burial and certain chemical conditions in the soil would also have played a part in the preservation, Klug added.

The discoveries of the well-preserved Acanthoteuthis specimens were certainly very special, and Klug and his colleagues were eager to see what the fossils might reveal. “Since we knew that the material was important, we figured we should get the most out of it,” he said.

Courtesy: Article BY MINDY WEISBERGER, LIVESCIENCE

Eoleptonema apex : Not Fossils but Chert

February 19th, 2016

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A team of scientists including Carnegie’s Dina Bower and Andrew Steele weigh in on whether microstructures found in 3.46 billion-year-old samples of a silica-rich rock called chert found in Western Australia are the planet’s oldest fossils. The purported fossils have been a heated scientific controversy for many years. The team asserts that at least a portion of the microstructures are actually pseudo-fossils. Their findings are published in Astrobiology.

More than two decades ago, microscopic filamentary structures, less than two dozen micrometers in length, found in Australia’s Apex chert formation were declared to be fossils of photosynthetic bacteria from the Archean eon. These alleged microfossils were obviously of great interest to scientists interested in the origins of life on Earth as well as those trying to determine the best way to look for life on other planets.

Different types of imaging show the micro structure that was originally designated as the fossil Eoleptonema apex.

But since then, subsequent research involving Owen Green at Oxford University (who is also a co-author on this study) has called these claims into question, putting forward the idea that the structures are fossil-like mineral formations, but not actually the remains of life. Debate about the authenticity of the Apex chert microfossils has raged over the last several years.

The research team—which also included Marc Fries of the NASA Johnson Space Center and John Lindsay (now deceased) of the Lunar and Planetary Science Institute—analyzed the orientation of the quartz crystals (quartz is a form of silica, which makes up chert) surrounding the alleged microfossils in order to determine whether the crystals and microstructures were both formed as part of the same geological processes.

“Based on our findings, we think that the Apex fossil that was designated as Eoleptonema apex in the originally described samples that we re-studied here was actually formed when a series of quartz grains cracked and was filled in with carbon-rich material to create a sheet-shaped structure within the larger crystal,” Steele explains.

The source of the carbon could have been biological, or abiotic, but this structure itself is not a fossil, the team asserts.

“Studies have shown that 60 percent of the originally described alleged microfossils were found in material that is younger than its host rock, E. apex being one such example. This study further develops a new technique in order to study the indigeneity of the microfossils in the rock and shows without a doubt that this particular example is a pseudo-fossil. The other microstructures in the primary rock (i.e. the oldest part of the rock) should now be analyzed critically in order to prove that similar processes have not been responsible for the formation of those features,” said Bower.

selective predation by Cambrian trilobite Rusophycus

February 18th, 2016

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@WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society

Evidence of predatory activity can be observed in the fossil record in the form of drill holes, repair scars, bite marks, and recognizable skeletal fragments in coprolites and preserved gut tracts. It is less common, however, to find fossil snapshots of predators caught in the act of feeding on their prey. Such interactions are preserved in recurring associations of the ichnogenera Rusophycus and Cruziana, most commonly attributed to trilobites, with burrows of likely vermiform (worm-like) organisms. In this study, we examine the Cambrian (Furongian Epoch, Steptoean Stage) Davis Formation, near Leadwood, southeastern Missouri, USA. In the lower to middle Davis Fm., several silty shale beds are extensively burrowed, from which we report a new occurrence and large number of Rusophycus traces associated with burrows of vermiform organisms. Within these beds, Rusophycus traces intersect vermiform burrows more often than expected by random chance and display a positive correlation in size between paired tracemakers. The median diameter of Rusophycus-associated vermiform burrows is significantly smaller than that of the non-intersected burrows. These results suggest that the paired traces record size selective predatory behavior. Moreover, low angle predator–prey trace intersections, though few in number, occurred more frequently than expected by random chance, supporting previous hypotheses that low angle attacks are preferred as they may improve prey handling success rates.

The Cambrian Period, which occurred between 541 million and 485 million years ago, is an important point in evolutionary history where most of the major groups of animals first appear in the fossil record. Often called the “Cambrian explosion,” fossils from this time provide glimpses into evolutionary history as the world’s ecosystems were rapidly diversifying. Most fossils preserve the physical remains of organisms and their structure; however, geologists and paleobiologists at the University of Missouri recently collaborated to study fossils that reveal the behaviors of predators preserved as traces in ancient sediments. Thus, fossils from southeast Missouri are helping scientists unlock clues about the behaviors of these predators and their interactions with their prey. Evidence shows that these ancient organisms were behaviorally sophisticated, tailoring their attacks for effectiveness.

A trilobite detects a lumpy worm burrow by sight and perhaps smell, then burrows down and grasps its prey with its many legs. Credit: Stacy Turpin Cheavens of the Department of Orthopaedic Surgery, University of Missouri

“The Saint Francois Mountains in southeastern Missouri have been the focus of geological research for decades and were once islands in the Cambrian ocean,” said Kevin Shelton, professor of geological sciences in the MU College of Arts and Science. “I’ve worked as a geologist studying ore deposits in the area for more than 30 years. In that time, I’ve run across thousands of fossilized trilobite burrows. It is rare that we get to study the activities of 500 million-year-old organisms, yet the fossils in this locality are helping us determine how these organisms behaved.”

The field area near the mountains is home to an abundance of trilobite trace and body fossils. James Schiffbauer and John Huntley, both assistant professors of geological sciences in the MU College of Arts and Science, worked with Shelton and Tara Selly, a graduate student in Schiffbauer’s research group, to collect slabs of rocks from the site. Selly, then analyzed them in the lab at MU.

Using sophisticated three-dimensional laser scanning and digital photograph analyses, sections of the rocks revealed burrows or trails left behind by trilobites and their prey — often worm-like creatures — in ocean sediments. To the scientists, these intersecting trails show how the predators caught their prey. Additionally, previous studies by former MU geology professor, James Stitt, revealed that the trilobites had very large eyes, so the researchers were looking for clues as to how their anatomy played into their feeding habits.

Tracks from the site showed that the predators attacked from above, moving alongside to use their many legs for more effective grappling of their prey. Further, predators preferentially selected smaller prey, indicating that they attacked their food rather than randomly bumping into it.

“Predation, or the action of attacking one’s prey, is a significant factor in evolution; this discovery is extremely important in the study of how organisms evolved in the Cambrian Period,” Schiffbauer said. “In this study, we provide evidence that these trilobites were likely visual predators, displaying selectivity in seeking and hunting their food.”

“Because we had an abundance of samples from the site, we were able to conduct more rigorous statistical analyses” Huntley said. “Our findings are important not only because of the large sample size, but because these early arthropods displayed such sophisticated predatory behavior.”

Courtesy:University of Missouri-Columbia. “500 million-year-old fossils show how extinct organisms attacked their prey: Missouri-based scientists unlock clues to predatory behavior, a significant factor in evolution.” ScienceDaily.

Strychnos : A fossil flower from Tertiary amber

February 16th, 2016

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Researchers today announced in the journal Nature Plants the discovery of the first-ever fossil specimens of an “asterid” — a family of flowering plants that gave us everything from the potato to tomatoes, tobacco, petunias and our morning cup of coffee.

But these two 20-30 million-year-old fossil flowers, found perfectly preserved in a piece of amber, came from the dark side of the asterid family — they belong to the genus Strychnos, which ultimately gave rise to some of the world’s most famous poisons, including strychnine and curare.

Strychnos electri sp. nov. holotype Sd-9-47A in Dominican amber.

Poisons that would later find their way into blow-gun weapons, rat control, Sherlock Holmes stories and the movie “Psycho” appear to have had some of their ancestral and biological roots in the prehistoric jungles of what’s now the Dominican Republic, researchers say.

“The specimens are beautiful, perfectly preserved fossil flowers, which at one point in time were borne by plants that lived in a steamy tropical forest with both large and small trees, climbing vines, palms, grasses and other vegetation,” said George Poinar, Jr., a courtesy professor in the College of Science at Oregon State University, and one of the world’s experts on plant and animal life forms preserved in amber.

“Specimens such as this are what give us insights into the ecology of ecosystems in the distant past,” Poinar said. “It shows that the asterids, which later gave humans all types of foods and other products, were already evolving many millions of years ago.”

Strychnos electri sp. nov. in Dominican amber.

Asterids, the researchers noted in this study, are among Earth’s most important and diverse plants, with 10 orders, 98 families, and about 80,000 species. They represent about one-third of all the Earth’s diversity of angiosperms, or flowering plants.

And one ancient genus, which has now been shown to be inherently toxic, existed for millions of years before humans appeared on the planet.

“Species of the genus Strychnos are almost all toxic in some way,” Poinar said. “Each plant has its own alkaloids with varying effects. Some are more toxic than others, and it may be that they were successful because their poisons offered some defense against herbivores.

“Today some of these toxins have been shown to possess useful and even medicinal properties.”

As natural poisons that humans came to understand and use, two extracts from plants in the Strychnos genus ultimately became famous — strychnine and curare.

Strychnine had practical uses for decades as a pesticide, and was often the deadly component of rat poison. But it also captured the imagination of writers, and was used by Norman Bates in the movie “Psycho” to kill his mother and her male companion. In small doses, it can increase mental and muscular activity.

Curare has an even stranger history. Sir Walter Raleigh may have first encountered it in 1596 when he observed poison arrows in South America, where natives also developed the poison in blow-gun darts to paralyze hunted prey. Curare was featured as the murder weapon in one Sherlock Holmes novel, and in lower doses it has been used as a muscle relaxant in surgery.

There are now about 200 species of Strychnos plants around the world, in forms ranging from shrubs to trees and woody climbing vines, mostly in the tropics. They are still being studied for medicinal properties, such as for the treatment of parasitic worm infections and even as drugs to treat malaria.

The discovery of these two fossil flowers, researchers said, suggests that many other related plant families could have evolved in the Late Cretaceous in tropical forests. Their fossil remains, however, still await discovery.

The co-author of this study, Lena Struwe, is an expert on plants in the strychnine family, Loganaceae, and is a plant biologist at Rutgers University.

Courtesy: Oregon State University. “Ancient flowering plant was beautiful, but probably poisonous.” ScienceDaily.

Key:WFS,Riffin T Sajeev,Russel T Sajeev,World Fossil Society