Microbiology!

Paleontologists Discover 52-Million-Year-Old Bat

The fossil represents the earliest-known species of the flying mammal

The fossil record is biased against bats. The flying mammals are small, making their fossilized remains very hard to find. And their light skeletons—ideal for flying around—mean it takes special circumstances for their bodies to be preserved. And yet, against these odds, paleontologists recently uncovered the exceptionally complete skeleton of what now stands as the earliest known bat.

To date, the most complete early bat fossils have come from an area paleontologists call Fossil Lake in Wyoming. The rock layers are world-famous for containing beautifully preserved fish, birds, mammals and other organisms that lived in the area about 52 million years ago. Among the stunning fossils recovered from these rocks, Naturalis Biodiversity Center paleontologist Tim Rietbergen and colleagues report Wednesday in PLOS One, are fossils of a new bat species the researchers have named Icaronycteris gunnelli. By comparing this new species with other early bats, paleontologists are beginning to develop a deeper understanding of how bats spread around the world in that period.

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[Hotwheels gen. nov., a new ground spider genus (Araneae, Gnaphosidae) from southwest China]

The generic name refers to Hot Wheels, a collectible die-cast toy car made by Mattel, as the long, coiled embolus of this new genus resembles a Hot Wheels track; neuter in gender.

Liu & Zhang, 2024

I’ve done it! I’ve designed such an incredibly cursed molecule that MolView doesn’t even assign it a systematic IUPAC name. Behold:

The image doesn’t even show up right in the post editor lol. This thing would have such unbelievably ridiculous angle strain that if a molecule of it was ever assembled, it would almost certainly degrade instantly. Possibly violently.

close my eyes and make a wish i wanna live together in a petri dish!!!

nature.com

Rosalind Franklin was so much more than the ‘wronged heroine’ of DNA

One hundred years after her birth, it’s time to reassess the legacy of a pioneering chemist and X-ray crystallographer.

At the centre of Rosalind Franklin’s tombstone in London’s Willesden Jewish Cemetery is the word “scientist”. This is followed by the inscription, “Her research and discoveries on viruses remain of lasting benefit to mankind.” As one of the twentieth century’s pre-eminent scientists, Franklin’s work has benefited all of humanity. The one-hundredth anniversary of her birth this month is prompting much reflection on her career and research contributions, not least Franklin’s catalytic role in unravelling the structure of DNA.

. . .

But Franklin’s remarkable work on DNA amounts to a fraction of her record and legacy. She was a tireless investigator of nature’s secrets, and worked across biology, chemistry and physics, with a focus on research that mattered to society. She made important advances in the science of coal and carbon, and she became an expert in the study of viruses that cause plant and human diseases. In essence, it is because of Franklin, her collaborators and successors, that today’s researchers are able to use tools such as DNA sequencing and X-ray crystallography to investigate viruses such as SARS-CoV-2.

. . .

Franklin was an inveterate traveller on the global conference circuit and a collaborator with international partners. She won a rare grant (with Klug) from the US National Institutes of Health. She was a global connector in the booming early days of research into virus structures: an expert in pathogenic viruses who had gained an international reputation and cared deeply about putting her research to use. It is a travesty that Franklin is mostly remembered for not receiving full credit for her contributions to the discovery of DNA’s structure. That part of Franklin’s life story must never be forgotten, but she was so much more than the “wronged heroine”, and it’s time to recognize her for the full breadth and depth of her research career.

What are Phytoplankton and Why Are They Important?

Breathe deep… and thank phytoplankton.

Why? Like plants on land, these microscopic creatures capture energy from the sun and carbon from the atmosphere to produce oxygen.

Phytoplankton are microscopic organisms that live in watery environments, both salty and fresh. Though tiny, these creatures are the foundation of the aquatic food chain. They not only sustain healthy aquatic ecosystems, they also provide important clues on climate change.

Let’s explore what these creatures are and why they are important for NASA research.

Phytoplankton are diverse

Phytoplankton are an extremely diversified group of organisms, varying from photosynthesizing bacteria, e.g. cyanobacteria, to diatoms, to chalk-coated coccolithophores. Studying this incredibly diverse group is key to understanding the health - and future - of our ocean and life on earth.

Their growth depends on the availability of carbon dioxide, sunlight and nutrients. Like land plants, these creatures require nutrients such as nitrate, phosphate, silicate, and calcium at various levels. When conditions are right, populations can grow explosively, a phenomenon known as a bloom.

Phytoplankton blooms in the South Pacific Ocean with sediment re-suspended from the ocean floor by waves and tides along much of the New Zealand coastline.

Phytoplankton are Foundational

Phytoplankton are the foundation of the aquatic food web, feeding everything from microscopic, animal-like zooplankton to multi-ton whales. Certain species of phytoplankton produce powerful biotoxins that can kill marine life and people who eat contaminated seafood.

Phytoplankton are Part of the Carbon Cycle

Phytoplankton play an important part in the flow of carbon dioxide from the atmosphere into the ocean. Carbon dioxide is consumed during photosynthesis, with carbon being incorporated in the phytoplankton, and as phytoplankton sink a portion of that carbon makes its way into the deep ocean (far away from the atmosphere).

Changes in the growth of phytoplankton may affect atmospheric carbon dioxide concentrations, which impact climate and global surface temperatures. NASA field campaigns like EXPORTS are helping to understand the ocean's impact in terms of storing carbon dioxide.

Phytoplankton are Key to Understanding a Changing Ocean

NASA studies phytoplankton in different ways with satellites, instruments, and ships. Upcoming missions like Plankton, Aerosol, Cloud, ocean Ecosystem (PACE) - set to launch Jan. 2024 - will reveal interactions between the ocean and atmosphere. This includes how they exchange carbon dioxide and how atmospheric aerosols might fuel phytoplankton growth in the ocean.

Information collected by PACE, especially about changes in plankton populations, will be available to researchers all over the world. See how this data will be used.

The Ocean Color Instrument (OCI) is integrated onto the PACE spacecraft in the cleanroom at Goddard Space Flight Center. Credit: NASA

Biology Keychains - Diatoms and Soil Bacteria!

Designed by me, available now on my Etsy!

Punctelia reddenda

This gorgeous foliose lichen grows in rosettes up to 6 cm in diameter. The upper surface is gray-green to yellow-green with white, punctiform (point or dot like) pseudocyphella which turn into soralia which produce granular or nodular soredia. The lower surface is black toward the center and lightens to brown near the rounded margins of the overlapping lobes. P. reddenda grows on mossy tree trunks and rock in Africa, Macaronesia, North and South America, and Europe.

images: source | source

info: source | source | source

[March, 2023] culture stains & snow days

Ceratiomyxa fruticulosa var. poroides

by fungispot