Claire Ainsworth, Author at 快猫短视频 Science news and science articles from 快猫短视频 Fri, 06 Feb 2026 16:07:12 +0000 en-US hourly 1 https://wordpress.org/?v=7.0.1 242057827 The secret signals our organs send to repair tissues and slow ageing /article/2513188-the-secret-signals-our-organs-send-to-repair-tissues-and-slow-ageing/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Mon, 02 Feb 2026 16:00:09 +0000 /?post_type=article&p=2513188 2513188 Inside the revolutionary idea that we can negotiate with cancer /article/2492582-inside-the-revolutionary-idea-that-we-can-negotiate-with-cancer/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Tue, 26 Aug 2025 15:00:01 +0000 /?post_type=article&p=2492582 2492582 Our cells can divide in a completely unexpected way /article/2478789-our-cells-can-divide-in-a-completely-unexpected-way/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Thu, 01 May 2025 18:00:42 +0000 /?post_type=article&p=2478789
The division of human cells may not exactly align with what鈥檚 written in textbooks
Iokanan VFX Studios/Shutterstock

快猫短视频s have discovered a kind of division that allows cells to use the information encoded in their shape to direct what kinds of cells their offspring become. This could help us develop ways of engineering tissues and deepen our understanding of how cancers spread.

Until now, scientists thought that most cells in the body become round as they prepare to divide in two. This makes it easier for them to distribute their contents equally between their 鈥渄aughter鈥 cells, resulting in two cells of the same type.

An exception to this is stem cells, which undergo an unequal, or asymmetric, cell division, which produces cells of two different types.

But at the University of Manchester, UK, and his colleagues noticed that non-stem cells in the developing blood vessels of zebrafish embryos were also dividing asymmetrically. These cells, known as endothelial cells, were migrating to form new blood vessel branches and divided without rounding to create two different types.

When the team manipulated the shape of human endothelial cells in a lab dish, it confirmed that their shape before division predicted how symmetric that division was going to be. Longer, thinner cells were the most likely to divide asymmetrically, which suggests that cells can fine-tune the nature of their divisions depending on the shape they take between them.

It means cells don鈥檛 lose information about their structure and behaviour as they would if they underwent rounding, says Herbert. 鈥淰ery frequently, they actually retain their shape, and that means they can transfer that kind of memory.鈥

This also means that cells don鈥檛 have to stop what they are doing to divide, but can migrate, divide and generate different cell types all at once. This lets them respond quickly to the dynamic demands of development, such as the need to supply an expanding tissue with blood vessels or nerves.

The discovery could have applications for growing replacement tissues in the lab, where the ability to grow blood vessels is a key limitation. 鈥淥ur work is showing is that there鈥檚 a really specific environment that鈥檚 needed to give these cells the kind of shape and behaviour that they need to generate functional blood vessels,鈥 says team member , also at the University of Manchester. Manipulating cell shapes could offer a new way to generate certain cell types, she says. Cancer, meanwhile, spreads by generating clusters of migrating cells, so the new findings could provide further insight into how they do this.

It is a nice example of how organisms can tweak mechanisms like cell rounding to do different things, such as the multitasking needed to sculpt developing tissues, says of the MRC Laboratory of Molecular Biology in Cambridge, UK. 鈥淚t鈥檚 a clever way to keep the information you need while still growing the network by making more cells.鈥

Journal reference:

Science

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The scientists on a mission to catch farts for the good of our health /article/2459271-the-scientists-on-a-mission-to-catch-farts-for-the-good-of-our-health/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Wed, 11 Dec 2024 18:00:00 +0000 http://mg26435212.200 2459271 Weird microbes could help rewrite the origin of multicellular life /article/2453548-weird-microbes-could-help-rewrite-the-origin-of-multicellular-life/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Mon, 28 Oct 2024 11:30:00 +0000 /?post_type=article&p=2453548 2453548 Two injured comb jellies can merge to form one individual /article/2450693-two-injured-comb-jellies-can-merge-to-form-one-individual/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Mon, 07 Oct 2024 15:00:39 +0000 /?post_type=article&p=2450693 Shimmering sea creatures called comb jellies have an astonishing ability: if injured, two can merge into one, without showing the kind of tissue rejection reaction seen in other animals. What鈥檚 more, the two animals鈥 nervous systems integrate together and their digestive tracts fuse to share food. The discovery could help scientists explore how immune systems evolved the ability to distinguish an organism鈥檚 own tissues from those of another, and develop insights into the evolution of nervous systems. Despite their name, comb jellies, or ctenophores, aren鈥檛 jellyfish 鈥 their bodies are fundamentally different. They are the earliest creatures still living today to branch from the common ancestor of all animals, and their unusual biology makes them a fascinating subject for scientists exploring the early evolution of animals. For example, they have a unique nervous system consisting of nerve cells that merge together to form a continuous net-like structure, rather than having individual nerve cells like other animals. at the University of Exeter, UK, was studying the iridescent combs of beating hairs on a ctenophore species known as Mnemiopsis leidyi when he noticed an individual that was unusually large. It had two rear ends and two sensory organs known as apical organs, as if two individuals had somehow joined together. To test this idea, he and his colleagues cut off parts of individuals that had been collected from different locations on different days 鈥 and were therefore unrelated to each other 鈥 and placed them together in pairs. In nine out of ten cases, the two bodies fused seamlessly into one in the space of a few hours. 鈥淚 was very surprised,鈥 says Jokura. Unlike the norm in most other animals, one body didn鈥檛 reject the foreign tissue of the other, suggesting that the ctenophore immune system lacks the ability to distinguish between 鈥渟elf鈥 and 鈥渘on-self鈥, known as allorecognition. When the team gently prodded one lobe, the whole fused body reacted as one, contracting its muscles in a synchronised way, suggesting that the two nervous systems had also fully merged. The digestive tract had fused too: when the team fed just one of the mouths, the food made its way into the joined tract. 鈥淚t鈥檚 a fascinating first finding,鈥 says at the University of Bergen in Norway. 鈥淚t opens many new questions you can study.鈥 These could include when animals evolved allorecognition and how nerve nets form and process information. These aren鈥檛 the only questions ctenophores could help answer. Burkhardt and his team that when starved or injured, Mnemiopsis leidyi individuals can reverse their development, reverting from an adult stage to a larval-like stage, and then back again. Until now, the only known examples of animals with similar abilities have been a handful of jellyfish species such as the so-called immortal jellyfish (Turritopsis dohrnii) and a species of tapeworm. The finding that ctenophores can also do this suggests that it might have been a feature of the last common ancestor of all animals, and may be more widespread among animals than previously thought. 鈥淲hat I personally find very fascinating [is] it could mean that the very first animals were more plastic, were more able to adapt,鈥 says Burkhardt. These enigmatic, shimmering animals are shaping up as keys to understanding a swathe of fundamental biological processes, some of which may even relate to human health, such as tissue rejection, regeneration and ageing. 鈥淚t鈥檚 definitely a very valuable model to tackle some of these big-picture questions,鈥 says Burkhardt.
Journal reference:

Current Biology

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Axolotls seem to pause their biological clocks and stop ageing /article/2449128-axolotls-seem-to-pause-their-biological-clocks-and-stop-ageing/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Tue, 24 Sep 2024 15:00:07 +0000 /?post_type=article&p=2449128 2449128 Colonies of single-celled creatures could explain how embryos evolved /article/2426811-colonies-of-single-celled-creatures-could-explain-how-embryos-evolved/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Wed, 17 Apr 2024 05:00:46 +0000 /?post_type=article&p=2426811 2426811 Blind cave fish offers lessons in how to survive starvation /article/2421466-blind-cave-fish-offers-lessons-in-how-to-survive-starvation/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Mon, 11 Mar 2024 15:00:40 +0000 /?post_type=article&p=2421466 2421466 The development of embryos may be less shaped by genes than we thought /article/2409123-the-development-of-embryos-may-be-less-shaped-by-genes-than-we-thought/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Wed, 20 Dec 2023 18:00:43 +0000 /?post_type=article&p=2409123 2409123