Microbiome & Memory - Yak Myelin - Striped Mouse Dads - Amazon Mollies

[Breedlove, S]

https://www.science.org/content/article/tour-de-force-mouse-study-shows-gut-microbe-can-promote-memory-loss

‘Tour de force’ mouse study shows a gut microbe can promote memory loss

 By Catherine Offord 

Scientists have plenty of ideas about why aging impairs memory. Reductions in blood flow in the brain, shrinking brain volume, and malfunctioning neural repair systems have all been blamed. Now, new research in mice points to another possible culprit: microbes in the gut.

In a study published today in Nature, scientists show how a bacterium that is particularly common in older animals can drive memory loss. This microbe makes compounds that impair signaling along neurons connecting the gut with the brain, dampening activity in brain regions associated with learning and memory, the team found.

“This is a tour de force,” says Haijiang Cai, a neuroscientist at the University of Arizona who studies gut-brain communication and was not involved in the work. “They define the pathway all the way from aging and bacteria … to cognitive function—it’s really impressive.” However, he and others emphasize it remains to be seen whether a similar mechanism exists in humans—and if so, how important it is compared with other drivers of cognitive decline.

Research on the so-called gut-brain axis has exploded in recent decades. Multiple studies have identified differences in microbiome composition between healthy people and those with cognitive disorders such as Alzheimer’s disease. This kind of research can’t establish cause and effect, though, and the literature is rife with conflicting results.

Some groups have used animal experiments to probe the microbe-memory link. In the new study, Stanford University researchers Christoph Thaiss and Maayan Levy tinkered with the microbiomes of young mice—either by housing them with older animals or feeding them these animals’ poop—and then gave them memory tests. For example, one such test rates animals higher if they spend more time exploring new objects than those they’ve seen before.

© 2026 American Association for the Advancement of Science. 
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https://www.sciencenews.org/article/yaks-brain-diseases-ms-genetic-mutation

 Yaks may hint at a way to treat brain diseases like MS

By Simon Makin

A brain repair kit that helps yaks and other animals naturally cope with low oxygen levels at high altitudes may point to a new way to treat brain diseases such as multiple sclerosis. In mice with brain damage that mimics MS, the kit’s tools lessened signs of damage in young mice exposed to low oxygen and improved symptoms of MS in adult mice, researchers report March 13 in Neuron.

Previous research found that animals living on the Tibetan Plateau, such as yaks and antelopes, carry a mutation in a gene called Retsat. Their lowland counterparts lack the mutation, leading scientists to suspect that it helps protect the brain in low-oxygen environments.

“People usually think it’s because of better lung capability, but I wondered whether evolutionary adaptation changes the brain,” says Liang Zhang, a neuroscientist at Shanghai Jiao Tong University. In particular, he was intrigued that these animals have normal white matter in their brains.

White matter makes up about half the brain; it consists of bundles of nerve fibers that allow different brain regions to communicate. This neural wiring is wrapped in myelin, a fatty substance that ensures nerve fibers conduct signals efficiently. In MS, the immune system attacks myelin, leading to neurological symptoms and problems with balance and coordination.

Myelin production requires a lot of energy, which the brain gets from oxygen. Low oxygen levels, known as hypoxia, can therefore disrupt myelination. During gestation, such disruption can lead to conditions such as cerebral palsy in newborns.

© Society for Science & the Public 2000–2026.
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https://www.sciencenews.org/article/african-striped-mice-male-caregiving

Why African striped mice can be the best of dads — or the worst

By Viviane Callier

The difference between a doting dad and a deadbeat one may come down to a molecular switch in the brain — at least in African striped mice.

Boosting activity of a particular gene in part of the brain known for regulating maternal care turned nurturing males into standoffish ones and even, in some cases, into mouse pup killers, researchers report February 18 in Nature. The findings reveal how social context can alter gene activity in the brain and thereby shape male caregiving.

Male caregiving is prevalent in fish and amphibians, suggesting that it is a very ancient behavior in vertebrates. Among mammals, however, fewer than 5 percent of species have fathers that stick around to raise their young. Male African striped mice (Rhabdomys pumilio) are one of the exceptions to the rule, though they vary a lot in their nurturing tendencies, making them an ideal species in which to study the factors that influence this behavior.

Some look after the young and groom them; others ignore the pups or even attack them. The same male could become aggressive or doting.

To understand that behavior, comparative neurobiologist Forrest Rogers and his colleagues observed the mice’s social environment. In laboratory settings, group-housed males tended to be aggressive toward mouse pups when introduced to them. But surprisingly, when these males were moved to be housed alone, they became very paternal.

“I thought clearly something must be wrong, because all the work we know of in mice and rats is that if you socially isolate them, they become very anxious and often not the most caring of individuals,” says Rogers, of Princeton University. But the lone African striped male mice didn’t seem anxious at all.

© Society for Science & the Public 2000–2026.
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https://www.science.org/content/article/genetic-trick-helps-all-female-fish-species-escape-evolutionary-doom

 A genetic trick helps this all-female fish species escape evolutionary doom

 By Phie Jacobs 

Talk about an odd couple. At least 100,000 years ago, a female Atlantic molly (Poecilia mexicana) living in the fresh waters near what is now Tampico, Mexico, mated with a male sailfin molly (Poecilia latipinna). The offspring of this cross-species coupling ought to have been sterile, like a mule. But this particular hybrid went on to birth a brood of daughters—all of which were genetic clones of their mother.

Scientists have long assumed this reproductive strategy of birthing clones to be an evolutionary dead end among vertebrate animals, with offspring inevitably succumbing to genomic degradation over time. But the Amazon molly (Poecilia formosa), named for the fierce female warriors of Greek mythology, has kept on defying the odds. According to research published today in Nature, it all comes down to a quirk of genetics that helps reverse harmful mutations.

“This is a very cool story,” says University of Oklahoma biologist Ingo Schlupp, who provided the study authors with samples but otherwise wasn’t involved in the new work. Researchers who study asexual animals, he explains, have been “scratching our heads” trying to figure out how some species manage to avoid what evolutionary theory predicts to be certain doom.

Although asexual reproduction is common in bacteria and plants, it only rarely occurs in vertebrate animals. Often, these “virgin births” involve a process called parthenogenesis, in which an embryo develops from an unfertilized egg cell—no contribution from the other sex required. The Amazon molly, however, is far from celibate. These fish still mate with males from closely related species because they need sperm to kick-start the development of their embryos. But none of the male’s genetic material gets passed on to the next generation.


© 2026 American Association for the Advancement of Science.
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