A synthetic biologist at Nagoya City University, Nagoya, Japan. Developing tools that contribute to an arbitrary and dynamic design of intracellular space.
音楽で「��クッ」とする瞬間、脳では何が起きているのか 期待と快感で異なるドーパミン放出を実証
Valorie Salimpoorらの@NatureNeuro #論文
Anatomically distinct dopamine release during anticipation and experience of peak emotion to music
https://t.co/ZwMLCalaWA
https://t.co/oXC7zacncN
Scientists present a workflow to study the interfacial behaviors of biomolecular condensates at the phase boundary, and use it to identify unexpected features such as bending rigidity and critical capillary waves.
Read more: https://t.co/tD1uHXAnKB
As living fossils, lampreys, such as this Far Eastern brook, provide an irreplaceable model for reconstructing the ancestral vertebrate brain.
The first single-cell three-dimensional lamprey brain atlas reveals that the vertebrate common ancestor (~500 million years ago) already had a highly regionalized brain, and subsequent neuronal specialization likely drove vertebrate brain diversification.
Learn more this week in Science: https://t.co/a9LAa6GKBY
Wenjin Cai's amazing discovery that symbiotic E. coli strains generated by experimental evolution outcompete co-infecting original symbiotic bacteria in the host insect and behave as cheater-like microbial associates is just published in mBio!
https://t.co/2qB62SgfGZ
Please RP!
Excited to share our new preprint:
“Single-cell chromatin tracing reveals multimodal molecular programs during memory formation”
We built a single-cell multiomic atlas of aversive learning and used it to trace memory-linked molecular programs.
https://t.co/asjEYsLKd0
While modern amphibians start life in a larval stage, a new fossil study in Science suggests these tadpole-like stages were not present in earlier times.
Learn more: https://t.co/yYkwa1Jl4F
Thrilled to share our paper in Small! We created dynamic DNA networks synthesized and assembled by two classes of biomolecular machines. Grateful to co-lead this work with @activematterKU. Congratulations Afroze, @RJANano & all contributors! https://t.co/RBCOK3Kv6f
The Venus flytrap is renowned for its ultrafast snap traps, which can capture insects in a fraction of a second.
New research reveals that trap closure is triggered by a rapid softening of the epidermal cell walls, uncovering the physical mechanism behind this remarkable movement.
Learn more this week in Science: https://t.co/35uDGps8Qe
Picture reaching for something on a high shelf and coming up short. You don’t give up; instead, you find a stool, carry it over, and climb up. Buried in that action is something remarkable: You held the goal in your mind, identified what you needed, and executed a plan. No training required.
A study suggests bumble bees can do the same—the first demonstration of this kind of goal-directed problem-solving in an insect.
Learn more: https://t.co/srV4TqUTsp