ON
← Back to feed
Bacterial protein reveals a hidden rule for controlling calcium
United Kingdom🔬 Science17 hr. ago

Bacterial protein reveals a hidden rule for controlling calcium

Researchers discovered that a bacterial membrane protein, BsYetJ, uses two distinct 'clasps' to regulate calcium flow based on acidity levels. Published in the Proceedings of the National Academy of Sciences, the study explains how protons alter the structure of these clasps, influencing both the frequency and efficiency of calcium passage through the protein. The findings highlight the role of electrostatic interactions in cellular signaling and could have implications for understanding calcium regulation in human cells. The research used artificial lipid membranes and targeted amino acid modifications to observe the protein's behavior under varying pH conditions.

How each side covered it

The same event, grouped by the political lean of the outlets covering it.

How each side covered it

Support independent, bias-aware news and unlock the social pulse, community voting, and your personalized For You feed.

Become a Supporter

Covered around the world

The same event as reported in other countries.

Covered around the world

Support independent, bias-aware news and unlock the social pulse, community voting, and your personalized For You feed.

Become a Supporter

Claims check

Key factual claims, and how many sources assert vs dispute each.

Claims check

Support independent, bias-aware news and unlock the social pulse, community voting, and your personalized For You feed.

Become a Supporter

Go to the primary sources (2)

The official sources this coverage is built on. Read them directly to bypass framing.

1 reports

Phys.org logoPhys.orgIndependentCenter17 hr. ago
Bacterial protein reveals a hidden rule for controlling calcium

Researchers discovered that a bacterial membrane protein, BsYetJ, uses two distinct 'clasps' to regulate calcium flow based on acidity levels. Published in the Proceedings of the National Academy of Sciences, the study explains how protons alter the structure of these clasps, influencing both the frequency and efficiency of calcium passage through the protein. The findings highlight the role of electrostatic interactions in cellular signaling and could have implications for understanding calcium regulation in human cells. The research used artificial lipid membranes and targeted amino acid modifications to observe the protein's behavior under varying pH conditions.

Bias read (Center): This article presents scientific research without political commentary or advocacy. The focus is on biological mechanisms and experimental methodology, making it apolitical in nature.

Keep the news honest.

ObjectiveNews is reader-funded and ad-free — we show you the bias instead of hiding it. Support independent journalism for €5/month.

Become a Supporter

Related stories