Latest Articles for Synthetic Biology

This research reveals how amino acid changes affect protein fitness and function.

This research reveals how lipid composition impacts cell growth and membrane function.

This study reveals new insights into how bacteria regulate gene expression using σ-factors.

Researchers create synthetic cells using innovative methods for advanced molecular interactions.

RNAinformer revolutionizes RNA design by enabling accurate sequence predictions for complex structures.

This article examines how bacteria use cAMP for environmental response and adaptation.

Research shows how reduced genomes can improve bacterial efficiency and productivity.

This research explores new methods for creating synthetic gene circuits using CRISPR.

Research explores engineering ferredoxins to control electron transfer in biological systems.

A new framework mimicking biological learning using chemical reactions.

A study shows how AI improves protein yield in cell-free systems.

This article explores the role and behavior of biomolecular condensates in cells.

Research shows how temporary gene changes can lead to lasting effects in bacteria.

Cell-free biosensors promise affordable solutions for environmental and health monitoring.

Researchers are optimizing gene circuits for real-world applications in medicine and environmental cleanup.

Exploring how tiny particles form complex structures without guidance.

Scientists use light to control starfish egg cells' shapes during reproduction.

Scientists develop efficient methods for creating monoterpenoids through engineered yeast and innovative biosensors.

Scientists utilize budding yeast for innovative genetic studies via the PIPO method.

Exploring how proteins collaborate for vital biological functions.

Scientists design and test genetic circuits in living cells for various applications.

New phage-based tools improve communication in engineered biological systems.

Discover how bacteria swim using flagella and the role of FliC.

XNAs offer new possibilities in genetic research and biotechnology.

PLAID simplifies protein design, merging sequence and structure for targeted applications.

Scientists are reshaping yeast genomes to unlock new capabilities.

Scientists unveil a more accurate genome for C. elegans, enhancing biological research.

Synthetic genotypes offer a safer, cost-effective way to study genetics.

New methods reveal insights into how cells develop and change over time.

EnzymeCAGE predicts enzyme functions, bridging gaps in biochemistry knowledge.

Study reveals how essential genes influence growth and evolution in bacteria.