Processes occurring within each protocell in the population at a single discrete time step. Continuous arrows show polymers being produced, segmented arrows show peptide catalysis of CO2 fixation and templated polymerization, and dotted arrows indicate RNA acting as templates for copying and translation. CO2 fixation (or monomer addition in the heterotrophic model) and polymer decay are sources of nucleotide and amino acid monomers, while monomers are consumed by polymerization, copying, and translation. Protocells grow as a result of CO2 fixation (or monomer addition) producing membrane fatty acids and divide when they reach a size threshold. Protocell division is followed by random loss of a protocell from the population (similar to a Moran process). The model tracks a population of protocells evolving under these dynamics. Sequences shown in the diagram are illustrative, and the model only keeps track of hydrophobicity and length of sequences, and not sequence order.

What selective forces first enabled protocells to evolve functional coding sequences? @andrewpom.bsky.social &co show that genetic #heredity could only originate once #protocells achieved sufficient metabolic capacity, so growth had to precede information @plosbiology.org 🧪 plos.io/3Py9uFl

Processes occurring within each protocell in the population at a single discrete time step. Continuous arrows show polymers being produced, segmented arrows show peptide catalysis of CO2 fixation and templated polymerization, and dotted arrows indicate RNA acting as templates for copying and translation. CO2 fixation (or monomer addition in the heterotrophic model) and polymer decay are sources of nucleotide and amino acid monomers, while monomers are consumed by polymerization, copying, and translation. Protocells grow as a result of CO2 fixation (or monomer addition) producing membrane fatty acids and divide when they reach a size threshold. Protocell division is followed by random loss of a protocell from the population (similar to a Moran process). The model tracks a population of protocells evolving under these dynamics. Sequences shown in the diagram are illustrative, and the model only keeps track of hydrophobicity and length of sequences, and not sequence order.

What selective forces first enabled protocells to evolve functional coding sequences? @andrewpom.bsky.social &co show that genetic #heredity could only originate once #protocells achieved sufficient metabolic capacity, so growth had to precede information @plosbiology.org 🧪 plos.io/3Py9uFl

From light to life-like protocells - Nature Synthesis Light-driven chemical reactivity enables a synthetic system to give rise to protocells with dynamic, life-like behaviour.

New paper! In my #Nature #Synthesis News & Views, I discuss how light-driven #chemistry enables dynamic life-like #protocells, highlighting the outstanding work of Lin and co-workers
#SyntheticBiology #SyntheticCells @imperiallifesci.bsky.social @natsynth.nature.com

www.nature.com/articles/s44...

NASA reveals that vesicles, akin to cell-like compartments, may naturally form in Titan's lakes, highlighting potential chemical evolution on Saturn's moon. 🌌🌑 Link: https://tinyurl.com/yvswd6bn #Astrobiology #SpaceExploration #Protocells

Cytomimetic calcification in chemically self-regulated prototissues - Nature Communications Protocell mimetics capable of orchestrated and adaptive functions are of interest. Here, the authors report on cytomimetic models of bone tissue calcification and decalcification, integrating enzyme-c...

#TuesdayReads:
Check out the latest from the Stevens Group—prototissues built from enzyme-loaded protocells mimic bone-like behaviour, enabling self-regulated calcification and structural remodelling.
🔗 www.nature.com/articles/s41...

#SyntheticBiology #TissueEngineering #Biomaterials #Protocells

🧪 Building Life in the Lab
To create synthetic life, we must understand hardware (chemical substrates) and software (information processing).
Inspired by ideas like Assembly Theory (Lee Cronin & Sara Walker).
#SyntheticBiology #Protocells

How did the first cells form on Earth? Scientists think they finally figured it out About 4 billion years ago, Earth began to show signs of the conditions that allowed the first cells to take hold and populate the planet.

How did the first cells form on Earth? Scientists think they finally figured it out: About 4 billion years ago, Earth began to show signs of the conditions that allowed the first cells to take hold and populate the planet.

#OriginOfLife #Protocells #Phospholipids #EarlyEarthChemistry #CellMembranes

Construction of complex bacteriogenic protocells from living material assembly - Nature Protocols This protocol describes how to prepare membrane-bound, complex protocells with life-like capabilities by using building blocks from two distinct bacterial colonies spatially segregated within individu...

#FeaturedProtocol this week is for preparation and characterization of #protocells constructed from the components of two bacterial colonies spatially segregated within #coacervate microdroplets bit.ly/4kBa1RH

Building Artificial Life: An Introductory Overview Of Synthetic Biology What Is Synthetic Biology?  While origin of life research generally pertains to figuring out the pathways of chemical systems that produce...

Building Artificial Life: An Introductory Overview Of Synthetic Biology
#artificiallife #protocells #syntheticbiology #biotechnology #bioengineering
biochemical-systems.blogspot.com/2024/05/buil...

Inspiring talk by Evan Spruijt at NWO Chain 2024! He shared exciting insights into how coacervate-based and liposome-based #protocells come together to facilitate complex chemistry related to the origin of life on Earth!

#Evolution #OriginofLife #Biomolecular #Condensate #ChemSky

I am excited to share our latest publication in JACS: "Chemically Driven Division of Protocells by Membrane Budding"
I am grateful to all my amazing coauthors for their incredible teamwork @boekhovenlab.bsky.social
Read it: pubs.acs.org/doi/10.1021/...
#protocells #chemistry #originoflife #JACS

6) According to Adamala, the self-assembly of the #earliest #biopolymers could have benefited #protocells.

The stable RNA sequences that arise from the libraries could encode information for important