Here come our new palette of fluorescent dyes. The BD dyes endeaves to balance glowy brightness, robust photostability, and biocompatibility. Let's boost 4D dynamic super-resolution imaging!!!
www.nature.com/articles/s41...
@spirochrome.com
Striking new study from @archaeon-alex.bsky.social's lab just out in @science.org on multicellular development induced by compression in Archaea: www.science.org/doi/10.1126/...
How does your favorite species elongate? 🧵 "Phenotypic plasticity in bacterial elongation among closely related species". Happy to see this paper in print @natcomms.nature.com. Nice work by @mariedelaby.bsky.social, Liu Yang et al. See original 🧵, different colours, same data and conclusions.
Mapping of DNA-binding sites for 139 E. coli transcription factors
and
A neural network that predicts binding energy from DNA sequence and can be used to design new binding sites
#NeuralNetworks #MachineLearning #Genomics
"E. coli nucleoid adopts a condensed, membrane-proximal configuration during rapid growth, an active role of transertion (coupled transcription, translation, and membrane insertion) in nucleoid organization" #microsky www.nature.com/articles/s41...
Zhixing Chen
Nature Communications
We enjoyed putting our heads together with the Jakob and Freddolino labs to find that polyphosphate modulates the formation of functional RNA-protein condensates in response to nitrogen-starvation stress!
journals.plos.org/plosbiology/...
Our paper on the E. coli Min system in vivo with @physicsoflifelmu.bsky.social & Judy Kim (UCSD) has been published in Nature Physics today. Tight integration of experiment and theory, and physiology and biophysics. Incredible perseverance of our young students. rdcu.be/ekIpO
How do internal promoters within operons shape bacterial stress responses? 🦠🧫
Contributing to a study with @andreribeirolbd.bsky.social, we show non-monotonic spatial expression patterns across operons in E. coli, B. subtilis, C. glutamicum, and H. pylori. www.science.org/doi/10.1126/...
Yves Brun lab
Zeynep Baharoglu
www.nature.com
A suite of bridged rhodamine dyes (BriDyes) offers excellent brightness, solubility, photostability, and tunable cell permeability along with resistance to photoblueing, making them exceptional all-pu...
The mechanisms underlying bacterial chromosome configuration are not fully understood. Here, Spahn et al. show that the Escherichia coli nucleoid adopts a condensed, membrane-proximal configuration du...
The advent of clonal multicellularity is a critical evolutionary milestone, seen often in eukaryotes, rarely in bacteria, and only once in archaea. We show that uniaxial compression induces clonal mul...
Nature Communications - Multiple types of cell elongation have been described in bacteria, but little is known about how these strategies vary across species. Here, the authors use fluorescent...
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How does your favorite species elongate? 🧵 "Phenotypic plasticity in bacterial elongation among closely related species" by @mariedelaby.bsky.social, Liu Yang et al https://buff.ly/48Kw96x. How do cells elongate, all over, poles, middle? Close species do it the same way right? Not quite! #Microsky
Yves Brun lab
Nature Physics - Oscillatory Min protein patterns prevent abnormal bacterial cell division. Now it is shown that Min pattern formation is resource efficient and involves wavelength-invariant...
The authors describe BoltzNet, a neural network that learns the energy of transcription factor (TF)-DNA binding from genomic data and can be used to design new binding sites. They report the in vivo mapping and BoltzNet modeling of 139 E. coli TFs.
