How can yeast cell factories produce valuable tryptophan-derived compounds sustainably? 🌱🧬
Discover how B. Sun et al. review metabolic engineering and synthetic biology strategies for aromatic bioproduction:
🔗 buff.ly/5ecaktj

#FEMSYeastRes

How do oxythiamine and ketoconazole work together against #Malassezia_pachydermatis? 🧬🧫

Discover how M. Czerniecka et al. reveal a synergistic mechanism targeting ergosterol synthesis and NADPH metabolism:
🔗 buff.ly/3rRLTTb

#FEMSYeastRes

How does sphingolipid diversity shape fluconazole resistance in #Candidozyma_auris? 🧬💊
Explore how P. Kumar et al. reveal intraclade lipid heterogeneity and key sphingolipid shifts linked to resistance:

🔗 buff.ly/N0BxvfN

#FEMSYeastRes

How do thiol groups help #Saccharomyces_cerevisiae overcome acetic acid stress? 🍷🧬

Explore how A. Shirvanyan et al. link redox balance, metabolism & pH to improved tolerance in wine and beer strains:
🔗 buff.ly/GGeI24A

#FEMSYeastRes

How does the C/N ratio drive sophorolipid production in #Starmerella_riodocensis? 🧪🦠
See how S. Sapsirisuk et al. boost antimicrobial SL yields, link gene upregulation to productivity & scale up in bioreactors:

🔗 buff.ly/CJphzmv

#FEMSYeastRes

Can regional yeast strains reshape whisky aroma profiles? 🥃🧬
Explore how R.A. Marr et al. screen #Canadian_yeasts for maltose use and reveal strain-driven diversity in new-make spirit volatiles:

🔗 buff.ly/pSKtXPv

#FEMSYeastRes

How did filamentous growth evolve across the #Saccharomycotina yeasts? 🧬🍄

Read how Chavez C.M. et al. map the macroevolution of hyphae and pseudohyphae across 1051 species using phylogeny and machine learning:
🔗 buff.ly/phisTGm

#FEMSYeastRes

How do prey choice and cell wall traits influence fungal predation? 🧫🦠
Discover how J.R. Smith et al. show that prey preference and cell wall remodelling shape predation efficiency in #Saccharomycopsis_schoenii:

🔗 buff.ly/Tlw6CUF

#FEMSYeastRes

How can engineered yeasts unlock efficient cellulosic ethanol production? 🌱🍶

Read how R. Vasylyshyn et al. compare yeast platforms for 2G bioethanol, balancing sugar use, stress tolerance & process performance:
🔗 buff.ly/FyDs5nr

#FEMSYeastRes

Breaking free from the Crabtree effect opens new paths for yeast biotechnology. ⚙️🧬
Read more on how Guo Y. et al. review strategies to engineer Crabtree-negative #Saccharomyces_cerevisiae for efficient chemical biosynthesis:
🔗 buff.ly/mFJHANf

#FEMSYeastRes

How do #Malassezia species grow when limited to single fatty acids? 🧬🧪
Discover how Liebregts J. et al. establish a defined medium to study lipid-dependent growth and lipidome adaptation here:
🔗 buff.ly/8XZFll0

#FEMSYeastRes

How can amino acid–rich brewing yeasts boost flavour in alcoholic beverages? 🍶🍺

Learn how S. Isogai et al. breed strains with amino acid accumulation for tailored aromas:
🔗 buff.ly/n4ix58J

#FEMSYeastRes

Why do methods for estimating microbial lag phase vary so much? 📈🧪

Read more on how Opalek M. et al. unravel the impact of noise, sampling, and growth rate on lag phase predictions in #Saccharomyces_cerevisiae:
🔗 buff.ly/IuOFcE7

#FEMSYeastRes

tRNA-derived fragments don’t just mark stress, they reshape translation. ⚡🧫
Read more on how Bąkowska-Żywicka K. & Tyczewska A. introduce tDR-quant, a powerful in vivo method revealing how tDRs selectively bind ribosomes under stress:
🔗https://buff.ly/9GTtT5i

#FEMSYeastRes

How is the cell wall protein Pir1 anchored in #Candida_albicans? 🔗
Read more on how Alvarado M. et al. uncover the role of Pir repeat units in β-1,3-glucan binding & wall incorporation, offering new insights into fungal cell integrity:
🔗 buff.ly/XpnsSSs

#FEMSYeastRes

How did multidrug resistance evolve in hemiascomycete yeasts? 🧬📊
Read more on how Dias P.J. traces the origins and diversification of Snq2/Pdr18 transporters, linking gene transfer and selection to antifungal resistance:

🔗 buff.ly/1upZBIG

#FEMSYeastRes

Yeast is an industrial workhorse underpinning massive industries including biofuels, pharmaceuticals, and chemical production. Discover the researchers pushing boundaries in our new thematic issue on #FEMSYeastRes: buff.ly/92Ck1PK

Why do some #yeast strains make wine smell like rotten eggs? 🥚🍷

We talk to the #FEMSYeastRes Article Award winners about their surprising genetic discoveries into S. cerevisiae and H₂S production.

👉 Listen now: buff.ly/VFaNoSm

#FEMSArticleAwards #YeastResearch #WineScience #Microbiology

Can #Saccharomyces_cerevisiae learn to sense xylose like glucose? 🧪
Read more on how Bruna C. Bolzico et al. engineered the Snf3p receptor to improve #xylose sensing and metabolism—advancing lignocellulosic bioprocessing 🌱🔬:

🔗 buff.ly/c6Gzftt

#FEMSYeastRes

How do tRNA-derived fragments regulate translation during stress? 🧬⚡
K. Bakowska-Zywicka & A. Tyczewska present tDR-quant—a new electroporation-based method to track ribosome binding of tRNA fragments in #S_cerevisiae.

Read more:
buff.ly/6qAVfxi

#FEMSYeastRes

Featuring research from #FEMSYeastRes 👇

Why is #Pichia_kudriavzevii more stress-tolerant than #Saccharomyces_cerevisiae ? 🌡🧫
Read more on how this resilient yeast thrives under harsh industrial conditions, featured in our Yeast Metabolic Engineering spotlight:
🔗 buff.ly/kNGa6tu

#FEMSYeastRes

How can we rewire yeast for industrial success? 🔧🧬
E. Celińska & Y. J. Zhou explore how global transcription machinery engineering boosts #Yarrowia_lipolytica traits like stress resistance & productivity by tweaking its regulatory networks.

Read more:
🔗 buff.ly/yNh3wmF

#FEMSYeastRes

Featuring research from #FEMSYeastRes 👇🍷🔬

What can yeast teach us about Alzheimer’s? 🧠🧪
H. Prasad & R. Rao uncover how endo-lysosomal pH, sterol balance, and intracellular trafficking interact in neurodegeneration — revealing new therapeutic angles rooted in yeast biology.

🔗 buff.ly/ucXz6Ui

#FEMSYeastRes

Guangchun Lu et al. uncover how specific oncohistone H2B variants in #Schizosaccharomyces_pombe disrupt H2B monoubiquitination, leading to genomic instability via altered gene expression. 🧬🧪
Read more at:

🔗 buff.ly/SzSsQtW
#FEMSYeastRes

F. Vega-Macaya et al. combine experimental evolution & hybridization to boost fermentation in wild #S_eubayanus strains🍺
Read on how the improved yeasts show enhanced fitness and aroma potential—promising tools for innovative brewing:

🔗 buff.ly/YI5WPQ9
#FEMSYeastRes

From the microbial networks behind kombucha fermentation to engineered strains powering sustainable fuels, #FEMSYeastRes brings you high-quality studies with major relevance across the field. 📊 Read the journal's most-read papers for the first half of 2025 buff.ly/NLKSc4N

X. Song et al. engineer a #Saccharomyces_cerevisiae consortium displaying a pentafunctional mini-cellulosome to boost cellulosic ethanol production. 🧪🧬
Read how their system relieves metabolic burden and improves yields by up to 106%:

🔗 buff.ly/v2OIsGe
#FEMSYeastRes

S. J. Britton et al. explore quorum sensing in industrial #Saccharomyces_cerevisiae brewing strains🍺🧬
Read more on how their study reveals strain-specific effects of 2-phenylethanol on yeast proteomic, lipidomic & metabolomic profiles:

🔗 buff.ly/WxGPaAt
#FEMSYeastRes