Volker Lipka
@volkerlipka.bsky.social
I am a plant molecular cell biologist at Göttingen University with an interest in host-microbe interactions, immune receptors, pathogen entry control and microbial effectors.
Thank you, Kenichi! Great to hear that you like it!
September 23, 2025 at 8:15 AM
Thank you, Kenichi! Great to hear that you like it!
Thank you, Gitta! We are waiting with anticipation to see how our work will be received...
September 23, 2025 at 6:54 AM
Thank you, Gitta! We are waiting with anticipation to see how our work will be received...
...and snapshot with a bat flying through...🦇... "blood" moon misunderstood?😂🧛
September 8, 2025 at 8:50 AM
...and snapshot with a bat flying through...🦇... "blood" moon misunderstood?😂🧛
Great news! Congrats and all the best for a smooth move and great start!
September 1, 2025 at 3:02 PM
Great news! Congrats and all the best for a smooth move and great start!
That said, we're more than happy with this outcome — it's certainly preferable to the typical endless rounds of additional experiments often demanded during peer review. 😉
April 29, 2025 at 2:22 PM
That said, we're more than happy with this outcome — it's certainly preferable to the typical endless rounds of additional experiments often demanded during peer review. 😉
Thank you, Tonni!
January 14, 2025 at 2:27 PM
Thank you, Tonni!
Thanks, Jennifer!
January 14, 2025 at 2:26 PM
Thanks, Jennifer!
Our findings underpin that sphingolipid production contributes to the role of the trans-Golgi network as a multi-domain sorting compartment and is required for defense against pathogen invasion.
January 14, 2025 at 9:50 AM
Our findings underpin that sphingolipid production contributes to the role of the trans-Golgi network as a multi-domain sorting compartment and is required for defense against pathogen invasion.
Here, we provide evidence that INOSITOL PHOSPHORYLCERAMIDE SYNTHASE 2 (IPCS2) is involved in proper delivery of the ATP-binding cassette transporter PEN3 to polarized plasma membrane domains at plant-microbe interaction sites.
January 14, 2025 at 9:49 AM
Here, we provide evidence that INOSITOL PHOSPHORYLCERAMIDE SYNTHASE 2 (IPCS2) is involved in proper delivery of the ATP-binding cassette transporter PEN3 to polarized plasma membrane domains at plant-microbe interaction sites.
Our analyses suggest dysregulated mRNA decay & accumulation of transcripts encoding master regulators of xylogenesis. Tissue-specific developmental reprogramming & de novo xylem formation ultimately increase the plant's water storage capacity & resistance to drought stress. (5/5)
January 14, 2025 at 9:43 AM
Our analyses suggest dysregulated mRNA decay & accumulation of transcripts encoding master regulators of xylogenesis. Tissue-specific developmental reprogramming & de novo xylem formation ultimately increase the plant's water storage capacity & resistance to drought stress. (5/5)
We show that TRADE triggers sustained phosphorylation of VARICOSE via co-option of ABA-independent SNF1-Related Protein Kinases 2, which are known to control rapid and transient intracellular signaling for adaptation to osmotic stress and root development. (4/5)
January 14, 2025 at 9:42 AM
We show that TRADE triggers sustained phosphorylation of VARICOSE via co-option of ABA-independent SNF1-Related Protein Kinases 2, which are known to control rapid and transient intracellular signaling for adaptation to osmotic stress and root development. (4/5)
We show that TRADE interacts with the conserved protein VARICOSE (VCS), a scaffold protein of processing (P) bodies, which represent cytosolic subdomains of mRNA turnover & storage formed by liquid-liquid phase separation. (3/5)
January 14, 2025 at 9:41 AM
We show that TRADE interacts with the conserved protein VARICOSE (VCS), a scaffold protein of processing (P) bodies, which represent cytosolic subdomains of mRNA turnover & storage formed by liquid-liquid phase separation. (3/5)
We are thrilled by and proud of this recent collaborative effort, in which we identified a single fungal effector protein, TRADE, that induces cell identity switches in dicot plants and thereby enhances plant resilience to concomitant drought stress conditions. (2/5)
January 14, 2025 at 9:39 AM
We are thrilled by and proud of this recent collaborative effort, in which we identified a single fungal effector protein, TRADE, that induces cell identity switches in dicot plants and thereby enhances plant resilience to concomitant drought stress conditions. (2/5)