Project description:Deep Sequencing CRISPR edits

Project description:Deep Sequencing CRISPR edits

Project description:Deep Sequencing CRISPR edits

Project description:We used microarrays to assess gene expression differences in the hippocampus between FoxO6 mutant and wild-type siblings before (basal) or after novel object learning. The cohort of basal mice were housed individually for at least 3 days prior to tissue harvesting. The mice used to collect hippocampal samples after the object learning task were handled daily in the procedure room, prior to the object learning task. 24 hours before the object learning task, each mouse was individually habituated to the empty novel object arena for 10 min. On the days of the novel object learning task and the empty arena habituation, the mice were transferred to the procedure room and acclimatized for 60 min. For the novel object learning task, the mice were allowed to explore two identical and novel objects for 10 min in a 70 x 70 x 70 cm black plastic arena with a white PVC vinyl material on the base. After the object exploration, mice were transferred to an empty cage, and were euthanized after 60 min. The brains were dissected and incubated in ice-cold RNAlater (Ambion) for 24 hours at 4M-BM-:C. The brains were then rapidly frozen in O.C.T. Tissue-Tek (Sakura) at -80M-BM-:C. Coronal brain sections (300 M-BM-5m) were made using a microtome (Microm), the hippocampus was finely dissected and collected into M-bM-^@M-^XRNA lysis bufferM-bM-^@M-^Y (Ambion), and homogenized for 30 sec using a rotar-stat homogenizer. Total RNA was extracted using the RNAqueous column (Ambion) following the manufacturerM-bM-^@M-^Ys protocol.

Project description:An important and largely unsolved problem in synthetic biology is how to target gene expression to specific cell types. Here, we apply iterative deep learning to design synthetic enhancers with strong differential activity between two human cell lines. We initially train models on published datasets of enhancer activity and chromatin accessibility and use them to guide the design of synthetic enhancers that maximize predicted specificity. We experimentally validate these sequences, use the measurements to re-optimize the predictor, and design a second generation of enhancers with improved specificity. Our design methods embed relevant transcription factor binding site (TFBS) motifs with higher frequencies than comparable endogenous enhancers while using a more selective motif vocabulary, and we show that enhancer activity is correlated with transcription factor expression at the single cell level. Finally, we characterize causal features of top enhancers via perturbation experiments and show enhancers as short as 50bp can maintain specificity.

Project description:An important and largely unsolved problem in synthetic biology is how to target gene expression to specific cell types. Here, we apply iterative deep learning to design synthetic enhancers with strong differential activity between two human cell lines. We initially train models on published datasets of enhancer activity and chromatin accessibility and use them to guide the design of synthetic enhancers that maximize predicted specificity. We experimentally validate these sequences, use the measurements to re-optimize the predictor, and design a second generation of enhancers with improved specificity. Our design methods embed relevant transcription factor binding site (TFBS) motifs with higher frequencies than comparable endogenous enhancers while using a more selective motif vocabulary, and we show that enhancer activity is correlated with transcription factor expression at the single cell level. Finally, we characterize causal features of top enhancers via perturbation experiments and show enhancers as short as 50bp can maintain specificity.

Project description:Design and deep learning of synthetic B- cell-specific promoters

Project description:The escalating crisis of multiresistant bacteria demands the rapid discovery of novel antibiotics that transcend the limitations imposed by the biased chemical space of current libraries. To address this challenge, we introduce an innovative deep learning-driven pipeline for de novo antibiotic design. This unique approach leverages a chemical language model, trained on a diverse chemical space encompassing drug-like molecules and natural products, coupled with transfer learning on diverse antibiotic scaffolds to efficiently generate structurally unprecedented antibiotic candidates. Through the use of predictive modeling and expert curation, we prioritized and synthesized the most promising and readily available candidates. Notably, our efforts culminated in a lead candidate demonstrating potent activity against methicillin-resistant Staphylococcus aureus. Iterative refinement through automated synthesis of 40 derivatives yielded a suite of active compounds, including 30 with activity against S. aureus and 17 against Escherichia coli. Among these, lead compound D8 exhibited remarkable submicromolar and single-digit micromolar potency against the aforementioned pathogens, respectively. Mechanistic investigations point to the generation of radical species as its primary mode of action. This work showcases the power of our innovative deep learning framework to significantly accelerate and expand the horizons of antibiotic drug discovery.

Project description:Evaluation and optimization of sequence-based gene regulatory deep learning models

Project description:Kinetic model of extended MEP pathway in Arabidopsis thaliana for cis-abienol production. This model was used for determining total optimization potential (TOP) of cis-abienol production in Arabidopsis thaliana using Spacescanner (https://github.com/atiselsts/spacescanner). This model was used to make designs A, B and C. An optimization task in COPASI can be perfomed using this model by accesing COPASI/Tasks/Optimization. Parameters which will be changed during the optimization and the optimization constraints can be selected. More description in Total optimization potential (TOP) approach based constrained design of isoprene and cis-abienol production in A. thaliana, Authors: Katrina D. Neiburga, Reinis Muiznieks, Darta M. Zake, Agris Pentjuss, Vitalijs Komasilovs, Johann Rohwer, Alain Tissier, Egils Stalidzans