Project description:Increasing cell size drives proteomic changes that impact cell physiology. However, the molecular basis of size-dependent proteome remodeling has remained unclear. Here, we develop an inducible Cyclin D1 expression system in human cells to generate proliferating cells spanning over a two-fold size range. We use this system to make comprehensive genome-wide measurements of mRNA and protein concentrations and stability. We find that protein and mRNA turnover rates are weakly related to cell size, but that mRNA concentrations are strongly size-dependent. This establishes that transcriptional regulation is the basis of proteome remodeling. Live-cell imaging of nascent mRNAs using the MS2 system is used to measure how transcriptional dynamics change with cell size. Larger cells prolong transcriptional bursts and shorten inactive periods between bursts but maintain similar burst amplitudes to achieve transcriptional scaling. Together, our results show how transcription is modulated by cell size to remodel the proteome and alter cell physiology.

Project description:Increasing cell size drives proteomic changes that impact cell physiology. However, the molecular basis of size-dependent proteome remodeling has remained unclear. Here, we develop an inducible Cyclin D1 expression system in human cells to generate proliferating cells spanning over a two-fold size range. We use this system to make comprehensive genome-wide measurements of mRNA and protein concentrations and stability. We find that protein and mRNA turnover rates are weakly related to cell size, but that mRNA concentrations are strongly size-dependent. This establishes that transcriptional regulation is the basis of proteome remodeling. Live-cell imaging of nascent mRNAs using the MS2 system is used to measure how transcriptional dynamics change with cell size. Larger cells prolong transcriptional bursts and shorten inactive periods between bursts but maintain similar burst amplitudes to achieve transcriptional scaling. Together, our results show how transcription is modulated by cell size to remodel the proteome and alter cell physiology.

Project description:Bacterial adaptation involves extensive cellular reorganization. In particular, growth rate adjustments are associated with substantial modifications of gene expression and mRNA abundance. In this work we aimed to assess the role of mRNA degradation during such variations. A genome-wide transcriptomic-based method was used to determine mRNA half-lives. The model bacterium Lactococcus lactis was used and five growth rates were studied in continuous cultures under isoleucine-limitation and in batch cultures during the adaptation to the isoleucine starvation. During continuous isoleucine-limited growth, the mRNAs of different genes had different half-lives. The stability of most of the transcripts was not constant, and increased as the growth rate decreased. This half-life diversity was analyzed to investigate determinants of mRNA stability. The concentration, length, codon adaptation index and secondary structures of mRNAs were found to contribute to the regulation of mRNA stability in these conditions. However, the growth rate was, by far, the most influential determinant. The respective influences of mRNA degradation and transcription on the regulation of intra-cellular transcript concentration were estimated. The role of degradation on mRNA homeostasis was clearly evidenced: for more than 90 % of the mRNAs studied during continuous isoleucine-limited growth of L. lactis, degradation was antagonistic to transcription. Although both transcription and degradation had, opposite effects,, the mRNA changes in response to growth rate were driven by transcription. Interestingly, degradation control increased during the dynamic adaptation of bacteria as the growth rate reduced due to progressive isoleucine starvation in batch cultures. This work shows that mRNA decay differs between gene transcripts and according to the growth rate. It demonstrates that mRNA degradation is an important regulatory process involved in bacterial adaptation. However, its impact on the regulation of mRNA levels is smaller than that of transcription in the conditions studied. In the study presented here mRNA stabilities were analyzed at 5 growth rates. For each growth rate mRNA levels were measured in a time course experiment following rifampicin addition. At least 12 time points per growth rate are available, including 3 replicates of the zero.

Project description:Cell migration is an essential process in health and disease - especially in cancer metastasis. The difficulty to assess migration in high throughput presents a methodological hurdle - hence, only very few screens revealed factors controlling this important process. Here, we introduce MigExpress as a platform for the "identification of Migration control genes by differential Expression". MigExpress exploits the combination of in-depth molecular profiling and the robust quantitative analysis of migration capacity in a broad panel of samples and identifies migration-associated genes by their differential expression in slowly versus fast migrating cells. We applied MigExpress to non-small cell lung cancer (NSCLC), the most frequent cause of cancer mortality mainly due to metastasis. In 54 NSCLC cell lines, we comprehensively determined mRNA and protein expression. Correlating the transcriptome and proteome profiles with the quantified migration properties led to the discovery and validation of FLNC, DSE, CPA4, TUBB6 and BICC1 as migration control factors in NSCLC cells, which also negatively correlated with patient survival. Notably, FLNC was the least expressed filamin in NSCLC, but the only one controlling cell migration and correlating with patient survival and metastatic disease stage.

Project description:Gene expression is a stochastic process that occurs in bursts of RNA synthesis. We applied a mathematical model to scRNA-Seq data to infer bursting dynamics transcriptome-wide under multiple perturbations in a wide range of cell types and identified possible molecular mechanisms. We find that mediator complex subunit MED26 primarily regulates frequency, MYC regulates burst size, while cohesin and super-enhancers can modulate both. Despite comparable effect sizes on RNA levels amongst these perturbations, we find that acute depletion of MED26 plays a larger role in perturbing gene regulatory networks. Furthermore, this perturbation acts downstream of both chromatin spatial architecture and preinitiation complex formation, indicating that later steps in the initiation of transcriptional bursts are primary nodes for integrating gene networks in single cells.

Project description:Antibody affinity maturation occurs in secondary lymphoid organs within germinal centers (GCs) where B cells mutate their antibody-encoding genes in the dark zone (DZ) followed by a selection of the high-affinity variants in the light zone (LZ) by T cells. The amount of the T cell-derived selection signals is proportional to the BCR affinity and the magnitude of Myc expression. However, since the lifetimes of Myc mRNA and protein are extremely short, it is unclear how high levels of Myc are maintained in the GC B cell to allow positive selection. Here, by measuring Myc transcripts in situ at the single-cell level, we find that T cell help promotes the frequency of Myc transcriptional bursts. T cell help primarily increases the number of Myc-positive cells rather than the amount of Myc per cell. Measurement of Myc intronic and exonic transcripts in situ demonstrates that positive selection is mediated by Myc transcriptional bursts through a rapid increase in the active transcription sites rather than an elevation in transcription rate or gene accessibility. Thus, the amount of Myc transcriptional bursts over time in the LZ, rather than Myc abundance, dictates B cell selection in germinal centers.

Project description:Genetic variation governs protein expression through both transcriptional and post-transcriptional processes. To investigate this relationship, we combined a multiplexed, mass spectrometry-based method for protein quantification with an emerging mouse model harboring extensive genetic variation from 8 founder strains. We collected genome-wide mRNA and protein profiling measurements to link genetic variation to protein expression differences in livers from 192 diversity outcross mice. We observed nearly 3,700 protein-level quantitative trait loci (pQTL) with an equal proportion of proteins regulated directly by their cognate mRNA as uncoupled from their transcript. Our analysis reveals an extensive array of at least five models for genetic variant control of protein abundance including direct protein-to-protein associations that act to achieve stoichiometric balance of functionally related enzymes and subunits of multimeric complexes.

Project description:Microbes exhibit precise control over their composition and geometry in order to adapt and grow in diverse environments. However, the mechanisms that orchestrate this simultaneous regulation, and how they are causally linked, remains poorly understood. In this work, we derive and experimentally test a biophysical model of cell size regulation in Escherichia coli which relates the cellular surface-to-volume ratio to the total macromolecular composition and partitioning of the proteome between cellular compartments. Central to this model is the observation that the macromolecular density of the cytoplasm and the protein density within the cell membranes are maintained at a constant ratio across growth conditions. Using quantitative mass spectrometry, single-cell microscopy, and biochemical assays, we show this model quantitatively predicts a non-linear relationship between the surface-to-volume ratio, proteome localization, and the total ribosome content of the cell. This model holds under perturbations of intracellular ppGpp concentrations–thereby changing the ribosomal content–demonstrating that cellular geometry is not strictly determined by the cellular growth rate. These findings provide a biophysical link between the coregulation of proteome organization and cellular geometry, offering a quantitative framework for understanding bacterial size regulation across conditions.

Project description:Minimal residual disease (MRD) status in multiple myeloma (MM) is an important prognostic biomarker. Personalized blood-based targeted mass spectrometry (MS-MRD) detecting M-proteins was shown to provide a sensitive and minimally invasive alternative to MRD assessment in bone marrow. However, MS-MRD still comprises manual steps that hamper upscaling of sample size. Here, we introduce a proof-of-concept for a novel workflow using dia-PASEF technology and automated data processing.Using automated data processing of PASEF DDA and dia-PASEF measurements, we developed a workflow that identified unique targets from MM patient sera and personalized protein sequence databases. We generated patient-specific libraries linked to dia-PASEF methods and subsequently quantitated and reported M-protein concentrations in follow-up samples from MM patients. Assay performance of prm-PASEF and dia-PASEF workflows were compared and we tested mixing patient intake sera for multiplexed target identification and selection.

Project description:Myc transcriptional bursts promote B cell positive selection by T cells in germinal centers