Project description:A biochemical explanation of development from the fertilized egg to the adult anatomy requires an understanding of the complement of proteins and RNAs expressed over time during embryogenesis. Here we present a comprehensive characterization of protein and mRNA dynamics across early development in Xenopus. Surprisingly, we find that most proteins change very little and duplicated genes are expressed similarly. While the correlation between mRNA levels and protein expression is poor, a mass action kinetics model parametrized by the protein synthesis and degradation rates regresses protein dynamics to RNA dynamics, corrected for initial protein concentration. This study provides a rich resource for developmental biologists, unveiling detailed data for absolute levels of ~10K proteins and ~28K transcripts via convenient web portal. It underscores the lasting impact of maternal dowry, finds surprisingly few cases where degradation alone drives a change in protein level, and highlights the importance of transcription in shaping the proteome. mRNA from 18 samples each at a different developmental stage. Libraries were constructed using RNA enriched for mRNA by rRNA depletion using the EpiCenter RiboZero kit and the EpiCenter ScripSeq kit V2 using 50ng input RNA, and 12 cycles amplification.

Project description:A biochemical explanation of development from the fertilized egg to the adult anatomy requires an understanding of the complement of proteins and RNAs expressed over time during embryogenesis. Here we present a comprehensive characterization of protein and mRNA dynamics across early development in Xenopus. Surprisingly, we find that most proteins change very little and duplicated genes are expressed similarly. While the correlation between mRNA levels and protein expression is poor, a mass action kinetics model parametrized by the protein synthesis and degradation rates regresses protein dynamics to RNA dynamics, corrected for initial protein concentration. This study provides a rich resource for developmental biologists, unveiling detailed data for absolute levels of ~10K proteins and ~28K transcripts via convenient web portal. It underscores the lasting impact of maternal dowry, finds surprisingly few cases where degradation alone drives a change in protein level, and highlights the importance of transcription in shaping the proteome.

Project description:A biochemical explanation of development from the fertilized egg to the adult anatomy requires an understanding of the complement of proteins and RNAs expressed over time during embryogenesis. Here we present a comprehensive characterization of protein and mRNA dynamics across early development in Xenopus. Surprisingly, we find that most proteins change very little and duplicated genes are expressed similarly. While the correlation between mRNA levels and protein expression is poor, a mass action kinetics model parametrized by the protein synthesis and degradation rates regresses protein dynamics to RNA dynamics, corrected for initial protein concentration. This study provides a rich resource for developmental biologists, unveiling detailed data for absolute levels of ~10K proteins and ~28K transcripts via convenient web portal. It underscores the lasting impact of maternal dowry, finds surprisingly few cases where degradation alone drives a change in protein level, and highlights the importance of transcription in shaping the proteome.

Project description:Protein expression is regulated by production and degradation of mRNAs and proteins, but their specific relationships remain unknown. We combine measurements of protein production and degradation and mRNA dynamics to build a quantitative genomic model of the differential regulation of gene expression in LPS stimulated mouse dendritic cells. Changes in mRNA abundance play a dominant role in determining most dynamic fold changes in protein levels. Conversely, the preexisting proteome of proteins performing basic cellular functions is remodeled primarily through changes in protein production or degradation, accounting for over half of the absolute change in protein molecules in the cell. Thus, the proteome is regulated by transcriptional induction of novel cellular functions and remodeling of preexisting functions through the protein life cycle. Mouse primary dendritic cells were treated with LPS or mock stimulus and profiled over a 12-hour time course. Cells were grown in M-labeled SILAC media, which was replaced with H-labeled SILAC media at time 0. Aliquots were taken at 0, 0.5, 1, 2, 3, 4, 5, 6, 9, and 12 hours post-stimulation and added to equal volumes of a master mix of unlabeled (L) cells for the purpose of normalization. RNA-Seq was performed at 0, 1, 2, 4, 6, 9, and 12 hours post-stimulation.

Project description:Protein expression is regulated by production and degradation of mRNAs and proteins, but their specific relationships remain unknown. We combine measurements of protein production and degradation and mRNA dynamics to build a quantitative genomic model of the differential regulation of gene expression in LPS stimulated mouse dendritic cells. Changes in mRNA abundance play a dominant role in determining most dynamic fold changes in protein levels. Conversely, the preexisting proteome of proteins performing basic cellular functions is remodeled primarily through changes in protein production or degradation, accounting for over half of the absolute change in protein molecules in the cell. Thus, the proteome is regulated by transcriptional induction of novel cellular functions and remodeling of preexisting functions through the protein life cycle. Mouse primary dendritic cells were treated with LPS or mock stimulus and profiled over a 12-hour time course. Cells were grown in M-labeled SILAC media, which was replaced with H-labeled SILAC media at time 0. Aliquots were taken at 0, 0.5, 1, 2, 3, 4, 5, 6, 9, and 12 hours post-stimulation and added to equal volumes of a master mix of unlabeled (L) cells for the purpose of normalization. RNA-Seq was performed at 0, 1, 2, 4, 6, 9, and 12 hours post-stimulation.

Project description:Protein expression is regulated by production and degradation of mRNAs and proteins, but their specific relationships remain unknown. We combine measurements of protein production and degradation and mRNA dynamics to build a quantitative genomic model of the differential regulation of gene expression in LPS stimulated mouse dendritic cells. Changes in mRNA abundance play a dominant role in determining most dynamic fold changes in protein levels. Conversely, the preexisting proteome of proteins performing basic cellular functions is remodeled primarily through changes in protein production or degradation, accounting for over half of the absolute change in protein molecules in the cell. Thus, the proteome is regulated by transcriptional induction of novel cellular functions and remodeling of preexisting functions through the protein life cycle.

Project description:Protein expression is regulated by production and degradation of mRNAs and proteins, but their specific relationships remain unknown. We combine measurements of protein production and degradation and mRNA dynamics to build a quantitative genomic model of the differential regulation of gene expression in LPS stimulated mouse dendritic cells. Changes in mRNA abundance play a dominant role in determining most dynamic fold changes in protein levels. Conversely, the preexisting proteome of proteins performing basic cellular functions is remodeled primarily through changes in protein production or degradation, accounting for over half of the absolute change in protein molecules in the cell. Thus, the proteome is regulated by transcriptional induction of novel cellular functions and remodeling of preexisting functions through the protein life cycle.

Project description:How the fertilized egg develops the anatomy of an adult ultimately must be explained at the biochemical level. Deeply connected to the anatomy is the complement of proteins and RNAs expressed during embryogenesis. The relationship of mRNA and respective protein expression dynamics during development has never been systematically explored. Here we present a comprehensive characterization of protein and mRNA dynamics across early development in Xenopus, between unfertilized egg and early tadpole stage. Surprisingly, most proteins change very little; there is an inverse correlation between abundance and rate of change. While the correlation of mRNA and protein expression is poor, a simple mass action kinetics model connects protein to RNA. Parameterized by two fixed parameters the median protein synthesis and degradation rates, the model depends on RNA dynamics, and initial protein concentration. Associated mRNA datasets in GEO: GSE73905 and GSE73870.

Project description:Quantitative studies of the P. falciparum transcriptome have shown that the tightly controlled progression of the parasite through the intraerythrocytic developmental cycle (IDC) is accompanied by a continuous gene expression cascade where most expressed genes exhibit a single transcriptional peak. Since proteins represent the decisive business end of gene expression, understanding the correlation between mRNA and protein levels is crucial for inferring biological activity from transcriptional gene expression data. While pertinent studies on other organisms show that as little as 20-40% of protein abundance variation may be attributable to corresponding mRNA levels, the situation in Plasmodium is further complicated by the dynamic nature of the cyclic gene expression cascade where the mRNA levels of most genes change constantly during the IDC. In this study, we simultaneously determined mRNA and protein abundance profiles for P. falciparum parasites during the IDC at 2-hour resolution based on spotted oligonucleotide microarrays and 2D-protein gels in combination with DIGE fluorescent dyes. Intriguingly, most proteins are represented by more than one isoform, presumably due to post-translational modifications. Analysis of 366 protein abundance profiles and the corresponding mRNA levels shows that in 67.2% of cases the protein abundance peaks at least 8 hours after the mRNA level peak. While it may be tempting to interpret this as evidence for widespread post-transcriptional gene regulation additional analyses including computer modeling demonstrate that in >60% of these cases the observed protein profiles including the peak lag times could arise as a consequence of the corresponding mRNA levels when simple translation and degradation dynamics are assumed. We further characterize and illustrate these dynamics and show that even human host proteins within the parasite may be subject to similar dynamics as their parasite counterparts. 24 timepoint samples were harvested from a tightly synchronous 6.5 liter biofermenter culture of P. falciparum (Dd2) at 2-hour intervals during one entire intraerythrocytic developmental cycle and compared against a 3D7 RNA reference pool.

Project description:We have employed whole genome microarray expression profiling to track the transcriptome expression change under DTT induced protein misfolding stress. The relative importance of gene expression regulation at the mRNA versus the protein-level is a matter of ongoing debate. We present an in-depth analysis of a cervical cancer cell line responding to protein misfolding stress induced by dithiothreitol treatment, quantifying the dynamics of mRNA and protein concentrations for >3,500 genes over a time-course 30 hours. While the early phase of the experiment (<two hours) was marked by apoptosis, surviving cells were marked by a strong response to unfolded proteins and stress of the endoplasmatic reticulum, specifically during the intermediate phase (two to eight hours). Using statistical time series analysis, we detected significant changes in the regulatory parameters at the RNA-level, caused by transcription and mRNA degradation, and at the protein-level, caused by translation and protein degradation. mRNA- and protein-level regulation were of equal importance (XX and YYY%, respectively), but displayed different magnitudes and dynamics: mRNA fold changes were much smaller on average than those of the proteins. While our method did not capture immediate changes, we found the strongest regulatory response between two and eight hours after the treatment. mRNA-level regulation showed a spike around this time interval, while protein-level regulation was delayed and continued at slower pace until the end of the experiment.