Your search keyword '"Naama Barkai"' showing total 4 results

1. Evolution of binding preferences among whole-genome duplicated transcription factors

Author

Tamar Gera, Felix Jonas, Roye More, and Naama Barkai

Subjects

transcription factors, functional divergence, whole genome duplication, gene regulation, DNA binding, paralogs, Medicine, Science, Biology (General), QH301-705.5

Abstract

Throughout evolution, new transcription factors (TFs) emerge by gene duplication, promoting growth and rewiring of transcriptional networks. How TF duplicates diverge was studied in a few cases only. To provide a genome-scale view, we considered the set of budding yeast TFs classified as whole-genome duplication (WGD)-retained paralogs (~35% of all specific TFs). Using high-resolution profiling, we find that ~60% of paralogs evolved differential binding preferences. We show that this divergence results primarily from variations outside the DNA-binding domains (DBDs), while DBD preferences remain largely conserved. Analysis of non-WGD orthologs revealed uneven splitting of ancestral preferences between duplicates, and the preferential acquiring of new targets by the least conserved paralog (biased neo/sub-functionalization). Interactions between paralogs were rare, and, when present, occurred through weak competition for DNA-binding or dependency between dimer-forming paralogs. We discuss the implications of our findings for the evolutionary design of transcriptional networks.

Published

2022

2. A repressor-decay timer for robust temporal patterning in embryonic Drosophila neuroblast lineages

Author

Inna Averbukh, Sen-Lin Lai, Chris Q Doe, and Naama Barkai

Subjects

neuroblast, biological timer, robustness, Medicine, Science, Biology (General), QH301-705.5

Abstract

Biological timers synchronize patterning processes during embryonic development. In the Drosophila embryo, neural progenitors (neuroblasts; NBs) produce a sequence of unique neurons whose identities depend on the sequential expression of temporal transcription factors (TTFs). The stereotypy and precision of NB lineages indicate reproducible TTF timer progression. We combine theory and experiments to define the timer mechanism. The TTF timer is commonly described as a relay of activators, but its regulatory circuit is also consistent with a repressor-decay timer, where TTF expression begins when its repressor decays. Theory shows that repressor-decay timers are more robust to parameter variations than activator-relay timers. This motivated us to experimentally compare the relative importance of the relay and decay interactions in vivo. Comparing WT and mutant NBs at high temporal resolution, we show that the TTF sequence progresses primarily by repressor-decay. We suggest that need for robust performance shapes the evolutionary-selected designs of biological circuits.

Published

2018

3. Principles of cellular resource allocation revealed by condition-dependent proteome profiling

Author

Eyal Metzl-Raz, Moshe Kafri, Gilad Yaakov, Ilya Soifer, Yonat Gurvich, and Naama Barkai

Subjects

translation, transcription, ribosomes, resource allocation, proteome, Medicine, Science, Biology (General), QH301-705.5

Abstract

Growing cells coordinate protein translation with metabolic rates. Central to this coordination is ribosome production. Ribosomes drive cell growth, but translation of ribosomal proteins competes with production of non-ribosomal proteins. Theory shows that cell growth is maximized when all expressed ribosomes are constantly translating. To examine whether budding yeast function at this limit of full ribosomal usage, we profiled the proteomes of cells growing in different environments. We find that cells produce excess ribosomal proteins, amounting to a constant ≈8% of the proteome. Accordingly, ≈25% of ribosomal proteins expressed in rapidly growing cells does not contribute to translation. Further, this fraction increases as growth rate decreases and these excess ribosomal proteins are employed when translation demands unexpectedly increase. We suggest that steadily growing cells prepare for conditions that demand increased translation by producing excess ribosomes, at the expense of lower steady-state growth rate.

Published

2017

4. Principles of cellular resource allocation revealed by condition-dependent proteome profiling

Author

Naama Barkai, Moshe Kafri, Gilad Yaakov, Ilya Soifer, Eyal Metzl-Raz, and Yonat Gurvich

Subjects

Ribosomal Proteins, 0301 basic medicine, Saccharomyces cerevisiae Proteins, QH301-705.5, proteome, Science, Systems biology, S. cerevisiae, translation, resource allocation, Saccharomyces cerevisiae, Biology, Ribosome, General Biochemistry, Genetics and Molecular Biology, ribosomes, 03 medical and health sciences, Ribosomal protein, Transcription (biology), Gene Expression Regulation, Fungal, Protein biosynthesis, Ribosome profiling, Biology (General), Condition dependent, General Immunology and Microbiology, Cell growth, Chemistry, Gene Expression Profiling, General Neuroscience, Translation (biology), Cell Biology, General Medicine, Ribosomal RNA, Molecular biology, Cell biology, Proteome profiling, 030104 developmental biology, Protein Biosynthesis, Proteome, Peptide Biosynthesis, Nucleic Acid-Independent, Medicine, transcription, Research Article, Computational and Systems Biology

Abstract

Growing cells devote much of their resources to producing ribosomes. Translation of ribosomal proteins competes with the production of other proteins, suggesting that cells optimize growth by producing the precise number of ribosomes required for meeting translation demands. Alternatively, maintaining a pool of ready-to-use ribosomes could facilitate a response to fluctuating conditions. To examine how cells balance their ribosomal content, we used proteome profiling. Differences in ribosomal proteins levels in cells growing at different rates precisely accounted for the estimated differences in translation rates. However, in all conditions, 8% of the proteome coded for extra ribosomal proteins, produced in addition to the growth-rate dependent fraction. This pool of extra ribosomal proteins, consisting of ~20% of the expressed ribosomes in fast growing cells and the majority of ribosomes in slow-growing ones, was employed upon unexpected increase in translation demands, for example during nutrient upshift and when forcing excess protein production. Cells therefore tune their ribosome content and activity to balance the opposing requirements of rapid growth with rapid response to fluctuating conditions.

Published

2017