Project description:Differences in biomolecular sequence and function underlie dramatic ranges of appearance and behavior among species. We studied the basic region-leucine zipper (bZIP) transcription factors and quantified bZIP dimerization networks for five metazoan and two single-cell species, measuring interactions in vitro for 2891 protein pairs. Metazoans have a higher proportion of heteromeric bZIP interactions and more network complexity than the single-cell species. The metazoan bZIP interactomes have broadly similar structures, but there has been extensive rewiring of connections compared to the last common ancestor, and each species network is highly distinct. Many metazoan bZIP orthologs and paralogs have strikingly different interaction specificities, and some differences arise from minor sequence changes. Our data show that a shifting landscape of biochemical functions related to signaling and gene expression contributes to species diversity.

Project description:The identification of homologous cell types across species represents a crucial step in understanding cell type evolution. The retina is particularly amenable to comparative analysis because the basic morphology, connectivity, and function of its six major cell classes have remained largely invariant since the earliest stages of vertebrate evolution. We used comparative single-nucleus chromatin accessibility analysis of lamprey, fish, bird, and mammalian retinas, which began to diverge over half a billion years ago, to demonstrate cross-species conservation of cis-regulatory codes in all six retinal cell classes. In this study, we acquired retinal single-cell gene expression profiling (scRNA-seq) and single-nucleus chromatin accessibility (snATAC-seq) from sea lamprey (Petromyzon marinus), a jawless species. We also acquired long-read sequence data from lamprey retina and single-nucleus chromatin accessibility from chicken (Gallus gallus).

Project description:The identification of homologous cell types across species represents a crucial step in understanding cell type evolution. The retina is particularly amenable to comparative analysis because the basic morphology, connectivity, and function of its six major cell classes have remained largely invariant since the earliest stages of vertebrate evolution. We used comparative single-nucleus chromatin accessibility analysis of lamprey, fish, bird, and mammalian retinas, which began to diverge over half a billion years ago, to demonstrate cross-species conservation of cis-regulatory codes in all six retinal cell classes. In this study, we acquired retinal single-cell gene expression profiling (scRNA-seq) and single-nucleus chromatin accessibility (snATAC-seq) from sea lamprey (Petromyzon marinus), a jawless species. We also acquired long-read sequence data from lamprey retina and single-nucleus chromatin accessibility from chicken (Gallus gallus).

Project description:The identification of homologous cell types across species represents a crucial step in understanding cell type evolution. The retina is particularly amenable to comparative analysis because the basic morphology, connectivity, and function of its six major cell classes have remained largely invariant since the earliest stages of vertebrate evolution. We used comparative single-nucleus chromatin accessibility analysis of lamprey, fish, bird, and mammalian retinas, which began to diverge over half a billion years ago, to demonstrate cross-species conservation of cis-regulatory codes in all six retinal cell classes. In this study, we acquired retinal single-cell gene expression profiling (scRNA-seq) and single-nucleus chromatin accessibility (snATAC-seq) from sea lamprey (Petromyzon marinus), a jawless species. We also acquired long-read sequence data from lamprey retina and single-nucleus chromatin accessibility from chicken (Gallus gallus).

Project description:Little is known about the evolution of protein structures and the degree of protein structure conservation over planetary time scales. Here, we report the X-ray crystal structures of seven laboratory resurrections of Precambrian thioredoxins dating up to approximately four billion years ago. Despite considerable sequence differences compared with extant enzymes, the ancestral proteins display the canonical thioredoxin fold, whereas only small structural changes have occurred over four billion years. This remarkable degree of structure conservation since a time near the last common ancestor of life supports a punctuated-equilibrium model of structure evolution in which the generation of new folds occurs over comparatively short periods and is followed by long periods of structural stasis.

Project description:Interactions among mutations within a protein have the potential to make molecular evolution contingent and irreversible, but the extent to which epistasis actually shaped historical evolutionary trajectories is unclear. To address this question, we experimentally measured how the fitness effects of historical sequence substitutions changed during the billion-year evolutionary history of the heat shock protein 90 (Hsp90) ATPase domain beginning from a deep eukaryotic ancestor to modern Saccharomyces cerevisiae We found a pervasive influence of epistasis. Of 98 derived amino acid states that evolved along this lineage, about half compromise fitness when introduced into the reconstructed ancestral Hsp90. And the vast majority of ancestral states reduce fitness when introduced into the extant S. cerevisiae Hsp90. Overall, more than 75% of historical substitutions were contingent on permissive substitutions that rendered the derived state nondeleterious, became entrenched by subsequent restrictive substitutions that made the ancestral state deleterious, or both. This epistasis was primarily caused by specific interactions among sites rather than a general effect on the protein's tolerance to mutation. Our results show that epistasis continually opened and closed windows of mutational opportunity over evolutionary timescales, producing histories and biological states that reflect the transient internal constraints imposed by the protein's fleeting sequence states.

Project description:The identification of homologous cell types across species represents a crucial step in understanding cell type evolution. The retina is particularly amenable to comparative analysis because the basic morphology, connectivity, and function of its six major cell classes have remained largely invariant since the earliest stages of vertebrate evolution. We used comparative single-nucleus chromatin accessibility analysis of lamprey, fish, bird, and mammalian retinas, which began to diverge over half a billion years ago, to demonstrate cross-species conservation of cis-regulatory codes in all six retinal cell classes. In this study, we acquired retinal single-cell gene expression profiling (scRNA-seq) and single-nucleus chromatin accessibility (snATAC-seq) from sea lamprey (Petromyzon marinus), a jawless species. We also acquired long-read sequence data from lamprey retina and single-nucleus chromatin accessibility from chicken (Gallus gallus).

Project description:The identification of homologous cell types across species represents a crucial step in understanding cell type evolution. The retina is particularly amenable to comparative analysis because the basic morphology, connectivity, and function of its six major cell classes have remained largely invariant since the earliest stages of vertebrate evolution. We used comparative single-nucleus chromatin accessibility analysis of lamprey, fish, bird, and mammalian retinas, which began to diverge over half a billion years ago, to demonstrate cross-species conservation of cis-regulatory codes in all six retinal cell classes. In this study, we acquired retinal single-cell gene expression profiling (scRNA-seq) and single-nucleus chromatin accessibility (snATAC-seq) from sea lamprey (Petromyzon marinus), a jawless species. We also acquired long-read sequence data from lamprey retina and single-nucleus chromatin accessibility from chicken (Gallus gallus).

Project description:The surficial cycling of Mg is coupled with the global carbon cycle, a predominant control of Earth's climate. However, how Earth's surficial Mg cycle evolved with time has been elusive. Magnesium isotope signatures of seawater (δ26Mgsw) track the surficial Mg cycle, which could provide crucial information on the carbon cycle in Earth's history. Here, we present a reconstruction of δ26Mgsw evolution over the past 2 billion years using marine halite fluid inclusions and sedimentary dolostones. The data show that δ26Mgsw decreased, with fluctuations, by about 1.4‰ from the Paleoproterozoic to the present time. Mass balance calculations based on this δ26Mgsw record reveal a long-term decline in net dolostone burial (NDB) over the past 2 billion years, due to the decrease in dolomitization in the oceans and the increase in dolostone weathering on the continents. This underlines a previously underappreciated connection between the weathering-burial cycle of dolostone and the Earth's climate on geologic timescales.

Project description: Not available