Replication of DNA-encoded information and its conversion into functional proteins are universal properties of life. In an effort toward the construction of a synthetic minimal cell, we implement here the DNA replication machinery of the Φ29 virus in a cell-free gene expression system. Amplification of a linear DNA template by self-encoded, de novo synthesized Φ29 proteins is demonstrated. Complete information transfer is confirmed as the copied DNA can serve as a functional template for gene expression, which can be seen as an autocatalytic DNA replication cycle. These results show how the central dogma of molecular biology can be reconstituted and form a cycle in vitro. Finally, coupled DNA replication and gene expression is compartmentalized inside phospholipid vesicles providing the chassis for evolving functions in a prospective synthetic cell relying on the extant biology.
The goal of bottom-up synthetic biology culminates in the assembly of an entire cell from separate biological building blocks. One major challenge resides in the in vitro production and implementation of complex genetic and metabolic pathways that can support essential cellular functions. Here, we show that phospholipid biosynthesis, a multiple-step process involved in cell membrane homeostasis, can be reconstituted starting from the genes encoding for all necessary proteins. A total of eight E. coli enzymes for acyl transfer and headgroup modifications were produced in a cell-free gene expression system and were co-translationally reconstituted in liposomes. Acyl-coenzyme A and glycerol-3-phosphate were used as canonical precursors to generate a variety of important bacterial lipids. Moreover, this study demonstrates that two-step acyl transfer can occur from enzymes synthesized inside vesicles. Besides clear implications for growth and potentially division of a synthetic cell, we postulate that gene-based lipid biosynthesis can become instrumental for ex vivo and protein purification-free production of natural and non-natural lipids.
Bacteria deficient in the DNA-binding protein from starved cells (Dps) are viable under controlled conditions but show dramatically increased mortality rates when exposed to any of a wide range of stresses, including starvation, oxidative stress, metal toxicity, or thermal stress. It remains unclear whether the protective action of Dps against specific stresses derives from its DNAbinding activity, which may exclude destructive agents from the chromosomal region, or its ferroxidase activity, which neutralizes and sequesters potentially damaging chemical species. To resolve this question, we have identified the critical residues of Escherichia coli Dps that bind to DNA and modulate iron oxidation. We uncoupled the biochemical activities of Dps, creating Dps variants and mutant E. coli strains that are defective in either DNA-binding or ferroxidase activity. Quantification of the contribution of each activity to the protection of DNA integrity and cellular viability revealed that both activities of Dps are required in order to counteract many differing stresses. These findings demonstrate that Dps plays a multipurpose role in stress protection via its dual activities, explaining how Dps can be of vital importance to bacterial viability over a wide range of stresses. IMPORTANCEThe DNA-binding protein from starved cells (Dps) protects bacterial cells against many different types of stressors. We find that DNA binding and iron oxidation by Dps are performed completely independently of each other. Both biochemical activities are required to protect E. coli against stressors, as well as to protect DNA from oxidative damage in vitro. These results suggest that many stressors may cause both oxidative stress and direct DNA damage.T he ability to adapt to changes in the environment is one of the key determinants of the fitness of a species. Bacteria have evolved a multitude of ways to survive and prosper under stressful conditions, ranging from extreme measures such as sporulation to the expression of specialized stress mediation proteins (1-3). One such protein vital in stress survival is the DNA-binding protein from starved cells (Dps) (4), which is conserved to a remarkable degree in more than 300 bacterial species (5). In Escherichia coli, Dps acts as a component of several stress response pathways; it can be independently upregulated as a member of the OxyR regulon in exponentially growing cells or via S in stationary-phase cells (6). The presence of Dps enhances bacterial survival of many different stresses, including starvation, heat shock, oxidative stress, and overexposure to iron (7,8). These protective effects of Dps expression are presumably due to one or both of its dual biochemical functions, DNA binding and ferroxidase activity (9), but the molecular mechanisms and physiological consequences of these activities are not yet fully elucidated.E. coli Dps binds to DNA in vitro with no apparent sequence specificity, forming a highly stable complex (7, 10). Dps is a minor component of the E. coli nucleoid ...
The compartmentalization of a cell-free gene expression system inside a self-assembled lipid vesicle is envisioned as the simplest chassis for the construction of a minimal cell. Although crucial for its realization, quantitative understanding of the dynamics of gene expression in bulk and liposome-confined reactions is scarce. Here, we used two orthogonal fluorescence labeling tools to report the amounts of mRNA and protein produced in a reconstituted biosynthesis system, simultaneously and in real-time. The Spinach RNA aptamer and its fluorogenic probe were used for mRNA detection. Applying this dual-reporter assay to the analysis of transcript and protein production inside lipid vesicles revealed that their levels are uncorrelated, most probably a consequence of the low copy-number of some components in liposome-confined reactions. We believe that the stochastic nature of gene expression should be appreciated as a design principle for the assembly of a minimal cell.
Curved DNA binding protein A (CbpA) is a co-chaperone and nucleoid associated DNA binding protein conserved in most γ-proteobacteria. Best studied in Escherichia coli, CbpA accumulates to >2500 copies per cell during periods of starvation and forms aggregates with DNA. However, the molecular basis for DNA binding is unknown; CbpA lacks motifs found in other bacterial DNA binding proteins. Here, we have used a combination of genetics and biochemistry to elucidate the mechanism of DNA recognition by CbpA. We show that CbpA interacts with the DNA minor groove. This interaction requires a highly conserved arginine side chain. Substitution of this residue, R116, with alanine, specifically disrupts DNA binding by CbpA, and its homologues from other bacteria, whilst not affecting other CbpA activities. The intracellular distribution of CbpA alters dramatically when DNA binding is negated. Hence, we provide a direct link between DNA binding and the behaviour of CbpA in cells.
Oxidative stress is an unavoidable byproduct of aerobic life. Molecular oxygen is essential for terrestrial metabolism, but it also takes part in many damaging reactions within living organisms. The combination of aerobic metabolism and iron, which is another vital compound for life, is enough to produce radicals through Fenton chemistry and degrade cellular components. DNA degradation is arguably the most damaging process involving intracellular radicals, as DNA repair is far from trivial. The assay presented in this article offers a quantitative technique to measure and visualize the effect of molecules and enzymes on radical-mediated DNA damage. The DNA protection assay is a simple, quick, and robust tool for the in vitro characterization of the protective properties of proteins or chemicals. It involves exposing DNA to a damaging oxidative reaction and adding varying concentrations of the compound of interest. The reduction or increase of DNA damage as a function of compound concentration is then visualized using gel electrophoresis. In this article we demonstrate the technique of the DNA protection assay by measuring the protective properties of the DNA-binding protein from starved cells (Dps). Dps is a mini-ferritin that is utilized by more than 300 bacterial species to powerfully combat environmental stressors. Here we present the Dps purification protocol and the optimized assay conditions for evaluating DNA protection by Dps.
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