Itaru Urabe scite author profile

Cells switch between various stable genetic programs (attractors) to accommodate environmental conditions. Signal transduction machineries efficiently convey environmental changes to the gene regulation apparatus in order to express the appropriate genetic program. However, since the number of environmental conditions is much larger than that of available genetic programs so that the cell may utilize the same genetic program for a large set of conditions, it may not have evolved a signaling pathway for every environmental condition, notably those that are rarely encountered. Here we show that in the absence of signal transduction, switching to the appropriate attractor state expressing the genes that afford adaptation to the external condition can occur. In a synthetic bistable gene switch in Escherichia coli in which mutually inhibitory operons govern the expression of two genes required in two alternative nutritional environments, cells reliably selected the “adaptive attractor” driven by gene expression noise. A mathematical model suggests that the “non-adaptive attractor” is avoided because in unfavorable conditions, cellular activity is lower, which suppresses mRNA metabolism, leading to larger fluctuations in gene expression. This, in turn, renders the non-adaptive state less stable. Although attractor selection is not as efficient as signal transduction via a dedicated cascade, it is simple and robust, and may represent a primordial mechanism for adaptive responses that preceded the evolution of signaling cascades for the frequently encountered environmental changes.

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Expression of a cascading genetic network within liposomes

Ishikawa

et al. 2004

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Liposomes have long been used as possible compartments for artificial cells, and it has been shown that liposomes can sustain various types of biochemical reactions. To elevate the degree of molecular complexity of the system in liposomes, we have constructed a two-stage genetic network encapsulated in liposomes. This two-stage genetic network was constructed with the plasmid pTH, in which the protein product of the first stage (T7 RNA polymerase) is required to drive the protein synthesis of the second stage (GFP). We show that the two-stage genetic network constructed in a cell-free expression system is functional within liposomes.

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Protein folding by the effects of macromolecular crowding

et al. 2004

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Unfolded states of ribonuclease A were used to investigate the effects of macromolecular crowding on macromolecular compactness and protein folding. The extent of protein folding and compactness were measured by circular dichroism spectroscopy, fluorescence correlation spectroscopy, and NMR spectroscopy in the presence of polyethylene glycol (PEG) or Ficoll as the crowding agent. The unfolded state of RNase A in a 2.4 M urea solution at pH 3.0 became native in conformation and compactness by the addition of 35% PEG 20000 or Ficoll 70. In addition, the effects of macromolecular crowding on inert macromolecule compactness were investigated by fluorescence correlation spectroscopy using Fluorescence-labeled PEG as a test macromolecule. The size of Fluorescence-labeled PEG decreased remarkably with an increase in the concentration of PEG 20000 or Ficoll 70. These results show that macromolecules are favored compact conformations in the presence of a high concentration of macromolecules and indicate the importance of a crowded environment for the folding and stabilization of globular proteins. Furthermore, the magnitude of the effects on macromolecular crowding by the different sizes of background molecules was investigated. RNase A and Fluorescence-labeled PEG did not become compact, and had folded conformation by the addition of PEG 200. The effect of the chemical potential on the compaction of a test molecule in relation to the relative sizes of the test and background molecules is also discussed.

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Replication of Genetic Information with Self‐Encoded Replicase in Liposomes

et al. 2008

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In all living systems, the genome is replicated by proteins that are encoded within the genome itself. This universal reaction is essential to allow the system to evolve. Here, we have constructed a simplified system involving encapsulated macromolecules termed a "self-encoding system", in which the genetic information is replicated by self-encoded replicase in liposomes. That is, the universal reaction was reconstituted within a microcompartment bound by a lipid bilayer. The system was assembled by using one template RNA sequence as the information molecule and an in vitro translation system reconstituted from purified translation factors as the machinery for decoding the information. In this system, the catalytic subunit of Qbeta replicase is synthesized from the template RNA that encodes the protein. The replicase then replicates the template RNA that was used for its production. This in-liposome self-encoding system is one of the simplest such systems available; it consists of only 144 gene products, while the information and the function for its replication are encoded on different molecules and are compartmentalized into the microenvironment for evolvability.

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Femtoliter compartment in liposomes for in vitro selection of proteins

Sunami

Sato

Matsuura

et al. 2006

Analytical Biochemistry

109

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Itaru Urabe

Adaptive Response of a Gene Network to Environmental Changes by Fitness-Induced Attractor Selection

Expression of a cascading genetic network within liposomes

Protein folding by the effects of macromolecular crowding

Replication of Genetic Information with Self‐Encoded Replicase in Liposomes

Femtoliter compartment in liposomes for in vitro selection of proteins

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