A central problem in biology is determining how genes interact as parts of functional networks. Creation and analysis of synthetic networks, composed of well-characterized genetic elements, provide a framework for theoretical modeling. Here, with the use of a combinatorial method, a library of networks with varying connectivity was generated in Escherichia coli. These networks were composed of genes encoding the transcriptional regulators LacI, TetR, and lambda CI, as well as the corresponding promoters. They displayed phenotypic behaviors resembling binary logical circuits, with two chemical "inputs" and a fluorescent protein "output." Within this simple system, diverse computational functions arose through changes in network connectivity. Combinatorial synthesis provides an alternative approach for studying biological networks, as well as an efficient method for producing diverse phenotypes in vivo.
In Escherichia coli, levels of the two major outer membrane porin proteins, OmpF and OmpC, are regulated in response to a variety of environmental parameters, and numerous factors have been shown to influence porin synthesis. EnvZ and OmpR control porin-gene transcription in response to osmolarity, and the antisense RNA, MicF, influences ompF translation. In contrast to these characterized factors, some of the components reported to influence porin expression have only modest effects and/or act indirectly. For others, potential regulatory roles, although intriguing, remain elusive. Here we review many of the components that have been reported to influence porin expression, address the potential regulatory nature of these components, and discuss how they may contribute to a regulatory network controlling porin synthesis.
Circadian oscillators, which provide internal daily periodicity, are found in a variety of living organisms, including mammals, insects, plants, fungi and cyanobacteria. Remarkably, these biochemical oscillators are resilient to external and internal modifications, such as temperature and cell division cycles. They have to be 'fluctuation (noise) resistant' because relative fluctuations in the number of messenger RNA and protein molecules forming the intracellular oscillators are likely to be large. In multicellular organisms, the strong temporal stability of circadian clocks, despite molecular fluctuations, can easily be explained by intercellular interactions. Here we study circadian rhythms and their stability in unicellular cyanobacteria Synechoccocus elongatus. Low-light-level microscopy has allowed us to measure gene expression under circadian control in single bacteria, showing that the circadian clock is indeed a property of individual cells. Our measurements show that the oscillators have a strong temporal stability with a correlation time of several months. In contrast to many circadian clocks in multicellular organisms, this stability seems to be ensured by the intracellular biochemical network, because the interactions between oscillators seem to be negligible.
EnvZ and OmpR are the sensor and response regulator proteins of a two-component system that controls the porin regulon of Escherichia coli in response to osmolarity. Three enzymatic activities are associated with EnvZ: autokinase, OmpR kinase, and OmpR-phosphate (OmpR-P) phosphatase. Conserved histidine-243 is critical for both autokinase and OmpR kinase activities. To investigate its involvement in OmpR-P phosphatase activity, histidine-243 was mutated to several other amino acids and the phosphatase activity of mutated EnvZ was measured both in vivo and in vitro. In agreement with previous reports, we found that certain substitutions abolished the phosphatase activity of EnvZ. However, a significant level of phosphatase activity remained when histidine-243 was replaced with certain amino acids, such as tyrosine. In addition, the phosphatase activity of a previously identified kinase ؊ phosphatase ؉ mutant was not abolished by the replacement of histidine-243 with asparagine. These data indicated that although conserved histidine-243 is important for the phosphatase activity, a histidine-243-P intermediate is not required. Our data are consistent with a previous model that proposes a common transition state with histidine-243 (EnvZ) in close contact with aspartate-55 (OmpR) for both OmpR phosphorylation and dephosphorylation. Phosphotransfer occurs from histidine-243-P to aspartate-55 during phosphorylation, but water replaces the phosphorylated histidine side chain leading to hydrolysis during dephosphorylation.Escherichia coli has two major porin proteins, OmpF and OmpC, which serve as channels for the passive diffusion of small, hydrophilic molecules through the outer membrane. The expression of ompF and ompC is regulated by a variety of environmental factors, including osmolarity, temperature, redox potential, and nutrient availability (for a recent review, see reference 32). Numerous studies demonstrate that a two-component system, including the sensor kinase EnvZ and the response regulator OmpR, mediates porin gene transcription in response to changes in osmolarity (for reviews, see references 4, 28, and 31).EnvZ belongs to a large family of two-component sensor kinases. It is an integral membrane protein that has all of the conserved motifs common to this family: H, N, G1, D/F, and G2 boxes (30). Three enzymatic activities have been shown to be associated with the carboxy-terminal cytoplasmic domain of EnvZ: autokinase, OmpR kinase, and OmpR-phosphate (OmpR-P) phosphatase. At high osmolarity, EnvZ functions as an OmpR kinase, and the resulting high level of OmpR-P activates ompC transcription and represses ompF transcription. In contrast, at low osmolarity, EnvZ functions as an OmpR-P phosphatase, and the resulting low level of OmpR-P activates ompF only. Thus, OmpC is abundant at high osmolarity, and OmpF predominates at low osmolarity (31).Most (if not all) of the two-component regulatory systems exhibit the same three biochemical activities outlined above for EnvZ (30). The mechanism for protein phosp...
EnvZ, a membrane receptor kinase-phosphatase, modulates porin expression in Escherichia coli in response to medium osmolarity. It shares its basic scheme of signal transduction with many other sensor-kinases, passing information from the amino-terminal, periplasmic, sensory domain via the transmembrane helices to the carboxy-terminal, cytoplasmic, catalytic domain. The native receptor can exist in two active but opposed signaling states, the OmpR kinase-dominant state (K+ P−) and the OmpR-P phosphatase-dominant state (K− P+). The balance between the two states determines the level of intracellular OmpR-P, which in turn determines the level of porin gene transcription. To study the structural requirements for these two states of EnvZ, mutational analysis was performed. Mutations that preferentially affect either the kinase or phosphatase have been identified and characterized both in vivo and in vitro. Most of these mapped to previously identified structural motifs, suggesting an important function for each of these conserved regions. In addition, we identified a novel motif that is weakly conserved among two-component sensors. Mutations that alter this motif, which is termed the X region, alter the confirmation of EnvZ and significantly reduce the phosphatase activity.
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