Omnipresent Maxwell’s demons orchestrate information management in living cells

The development of synthetic biology calls for accurate understanding of the critical functions that allow construction and operation of a living cell. Besides coding for ubiquitous structures, minimal genomes encode a wealth of functions that dissipate energy in an unanticipated way. Analysis of these functions shows that they are meant to manage information under conditions when discrimination of substrates in a noisy background is preferred over a simple recognition process. We show here that many of these functions, including transporters and the ribosome construction machinery, behave as would behave a material implementation of the informationmanaging agent theorized by Maxwell almost 150 years ago and commonly known as Maxwell’s demon (MxD). A core gene set encoding these functions belongs to the minimal genome required to allow the construction of an autonomous cell. These MxDs allow the cell to perform computations in an energy-efficient way that is vastly better than our contemporary computers

How 'arm-twisting' by the inducer triggers activation of the MalT transcription factor, a typical signal transduction ATPase with numerous domains (STAND)

International audienceSignal transduction ATPases with numerous domains (STAND) get activated through inducer-dependent assembly into multimeric platforms. This switch relies on the conversion of their nucleotide-binding oligomerization domain (NOD) from a closed, ADP-bound form to an open, ATP-bound form. The NOD closed form is stabilized by contacts with the arm, a domain that connects the NOD to the inducer-binding domain called the sensor. How the inducer triggers NOD opening remains unclear. Here, I pinpointed the NOD-arm interface of the MalT STAND transcription factor, and I generated a MalT variant in which this interface can be covalently locked on demand , thereby trapping the NOD in the closed state. By characterizing this locked variant, I found that the inducer is recognized in two steps: it first binds to the sole sensor with low affinity, which then triggers the recruitment of the arm to form a high-affinity arm-sensor inducer-binding site. Strikingly, this high-affinity binding step was incompatible with arm-NOD contacts maintaining the NOD closed. Through this toggling between two mutually exclusive states reminiscent of a single-pole double-throw switch, the arm couples inducer binding to NOD opening, shown here to precede nucleotide exchange. This scenario likely holds for other STANDs like mammalian NLR innate immunity receptors

The inducer maltotriose binds in the central cavity of the tetratricopeptide-like sensor domain of MalT, a bacterial STAND transcription factor

International audienceSignal transduction ATPases with numerous domains (STAND) are sophisticated proteins that integrate several signals and respond by building multimeric platforms allowing signaling in various processes: apoptosis, innate immunity, bacterial metabolism. They comprise a conserved nucleotide oligomerization domain (NOD), which functions as a binary switch that oscillates between the OFF (ADP-bound) and the ON (ATP-bound) conformation, and non conserved sensor and effector domains. Transition from the OFF form to the ON form strictly depends on the binding of an inducer to the sensor domain. The interaction of the inducer with this domain was studied in MalT, a model STAND protein. MalT sensor domain has a SUPR (superhelical repeats) fold resembling a cylinder with a central cavity. The cavity was subjected to an alanine-scanning approach, and the effects of the alanine substitutions on inducer binding and transcription activation were analyzed. This work unambiguously showed that the inducer maltotriose binds inside the cavity, and a patch on the inner surface was proposed to be the primary maltotriose binding-site. Furthermore, limited proteolysis suggested that maltotriose binding changes the conformation of the sensor domain

Two domains of MalT, the activator of the Escherichia coli maltose regulon, bear determinants essential for anti-activation by MalK

International audienceMalT, the dedicated transcriptional activator of the maltose regulon in Escherichia coli, is subject to multiple controls. Maltotriose, the inducer, promotes MalT self-association, a critical step in promoter binding, whereas three proteins acting as negative allosteric effectors (MalK, the ABC-component of the maltodextrin transporter, MalY, and Aes) antagonize maltotriose binding. All of these regulatory signals are integrated by a novel signal transduction module that comprises three out of the four MalT structural domains: DT1, the ATP-binding domain that contains determinants recognized by the negative effectors, DT2, and DT3, the maltotriose-binding domain. For a better insight into the role of DT3 in signal integration, we PCR mutagenized the DT3-encoding region and screened for gain of function mutations in a malK+ strain in the absence of repression by MalY or Aes. Most of the mutations isolated alter one of seven residues that are located in DT3 helices 10 and 11, or in the turn between them and delineate a surface-exposed motif. In vivo and in vitro analyses revealed that the substitutions altering the so-called H10/H11 motif do not affect the ability of MalT to activate transcription or its sensitivity to MalY and Aes, but dramatically decrease its sensitivity to MalK. We propose that MalT/MalK interaction might involve two distinct contact sites on each partner. These sites would be located in DT1 and DT3 of MalT, and in the nucleotide-binding domain and the regulatory domain of MalK. Such a two-point interaction model would explain how the regulatory activity of MalK might be coupled to transport

Omnipresent Maxwell's demons orchestrate information management in living cells

International audienceThe development of synthetic biology calls for accurate understanding of the critical functions that allow construction and operation of a living cell. Besides coding for ubiquitous structures, minimal genomes encode a wealth of functions that dissipate energy in an unanticipated way. Analysis of these functions shows that they are meant to manage information under conditions when discrimination of substrates in a noisy background is preferred over a simple recognition process. We show here that many of these functions, including transporters and the ribo-some construction machinery, behave as would behave a material implementation of the information-managing agent theorized by Maxwell almost 150 years ago and commonly known as Maxwell's demon (MxD). A core gene set encoding these functions belongs to the minimal genome required to allow the construction of an autonomous cell. These MxDs allow the cell to perform computations in an energy-efficient way that is vastly better than our contemporary computers

Omnipresent Maxwell's demons orchestrate information management in living cells

© 2019 The Authors.The development of synthetic biology calls for accurate understanding of the critical functions that allow construction and operation of a living cell. Besides coding for ubiquitous structures, minimal genomes encode a wealth of functions that dissipate energy in an unanticipated way. Analysis of these functions shows that they are meant to manage information under conditions when discrimination of substrates in a noisy background is preferred over a simple recognition process. We show here that many of these functions, including transporters and the ribosome construction machinery, behave as would behave a material implementation of the information‐managing agent theorized by Maxwell almost 150 years ago and commonly known as Maxwell's demon (MxD). A core gene set encoding these functions belongs to the minimal genome required to allow the construction of an autonomous cell. These MxDs allow the cell to perform computations in an energy‐efficient way that is vastly better than our contemporary computers.This work was supported by the Fondation Fourmentin-Guilbert support of the Stanislas Noria network

The N Terminus of the Escherichia coli Transcription Activator MalT Is the Domain of Interaction with MalY

The maltose system of Escherichia coli consists of a number of genes encoding proteins involved in the uptake and metabolism of maltose and maltodextrins. The system is positively regulated by MalT, its transcriptional activator. MalT activity is controlled by two regulatory circuits: a positive one with maltotriose as effector and a negative one involving several proteins. MalK, the ATP-hydrolyzing subunit of the cognate ABC transporter, MalY, an enzyme with the activity of a cystathionase, and Aes, an acetyl esterase, phenotypically act as repressors of MalT activity. By in vivo titration assays, we have shown that the N-terminal 250 amino acids of MalT contain the interaction site for MalY but not for MalK. This was confirmed by gel filtration analysis, where MalY was shown to coelute with the N-terminal MalT structural domain. Mutants in MalT causing elevated mal gene expression in the absence of exogenous maltodextrins were tested in their response to the three repressors. The different MalT mutations exhibited a various degree of sensitivity towards these repressors, but none was resistant to all of them. Some of them became nearly completely resistant to Aes while still being sensitive to MalY. These mutations are located at positions 38, 220, 243, and 359, most likely defining the interaction patch with Aes on the three-dimensional structure of MalT