Ethylene-producing bacteria that ripen fruit.

Ethylene is a plant hormone widely used to ripen fruit. However, the synthesis, handling, and storage of ethylene are environmentally harmful and dangerous. We engineered E. coli to produce ethylene through the activity of the ethylene-forming enzyme (EFE) from Pseudomonas syringae. EFE converts a citric acid cycle intermediate, 2-oxoglutarate, to ethylene in a single step. The production of ethylene was placed under the control of arabinose and blue light responsive regulatory systems. The resulting bacteria were capable of accelerating the ripening of tomatoes, kiwifruit, and apples.

Integrating artificial with natural cells to translate chemical messages that direct E. coli behaviour.

Previous efforts to control cellular behaviour have largely relied upon various forms of genetic engineering. Once the genetic content of a living cell is modified, the behaviour of that cell typically changes as well. However, other methods of cellular control are possible. All cells sense and respond to their environment. Therefore, artificial, non-living cellular mimics could be engineered to activate or repress already existing natural sensory pathways of living cells through chemical communication. Here we describe the construction of such a system. The artificial cells expand the senses of Escherichia coli by translating a chemical message that E. coli cannot sense on its own to a molecule that activates a natural cellular response. This methodology could open new opportunities in engineering cellular behaviour without exploiting genetically modified organisms.

Fluorescent proteins and in vitro genetic organization for cell-free synthetic biology.

To facilitate the construction of cell-free genetic devices, we evaluated the ability of 17 different fluorescent proteins to give easily detectable fluorescence signals in real-time from in vitro transcription-translation reactions with a minimal system consisting of T7 RNA polymerase and E. coli translation machinery, i.e., the PUREsystem. The data were used to construct a ratiometric fluorescence assay to quantify the effect of genetic organization on in vitro expression levels. Synthetic operons with varied spacing and sequence composition between two genes that coded for fluorescent proteins were then assembled. The resulting data indicated which restriction sites and where the restriction sites should be placed in order to build genetic devices in a manner that does not interfere with protein expression. Other simple design rules were identified, such as the spacing and sequence composition influences of regions upstream and downstream of ribosome binding sites and the ability of non-AUG start codons to function in vitro.

Nonreplicating protocells.

Prebiotic soup experiments have shown that the molecular building blocks of life can be built under prebiotically plausible conditions. From this starting point, researchers have launched continued studies of polymerization and explorations of the breadth of RNA function. Recently, effort has intensified to examine experimentally another stage of the origins of life: the assembly of the molecular parts into model protocells intended to represent the first primitive, cell-like systems to emerge on Earth. Although it may not be possible to recreate the precise sequence of events that led to cellular life, laboratory experiments have begun to show what was and was not possible. Prebiotically plausible lipid vesicles form easily and have many properties that are conducive to cellular function. In addition to protecting nascent replicating genetic systems from parasitic sequences, vesicles facilitate evolution. The data thus far suggest that prebiotically plausible vesicles could have grown, divided, and promoted competition between distinct chemical systems. Most protocellular studies to date have probed the role of self-replication, one feature of extant life in the emergence of the first cellular system. Undoubtedly replicating systems were crucial for protocellular evolution, but other features of life must have been important as well. For example, life does not exist in isolation. A living system must cope with and adapt to environmental fluctuations to survive. The protocell must have generated some of these fluctuations because cellular activity necessarily modifies its surroundings by selectively absorbing nutrients and releasing unwanted molecules. It seems likely that life would have faced this challenge early and either emerged in dynamic locales that continuously regenerated conditions conducive to life or exploited mechanisms to physically move to new areas not depleted in resources. Further studies that explore non-replication-based aspects of the origins of life could reveal a more complete picture of the transition from prebiotic chemistry to early life.

Intravesicle isothermal DNA replication.

BACKGROUND: Bacterial and viral DNA replication was previously reconstituted in vitro from component parts 1234. Significant advances in building minimal cell-like structures also have been made recently 567. Combining the two approaches would further attempts to build a minimal cell-like structure capable of undergoing evolution by combining membrane encapsulation and genome replication. Towards this end, we attempted to use purified genomic replication protein components from thermophilic bacterial sources to copy strands of DNA isothermally within lipid vesicles. FINDINGS: Bacterial replication components (such as helicases and DNA polymerases) are compatible with methods for the generation of lipid vesicles. Encapsulation inside phospholipid vesicles does not inhibit the activity of bacterial DNA genome replication machinery. Further the described system is efficient at isothermally amplifying short segments of DNA within phospholipid vesicles. CONCLUSIONS: Herein we show that bacterial isothermal DNA replication machinery is functional inside of phospholipid vesicles, suggesting that replicating cellular mimics can be built from purified bacterial components.

Notch and MAML-1 complexation do not detectably alter the DNA binding specificity of the transcription factor CSL.

BACKGROUND: Canonical Notch signaling is initiated when ligand binding induces proteolytic release of the intracellular part of Notch (ICN) from the cell membrane. ICN then travels into the nucleus where it drives the assembly of a transcriptional activation complex containing the DNA-binding transcription factor CSL, ICN, and a specialized co-activator of the Mastermind family. A consensus DNA binding site motif for the CSL protein was previously defined using selection-based methods, but whether subsequent association of Notch and Mastermind-like proteins affects the DNA binding preferences of CSL has not previously been examined. PRINCIPAL FINDINGS: Here, we utilized protein-binding microarrays (PBMs) to compare the binding site preferences of isolated CSL with the preferred binding sites of CSL when bound to the CSL-binding domains of all four different human Notch receptors. Measurements were taken both in the absence and in the presence of Mastermind-like-1 (MAML1). Our data show no detectable difference in the DNA binding site preferences of CSL before and after loading of Notch and MAML1 proteins. CONCLUSIONS/SIGNIFICANCE: These findings support the conclusion that accrual of Notch and MAML1 promote transcriptional activation without dramatically altering the preferred sites of DNA binding, and illustrate the potential of PBMs to analyze the binding site preferences of multiprotein-DNA complexes.

Direct inhibition of the NOTCH transcription factor complex.

Direct inhibition of transcription factor complexes remains a central challenge in the discipline of ligand discovery. In general, these proteins lack surface involutions suitable for high-affinity binding by small molecules. Here we report the design of synthetic, cell-permeable, stabilized alpha-helical peptides that target a critical protein-protein interface in the NOTCH transactivation complex. We demonstrate that direct, high-affinity binding of the hydrocarbon-stapled peptide SAHM1 prevents assembly of the active transcriptional complex. Inappropriate NOTCH activation is directly implicated in the pathogenesis of several disease states, including T-cell acute lymphoblastic leukaemia (T-ALL). The treatment of leukaemic cells with SAHM1 results in genome-wide suppression of NOTCH-activated genes. Direct antagonism of the NOTCH transcriptional program causes potent, NOTCH-specific anti-proliferative effects in cultured cells and in a mouse model of NOTCH1-driven T-ALL.

Mutational and energetic studies of Notch 1 transcription complexes.

Notch proteins constitute the receptors of a highly conserved signaling pathway that influences cell fate decisions both during development and in adulthood. A proteolytic cascade induced by ligand stimulation results in release of the intracellular Notch domain from the cell membrane, allowing it to enter the nucleus and form a complex with a DNA-bound transcription factor called CSL (CBF-1/RBP-J kappa, Suppressor of Hairless, and Lag-1) and a coactivator of the Mastermind family. Assembly of this Notch nuclear complex is the key step in the transcriptional response to a Notch signal. In the studies reported here, we mapped residues important for the stabilization of this multiprotein-DNA complex using site-directed mutagenesis, determined the affinity of the three-domain form of CSL for its various partners, and investigated sources of cooperativity in complex formation by monitoring the influence of various components of the complex on the interactions of CSL with its other partners. Our findings are consistent with a model for complex assembly in which the RBP-J kappa-associated molecule domain of Notch increases the effective concentration of the ankyrin domain for its binding site on the Rel-homology region of CSL, enabling docking of the ankyrin domain and subsequent recruitment of the Mastermind-like coactivator.

Notch directly regulates Gata3 expression during T helper 2 cell differentiation.

Notch signaling plays multiple roles to direct diverse decisions regarding cell fate during T cell development. During helper T (Th) cell differentiation, Notch is involved in generating optimal Th2 cell responses. Here, we present data investigating how Notch mediates Th2 cell differentiation. Notch showed a CD4(+) T cell intrinsic role in promoting IL-4 expression that required GATA-3. In the absence of Notch signals, Gata3 expression was markedly diminished. Introduction of an activated allele of Notch1 into CD4(+) T cells led to the specific and direct upregulation of a developmentally regulated Gata3 transcript that included the exon 1a sequences. Furthermore, Notch acted in parallel with GATA-3 to synergistically activate IL-4 expression. Together, these data implicate Gata3 as a direct transcriptional Notch target that acts in concert with Notch signaling to generate optimal Th2 cell responses.

Coordination of three and four Cu(I) to the alpha- and beta-domain of vertebrate Zn-metallothionein-1, respectively, induces significant structural changes.

Vertebrate metallothioneins are found to contain Zn(II) and variable amounts of Cu(I), in vivo, and are believed to be important for d10-metal control. To date, structural information is available for the Zn(II) and Cd(II) forms, but not for the Cu(I) or mixed metal forms. Cu(I) binding to metallothionein-1 has been investigated by circular dichroism, luminescence and 1H NMR using two synthetic fragments representing the alpha- and the beta-domain. The 1H NMR data and thus the structures of Zn4alpha metallothionein (MT)-1 and Zn3betaMT-1 were essentially the same as those already published for the corresponding domains of native Cd7MT-1. Cu(I) titration of the Zn(II)-reconstituted domains provided clear evidence of stable polypeptide folds of the three Cu(I)-containing alpha- and the four Cu(I)-containing beta-domains. The solution structures of these two species are grossly different from the structures of the starting Zn(II) complexes. Further addition of Cu(I) to the two single domains led to the loss of defined domain structures. Upon mixing of the separately prepared aqueous three and four Cu(I) loaded alpha- and beta-domains, no interaction was seen between the two species. There was neither any indication for a net transfer of Cu(I) between the two domains nor for the formation of one large single Cu(I) cluster involving both domains.

c-Myc is an important direct target of Notch1 in T-cell acute lymphoblastic leukemia/lymphoma.

Human acute T-cell lymphoblastic leukemias and lymphomas (T-ALL) are commonly associated with gain-of-function mutations in Notch1 that contribute to T-ALL induction and maintenance. Starting from an expression-profiling screen, we identified c-myc as a direct target of Notch1 in Notch-dependent T-ALL cell lines, in which Notch accounts for the majority of c-myc expression. In functional assays, inhibitors of c-myc interfere with the progrowth effects of activated Notch1, and enforced expression of c-myc rescues multiple Notch1-dependent T-ALL cell lines from Notch withdrawal. The existence of a Notch1-c-myc signaling axis was bolstered further by experiments using c-myc-dependent murine T-ALL cells, which are rescued from withdrawal of c-myc by retroviral transduction of activated Notch1. This Notch1-mediated rescue is associated with the up-regulation of endogenous murine c-myc and its downstream transcriptional targets, and the acquisition of sensitivity to Notch pathway inhibitors. Additionally, we show that primary murine thymocytes at the DN3 stage of development depend on ligand-induced Notch signaling to maintain c-myc expression. Together, these data implicate c-myc as a developmentally regulated direct downstream target of Notch1 that contributes to the growth of T-ALL cells.

The crystal structure of yeast copper thionein: the solution of a long-lasting enigma.

We report here the crystal structure of yeast copper thionein (Cu-MT), determined at 1.44-A resolution. The Cu-MT structure shows the largest known oligonuclear Cu(I) thiolate cluster in biology, consisting of six trigonally and two digonally coordinated Cu(I) ions. This is at variance with the results from previous spectroscopic determinations, which were performed on MT samples containing seven rather than eight metal ions. The protein backbone has a random coil structure with the loops enfolding the copper cluster, which is located in a cleft where it is bound to 10 cysteine residues. The protein structure is somewhat different from that of Ag(7)-MT and similar, but not identical, to that of Cu(7)-MT. Besides the different structure of the metal cluster, the main differences lie in the cysteine topology and in the conformation of some portions of the backbone. The present structure suggests that Cu-MT, in addition to its role as a safe depository for copper ions in the cell, may play an active role in the delivery of copper to metal-free chaperones.

Solution structure of human beta-parvalbumin and structural comparison with its paralog alpha-parvalbumin and with their rat orthologs.

The aim of this research was to determine the structure of human beta-parvalbumin (109 amino acids) and to compare it with its paralog and ortholog proteins. The structure was determined in solution using multinuclear and multidimensional NMR methods and refined using substitution of the EF-hand Ca(2+) ion with a paramagnetic lanthanide. The resulting family of structures had a backbone rmsd of 0.50 A. Comparison with rat oncomodulin (X-ray, 1.3 A resolution) as well as with human (NMR, backbone rmsd of 0.49 A) and rat (X-ray, 2.0 A resolution) parvalbumins reveals small but reliable local differences, often but not always related to amino acid variability. The analysis of these structures has led us to propose an explanation for the different affinity for Ca(2+) between alpha- and beta-parvalbumins and between parvalbumins and calmodulins.

Energetics and mechanism of Ca2+ displacement by lanthanides in a calcium binding protein.

The displacement of Ca(2+) by trivalent lanthanide ions (Tm(3+)) in a protozoan (Entamoeba histolytica) Ca(2+) binding protein has been studied by NMR and isothermal calorimetry (ITC). The study provides a basis for understanding the behavior of lanthanides when used as a substitute for Ca(2+), the pattern of sequential binding, the structural changes involved, the range and magnitude of paramagnetic interaction, and the associated energetics and mechanism. The progressive Ca(2+) displacement from site III first, followed by displacement from site II, I, and IV, as observed during the NMR titration experiments, is interpreted in the light of ITC data to provide a deeper insight into the intradomain and, for the first time, interdomain cooperativity and information about the statistical phenomenon involved in it. A theoretical model governing Ca(2+) displacement is provided. The small structural changes involved in Ca(2+) displacement by a diamagnetic lanthanide (La(3+)) has also been monitored.

Paramagnetism-based refinement strategy for the solution structure of human alpha-parvalbumin.

In the frame of a research aimed at the detailed structural characterization of human calcium-binding proteins of the EF-hand family, the solution structure of human alpha-parvalbumin has been solved by NMR and refined with the help of substitution of the Ca(2+) ion in the EF site with the paramagnetic Dy(3+) ion. A simple (1)H-(15)N HSQC spectrum allowed the NH assignments based on the properties of Dy(3+). This allowed us to exploit pseudocontact shifts and residual dipolar couplings for solution structure refinement. The backbone and heavy atom RMSD are 0.55 +/- 0.08 and 1.02 +/- 0.08 A, respectively, and decrease to 0.39 +/- 0.05 and 0.90 +/- 0.06 A upon refinement with paramagnetism-based restraints. The RMSD for the metal itself in the EF site in the refined structure is 0.26 +/- 0.12 A. Backbone NH R(1), R(2), and NOE measured at two temperatures show the protein to be relatively rigid. The NH orientations are well determined by the paramagnetism-based restraints. This allows us to detect small but significant local structural differences with the orthologue protein from rat, whose X-ray structure is available at 2.0 A resolution. All differences are related to local changes in the amino acidic composition.

Experimentally exploring the conformational space sampled by domain reorientation in calmodulin.

The conformational space sampled by the two-domain protein calmodulin has been explored by an approach based on four sets of NMR observables obtained on Tb(3+)- and Tm(3+)-substituted proteins. The observables are the pseudocontact shifts and residual dipolar couplings of the C-terminal domain when lanthanide substitution is at the N-terminal domain. Each set of observables provides independent information on the conformations experienced by the molecule. It is found that not all sterically allowed conformations are equally populated. Taking the N-terminal domain as the reference, the C-terminal domain preferentially resides in a region of space inscribed in a wide elliptical cone. The axis of the cone is tilted by approximately 30 degrees with respect to the direction of the N-terminal part of the interdomain helix, which is known to have a flexible central part in solution. The C-terminal domain also undergoes rotation about the axis defined by the C-terminal part of the interdomain helix. Neither the extended helix conformation initially observed in the solid state for free calcium calmodulin nor the closed conformation(s) adopted by calcium calmodulin either alone or in its adduct(s) with target peptide(s) is among the most preferred ones. These findings are unique, both in terms of structural information obtained on a biomolecule that samples multiple conformations and in terms of the approach developed to achieve the results. The same approach is in principle applicable to other multidomain proteins, as well as to multiple interaction modes between two macromolecular partners.

Thermotoga maritima IscU. Structural characterization and dynamics of a new class of metallochaperone.

Members of the IscU family of proteins are among the most conserved of all protein groups, extending across all three kingdoms of life. IscU serves as a scaffold for the assembly of intermediate iron-sulfur cluster centers and further mediates delivery to apo protein targets. Several proteins that mediate delivery of single metal ions to apo targets (termed metallochaperones) have recently been characterized structurally. Each displays a ferredoxin-like betaalphabetabetaalphabeta motif as a structural core. Assembly and delivery of a polynuclear iron-sulfur cluster is, however, a more complex pathway and presumably would demand a distinctive protein mediator. Here, we demonstrate Thermotoga maritima IscU (Tm IscU) to display unique structural and motional characteristics that distinguish it from other members of this class of proteins. In particular, IscU adopts a mobile, physiologically relevant, molten globule-like state that is vastly different from the previously identified ferredoxin-like fold that has thus far been characterized for other metallochaperones. The secondary structural content of Tm IscU is consistent with previous circular dichroism measurements on apo and holo protein, consisting of six alpha-helices and three beta-strands, the latter forming an anti-parallel beta-sheet. Extensive dynamics studies are consistent with a protein that has reasonably well defined secondary structural elements, but with a tertiary structure that is fluxional among widely different conformational arrangements. Analogous conformational flexibility does not exist in other structurally characterized metallochaperones; however, such a dynamic molecule may account for the lack of long-range NOEs, and allow both for the flexibility that is necessary for the multiple roles of Fe-S cluster assembly, and recognition and delivery of that cluster to a target protein. Additionally, the fluxionality of IscU is unique in that the protein appears to be more compact (based on 1H/2H exchange, R1, R2, and NOE data) but yet more fluid (lack of long-range NOEs) than typical molten globule proteins.

The Cu(I)(7) cluster in yeast copper thionein survives major shortening of the polypeptide backbone as deduced from electronic absorption, circular dichroism, luminescence and( 1)H NMR.

Owing to the frustrating experience of not being able to obtain crystalline yeast Cu(I)(7) -metallothionein, thereby allowing elucidation of the X-ray structure, truncated forms were prepared to facilitate possible crystallization. The mobile remnants at either the N- or C-terminal end of the polypeptide chain were omitted. In parallel with the crystallization efforts, it was of interest to examine the degree to which the shortening of the protein portion might affect the intactness of the Cu(I)(7) -thiolate cluster, thereby hampering their use as structural models for the intact protein. (1)H two-dimensional NMR spectroscopy at 800 MHz was performed on the intact wild-type yeast Cu(7)-thionein and on two truncated forms (peptide(-1-40) and peptide(5-40)). The NMR spectral data reveal, regardless of the length of the polypeptide chain, that the spin patterns were fully preserved with all relevant NOEs. The corresponding calculated structures were virtually identical. All other spectrometric properties, including circular dichroism, luminescence and electronic absorption, allowed the same conclusion. Minor differences were observed in the chiroptic and luminescent measurements. Interestingly, however, the resistance towards oxygen was progressively diminished with decreasing length of the polypeptide backbone. The half-life of the luminescence of the wild-type protein was 48 h while the luminescence of the shortest peptide levelled off within 24 h.