Neutron crystallographic studies of T4 lysozyme at cryogenic temperature

Bacteriophage T4 lysozyme (T4L) has been used as a paradigm for seminal biophysical studies on protein structure, dynamics, and stability. Approximately 700 mutants of this protein and their respective complexes have been characterized by X‐ray crystallography; however, despite the high resolution diffraction limits attained in several studies, no hydrogen atoms were reported being visualized in the electron density maps. To address this, a 2.2 Å‐resolution neutron data set was collected at 80 K from a crystal of perdeuterated T4L pseudo‐wild type. We describe a near complete atomic structure of T4L, which includes the positions of 1737 hydrogen atoms determined by neutron crystallography. The cryogenic neutron model reveals explicit detail of the hydrogen bonding interactions in the protein, in addition to the protonation states of several important residues.     

The transcriptome of Toxoplasma gondii

Background  

Toxoplasma gondii gives rise to toxoplasmosis, among the most prevalent parasitic diseases of animals and man. Transformation of the tachzyoite stage into the latent bradyzoite-cyst form underlies chronic disease and leads to a lifetime risk of recrudescence in individuals whose immune system becomes compromised. Given the importance of tissue cyst formation, there has been intensive focus on the development of methods to study bradyzoite differentiation, although the molecular basis for the developmental switch is still largely unknown.     

Revealing the uncultivated majority: combining DNA stable-isotope probing, multiple displacement amplification and metagenomic analyses of uncultivated Methylocystis in acidic peatlands

Peatlands represent an enormous carbon reservoir and have a potential impact on the global climate because of the active methanogenesis and methanotrophy in these soils. Uncultivated methanotrophs from seven European peatlands were studied using a combination of molecular methods. Screening for methanotroph diversity using a particulate methane monooxygenase-based diagnostic gene array revealed that Methylocystis-related species were dominant in six of the seven peatlands studied. The abundance and methane oxidation activity of Methylocystis spp. were further confirmed by DNA stable-isotope probing analysis of a sample taken from the Moor House peatland (England). After ultracentrifugation, (13)C-labelled DNA, containing genomic DNA of these Methylocystis spp., was separated from (12)C DNA and subjected to multiple displacement amplification (MDA) to generate sufficient DNA for the preparation of a fosmid metagenomic library. Potential bias of MDA was detected by fingerprint analysis of 16S rRNA using denaturing gradient gel electrophoresis for low-template amplification (0.01 ng template). Sufficient template (1-5 ng) was used in MDA to circumvent this bias and chimeric artefacts were minimized by using an enzymatic treatment of MDA-generated DNA with S1 nuclease and DNA polymerase I. Screening of the metagenomic library revealed one fosmid containing methanol dehydrogenase and two fosmids containing 16S rRNA genes from these Methylocystis-related species as well as one fosmid containing a 16S rRNA gene related to that of Methylocella/Methylocapsa. Sequencing of the 14 kb methanol dehydrogenase-containing fosmid allowed the assembly of a gene cluster encoding polypeptides involved in bacterial methanol utilization (mxaFJGIRSAC). This combination of DNA stable-isotope probing, MDA and metagenomics provided access to genomic information of a relatively large DNA fragment of these thus far uncultivated, predominant and active methanotrophs in peatland soil.     

Bergmann glia and the recognition molecule CHL1 organize GABAergic axons and direct innervation of Purkinje cell dendrites

The geometric and subcellular organization of axon arbors distributes and regulates electrical signaling in neurons and networks, but the underlying mechanisms have remained elusive. In rodent cerebellar cortex, stellate interneurons elaborate characteristic axon arbors that selectively innervate Purkinje cell dendrites and likely regulate dendritic integration. We used GFP BAC transgenic reporter mice to examine the cellular processes and molecular mechanisms underlying the development of stellate cell axons and their innervation pattern. We show that stellate axons are organized and guided towards Purkinje cell dendrites by an intermediate scaffold of Bergmann glial (BG) fibers. The L1 family immunoglobulin protein Close Homologue of L1 (CHL1) is localized to apical BG fibers and stellate cells during the development of stellate axon arbors. In the absence of CHL1, stellate axons deviate from BG fibers and show aberrant branching and orientation. Furthermore, synapse formation between aberrant stellate axons and Purkinje dendrites is reduced and cannot be maintained, leading to progressive atrophy of axon terminals. These results establish BG fibers as a guiding scaffold and CHL1 a molecular signal in the organization of stellate axon arbors and in directing their dendritic innervation.     

Discovery of a potent and selective aurora kinase inhibitor

This communication describes the discovery of a novel series of Aurora kinase inhibitors. Key SAR and critical binding elements are discussed. Some of the more advanced analogues potently inhibit cellular proliferation and induce phenotypes consistent with Aurora kinase inhibition. In particular, compound 21 (SNS-314) is a potent and selective Aurora kinase inhibitor that exhibits significant activity in pre-clinical in vivo tumor models.     

Finding and comparing syntenic regions among Arabidopsis and the outgroups papaya, poplar, and grape: CoGe with rosids

In addition to the genomes of Arabidopsis (Arabidopsis thaliana) and poplar (Populus trichocarpa), two near-complete rosid genome sequences, grape (Vitis vinifera) and papaya (Carica papaya), have been recently released. The phylogenetic relationship among these four genomes and the placement of their three independent, fractionated tetraploidies sum to a powerful comparative genomic system. CoGe, a platform of multiple whole or near-complete genome sequences, provides an integrative Web-based system to find and align syntenic chromosomal regions and visualize the output in an intuitive and interactive manner. CoGe has been customized to specifically support comparisons among the rosids. Crucial facts and definitions are presented to clearly describe the sorts of biological questions that might be answered in part using CoGe, including patterns of DNA conservation, accuracy of annotation, transposability of individual genes, subfunctionalization and/or fractionation of syntenic gene sets, and conserved noncoding sequence content. This précis of an online tutorial, CoGe with Rosids (http://tinyurl.com/4a23pk), presents sample results graphically.     

The N Terminus of Connexin37 Contains an ��-Helix That Is Required for Channel Function

The cytoplasmic N-terminal domain of connexins has been implicated in multiple aspects of gap junction function, including connexin trafficking/assembly and channel gating. A synthetic peptide corresponding to the first 23 amino acids of human connexin37 was prepared, and circular dichroism and nuclear magnetic resonance studies showed that this N-terminal peptide was predominantly α-helical between glycine 5 and glutamate 16. The importance of this structure for localization of the protein at appositional membranes and channel function was tested by expression of site-directed mutants of connexin37 in which amino acids leucine 10 and glutamine 15 were replaced with prolines or alanines. Wild type connexin37 and both substitution mutants localized to appositional membranes between transfected HeLa cells. The proline mutant did not allow intercellular transfer of microinjected neurobiotin; the alanine mutant allowed transfer, but less extensively than wild type connexin37. When expressed alone in Xenopus oocytes, wild type connexin37 produced hemichannel currents, but neither of the double substitution mutants produced detectable currents. The proline mutant (but not the alanine mutant) inhibited co-expressed wild type connexin37. Taken together, our data suggest that the α-helical structure of the connexin37 N terminus may be dispensable for protein localization, but it is required for channel and hemichannel function.Gap junction channels allow intercellular passage of ions and small molecules up to 1000 Da. They are oligomeric assemblies of members of a family of related proteins called connexins (CX)² (reviewed in Ref. 1). Six connexin monomers assemble to form a hemichannel or connexon (Fig. 1, top panel), which, in turn, forms a complete gap junction channel by docking with a hemichannel from an adjacent cell. Based on sequence similarities, connexins have been separated into subfamilies designated by Greek characters (2, 3). The majority of connexins are members of the α- and β-subfamilies. Connexin polypeptides span the plasma membrane four times and have three cytoplasmic regions: the N terminus (NT), a cytoplasmic loop between the second and third transmembrane domains, and the C terminus (Fig. 1, middle panel). Structural studies of gap junctions have revealed that each hemichannel contains a ring of 24 transmembrane spanning helices (4, 5). Most topological models suggest that the NT of α-subfamily connexins contains 23 amino acids (illustrated for connexin37, CX37, in Fig. 1, bottom panel) and that of β-subfamily connexins contains 22 amino acids.Open in a separate windowFIGURE 1.Diagrams depicting the relationships between a gap junction hemichannel (top), the connexin polypeptide (middle), and the amino acid sequence of the CX37 N-terminal domain (bottom). Thick vertical lines represent the boundaries of the plasma membrane; the intracellular and extracellular spaces are indicated. The transmembrane (M1–M4), extracellular (E1 and E2), and cytoplasmic (NT, N terminus; CL, cytoplasmic loop; and CT, C terminus) domains within a connexin are indicated.The importance of the connexin NT has been emphasized by the identification of a number of connexin mutants that cause amino acid substitutions within this region and are linked to diseases including sensorineural deafness (CX26, CX30, and CX31), Charcot-Marie-Tooth disease (CX32), oculodentodigital dysplasia (CX43), and congenital cataracts (CX46 and CX50). Among the disease-linked mutants that have been studied, some show impaired protein trafficking to the cell surface, whereas others traffic properly, but show loss or alterations of channel function (6–16). Heterologous expression of site-directed mutants and chimeric connexins has demonstrated the influence of NT amino acids upon channel properties, including transjunctional voltage (V_j)-dependent gating, unitary conductance, permeability, and sensitivity to regulation by polyamines (17–22). Lagree et al. (23) have provided evidence that the NT influences the compatibility of connexin hetero-oligomerization.The structure of the NT domain of a β-group connexin, Cx26, has been investigated through circular dichroism (CD) and nuclear magnetic resonance (NMR) of a synthetic peptide corresponding to part of the predicted CX26NT (24, 25). Based on their data, Purnick et al. (24) proposed a model for the NT of CX26 with an α-helix extending from position 1 to 10 and a critical bend at positions 11 and 12 that was suggested to act as a “hinge” allowing the first 10 amino acids to swing into the pore and block the channel. Oshima et al. (5) have published structural studies of a “permeability” mutant (M34A) of CX26 (26) showing a density within the pore of the channel that they suggested might represent a bundle of N termini acting as a “plug” to close the channel.We have been studying CX37, an α-group connexin that is expressed in endothelial cells (27), which may be important for development of atherosclerotic disease (28) and that can form large conductance channels and hemichannels (27, 29). We have shown that as much as half the length of the CX37NT can be deleted without affecting formation of gap junction plaques, but a full-length N terminus is required for hemichannel gating and intercellular communication (30). These observations suggested that the CX37NT may have a structure that is required for function. Therefore, the present experiments were designed to determine the structure of the NT of CX37 and the importance of that structure for protein localization and formation of functional channels and hemichannels. Differences between our data and those previously reported in studies of CX26 suggest that the structure of the NT in α-group connexins may differ from that in β-group connexins.