20 research outputs found
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Mapping the phylogeny and lineage history of geographically distinct BCG vaccine strains.
The bacillus Calmette-Guérin (BCG) vaccine has been in use for prevention of tuberculosis for over a century. It remains the only widely available tuberculosis vaccine and its protective efficacy has varied across geographical regions. Since it was developed, the BCG vaccine strain has been shared across different laboratories around the world, where use of differing culture methods has resulted in genetically distinct strains over time. Whilst differing BCG vaccine efficacy around the world is well documented, and the reasons for this may be multifactorial, it has been hypothesized that genetic differences in BCG vaccine strains contribute to this variation. Isolates from an historic archive of lyophilized BCG strains were regrown, DNA was extracted and then whole-genome sequenced using Oxford Nanopore Technologies. The resulting whole-genome data were plotted on a phylogenetic tree and analysed to identify the presence or absence of regions of difference (RDs) and single-nucleotide polymorphisms (SNPs) relating to virulence, growth and cell wall structure. Of 50 strains available, 36 were revived in culture and 39 were sequenced. Morphology differed between the strains distributed before and after 1934. There was phylogenetic association amongst certain geographically classified strains, most notably BCG-Russia, BCG-Japan and BCG-Danish. RD2, RD171 and RD713 deletions were associated with late strains (seeded after 1927). When mapped to BCG-Pasteur 1172, the SNPs in sigK, plaA, mmaA3 and eccC5 were associated with early strains. Whilst BCG-Russia, BCG-Japan and BCG-Danish showed strong geographical isolate clustering, the late strains, including BCG-Pasteur, showed more variation. A wide range of SNPs were seen within geographically classified strains, and as much intra-strain variation as between-strain variation was seen. The date of distribution from the original Pasteur laboratory (early pre-1927 or late post-1927) gave the strongest association with genetic differences in regions of difference and virulence-related SNPs, which agrees with the previous literature
Comparison of intensity, phase retardation, and local birefringence images for filtering blebs using polarization-sensitive optical coherence tomography
Cryo-Electron Microscopic Structure of SecA Bound to the 70S Ribosome.
Background: SecA targets preproteins to the protein-conducting channel in bacteria. Results: Both the single and double copies of SecA bind to the 70S ribosome. Conclusion: Two copies of SecA completely surround the polypeptide tunnel exit. Significance: The structures suggest a function of the dimeric form of SecA on the ribosome. © 2014 by The American Society for Biochemistry and Molecular Biology, Inc
Publisher Correction: Mechanisms of inhibition and activation of extrasynaptic αβ GABAA receptors.
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Mechanisms of inhibition and activation of extrasynaptic αβ GABAA receptors.
Type A GABA (γ-aminobutyric acid) receptors represent a diverse population in the mammalian brain, forming pentamers from combinations of α-, β-, γ-, δ-, ε-, ρ-, θ- and π-subunits1. αβ, α4βδ, α6βδ and α5βγ receptors favour extrasynaptic localization, and mediate an essential persistent (tonic) inhibitory conductance in many regions of the mammalian brain1,2. Mutations of these receptors in humans are linked to epilepsy and insomnia3,4. Altered extrasynaptic receptor function is implicated in insomnia, stroke and Angelman and Fragile X syndromes1,5, and drugs targeting these receptors are used to treat postpartum depression6. Tonic GABAergic responses are moderated to avoid excessive suppression of neuronal communication, and can exhibit high sensitivity to Zn2+ blockade, in contrast to synapse-preferring α1βγ, α2βγ and α3βγ receptor responses5,7-12. Here, to resolve these distinctive features, we determined structures of the predominantly extrasynaptic αβ GABAA receptor class. An inhibited state bound by both the lethal paralysing agent α-cobratoxin13 and Zn2+ was used in comparisons with GABA-Zn2+ and GABA-bound structures. Zn2+ nullifies the GABA response by non-competitively plugging the extracellular end of the pore to block chloride conductance. In the absence of Zn2+, the GABA signalling response initially follows the canonical route until it reaches the pore. In contrast to synaptic GABAA receptors, expansion of the midway pore activation gate is limited and it remains closed, reflecting the intrinsic low efficacy that characterizes the extrasynaptic receptor. Overall, this study explains distinct traits adopted by αβ receptors that adapt them to a role in tonic signalling.This work was supported by a Department of Pharmacology new lab start-up fund, the University of Cambridge Isaac Newton & Wellcome Trust Institutional Strategic Support Fund, and Academy of Medical Sciences Springboard Award (SBF004\1074). Electrophysiology work in the laboratory of Professor Trevor Smart was funded by an MRC programme grant (MR/T002581/1) and Wellcome Trust Collaborative Award (217199/Z/19/Z). The cryo-EM facility receives funding from the Wellcome Trust (206171/Z/17/Z; 202905/Z/16/Z) and University of Cambridge
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The molecular basis of drug selectivity for α5 subunit-containing GABAA receptors.
α5 subunit-containing γ-aminobutyric acid type A (GABAA) receptors represent a promising drug target for neurological and neuropsychiatric disorders. Altered expression and function contributes to neurodevelopmental disorders such as Dup15q and Angelman syndromes, developmental epilepsy and autism. Effective drug action without side effects is dependent on both α5-subtype selectivity and the strength of the positive or negative allosteric modulation (PAM or NAM). Here we solve structures of drugs bound to the α5 subunit. These define the molecular basis of binding and α5 selectivity of the β-carboline, methyl 6,7-dimethoxy-4-ethyl-β-carboline-3-carboxylate (DMCM), type II benzodiazepine NAMs, and a series of isoxazole NAMs and PAMs. For the isoxazole series, each molecule appears as an 'upper' and 'lower' moiety in the pocket. Structural data and radioligand binding data reveal a positional displacement of the upper moiety containing the isoxazole between the NAMs and PAMs. Using a hybrid molecule we directly measure the functional contribution of the upper moiety to NAM versus PAM activity. Overall, these structures provide a framework by which to understand distinct modulator binding modes and their basis of α5-subtype selectivity, appreciate structure-activity relationships, and empower future structure-based drug design campaigns.F. Hoffmann-La Roche Lt
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The molecular basis of drug selectivity for α5 subunit-containing GABAA receptors.
Acknowledgements: We acknowledge L. Cooper for training in cryo-EM grid preparation and for performing grid clipping; J. Stayaert (Vrije Universiteit Brussel) for kindly providing MbF3; M. Reutlinger and J. Benz for scientific discussions early in the project; V. Graf for electrophysiology support; and M. Karg, M. Fogetta and M. Siegrist for molecular biology support. This work was supported by a BBSRC project grant, BB/M024709/1 (P.S.M.), the Department of Pharmacology new lab start-up fund, and the University of Cambridge Isaac Newton & Wellcome Trust Institutional Strategic Support Fund, Academy of Medical Sciences Springboard Award, SBF004\1074 (P.S.M.), and funding from F. Hoffmann-La Roche Ltd. The cryo-EM facility receives funding from the Wellcome Trust, 206171/Z/17/Z; 202905/Z/16/Z (S.W.H. and D.Y.C.) and University of Cambridge.α5 subunit-containing γ-aminobutyric acid type A (GABAA) receptors represent a promising drug target for neurological and neuropsychiatric disorders. Altered expression and function contributes to neurodevelopmental disorders such as Dup15q and Angelman syndromes, developmental epilepsy and autism. Effective drug action without side effects is dependent on both α5-subtype selectivity and the strength of the positive or negative allosteric modulation (PAM or NAM). Here we solve structures of drugs bound to the α5 subunit. These define the molecular basis of binding and α5 selectivity of the β-carboline, methyl 6,7-dimethoxy-4-ethyl-β-carboline-3-carboxylate (DMCM), type II benzodiazepine NAMs, and a series of isoxazole NAMs and PAMs. For the isoxazole series, each molecule appears as an 'upper' and 'lower' moiety in the pocket. Structural data and radioligand binding data reveal a positional displacement of the upper moiety containing the isoxazole between the NAMs and PAMs. Using a hybrid molecule we directly measure the functional contribution of the upper moiety to NAM versus PAM activity. Overall, these structures provide a framework by which to understand distinct modulator binding modes and their basis of α5-subtype selectivity, appreciate structure-activity relationships, and empower future structure-based drug design campaigns.F. Hoffmann-La Roche Lt