Your search keyword '"Cowieson, Nathan"' showing total 7 results

1. Crystal Structure of an Indole-3-Acetic Acid Amido Synthetase from Grapevine Involved in Auxin Homeostasis

Author

Peat, Thomas S., Böttcher, Christine, Newman, Janet, Lucent, Del, Cowieson, Nathan, and Davies, Christopher

Published

2012

2. Crystal structure of posnjakite formed in the first crystal water-cooling line of the ANSTO Melbourne Australian Synchrotron MX1 Double Crystal Monochromator.

Author

Mills, Stuart, Aishima, Jun, Aragao, David, Caradoc-Davies, Tom Tudor, Cowieson, Nathan, Gee, Christine L., Ericsson, Daniel, Harrop, Stephen, Panjikar, Santosh, Louise Smith, Kate Mary, Riboldi-Tunnicliffe, Alan, Williamson, Rachel, and Price, Jason Roy

Subjects

MONOCHROMATORS, SYNCHROTRON radiation, SYNCHROTRONS, CRYSTALS, HYDROGEN bonding, CRYSTAL structure

Abstract

Exceptionally large crystals of posnjakite, Cu4SO4(OH)6(H2O), formed during corrosion of a Swagelock(tm) Snubber copper gasket within the MX1 beamline at the ANSTO-Melbourne, Australian Synchrotron. The crystal structure was solved using synchrotron radiation to R1 = 0.029 and revealed a structure based upon [Cu4(OH)6(H2O)O] sheets, which contain Jahn–Teller-distorted Cu octa­hedra. The sulfate tetrahedra are bonded to one side of the sheet via corner sharing and linked to successive sheets via extensive hydrogen bonds. The sulfate tetra­hedra are split and rotated, which enables additional hydrogen bonds. [ABSTRACT FROM AUTHOR]

Published

2020

3. Dynamic Motion and Communication in the Streptococcal C1 Phage Lysin, PlyC.

Author

Riley, Blake T., Broendum, Sebastian S., Reboul, Cyril F., Cowieson, Nathan P., Costa, Mauricio G. S., Kass, Itamar, Jackson, Colin, Perahia, David, Buckle, Ashley M., and McGowan, Sheena

Subjects

STREPTOCOCCUS, LYSINE, ANTIBIOTICS, DRUG resistance, BACTERIAL disease prevention, CRYSTAL structure, PHYSIOLOGY

Abstract

The growing problem of antibiotic resistance underlies the critical need to develop new treatments to prevent and control resistant bacterial infection. Exogenous application of bacteriophage lysins results in rapid and specific destruction of Gram-positive bacteria and therefore lysins represent novel antibacterial agents. The PlyC phage lysin is the most potent lysin characterized to date and can rapidly lyse Group A, C and E streptococci. Previously, we have determined the X-ray crystal structure of PlyC, revealing a complicated and unique arrangement of nine proteins. The scaffold features a multimeric cell-wall docking assembly bound to two catalytic domains that communicate and work synergistically. However, the crystal structure appeared to be auto-inhibited and raised important questions as to the mechanism underlying its extreme potency. Here we use small angle X-ray scattering (SAXS) and reveal that the conformational ensemble of PlyC in solution is different to that in the crystal structure. We also investigated the flexibility of the enzyme using both normal mode (NM) analysis and molecular dynamics (MD) simulations. Consistent with our SAXS data, MD simulations show rotational dynamics of both catalytic domains, and implicate inter-domain communication in achieving a substrate-ready conformation required for enzyme function. Our studies therefore provide insights into how the domains in the PlyC holoenzyme may act together to achieve its extraordinary potency. [ABSTRACT FROM AUTHOR]

Published

2015

4. The structure of vanin 1: a key enzyme linking metabolic disease and inflammation.

Author

Boersma, Ykelien L., Newman, Janet, Adams, Timothy E., Cowieson, Nathan, Krippner, Guy, Bozaoglu, Kiymet, and Peat, Thomas S.

Subjects

ENZYME-linked immunosorbent assay, METABOLIC disorders, INFLAMMATION, COENZYME A, CRYSTAL structure

Abstract

Although part of the coenzyme A pathway, vanin 1 (also known as pantetheinase) sits on the cell surface of many cell types as an ectoenzyme, catalyzing the breakdown of pantetheine to pantothenic acid (vitamin B5) and cysteamine, a strong reducing agent. Vanin 1 was initially discovered as a protein involved in the homing of leukocytes to the thymus. Numerous studies have shown that vanin 1 is involved in inflammation, and more recent studies have shown a key role in metabolic disease. Here, the X-ray crystal structure of human vanin 1 at 2.25 Å resolution is presented, which is the first reported structure from the vanin family, as well as a crystal structure of vanin 1 bound to a specific inhibitor. These structures illuminate how vanin 1 can mediate its biological roles by way of both enzymatic activity and protein-protein interactions. Furthermore, it sheds light on how the enzymatic activity is regulated by a novel allosteric mechanism at a domain interface. [ABSTRACT FROM AUTHOR]

Published

2014

5. The X-ray Crystal Structure of Full-Length Human Plasminogen

Author

Law, Ruby H.P., Caradoc-Davies, Tom, Cowieson, Nathan, Horvath, Anita J., Quek, Adam J., Encarnacao, Joanna Amarante, Steer, David, Cowan, Angus, Zhang, Qingwei, Lu, Bernadine G.C., Pike, Robert N., Smith, A. Ian, Coughlin, Paul B., and Whisstock, James C.

Subjects

PLASMINOGEN, PROTEIN precursors, FIBRINOLYTIC agents, SERINE proteinases, UROKINASE, GLYCOSYLATION, CRYSTAL structure

Abstract

Summary: Plasminogen is the proenzyme precursor of the primary fibrinolytic protease plasmin. Circulating plasminogen, which comprises a Pan-apple (PAp) domain, five kringle domains (KR1-5), and a serine protease (SP) domain, adopts a closed, activation-resistant conformation. The kringle domains mediate interactions with fibrin clots and cell-surface receptors. These interactions trigger plasminogen to adopt an open form that can be cleaved and converted to plasmin by tissue-type and urokinase-type plasminogen activators. Here, the structure of closed plasminogen reveals that the PAp and SP domains, together with chloride ions, maintain the closed conformation through interactions with the kringle array. Differences in glycosylation alter the position of KR3, although in all structures the loop cleaved by plasminogen activators is inaccessible. The ligand-binding site of KR1 is exposed and likely governs proenzyme recruitment to targets. Furthermore, analysis of our structure suggests that KR5 peeling away from the PAp domain may initiate plasminogen conformational change. [ABSTRACT FROM AUTHOR]

Published

2012

6. Structure and activity of exo-1,3/1,4-β-glucanase from marine bacterium Pseudoalteromonas sp. BB1 showing a novel C-terminal domain.

Author

Nakatani, Yoshio, Cutfield, Susan M., Cowieson, Nathan P., and Cutfield, John F.

Subjects

GLYCOSIDASES, CRYSTAL structure, MARINE algae, X-ray scattering, CARBOHYDRATES, PROTEIN structure

Abstract

Following the discovery of an exo-1,3/1,4-β-glucanase (glycoside hydrolase family 3) from a seaweed-associated bacterium Pseudoalteromonas sp. BB1, the recombinant three-domain protein (ExoP) was crystallized and its structure solved to 2.3 Å resolution. The first two domains of ExoP, both of which contribute to the architecture of the active site, are similar to those of the two-domain barley homologue β- d-glucan exohydrolase (ExoI) with a distinctive Trp-Trp clamp at the +1 subsite, although ExoI displays broader specificity towards β-glycosidic linkages. Notably, excision of the third domain of ExoP results in an inactive enzyme. Domain 3 has a β-sandwich structure and was shown by CD to be more temperature stable than the native enzyme. It makes relatively few contacts to domain 1 and none at all to domain 2. Two of the domain 3 residues involved at the interface, Q683 (forming one hydrogen bond) and Q676 (forming two hydrogen bonds) were mutated to alanine. Variant Q676A retained about half the activity of native ExoP, but the Q683A variant was severely attenuated. The crystal structure of Q683A-ExoP indicated that domain 3 was highly mobile and that Q683 is critical to the stabilization of ExoP by domain 3. Small-angle X-ray scattering data lent support to this proposal. Domain 3 does not appear to be an obvious carbohydrate-binding domain and is related neither in sequence nor structure to the additional domains characterized in other glycoside hydrolase 3 subgroups. Its major role appears to be for protein stability but it may also help orient substrate. Database Structural data are available in the Protein Data Bank under the accession numbers , , and [ABSTRACT FROM AUTHOR]

Published

2012

7. Structural comparison of typical and atypical E2 pestivirus glycoproteins.

Author

Aitkenhead, Hazel, Riedel, Christiane, Cowieson, Nathan, Rümenapf, Hans Tillmann, Stuart, David I., and El Omari, Kamel

Subjects

*GLYCOPROTEINS, *RATTUS norvegicus, *MEMBRANE glycoproteins, *VETERINARY virology, *CRYSTAL structure

Abstract

Pestiviruses, within the family Flaviviridae , are economically important viruses of livestock. In recent years, new pestiviruses have been reported in domestic animals and non-cloven-hoofed animals. Among them, atypical porcine pestivirus (APPV) and Norway rat pestivirus (NRPV) have relatively little sequence conservation in their surface glycoprotein E2. Despite E2 being the main target for neutralizing antibodies and necessary for cell attachment and viral fusion, the mechanism of viral entry remains elusive. To gain further insights into the pestivirus E2 mechanism of action and to assess its diversity within the genus, we report X-ray structures of the pestivirus E2 proteins from APPV and NRPV. Despite the highly divergent structures, both are able to dimerize through their C-terminal domain and contain a solvent-exposed β-hairpin reported to be involved in host receptor binding. Functional analysis of this β-hairpin in the context of BVDV revealed its ability to rescue viral infectivity. [Display omitted] • The X-ray crystal structures of APPV and NRPV E2 glycoproteins were determined • APPV and NRPV E2 form a dimer in solution Aitkenhead et al. report the X-ray crystal structures of pestivirus E2 surface glycoproteins from atypical porcine pestivirus and Norway rat pestivirus. These glycoproteins serve as primary targets for neutralizing antibodies and play crucial roles in cell attachment and viral fusion. [ABSTRACT FROM AUTHOR]

Published

2024