High resolution refinement of β-galactosidase in a new crystal form reveals multiple metal-binding sites and provides a structural basis for α-complementation

DOUGLAS H. JUERS; RAYMOND H. JACOBSON; DALE WIGLEY; XUE-JUN ZHANG; REUBEN E. HUBER; DALE E. TRONRUD; BRIAN W. MATTHEWS

doi:10.1110/ps.9.9.1685

Abstract

The unrefined fold of Escherichia coli β-galactosidase based on a monoclinic crystal form with four independent tetramers has been reported previously. Here, we describe a new, orthorhombic form with one tetramer per asymmetric unit that has permitted refinement of the structure at 1.7 Å resolution. This high-resolution analysis has confirmed the original description of the structure and revealed new details. An essential magnesium ion, identified at the active site in the monoclinic crystals, is also seen in the orthorhombic form. Additional putative magnesium binding sites are also seen. Sodium ions are also known to affect catalysis, and five putative binding sites have been identified, one close to the active site. In a crevice on the protein surface, five linked five-membered solvent rings form a partial clathrate-like structure. Some other unusual aspects of the structure include seven apparent cis-peptide bonds, four of which are proline, and several internal salt-bridge networks. Deep solvent-filled channels and tunnels extend across the surface of the molecule and pass through the center of the tetramer. Because of these departures from a compact globular shape, the molecule is not well characterized by prior empirical relationships between the mass and surface area of proteins. The 50 or so residues at the amino terminus have a largely extended conformation and mostly lie across the surface of the protein. At the same time, however, segment 13–21 contributes to a subunit interface, and residues 29–33 pass through a “tunnel” formed by a domain interface. Taken together, the overall arrangement provides a structural basis for the phenomenon of α-complementation.

Crossref Citations

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Huber, Reuben E Hlede, Isabel Y Roth, Nathan J McKenzie, Kyle C and Ghumman, Kiran K 2001. His-391 of β-galactosidase (Escherichia coli) promotes catalyes by strong interactions with the transition state. Biochemistry and Cell Biology, Vol. 79, Issue. 2, p. 183.

Huber, R.E. 2001. Encyclopedia of Genetics. p. 212.

Juers, Douglas H. Heightman, Tom D. Vasella, Andrea McCarter, John D. Mackenzie, Lloyd Withers, Stephen G. and Matthews, Brian W. 2001. A Structural View of the Action ofEscherichia coli(lacZ) β-Galactosidase,. Biochemistry, Vol. 40, Issue. 49, p. 14781.

Juers, Douglas H and Matthews, Brian W 2001. Reversible lattice repacking illustrates the temperature dependence of macromolecular interactions. Journal of Molecular Biology, Vol. 311, Issue. 4, p. 851.

Inohara-Ochiai, Misa Hasegawa, Satoshi Iguchi, Sota Ashikari, Toshihiko Shibano, Yuji Hemmi, Hisashi Nakayama, Toru and Nishino, Tokuzo 2002. Deletion and insertion of a 192-residue peptide in the active-site domain of glycosyl hydrolase family-2 β-galactosidases. Journal of Bioscience and Bioengineering, Vol. 93, Issue. 6, p. 575.

Hidaka, Masafumi Fushinobu, Shinya Ohtsu, Naomi Motoshima, Hidemasa Matsuzawa, Hiroshi Shoun, Hirofumi and Wakagi, Takayoshi 2002. Trimeric Crystal Structure of the Glycoside Hydrolase Family 42 β-Galactosidase from Thermus thermophilus A4 and the Structure of its Complex with Galactose. Journal of Molecular Biology, Vol. 322, Issue. 1, p. 79.

Mongelard, Fabien Labrador, Mariano Baxter, Ellen M Gerasimova, Tatiana I and Corces, Victor G 2002. Trans-splicing as a Novel Mechanism to Explain Interallelic Complementation in Drosophila. Genetics, Vol. 160, Issue. 4, p. 1481.

Lopes Ferreira, Nicolas and Alix, Jean-Hervé 2002. The DnaK Chaperone Is Necessary for α-Complementation of β-Galactosidase in Escherichia coli . Journal of Bacteriology, Vol. 184, Issue. 24, p. 7047.

Doruker, Pemra Jernigan, Robert L. Navizet, Isabelle and Hernandez, Rigoberto 2002. Important fluctuation dynamics of large protein structures are preserved upon coarse‐grained renormalization*. International Journal of Quantum Chemistry, Vol. 90, Issue. 2, p. 822.

Cohen, Georges N. 2002. The Early Influence of the Institut Pasteur on the Emergence of Molecular Biology. Journal of Biological Chemistry, Vol. 277, Issue. 52, p. 50215.

García-Herrero, Alicia Montero, Esther Muñoz, Jose L. Espinosa, Juan F. Vián, Alejandro García, Jose L. Asensio, Juan L. Cañada, F. Javier and Jiménez-Barbero, Jesus 2002. Conformational Selection of Glycomimetics at Enzyme Catalytic Sites: Experimental Demonstration of the Binding of Distinct High-Energy Distorted Conformations of C-, S-, and O-Glycosides by E. Coli β-Galactosidases. Journal of the American Chemical Society, Vol. 124, Issue. 17, p. 4804.

Sibler, Annie-Paule Nordhammer, Alexandra Masson, Murielle Martineau, Pierre Travé, Gilles and Weiss, Etienne 2003. Nucleocytoplasmic shuttling of antigen in mammalian cells conferred by a soluble versus insoluble single-chain antibody fragment equipped with import/export signals. Experimental Cell Research, Vol. 286, Issue. 2, p. 276.

Coker, James A. Sheridan, Peter P. Loveland-Curtze, Jennifer Gutshall, Kevin R. Auman, Ann J. and Brenchley, Jean E. 2003. Biochemical Characterization of a β-Galactosidase with a Low Temperature Optimum Obtained from an Antarctic Arthrobacter Isolate . Journal of Bacteriology, Vol. 185, Issue. 18, p. 5473.

Rönnmark, Jenny Kampf, Caroline Asplund, Anna Höidén-Guthenberg, Ingmarie Wester, Kenneth Pontén, Fredrik Uhlén, Mathias and Nygren, Per-Åke 2003. Affibody-β-galactosidase immunoconjugates produced as soluble fusion proteins in the Escherichia coli cytosol. Journal of Immunological Methods, Vol. 281, Issue. 1-2, p. 149.

Ueda, Hiroshi Yokozeki, Tomoichi Arai, Ryoichi Tsumoto, Kouhei Kumagai, Izumi and Nagamune, Teruyuki 2003. An optimized homogeneous noncompetitive immunoassay based on the antigen-driven enzymatic complementation. Journal of Immunological Methods, Vol. 279, Issue. 1-2, p. 209.

Roth, Nathan J. Penner, Robert M. and Huber, Reuben E. 2003. β-Galactosidases (Escherichia coli) with Double Substitutions Show That Tyr-503 Acts Independently of Glu-461 but Cooperatively with Glu-537. Journal of Protein Chemistry, Vol. 22, Issue. 7-8, p. 663.

Buskirk, Allen R. Ong, Yi-Ching Gartner, Zev J. and Liu, David R. 2004. Directed evolution of ligand dependence: Small-molecule-activated protein splicing. Proceedings of the National Academy of Sciences, Vol. 101, Issue. 29, p. 10505.

Philibert, Pascal and Martineau, Pierre 2004. Directed evolution of single-chain Fv for cytoplasmic expression using the β-galactosidase complementation assay results in proteins highly susceptible to protease degradation and aggregation. Microbial Cell Factories, Vol. 3, Issue. 1,

Hidaka, Masafumi Honda, Yuji Kitaoka, Motomitsu Nirasawa, Satoru Hayashi, Kiyoshi Wakagi, Takayoshi Shoun, Hirofumi and Fushinobu, Shinya 2004. Chitobiose Phosphorylase from Vibrio proteolyticus, a Member of Glycosyl Transferase Family 36, Has a Clan GH-L-like (α/α)6 Barrel Fold. Structure, Vol. 12, Issue. 6, p. 937.

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High resolution refinement of β-galactosidase in a new crystal form reveals multiple metal-binding sites and provides a structural basis for α-complementation

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High resolution refinement of β-galactosidase in a new crystal form reveals multiple metal-binding sites and provides a structural basis for α-complementation

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