Comparison of anionic and cationic trypsinogens: The anionic activation domain is more flexible in solution and differs in its mode of BPTI binding in the crystal structure

ANNETTE PASTERNAK; DAGMAR RINGE; LIZBETH HEDSTROM

doi:10.1110/ps.8.1.253

Abstract

Unlike bovine cationic trypsin, rat anionic trypsin retains activity at high pH. This alkaline stability has been attributed to stabilization of the salt bridge between the N-terminal Ile16 and Asp194 by the surface negative charge (Soman K, Yang A-S, Honig B, Fletterick R., 1989, Biochemistry 28:9918–9926). The formation of this salt bridge controls the conformation of the activation domain in trypsin. In this work we probe the structure of rat trypsinogen to determine the effects of the surface negative charge on the activation domain in the absence of the Ile16–Asp194 salt bridge. We determined the crystal structures of the rat trypsin-BPTI complex and the rat trypsinogen-BPTI complex at 1.8 and 2.2 Å, respectively. The BPTI complex of rat trypsinogen resembles that of rat trypsin. Surprisingly, the side chain of Ile16 is found in a similar position in both the rat trypsin and trypsinogen complexes, although it is not the N-terminal residue and cannot form the salt bridge in trypsinogen. The resulting position of the activation peptide alters the conformation of the adjacent autolysis loop (residues 142–153). While bovine trypsinogen and trypsin have similar CD spectra, the CD spectrum of rat trypsinogen has only 60% of the intensity of rat trypsin. This lower intensity most likely results from increased flexibility around two conserved tryptophans, which are adjacent to the activation domain. The NMR spectrum of rat trypsinogen contains high field methyl signals as observed in bovine trypsinogen. It is concluded that the activation domain of rat trypsinogen is more flexible than that of bovine trypsinogen, but does not extend further into the protein core.

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Pasternak, Annette White, Andre Jeffery, Constance J. Medina, Nivia Cahoon, Marguerite Ringe, Dagmar and Hedstrom, Lizbeth 2001. The energetic cost of induced fit catalysis: Crystal structures of trypsinogen mutants with enhanced activity and inhibitor affinity. Protein Science, Vol. 10, Issue. 7, p. 1331.

Arnórsdóttir, Jóhanna Kristjánsson, Magnús M. and Ficner, Ralf 2005. Crystal structure of a subtilisin‐like serine proteinase from a psychrotrophic Vibrio species reveals structural aspects of cold adaptation. The FEBS Journal, Vol. 272, Issue. 3, p. 832.

Zamolodchikova, T. S. Smirnova, E. V. Andrianov, A. N. Kashparov, I. V. Kotsareva, O. D. Sokolova, E. A. Ignatov, K. B. and Pemberton, A. D. 2005. Cloning and Molecular Modeling of Duodenase with Respect to Evolution of Substrate Specificity within Mammalian Serine Proteases That Have Lost a Conserved Active-Site Disulfide Bond. Biochemistry (Moscow), Vol. 70, Issue. 6, p. 672.

Díaz-Mendoza, M. Ortego, F. García de Lacoba, M. Magaña, C. de la Poza, M. Farinós, G.P. Castañera, P. and Hernández-Crespo, P. 2005. Diversity of trypsins in the Mediterranean corn borer Sesamia nonagrioides (Lepidoptera: Noctuidae), revealed by nucleic acid sequences and enzyme purification. Insect Biochemistry and Molecular Biology, Vol. 35, Issue. 9, p. 1005.

Király, Orsolya Guan, Lan Szepessy, Edit Tóth, Miklós Kukor, Zoltán and Sahin-Tóth, Miklós 2006. Expression of human cationic trypsinogen with an authentic N terminus using intein-mediated splicing in aminopeptidase P deficient Escherichia coli. Protein Expression and Purification, Vol. 48, Issue. 1, p. 104.

Liu, Shu-Qun Meng, Zhao-Hui Yang, Jin-Kui Fu, Yun-Xin and Zhang, Ke-Qin 2007. Characterizing structural features of cuticle-degrading proteases from fungi by molecular modeling. BMC Structural Biology, Vol. 7, Issue. 1,

Aleshin, Alexander E. Shiryaev, Sergey A. Strongin, Alex Y. and Liddington, Robert C. 2007. Structural evidence for regulation and specificity of flaviviral proteases and evolution of the Flaviviridae fold. Protein Science, Vol. 16, Issue. 5, p. 795.

Muhlia-Almazán, Adriana Sánchez-Paz, Arturo and García-Carreño, Fernando L. 2008. Invertebrate trypsins: a review. Journal of Comparative Physiology B, Vol. 178, Issue. 6, p. 655.

Getun, Irina V. Brown, C. Kent Tulla-Puche, Judit Ohlendorf, Douglas Woodward, Clare and Barany, George 2008. Partially Folded Bovine Pancreatic Trypsin Inhibitor Analogues Attain Fully Native Structures when Co-Crystallized with S195A Rat Trypsin. Journal of Molecular Biology, Vol. 375, Issue. 3, p. 812.

Yadav, Subhash Chandra Jagannadham, M.V. Kundu, Suman and Jagannadham, Medicherla V. 2009. A kinetically stable plant subtilase with unique peptide mass fingerprints and dimerization properties. Biophysical Chemistry, Vol. 139, Issue. 1, p. 13.

Zakharova, Elena Horvath, Martin P. and Goldenberg, David P. 2009. Structure of a serine protease poised to resynthesize a peptide bond. Proceedings of the National Academy of Sciences, Vol. 106, Issue. 27, p. 11034.

Halabi, Najeeb Rivoire, Olivier Leibler, Stanislas and Ranganathan, Rama 2009. Protein Sectors: Evolutionary Units of Three-Dimensional Structure. Cell, Vol. 138, Issue. 4, p. 774.

Shiryaev, Sergey A and Strongin, Alex Y 2010. Structural and Functional Parameters of the Flaviviral Protease: A Promising Antiviral Drug Target. Future Virology, Vol. 5, Issue. 5, p. 593.

Nekrasov, Alexei N. and Zinchenko, Alexei A. 2010. Structural Features of the Interfaces in Enzyme-Inhibitor Complexes. Journal of Biomolecular Structure and Dynamics, Vol. 28, Issue. 1, p. 85.

KISHIMURA, HIDEKI KLOMKLAO, SAPPASITH NALINANON, SITTHIPONG BENJAKUL, SOOTTAWAT CHUN, BYUNG-SOO and ADACHI, KOHSUKE 2010. COMPARATIVE STUDY ON THERMAL STABILITY OF TRYPSIN FROM THE PYLORIC CECA OF THREADFIN HAKELING (LAEMONEMA LONGIPES). Journal of Food Biochemistry, Vol. 34, Issue. 1, p. 50.

Morcos, Faruck Pagnani, Andrea Lunt, Bryan Bertolino, Arianna Marks, Debora S. Sander, Chris Zecchina, Riccardo Onuchic, José N. Hwa, Terence and Weigt, Martin 2011. Direct-coupling analysis of residue coevolution captures native contacts across many protein families. Proceedings of the National Academy of Sciences, Vol. 108, Issue. 49,

Liang, Lianming Yang, Jinkui Li, Juan Mo, Yuanyuan Li, Li Zhao, Xinying and Zhang, Ke-Qin 2011. Cloning and homology modeling of a serine protease gene (PrC) from the nematophagous fungus Clonostachys rosea. Annals of Microbiology, Vol. 61, Issue. 3, p. 511.

Batra, Jyotica Szabó, András Caulfield, Thomas R. Soares, Alexei S. Sahin-Tóth, Miklós and Radisky, Evette S. 2013. Long-range Electrostatic Complementarity Governs Substrate Recognition by Human Chymotrypsin C, a Key Regulator of Digestive Enzyme Activation. Journal of Biological Chemistry, Vol. 288, Issue. 14, p. 9848.

Rivoire, Olivier 2013. Elements of Coevolution in Biological Sequences. Physical Review Letters, Vol. 110, Issue. 17,

Liu, Juntao Duan, Xiaoyun Sun, Jianyang Yin, Yanbin Li, Guojun Wang, Lushan Liu, Bingqiang and Boudko, Dmitri 2013. Bi-Factor Analysis Based on Noise-Reduction (BIFANR): A New Algorithm for Detecting Coevolving Amino Acid Sites in Proteins. PLoS ONE, Vol. 8, Issue. 11, p. e79764.

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Comparison of anionic and cationic trypsinogens: The anionic activation domain is more flexible in solution and differs in its mode of BPTI binding in the crystal structure

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Comparison of anionic and cationic trypsinogens: The anionic activation domain is more flexible in solution and differs in its mode of BPTI binding in the crystal structure

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