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51. The plastic energy landscape of protein folding: a triangular folding mechanism with an equilibrium intermediate for a small protein domain

Author

Haq SR, Jürgens MC, Chi CN, Koh CS, Elfström L, Selmer M, Gianni S, and Jemth P.

Abstract

Protein domains usually fold without or with only transiently populated intermediates, possibly to avoid misfolding, which could result in amyloidogenic disease. Whether observed intermediates are productive and obligatory species on the folding reaction pathway or dispensable by-products is a matter of debate. Here, we solved the crystal structure of a small protein domain, SAP97 PDZ2 I342W C378A, and determined its folding pathway. The presence of a folding intermediate was demonstrated both by single and double-mixing kinetic experiments using urea-induced (un) folding as well as ligand-induced folding. This protein domain was found to fold via a triangular scheme, where the folding intermediate could be either on-or off-pathway, depending on the experimental conditions. Furthermore, we found that the intermediate was present at equilibrium, which is rarely seen in folding reactions of small protein domains. The folding mechanism observed here illustrates the roughness and plasticity of the protein folding energy landscape, where several routes may be employed to reach the native state. The results also reconcile the folding mechanisms of topological variants within the PDZ domain family.

Published
2010

52. Investigating the structural plasticity of a cytochrome P450: three-dimensional structures of P450 EryK and binding to its physiological substrate

Author

Savino, C, Montemiglio, LINDA CELESTE, Sciara, G, Miele, Adriana Erica, Kendrew, Sg, Jemth, P, Gianni, S., Vallone, Beatrice, Dept Biochem Sci, Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Biot Technol Ltd, University of Essex, Dept Med Biochem & Microbio, Uppsala University, Inst Mol Biol & Pathol, Dept Biochem Sci, Consiglio Nazionale delle Ricerche, CNR, Inst Mol Biol & Pathol, Dept Biochem Sci, Italian MIUR FIRB2003 RBLA03B3KC_004, and CNR RSTL2007-856

Subjects
cytochrome, Protein Conformation, [SDV]Life Sciences [q-bio], substrate specificity, MOLECULAR RECOGNITION, erythromycin, Cytochrome P450, CRYSTAL STRUCTURE, Molecular Conformation, Heme, Ligands, Catalysis, Erythromycin, Substrate Specificity, Oxygen, métabolisme oxydatif, Kinetics, saccharopolyspora erythraea, Bacterial Proteins, Cytochrome P-450 Enzyme System, Models, Chemical, Catalytic Domain, structure tridimensionnelle, Protein Structure and Folding, Escherichia coli, plasticité de l'architecture, Protein Binding
Abstract

Cytochrome P450s are heme-containing proteins that catalyze the oxidative metabolism of many physiological endogenous compounds. Because of their unique oxygen chemistry and their key role in drug and xenobiotic metabolism, particular attention has been devoted in elucidating their mechanism of substrate recognition. In this work, we analyzed the three-dimensional structures of a monomeric cytochrome P450 from Saccharopolyspora erythraea, commonly called EryK, and the binding kinetics to its physiological ligand, erythromycin D. Three different structures of EryK were obtained: two ligand-free forms and one in complex with its substrate. Analysis of the substrate-bound structure revealed the key structural determinants involved in substrate recognition and selectivity. Interestingly, the ligand-free structures of EryK suggested that the protein may explore an open and a closed conformation in the absence of substrate. In an effort to validate this hypothesis and to investigate the energetics between such alternative conformations, we performed stopped-flow absorbance experiments. Data demonstrated that EryK binds erythromycin D via a mechanism involving at least two steps. Contrary to previously characterized cytochrome P450s, analysis of double jump mixing experiments confirmed that this complex scenario arises from a pre-existing equilibrium between the open and closed subpopulations of EryK, rather than from an induced-fit type mechanism.

Published
2009

54. Folding and stability of globular proteins and implications for function

Author

Travaglini-Allocatelli C, Ivarsson Y, Jemth P, and Gianni S.

Abstract

The description of protein folding pathways and the principles that govern them has proven to be one of the most difficult problems to be solved in structural biology. But the combination of experiments and simulations has now provided a clearer picture of the chemistry involved. Once folded, however, proteins remain dynamic systems making possible both small-scale and large-scale structural and/or dynamical changes upon binding or releasing of ligands and during catalysis. In this review we focus on recent advances in the field of protein folding and discuss possible links between folding, stability, and binding dynamics.

Published
2009

55. Investigating the structural plasticity of a cytochrome P450: three-dimensional structures of P450 EryK and binding to its physiological substrate

Author

Savino C, Montemiglio LC, Sciara G, Miele AE, Kendrew SG, Jemth P, Gianni S, and Vallone B.

Subjects
C-12 HYDROXYLASE, LIGAND-BINDING, ERYTHROMYCIN BIOSYNTHESIS, CRYSTAL-STRUCTURE, PROTEIN STRUCTURES
Abstract

Cytochrome P450s are heme-containing proteins that catalyze the oxidative metabolism of many physiological endogenous compounds. Because of their unique oxygen chemistry and their key role in drug and xenobiotic metabolism, particular attention has been devoted in elucidating their mechanism of substrate recognition. In this work, we analyzed the three-dimensional structures of a monomeric cytochrome P450 from Saccharopolyspora erythraea, commonly called EryK, and the binding kinetics to its physiological ligand, erythromycin D. Three different structures of EryK were obtained: two ligand-free forms and one in complex with its substrate. Analysis of the substrate-bound structure revealed the key structural determinants involved in substrate recognition and selectivity. Interestingly, the ligand-free structures of EryK suggested that the protein may explore an open and a closed conformation in the absence of substrate. In an effort to validate this hypothesis and to investigate the energetics between such alternative conformations, we performed stopped-flow absorbance experiments. Data demonstrated that EryK binds erythromycin D via a mechanism involving at least two steps. Contrary to previously characterized cytochrome P450s, analysis of double jump mixing experiments confirmed that this complex scenario arises from a pre-existing equilibrium between the open and closed subpopulations of EryK, rather than from an induced-fit type mechanism.

Published
2009

59. PDZ domains: folding and binding

Author

Jemth P and Gianni S.

Abstract

The PDZ domain is one of the most common protein-protein interaction domains in humans, and it is found in all kingdoms of life. We will review recent progress in the understanding of biophysical aspects of PDZ domains with emphasis on the folding and binding reactions. Finally, we discuss an intriguing correlation between stability and binding of peptide for PDZ2 from PTP-BL.

Published
2007

62. An on-pathway intermediate in the folding of a PDZ domain

Author

Ivarsson Y, Travaglini-Allocatelli C, Jemth P, Malatesta F, Brunori M, and Gianni S.

Abstract

The folding pathways of some proteins include the population of partially structured species en route to the native state. Identification and characterization of these folding intermediates are particularly difficult as they are often only transiently populated and play different mechanistic roles, being either on-pathway productive species or off-pathway kinetic traps. To define the role of folding intermediates, a quantitative analysis of the folding and unfolding rate constants over a wide range of denaturant concentration is often required. Such a task is further complicated by the reversible nature of the folding reaction, which implies the observed kinetics to be governed by a complex combination of different microscopic rate constants. Here, we tackled this problem by measuring directly the folding rate constant under highly denaturing conditions, namely by inducing the folding of a PDZ domain through a quasi-irreversible binding reaction with a specific peptide. In analogy with previous works based on hydrogen exchange experiments, we present evidence that the folding pathway of the PDZ domain involves the formation of an obligatory on-pathway intermediate. The results presented exemplify a novel type of kinetic test to detect an on-pathway folding intermediate.

Published
2007

64. Piperazin-1-ylpyridazine Derivatives Are a Novel Class of Human dCTP Pyrophosphatase 1 Inhibitors.

Author

Llona-Minguez, Sabin, Höglund, Andreas, Ghassemian, Artin, Desroses, Matthieu, Calderón-Montaño, José Manuel, Burgos Morón, Estefanía, Valerie, Nicholas C. K., Wiita, Elisee, Almlöf, Ingrid, Koolmeister, Tobias, Mateus, André, Cazares-Körner, Cindy, Sanjiv, Kumar, Homan, Evert, Loseva, Olga, Baranczewski, Pawel, Darabi, Masoud, Mehdizadeh, Amir, Fayezi, Shabnam, and Ann-Sofie Jemth

Published
2017
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65. Identification of Triazolothiadiazoles as Potent Inhibitors of the dCTP Pyrophosphatase 1.

Author

Llona-Minguez, Sabin, Höglund, Andreas, Wiita, Elisee, Almlöf, Ingrid, Mateus, André, Calderón-Montaño, José Manuel, Cazares-Körner, Cindy, Homan, Evert, Loseva, Olga, Baranczewski, Pawel, Jemth, Ann-Sofie, Häggblad, Maria, Martens, Ulf, Lundgren, Bo, Artursson, Per, Lundbäck, Thomas, Jenmalm Jensen, Annika, Warpman Berglund, Ulrika, Scobie, Martin, and Helleday, Thomas

Published
2017
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67. Crystal Structures and Inhibitor Interactions of Mouse and Dog MTH1 Reveal Species-Specific Differences in Affinity

Author

Narwal, Mohit, Jemth, Ann-Sofie, Gustafsson, Robert, Almlöf, Ingrid, Warpman Berglund, Ulrika, Helleday, Thomas, and Stenmark, Pål

Abstract

MTH1 hydrolyzes oxidized nucleoside triphosphates, thereby sanitizing the nucleotide pool from oxidative damage. This prevents incorporation of damaged nucleotides into DNA, which otherwise would lead to mutations and cell death. The high level of reactive oxygen species in cancer cells leads to a higher level of oxidized nucleotides in cancer cells compared to that in nonmalignant cells, making cancer cells more dependent on MTH1 for survival. The possibility of specifically targeting cancer cells by inhibiting MTH1 has highlighted MTH1 as a promising cancer target. The progression of MTH1 inhibitors into the clinic requires animal studies, and knowledge of species differences in the potency of inhibitors is vitally important. We here show that the human MTH1 inhibitor TH588 is approximately 20-fold less potent with respect to inhibition of mouse MTH1 than the human, rat, pig, and dog MTH1 proteins are. We present the crystal structures of mouse MTH1 in complex with TH588 and dog MTH1 and elucidate the structural and sequence basis for the observed difference in affinity for TH588. We identify amino acid residue 116 in MTH1 as an important determinant of TH588 affinity. Furthermore, we present the structure of mouse MTH1 in complex with the substrate 8-oxo-dGTP. The crystal structures provide insight into the high degree of structural conservation between MTH1 proteins from different organisms and provide a detailed view of interactions between MTH1 and the inhibitor, revealing that minute structural differences can have a large impact on affinity and specificity.

Published
2017
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68. A PDZ domain recapitulates a unifying mechanism for protein folding

Author

Gianni, S., Geierhaas, C.D., Calosci, N., Jemth, P., Vuister, G.W., Travaglini-Allocatelli, C., Vendruscolo, M., Brunori, M., Gianni, S., Geierhaas, C.D., Calosci, N., Jemth, P., Vuister, G.W., Travaglini-Allocatelli, C., Vendruscolo, M., and Brunori, M.

Abstract

Contains fulltext : 34641.pdf (publisher's version ) (Closed access), A unifying view has been recently proposed according to which the classical diffusion-collision and nucleation-condensation models may represent two extreme manifestations of an underlying common mechanism for the folding of small globular proteins. We report here the characterization of the folding process of the PDZ domain, a protein that recapitulates the three canonical steps involved in this unifying mechanism, namely: (i) the early formation of a weak nucleus that determines the native-like topology of a large portion of the structure, (ii) a global collapse of the entire polypeptide chain, and (iii) the consolidation of the remaining partially structured regions to achieve the native state conformation. These steps, which are clearly detectable in the PDZ domain investigated here, may be difficult to distinguish experimentally in other proteins, which would thus appear to follow one of the two limiting mechanisms. The analysis of the (un)folding kinetics for other three-state proteins (when available) appears consistent with the predictions ensuing from this unifying mechanism, thus providing a powerful validation of its general nature.

Published
2007

72. Targeting SAMHD1 with the Vpx protein to improve cytarabine therapy for hematological malignancies

Author

Herold, Nikolas, Rudd, Sean G, Ljungblad, Linda, Sanjiv, Kumar, Myrberg, Ida Hed, Paulin, Cynthia B J, Heshmati, Yaser, Hagenkort, Anna, Kutzner, Juliane, Page, Brent D G, Calderón-Montaño, José M, Loseva, Olga, Jemth, Ann-Sofie, Bulli, Lorenzo, Axelsson, Hanna, Tesi, Bianca, Valerie, Nicholas C K, Höglund, Andreas, Bladh, Julia, Wiita, Elisée, Sundin, Mikael, Uhlin, Michael, Rassidakis, Georgios, Heyman, Mats, Tamm, Katja Pokrovskaja, Warpman-Berglund, Ulrika, Walfridsson, Julian, Lehmann, Sören, Grandér, Dan, Lundbäck, Thomas, Kogner, Per, Henter, Jan-Inge, Helleday, Thomas, and Schaller, Torsten

Abstract

The cytostatic deoxycytidine analog cytarabine (ara-C) is the most active agent available against acute myelogenous leukemia (AML). Together with anthracyclines, ara-C forms the backbone of AML treatment for children and adults. In AML, both the cytotoxicity of ara-C in vitro and the clinical response to ara-C therapy are correlated with the ability of AML blasts to accumulate the active metabolite ara-C triphosphate (ara-CTP), which causes DNA damage through perturbation of DNA synthesis. Differences in expression levels of known transporters or metabolic enzymes relevant to ara-C only partially account for patient-specific differential ara-CTP accumulation in AML blasts and response to ara-C treatment. Here we demonstrate that the deoxynucleoside triphosphate (dNTP) triphosphohydrolase SAM domain and HD domain 1 (SAMHD1) promotes the detoxification of intracellular ara-CTP pools. Recombinant SAMHD1 exhibited ara-CTPase activity in vitro, and cells in which SAMHD1 expression was transiently reduced by treatment with the simian immunodeficiency virus (SIV) protein Vpx were dramatically more sensitive to ara-C-induced cytotoxicity. CRISPR–Cas9-mediated disruption of the gene encoding SAMHD1 sensitized cells to ara-C, and this sensitivity could be abrogated by ectopic expression of wild-type (WT), but not dNTPase-deficient, SAMHD1. Mouse models of AML lacking SAMHD1 were hypersensitive to ara-C, and treatment ex vivo with Vpx sensitized primary patient-derived AML blasts to ara-C. Finally, we identified SAMHD1 as a risk factor in cohorts of both pediatric and adult patients with de novo AML who received ara-C treatment. Thus, SAMHD1 expression levels dictate patient sensitivity to ara-C, providing proof-of-concept that the targeting of SAMHD1 by Vpx could be an attractive therapeutic strategy for potentiating ara-C efficacy in hematological malignancies.

Published
2017
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78. Yeast glyoxalase I is a monomeric enzyme with two active sites

Author

Frickel, EM, Jemth, P, Widersten, M, Mannervik, B, Frickel, EM, Jemth, P, Widersten, M, and Mannervik, B

Abstract

The tertiary structure of the monomeric yeast glyoxalase I has been modeled based on the crystal structure of the dimeric human glyoxalase I and a sequence alignment of the two enzymes, The model suggests that yeast glyoxalase I has two active sites conta, Addresses: Mannervik B, Uppsala Univ, Ctr Biomed, Dept Biochem, Box 576, SE-75123 Uppsala, Sweden. Uppsala Univ, Ctr Biomed, Dept Biochem, SE-75123 Uppsala, Sweden.

Published
2001

79. Ser11 plays several roles in the catalytic mechanism of rat glutathione transferase T2-2

Author

Jemth, P, Mannervik, B, Jemth, P, and Mannervik, B

Abstract

Ser11 in rat glutathione transferase T2-2 promotes several steps in the catalyzed reaction pathway of the enzyme. First, the residue lowers the pK(a) value of the enzyme-bound glutathione thiol by 2.2 pH units, from 7.9 to 5.7. Secondly, the presence of S, Addresses: Mannervik B, Uppsala Univ, Dept Biochem, Biomed Ctr, Box 576, SE-75123 Uppsala, Sweden. Uppsala Univ, Dept Biochem, Biomed Ctr, SE-75123 Uppsala, Sweden.

Published
2001

80. Evolutionary design of glutathione-linked proteins in vivo and in vitro based on sampling of modules from pre-existing structures

Author

Mannervik, B, Bolton-Grob, R, Cameron, AD, Etahadieh, M, Gustafsson, A, Hansson, LO, Hubatsch, I, Jemth, P, Johansson, AS, Jones, TA, Larsson, AK, Nilsson, LO, Olin, B, Pettersson, PL, Ridderstrom, M, Stenberg, G, Widersten, M, Wisen, S, Mannervik, B, Bolton-Grob, R, Cameron, AD, Etahadieh, M, Gustafsson, A, Hansson, LO, Hubatsch, I, Jemth, P, Johansson, AS, Jones, TA, Larsson, AK, Nilsson, LO, Olin, B, Pettersson, PL, Ridderstrom, M, Stenberg, G, Widersten, M, and Wisen, S

Abstract

Structural studies suggest that naturally occurring proteins represent a limited number of folds. It would appear that the evolution of novel protein functions to a large extent involves redesign of stable peptide scaffolds by means of combinatorial prote, Addresses: Mannervik B, Uppsala Univ, Dept Biochem, Ctr Biomed, Box 576, SE-75123 Uppsala, Sweden. Uppsala Univ, Dept Biochem, Ctr Biomed, SE-75123 Uppsala, Sweden. Uppsala Univ, Dept Mol Biol, SE-75123 Uppsala, Sweden.

Published
2001

82. Active site serine promotes stabilization of the reactive glutathione thiolate in rat glutathione transferase T2-2 - Evidence against proposed sulfatase activity of the corresponding human enzyme

Author

Jemth, P, Mannervik, B, Jemth, P, and Mannervik, B

Abstract

Ser(11) in rat glutathione transferase T2-2 is important for stabilization of the reactive enzyme-bound glutathione thiolate in the reaction with 1-menaphthyl sulfate. The S11A mutation increased the pK(a) value for the pH dependence of the rate constant, Addresses: Mannervik B, Univ Uppsala, Ctr Biomed, Dept Biochem, Box 576, S-75123 Uppsala, Sweden. Univ Uppsala, Ctr Biomed, Dept Biochem, S-75123 Uppsala, Sweden.

Published
2000

83. The active-site residue Tyr-175 in human glyoxalase II contributes to binding of glutathione derivatives

Author

Ridderstrom, M, Jemth, P, Cameron, AD, Mannervik, B, Ridderstrom, M, Jemth, P, Cameron, AD, and Mannervik, B

Abstract

Tyrosine-175 located in the active site of human glyoxalase II was replaced by phenylalanine in order to study the contribution of this residue to catalysis. The mutation had a marginal effect on the k(cat) value determined using S-D-lactoylglutathione as, Addresses: Mannervik B, Univ Uppsala, Ctr Biomed, Dept Biochem, Box 576, S-75123 Uppsala, Sweden. Univ Uppsala, Ctr Biomed, Dept Biochem, S-75123 Uppsala, Sweden. Uppsala Univ, Biomed Ctr, Dept Mol Biol, S-75124 Uppsala, Sweden.

Published
2000

86. An evolutionary approach to the design of glutathione-linked enzymes

Author

Mannervik, B, Cameron, AD, Fernandez, E, Gustafsson, A, Hansson, LO, Jemth, P, Jiang, FY, Jones, TA, Larsson, AK, Nilsson, LO, Olin, B, Pettersson, PL, Ridderstrom, M, Stenberg, G, Widersten, M, Mannervik, B, Cameron, AD, Fernandez, E, Gustafsson, A, Hansson, LO, Jemth, P, Jiang, FY, Jones, TA, Larsson, AK, Nilsson, LO, Olin, B, Pettersson, PL, Ridderstrom, M, Stenberg, G, and Widersten, M

Abstract

Studies of protein structure provide information about principles of protein design that have come into play in natural evolution. This information can be exploited in the redesign of enzymes for novel functions. The glutathione-binding domain of glutathi, Addresses: Mannervik B, Univ Uppsala, Ctr Biomed, Dept Biochem, Box 576, S-75123 Uppsala, Sweden. Univ Uppsala, Ctr Biomed, Dept Biochem, S-75123 Uppsala, Sweden. Univ Uppsala, Ctr Biomed, Dept Mol Biol, S-75123 Uppsala, Sweden.

Published
1998

87. Phospholipid hydroperoxide glutathione peroxidase activity of human glutathione transferases

Author

Hurst, R, Bao, YP, Jemth, P, Mannervik, B, Williamson, G, Hurst, R, Bao, YP, Jemth, P, Mannervik, B, and Williamson, G

Abstract

Human glutathione transferases (GSTs) from Alpha (A), Mu (M) and Theta (T) classes exhibited glutathione peroxidase activity towards phospholipid hydroperoxide. The specific activities are in the order: GST A1-1 > GST T1-1 > GST M1-1 > GST A2-2 > GST A4, Addresses: Williamson G, AFRC, Inst Food Res, Norwich Lab, Dept Biochem, Norwich Res Pk, Norwich NR4 7UA, Norfolk, England. AFRC, Inst Food Res, Norwich Lab, Dept Biochem, Norwich NR4 7UA, Norfolk, England. Univ Uppsala, Biochem Ctr, Dept Biochem, S-7512

Published
1998

89. Phospholipid hydroperoxide glutathione peroxidase activity of rat class Theta glutathione transferase T2-2

Author

Hurst, R, Bao, YP, Jemth, P, Mannervik, B, Williamson, G, Hurst, R, Bao, YP, Jemth, P, Mannervik, B, and Williamson, G

Abstract

Addresses: Hurst R, AFRC, Inst Food Res, Norwich Lab, Norwich Res Pk, Colney Lane, Norwich NR4 7UA, Norfolk, England. AFRC, Inst Food Res, Norwich Lab, Norwich NR4 7UA, Norfolk, England. Univ Uppsala, Biochem Ctr, Dept Biochem, S-75123 Uppsala, Sweden.

Published
1997

90. Nonequilibrium Capture Rates Induce Protein Accumulation and Enhanced Adsorption to Solid-State Nanopores

Author

Freedman, Kevin J., Haq, Syed Raza, Fletcher, Michael R., Foley, Joe P., Jemth, Per, Edel, Joshua B., and Kim, Min Jun

Abstract

Single molecule capturing of analytes using an electrically biased nanopore is the fundamental mechanism in which nearly all nanopore experiments are conducted. With pore dimensions being on the order of a single molecule, the spatial zone of sensing only contains approximately a zeptoliter of volume. As a result, nanopores offer high precision sensing within the pore but provide little to no information about the analytes outside the pore. In this study, we use capture frequency and rate balance theory to predict and study the accumulation of proteins at the entrance to the pore. Protein accumulation is found to have positive attributes such as capture rate enhancement over time but can additionally lead to negative effects such as long-term blockages typically attributed to protein adsorption on the surface of the pore. Working with the folded and unfolded states of the protein domain PDZ2 from SAP97, we show that applying short (e.g., 3–25 s in duration) positive voltage pulses, rather than a constant voltage, can prevent long-term current blockades (i.e., adsorption events). By showing that the concentration of proteins around the pore can be controlled in real time using modified voltage protocols, new experiments can be explored which study the role of concentration on single molecular kinetics including protein aggregation, folding, and protein binding.

Published
2014
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