scholarly journals Oligomerization of EpsE Coordinates Residues from Multiple Subunits to Facilitate ATPase Activity

2011 ◽  
Vol 286 (12) ◽  
pp. 10378-10386 ◽  
Author(s):  
Marcella Patrick ◽  
Konstantin V. Korotkov ◽  
Wim G. J. Hol ◽  
Maria Sandkvist
Keyword(s):  
Atpase Activity ◽  
Conformational Changes ◽  
Active Site ◽  
Structural Changes ◽  
Atp Hydrolysis ◽  
Hydrolytic Enzymes ◽  
Point Mutations ◽  
Nucleotide Binding ◽  
Type Ii ◽  
Arginine Residues

EpsE is an ATPase that powers transport of cholera toxin and hydrolytic enzymes through the Type II secretion (T2S) apparatus in the Gram-negative bacterium, Vibrio cholerae. On the basis of structures of homologous Type II/IV secretion ATPases and our biochemical data, we believe that EpsE is active as an oligomer, likely a hexamer, and the binding, hydrolysis, and release of nucleotide cause EpsE to undergo dynamic structural changes, thus converting chemical energy to mechanical work, ultimately resulting in extracellular secretion. The conformational changes that occur as a consequence of nucleotide binding would realign conserved arginines (Arg210, Arg225, Arg320, Arg324, Arg336, and Arg369) from adjoining domains and subunits to complete the active site around the bound nucleotide. Our data suggest that these arginines are essential for ATP hydrolysis, although their roles in shaping the active site of EpsE are varied. Specifically, we have shown that replacements of these arginine residues abrogate the T2S process due to a reduction of ATPase activity yet do not have any measurable effect on nucleotide binding or oligomerization of EpsE. We have further demonstrated that point mutations in the EpsE intersubunit interface also reduce ATPase activity without disrupting oligomerization, strengthening the idea that residues from multiple subunits must precisely interact in order for EpsE to be sufficiently active to support T2S. Our findings suggest that the action of EpsE is similar to that of other Type II/IV secretion ATPase family members, and thus these results may be widely applicable to the family as a whole.

A molecular understanding of the catalytic cycle of the nucleotide-binding domain of the ABC transporter HlyB

2005 ◽  
Vol 33 (5) ◽  
pp. 990-995 ◽  
Author(s):  
J. Zaitseva ◽  
S. Jenewein ◽  
C. Oswald ◽  
T. Jumpertz ◽  
I.B. Holland ◽  
...  
Keyword(s):  
Abc Transporter ◽  
Conformational Changes ◽  
Structural Changes ◽  
Atp Hydrolysis ◽  
Central Element ◽  
Nucleotide Binding ◽  
Single Step ◽  
Catalytic Cycle ◽  
Type I ◽  
Individual Crystal

The ABC transporter (ATP-binding-cassette transporter) HlyB (haemolysin B) is the central element of a type I secretion machinery, dedicated to the secretion of the toxin HlyA in Escherichia coli. In addition to the ABC transporter, two other indispensable elements are necessary for the secretion of the toxin across two membranes in a single step: the transenvelope protein HlyD and the outer membrane protein TolC. Despite the fact that the hydrolysis of ATP by HlyB fuels secretion of HlyA, the essential features of the underlying transport mechanism remain an enigma. Similar to all other ABC transporters, ranging from bacteria to man, HlyB is composed of two NBDs (nucleotide-binding domains) and two transmembrane domains. Here we summarize our detailed biochemical, biophysical and structural studies aimed at an understanding of the molecular principles of how ATP-hydrolysis is coupled to energy transduction, including the conformational changes occurring during the catalytic cycle, leading to substrate transport. We have obtained individual crystal structures for each single ground state of the catalytic cycle. From these and other biochemical and mutational studies, we shall provide a detailed molecular picture of the steps governing intramolecular communication and the utilization of chemical energy, due to ATP hydrolysis, in relation to resulting structural changes within the NBD. These data will be summarized in a general model to explain how these molecular machines achieve translocation of molecules across biological membranes.

scholarly journals Kinesin: switch I & II and the motor mechanism

2002 ◽  
Vol 115 (1) ◽  
pp. 15-23 ◽  
Author(s):  
F. Jon Kull ◽  
Sharyn A. Endow
Keyword(s):  
Crystal Structures ◽  
Conformational Changes ◽  
Active Site ◽  
Atp Hydrolysis ◽  
Nucleotide Binding ◽  
Structural Transitions ◽  
Rotational Movement ◽  
Atomic Models ◽  
Binding Cleft

New crystal structures of the kinesin motors differ from previously described motor-ADP atomic models, showing striking changes both in the switch I region near the nucleotide-binding cleft and in the switch II or ‘relay’ helix at the filament-binding face of the motor. The switch I region, present as a short helix flanked by two loops in previous motor-ADP structures, rearranges into a pseudo-β-hairpin or is completely disordered with melted helices to either side of the disordered switch I loop. The relay helix undergoes a rotational movement coupled to a translation that differs from the piston-like movement of the relay helix observed in myosin. The changes observed in the crystal structures are interpreted to represent structural transitions that occur in the kinesin motors during the ATP hydrolysis cycle. The movements of switch I residues disrupt the water-mediated coordination of the bound Mg2+, which could result in loss of Mg2+ and ADP, raising the intriguing possibility that disruption of the switch I region leads to release of nucleotide by the kinesins. None of the new structures is a true motor-ATP state, however, probably because conformational changes at the active site of the kinesins require interactions with microtubules to stabilize the movements.

scholarly journals Structural basis of mechano-chemical coupling by the mitotic kinesin KIF14

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Matthieu P.M.H. Benoit ◽  
Ana B. Asenjo ◽  
Mohammadjavad Paydar ◽  
Sabin Dhakal ◽  
Benjamin H. Kwok ◽  
...  
Keyword(s):  
Conformational Changes ◽  
Structural Changes ◽  
Atp Hydrolysis ◽  
Nucleotide Binding ◽  
Binding Pocket ◽  
Bound State ◽  
Structural Basis ◽  
Coupling Mechanism ◽  
Developmental Defects ◽  
Microtubule Binding

AbstractKIF14 is a mitotic kinesin whose malfunction is associated with cerebral and renal developmental defects and several cancers. Like other kinesins, KIF14 couples ATP hydrolysis and microtubule binding to the generation of mechanical work, but the coupling mechanism between these processes is still not fully clear. Here we report 20 high-resolution (2.7–3.9 Å) cryo-electron microscopy KIF14-microtubule structures with complementary functional assays. Analysis procedures were implemented to separate coexisting conformations of microtubule-bound monomeric and dimeric KIF14 constructs. The data provide a comprehensive view of the microtubule and nucleotide induced KIF14 conformational changes. It shows that: 1) microtubule binding, the nucleotide species, and the neck-linker domain govern the transition between three major conformations of the motor domain; 2) an undocked neck-linker prevents the nucleotide-binding pocket to fully close and dampens ATP hydrolysis; 3) 13 neck-linker residues are required to assume a stable docked conformation; 4) the neck-linker position controls the hydrolysis rather than the nucleotide binding step; 5) the two motor domains of KIF14 dimers adopt distinct conformations when bound to the microtubule; and 6) the formation of the two-heads-bound-state introduces structural changes in both motor domains of KIF14 dimers. These observations provide the structural basis for a coordinated chemo-mechanical kinesin translocation model.

Functional analysis of box I mutations in yeast site-specific recombinases Flp and R: pairwise complementation with recombinase variants lacking the active-site tyrosine

1992 ◽  
Vol 12 (9) ◽  
pp. 3757-3765
Author(s):  
J W Chen ◽  
B R Evans ◽  
S H Yang ◽  
H Araki ◽  
Y Oshima ◽  
...  
Keyword(s):  
Active Site ◽  
Dna Cleavage ◽  
Substrate Binding ◽  
Point Mutations ◽  
Transfer Reactions ◽  
Strand Transfer ◽  
Site Specific ◽  
Arginine Residues ◽  
Active Site Tyrosine ◽  
Half Site

The site-specific recombinases Flp and R from Saccharomyces cerevisiae and Zygosaccharomyces rouxii, respectively, are related proteins that belong to the yeast family of site-specific recombinases. They share approximately 30% amino acid matches and exhibit a common reaction mechanism that appears to be conserved within the larger integrase family of site-specific recombinases. Two regions of the proteins, designated box I and box II, also harbor a significantly high degree of homology at the nucleotide sequence level. We have analyzed the properties of Flp and R variants carrying point mutations within the box I segment in substrate-binding, DNA cleavage, and full-site and half-site strand transfer reactions. All mutations abolish or seriously diminish recombinase function either at the substrate-binding step or at the catalytic steps of strand cleavage or strand transfer. Of particular interest are mutations of Arg-191 of Flp and R, residues which correspond to one of the two invariant arginine residues of the integrase family. These variant proteins bind substrate with affinities comparable to those of the corresponding wild-type recombinases. Among the binding-competent variants, only Flp(R191K) is capable of efficient substrate cleavage in a full recombination target. However, this protein does not cleave a half recombination site and fails to complete strand exchange in a full site. Strikingly, the Arg-191 mutants of Flp and R can be rescued in half-site strand transfer reactions by a second point mutant of the corresponding recombinase that lacks its active-site tyrosine (Tyr-343). Similarly, Flp and R variants of Cys-189 and Flp variants at Asp-194 and Asp-199 can also be complemented by the corresponding Tyr-343-to-phenylalanine recombinase mutant.

P219L substitution in human D-amino acid oxidase impacts the ligand binding and catalytic efficiency

2020 ◽  
Vol 168 (5) ◽  
pp. 557-567
Author(s):  
Wanitcha Rachadech ◽  
Yusuke Kato ◽  
Rabab M Abou El-Magd ◽  
Yuji Shishido ◽  
Soo Hyeon Kim ◽  
...  
Keyword(s):  
Amino Acid ◽  
Conformational Changes ◽  
Active Site ◽  
Structural Changes ◽  
Catalytic Efficiency ◽  
Acid Oxidase ◽  
Wild Type ◽  
Amino Acid Oxidase ◽  
Adenine Ring ◽  
The Impact

Abstract Human D-amino acid oxidase (DAO) is a flavoenzyme that is implicated in neurodegenerative diseases. We investigated the impact of replacement of proline with leucine at Position 219 (P219L) in the active site lid of human DAO on the structural and enzymatic properties, because porcine DAO contains leucine at the corresponding position. The turnover numbers (kcat) of P219L were unchanged, but its Km values decreased compared with wild-type, leading to an increase in the catalytic efficiency (kcat/Km). Moreover, benzoate inhibits P219L with lower Ki value (0.7–0.9 µM) compared with wild-type (1.2–2.0 µM). Crystal structure of P219L in complex with flavin adenine dinucleotide (FAD) and benzoate at 2.25 Å resolution displayed conformational changes of the active site and lid. The distances between the H-bond-forming atoms of arginine 283 and benzoate and the relative position between the aromatic rings of tyrosine 224 and benzoate were changed in the P219L complex. Taken together, the P219L substitution leads to an increase in the catalytic efficiency and binding affinity for substrates/inhibitors due to these structural changes. Furthermore, an acetic acid was located near the adenine ring of FAD in the P219L complex. This study provides new insights into the structure–function relationship of human DAO.

G-actin conformational change and polymerization induced by paraquat

1998 ◽  
Vol 76 (4) ◽  
pp. 583-591 ◽  
Author(s):  
Isabella DalleDonne ◽  
Aldo Milzani ◽  
Roberto Colombo
Keyword(s):  
Conformational Changes ◽  
Mammalian Cells ◽  
Structural Changes ◽  
Cell Injury ◽  
Atp Hydrolysis ◽  
Protein Composition ◽  
Dnase I ◽  
Cross Linking ◽  
Cytoskeletal Protein ◽  
Actin Assembly

Paraquat (1,1´-dimethyl-4,4´-bipyridilium dichloride) is a broad-spectrum herbicide that is highly toxic to animals (including man), the major lesion being in the lung. In mammalian cells, paraquat causes deep alterations in the organization of the cytoskeleton, marked decreases in cytoskeletal protein synthesis, and alterations in cytoskeletal protein composition; therefore, the involvement of the cytoskeleton in cell injury by paraquat was suggested. We previously demonstrated that monomeric actin binds paraquat; moreover, prolonged actin exposure to paraquat, in depolymerizing medium, induces the formation of actin aggregates, which are built up by F-actin. In this work we have shown that the addition of paraquat to monomeric actin results in a strong quenching of Trp-79 and Trp-86 fluorescence. Trypsin digestion experiments demonstrated that the sequence 61-69 on actin subdomain 2 undergoes paraquat-dependent conformational changes. These paraquat-induced structural changes render actin unable to completely inhibit DNase I. By using intermolecular cross-linking to characterize oligomeric species formed during paraquat-induced actin assembly, we found that the herbicide causes the formation of actin oligomers characterized by subunit-subunit contacts like those occurring in oligomers induced by polymerizing salts (i.e., between subdomain 1 on one actin subunit and subdomain 4 on the adjacent subunit). Furthermore, the oligomerization of G-actin induced by paraquat is paralleled by ATP hydrolysis.Key words: actin, paraquat, subdomain 2, DNase I, ATP hydrolysis.

scholarly journals The Walker B motif of the second nucleotide-binding domain (NBD2) of CFTR plays a key role in ATPase activity by the NBD1–NBD2 heterodimer

2006 ◽  
Vol 401 (2) ◽  
pp. 581-586 ◽  
Author(s):  
Fiona L. L. Stratford ◽  
Mohabir Ramjeesingh ◽  
Joanne C. Cheung ◽  
Ling-JUN Huan ◽  
Christine E. Bear
Keyword(s):  
Atpase Activity ◽  
Atp Hydrolysis ◽  
Nucleotide Binding ◽  
Vital Role ◽  
Atp Binding ◽  
Primary Role ◽  
Binding Domains ◽  
Membrane Spanning ◽  
Atp Binding And Hydrolysis

CFTR (cystic fibrosis transmembrane conductance regulator), a member of the ABC (ATP-binding cassette) superfamily of membrane proteins, possesses two NBDs (nucleotide-binding domains) in addition to two MSDs (membrane spanning domains) and the regulatory ‘R’ domain. The two NBDs of CFTR have been modelled as a heterodimer, stabilized by ATP binding at two sites in the NBD interface. It has been suggested that ATP hydrolysis occurs at only one of these sites as the putative catalytic base is only conserved in NBD2 of CFTR (Glu1371), but not in NBD1 where the corresponding residue is a serine, Ser573. Previously, we showed that fragments of CFTR corresponding to NBD1 and NBD2 can be purified and co-reconstituted to form a heterodimer capable of ATPase activity. In the present study, we show that the two NBD fragments form a complex in vivo, supporting the utility of this model system to evaluate the role of Glu1371 in ATP binding and hydrolysis. The present studies revealed that a mutant NBD2 (E1371Q) retains wild-type nucleotide binding affinity of NBD2. On the other hand, this substitution abolished the ATPase activity formed by the co-purified complex. Interestingly, introduction of a glutamate residue in place of the non-conserved Ser573 in NBD1 did not confer additional ATPase activity by the heterodimer, implicating a vital role for multiple residues in formation of the catalytic site. These findings provide the first biochemical evidence suggesting that the Walker B residue: Glu1371, plays a primary role in the ATPase activity conferred by the NBD1–NBD2 heterodimer.

scholarly journals Demonstration of Conformational Changes Associated with Activation of the Maltose Transport Complex

2001 ◽  
Vol 276 (15) ◽  
pp. 12362-12368 ◽  
Author(s):  
Daynene E. Mannering ◽  
Susan Sharma ◽  
Amy L. Davidson
Keyword(s):  
Conformational Changes ◽  
Atp Hydrolysis ◽  
Binding Protein ◽  
Nucleotide Binding ◽  
Wild Type ◽  
Nucleotide Binding Sites ◽  
Atp Binding Cassette Transporter ◽  
Aqueous Solvent ◽  
In The Wild ◽  
Transport Complex

InEscherichia coli, interaction of a periplasmic maltose-binding protein with a membrane-associated ATP-binding cassette transporter stimulates ATP hydrolysis, resulting in translocation of maltose into the cell. The maltose transporter contains two transmembrane subunits, MalF and MalG, and two copies of a nucleotide-hydrolyzing subunit, MalK. Mutant transport complexes that function in the absence of binding protein are thought to be stabilized in an ATPase-active conformation. To probe the conformation of the nucleotide-binding site and to gain an understanding of the nature of the conformational changes that lead to activation, cysteine 40 within the Walker A motif of the MalK subunit was modified by the fluorophore 2-(4′-maleimidoanilino)naphthalene-6-sulfonic acid. Fluorescence differences indicated that residues involved in nucleotide binding were less accessible to aqueous solvent in the binding protein independent transporter than in the wild-type transporter. Similar differences in fluorescence were seen when a vanadate-trapped transition state conformation was compared with the ground state in the wild-type transporter. Our results and recent crystal structures are consistent with a model in which activation of ATPase activity is associated with conformational changes that bring the two MalK subunits closer together, completing the nucleotide-binding sites and burying ATP in the interface.

scholarly journals FRET and optical trapping reveal mechanisms of actin activation of the power stroke and phosphate release in myosin V

2020 ◽  
Vol 295 (51) ◽  
pp. 17383-17397 ◽  
Author(s):  
Laura K. Gunther ◽  
John A. Rohde ◽  
Wanjian Tang ◽  
Joseph A. Cirilo ◽  
Christopher P. Marang ◽  
...  
Keyword(s):  
Active Site ◽  
Maximum Rate ◽  
Optical Trapping ◽  
Structural Changes ◽  
Nucleotide Binding ◽  
Power Stroke ◽  
Myosin V ◽  
Phosphate Release ◽  
Lever Arm ◽  
Binding Regions

Myosins generate force and motion by precisely coordinating their mechanical and chemical cycles, but the nature and timing of this coordination remains controversial. We utilized a FRET approach to examine the kinetics of structural changes in the force-generating lever arm in myosin V. We directly compared the FRET results with single-molecule mechanical events examined by optical trapping. We introduced a mutation (S217A) in the conserved switch I region of the active site to examine how myosin couples structural changes in the actin- and nucleotide-binding regions with force generation. Specifically, S217A enhanced the maximum rate of lever arm priming (recovery stroke) while slowing ATP hydrolysis, demonstrating that it uncouples these two steps. We determined that the mutation dramatically slows both actin-induced rotation of the lever arm (power stroke) and phosphate release (≥10-fold), whereas our simulations suggest that the maximum rate of both steps is unchanged by the mutation. Time-resolved FRET revealed that the structure of the pre– and post–power stroke conformations and mole fractions of these conformations were not altered by the mutation. Optical trapping results demonstrated that S217A does not dramatically alter unitary displacements or slow the working stroke rate constant, consistent with the mutation disrupting an actin-induced conformational change prior to the power stroke. We propose that communication between the actin- and nucleotide-binding regions of myosin assures a proper actin-binding interface and active site have formed before producing a power stroke. Variability in this coupling is likely crucial for mediating motor-based functions such as muscle contraction and intracellular transport.

scholarly journals Molecular mechanisms of substrate-controlled ring dynamics and sub-stepping in a nucleic-acid dependent hexameric motor

2016 ◽  
Author(s):  
Nathan D. Thomsen ◽  
Michael R. Lawson ◽  
Lea B. Witkowsky ◽  
Song Qu ◽  
James M. Berger
Keyword(s):  
Nucleic Acid ◽  
Conformational Changes ◽  
Molecular Motors ◽  
Structural Changes ◽  
Molecular Mechanisms ◽  
Atp Hydrolysis ◽  
Ring Closure ◽  
Structural Studies ◽  
Saxs Data ◽  
Structural Methods

ABSTRACTRing-shaped hexameric helicases and translocases support essential DNA, RNA, and protein-dependent transactions in all cells and many viruses. How such systems coordinate ATPase activity between multiple subunits to power conformational changes that drive the engagement and movement of client substrates is a fundamental question. Using the E. coli Rho transcription termination factor as a model system, we have employed solution and crystallographic structural methods to delineate the range of conformational changes that accompany distinct substrate and nucleotide cofactor binding events. SAXS data show that Rho preferentially adopts an open-ring state in solution, and that RNA and ATP are both required to cooperatively promote ring closure. Multiple closed-ring structures with different RNA substrates and nucleotide occupancies capture distinct catalytic intermediates accessed during translocation. Our data reveal how RNA-induced ring closure templates a sequential ATP-hydrolysis mechanism, provide a molecular rationale for how the Rho ATPase domains distinguishes between distinct RNA sequences, and establish the first structural snapshots of substepping events in a hexameric helicase/translocase.SIGNIFICANCEHexameric, ring-shaped translocases are molecular motors that convert the chemical energy of ATP hydrolysis into the physical movement of protein and nucleic acid substrates. Structural studies of several distinct hexameric translocases have provided insights into how substrates are loaded and translocated; however, the range of structural changes required for coupling ATP turnover to a full cycle of substrate loading and translocation has not been visualized for any one system. Here, we combine low-and high-resolution structural studies of the Rho helicase, defining for the first time the ensemble of conformational transitions required both for substrate loading in solution and for substrate movement by a processive hexameric translocase.

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