The force-generating mechanism of dynein differs from the forcegenerating mechanisms of other cytoskeletal motors. To examine the structural dynamics of dynein's stepping mechanism in real time, we used polarized total internal reflection fluorescence microscopy with nanometer accuracy localization to track the orientation and position of single motors. By measuring the polarized emission of individual quantum nanorods coupled to the dynein ring, we determined the angular position of the ring and found that it rotates relative to the microtubule (MT) while walking. Surprisingly, the observed rotations were small, averaging only 8.3°, and were only weakly correlated with steps. Measurements at two independent labeling positions on opposite sides of the ring showed similar small rotations. Our results are inconsistent with a classic power-stroke mechanism, and instead support a flexible stalk model in which interhead strain rotates the rings through bending and hinging of the stalk. Mechanical compliances of the stalk and hinge determined based on a 3.3-μs molecular dynamics simulation account for the degree of ring rotation observed experimentally. Together, these observations demonstrate that the stepping mechanism of dynein is fundamentally different from the stepping mechanisms of other well-studied MT motors, because it is characterized by constant small-scale fluctuations of a large but flexible structure fully consistent with the variable stepping pattern observed as dynein moves along the MT.ynein is a molecular motor that walks processively toward the minus end of microtubules (MTs) in an ATP-dependent manner (1-3). Axonemal dyneins drive the motility of eukaryotic cilia and flagella, whereas cytoplasmic dynein is responsible for a wide range of functions within eukaryotic cells, including the retrograde transport of cargo such as autophagosomes in neurons (4), alignment of the mitotic spindle (5, 6), and chromosome segregation during mitosis (7). Disruption of dynein-mediated neuronal transport has been implicated in neurodegeneration (8), and mutations in dynein and dynein-associated proteins can cause a range of diseases, including spinal muscular atrophy (9, 10), lissencephaly (11) and Charcot-Marie-Tooth disease type 2 (reviewed in ref. 12). Despite the importance of dynein function, the mechanism by which dynein walks along the MT is not yet well understood.The motor domains of dynein are formed from six concatenated AAA domains, interrupted by a long, antiparallel, coiled-coil stalk that emerges from AAA4 and terminates in the microtubulebinding domain (MTBD) and the buttress that extends from AAA5 and is thought to stabilize the stalk (13,14). Two motor domains form a dimer via their N-terminal tails (2, 3). ATP binding and hydrolysis drive dynein mechanochemistry; the binding of ATP to AAA1 induces a conformational change leading to dissociation of the MTBD from the MT. Hydrolysis on the dissociated head induces a primed conformation that then rebinds to the MT. The forward step, or power stroke,...
Plasmodium falciparum (Pf) hypoxanthine-guanine phosphoribosyltransferase (HGPRT) is a potential therapeutic target. Compared to structurally homologous human enzymes, it has expanded substrate specificity. In this study, 9-deazapurines are used as in situ probes of the active sites of human and Pf HGPRTs. Through the use of these probes it is found that non-covalent interactions stabilise the pre-transition state of the HGPRT-catalysed reaction. Vibrational spectra reveal that the bound substrates are extensively distorted, the carbonyl bond of nucleobase moiety is weakened and the substrate is destabilised along the reaction coordinate. Raman shifts of the human and Pf enzymes are used to quantify the differing degrees of hydrogen bonding in the homologues. A decreased Raman cross-section in enzyme-bound 9-deazaguanine (9DAG) shows that the phenylalanine residue (Phe186 in human and Phe197 in Pf) of HGPRT stacks with the nucleobase. Differential loss of the Raman cross-section suggests that the active site is more compact in human HGPRT as compared to the Pf enzyme, and is more so in the phosphoribosyl pyrophosphate (PRPP) complex 9DAG-PRPP-HGPRT than in 9-deazahypoxanthine (9DAH)-PRPP-HGPRT.
Deaza analogues of nucleobases are potential drugs against infectious diseases caused by parasites. A caveat is that apart from binding their target parasite enzymes, they also bind and inhibit enzymes of the host. In order to design derivatives of deaza analogues which specifically bind target enzymes, knowledge of their molecular structure, protonation state, and predominant tautomers at physiological conditions is essential. We have employed resonance Raman spectroscopy at an excitation wavelength of 260 nm, to decipher solution structure of 9-deazaguanine (9DAG) and 9-deazahypoxanthine (9DAH). These are analogues of guanine and hypoxanthine, respectively, and have been exploited to study static complexes of nucleobase binding enzymes. Such enzymes are known to perturb pKa of their ligands, and thus, we also determined solution structures of these analogues at two, acidic and alkaline, pH. Structure of each possible protonation state and tautomer was computed using density functional theoretical calculations. Species at various pHs were identified based on isotopic shifts in experimental wavenumbers and by comparing these shifts with corresponding computed isotopic shifts. Our results show that at physiological pH, N1 of pyrimidine ring in 9DAG and 9DAH bears a proton. At lower pH, N3 is place of protonation, and at higher pH, deprotonation occurs at N1 position. The proton at N7 of purine ring remains intact even at pH 12.5. We have further compared these results with naturally occurring nucleotides. Our results identify key vibrational modes which can report on hydrogen bonding interactions, protonation and deprotonation in purine rings upon binding to the active site of enzymes.
Enzymes of the salvage pathway are essential to understanding the biochemistry of parasitic protozoa. These parasites lack de novo pathway for nucleotide synthesis and depend solely on purines salvage from their host. Hypoxanthine guanine phosphoribosyltransferase (HGPRT) from Plasmodium falciparum has long been regarded as a potential therapeutic target. Although structurally homologous to human enzyme, PfHGPRT differs from human (h) HGPRT in its expanded substrate specificity and activity towards common substrates. We used substrate analogues, 9‐deazapurines, in combination with UV resonance Raman spectroscopy to capture non‐covalent interactions in enzyme‐substrate complexes. Raman spectral band positions are sensitive to sub‐angstrom changes in bond length. We observed perturbations in Raman spectra that provide quantitative information about hydrogen bonding and stacking‐interactions with the enzyme active‐site. The bound ligands are extensively distorted towards the transition‐state of phosphoribosyltransferase reaction. Differential loss in Raman crosssection of the ligands bound to two enzymes suggests that active‐site is more compact in hHGPRT than in PfHGPRT. The rigidity of active‐site in hHGPRT is attributed to tighter stacking interaction between phenylalanine residue of the active‐site and the nucleobase.Research was supported by IISER, India and Council for Scientific and Industrial Research, India.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.