Stepwise Translocation Research Articles

Assessing the feasibility of protein sequencing using biological nanopores

The nanopore technology offers extraordinary long reads of DNA and RNA sequence by measuring ionic current signals produced by nucleic acid translocation through a biological nanopore. The key to success of the nanopore sequencing method is stepwise translocation of the nucleic acid realized by means of a DNA processing motor and the sharp constriction of the biological nanopore that enables detection of subtle differences among the nucleotides. Here, we use all-atom molecular dynamics simulations to explore the ability of biological nanopores to distinguish amino acids by means of an ionic current blockade.

Structural basis for substrate gripping and translocation by the ClpB AAA+ disaggregase

Bacterial ClpB and yeast Hsp104 are homologous Hsp100 protein disaggregases that serve critical functions in proteostasis by solubilizing protein aggregates. Two AAA+ nucleotide binding domains (NBDs) power polypeptide translocation through a central channel comprised of a hexameric spiral of protomers that contact substrate via conserved pore-loop interactions. Here we report cryo-EM structures of a hyperactive ClpB variant bound to the model substrate, casein in the presence of slowly hydrolysable ATPγS, which reveal the translocation mechanism. Distinct substrate-gripping interactions are identified for NBD1 and NBD2 pore loops. A trimer of N-terminal domains define a channel entrance that binds the polypeptide substrate adjacent to the topmost NBD1 contact. NBD conformations at the seam interface reveal how ATP hydrolysis-driven substrate disengagement and re-binding are precisely tuned to drive a directional, stepwise translocation cycle.

Structural evidence for product stabilization by the ribosomal mRNA helicase.

Protein synthesis in all organisms proceeds by stepwise translocation of the ribosome along messenger RNAs (mRNAs), during which the helicase activity of the ribosome unwinds encountered structures in the mRNA. This activity is known to occur near the mRNA tunnel entrance, which is lined by ribosomal proteins uS3, uS4, and uS5. However, the mechanism(s) of mRNA unwinding by the ribosome and the possible role of these proteins in the helicase activity are not well understood. Here, we present a crystal structure of the Escherichia coli ribosome in which single-stranded mRNA is observed beyond the tunnel entrance, interacting in an extended conformation with a positively charged patch on ribosomal protein uS3 immediately outside the entrance. This apparent binding specificity for single-stranded mRNA ahead of the tunnel entrance suggests that product stabilization may play a role in the unwinding of structured mRNA by the ribosomal helicase.

Single-Molecule Dynamics and Discrimination between Hydrophilic and Hydrophobic Amino Acids in Peptides, through Controllable, Stepwise Translocation across Nanopores.

In this work, we demonstrate the proof-of-concept of real-time discrimination between patches of hydrophilic and hydrophobic monomers in the primary structure of custom-engineered, macro-dipole-like peptides, at uni-molecular level. We employed single-molecule recordings to examine the ionic current through the α-hemolysin (α-HL) nanopore, when serine or isoleucine residues, flanked by segments of oppositely charged arginine and glutamic amino acids functioning as a voltage-dependent “molecular brake” on the peptide, were driven at controllable rates across the nanopore. The observed differences in the ionic currents blockades through the nanopore, visible at time resolutions corresponding to peptide threading through the α-HL’s constriction region, was explained by a simple model of the volumes of electrolyte excluded by either amino acid species, as groups of serine or isoleucine monomers transiently occupy the α-HL. To provide insights into the conditions ensuring optimal throughput of peptide readout through the nanopore, we probed the sidedness-dependence of peptide association to and dissociation from the electrically and geometrically asymmetric α-HL.

Graphene Nanopores for Protein Sequencing.

An inexpensive, reliable method for protein sequencing is essential to unraveling the biological mechanisms governing cellular behavior and disease. Current protein sequencing methods suffer from limitations associated with the size of proteins that can be sequenced, the time, and the cost of the sequencing procedures. Here, we report the results of all-atom molecular dynamics simulations that investigated the feasibility of using graphene nanopores for protein sequencing. We focus our study on the biologically significant phenylalanine-glycine repeat peptides (FG-nups)-parts of the nuclear pore transport machinery. Surprisingly, we found FG-nups to behave similarly to single stranded DNA: the peptides adhere to graphene and exhibit step-wise translocation when subject to a transmembrane bias or a hydrostatic pressure gradient. Reducing the peptide's charge density or increasing the peptide's hydrophobicity was found to decrease the translocation speed. Yet, unidirectional and stepwise translocation driven by a transmembrane bias was observed even when the ratio of charged to hydrophobic amino acids was as low as 1:8. The nanopore transport of the peptides was found to produce stepwise modulations of the nanopore ionic current correlated with the type of amino acids present in the nanopore, suggesting that protein sequencing by measuring ionic current blockades may be possible.

On nanopore DNA sequencing by signal and noise analysis of ionic current

DNA sequencing, i.e., the process of determining the succession of nucleotides on a DNA strand, has become a standard aid in biomedical research and is expected to revolutionize medicine. With the capability of handling single DNA molecules, nanopore technology holds high promises to become speedier in sequencing at lower cost than what are achievable with the commercially available optics- or semiconductor-based massively parallelized technologies. Despite tremendous progress made with biological and solid-state nanopores, high error rates and large uncertainties persist with the sequencing results. Here, we employ a nano-disk model to quantitatively analyze the sequencing process by examining the variations of ionic current when a DNA strand translocates a nanopore. Our focus is placed on signal-boosting and noise-suppressing strategies in order to attain the single-nucleotide resolution. Apart from decreasing pore diameter and thickness, it is crucial to also reduce the translocation speed and facilitate a stepwise translocation. Our best-case scenario analysis points to severe challenges with employing plain nanopore technology, i.e., without recourse to any signal amplification strategy, in achieving sequencing with the desired single-nucleotide resolution. A conceptual approach based on strand synthesis in the nanopore of the translocating DNA from single-stranded to double-stranded is shown to yield a 10-fold signal amplification. Although it involves no advanced physics and is very simple in mathematics, this simple model captures the essence of nanopore sequencing and is useful in guiding the design and operation of nanopore sequencing.

Graphene Nanopores for Protein Sequencing

An inexpensive, reliable method for protein sequencing is essential to unraveling the biological mechanisms governing cellular behavior and disease. Current protein sequencing methods suffer from limitations associated with the size of individual proteins that can be sequenced, the time, and the cost of the sequencing procedures. Over the past decade, nanopores have emerged as an alternative platform for detection and characterization of nucleic acid polymers. Here, we report the results of all-atom molecular dynamics simulations that investigated the feasibility of using graphene nanopores for protein sequencing. We focus our study on the biologically significant phenylalanine-glycine repeat peptides (FG-nups) abundant in the nuclear pore complexes of eukaryotic cells. Surprisingly, we found FG-nups to behave similarly to single stranded DNA: the peptides adhere to graphene and exhibit step-wise translocation when subject to a transmembrane bias. Reducing the peptide's charge density or increasing the peptide's hydrophobicity was found to decrease the translocation speed. Yet, unidirectional and stepwise translocation driven by a transmembrane bias was observed even when the ratio of charged to hydrophobic amino acids within the peptide was as low as 1:8. Neutral peptides were found to exhibit unidirectional and stepwise transport when driven by a gradient of hydrostatic pressure. Analysis of the ionic current blockade produced by the stepwise transport revealed stepwise modulations of the nanopore ionic current correlated with the type of amino acids present in the nanopore. All of the above suggests that protein sequencing by measuring ionic current blockades in a graphene nanopore may be possible.

Stepwise Transport of Stretched ssDNA Through Graphene Nanopores

Among various biological and solid-state nanopores employed for DNA sensing, graphene nanopores have the greatest potential to be successful for DNA sequencing because graphene's single-atom-thin layer may offer single-base resolution recognition. However, the identification of individual bases could not be achieved yet by means of graphene nanopores, mainly because DNA translocation through the pore is too fast and thermal motion of bases is too strong to permit individual bases to be resolved. Here we demonstrate by means of molecular dynamics simulations that stretch-induced stepwise translocation of single-stranded DNA (ssDNA) through graphene nanopores can permit single-base resolution detection. The intrinsic stepwise DNA motion is brought about through alternating conformational changes between spontaneous adhesion of DNA bases to the rim of the graphene nanopore and unbinding due to mechanical force or electric field. A graphene membrane shaped as a quantum point contact permits, by means of transverse electronic conductance measurement, detection of the stepwise translocation of the DNA as predicted through quantum mechanical Green's function-based transport calculations. The measurement scheme described opens a route to enhance the signal-to-noise ratio by not only slowing down DNA translocation to provide sufficient time for base recognition, but also by stabilizing single DNA bases and, thereby, reducing thermal noise.

Intrinsic Stepwise Translocation of Stretched ssDNA in Graphene Nanopores

We investigate by means of molecular dynamics simulations stretch-induced stepwise translocation of single-stranded DNA (ssDNA) through graphene nanopores. The intrinsic stepwise DNA motion, found to be largely independent of size and shape of the graphene nanopore, is brought about through alternating conformational changes between spontaneous adhesion of DNA bases to the rim of the graphene nanopore and unbinding due to mechanical force or electric field. The adhesion reduces the DNA bases’ vertical conformational fluctuations, facilitating base detection and recognition. A graphene membrane shaped as a quantum point contact permits, by means of transverse electronic conductance measurement, detection of the stepwise translocation of the DNA as predicted through quantum mechanical Green’s function-based transport calculations. The measurement scheme described opens a route to enhance the signal-to-noise ratio not only by slowing down DNA translocation to provide sufficient time for base recognition but also by stabilizing single DNA bases and, thereby, reducing thermal noise.

Methods for the assembly and analysis of in vitro transcription-coupled-to-translation systems.

RNA polymerase is a complex machinery, which is further embedded in interactions with other cellular components that interplay with either the transcribed DNA (DNA polymerases, topoisomerases, etc.) or the nascent RNA (RNA processing enzymes, ribosomes, etc.). In prokaryotes, coupling of transcription and translation is thought to play many regulatory roles but the mechanistic understanding of their interactions has been hindered by the lack of a defined experimental system. Here, we describe a pure transcription-coupled-to-translation system in which control of the ribosome has been achieved through its stepwise translocation towards RNA polymerase. This system can be used to study the effects of concurrent translation on RNA chain elongation and to elucidate the interface between the two macromolecular complexes.

Synchronous tRNA movements during translocation on the ribosome are orchestrated by elongation factor G and GTP hydrolysis.

The translocation of tRNAs through the ribosome proceeds through numerous small steps in which tRNAs gradually shift their positions on the small and large ribosomal subunits. The most urgent questions are: (i) whether these intermediates are important; (ii) how the ribosomal translocase, the GTPase elongation factor G (EF-G), promotes directed movement; and (iii) how the energy of GTP hydrolysis is coupled to movement. In the light of recent advances in biophysical and structural studies, we argue that intermediate states of translocation are snapshots of dynamic fluctuations that guide the movement. In contrast to current models of stepwise translocation, kinetic evidence shows that the tRNAs move synchronously on the two ribosomal subunits in a rapid reaction orchestrated by EF-G and GTP hydrolysis. EF-G combines the energy regimes of a GTPase and a motor protein and facilitates tRNA movement by a combination of directed Brownian ratchet and power stroke mechanisms.

Identification of small ORFs in vertebrates using ribosome footprinting and evolutionary conservation

Identification of the coding elements in the genome is a fundamental step to understanding the building blocks of living systems. Short peptides (< 100 aa) have emerged as important regulators of development and physiology, but their identification has been limited by their size. We have leveraged the periodicity of ribosome movement on the mRNA to define actively translated ORFs by ribosome footprinting. This approach identifies several hundred translated small ORFs in zebrafish and human. Computational prediction of small ORFs from codon conservation patterns corroborates and extends these findings and identifies conserved sequences in zebrafish and human, suggesting functional peptide products (micropeptides). These results identify micropeptide-encoding genes in vertebrates, providing an entry point to define their function in vivo.

Mapping of the SecA·SecY and SecA·SecG Interfaces by Site-directed in Vivo Photocross-linking

The two major components of the Eubacteria Sec-dependent protein translocation system are the heterotrimeric channel-forming component SecYEG and its binding partner, the SecA ATPase nanomotor. Once bound to SecYEG, the preprotein substrate, and ATP, SecA undergoes ATP-hydrolytic cycles that drive the stepwise translocation of proteins. Although a previous site-directed in vivo photocross-linking study (Mori, H., and Ito, K. (2006) Proc. Natl. Acad. Sci. U.S.A. 103, 16159-16164) elucidated residues of SecY needed for interaction with SecA, no reciprocal study for SecA protein has been reported to date. In the present study we mapped residues of SecA that interact with SecY or SecG utilizing this approach. Our results show that distinct domains of SecA on two halves of the molecule interact with two corresponding SecY partners as well as with the central cytoplasmic domain of SecG. Our data support the in vivo relevance of the Thermotoga maritima SecA·SecYEG crystal structure that visualized SecYEG interaction for only one-half of SecA as well as previous studies indicating that SecA normally binds two molecules of SecYEG.

A Conserved Aromatic Residue in the Autochaperone Domain of the Autotransporter Hbp Is Critical for Initiation of Outer Membrane Translocation

Autotransporters are bacterial virulence factors that share a common mechanism by which they are transported to the cell surface. They consist of an N-terminal passenger domain and a C-terminal β-barrel, which has been implicated in translocation of the passenger across the outer membrane (OM). The mechanism of passenger translocation and folding is still unclear but involves a conserved region at the C terminus of the passenger domain, the so-called autochaperone domain. This domain functions in the stepwise translocation process and in the folding of the passenger domain after translocation. In the autotransporter hemoglobin protease (Hbp), the autochaperone domain consists of the last rung of the β-helix and a capping domain. To examine the role of this region, we have mutated several conserved aromatic residues that are oriented toward the core of the β-helix. We found that non-conservative mutations affected secretion with Trp(1015) in the cap region as the most critical residue. Substitution at this position yielded a DegP-sensitive intermediate that is located at the periplasmic side of the OM. Further analysis revealed that Trp(1015) is most likely required for initiation of processive folding of the β-helix at the cell surface, which drives sequential translocation of the Hbp passenger across the OM.

Translocation and Unwinding Mechanisms of RNA and DNA Helicases

Helicases and remodeling enzymes are ATP-dependent motor proteins that play a critical role in every aspect of RNA and DNA metabolism. Most RNA-remodeling enzymes are members of helicase superfamily 2 (SF2), which includes many DNA helicase enzymes that display similar structural and mechanistic features. Although SF2 enzymes are typically called helicases, many of them display other types of functions, including single-strand translocation, strand annealing, and protein displacement. There are two mechanisms by which RNA helicase enzymes unwind RNA: The nonprocessive DEAD group catalyzes local unwinding of short duplexes adjacent to their binding sites. Members of the processive DExH group often translocate along single-stranded RNA and displace paired strands (or proteins) in their path. In the latter case, unwinding is likely to occur by an active mechanism that involves Brownian motor function and stepwise translocation along RNA. Through structural and single-molecule investigations, researchers are developing coherent models to explain the functions and dynamic motions of helicase enzymes.

Complex translocations derived stepwise from standard t(15;17) in a patient with variant acute promyelocytic leukemia

We report the case of an elderly man with an acute promyelocytic leukemia variant carrying complex variant translocations. The Q-banded karyotype and spectral karyotyping method revealed a typical t(15;17), and two complex rearrangements caused by stepwise translocation derived from a typical t(15;17). Chromosomes 8 and 14 were related to these rearrangements. The patient received induction chemotherapy using all-trans retinoic acid and achieved complete remission. To our knowledge, a case with complex rearrangements, caused by apparent stepwise translocation, at diagnosis, has not been reported previously.

Deletion of a Conserved, Central Ribosomal Intersubunit RNA Bridge

Elucidation of the structure of the ribosome has stimulated numerous proposals for the roles of specific rRNA elements, including the universally conserved helix 69 (H69) of 23S rRNA, which forms intersubunit bridge B2a and contacts the D stems of A- and P-site tRNAs. H69 has been proposed to be involved not only in subunit association and tRNA binding but also in initiation, translocation, translational accuracy, the peptidyl transferase reaction, and ribosome recycling. Consistent with such proposals, deletion of H69 confers a dominant lethal phenotype. Remarkably, in vitro assays show that affinity-purified Deltah69 ribosomes have normal translational accuracy, synthesize a full-length protein from a natural mRNA template, and support EF-G-dependent translocation at wild-type rates. However, Deltah69 50S subunits are unable to associate with 30S subunits in the absence of tRNA, are defective in RF1-catalyzed peptide release, and can be recycled in the absence of RRF.

SecA Supports a Constant Rate of Preprotein Translocation

In Escherichia coli, secretory proteins (preproteins) are translocated across the cytoplasmic membrane by the Sec system composed of a protein-conducting channel, SecYEG, and an ATP-dependent motor protein, SecA. After binding of the preprotein to SecYEG-bound SecA, cycles of ATP binding and hydrolysis by SecA are thought to drive the stepwise translocation of the preprotein across the membrane. To address how the length of a preprotein substrate affects the SecA-driven translocation process, we constructed derivatives of the precursor of the outer membrane protein A (proOmpA) with 2, 4, 6, and 8 in-tandem repeats of the periplasmic domain. With increasing polypeptide length, an increasing delay in the time before full-length translocation was observed, but the translocation rate expressed as amino acid translocation per minute remained constant. These data indicate that in the ATP-dependent reaction, SecA drives a constant rate of preprotein translocation consistent with a stepping mechanism of translocation.

Stepwise Translocation of Dpo4 Polymerase during Error-Free Bypass of an oxoG Lesion

7,8-dihydro-8-oxoguanine (oxoG), the predominant lesion formed following oxidative damage of DNA by reactive oxygen species, is processed differently by replicative and bypass polymerases. Our kinetic primer extension studies demonstrate that the bypass polymerase Dpo4 preferentially inserts C opposite oxoG, and also preferentially extends from the oxoG•C base pair, thus achieving error-free bypass of this lesion. We have determined the crystal structures of preinsertion binary, insertion ternary, and postinsertion binary complexes of oxoG-modified template-primer DNA and Dpo4. These structures provide insights into the translocation mechanics of the bypass polymerase during a complete cycle of nucleotide incorporation. Specifically, during noncovalent dCTP insertion opposite oxoG (or G), the little-finger domain–DNA phosphate contacts translocate by one nucleotide step, while the thumb domain–DNA phosphate contacts remain fixed. By contrast, during the nucleotidyl transfer reaction that covalently incorporates C opposite oxoG, the thumb-domain–phosphate contacts are translocated by one nucleotide step, while the little-finger contacts with phosphate groups remain fixed. These stepwise conformational transitions accompanying nucleoside triphosphate binding and covalent nucleobase incorporation during a full replication cycle of Dpo4-catalyzed bypass of the oxoG lesion are distinct from the translocation events in replicative polymerases.

Conformational State of the SecYEG-Bound SecA Probed by Single Tryptophan Fluorescence Spectroscopy

The SecYEG complex is a membrane-embedded channel that permits the passage of precursor proteins (preproteins) across the inner membrane of Escherichia coli. SecA is a molecular motor that associates with the SecYEG pore and drives the stepwise translocation of preproteins across the membrane through multiple cycles of ATP binding and hydrolysis. We have investigated the conformational state of soluble and SecYEG-bound SecA using single tryptophan mutants of SecA. The fluorescence spectral properties of the single tryptophans of SecA and their accessibility to the quencher acrylamide demonstrate that SecA undergoes a conformational change that results in a more compact structure upon binding of ATP and binding to the SecYEG pore. In addition, SecYEG-bound SecA undergoes ATP-dependent conformational changes that are not observed for soluble SecA. These data support a model in which binding to the SecYEG channel has a major impact on the SecA conformation.