TDP-43 Oligomerization and Phase Separation Properties Are Necessary for Autoregulation.

Loss of TDP-43 protein homeostasis and dysfunction, in particular TDP-43 aggregation, are tied to amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). TDP-43 is an RNA binding protein tightly controlling its own expression levels through a negative feedback loop, involving TDP-43 recruitment to the 3' untranslated region of its own transcript. Aberrant TDP-43 expression caused by autoregulation defects are linked to TDP-43 pathology. Therefore, interactions between TDP-43 and its own transcript are crucial to prevent TDP-43 aggregation and loss of function. However, the mechanisms that mediate this interaction remain ill-defined. We find that a central RNA sequence in the 3' UTR, which mediates TDP-43 autoregulation, increases the liquid properties of TDP-43 phase separation. Furthermore, binding to this RNA sequence induces TDP-43 condensation in human cell lysates, suggesting that this interaction promotes TDP-43 self-assembly into dynamic ribonucleoprotein granules. In agreement with these findings, our experiments show that TDP-43 oligomerization and phase separation, mediated by the amino and carboxy-terminal domains, respectively, are essential for TDP-43 autoregulation. According to our additional observations, CLIP34-associated phase separation and autoregulation may be efficiently controlled by phosphorylation of the N-terminal domain. Importantly, we find that specific ALS-associated TDP-43 mutations, mainly M337V, and a shortened TDP-43 isoform recently tied to motor neuron toxicity in ALS, disrupt the liquid properties of TDP-43-RNA condensates as well as autoregulatory function. In addition, we find that M337V decreases the cellular clearance of TDP-43 and other RNA binding proteins associated with ALS/FTD. These observations suggest that loss of liquid properties in M337V condensates strongly affects protein homeostasis. Together, this work provides evidence for the central role of TDP-43 oligomerization and liquid-liquid phase separation linked to RNA binding in autoregulation. These mechanisms may be impaired by TDP-43 disease variants and controlled by specific cellular signaling.

Bioorthogonal Chemistry Enables Single-Molecule FRET Measurements of Catalytically Active Protein Disulfide Isomerase.

Folding of newly synthesized proteins in the endoplasmic reticulum is assisted by several families of enzymes. One such family is the protein disulfide isomerases (PDIs). PDIs are oxidoreductases, capable of forming new disulfide bonds or breaking existing ones. Structural information on PDIs unbound and bound to substrates is highly desirable for developing targeted therapeutics, yet it has been difficult to obtain by using traditional approaches because of their relatively large size and remarkable flexibility. Single-molecule FRET (smFRET) could be a powerful tool to study PDIs' structure and dynamics under conditions relevant to physiology, but its implementation has been hindered by technical challenges of position-specific fluorophore labeling. We have overcome this limitation by site-specifically engineering fluorescent dyes into human PDI, the founding member of the family. Proof-of-concept smFRET measurements of catalytically active PDI demonstrate, for the first time, the feasibility of this approach, expanding the toolkit for structural studies of PDIs.

Peptide ligand-based ELISA reagents for antibody detection.

Detection of specific antibodies has numerous research, therapeutic and diagnostic applications. Short peptide ligands that bind specifically to antibodies with continuous epitopes can be derived from epitope mapping experiments. Short peptide ligands (mimotopes) specific to antibodies with discontinuous epitopes can be identified by screening complex peptide libraries. In an effort to enhance practical utility of such peptide ligands, we describe here a simple approach to turn such target antibody-specific peptide ligands into specific ELISA detection reagents. We show that a simple addition of biotinylated peptide ligands to commonly available horseradish peroxidase (HRP)-labeled streptavidin (or HRP-anti-biotin antibody), or digoxigenin-labeled peptides to HRP-anti-digoxigenin antibody detection reagents transformed these generic detection reagents into sensitive target antibody-specific reagents. ELISA assays performed using these reagents exhibited excellent analytical properties indicating their practical utility for antibody detection. One generic detection reagent can be readily transformed into many different specific ELISA reagents by a simple mix and match design using an appropriate target-specific peptide ligand. Simplicity of preparation of these ELISA reagents for detecting antibodies should facilitate their practical applications.

DNA template sequence control of bacterial RNA polymerase escape from the promoter.

Promoter escape involves breaking of the favourable contacts between RNA polymerase (RNAP) and the promoter to allow transition to an elongation complex. The sequence of DNA template that is transcribed during promoter escape (ITS; Initially Transcribed Sequence) can affect promoter escape by mechanisms that are not yet fully understood. We employed a highly parallel strategy utilizing Next Generation Sequencing (NGS) to collect data on escape properties of thousands of ITS variants. We show that ITS controls promoter escape through a combination of position-dependent effects (most prominently, sequence-directed RNAP pausing), and position-independent effects derived from sequence encoded physical properties of the template (for example, RNA/DNA duplex stability). ITS often functions as an independent unit affecting escape in the same manner regardless of the promoter from which transcription initiates. However, in some cases, a strong dependence of ITS effects on promoter context was observed suggesting that promoters may have 'allosteric' abilities to modulate ITS effects. Large effects of ITS on promoter output and the observed interplay between promoter sequence and ITS effects suggests that the definition of bacterial promoter should include ITS sequence.

RNA polymerase motions during promoter melting.

All cellular RNA polymerases (RNAPs), from those of bacteria to those of man, possess a clamp that can open and close, and it has been assumed that the open RNAP separates promoter DNA strands and then closes to establish a tight grip on the DNA template. Here, we resolve successive motions of the initiating bacterial RNAP by studying real-time signatures of fluorescent reporters placed on RNAP and DNA in the presence of ligands locking the clamp in distinct conformations. We report evidence for an unexpected and obligatory step early in the initiation involving a transient clamp closure as a prerequisite for DNA melting. We also present a 2.6-angstrom crystal structure of a late-initiation intermediate harboring a rotationally unconstrained downstream DNA duplex within the open RNAP active site cleft. Our findings explain how RNAP thermal motions control the promoter search and drive DNA melting in the absence of external energy sources.

Real-Time Observation of Backtracking by Bacterial RNA Polymerase.

RNA polymerase (RNAP) backtracking is a backward sliding of the enzyme along DNA and RNA. It plays important roles in many essential processes in bacteria and in eukaryotes. We describe here a fluorescence-based approach that allows a real-time observation of bacterial RNAP backtracking. A Cy3 fluorescence probe, when incorporated into a specific site in the nontemplate strand near the site of backtracking, allows RNAP movements to be monitored near the probe because of a robust enhancement of fluorescence caused by protein proximity. Using this approach, we showed that binding of NTP to the active site prior to phosphodiester bond formation inhibited backtracking, consistent with the coupling of NTP binding to translocation. The extent and the kinetics of backtracking did not show a simple correlation with the instability of the DNA-RNA hybrid, indicating a more complex dependence of backtracking on DNA template sequence. Experiments with transcription through an abasic site in DNA template or neutravidin bound to biotinylated template strand base illustrated an important role of backtracking in defining how RNAP reacts to such obstacles in the DNA template. The described approach will be a useful tool in deciphering the mechanism of backtracking and in studying factors that affect the backtracking.

Next Generation Sequencing-based analysis of RNA polymerase functions.

Next Generation Sequencing (NGS) that revolutionized genome wide studies allows analysis of complex nucleic acids mixtures containing thousands of sequences. This extraordinary analytical power of NGS can be harnessed for the analysis of in vitro experiments where DNA template sequence dependence of protein activity acting on DNA can be studied in a single reaction for thousands of DNA sequence variants. This allows a rapid accumulation of data on DNA sequence dependence of the process of interest to a depth not accessible by standard experimentation. We use an example of bacterial RNA polymerase promoter melting activity to describe the NGS-based methodology to study DNA template dependence of protein activity.

Ribosome display enhanced by next generation sequencing: a tool to identify antibody-specific peptide ligands.

Detection of antibodies in serum has many important applications. Our goal was to develop a facile general experimental approach for identifying antibody-specific peptide ligands that could be used as the reagents for antibody detection. Our emphasis was on an approach that would allow identification of peptide ligands for antibodies in serum without the need to isolate the target antibody or to know the identity of its antigen. We combined ribosome display (RD) with the analysis of peptide libraries by next generation sequencing (NGS) of their coding RNA to facilitate identification of antibody-specific peptide ligands from random sequence peptide library. We first demonstrated, using purified antibodies, that with our approach-specific peptide ligands for antibodies with simple linear epitopes, as well as peptide mimotopes for antibodies recognizing complex epitopes, were readily identified. Inclusion of NGS analysis reduced the number of RD selection rounds that were required to identify specific ligands and facilitated discrimination between specific and spurious nonspecific sequences. We then used a model of human serum spiked with a known target antibody to develop NGS-based analysis that allowed identification of specific ligands for a target antibody in the context of an overwhelming amount of unrelated immunoglobins present in serum.

Kinetics of promoter escape by bacterial RNA polymerase: effects of promoter contacts and transcription bubble collapse.

Promoter escape by RNA polymerase, the transition between the initiation and elongation, is a critical step that defines transcription output at many promoters. In the present study we used a real-time fluorescence assay for promoter melting and escape to study the determinants of the escape. Perturbation of core promoter-polymerase contacts had opposing effects on the rates of melting and escape, demonstrating a direct role of core promoter elements sequence in setting not only the kinetics of promoter melting, but also the kinetics of promoter escape. The start of RNA synthesis is accompanied by an enlargement of the transcription bubble and pulling in of the downstream DNA into the enzyme, resulting in DNA scrunching. Promoter escape results in collapse of the enlarged bubble. To test whether the energy that could be potentially released by the collapse of the bubble plays a role in determining escape kinetics, we measured the rates of promoter escape in promoter constructs, in which the amount of this energy was perturbed by introducing sequence mismatches. We found no significant changes in the rate of promoter escape with these promoter constructs suggesting that the energy released upon bubble collapse does not play a critical role in determining the kinetics of promoter escape.

Next generation sequencing-based parallel analysis of melting kinetics of 4096 variants of a bacterial promoter.

Promoter melting by bacterial RNA polymerase is a key step in transcription initiation. We used a next generation sequencing (NGS) based approach to analyze in parallel promoter melting of all 4096 sequence variants of the 6 bp -10 promoter element. We used NGS read count for each sequence of a promoter library containing a randomized -10 sequence as an observable to determine relative enrichment of -10 element sequence variants at different time points of the promoter melting reaction. The analysis reinforced the dominating role of consensus bases at positions -11 and -7, demonstrated an enhanced preference for A at -11 among sequences exhibiting the fastest melting kinetics, and showed higher overall importance of the T at -7 compared to the A at -11 for efficient promoter melting. Sequences lacking the consensus bases at -7 or -11 could still melt fast if they contained compensatory base patterns at other positions. We observed a significant correlation between the duplex melting energy of -10 element and the kinetics of promoter melting that became more pronounced when the dominating base-specific interactions with RNAP were diminished. These observations indicate that promoter melting kinetics is determined by a combination of base-specific effects/interactions and sequence-dependent stability of DNA duplex with the former playing a dominating role. Our data show that NGS can provide a reliable, quantitative readout for a highly parallel analysis of DNA template sequence dependence of activities of proteins that bind or operate on a DNA template.

Crystal structure of prothrombin reveals conformational flexibility and mechanism of activation.

The zymogen prothrombin is composed of fragment 1 containing a Gla domain and kringle-1, fragment 2 containing kringle-2, and a protease domain containing A and B chains. The prothrombinase complex assembled on the surface of platelets converts prothrombin to thrombin by cleaving at Arg-271 and Arg-320. The three-dimensional architecture of prothrombin and the molecular basis of its activation remain elusive. Here we report the first x-ray crystal structure of prothrombin as a Gla-domainless construct carrying an Ala replacement of the catalytic Ser-525. Prothrombin features a conformation 80 Å long, with fragment 1 positioned at a 36° angle relative to the main axis of fragment 2 coaxial to the protease domain. High flexibility of the linker connecting the two kringles suggests multiple arrangements for kringle-1 relative to the rest of the prothrombin molecule. Luminescence resonance energy transfer measurements detect two distinct conformations of prothrombin in solution, in a 3:2 ratio, with the distance between the two kringles either fully extended (54 ± 2 Å) or partially collapsed (≤34 Å) as seen in the crystal structure. A molecular mechanism of prothrombin activation emerges from the structure. Of the two sites of cleavage, Arg-271 is located in a disordered region connecting kringle-2 to the A chain, but Arg-320 is well defined within the activation domain and is not accessible to proteolysis in solution. Burial of Arg-320 prevents prothrombin autoactivation and directs prothrombinase to cleave at Arg-271 first. Reversal of the local electrostatic potential then redirects prothrombinase toward Arg-320, leading to thrombin generation via the prethrombin-2 intermediate.

Detection methodology based on target molecule-induced sequence-specific binding to a single-stranded oligonucleotide.

We have recently developed a mix-and-read format homogeneous antigen peptide based assay for detection of the antibodies (Tian, L.; Heyduk, T. Anal. Chem. 2009, 81, 5218-5225) that employed for target detection a simple biophysical mechanism of target antibody induced annealing between two complementary oligonucleotides attached to the antigen peptide. In this work, we propose and experimentally validate an alternative variant of this assay format in which target antibody binding to antigen peptide-oligonucleotide conjugate produces a complex with high sequence-specific binding affinity to a single-stranded capture oligonucleotide. This new assay format can be used for preparing various solid-surface based assays by immobilizing the capture oligonucleotide. This assay design is not limited to antibody detection. We demonstrate that it can also be employed for detecting proteins or pathogenic bacteria using oligonucleotide-labeled antibodies as target recognition elements. Preparation of these solid-surface based assays is simplified because all interactions with the solid surfaces are mediated by well-understood oligonucleotide-oligonucleotide interactions and because of the relative ease of immobilizing oligonucleotides on various solid surfaces. These unique aspects of the assay design also allow microarray-style multiplexing that could be most useful for multiplexed antibody profiling for diagnosis and analysis of cancer, autoimmune, and infectious diseases.

Promoter spacer DNA plays an active role in integrating the functional consequences of RNA polymerase contacts with -10 and -35 promoter elements.

Bacterial RNA polymerase (RNAP) interacts with conserved -10 and -35 promoter elements to recognize the promoter and to form an open complex in which DNA duplex around transcription start site melts. Using model DNA constructs (fork junction DNA) that mimic DNA structure found in the open complex we observed that the consequences of mutations in -10 promoter element for RNAP binding exhibited a striking dependence on the presence or absence of a functional -35 promoter element. A role of spacer DNA (a non-conserved DNA sequence connecting -10 and -35 promoter elements) in this phenomenon was probed with a series of fork junction DNA constructs containing perturbations to the spacer DNA. In the absence of a physical connection between the -10 and -35 DNA elements, or when -10 and -35 DNA elements were connected by a long flexible non-DNA linker, the dependence of RNAP interactions with -10 element on the strength of -35 element was lost. When these DNA elements were linked by a rigid DNA duplex or by a DNA duplex containing a short single-stranded gap, the coupling between the -10 and -35 binding activities was observed. These results indicated that promoter spacer DNA played an active role in integrating the functional consequences of RNA polymerase contacts with -10 and -35 promoter element. This role likely involves physical deformation of the spacer occurring in parallel with promoter melting as shown by Fluorescence Resonance Energy Transfer (FRET) experiments with the probes incorporated into spacer DNA.

Homogeneous insulin and C-Peptide sensors for rapid assessment of insulin and C-peptide secretion by the islets.

OBJECTIVE: Glucose-stimulated islet insulin or C-peptide secretion experiments are a fundamental tool for studying and assessing islet function. The goal of this work was to develop Ab-based fluorescent homogenous sensors that would allow rapid, inexpensive, near-instantaneous determinations of insulin and C-peptide levels in biological samples. RESEARCH DESIGN AND METHODS: Our approach was to use molecular pincer design (Heyduk et al., Anal Chem 2008;80:5152-5159) in which a pair of antibodies recognizing nonoverlapping epitopes of the target are modified with short fluorochrome-labeled complementary oligonucleotides and are used to generate a fluorescence energy transfer (FRET) signal in the presence of insulin or C-peptide. RESULTS: The sensors were capable of detecting insulin and C-peptide with high specificity and with picomolar concentration detection limits in times as short as 20 min. Insulin and C-peptide levels determined with the FRET sensors showed outstanding correlation with determinations performed under the same conditions with enzyme-linked immunosorbent assay. Most importantly, the sensors were capable of rapid and accurate determinations of insulin and C-peptide secreted from human or rodent islets, verifying their applicability for rapid assessment of islet function. CONCLUSIONS: The homogeneous, rapid, and uncomplicated nature of insulin and C-peptide FRET sensors allows rapid assessment of ß-cell function and could enable point-of-care determinations of insulin and C-peptide.

Practical biophysics: Sensors for rapid detection of biological targets utilizing target-induced oligonucleotide annealing.

Detection and quantitation of biomolecules is one of the most commonly performed measurements in biomedical research and clinical diagnostics. There is high demand for convenient, rapid and sensitive biomolecule detection methodologies. In this review we discuss a family of sensors that have been developed in our laboratory that share a common simple biophysical mechanism of action and that are capable of rapid detection of a diverse range of biological targets. The sensors generate fluorescence signal in the presence of the target molecule through target-induced association of short fluorochrome-labeled complementary oligonucleotides that are attached to target recognition elements of the sensors (antibodies, aptamers, etc.) via nanometer scale flexible linkers. This sensor design can be used for detecting proteins, antibodies, nucleic acids and whole cells. The assays using these sensors require only adding a sample to the sensor mix followed by simple fluorescence intensity readout. The simplicity, the speed of detection and the potential for miniaturization are the main assets of these sensors.

Fluorescent homogeneous immunosensors for detecting pathogenic bacteria.

We developed a straightforward antibody-based assay for rapid homogeneous detection of bacteria. Our sensors utilize antibody recognizing cell-surface epitopes of the target cell. Two samples of the antibody are prepared, each labeled via nanometer size flexible linkers with short complementary oligonucleotides that are modified with fluorochromes that could participate in fluorescence resonance energy transfer (FRET). The length of the complementary oligonucleotide sequences was designed such that very little annealing occurred in the absence of the target cells. In the presence of the target cells the two labeled antibodies bind to the surface of the cell resulting in a large local concentration of the complementary oligonucleotides that are attached to the antibody. This in turn drives the annealing of the complementary oligonucleotides which brings the fluorescence probes to close proximity producing large FRET signals proportional to the amount of target cells. Long flexible linkers used to attach the oligonucleotides to the antibody enable target-induced oligonucleotide annealing even if the density of surface antigens is only modest. We used Escherichia coli 0157:H7 and Salmonella typhimurium to demonstrate that this design produced sensors exhibiting rapid response time, high specificity, and sensitivity in detecting the target bacteria.

Antigen peptide-based immunosensors for rapid detection of antibodies and antigens.

The homogeneous immunosensor design described here utilizes the bivalent nature of the antibody. Antigen peptide is conjugated using flexible linkers with short complementary oligonucleotides (signaling oligonucleotides), each of which containing a fluorochrome that can form a fluorescence resonance energy transfer (FRET) donor-acceptor pair. The complementary signaling oligonucleotides are short enough to prevent their annealing on their own. Binding of the peptide-signaling oligonucleotide constructs to bivalent antibody results in a large increase in local concentration of signaling oligonucleotides causing their annealing and appearance of FRET signal. We used simple model system (antibiotin antibody) to obtain proof-of-principle validation of the sensor design. We then constructed two sensors based on two peptides corresponding to the antigens of two antibodies raised against human cardiac troponin I. We demonstrated that these sensors could be used for sensitive detection of the antibody and for competition-based detection of the intact troponin I. Furthermore, we showed that these sensors could be used for detection of kinase activity targeting the antigen peptide. These simple and robust immunosensors may find applications in antibody detection (for example, in diagnosis of autoimmune or infectious disease), in protein detection (especially when speed of detection is essential), and in assays for detecting enzymatic activities involved in post-translational modifications of proteins.

Transcription regulation of restriction-modification system Esp1396I.

The convergently transcribed restriction (R) and methylase (M) genes of the Restriction-Modification system Esp1396I are tightly regulated by a controller (C) protein that forms part of the CR operon. We have mapped the transcriptional start sites from each promoter and examined the regulatory role of C.Esp1396I in vivo and in vitro. C-protein binding at the CR and M promoters was analyzed by DNA footprinting and a range of biophysical techniques. The distal and proximal C-protein binding sites at the CR promoter are responsible for activation and repression, respectively. In contrast, a C-protein dimer binds to a single site at the M-promoter to repress the gene, with an affinity much greater than for the CR promoter. Thus, during establishment of the system in a naïve host, the activity of the M promoter is turned off early, preventing excessive synthesis of methylase. Mutational analysis of promoter binding sites reveals that the tetranucleotide inverted repeats long believed to be important for C-protein binding to DNA are less significant than previously thought. Instead, symmetry-related elements outside of these repeats appear to be critical for the interaction and are discussed in terms of the recent crystal structure of C.Esp139I bound to the CR promoter.

Bivalent ligands with long nanometer-scale flexible linkers.

High-affinity ligands recognizing biomolecules with high specificity are crucial for drug discovery and biomolecule detection. We describe here a simple approach to preparing aptamer-based ligands with enhanced binding affinity. In this approach, two aptamer ligands with suboptimal binding properties are covalently linked with a long flexible linker to create a bivalent ligand with significantly improved binding affinity. We first used a simple oligonucleotide-based model, which mimicked the interaction between bivalent ligands and their target molecules, to investigate the principles governing the affinity enhancement. These experiments showed that as long as the individual ligands had at least submicromolar binding affinities, they could be linked with a nanometer-scale flexible linker to produce bivalent ligands with improved binding affinity and specificity. Furthermore, comparison of the experimental data with the bivalent ligand properties predicted by a wormlike chain model showed that this model provided a good approximation of the binding properties of nanometer-scale flexible bivalent ligands. To verify the practicality of bivalent ligands with nanometer-scale flexible linkers, we constructed aptamer-based bivalent ligands for human alpha-thrombin. In agreement with the predictions derived from the model system, the binding affinities and the anticlotting activities of thrombin bivalent ligands were significantly improved compared to those of the individual ligands.

Molecular pincers: antibody-based homogeneous protein sensors.

We describe here a new homogeneous antibody-based protein sensor design (molecular pincers) that allows rapid and sensitive detection of a specific protein in solution. In the presence of the target protein these sensors produce fluorescence signal derived from target-dependent annealing of short complementary fluorochrome-labeled oligonucleotides attached to a pair of target-specific antibodies via nanometer-scale flexible linkers. The sensors allow near-instantaneous detection of the target with sensitivity and specificity approaching that of enzyme-linked immunosorbent assay (ELISA) but requiring no sample manipulation other then the addition of the sample to the sensor mix. We used cardiac troponin I and C-reactive protein as the targets to validate these desirable properties of the sensors. Due to the availability of antibodies to thousands of interesting targets and the straightforward design blueprint of the sensors we expect their wide-ranging applications in research and medical diagnosis, especially when simplicity, high throughput, and short detection time are essential.