Jamie L. Gilmore

Novel Nanomaterials for Clinical Neuroscience

Neurodegenerative disorders including Alzheimer’s and Parkinson’s diseases, amyotrophic lateral sclerosis, and stroke are rapidly increasing as population ages. The field of nanomedicine is rapidly expanding and promises revolutionary advances to the diagnosis and treatment of devastating human diseases. This paper provides an overview of novel nanomaterials that have potential to improve diagnosis and therapy of neurodegenerative disorders. Examples include liposomes, nanoparticles, polymeric micelles, block ionomer complexes, nanogels, and dendrimers that have been tested clinically or in experimental models for delivery of drugs, genes, and imaging agents. More recently discovered nanotubes and nanofibers are evaluated as promising scaffolds for neuroregeneration. Novel experimental neuroprotective strategies also include nanomaterials, such as fullerenes, which have antioxidant properties to eliminate reactive oxygen species in the brain to mitigate oxidative stress. Novel technologies to enable these materials to cross the blood brain barrier will allow efficient systemic delivery of therapeutic and diagnostic agents to the brain. Furthermore, by combining such nanomaterials with cell-based delivery strategies, the outcomes of neurodegenerative disorders can be greatly improved.

Single Molecule Dynamics of the DNA-EcoRII Protein Complexes Revealed with High-Speed Atomic Force Microscopy

The study of interactions of protein with DNA is important for gaining a fundamental understanding of how numerous biological processes occur, including recombination, transcription, repair, etc. In this study, we use the EcoRII restriction enzyme, which employs a three-site binding mechanism to catalyze cleavage of a single recognition site. Using high-speed atomic force microscopy (HS-AFM) to image single-molecule interactions in real time, we were able to observe binding, translocation, and dissociation mechanisms of the EcoRII protein. The results show that the protein can translocate along DNA to search for the specific binding site. Also, once specifically bound at a single site, the protein is capable of translocating along the DNA to locate the second specific binding site. Furthermore, two alternative modes of dissociation of the EcoRII protein from the loop structure were observed, which result in the protein stably bound as monomers to two sites or bound to a single site as a dimer. From these observations, we propose a model in which this pathway is involved in the formation and dynamics of a catalytically active three-site complex.

Molecular mechanism underlying RAG1/RAG2 synaptic complex formation.

Two lymphoid cell-specific proteins, RAG1 and RAG2 (RAG), initiate V(D)J recombination by assembling a synaptic complex with recombination signal sequences (RSSs) abutting two different antigen receptor gene coding segments, and then introducing a DNA double strand break at the end of each RSS. Despite the biological importance of this system, the structure of the synaptic complex, and the RAG protein stoichiometry and arrangement of DNA within the synaptosome, remains poorly understood. Here we applied atomic force microscopy to directly visualize and characterize RAG synaptic complexes. We report that the pre-cleavage RAG synaptic complex contains about twice the protein content as a RAG complex bound to a single RSS, with a calculated mass consistent with a pair of RAG heterotetramers. In the synaptic complex, the RSSs are predominantly oriented in a side-by-side configuration with no DNA strand crossover. The mass of the synaptic complex, and the conditions under which it is formed in vitro, favors an association model of assembly in which isolated RAG-RSS complexes undergo synapsis mediated by RAG protein-protein interactions. The replacement of Mg2+ cations with Ca2+ leads to a dramatic change in protein stoichiometry for all RAG-RSS complexes, suggesting that the cation composition profoundly influences the type of complex assembled.

Visual Analysis of Concerted Cleavage by Type IIF Restriction Enzyme SfiI in Subsecond Time Region

Many DNA regulatory factors require communication between distantly separated DNA sites for their activity. The type IIF restriction enzyme SfiI is often used as a model system of site communication. Here, we used fast-scanning atomic force microscopy to monitor the DNA cleavage process with SfiI and the changes in the single SfiI-DNA complex in the presence of either Mg²⁺ or Ca²⁺ at a scan rate of 1-2 fps. The increased time resolution allowed us to visualize the concerted cleavage of the protein at two cognate sites. The four termini generated by the cleavage were released in a multistep manner. The high temporal resolution enabled us to visualize the translocation of a DNA strand on a looped complex and intersegmental transfer of the SfiI protein in which swapping of the site is performed without protein dissociation. On the basis of our results, we propose that the SfiI tetramer can remain bound to one of the sites even after cleavage, allowing the other site on the DNA molecule to fill the empty DNA-binding cleft by combining a one-dimensional diffusion-mediated sliding and a segment transfer mechanism.

Probing in vivo dynamics of mitochondria and cortical actin networks using high-speed atomic force/fluorescence microscopy.

The dynamics of the cell membrane and submembrane structures are closely linked, facilitating various cellular activities. Although cell surface research and cortical actin studies have shown independent mechanisms for the cell membrane and the actin network, it has been difficult to obtain a comprehensive understanding of the dynamics of these structures in live cells. Here, we used a combined atomic force/optical microscope system to analyze membrane‐based cellular events at nanometer‐scale resolution in live cells. Imaging the COS‐7 cell surface showed detailed structural properties of membrane invagination events corresponding to endocytosis and exocytosis. In addition, the movement of mitochondria and the spatiotemporal dynamics of the cortical F‐actin network were directly visualized in vivo. Cortical actin microdomains with sizes ranging from 1.7 × 104 to 1.4 × 105 nm2 were dynamically rearranged by newly appearing actin filaments, which sometimes accompanied membrane invaginations, suggesting that these events are integrated with the dynamic regulation of submembrane organizations maintained by actin turnovers. These results provide novel insights into the structural aspects of the entire cell membrane machinery which can be visualized with high temporal and spatial resolution.

Nanoimaging of ssRNA: Genome Architecture of the Hepatitis C Virus Revealed by Atomic Force Microscopy

The complex structures that RNA molecules fold into play important roles in their ability to perform various functions in the cell. The structure and composition of viral RNA influences the ability of the virus to implement the various stages of the viral lifecycle and can influence the severity of the virus effects on the host. Although many individual secondary structures and some tertiary interactions of the Hepatitis C virus genome have previously been identified, the global 3D architecture of the full 9678 nucleotide genome still remains uncertain. One promising technique for the determination of the overall 3D structure of large RNA molecules is nanoimaging with Atomic Force Microscopy. In order to get an idea of the structure of the HCV genome, we imaged the RNA prepared in the presence of Mg2+, which allowed us to observe the compact folded tertiary structure of the viral genome. In addition, to identify individual structural elements of the genome, we imaged the RNA prepared in the absence of Mg2+, which allowed us to visualize the unfolded secondary structure of the genome. We were able to identify a recurring single stranded region of the genome in many of the RNA molecules which was about 58 nm long. This method opens up a whole new avenue for the study of the secondary and tertiary structure of long RNA molecules. This ability to ascertain RNA structure can aid in drawing associations between the structure and the function of the RNA in cells which is vital to the development of potential antiviral therapies.

Caprice/MISP is a novel F-actin bundling protein critical for actin-based cytoskeletal reorganizations

Caprice [C19orf21 actin‐bundling protein in characteristic epithelial cells, also called mitotic interactor and substrate of Plk1 (MISP)] is a novel actin‐related protein identified in the highly‐insoluble subcellular scaffold proteins. This protein contains multiple actin‐binding sites, forms characteristic mesh‐like F‐actin bundles in vitro, and exhibits capricious localization and expression patterns in vivo. Overexpression or knock‐down of Caprice resulted in a dramatic effect on cellular morphology by inducing stress fiber‐like thick filaments or filopodial formations, respectively. Caprice is expressed and localized in distinct cells and tissues with specialized actin‐based structures, such as growth cones of migrating neurons and stereocilia of inner ear hair cells. However, Caprice gene expression is varied among different cell types; especially enriched in several epithelial cells whereas relatively suppressed in a subset of epithelial cells, fibroblasts, and neuroblastoma cells at the transcriptional level. Thus, this protein is expected to be an effector for cell type‐specific actin reorganization with its direct actin‐binding properties and provides a novel model of cell morphology regulation by a non‐ubiquitous single actin‐bundling protein.

Analyses of nuclear proteins and nucleic acid structures using atomic force microscopy.

Since the inception of atomic force microscopy (AFM) in 1986, the value of this technology for exploring the structure and biophysical properties of a variety of biological samples has been increasingly recognized. AFM provides the opportunity to both image samples at nanometer resolution and also measure the forces on the surface of the sample. Here, we describe a variety of methods for studying nuclear samples including single nucleic acid molecules, higher-order chromatin structures, the nucleolus, and the nucleus. Protocols to prepare nucleic acids, nucleic acid-protein complexes, reconstituted chromatin, the cell nucleus, and the nucleolus are included, as well as protocols describing how to prepare the AFM substrate and the AFM tip. Finally, we describe how to perform conventional imaging, high-speed imaging, recognition imaging, force spectroscopy, and nanoindentation experiments.

Structural Analysis of Long Single-Stranded RNA Molecules with Atomic Force Microscopy Imaging

Characterization of the structure of long RNA molecules (>1 kb) is usually a time-consuming and tedious process. In this study, we have developed an imaging procedure for obtaining images of the extended secondary structures of long RNA molecules combined with automated MATLAB-based data processing algorithms for identification of the domain architecture of the molecules in these images. These algorithms include a molecule autoselection procedure based on height and area thresholding, a morphological thinning procedure to generate skeletons of the molecule in order to analyze the branched structure of the molecules, and a procedure to generate local volume profiles along the main chain of the molecule for identification of domains and prediction of the number of nucleotides comprising each domain. The single-molecule nature of this technique also allows for the identification of varying conformations of the molecule and assessment of the conformational flexibility of the identified domain organization.

RecA Regulation by RecU and DprA During Bacillus subtilis Natural Plasmid Transformation

Natural plasmid transformation plays an important role in the dissemination of antibiotic resistance genes in bacteria. During this process, Bacillus subtilis RecA physically interacts with RecU, RecX, and DprA. These three proteins are required for plasmid transformation, but RecA is not. In vitro, DprA recruits RecA onto SsbA-coated single-stranded (ss) DNA, whereas RecX inhibits RecA filament formation, leading to net filament disassembly. We show that a null recA (ΔrecA) mutation suppresses the plasmid transformation defect of competent ΔrecU cells, and that RecU is essential for both chromosomal and plasmid transformation in the ΔrecX context. RecU inhibits RecA filament growth and facilitates RecA disassembly from preformed filaments. Increasing SsbA concentrations additively contributes to RecU-mediated inhibition of RecA filament extension. DprA is necessary and sufficient to counteract the negative effect of both RecU and SsbA on RecA filament growth onto ssDNA. DprA-SsbA activates RecA to catalyze DNA strand exchange in the presence of RecU, but this effect was not observed if RecU was added prior to RecA. We propose that DprA contributes to RecA filament growth onto any internalized SsbA-coated ssDNA. When the ssDNA is homologous to the recipient, DprA antagonizes the inhibitory effect of RecU on RecA filament growth and helps RecA to catalyze chromosomal transformation. On the contrary, RecU promotes RecA filament disassembly from a heterologous (plasmid) ssDNA, overcoming an unsuccessful homology search and favoring plasmid transformation. The DprA–DprA interaction may promote strand annealing upon binding to the complementary plasmid strands and facilitating thereby plasmid transformation rather than through a mediation of RecA filament growth.