Your search keyword '"Issue 72"' showing total 8 results

1. Rapid Genetic Analysis of Epithelial-Mesenchymal Signaling During Hair Regeneration

Author

Scott X. Atwood, Wei-Meng Woo, Anthony E. Oro, and Hanson H. Zhen

Subjects

Keratinocytes, Pathology, General Chemical Engineering, Nude, Cell Communication, Regenerative Medicine, Mesoderm, 0302 clinical medicine, lentivirus, Psychology, dermal cells, Skin, 0303 health sciences, integumentary system, General Neuroscience, knockdown, dermis, Cell biology, Cellular Biology, Hair follicle morphogenesis, Dermal papillae, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Medicine, Stem Cell Research - Nonembryonic - Non-Human, Cognitive Sciences, Female, Epithelial Biology, Keratinocyte, Hair Follicle, Biotechnology, Signal Transduction, Cell signaling, medicine.medical_specialty, mice, shRNA-mediated knockdown, 1.1 Normal biological development and functioning, Mesenchyme, Biomedical Engineering, Mice, Nude, keratinocyte, epithelial, transgenic mice, Biology, follicle, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Underpinning research, Genetic model, Genetics, medicine, Animals, Regeneration, Issue 72, 030304 developmental biology, cell culture, Tissue Engineering, General Immunology and Microbiology, animal model, Regeneration (biology), Epithelial Cells, chamber, hair, Stem Cell Research, Hair follicle, graft, Surgery, Biochemistry and Cell Biology, overexpression

Abstract

Hair follicle morphogenesis, a complex process requiring interaction between epithelia-derived keratinocytes and the underlying mesenchyme, is an attractive model system to study organ development and tissue-specific signaling. Although hair follicle development is genetically tractable, fast and reproducible analysis of factors essential for this process remains a challenge. Here we describe a procedure to generate targeted overexpression or shRNA-mediated knockdown of factors using lentivirus in a tissue-specific manner. Using a modified version of a hair regeneration model 5, 6, 11, we can achieve robust gain- or loss-of-function analysis in primary mouse keratinocytes or dermal cells to facilitate study of epithelial-mesenchymal signaling pathways that lead to hair follicle morphogenesis. We describe how to isolate fresh primary mouse keratinocytes and dermal cells, which contain dermal papilla cells and their precursors, deliver lentivirus containing either shRNA or cDNA to one of the cell populations, and combine the cells to generate fully formed hair follicles on the backs of nude mice. This approach allows analysis of tissue-specific factors required to generate hair follicles within three weeks and provides a fast and convenient companion to existing genetic models.

Published

2013

2. Design and Use of Multiplexed Chemostat Arrays

Author

Maitreya J. Dunham, Emily O. Kerr, Aaron W. Miller, and Corrie Befort

Subjects

Physiology, General Chemical Engineering, yeast, Biochemistry, Multiplexing, Ministat, arrays, Throughput (business), Biological Phenomena, Microbiological Phenomena, chemostat, 0303 health sciences, Experimental evolution, General Neuroscience, Eukaryota, Metabolic Phenomena, Genomics, Limiting, Replicate, Life sciences, Cellular Biology, Genetic Phenomena, Cytological Techniques, Environment controlled, high throughput, Chemostat, Biology, Microbiology, General Biochemistry, Genetics and Molecular Biology, Cell Physiological Phenomena, 03 medical and health sciences, Continuous culture, E. coli, evolution, Genetics, experimental evolution, Issue 72, Basic Protocols, Molecular Biology, 030304 developmental biology, cell culture, Bacteria, General Immunology and Microbiology, 030306 microbiology, business.industry, Biotechnology, Saccharomycetales, Biochemical engineering, business, Adaptive evolution

Abstract

Chemostats are continuous culture systems in which cells are grown in a tightly controlled, chemically constant environment where culture density is constrained by limiting specific nutrients.(1,2) Data from chemostats are highly reproducible for the measurement of quantitative phenotypes as they provide a constant growth rate and environment at steady state. For these reasons, chemostats have become useful tools for fine-scale characterization of physiology through analysis of gene expression(3-6) and other characteristics of cultures at steady-state equilibrium.(7) Long-term experiments in chemostats can highlight specific trajectories that microbial populations adopt during adaptive evolution in a controlled environment. In fact, chemostats have been used for experimental evolution since their invention.(8) A common result in evolution experiments is for each biological replicate to acquire a unique repertoire of mutations.(9-13) This diversity suggests that there is much left to be discovered by performing evolution experiments with far greater throughput. We present here the design and operation of a relatively simple, low cost array of miniature chemostats-or ministats-and validate their use in determination of physiology and in evolution experiments with yeast. This approach entails growth of tens of chemostats run off a single multiplexed peristaltic pump. The cultures are maintained at a 20 ml working volume, which is practical for a variety of applications. It is our hope that increasing throughput, decreasing expense, and providing detailed building and operation instructions may also motivate research and industrial application of this design as a general platform for functionally characterizing large numbers of strains, species, and growth parameters, as well as genetic or drug libraries.

Published

2013

3. Detection of Protein Palmitoylation in Cultured Hippocampal Neurons by Immunoprecipitation and Acyl-Biotin Exchange (ABE)

Author

Shernaz X. Bamji and G. Stefano Brigidi

Subjects

Physiology, Acylation, General Chemical Engineering, Hydroxylamine, immunoprecipitation, Hippocampus, Biochemistry, Mice, 0302 clinical medicine, Neurobiology, synapse, palmitoylation, rat, Protein palmitoylation, Cells, Cultured, Neurons, 0303 health sciences, General Neuroscience, Assay, Acyl-Biotin Exchange, Cell biology, Cellular Biology, Biotinylation, Saturated fatty acid, lipids (amino acids, peptides, and proteins), ABE, Immunoprecipitation, Lipoylation, brain, Biotin, Nerve Tissue Proteins, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Palmitoylation, lipid, Animals, Issue 72, Molecular Biology, mouse, 030304 developmental biology, cell culture, western blotting, General Immunology and Microbiology, animal model, Proteins, neuron, Rats, cultured hippocampal neurons, Lipid modification, 030217 neurology & neurosurgery, Neuroscience, Cysteine

Abstract

Palmitoylation is a post-translational lipid modification involving the attachment of a 16-carbon saturated fatty acid, palmitate, to cysteine residues of substrate proteins through a labile thioester bond [reviewed in1]. Palmitoylation of a substrate protein increases its hydrophobicity, and typically facilitates its trafficking toward cellular membranes. Recent studies have shown palmitoylation to be one of the most common lipid modifications in neurons1, 2, suggesting that palmitate turnover is an important mechanism by which these cells regulate the targeting and trafficking of proteins. The identification and detection of palmitoylated substrates can therefore better our understanding of protein trafficking in neurons. Detection of protein palmitoylation in the past has been technically hindered due to the lack of a consensus sequence among substrate proteins, and the reliance on metabolic labeling of palmitoyl-proteins with 3H-palmitate, a time-consuming biochemical assay with low sensitivity. Development of the Acyl-Biotin Exchange (ABE) assay enables more rapid and high sensitivity detection of palmitoylated proteins2-4, and is optimal for measuring the dynamic turnover of palmitate on neuronal proteins. The ABE assay is comprised of three biochemical steps (Figure 1): 1) irreversible blockade of unmodified cysteine thiol groups using N-ethylmaliemide (NEM), 2) specific cleavage and unmasking of the palmitoylated cysteine's thiol group by hydroxylamine (HAM), and 3) selective labeling of the palmitoylated cysteine using a thiol-reactive biotinylation reagent, biotin-BMCC. Purification of the thiol-biotinylated proteins following the ABE steps has differed, depending on the overall goal of the experiment. Here, we describe a method to purify a palmitoylated protein of interest in primary hippocampal neurons by an initial immunoprecipitation (IP) step using an antibody directed against the protein, followed by the ABE assay and western blotting to directly measure palmitoylation levels of that protein, which is termed the IP-ABE assay. Low-density cultures of embryonic rat hippocampal neurons have been widely used to study the localization, function, and trafficking of neuronal proteins, making them ideally suited for studying neuronal protein palmitoylation using the IP-ABE assay. The IP-ABE assay mainly requires standard IP and western blotting reagents, and is only limited by the availability of antibodies against the target substrate. This assay can easily be adapted for the purification and detection of transfected palmitoylated proteins in heterologous cell cultures, primary neuronal cultures derived from various brain tissues of both mouse and rat, and even primary brain tissue itself.

Published

2013

4. Optimized System for Cerebral Perfusion Monitoring in the Rat Stroke Model of Intraluminal Middle Cerebral Artery Occlusion

Author

V Rodriguez Menendez, Carlo Giussani, Giada Padovano, Simone Beretta, G. Pappadà, Davide Carone, Michele Augusto Riva, E Cuccione, A Versace, Carlo Ferrarese, Erik P. Sganzerla, Beretta, S, Riva, M, Carone, D, Cuccione, E, Padovano, G, RODRIGUEZ MENENDEZ, V, Pappadá, G, Versace, A, Giussani, C, Sganzerla, E, and Ferrarese, C

Subjects

medicine.medical_specialty, rat, stroke model, cerebral perfusion, Subarachnoid hemorrhage, Physiology, middle cerebral artery occlusion, General Chemical Engineering, Biomedical Engineering, Perfusion scanning, Laser Doppler, Cerebral autoregulation, General Biochemistry, Genetics and Molecular Biology, Brain Ischemia, Brain ischemia, Neurobiology, Internal medicine, Laser-Doppler Flowmetry, Medicine, Animals, cerebral hemodynamics, ischemic penumbra, rat, Cerebral perfusion pressure, Issue 72, Stroke, intracranial collaterals, General Immunology and Microbiology, business.industry, animal model, General Neuroscience, Hemodynamics, Brain, Infarction, Middle Cerebral Artery, perfusion monitoring, Laser Doppler velocimetry, medicine.disease, Arterial occlusion, Rats, Perfusion, Disease Models, Animal, Anesthesia, Cerebrovascular Circulation, Cardiology, Surgery, Anatomy, business, Neuroscience

Abstract

The translational potential of pre-clinical stroke research depends on the accuracy of experimental modeling. Cerebral perfusion monitoring in animal models of acute ischemic stroke allows to confirm successful arterial occlusion and exclude subarachnoid hemorrhage. Cerebral perfusion monitoring can also be used to study intracranial collateral circulation, which is emerging as a powerful determinant of stroke outcome and a possible therapeutic target. Despite a recognized role of Laser Doppler perfusion monitoring as part of the current guidelines for experimental cerebral ischemia, a number of technical difficulties exist that limit its widespread use. One of the major issues is obtaining a secure and prolonged attachment of a deep-penetration Laser Doppler probe to the animal skull. In this video, we show our optimized system for cerebral perfusion monitoring during transient middle cerebral artery occlusion by intraluminal filament in the rat. We developed in-house a simple method to obtain a custom made holder for twin-fibre (deep-penetration) Laser Doppler probes, which allow multi-site monitoring if needed. A continuous and prolonged monitoring of cerebral perfusion could easily be obtained over the intact skull.

Published

2013

5. Vertical T-maze Choice Assay for Arthropod Response to Odorants

Author

Siddharth Tiwari and Lukasz L. Stelinski

Subjects

Male, General Chemical Engineering, Biochemistry, Pheromones, insect model, anthropod, Phototaxis, Organic Chemicals, chemotaxis, Behavior, Animal, biology, Ecology, General Neuroscience, Eukaryota, Life Sciences (General), psyllid, Attraction, Chemical ecology, Sex pheromone, Female, T-maze, Biological system, Behavioral Sciences, olfaction, attraction, Chemical Actions and Uses, olfactometer, Olfaction, repulsion, General Biochemistry, Genetics and Molecular Biology, Animals, Issue 72, Pesticides, Basic Protocols, Maze Learning, Pest Control, Biological, Molecular Biology, odorant, Arthropods, Behavior, General Immunology and Microbiology, fungi, chemical ecology, Olfactory Perception, biology.organism_classification, Arthropod behavior, Olfactometer, Odor, Diaphorina citri, Insect Repellents, Odorants, insect, Arthropod, Entomology

Abstract

Given the economic importance of insects and arachnids as pests of agricultural crops, urban environments or as vectors of plant and human diseases, various technologies are being developed as control tools. A subset of these tools focuses on modifying the behavior of arthropods by attraction or repulsion. Therefore, arthropods are often the focus of behavioral investigations. Various tools have been developed to measure arthropod behavior, including wind tunnels, flight mills, servospheres, and various types of olfactometers. The purpose of these tools is to measure insect or arachnid response to visual or more often olfactory cues. The vertical T-maze olfactometer described here measures choices performed by insects in response to attractants or repellents. It is a high throughput assay device that takes advantage of the positive phototaxis (attraction to light) and negative geotaxis (tendency to walk or fly upward) exhibited by many arthropods. The olfactometer consists of a 30 cm glass tube that is divided in half with a Teflon strip forming a T-maze. Each half serves as an arm of the olfactometer enabling the test subjects to make a choice between two potential odor fields in assays involving attractants. In assays involving repellents, lack of normal response to known attractants can also be measured as a third variable.

Published

2013

6. Density Gradient Multilayered Polymerization (DGMP): A Novel Technique for Creating Multi-compartment, Customizable Scaffolds for Tissue Engineering

Author

Jerome V. Karpiak, Adah Almutairi, Shivanjali Joshi-Barr, Jessica H. Wen, Yogesh Ner, and Adam J. Engler

Subjects

Scaffold, Materials science, Fluorophore, Density gradient, General Chemical Engineering, Biomedical Engineering, Cell Culture Techniques, Bioengineering, 02 engineering and technology, Polyethylene glycol, Acetates, General Biochemistry, Genetics and Molecular Biology, Polyethylene Glycols, Tissue Culture Techniques, Mice, 03 medical and health sciences, chemistry.chemical_compound, Tissue engineering, Animals, Issue 72, Prepolymer, hydrogels, Cells, Cultured, Fluorescent Dyes, 030304 developmental biology, Scaffolds, cell culture, Muscle Cells, 0303 health sciences, life sciences, Tissue Engineering, Tissue Scaffolds, General Immunology and Microbiology, General Neuroscience, 021001 nanoscience & nanotechnology, bioengineering (general), chemistry, Chemical engineering, Polymerization, Chromones, RGDS, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, polyethylene glycol, Self-healing hydrogels, 0210 nano-technology, Oligopeptides

Abstract

Complex tissue culture matrices, in which types and concentrations of biological stimuli (e.g. growth factors, inhibitors, or small molecules) or matrix structure (e.g. composition, concentration, or stiffness of the matrix) vary over space, would enable a wide range of investigations concerning how these variables affect cell differentiation, migration, and other phenomena. The major challenge in creating layered matrices is maintaining the structural integrity of layer interfaces without diffusion of individual components from each layer1. Current methodologies to achieve this include photopatterning2-3, lithography4, sequential functionalization5, freeze drying6, microfluidics7, or centrifugation8, many of which require sophisticated instrumentation and technical skills. Others rely on sequential attachment of individual layers, which may lead to delamination of layers9. DGMP overcomes these issues by using an inert density modifier such as iodixanol to create layers of varying densities10. Since the density modifier can be mixed with any prepolymer or bioactive molecule, DGMP allows each scaffold layer to be customized. Simply varying the concentration of the density modifier prevents mixing of adjacent layers while they remain aqueous. Subsequent single step polymerization gives rise to a structurally continuous multilayered scaffold, in which each layer has distinct chemical and mechanical properties. The density modifier can be easily removed with sufficient rinsing without perturbation of the individual layers or their components. This technique is therefore well suited for creating hydrogels of various sizes, shapes, and materials. A protocol for fabricating a 2D-polyethylene glycol (PEG) gel, in which alternating layers incorporate RGDS-350, is outlined below. We use PEG because it is biocompatible and inert. RGDS, a cell adhesion peptide11, is used to demonstrate spatial restriction of a biological cue, and the conjugation of a fluorophore (Alexa Fluor 350) enables us to visually distinguish various layers. This procedure can be adapted for other materials (e.g. collagen, hyaluronan, etc.) and can be extended to fabricate 3D gels with some modifications10.

Published

2013

7. Origami Inspired Self-assembly of Patterned and Reconfigurable Particles

Author

Evin Gultepe, Shivendra Pandey, and David H. Gracias

Subjects

synthesis, Polymers, General Chemical Engineering, Nanoparticle, reaction, 02 engineering and technology, 01 natural sciences, law.invention, Planar, law, origami, Electrochemistry, Nanotechnology, patchy particles, robotics, Physics, General Neuroscience, Chemical Engineering, 021001 nanoscience & nanotechnology, 3. Good health, Chemistry, Nanolithography, Metals, Microtechnology, lithography, nano, 0210 nano-technology, three dimensional, Microfabrication, assembly, Silicon, Manufactured Materials, Surface Properties, Biomolecular Engineering, Materials Science, Hinge, 010402 general chemistry, General Biochemistry, Genetics and Molecular Biology, Residual stress, Particle Size, Issue 72, colloid, Lithography, Molecular Self-assembly, microfabrication, particles, General Immunology and Microbiology, Folding, 0104 chemical sciences, drug delivery, nanofabrication, nanoparticles, Glass, Photolithography

Abstract

There are numerous techniques such as photolithography, electron-beam lithography and soft-lithography that can be used to precisely pattern two dimensional (2D) structures. These technologies are mature, offer high precision and many of them can be implemented in a high-throughput manner. We leverage the advantages of planar lithography and combine them with self-folding methods(1-20) wherein physical forces derived from surface tension or residual stress, are used to curve or fold planar structures into three dimensional (3D) structures. In doing so, we make it possible to mass produce precisely patterned static and reconfigurable particles that are challenging to synthesize. In this paper, we detail visualized experimental protocols to create patterned particles, notably, (a) permanently bonded, hollow, polyhedra that self-assemble and self-seal due to the minimization of surface energy of liquefied hinges(21-23) and (b) grippers that self-fold due to residual stress powered hinges(24,25). The specific protocol described can be used to create particles with overall sizes ranging from the micrometer to the centimeter length scales. Further, arbitrary patterns can be defined on the surfaces of the particles of importance in colloidal science, electronics, optics and medicine. More generally, the concept of self-assembling mechanically rigid particles with self-sealing hinges is applicable, with some process modifications, to the creation of particles at even smaller, 100 nm length scales(22, 26) and with a range of materials including metals(21), semiconductors(9) and polymers(27). With respect to residual stress powered actuation of reconfigurable grasping devices, our specific protocol utilizes chromium hinges of relevance to devices with sizes ranging from 100 μm to 2.5 mm. However, more generally, the concept of such tether-free residual stress powered actuation can be used with alternate high-stress materials such as heteroepitaxially deposited semiconductor films(5,7) to possibly create even smaller nanoscale grasping devices.

Published

2013

8. LabVIEW-operated Novel Nanoliter Osmometer for Ice Binding Protein Investigations

Author

Ido Braslavsky and Ran Drori

Subjects

antifreeze proteins, General Chemical Engineering, Analytical chemistry, Video microscopy, 01 natural sciences, Biochemistry, Crystal, thermal hysteresis proteins, Nanotechnology, Marinomonas, 0303 health sciences, Ice crystals, Physics, General Neuroscience, Thermistor, recrystallization inhibition proteins, Freezing point, Chemistry, Ice binding, TH, nano, Crystallization, Thermoelectric cooling, Biophysics, microfluidics, Bioengineering, IBP, 010402 general chemistry, Microbiology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, microscopy stage, LabVIEW, nanoliter osmometer, Issue 72, microscale chemistry, temperature control, 030304 developmental biology, Automation, Laboratory, Temperature control, General Immunology and Microbiology, Ice, Osmolar Concentration, Proteins, Ice binding proteins, 0104 chemical sciences, Gibbs-Thomson effect, 13. Climate action, ice structuring proteins, Software

Abstract

Ice-binding proteins (IBPs), including antifreeze proteins, ice structuring proteins, thermal hysteresis proteins, and ice recrystallization inhibition proteins, are found in cold-adapted organisms and protect them from freeze injuries by interacting with ice crystals. IBPs are found in a variety of organism, including fish(1), plants(2, 3), arthropods(4, 5), fungi(6), and bacteria(7). IBPs adsorb to the surfaces of ice crystals and prevent water molecules from joining the ice lattice at the IBP adsorption location. Ice that grows on the crystal surface between the adsorbed IBPs develops a high curvature that lowers the temperature at which the ice crystals grow, a phenomenon referred to as the Gibbs-Thomson effect. This depression creates a gap (thermal hysteresis, TH) between the melting point and the nonequilibrium freezing point, within which ice growth is arrested(8-10), see Figure 1. One of the main tools used in IBP research is the nanoliter osmometer, which facilitates measurements of the TH activities of IBP solutions. Nanoliter osmometers, such as the Clifton instrument (Clifton Technical Physics, Hartford, NY,) and Otago instrument (Otago Osmometers, Dunedin, New Zealand), were designed to measure the osmolarity of a solution by measuring the melting point depression of droplets with nanoliter volumes. These devices were used to measure the osmolarities of biological samples, such as tears(11), and were found to be useful in IBP research. Manual control over these nanoliter osmometers limited the experimental possibilities. Temperature rate changes could not be controlled reliably, the temperature range of the Clifton instrument was limited to 4,000 mOsmol (about -7.5 °C), and temperature recordings as a function of time were not an available option for these instruments. We designed a custom-made computer-controlled nanoliter osmometer system using a LabVIEW platform (National Instruments). The cold stage, described previously(9, 10), contains a metal block through which water circulates, thereby functioning as a heat sink, see Figure 2. Attached to this block are thermoelectric coolers that may be driven using a commercial temperature controller that can be controlled via LabVIEW modules, see Figure 3. Further details are provided below. The major advantage of this system is its sensitive temperature control, see Figure 4. Automated temperature control permits the coordination of a fixed temperature ramp with a video microscopy output containing additional experimental details. To study the time dependence of the TH activity, we tested a 58 kDa hyperactive IBP from the Antarctic bacterium Marinomonas primoryensis (MpIBP)(12). This protein was tagged with enhanced green fluorescence proteins (eGFP) in a construct developed by Peter Davies' group (Queens University)(10). We showed that the temperature change profile affected the TH activity. Excellent control over the temperature profile in these experiments significantly improved the TH measurements. The nanoliter osmometer additionally allowed us to test the recrystallization inhibition of IBPs(5, 13). In general, recrystallization is a phenomenon in which large crystals grow larger at the expense of small crystals. IBPs efficiently inhibit recrystallization, even at low concentrations(14, 15). We used our LabVIEW-controlled osmometer to quantitatively follow the recrystallization of ice and to enforce a constant ice fraction using simultaneous real-time video analysis of the images and temperature feedback from the sample chamber(13). The real-time calculations offer additional control options during an experimental procedure. A stage for an inverted microscope was developed to accommodate temperature-controlled microfluidic devices, which will be described elsewhere(16). The Cold Stage System The cold stage assembly (Figure 2) consists of a set of thermoelectric coolers that cool a copper plate. Heat is removed from the stage by flowing cold water through a closed compartment under the thermoelectric coolers. A 4 mm diameter hole in the middle of the copper plate serves as a viewing window. A 1 mm diameter in-plane hole was drilled to fit the thermistor. A custom-made copper disc (7 mm in diameter) with several holes (500 μm in diameter) was placed on the copper plate and aligned with the viewing window. Air was pumped at a flow rate of 35 ml/sec and dried using Drierite (W.A. Hammond). The dry air was used to ensure a dry environment at the cooling stage. The stage was connected via a 9 pin connection outlet to a temperature controller (Model 3040 or 3150, Newport Corporation, Irvine, California, US). The temperature controller was connected via a cable to a computer GPIB-PCI card (National instruments, Austin, Texas, USA).

Published

2013