Electrochemically controllable conjugation of proteins on surfaces

The rational design of surfaces for immobilization of proteins is essential to a variety of biological and medical applications ranging from molecular diagnostics to advanced platforms for fundamental studies of molecular and cell biology. We have developed an advanced electrochemically based approach for site-selective and reaction-controlled immobilization of proteins on surfaces. When a molecular monolayer of 4-nitrothiophenol on gold electrode surfaces is reduced electrochemically in a selective fashion at its nitro groups, to afford amino groups by potentiometric scans, the amine can be employed to orchestrate the immobilization of proteins to the surface. This protein immobilization strategy could allow one to fabricate intricate protein structures on surfaces for addressing fundamental and applied problems in biology and medicine.     

Rapid micropatterning of cell lines and human pluripotent stem cells on elastomeric membranes

Tissue function during development and in regenerative medicine completely relies on correct cell organization and patterning at micro and macro scales. We describe a rapid method for patterning mammalian cells including human embryonic stem cells (HESCs) and induced pluripotent stem cells (iPSCs) on elastomeric membranes such that micron‐scale control of cell position can be achieved over centimeter‐length scales. Our method employs surface engineering of hydrophobic polydimethylsiloxane (PDMS) membranes by plasma polymerization of allylamine. Deposition of plasma polymerized allylamine (ppAAm) using our methods may be spatially restricted using a micro‐stencil leaving faithful hydrophilic ppAAm patterns. We employed airbrushing to create aerosols which deposit extracellular matrix (ECM) proteins (such as fibronectin and Matrigel?) onto the same patterned ppAAm rich regions. Cell patterns were created with a variety of well characterized cell lines (e.g., NIH‐3T3, C2C12, HL1, BJ6, HESC line HUES7, and HiPSC line IPS2). Individual and multiple cell line patterning were also achieved. Patterning remains faithful for several days and cells are viable and proliferate. To demonstrate the utility of our technique we have patterned cells in a variety of configurations. The ability to rapidly pattern cells at high resolution over macro scales should aid future tissue engineering efforts for regenerative medicine applications and in creating in vitro stem cell niches. Biotechnol. Bioeng. 2012; 109: 2630–2641. © 2012 Wiley Periodicals, Inc.     

Membrane bending by protein-protein crowding

Curved membranes are an essential feature of dynamic cellular structures, including endocytic pits, filopodia protrusions and most organelles. It has been proposed that specialized proteins induce curvature by binding to membranes through two primary mechanisms: membrane scaffolding by curved proteins or complexes; and insertion of wedge-like amphipathic helices into the membrane. Recent computational studies have raised questions about the efficiency of the helix-insertion mechanism, predicting that proteins must cover nearly 100% of the membrane surface to generate high curvature, an improbable physiological situation. Thus, at present, we lack a sufficient physical explanation of how protein attachment bends membranes efficiently. On the basis of studies of epsin1 and AP180, proteins involved in clathrin-mediated endocytosis, we propose a third general mechanism for bending fluid cellular membranes: protein-protein crowding. By correlating membrane tubulation with measurements of protein densities on membrane surfaces, we demonstrate that lateral pressure generated by collisions between bound proteins drives bending. Whether proteins attach by inserting a helix or by binding lipid heads with an engineered tag, protein coverage above ~20% is sufficient to bend membranes. Consistent with this crowding mechanism, we find that even proteins unrelated to membrane curvature, such as green fluorescent protein (GFP), can bend membranes when sufficiently concentrated. These findings demonstrate a highly efficient mechanism by which the crowded protein environment on the surface of cellular membranes can contribute to membrane shape change.     

Dynamic Association with Donor Cell Filopodia and Lipid-Modification Are Essential Features of Wnt8a during Patterning of the Zebrafish Neuroectoderm

Background

Wnt proteins are conserved signaling molecules that regulate pattern formation during animal development. Many Wnt proteins are post-translationally modified by addition of lipid adducts. Wnt8a provides a crucial signal for patterning the anteroposterior axis of the developing neural plate in vertebrates. However, it is not clear how this protein propagates from its source, the blastoderm margin, to the target cells in the prospective neural plate, and how lipid-modifications might influence Wnt8a propagation and activity.

Results

We have dynamically imaged biologically active, fluorescently tagged Wnt8a in living zebrafish embryos. We find that Wnt8a localizes to membrane-associated, punctate structures in live tissue. In Wnt8a expressing cells, these puncta are found on filopodial cellular processes, from where the protein can be released. In addition, Wnt8a is found colocalized with Frizzled receptor-containing clusters on signal receiving cells. Combining in vitro and in vivo assays, we compare the roles of conserved Wnt8a residues in cell and non-cell-autonomous signaling activity and secretion. Non-signaling Wnt8 variants show these residues can regulate Wnt8a distribution in producing cell membranes and filopodia as well as in the receiving tissue.

Conclusions

Together, our results show that Wnt8a forms dynamic clusters found on filopodial donor cell and on signal receiving cell membranes. Moreover, they demonstrate a differential requirement of conserved residues in Wnt8a protein for distribution in producing cells and receiving tissue and signaling activity during neuroectoderm patterning.     

Micropatterned substratum adhesiveness: a model for morphogenetic cues controlling cell behavior.

It is generally considered that tracks of cell adhesiveness are important in controlling cell migration during the development and regeneration of many tissues. In order to investigate this experimentally, a number of techniques have in the past been employed to make patterns of differential adhesiveness for in vitro studies. However, practical limitations on patterning resolution and the introduction of residual topography to the experimental substrata have restricted their usefulness. Here we describe a simplified photolithographic technique for patterning cell adhesiveness which allows a high degree of flexibility and precision. We have quantified, using adhesion and spreading characteristics of BHK cells, the differential adhesiveness that can be created on patterned surfaces, how this alters with the duration of exposure to serum proteins, and how this, in turn, relates to the persistence of cell patterning despite increases in cell density. We believe that this technique will prove extremely useful for the detailed in vitro examination of the mechanisms controlling cell behavior as it offers a degree of precision and ease of fabrication that has previously been unavailable.     

Surface modification of silicon and gold-patterned silicon surfaces for improved biocompatibility and cell patterning selectivity

Clean silicon and gold-patterned silicon platforms were modified with methoxy-polyethylene glycol (M-PEG silane) via a self-assembly technique, which significantly improved their plasma protein resistance capability and cell patterning selectivity. Fibrinogen and IgG were used as model plasma proteins to study the efficacy of PEG layers in resisting protein adsorption. Selective cell patterning on the gold regions of a gold-patterned silicon substrate and tissue compatibility were studied with macrophage and fibroblast cells. The research also revealed how the presence of gold electrodes on a silicon substrate would influence the cell patterning selectivity. Our experimental results showed that the PEG-modified silicon surfaces had a high resistivity to protein and cell attachment and that the PEG-modified gold-patterned silicon surfaces nearly completely eliminated the protein adsorption and cell attachment on silicon. This study provides a new approach to developing biocompatible surfaces for silicon-based BioMEMS devices, particularly for biosensors where a metal-insulator format must be enforced.     

The ferritin superfamily: Supramolecular templates for materials synthesis

Members of the ferritin superfamily are multi-subunit cage-like proteins with a hollow interior cavity. These proteins possess three distinct surfaces, i.e. interior and exterior surfaces of the cages and interface between subunits. The interior cavity provides a unique reaction environment in which the interior reaction is separated from the external environment. In biology the cavity is utilized for sequestration of irons and biomineralization as a mechanism to render Fe inert and sequester it from the external environment. Material scientists have been inspired by this system and exploited a range of ferritin superfamily proteins as supramolecular templates to encapsulate nanoparticles and/or as well-defined building blocks for fabrication of higher order assembly. Besides the interior cavity, the exterior surface of the protein cages can be modified without altering the interior characteristics. This allows us to deliver the protein cages to a targeted tissue in vivo or to achieve controlled assembly on a solid substrate to fabricate higher order structures. Furthermore, the interface between subunits is utilized for manipulating chimeric self-assembly of the protein cages and in the generation of symmetry-broken Janus particles. Utilizing these ideas, the ferritin superfamily has been exploited for development of a broad range of materials with applications from biomedicine to electronics.     

Micropatterned cell cultures on elastic membranes as an in vitro model of myocardium

We describe here a new in vitro protocol for structuring cardiac cell cultures to mimic important aspects of the in vivo ventricular myocardial phenotype by controlling the location and mechanical environment of cultured cells. Microlithography is used to engineer microstructured silicon metal wafers. Those are used to fabricate either microgrooved silicone membranes or silicone molds for microfluidic application of extracellular matrix proteins onto elastic membranes (involving flow control at micrometer resolution). The physically or microfluidically structured membranes serve as a cell culture growth substrate that supports cell alignment and allows the application of stretch. The latter is achieved with a stretching device that can deliver isotropic or anisotropic stretch. Neonatal ventricular cardiomyocytes, grown on these micropatterned membranes, develop an in vivo-like morphology with regular sarcomeric patterns. The entire process from fabrication of the micropatterned silicon metal wafers to casting of silicone molds, microfluidic patterning and cell isolation and seeding takes approximately 7 days.     

AFM: a nanotool in membrane biology

Cellular membranes are vital for life. They confine cells and cytosolic compartments and are involved in virtually every cellular process. Cellular membranes form cellular contacts and focal adhesions, anchor the cytoskeleton, generate energy gradients, transform energy, transduce signals, move cells, and actively form compartments to assemble different membrane proteins into functional entities. But how do cellular membranes perform these tasks? What do the machineries of cellular membranes look like, and how are they controlled and guided? Atomic force microscopy (AFM) allows the observation of biological surfaces in their native environment at a signal-to-noise ratio superior to that of any optical microscopic technique. With a spatial resolution approaching approximately 1 nm, AFM can identify the supramolecular assemblies, characteristic structure, and functional conformation of native membrane proteins. In recent years, AFM has evolved from imaging applications to a multifunctional "laboratory on a tip" that allows observation and manipulation of the machineries of cellular membranes. In the force spectroscopy mode, AFM detects interactions between two single cells at molecular resolution. Force spectroscopy can also be used to probe the local elasticity, chemical groups, and receptor sites of live cells. Other applications locate molecular interactions driving membrane protein folding, assembly, and their switching between functional states. It is also possible to examine the energy landscape of biomolecular reactions, as well as reaction pathways, associated lifetimes, and free energy. In this review, we provide a flavor of the fascinating opportunities offered by the use of AFM as a nanobiotechnological tool in modern membrane biology.     

Possible Roles for Cognin in Chick Embryo Neural Retina

In this review, we discuss current information about a cell-cellrecognition protein present in chick embryo neural retina. Thisprotein, retina cognin, has cell adhesion or aggregation promotingpropertiesin vitro. We discuss five questions. First, what isretina cognin (R-cognin)? Second, what do we know about cogninin chick retina? We discuss its histological distribution inretina and how that distribution changes during embryonic andearly post-hatching development. Third, where is cognin withincells? We review light microscopy evidence for its localizationin plasma membranes of somas and neurites of selected retinalneurons as an intrinsic membrane protein. Fourth, how is cognindistributed in membranes? We summarize evidence that cogninmight not be uniformly distributed over cellsurfaces and thatit might bind to specific proteins on the surfaces of otherretina cells. From the available information, we ask what wecan deduce about cognin's biological role in the neural retina.     

Lithographic techniques and surface chemistries for the fabrication of PEG-passivated protein microarrays

This article presents a new technique to fabricate patterns of functional molecules surrounded by a coating of the inert poly(ethylene glycol) (PEG) on glass slides for applications in protein microarray technology. The chief advantages of this technique are that it is based entirely on standard lithography processes, makes use of glass slides employing surface chemistries that are standard in the microarray community, and has the potential to massively scale up the density of microarray spots. It is shown that proteins and antibodies can be made to self-assemble on the functional patterns in a microarray format, with the PEG coating acting as an effective passivating agent to prevent non-specific protein adsorption. Various standard surface chemistries such as aldehyde, epoxy and amine are explored for the functional layer, and it is conclusively demonstrated that only an amine-terminated surface satisfies all the process constraints imposed by the lithography process sequence. The effectiveness of this microarray technology is demonstrated by patterning fluorescent streptavidin and a fluorescent secondary antibody using the well-known and highly specific interaction between biotin and streptavidin.     

Patterning of proteins and cells on functionalized surfaces prepared by polyelectrolyte multilayers and micromolding in capillaries

A method for protein and cell patterning on polyelectrolyte-coated surfaces using simple micromolding in capillaries (MIMIC) is described. MIMIC produced two distinctive regions. One contained polyethylene glycol (PEG) microstructures fabricated using photopolymerization that provided physical, chemical, and biological barriers to the nonspecific binding of proteins, bacteria, and fibroblast cells. The second region was the polyelectrolyte (PEL) coated surface that promoted protein and cell immobilization.

The difference in surface functionality between the PEL region and background PEG microstructures resulted in simple patterning of biomolecules. Fluorescein isothiocyanate-tagged bovine serum albumin, E. coli expressing green fluorescence protein (GFP), and fibroblast cells were successfully bound to the exposed PEL surfaces at micron scale. Compared with the simple adsorption of protein, fluorescence intensity was dramatically improved (by about six-fold) on the PEL-modified surfaces. Although animal cell patterning is prerequisite for adhesive protein layer to survive on desired area, the PEL surface without adhesive proteins provides affordable microenvironment for cells.

The simple preparation of functionalized surface but universal platform can be applied to various biomolecules such as proteins, bacteria, and cells.     

Annexin A4 self-association modulates general membrane protein mobility in living cells

Annexins are Ca2+-regulated phospholipid-binding proteins whose function is only partially understood. Annexin A4 is a member of this family that is believed to be involved in exocytosis and regulation of epithelial Cl- secretion. In this work, fluorescent protein fusions of annexin A4 were used to investigate Ca2+-induced annexin A4 translocation and self-association on membrane surfaces in living cells. We designed a novel, genetically encoded, FRET sensor (CYNEX4) that allowed for easy quantification of translocation and self-association. Mobility of annexin A4 on membrane surfaces was investigated by FRAP. The experiments revealed the immobile nature of annexin A4 aggregates on membrane surfaces, which in turn strongly reduced the mobility of transmembrane and plasma membrane associated proteins. Our work provides mechanistic insight into how annexin A4 may regulate plasma membrane protein function.     

Vectorial proteomics

Vectorial proteomics is a methodology for the differential identification and characterization of proteins and their domains exposed to the opposite sides of biological membranes. Proteomics of membrane vesicles from defined isolated membranes automatically determine cellular localization of the identified proteins and reduce complexity of protein characterizations. The enzymatic shaving of naturally-oriented, or specifically-inverted sealed membrane vesicles, release the surface-exposed peptides from membrane proteins. These soluble peptides are amenable to various chromatographic separations and to sequencing by mass spectrometry, which provides information on the topology of membrane proteins and on their posttranslational modifications. The membrane shaving techniques have made a breakthrough in the identification of in vivo protein phosphorylation sites in membrane proteins form plant photosynthetic and plasma membranes, and from caveolae membrane vesicles of human fat cells. This approach has also allowed investigation of dynamics for in vivo protein phosphorylation in membranes from cells exposed to different conditions. Vectorial proteomics of membrane vesicles with retained peripheral proteins identify extrinsic proteins associated with distinct membrane surfaces, as well as a variety of posttranslational modifications in these proteins. The rapid integration of versatile vectorial proteomics techniques in the functional characterization of biological membranes is anticipated to bring significant insights in cell biology.     

Protein Molecular Surface Mapped at Different Geometrical Resolutions

Many areas of biochemistry and molecular biology, both fundamental and applications-orientated, require an accurate construction, representation and understanding of the protein molecular surface and its interaction with other, usually small, molecules. There are however many situations when the protein molecular surface gets in physical contact with larger objects, either biological, such as membranes, or artificial, such as nanoparticles. The contribution presents a methodology for describing and quantifying the molecular properties of proteins, by geometrical and physico-chemical mapping of the molecular surfaces, with several analytical relationships being proposed for molecular surface properties. The relevance of the molecular surface-derived properties has been demonstrated through the calculation of the statistical strength of the prediction of protein adsorption. It is expected that the extension of this methodology to other phenomena involving proteins near solid surfaces, in particular the protein interaction with nanoparticles, will result in important benefits in the understanding and design of protein-specific solid surfaces.     

Revealing Dynamic Processes of Materials in Liquids Using Liquid Cell Transmission Electron Microscopy

The recent development for in situ transmission electron microscopy, which allows imaging through liquids with high spatial resolution, has attracted significant interests across the research fields of materials science, physics, chemistry and biology. The key enabling technology is a liquid cell. We fabricate liquid cells with thin viewing windows through a sequential microfabrication process, including silicon nitride membrane deposition, photolithographic patterning, wafer etching, cell bonding, etc. A liquid cell with the dimensions of a regular TEM grid can fit in any standard TEM sample holder. About 100 nanoliters reaction solution is loaded into the reservoirs and about 30 picoliters liquid is drawn into the viewing windows by capillary force. Subsequently, the cell is sealed and loaded into a microscope for in situ imaging. Inside the TEM, the electron beam goes through the thin liquid layer sandwiched between two silicon nitride membranes. Dynamic processes of nanoparticles in liquids, such as nucleation and growth of nanocrystals, diffusion and assembly of nanoparticles, etc., have been imaged in real time with sub-nanometer resolution. We have also applied this method to other research areas, e.g., imaging proteins in water. Liquid cell TEM is poised to play a major role in revealing dynamic processes of materials in their working environments. It may also bring high impact in the study of biological processes in their native environment.     

Joe Goldstein and Mike Brown: from cholesterol homeostasis to new paradigms in membrane biology

Joe Goldstein and Mike Brown have worked for over 30 years on the molecular basis of cholesterol homeostasis. Through the systematic use of genetics, biochemistry, molecular biology and cell biology, they have identified a complex set of interacting molecules that work coordinately to regulate cholesterol import and synthesis. Not only did they identify the crucial proteins in this pathway but also determined their function. An unexpected outcome of their work has been a new understanding of the structure and function of cell membranes. From the low-density lipoprotein receptor to sterol regulatory element binding protein (SREBP) to SREBP cleavage-activating protein to Insig-1, each protein has provided a new and fundamentally novel insight into how membranes function as molecular sensors that respond to changes in the metabolic condition of the cell by moving molecules between cellular compartments.*     

Potential subversion of autophagosomal pathway by picornaviruses

The RNA replication complexes of small positive-strand RNA viruses such as poliovirus are known to form on the surfaces of membranous vesicles in the cytoplasm of infected mammalian cells. These membranes resemble cellular autophagosomes in their double-membraned morphology, cytoplasmic lumen, lipid-rich composition and the presence of cellular proteins LAMP 1 and LC3. Furthermore, LC3 protein is covalently modified during poliovirus infection in a manner indistinguishable from that observed during bona fide autophagy. This covalent modification can also be induced by the expression of viral protein 2BC in isolation.However, differences between poliovirus-induced vesicles and autophagosomes also exist: the viral-induced membranes are smaller, at 200- 400 nm in diameter, and can be induced by the combination of two viral proteins, termed 2BC and 3A. Experimental suppression of expression of proteins in the autophagy pathway was found to viral yield, arguing that this pathway facilitates viral infection, rather than clearing it. We have hypothesized that, in addition to providing membranous surfaces for assembly of viral RNA replication complexes, double-membraned vesicles provide a topological mechanism to deliver cytoplasmic contents, including mature virus, to the extracellular milieu without lysing the cell.