Super-resolution fluorescence micrograph of a giant HepAD38 human liver cell surrounded by smaller cells. The image shows the actin cytoskeleton in cyan.Super-resolution fluorescence micrograph of a primary Human Foreskin Fibroblast cell. The actin cytoskeleton is shown in a blue to green to yellow palette.Super-resolution fluorescence micrograph of a primary Mouse Embryonic Fibroblast (MEF) cell cultivated on a poly-L-lysine covered substrate. The actin cytoskeleton, forming a massive central ring and peripheral extensions, is stained in a grey to black to orange Lookup Table. The cell nucleus containing DNA is stained cyan.Super-resolution fluorescence micrograph of NIH3T3 mouse fibroblast cells expressing the Vesicular Stomatitis Virus G glycoprotein (VSV-G). The VSV-G transmembrane protein (gold) is a viral fusion protein that causes cells to fuse together, forming large multinucleated cells known as syncytia. Here, a small syncytium is seen assimilating surrounding cells. Membrane debris attest to cell movement. The actin cytoskeleton is stained cyan and cell nuclei are grey.Super-resolution fluorescence micrograph of a primary brain-derived cell from a Boa constrictor. The image highlights the complex actin cytoskeleton, stained yellow, showing a prominent meshwork and distinct stress fibers. The cell nucleus, containing DNA, is stained pink.Super-resolution fluorescence micrograph of a syncytium formed by NIH3T3 mouse fibroblast cells expressing the Vesicular Stomatitis Virus G glycoprotein (VSV-G), in yellow. The actin cytoskeleton is stained cyan and cell nuclei containing DNA are stained orange.Super-resolution fluorescence micrograph of a primary Human Foreskin Fibroblast cell. The actin cytoskeleton is stained blue. The microtubule network is stained pink. The vimentin network is stained orange. The cell nucleus containing DNA is stained grey.Super-resolution fluorescence micrograph of a developing syncytium in NIH3T3 mouse fibroblast cells. The cells express the Vesicular Stomatitis Virus G glycoprotein (VSV-G), in gold. VSV-G is a fusion protein that merges the plasma membranes of adjacent cells, creating a single multinucleated cell (syncytium). The actin cytoskeleton is stained cyan and cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph of a primary brain-derived cell from a Boa constrictor. The cells express the Vesicular Stomatitis Virus G glycoprotein (VSV-G), stained white. The actin cytoskeleton, displaying prominent stress fibers, is stained cyan. Cell nuclei containing DNA are stained red.Super-resolution fluorescence micrograph of primary brain-derived cells from a Boa constrictor. The cells express the Vesicular Stomatitis Virus G glycoprotein (VSV-G), stained magenta, which highlights the plasma membrane and delicate membrane prolongations. The actin cytoskeleton, displaying prominent stress fibers, is stained yellow. Cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph of a primary brain-derived cell from a Boa constrictor. The cell expresses the Vesicular Stomatitis Virus G glycoprotein (VSV-G), stained cyan, which highlights the plasma membrane and numerous spiky protrusions extending from the cell surface. The actin cytoskeleton, displaying prominent stress fibers, is stained yellow. The cell nucleus containing DNA is stained pink.Super-resolution fluorescence micrograph of HepAD38 human liver cells displaying varied morphologies. The image shows the actin cytoskeleton in magenta.Super-resolution fluorescence micrograph of a COS7 cell. The actin cytoskeleton, forming the cell cortex and stress fibers, is stained white. The microtubule network, radiating from the center to the periphery, is stained gold. The cell nucleus containing DNA is stained orange.Super-resolution fluorescence micrograph of a HepAD38 cell. The actin cytoskeleton, revealing many spiky cell extensions, is stained cyan. The cell nucleus containing DNA is stained yellow.Super-resolution fluorescence micrograph (Maximum Intensity Projection) of Huh7.5 human liver cells, featuring a giant multinucleated cell. The cells express the human MX1 protein (Myxovirus resistance protein 1), stained magenta. The actin cytoskeleton is stained cyan and cell nuclei containing DNA are stained orange.Super-resolution fluorescence micrograph of a HepAD38 cell. The actin cytoskeleton, is stained white. The Septin 7 network is stained yellow. The cell nucleus containing DNA is stained cyan.Super-resolution fluorescence micrograph of primary Human Foreskin Fibroblast cells. The actin cytoskeleton is stained white. The microtubule network is stained pink. The Septin 7 network is stained yellow. The cell nucleus containing DNA is stained cyan.Super-resolution fluorescence micrograph of four connected fibroblast cells from a Tasmanian devil. The microtubule network is stained cyan, striking through the cell like lightning. The actin cytoskeleton is stained dark grey to black, providing a cloud-like backdrop. Cell nuclei containing DNA are stained orange.Super-resolution fluorescence micrograph of a syncytium formed by primary kidney-derived cells from a Boa constrictor. The cells express the Vesicular Stomatitis Virus G glycoprotein (VSV-G), a viral fusion protein that causes plasma membranes to merge, creating a massive multinucleated cell. VSV-G is shown in gold and the actin cytoskeleton is displayed in white, revealing a dense structural network. Cell nuclei containing DNA are stained cyan.Super-resolution fluorescence micrograph of a fibroblast cell from a Tasmanian devil. The image highlights the complex cytoskeletal architecture of the cell. The actin filaments are stained cyan and the microtubule network is stained yellow. The cell nucleus containing DNA is stained pink.Super-resolution fluorescence micrograph of a syncytium formed by primary kidney-derived cells from a Boa constrictor. The cells express the Vesicular Stomatitis Virus G glycoprotein (VSV-G), stained gold. VSV-G is a viral fusion protein that causes plasma membranes to merge, creating a large multinucleated cell known as a syncytium. The microtubule cytoskeleton is stained cyan, highlighting the internal transport network. Cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph of the nucleus of a NIH3T3 mouse fibroblast cell, replicating the rodent deltavirus (RDeV), in cyan. DNA is stained in orange.Super-resolution fluorescence micrograph of primary Human Foreskin Fibroblast cells showing striking cytoskeletal organization. The actin cytoskeleton is stained gold, displaying prominent stress fibers and distinct star-like patterns. Septin 7, a GTP-binding protein that forms a fourth component of the cytoskeleton, is stained cyan. Cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph of a monolayer of connected fibroblast cells from a Tasmanian devil. The actin network is stained orange, revealing dense stress fibers. Cell nuclei containing DNA are stained cyan.Super-resolution fluorescence micrograph of a fibroblast cell from a Tasmanian devil. The cell expresses Aquaporin-4, a water channel protein tagged with GFP and displayed in purple. The actin cytoskeleton is stained white, and the cell nucleus containing DNA is stained orange.Super-resolution fluorescence micrograph of a primary fibroblast cell isolated from a mouse ear. This particular cell exhibits a giant, elongated morphology, stretching across a large area. The actin cytoskeleton, stained magenta, and the microtubule network, stained cyan, provide the structural support necessary for this extensive shape. The cell nucleus containing DNA is stained orange.Super-resolution fluorescence micrograph of a COS7 cell. The microtubule cytoskeleton is stained purple. The actin cytoskeleton is stained orange. The nucleus, containing DNA, is stained grey.Super-resolution fluorescence micrograph of a primary Mouse Embryonic Fibroblast (MEF) cell displaying a distinctive morphology resembling a jellyfish. The actin cytoskeleton, which outlines the cell's "bell" and "tentacles," is stained cyan. The microtubule network provides internal structural support and is stained green. The cell nucleus containing DNA is stained orange.Confocal fluorescence micrograph of A549 human lung cells infected with Influenza A virus (H3N2) for 24 hours. The viral Nucleoprotein, which encapsidates the viral genome, is stained cyan. COPII vesicles that mark Endoplasmic Reticulum exit sites, are stained gold. These sites are critical for the trafficking of newly synthesized viral proteins. Cell nuclei containing DNA are stained orange.Super-resolution fluorescence micrograph of a COS7 cell undergoing cell division (mitosis). The microtubule cytoskeleton, which forms the mitotic spindle responsible for segregating chromosomes, is stained cyan. The separated masses of chromosomes (DNA) are stained orange.Confocal fluorescence micrograph of A549 human lung cells infected with Influenza A virus (H3N2) for 24 hours. The image highlights the relationship between the virus and the host cell architecture. The viral Nucleoprotein, which encapsidates the viral genome, is stained blue. The microtubule cytoskeleton, often hijacked by viruses for intracellular transport, is stained gold. Cell nuclei containing DNA are stained pink.Super-resolution fluorescence micrograph of Vero cells expressing the antiviral protein MX1 (Myxovirus resistance protein 1), stained red. The actin cytoskeleton is stained cyan, and cell nuclei containing DNA are stained grey.Confocal fluorescence micrograph of A549 human lung cells infected with Influenza A virus (H3N2) for 24 hours. The image reveals the complex transport machinery hijacked by the virus. The viral Nucleoprotein is stained cyan. Rab11, a marker for recycling endosomes that the virus uses to transport its genome to the plasma membrane for budding, is stained pink. The microtubule cytoskeleton, acting as the tracks for this transport, is stained yellow. Cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph of an A549 human lung cancer cell. The Septin 7 cytoskeleton is stained cyan. MX1 (Myxovirus resistance protein 1), an interferon-induced GTPase that plays a key role in antiviral immunity, is stained orange. The cell nucleus containing DNA is stained yellow.Confocal fluorescence micrograph of A549 human lung cancer cells expressing a mutant form of the mouse MX1 protein that forms giant snake-like structures within cells, stained red. Cell nuclei containing DNA are stained yellow.Confocal fluorescence micrograph of differentiated LUHMES (Lund Human Mesencephalic) neurons, revealing the three major components of the cytoskeleton. The actin filaments are stained cyan. The microtubule network is stained purple. Vimentin is stained gold. Cell nuclei containing DNA are stained green.Confocal fluorescence micrograph of A549 human lung cancer cells, infected with influenza A virus (H3N2), stained cyan, and expressing a mutant form of the mouse Mx1 protein (L7A), stained orange. Cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph a giant A549 human lung cancer cell surrounded by normal sized cells. The microtubule networkis stained cyan. Mx1 (Myxovirus resistance protein 1), an interferon-induced GTPase that plays a key role in antiviral immunity, is stained green. The cell nucleus containing DNA is stained orange.Super-resolution fluorescence micrograph of Mouse Embryonic Fibroblasts (MEFs). The image is presented in a monochrome palette to emphasize structural details. The actin cytoskeleton, showing the cell's internal framework, is displayed in shades of grey to black. Cell nuclei containing DNA are stained white.Super-resolution fluorescence micrograph of a migrating NIH3T3 mouse fibroblast cell. The cell expresses the Vesicular Stomatitis Virus G glycoprotein (VSV-G), stained white. The actin cytoskeleton is stained cyan, revealing the structural network driving cell motility. The cell nucleus containing DNA is stained red.Super-resolution fluorescence micrograph of a forming syncytium in Tasmanian devil fibroblast cells. The cells express the Vesicular Stomatitis Virus G glycoprotein (VSV-G), stained white, which causes the plasma membranes of neighboring cells to fuse into a single multinucleated body. The actin cytoskeleton is stained purple, providing structural support during this dramatic reorganization. Cell nuclei containing DNA are stained orange.Super-resolution fluorescence micrograph of an NIH3T3 mouse fibroblast cell displaying a distinctive morphology resembling a bird in flight. The cell expresses the Vesicular Stomatitis Virus G glycoprotein (VSV-G), stained yellow to red. The actin cytoskeleton is stained cyan, revealing the structural support for this unique shape. The cell nucleus containing DNA is stained pink. Super-resolution fluorescence micrograph of a monolayer of Vero E6 cells. The actin cytoskeleton is heavily stained gold, revealing the strong structural framework of these epithelial cells. Cell nuclei containing DNA are stained cyan.Confocal fluorescence micrograph of A549 human lung cancer cells expressing a mutant form of the mouse Mx1 protein (L7A), stained orange. While wild-type mouse Mx1 is typically nuclear and spherical, this specific L7A mutant forms distinct, star-like structures within the cell nucleus. Cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph of a single NIH3T3 mouse fibroblast cell. This image highlights the complex interplay of the cytoskeleton using a vibrant false-colour palette. The actin filaments are stained cyan, the microtubule network is stained pink, and the cell nucleus containing DNA is stained orange.Confocal fluorescence micrograph of human embryonic kidney cells. The cells have been transfected to express a VHH (Variable domain of Heavy chain of Heavy chain-only antibody), also known as a nanobody, stained yellow. The actin cytoskeleton is stained magenta and cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph of primary fibroblast cells isolated from a mouse ear. In the center, a single cell is undergoing cell division (mitosis), characterized by its rounded shape and condensed genetic material. The actin cytoskeleton is stained green, and cell nuclei containing DNA are stained pink.Super-resolution fluorescence micrograph of a migrating primary mouse embryonic fibroblast (MEF) cultured on a poly-L-lysine coated surface. The cell displays a polarized morphology characteristic of directional movement, featuring a broad leading edge. The actin cytoskeleton, which drives this motility, is stained gold. Septin 7, a protein that regulates membrane domains during migration, is stained cyan. Intracellular lipid rich regions are visualized in pink, highlighting localized metabolic stores. The nucleus containing DNA is stained blue.Super-resolution fluorescence micrograph of a primary Human Foreskin Fibroblast cell. The actin cytoskeleton is stained red, revealing the cell's structural framework. Cyclin D1, a key protein regulator of the cell cycle, is stained cyan. The cell nucleus containing DNA is stained grey.Super-resolution fluorescence micrograph of a Huh7.5 human hepatoma cell. The actin cytoskeleton is stained gold, outlining the cell structure. Cyclin D1, a regulatory protein that controls the progression of the cell cycle, is stained blue. The cell nucleus containing DNA is stained grey.Super-resolution fluorescence micrograph focusing on the periphery of a giant primary mouse ear fibroblast cultured on a poly-L-lysine coated surface. The adhesive coating promotes extreme spreading, stretching the cell's boundaries. The actin cytoskeleton, which provides the mechanical tension and structural framework required to maintain this massive footprint, is stained magenta. Septin 7, a protein that forms filamentous networks to coordinate membrane dynamics and cytoskeletal organization, is vividly stained green. Lipid rich regions, serving as local metabolic reservoirs, are visualized in blue. Super-resolution fluorescence micrograph of a monolayer of Huh7.5 human hepatoma cells. The actin cytoskeleton is stained gold, revealing the structural connection between neighboring cells. Cell nuclei containing DNA are stained blue.Super-resolution fluorescence micrograph of A549 human lung cancer cells expressing a mutant form of the mouse Mx1 antiviral protein (L7A), stained yellow. Unlike the wild-type protein, this specific L7A mutant forms distinct star-shaped structures within the cell nucleus. The actin cytoskeleton is stained cyan, revealing the cell's internal structure. Cell nuclei containing DNA are stained pink.Super-resolution fluorescence micrograph of LUHMES human neurons infected with Herpes Simplex Virus 1 (HSV-1). The actin cytoskeleton is stained cyan, revealing the intricate network of neurites. Red fluorescence indicates sites of active viral replication within the cells.Super-resolution fluorescence micrograph of a primary fibroblast cell isolated from a mouse tail. The actin cytoskeleton is stained in a gradient of red to orange, revealing complex internal structures and numerous filopodia, thin, finger-like projections used for sensing the environment and cell movement. The cell nucleus containing DNA is stained blue.Super-resolution fluorescence micrograph of the leading edge of an A549 human lung cancer cell. The image highlights the lamellipodium, a broad, sheet-like cytoskeletal projection used for cell migration. The actin cytoskeleton is stained cyan. MX1 (Myxovirus resistance protein 1), an interferon-induced GTPase that plays a key role in antiviral immunity, is stained red. The cell nucleus containing DNA is stained yellow.Super-resolution fluorescence micrograph of LUHMES (Lund Human Mesencephalic) neurons. The image highlights the extensive neurite prolongations (axons and dendrites) extending from the cell bodies, forming a complex neural network. The actin cytoskeleton is stained cyan, and cell nuclei containing DNA are stained orange.Super-resolution fluorescence micrograph of a group of human embryonic kidney cells, with one cell undergoing cell division (mitosis). The dividing cell displays a reorganized microtubule spindle, stained purple, and condensed chromosomes stained grey. The actin cytoskeleton, maintaining the shape of the surrounding cells, is stained red.Super-resolution fluorescence micrograph of Huh7.5 human liver cells. The cells express the antiviral protein MX1 (Myxovirus resistance protein 1), stained magenta. The actin cytoskeleton is stained cyan. Cell nuclei containing DNA are stained grey.Super-resolution fluorescence micrograph of two interacting U2OS human osteosarcoma cells. The actin cytoskeleton, forming the cell cortex and stress fibers, is stained red. The microtubule network is stained blue. Cyclin D1, a key regulatory protein that controls the progression of the cell cycle, is stained cyan. Cell nuclei containing DNA are stained orange.Confocal fluorescence micrograph of A549 human lung cells infected with Influenza A virus (H3N2) for 24 hours. This composite image reveals the interaction between viral components and host cell machinery. The viral Nucleoprotein is stained blue. Rab11, a marker for recycling endosomes hijacked by the virus to transport its genome to the cell surface, is stained pink. The microtubule cytoskeleton, which provides the tracks for this transport, is stained orange. Cell nuclei containing DNA are stained green.Super-resolution fluorescence micrograph of primary fibroblast cells isolated from a mouse ear. The actin cytoskeleton, which maintains cell shape and enables motility, is stained pink. The cell nuclei containing DNA are stained blue.
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