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Cell Organelle Isolation Kits

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F-actin is visible in the cells as long straight lines that cover the cells. These lines cover the entire image as the cells cover the image.

TRITC-conjugated F-actin in ProteoExtract Cytoskeleton Enrichment and Staining Kit-treated cells.

Small dots cover the surface of the cells, so no dot is completely visible. The cells cover the top of the image and expands into the bottom middle of the image.

Focal point contacts visualized using Vinculin antibody and FITC-conjugated secondary antibody in non-ProteoExtract Cytoskeleton Enrichment and Staining Kit-treated cells.

Small dots cover the surface of the cells so no dot is completely visible. F-actin is visible in cells as long straight lines that cover the cell. The nucleus is visible as an oval in the middle of each of the cells. These cells cover the top of the image and extend into the bottom middle of the image.

F-actin, focal point contacts, and the nucleus is visualized and overlaid in non-ProteoExtract Cytoskeleton Enrichment and Staining Kit-treated cells.

F-actin is visible in the cells as long straight lines that cover the cells. These lines cover the top of the image and expand into the bottom middle of the image.

TRITC-conjugated F-actin in non-ProteoExtract Cytoskeleton Enrichment and Staining Kit-treated cells.

Small dots cover the surface of the cells, and each dot is visible from another. The cells cover the entirety of the image.

Focal point contacts visualized using Vinculin antibody and FITC-conjugated secondary antibody in ProteoExtract Cytoskeleton Enrichment and Staining Kit-treated cells.

Small dots cover the surface of the cells, and each dot is visible from another. F-actin is visible in the cells as long straight lines that cover the cells. The nucleus is visible as an oval in the middle of each of the cells. These cells cover the entirety of the image.

F-actin, focal point contacts, and the nucleus is visualized and overlaid in ProteoExtract Cytoskeleton Enrichment and Staining Kit-treated cells.

Although the study of cells derived from in vivo tissues is most predictive of cellular biology and function, biological complexity can confound results unless target cell populations are isolated. In order to study cell phenotypes, diverse methods have evolved for isolating cell populations based on definitive characteristics. Isolating cell populations not only aids biological research, but also facilitates clinical diagnostic testing. The most effective isolation methods demonstrate enhanced yield, purity, and viability. Enrichment or purification of target populations can be achieved by positive selection─often employing antibodies that bind cell-specific markers─or by negative selection that may use biophysical properties to deplete unwanted cells in order to enrich for the target population.

Fractionation of cells into their subcellular components has long been fundamental to cell biology studies. Subcellular fractionation techniques have been widely used to study structure and function of organelles and subcellular compartments, as well as to understand the location, processing, and trafficking of biomolecules. The goal of most fractionation techniques is to obtain organelles and cellular macromolecules in a functional state, where they retain their intrinsic biochemical properties. This is often achieved by cell lysis employing gentle mechanical means or with mild detergents, frequently followed by fractionation of cellular components by differential centrifugation.

Cells are filled with circles of various sizes indicating lipid droplets. The visible lipid droplets and cells span the foreground of the image.

Visible lipid droplets confirm the isolation of preadipocytes 7 days after differentiation using 3T3-L1 Differentiation Kit.

Organelles and Subcellular Complexes Isolation Kits

Derivation of subcellular components promotes understanding of organelle function and can lead to new biotechnologies. For example, nuclei isolated from mammalian cells can subsequently be used for the synthesis of endogenous RNA primary transcripts. The high-yield Nuclei EZ Prep Kit (NUC101, NUC201) was developed for the rapid isolation of nuclei from most mammalian cells.

For the detection of mitochondrial integrity and membrane potential, our mitochondrial staining kit (CS0390, CS0760) uses the JC-1 dye (420200, T4069), which concentrates in the mitochondrial matrix to form red fluorescent aggregates. Events like apoptosis that dissipate the mitochondrial membrane potential prevent the accumulation of JC-1 dye in the mitochondria, and a fluorescence microscope can then be used to distinguish viable from compromised mitochondria.

Non-organelle subcellular complexes like proteasomes can also be isolated for use in proteolytic assays. Our method uses affinity matrix beads containing a GST-fusion protein with a ubiquitin-like domain bound to GST-agarose.

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