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This is a searchable collection of scientific photos, illustrations, and videos. The images and videos in this gallery are licensed under Creative Commons Attribution Non-Commercial ShareAlike 3.0. This license lets you remix, tweak, and build upon this work non-commercially, as long as you credit and license your new creations under identical terms.

3264: Peripheral nerve cell derived from ES cells
3264: Peripheral nerve cell derived from ES cells
A peripheral nerve cell made from human embryonic stem cell-derived neural crest stem cells. The nucleus is shown in blue, and nerve cell proteins peripherin and beta-tubulin (Tuj1) are shown in green and red, respectively. Related to image 3263.
Stephen Dalton, University of Georgia
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5882: Beta-galactosidase montage showing cryo-EM improvement--transparent background
5882: Beta-galactosidase montage showing cryo-EM improvement--transparent background
Composite image of beta-galactosidase showing how cryo-EM’s resolution has improved dramatically in recent years. Older images to the left, more recent to the right. Related to image 5883. NIH Director Francis Collins featured this on his blog on January 14, 2016.
Veronica Falconieri, Sriram Subramaniam Lab, National Cancer Institute
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5771: Lysosome clusters around amyloid plaques
5771: Lysosome clusters around amyloid plaques
It's probably most people's least favorite activity, but we still need to do it--take out our trash. Otherwise our homes will get cluttered and smelly, and eventually, we'll get sick. The same is true for our cells: garbage disposal is an ongoing and essential activity, and our cells have a dedicated waste-management system that helps keep them clean and neat. One major waste-removal agent in the cell is the lysosome. Lysosomes are small structures, called organelles, and help the body to dispose of proteins and other molecules that have become damaged or worn out.
This image shows a massive accumulation of lysosomes (visualized with LAMP1 immunofluorescence, in purple) within nerve cells that surround amyloid plaques (visualized with beta-amyloid immunofluorescence, in light blue) in a mouse model of Alzheimer's disease. Scientists have linked accumulation of lysosomes around amyloid plaques to impaired waste disposal in nerve cells, ultimately resulting in cell death.
This image shows a massive accumulation of lysosomes (visualized with LAMP1 immunofluorescence, in purple) within nerve cells that surround amyloid plaques (visualized with beta-amyloid immunofluorescence, in light blue) in a mouse model of Alzheimer's disease. Scientists have linked accumulation of lysosomes around amyloid plaques to impaired waste disposal in nerve cells, ultimately resulting in cell death.
Swetha Gowrishankar and Shawn Ferguson, Yale School of Medicine
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2430: Fruit fly retina 01
2430: Fruit fly retina 01
Image showing rhabdomeres (red), the light-sensitive structures in the fruit fly retina, and rhodopsin-4 (blue), a light-sensing molecule.
Hermann Steller, Rockefeller University
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2406: Hen egg lysozyme (2)
2406: Hen egg lysozyme (2)
A crystal of hen egg lysozyme protein created for X-ray crystallography, which can reveal detailed, three-dimensional protein structures.
Alex McPherson, University of California, Irvine
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3787: In vitro assembly of a cell-signaling pathway
3787: In vitro assembly of a cell-signaling pathway
T cells are white blood cells that are important in defending the body against bacteria, viruses and other pathogens. Each T cell carries proteins, called T-cell receptors, on its surface that are activated when they come in contact with an invader. This activation sets in motion a cascade of biochemical changes inside the T cell to mount a defense against the invasion. Scientists have been interested for some time what happens after a T-cell receptor is activated. One obstacle has been to study how this signaling cascade, or pathway, proceeds inside T cells.
In this image, researchers have created a T-cell receptor pathway consisting of 12 proteins outside the cell on an artificial membrane. The image shows two key steps during the signaling process: clustering of a protein called linker for activation of T cells (LAT) (blue) and polymerization of the cytoskeleton protein actin (red). The findings show that the T-cell receptor signaling proteins self-organize into separate physical and biochemical compartments. This new system of studying molecular pathways outside the cells will enable scientists to better understand how the immune system combats microbes or other agents that cause infection.
To learn more how researchers assembled this T-cell receptor pathway, see this press release from HHMI's Marine Biological Laboratory Whitman Center. Related to video 3786.
In this image, researchers have created a T-cell receptor pathway consisting of 12 proteins outside the cell on an artificial membrane. The image shows two key steps during the signaling process: clustering of a protein called linker for activation of T cells (LAT) (blue) and polymerization of the cytoskeleton protein actin (red). The findings show that the T-cell receptor signaling proteins self-organize into separate physical and biochemical compartments. This new system of studying molecular pathways outside the cells will enable scientists to better understand how the immune system combats microbes or other agents that cause infection.
To learn more how researchers assembled this T-cell receptor pathway, see this press release from HHMI's Marine Biological Laboratory Whitman Center. Related to video 3786.
Xiaolei Su, HHMI Whitman Center of the Marine Biological Laboratory
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1337: Bicycling cell
1337: Bicycling cell
A humorous treatment of the concept of a cycling cell.
Judith Stoffer
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5881: Zebrafish larva
5881: Zebrafish larva
You are face to face with a 6-day-old zebrafish larva. What look like eyes will become nostrils, and the bulges on either side will become eyes. Scientists use fast-growing, transparent zebrafish to see body shapes form and organs develop over the course of just a few days. Images like this one help researchers understand how gene mutations can lead to facial abnormalities such as cleft lip and palate in people.
This image won a 2016 FASEB BioArt award. In addition, NIH Director Francis Collins featured this on his blog on January 26, 2017.
This image won a 2016 FASEB BioArt award. In addition, NIH Director Francis Collins featured this on his blog on January 26, 2017.
Oscar Ruiz and George Eisenhoffer, University of Texas MD Anderson Cancer Center, Houston
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3688: Brain cells in the hippocampus
3688: Brain cells in the hippocampus
Hippocampal cells in culture with a neuron in green, showing hundreds of the small protrusions known as dendritic spines. The dendrites of other neurons are labeled in blue, and adjacent glial cells are shown in red.
Shelley Halpain, UC San Diego
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2552: Alternative splicing
2552: Alternative splicing
Arranging exons in different patterns, called alternative splicing, enables cells to make different proteins from a single gene. See image 2553 for a labeled version of this illustration. Featured in The New Genetics.
Crabtree + Company
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3269: Colony of human ES cells
3269: Colony of human ES cells
A colony of human embryonic stem cells (light blue) grows on fibroblasts (dark blue).
California Institute for Regenerative Medicine
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2310: Cellular traffic
2310: Cellular traffic
Like tractor-trailers on a highway, small sacs called vesicles transport substances within cells. This image tracks the motion of vesicles in a living cell. The short red and yellow marks offer information on vesicle movement. The lines spanning the image show overall traffic trends. Typically, the sacs flow from the lower right (blue) to the upper left (red) corner of the picture. Such maps help researchers follow different kinds of cellular processes as they unfold.
Alexey Sharonov and Robin Hochstrasser, University of Pennsylvania
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2635: Mitochondria and endoplasmic reticulum
2635: Mitochondria and endoplasmic reticulum
A computer model shows how the endoplasmic reticulum is close to and almost wraps around mitochondria in the cell. The endoplasmic reticulum is lime green and the mitochondria are yellow. This image relates to a July 27, 2009 article in Computing Life.
Bridget Wilson, University of New Mexico
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3607: Fruit fly ovary
3607: Fruit fly ovary
A fruit fly ovary, shown here, contains as many as 20 eggs. Fruit flies are not merely tiny insects that buzz around overripe fruit—they are a venerable scientific tool. Research on the flies has shed light on many aspects of human biology, including biological rhythms, learning, memory, and neurodegenerative diseases. Another reason fruit flies are so useful in a lab (and so successful in fruit bowls) is that they reproduce rapidly. About three generations can be studied in a single month.
Related to image 3656. This image was part of the Life: Magnified exhibit that ran from June 3, 2014, to January 21, 2015, at Dulles International Airport.
Related to image 3656. This image was part of the Life: Magnified exhibit that ran from June 3, 2014, to January 21, 2015, at Dulles International Airport.
Denise Montell, Johns Hopkins University and University of California, Santa Barbara
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6551: ¿Qué es la sepsis? (Sepsis Infographic)
6551: ¿Qué es la sepsis? (Sepsis Infographic)
La sepsis o septicemia es la respuesta fulminante y extrema del cuerpo a una infección. En los Estados Unidos, más de 1.7 millones de personas contraen sepsis cada año. Sin un tratamiento rápido, la sepsis puede provocar daño de los tejidos, insuficiencia orgánica y muerte. El NIGMS apoya a muchos investigadores en su trabajo para mejorar el diagnóstico y el tratamiento de la sepsis.
Vea 6536 para la versión en inglés de esta infografía.
Vea 6536 para la versión en inglés de esta infografía.
Instituto Nacional de Ciencias Médicas Generales
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3416: X-ray co-crystal structure of Src kinase bound to a DNA-templated macrocycle inhibitor 4
3416: X-ray co-crystal structure of Src kinase bound to a DNA-templated macrocycle inhibitor 4
X-ray co-crystal structure of Src kinase bound to a DNA-templated macrocycle inhibitor. Related to 3413, 3414, 3415, 3417, 3418, and 3419.
Markus A. Seeliger, Stony Brook University Medical School and David R. Liu, Harvard University
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6573: Nuclear Lamina – Three Views
6573: Nuclear Lamina – Three Views
Three views of the entire nuclear lamina of a HeLa cell produced by tilted light sheet 3D single-molecule super-resolution imaging using a platform termed TILT3D.
See 6572 for a 3D view of this structure.
See 6572 for a 3D view of this structure.
Anna-Karin Gustavsson, Ph.D.
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3634: Cells use bubble-like structures called vesicles to transport cargo
3634: Cells use bubble-like structures called vesicles to transport cargo
Cells use bubble-like structures called vesicles (yellow) to import, transport, and export cargo and in cellular communication. A single cell may be filled with thousands of moving vesicles.
This image was part of the Life: Magnified exhibit that ran from June 3, 2014, to January 21, 2015, at Dulles International Airport.
This image was part of the Life: Magnified exhibit that ran from June 3, 2014, to January 21, 2015, at Dulles International Airport.
Tatyana Svitkina, University of Pennsylvania
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3677: Human skeletal muscle
3677: Human skeletal muscle
Cross section of human skeletal muscle. Image taken with a confocal fluorescent light microscope.
Tom Deerinck, National Center for Microscopy and Imaging Research (NCMIR)
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3361: A2A adenosine receptor
3361: A2A adenosine receptor
The receptor is shown bound to an inverse agonist, ZM241385.
Raymond Stevens, The Scripps Research Institute
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6781: Video of Calling Cards in a mouse brain
6781: Video of Calling Cards in a mouse brain
The green spots in this mouse brain are cells labeled with Calling Cards, a technology that records molecular events in brain cells as they mature. Understanding these processes during healthy development can guide further research into what goes wrong in cases of neuropsychiatric disorders. Also fluorescently labeled in this video are neurons (red) and nuclei (blue). Calling Cards and its application are described in the Cell paper “Self-Reporting Transposons Enable Simultaneous Readout of Gene Expression and Transcription Factor Binding in Single Cells” by Moudgil et al.; and the Proceedings of the National Academy of Sciences paper “A viral toolkit for recording transcription factor–DNA interactions in live mouse tissues” by Cammack et al. This video was created for the NIH Director’s Blog post The Amazing Brain: Tracking Molecular Events with Calling Cards.
Related to image 6780.
Related to image 6780.
NIH Director's Blog
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3479: Electrode probe on mouse Huntington's muscle cell
3479: Electrode probe on mouse Huntington's muscle cell
Using an electrode, researchers apply an electrical pulse onto a piece of muscle tissue affected by Huntington's disease.
Grigor Varuzhanyan and Andrew A. Voss, California State Polytechnic University
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2636: Computer model of cell membrane
2636: Computer model of cell membrane
A computer model of the cell membrane, where the plasma membrane is red, endoplasmic reticulum is yellow, and mitochondria are blue. This image relates to a July 27, 2009 article in Computing Life.
Bridget Wilson, University of New Mexico
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2796: Anti-tumor drug ecteinascidin 743 (ET-743), structure without hydrogens 03
2796: Anti-tumor drug ecteinascidin 743 (ET-743), structure without hydrogens 03
Ecteinascidin 743 (ET-743, brand name Yondelis), was discovered and isolated from a sea squirt, Ecteinascidia turbinata, by NIGMS grantee Kenneth Rinehart at the University of Illinois. It was synthesized by NIGMS grantees E.J. Corey and later by Samuel Danishefsky. Multiple versions of this structure are available as entries 2790-2797.
Timothy Jamison, Massachusetts Institute of Technology
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1050: Sea urchin embryo 04
1050: Sea urchin embryo 04
Stereo triplet of a sea urchin embryo stained to reveal actin filaments (orange) and microtubules (blue). This image is part of a series of images: image 1047, image 1048, image 1049, image 1051 and image 1052.
George von Dassow, University of Washington
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3549: TonB protein in gram-negative bacteria
3549: TonB protein in gram-negative bacteria
The green in this image highlights a protein called TonB, which is produced by many gram-negative bacteria, including those that cause typhoid fever, meningitis and dysentery. TonB lets bacteria take up iron from the host's body, which they need to survive. More information about the research behind this image can be found in a Biomedical Beat Blog posting from August 2013.
Phillip Klebba, Kansas State University
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2572: VDAC video 03
2572: VDAC video 03
This video shows the structure of the pore-forming protein VDAC-1 from humans. This molecule mediates the flow of products needed for metabolism--in particular the export of ATP--across the outer membrane of mitochondria, the power plants for eukaryotic cells. VDAC-1 is involved in metabolism and the self-destruction of cells--two biological processes central to health.
Related to videos 2570 and 2571.
Related to videos 2570 and 2571.
Gerhard Wagner, Harvard Medical School
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3616: Weblike sheath covering developing egg chambers in a giant grasshopper
3616: Weblike sheath covering developing egg chambers in a giant grasshopper
The lubber grasshopper, found throughout the southern United States, is frequently used in biology classes to teach students about the respiratory system of insects. Unlike mammals, which have red blood cells that carry oxygen throughout the body, insects have breathing tubes that carry air through their exoskeleton directly to where it's needed. This image shows the breathing tubes embedded in the weblike sheath cells that cover developing egg chambers.
This image was part of the Life: Magnified exhibit that ran from June 3, 2014, to January 21, 2015, at Dulles International Airport.
This image was part of the Life: Magnified exhibit that ran from June 3, 2014, to January 21, 2015, at Dulles International Airport.
Kevin Edwards, Johny Shajahan, and Doug Whitman, Illinois State University.
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2529: Aspirin
2529: Aspirin
Acetylsalicylate (bottom) is the aspirin of today. Adding a chemical tag called an acetyl group (shaded box, bottom) to a molecule derived from willow bark (salicylate, top) makes the molecule less acidic (and easier on the lining of the digestive tract), but still effective at relieving pain. See image 2530 for a labeled version of this illustration. Featured in Medicines By Design.
Crabtree + Company
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3557: Bioluminescent imaging in adult zebrafish - overhead view
3557: Bioluminescent imaging in adult zebrafish - overhead view
Luciferase-based imaging enables visualization and quantification of internal organs and transplanted cells in live adult zebrafish. In this image, a cardiac muscle-restricted promoter drives firefly luciferase expression.
For imagery of both the lateral and overhead view go to 3556.
For imagery of the lateral view go to 3558.
For more information about the illumated area go to 3559.
For imagery of both the lateral and overhead view go to 3556.
For imagery of the lateral view go to 3558.
For more information about the illumated area go to 3559.
Kenneth Poss, Duke University
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2565: Recombinant DNA (with labels)
2565: Recombinant DNA (with labels)
To splice a human gene (in this case, the one for insulin) into a plasmid, scientists take the plasmid out of an E. coli bacterium, cut the plasmid with a restriction enzyme, and splice in insulin-making human DNA. The resulting hybrid plasmid can be inserted into another E. coli bacterium, where it multiplies along with the bacterium. There, it can produce large quantities of insulin. See image 2564 for an unlabeled version of this illustration. Featured in The New Genetics.
Crabtree + Company
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3480: Cancer Cells Glowing from Luciferin
3480: Cancer Cells Glowing from Luciferin
The activator cancer cell culture, right, contains a chemical that causes the cells to emit light when in the presence of immune cells.
Mark Sellmyer, Stanford University School of Medicine
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3729: A molecular switch strips transcription factor from DNA
3729: A molecular switch strips transcription factor from DNA
In this video, Rice University scientists used molecular modeling with a mathematical algorithm called AWSEM (for associative memory, water-mediated, structure and energy model) and structural data to analyze how a transcription factor called nuclear factor kappa B (NFkB) is removed from DNA to stop gene activation. AWSEM uses the interacting energies of their components to predict how proteins fold. At the start, the NFkB dimer (green and yellow, in the center) grips DNA (red, to the left), which activates the transcription of genes. IkB (blue, to the right), an inhibitor protein, stops transcription when it binds to NFkB and forces the dimer to twist and release its hold on DNA. The yellow domain at the bottom of IkB is the PEST domain, which binds first to NFkB. For more details about this mechanism called molecular stripping, see here.
Davit Potoyan and Peter Wolynes
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3283: Mouse heart muscle cells 02
3283: Mouse heart muscle cells 02
This image shows neonatal mouse heart cells. These cells were grown in the lab on a chip that aligns the cells in a way that mimics what is normally seen in the body. Green shows the muscle protein toponin I. Red indicates the muscle protein actin, and blue indicates the cell nuclei. The work shown here was part of a study attempting to grow heart tissue in the lab to repair damage after a heart attack. Image and caption information courtesy of the California Institute for Regenerative Medicine. Related to images 3281 and 3282.
Kara McCloskey lab, University of California, Merced, via CIRM
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5780: Ribosome illustration from PDB
5780: Ribosome illustration from PDB
Ribosomes are complex machines made up of more than 50 proteins and three or four strands of genetic material called ribosomal RNA (rRNA). The busy cellular machines make proteins, which are critical to almost every structure and function in the cell. To do so, they read protein-building instructions, which come as strands of messenger RNA. Ribosomes are found in all forms of cellular life—people, plants, animals, even bacteria. This illustration of a bacterial ribosome was produced using detailed information about the position of every atom in the complex. Several antibiotic medicines work by disrupting bacterial ribosomes but leaving human ribosomes alone. Scientists are carefully comparing human and bacterial ribosomes to spot differences between the two. Structures that are present only in the bacterial version could serve as targets for new antibiotic medications.
From PDB’s Molecule of the Month collection (direct link: http://pdb101.rcsb.org/motm/121) Molecule of the Month illustrations are available under a CC-BY-4.0 license. Attribution should be given to David S. Goodsell and the RCSB PDB.
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5825: A Growing Bacterial Biofilm
5825: A Growing Bacterial Biofilm
A growing Vibrio cholerae (cholera) biofilm. Cholera bacteria form colonies called biofilms that enable them to resist antibiotic therapy within the body and other challenges to their growth.
Each slightly curved comma shape represents an individual bacterium from assembled confocal microscopy images. Different colors show each bacterium’s position in the biofilm in relation to the surface on which the film is growing.
Each slightly curved comma shape represents an individual bacterium from assembled confocal microscopy images. Different colors show each bacterium’s position in the biofilm in relation to the surface on which the film is growing.
Jing Yan, Ph.D., and Bonnie Bassler, Ph.D., Department of Molecular Biology, Princeton University, Princeton, NJ.
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2563: Epigenetic code (with labels)
2563: Epigenetic code (with labels)
The "epigenetic code" controls gene activity with chemical tags that mark DNA (purple diamonds) and the "tails" of histone proteins (purple triangles). These markings help determine whether genes will be transcribed by RNA polymerase. Genes hidden from access to RNA polymerase are not expressed. See image 2562 for an unlabeled version of this illustration. Featured in The New Genetics.
Crabtree + Company
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3391: Protein folding video
3391: Protein folding video
Proteins are long chains of amino acids. Each protein has a unique amino acid sequence. It is still a mystery how a protein folds into the proper shape based on its sequence. Scientists hope that one day they can "watch" this folding process for any given protein. The dream has been realized, at least partially, through the use of computer simulation.
Theoretical and Computational Biophysics Group
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3678: STORM image of axonal cytoskeleton
3678: STORM image of axonal cytoskeleton
This image shows the long, branched structures (axons) of nerve cells. Running horizontally across the middle of the photo is an axon wrapped in rings made of actin protein (green), which plays important roles in nerve cells. The image was captured with a powerful microscopy technique that allows scientists to see single molecules in living cells in real time. The technique is called stochastic optical reconstruction microscopy (STORM). It is based on technology so revolutionary that its developers earned the 2014 Nobel Prize in Chemistry. More information about this image can be found in: K. Xu, G. Zhong, X. Zhuang. Actin, spectrin and associated proteins form a periodic cytoskeleton structure in axons. Science 339, 452-456 (2013).
Xiaowei Zhuang Laboratory, Howard Hughes Medical Institute, Harvard University
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1284: Ion channels
1284: Ion channels
The body uses a variety of ion channels to transport small molecules across cell membranes.
Judith Stoffer
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3487: Ion channel
3487: Ion channel
A special "messy" region of a potassium ion channel is important in its function.
Yu Zhoi, Christopher Lingle Laboratory, Washington University School of Medicine in St. Louis
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1157: Streptococcus bacteria
1157: Streptococcus bacteria
Image of Streptococcus, a type (genus) of spherical bacteria that can colonize the throat and back of the mouth. Stroptococci often occur in pairs or in chains, as shown here.
Tina Weatherby Carvalho, University of Hawaii at Manoa
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2437: Hydra 01
2437: Hydra 01
Hydra magnipapillata is an invertebrate animal used as a model organism to study developmental questions, for example the formation of the body axis.
Hiroshi Shimizu, National Institute of Genetics in Mishima, Japan
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2325: Multicolor STORM
2325: Multicolor STORM
In 2006, scientists developed an optical microscopy technique enabling them to clearly see individual molecules within cells. In 2007, they took the technique, abbreviated STORM, a step further. They identified multicolored probes that let them peer into cells and clearly see multiple cellular components at the same time, such as these microtubules (green) and small hollows called clathrin-coated pits (red). Unlike conventional methods, the multicolor STORM technique produces a crisp and high resolution picture. A sharper view of how cellular components interact will likely help scientists answer some longstanding questions about cell biology.
Xiaowei Zhuang, Harvard University
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2363: PSI: from genes to structures
2363: PSI: from genes to structures
The goal of the Protein Structure Initiative (PSI) is to determine the three-dimensional shapes of a wide range of proteins by solving the structures of representative members of each protein family found in nature. The collection of structures should serve as a valuable resource for biomedical research scientists.
National Institute of General Medical Sciences
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2564: Recombinant DNA
2564: Recombinant DNA
To splice a human gene into a plasmid, scientists take the plasmid out of an E. coli bacterium, cut the plasmid with a restriction enzyme, and splice in human DNA. The resulting hybrid plasmid can be inserted into another E. coli bacterium, where it multiplies along with the bacterium. There, it can produce large quantities of human protein. See image 2565 for a labeled version of this illustration. Featured in The New Genetics.
Crabtree + Company
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2455: Golden gene chips
2455: Golden gene chips
A team of chemists and physicists used nanotechnology and DNA's ability to self-assemble with matching RNA to create a new kind of chip for measuring gene activity. When RNA of a gene of interest binds to a DNA tile (gold squares), it creates a raised surface (white areas) that can be detected by a powerful microscope. This nanochip approach offers manufacturing and usage advantages over existing gene chips and is a key step toward detecting gene activity in a single cell. Featured in the February 20, 2008, issue of Biomedical Beat.
Hao Yan and Yonggang Ke, Arizona State University
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6572: Nuclear Lamina
6572: Nuclear Lamina
The 3D single-molecule super-resolution reconstruction of the entire nuclear lamina in a HeLa cell was acquired using the TILT3D platform. TILT3D combines a tilted light sheet with point-spread function (PSF) engineering to provide a flexible imaging platform for 3D single-molecule super-resolution imaging in mammalian cells.
See 6573 for 3 seperate views of this structure.
See 6573 for 3 seperate views of this structure.
Anna-Karin Gustavsson, Ph.D.
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5856: Dense tubular matrices in the peripheral endoplasmic reticulum (ER) 2
5856: Dense tubular matrices in the peripheral endoplasmic reticulum (ER) 2
Three-dimensional reconstruction of a tubular matrix in a thin section of the peripheral endoplasmic reticulum between the plasma membranes of the cell. The endoplasmic reticulum (ER) is a continuous membrane that extends like a net from the envelope of the nucleus outward to the cell membrane. The ER plays several roles within the cell, such as in protein and lipid synthesis and transport of materials between organelles. Shown here are super-resolution microscopic images of the peripheral ER showing the structure of an ER tubular matrix between the plasma membranes of the cell. See image 5857 for a more detailed view of the area outlined in white in this image. For another view of the ER tubular matrix see image 5855
Jennifer Lippincott-Schwartz, Howard Hughes Medical Institute Janelia Research Campus, Virginia
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2746: Active site of sulfite oxidase
2746: Active site of sulfite oxidase
Sulfite oxidase is an enzyme that is essential for normal neurological development in children. This video shows the active site of the enzyme and its molybdenum cofactor visible as a faint ball-and-stick representation buried within the protein. The positively charged channel (blue) at the active site contains a chloride ion (green) and three water molecules (red). As the protein oscillates, one can see directly down the positively charged channel. At the bottom is the molybdenum atom of the active site (light blue) and its oxo group (red) that is transferred to sulfite to form sulfate in the catalytic reaction.
John Enemark, University of Arizona
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