Molecules Collection (page 8)

DNA supercoils, artwork
DNA supercoils. Computer artwork showing DNA (deoxyribonucleic acid) in three stages of supercoiling. Supercoiling is important in a number of biological processes

Saliva chemicals, molecular model
Saliva chemicals. Molecular structure of a group of saliva molecules. These include the antibody immunoglobulin A (blue, double-y shape, see C014/5652)

Enterovirus particle C014 / 4900
Enterovirus particle. Computer artwork of an enterovirus particle (virion), showing the structure of the capsid (outer shell)

Enterovirus capsid proteins structure C014 / 4897
Enterovirus capsid proteins structure. Computer artwork showing how the four component proteins (VP1 to VP4) of an enterovirus particle (virion) interlock to form the capsid (outer shell)

Enterovirus capsid proteins structure C014 / 4896
Enterovirus capsid proteins structure. Computer artwork showing how the four component proteins (VP1 to VP4) of an enterovirus particle (virion) interlock to form the capsid (outer shell)

Enterovirus particle C014 / 4898
Enterovirus particle. Computer artwork of an enterovirus particle (virion), showing the structure of the capsid (outer shell)

Enterovirus particles C014 / 4899
Enterovirus particles. Computer artwork of enterovirus particles (virion). Enteroviruses are a genus of non-enveloped positive-sense single-stranded RNA viruses associated with several human

UVR8 protein molecule C014 / 4912
UVR8 protein molecule. Computer model showing photoreception of UV-B (ultraviolet-B) light rays (top) by a UVR8 protein. The secondary structure (purple ribbons) of UVR8 is shown at bottom

Glutaminyl-tRNA synthetase molecule
Glutaminyl-tRNA synthetase protein molecule. Molecular model showing bacterial glutaminyl-tRNA synthetase complexed with glutamine tRNA (transfer ribonucleic acid)

Paracetamol molecule
Serotonin molecule. Computer model showing the structure of a molecule of the neurotransmitter (nerve signalling chemical) serotonin (5-hydroxytryptamine)

Bone morphogenetic protein complex, molecular model. Bone Morphogenetic Protein-7 (BMP-7, blue) in complex with the secreted antagonist Noggin (pink)

Light-harvesting protein complex, molecular model. Peripheral light-harvesting protein complex from the purple bacterium Rhodopseudomonas acidophila

Buckminsterfullerene molecule C016 / 8372
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8370
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8368
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8369
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8364
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8367
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8363
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8361
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (orange)

Buckminsterfullerene molecule C016 / 8362
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (orange)

Buckminsterfullerene molecules C016 / 8359
Buckminsterfullerene molecules. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (black)

Buckminsterfullerene molecule C016 / 8358
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (black)

Buckminsterfullerene molecule C016 / 8357
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (black)

Buckminsterfullerene molecule C016 / 8351
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (dark blue)

Plant water transport, artwork
Plant water transport. Artwork of water molecules (blue) entering a tree through osmosis in the roots, passing upwards through the xylem vessels in the trunk and branches

Carbon nanotube, artwork C016 / 8270
Carbon nanotube. Computer artwork of the inside of a carbon nanotube, also known as a buckytube, showing the hexagonal carbon structure

Carbon nanotube, artwork C016 / 8269
Carbon nanotube. Computer artwork of the inside of a carbon nanotube, also known as a buckytube, showing the hexagonal carbon structure

Vitamin B1 molecule C016 / 8278
Vitamin B1 molecule. Computer model showing the structure of a molecule of vitamin B1 (thiamine). Atoms are represented as colour-coded spheres: carbon (light blue), hydrogen (white)

Vitamin B1 molecule C016 / 8277
Vitamin B1 molecule. Computer model showing the structure of a molecule of vitamin B1 (thiamine). Vitamin B1 is an essential nutrient that humans are unable to produce

Vitamin B1 molecule C016 / 8276
Vitamin B1 molecule. Computer model showing the structure of a molecule of vitamin B1 (thiamine). Vitamin B1 is an essential nutrient that humans are unable to produce

Vitamin B1 molecule C016 / 8275
Vitamin B1 molecule. Computer model showing the structure of a molecule of vitamin B1 (thiamine). Vitamin B1 is an essential nutrient that humans are unable to produce

Carbon nanotube, artwork C016 / 8271
Carbon nanotube. Computer artwork of a carbon nanotube, also known as a buckytube, showing the hexagonal carbon structure. Atoms are represented as spheres and the bonds between them by rods

Buckminsterfullerene molecule C016 / 8268
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope)

Buckminsterfullerene molecule C016 / 8266
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope)

Carbon nanotubes in POM matrix, SEM C016 / 8042
Carbon nanotubes. Coloured scanning electron micrograph (SEM) of carbon nanotubes in a POM matrix. Carbon nanotubes are a type of fullerene, a structural type (allotrope) of carbon

Biotin ligase enzyme, molecular model. This enzyme is a protein formed from 268 amino acids and two chains (green and pink)

B-Z junction in DNA, molecular model. Deoxyribonucleic acid (DNA) occurs in three forms, A-DNA, B-DNA and Z-DNA. The first two are right-handed, with B-DNA being the more common form

Cat allergen protein, molecular model C015 / 3962
Cat allergen protein. Molecular model of the tetrameric form of the major cat allergen fel d 1 (Felis domesticus allergen 1)

All Professionally Made to Order for Quick Shipping

"Molecules: The Building Blocks of Life and Beyond" From the intricate workings of an anaesthetic inhibiting an ion channel C015/6718 to the genius mind of James Clerk Maxwell, they have captivated scientists and artists alike. With their diverse structures and functions, they hold the key to understanding life at its core. Delving into the world of proteins, we witness their secondary structure through mesmerizing artwork that unveils their complexity. Meanwhile, the caffeine drug molecule keeps us awake while bacterial ribosomes tirelessly synthesize proteins within our cells. Vitamin B12's molecular model reminds us of nature's intricate design as zinc fingers elegantly bind to a DNA strand, orchestrating genetic processes. And who can forget capsaicin - the fiery molecule responsible for giving chili peppers their spicy kick? But molecules aren't limited to just earthly matters; they extend beyond our planet's boundaries. Oxytocin neurotransmitter molecules remind us of love's chemical connection while praziquantel parasite drugs combat infections in distant lands. Interferon molecules stand tall as defenders against viral invasions, showcasing our body's remarkable defense mechanisms. And amidst all this scientific wonder lies a breathtaking sight - Aurora Borealis dancing over a snow-covered coniferous forest in Northern Finland. Intricate and awe-inspiring, these glimpses into the molecular world remind us that there is so much more than meets the eye. From unlocking medical breakthroughs to unraveling nature's mysteries or simply marveling at captivating artistry – they can truly extraordinary entities shaping our understanding of life itself.