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Molecular Model Collection

Background imageMolecular Model Collection: DNA transcription, molecular model

DNA transcription, molecular model

Background imageMolecular Model Collection: Anaesthetic inhibiting an ion channel C015 / 6718

Anaesthetic inhibiting an ion channel C015 / 6718
Anaesthetic inhibiting an ion channel

Background imageMolecular Model Collection: Double-stranded RNA molecule

Double-stranded RNA molecule. Computer model of the structure of double-stranded RNA (ribonucleic acid)

Background imageMolecular Model Collection: Immunoglobulin G antibody molecule

Immunoglobulin G antibody molecule. Computer model of the secondary structure of immunoglobulin G (IgG). This is the most abundant immunoglobulin and is found in all body fluids

Background imageMolecular Model Collection: Graphene sheet, artwork C016 / 8274

Graphene sheet, artwork C016 / 8274
Graphene sheet. Computer artwork showing the molecular structure of a graphene sheet

Background imageMolecular Model Collection: Immunoglobulin G antibody molecule F007 / 9894

Immunoglobulin G antibody molecule F007 / 9894
Immunoglobulin G antibody molecule. Computer model of the secondary structure of immunoglobulin G (IgG). This is the most abundant immunoglobulin and is found in all body fluids

Background imageMolecular Model Collection: 2C-B psychedelic drug, molecular model

2C-B psychedelic drug, molecular model. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (white), oxygen (pink), nitrogen (blue) and bromine (dark red)

Background imageMolecular Model Collection: Secondary structure of proteins, artwork

Secondary structure of proteins, artwork
Secondary structure of proteins, computer artwork. The secondary structure is the shape taken by the strands of proteins, which are biological polymers of amino acids

Background imageMolecular Model Collection: Perovskite crystal structure

Perovskite crystal structure. Perovskite is the name for the mineral calcium titanium oxide (CaTiO3)

Background imageMolecular Model Collection: DNA molecule, computer model

DNA molecule, computer model
DNA molecule. Computer artwork of the molecular structure of DNA (deoxyribonucleic acid). The DNA molecule is composed of two strands twisted into a double helix

Background imageMolecular Model Collection: Nucleosome molecule

Nucleosome molecule, computer model. A nucleosome is a subunit of chromatin, the substance that forms chromosomes

Background imageMolecular Model Collection: DNA nucleosome, molecular model

DNA nucleosome, molecular model
DNA nucleosome. Molecular model of a nucleosome, the fundamental repeating unit used to package DNA (deoxyribonucleic acid) inside cell nuclei

Background imageMolecular Model Collection: Antibodies, artwork

Antibodies, artwork
Computer artwork of antibody molecules showing the structure of an immunoglobulin G (IgG) molecule. This is the most abundant immunoglobulin and is found in all body fluids

Background imageMolecular Model Collection: Vitamin B12, molecular model

Vitamin B12, molecular model. Vitamin B12 (cyanocobalamin) is an essential nutrient that humans are unable to produce and need to obtain from their diet

Background imageMolecular Model Collection: Caffeine drug molecule

Caffeine drug molecule
Caffeine. Computer model of a molecule of the alkaloid, stimulant and legal drug caffeine. Caffeine is most often consumed in drinks like tea and coffee

Background imageMolecular Model Collection: Bacterial ribosome

Bacterial ribosome. Computer model showing the secondary structure of a 30S (small) ribosomal sub-unit from the bacteria Thermus thermophilus

Background imageMolecular Model Collection: HIV reverse transcription enzyme

HIV reverse transcription enzyme. Molecular models of the reverse transcriptase enzyme found in HIV (the human immunodeficiency virus)

Background imageMolecular Model Collection: Hepatitis C virus enzyme, molecular model

Hepatitis C virus enzyme, molecular model
Hepatitis C virus enzyme. Molecular model of a genetic enzyme from the Hepatitis C virus. This enzyme is called HC-J4 RNA polymerase

Background imageMolecular Model Collection: Glutamine synthetase enzyme

Glutamine synthetase enzyme computer model. This is a ligase enzyme, which forms chemical bonds between molecules. The different colours show the different subunits that comprise the protein

Background imageMolecular Model Collection: Insulin molecule, artwork

Insulin molecule, artwork
Artwork of a molecule of human insulin, a hormone produced by the pancreas which controls levels of glucose in the blood

Background imageMolecular Model Collection: RNA-editing enzyme, molecular model

RNA-editing enzyme, molecular model
RNA-editing enzyme

Background imageMolecular Model Collection: SARS coronavirus protein

SARS coronavirus protein. Molecular model of the ORF-9b protein produced by the SARS (severe acute respiratory syndrome) coronavirus

Background imageMolecular Model Collection: Zinc fingers bound to a DNA strand

Zinc fingers bound to a DNA strand, molecular model. The double helix of DNA (deoxyribonucleic acid, red and yellow) is seen here with two Zif268 proteins (blue and green)

Background imageMolecular Model Collection: Carbon nanotube

Carbon nanotube. Computer artwork showing the hexagonal carbon structure of a nanotube, or buckytube

Background imageMolecular Model Collection: RNA binding protein and mRNA complex

RNA binding protein and mRNA complex

Background imageMolecular Model Collection: Capsaicin molecule

Capsaicin molecule
Capsaicin, molecular model. This chemical gives chilies their heat and causes a burning sensation when ingested

Background imageMolecular Model Collection: Oxytocin neurotransmitter molecule

Oxytocin neurotransmitter molecule. Computer model showing the structure of the neurotransmitter and hormone Oxytocin

Background imageMolecular Model Collection: Januvia diabetes drug molecule

Januvia diabetes drug molecule
Januvia diabetes drug, molecular model. Januvia (sitagliptin) is a hypoglycaemic drug, one that reduces blood sugar levels

Background imageMolecular Model Collection: Water molecule

Water molecule. Computer model of a molecule of water. Atoms are colour-coded: oxygen (red) and hydrogen (white)

Background imageMolecular Model Collection: Fullerene molecule, computer artwork

Fullerene molecule, computer artwork
Fullerene molecule. Computer artwork of the spherical fullerene molecule C320. Fullerenes are a structural type (allotrope) of carbon

Background imageMolecular Model Collection: Interferon molecule

Interferon molecule. Computer model showing the secondary structure of a molecule of interferon

Background imageMolecular Model Collection: Myoglobin molecule C015 / 5702

Myoglobin molecule C015 / 5702
Myoglobin molecule. Computer model showing the structure of a myoglobin molecule

Background imageMolecular Model Collection: Manganese superoxide dismutase enzyme F006 / 9423

Manganese superoxide dismutase enzyme F006 / 9423
Manganese superoxide dismutase enzyme, molecular model. This enzyme scavenges and decomposes the potentially toxic first reduction product, superoxide, of aerobic respiration

Background imageMolecular Model Collection: Cytochrome b5 molecule C015 / 6696

Cytochrome b5 molecule C015 / 6696
Cytochrome b5. Molecular model of cytochrome b5 from a cows liver

Background imageMolecular Model Collection: Z-DNA tetramer molecule C015 / 6557

Z-DNA tetramer molecule C015 / 6557
Z-DNA (deoxyribonucleic acid) tetramer, molecular model. DNA is composed of two strands twisted into a double helix. This is a tetramer of the molecule, containing four strands

Background imageMolecular Model Collection: Caffeine, molecular model

Caffeine, molecular model. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (green), oxygen (red) and nitrogen (blue)

Background imageMolecular Model Collection: Aflatoxin, molecular model

Aflatoxin, molecular model. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (white) and oxygen (red)

Background imageMolecular Model Collection: Rotavirus particle, artwork

Rotavirus particle, artwork
Rotavirus particle. Cut-away artwork showing the structure of the rotavirus icosahedral capsid (protein coat)

Background imageMolecular Model Collection: Cubane molecule

Cubane molecule. Computer model showing the structure of a molecule of cubane (C8H8)

Background imageMolecular Model Collection: Cholera toxin, molecular model

Cholera toxin, molecular model
Cholera toxin. Molecular model of the secondary structure of cholera enterotoxin (intestinal toxin). The molecule consists of two subunits, A (top) and B (bottom)

Background imageMolecular Model Collection: Isotretinoin anti-acne drug

Isotretinoin anti-acne drug, molecular model. Atoms are represented as tubes and are colour- coded; carbon (yellow), hydrogen (white) and oxygen (red)

Background imageMolecular Model Collection: Mescaline hallucinogenic drug molecule

Mescaline hallucinogenic drug molecule
Mescaline hallucinogenic drug, molecular model

Background imageMolecular Model Collection: Nanotube technology, computer artwork

Nanotube technology, computer artwork
Nanotube technology. Computer artwork of a cylindrical fullerene molecule (carbon nanotube). The hexagonal carbon structure of the nanotube is shown here

Background imageMolecular Model Collection: Valdecoxib anti-inflammatory drug

Valdecoxib anti-inflammatory drug
Valdecoxib, computer model. This drug was used in the treatment of osteoarthritis, rheumatoid arthritis and menstrual symptoms under the trade name Bextra

Background imageMolecular Model Collection: Paclitaxel drug molecule

Paclitaxel drug molecule
Paclitaxel. Computer model of a molecule of the drug paclitaxel. It is sold under the brand name Taxol. It is a chemotherapy drug, used to treat cancers

Background imageMolecular Model Collection: Calcium ATPase ion pump, molecular model

Calcium ATPase ion pump, molecular model. This enzyme is found in muscle cell membranes, where it pumps calcium in and out of muscle cells and controls muscle contractions

Background imageMolecular Model Collection: Dopamine and dopamine receptor, molecular model

Dopamine and dopamine receptor, molecular model Molecular model of a dopamine molecule (red) approaching a dopamine receptor D1 (blue) in a cell membrane (orange)

Background imageMolecular Model Collection: Maurice Wilkins Studying DNA Molecular Structure

Maurice Wilkins Studying DNA Molecular Structure
(Original Caption) Nobel Prize winner Dr. Maurice H.F. Wilkins studies a model of DNA molecular structure as he meets with the press 10/18, following announcement of his award

Background imageMolecular Model Collection: Nitrogen molecule

Nitrogen molecule. Computer model of a molecule of nitrogen (N2). The two nitrogen atoms are joined by a covalent triple bond. Nitrogen is a colourless gas at room temperature

Background imageMolecular Model Collection: Frederick Sanger and DNA Model

Frederick Sanger and DNA Model
British biochemist Professor Frederick Sanger was awarded his second Nobel Prize for Chemistry in 1980

Background imageMolecular Model Collection: Reaction of hydrogen and oxygen to water C017 / 3598

Reaction of hydrogen and oxygen to water C017 / 3598
Reaction of hydrogen and oxygen to water

Background imageMolecular Model Collection: Argonaute protein molecule F006 / 9526

Argonaute protein molecule F006 / 9526
Argonaute protein, molecular model. This protein forms the RNA-induced silencing complex (RISC) along with a small interfering RNA (ribonucleic acid) molecule

Background imageMolecular Model Collection: TFAM transcription factor bound to DNA C015 / 7059

TFAM transcription factor bound to DNA C015 / 7059
TFAM transcription factor bound to DNA, molecular model. Human mitochondrial transcription factor A (TFAM, green) bound to a strand of DNA (deoxyribonucleic acid, blue and pink)

Background imageMolecular Model Collection: Rhinovirus and antibody, molecular model C015 / 7139

Rhinovirus and antibody, molecular model C015 / 7139
Rhinovirus. Molecular model of the antigen-binding fragment (Fab) from a strongly neutralising antibody bound to a human rhinovirus 14 (HRV-14) particle

Background imageMolecular Model Collection: Adenovirus hexon protein

Adenovirus hexon protein, molecular model. Hexon proteins are part of the protein coat or shell (capsid) of adenoviruses

Background imageMolecular Model Collection: Methane molecule

Methane molecule. Computer model of a methane molecule (CH4). Atoms are represented as spheres and are colour-coded: carbon (grey) and hydrogen (white)

Background imageMolecular Model Collection: DNA strands, illustration

DNA strands, illustration
DNA strands. Computer illustration showing the structure of double stranded DNA (deoxyribonucleic acid) molecules. DNA is composed of two strands twisted into a double helix

Background imageMolecular Model Collection: DNA structure, artwork C017 / 7218

DNA structure, artwork C017 / 7218
DNA structure. Computer artwork showing the structure of a double stranded DNA (deoxyribonucleic acid) molecule (right) and its components (left)

Background imageMolecular Model Collection: Aspartic molecule

Aspartic molecule
Aspartic acid molecule. Alpha-amino acid nonessential in mammals. Precursor to several amino acids including methionine, threonine, isoleucine and lysine

Background imageMolecular Model Collection: Serine molecule

Serine molecule
Serine, molecular model. Non-essential proteinogenic amino acid. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green), nitrogen (blue) and oxygen (red)

Background imageMolecular Model Collection: Teriflunomide multiple sclerosis drug F007 / 0193

Teriflunomide multiple sclerosis drug F007 / 0193
Teriflunomide multiple sclerosis drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), fluorine (dark yellow) and nitrogen (blue)

Background imageMolecular Model Collection: Argonaute protein and microRNA F006 / 9752

Argonaute protein and microRNA F006 / 9752
Argonaute protein. Molecular model of human argonaute-2 protein complexed with microRNA (micro ribonucleic acid). This protein is part of the RNA-induced silencing complex (RISC)

Background imageMolecular Model Collection: Isocitrate dehydrogenase kinase F006 / 9698

Isocitrate dehydrogenase kinase F006 / 9698
Isocitrate dehydrogenase kinase. Molecular model of isocitrate dehydrogenase kinase phosphatase (AceK) complexed with its substrate isocitrate dehydrogenase (ICDH)

Background imageMolecular Model Collection: Immunoglobulin G antibody and egg white F006 / 9682

Immunoglobulin G antibody and egg white F006 / 9682
Immunoglobulin G and egg white. Molecular model of an immunoglobulin G (IgG) antibody bound to a molecule of egg white. This is the most abundant immunoglobulin and is found in all body fluids

Background imageMolecular Model Collection: Cytochrome P450 complex F006 / 9669

Cytochrome P450 complex F006 / 9669
Cytochrome P450 complex. Molecular model of a complex composed of cytochrome P450, carbon monoxide and camphor

Background imageMolecular Model Collection: Thrombin protein, molecular model F006 / 9603

Thrombin protein, molecular model F006 / 9603
Thrombin protein, molecular model. Thrombin is an enzyme involved in the blood coagulation (clotting) process

Background imageMolecular Model Collection: Succinyl-CoA synthetase enzyme F006 / 9592

Succinyl-CoA synthetase enzyme F006 / 9592
Succinyl-CoA synthetase bound to GTP, molecular model. Also known as succinyl coenzyme A synthetase (SCS), this enzyme catalyses the reversible reaction between succinyl-CoA and succinic acid

Background imageMolecular Model Collection: RNA-induced silencing complex F006 / 9586

RNA-induced silencing complex F006 / 9586
RNA-induced silencing complex (RISC), molecular model. This complex consists of a bacterial argonaute protein (top) bound to a small interfering RNA (siRNA) molecule (red and blue)

Background imageMolecular Model Collection: Foot-and-mouth disease virus F006 / 9556

Foot-and-mouth disease virus F006 / 9556
Foot-and-mouth disease virus. Molecular model of the foot-and-mouth disease (FMD) virus (Aphtae epizooticae) protein coat (capsid)

Background imageMolecular Model Collection: Adenovirus penton base protein F006 / 9542

Adenovirus penton base protein F006 / 9542
Adenovirus penton base protein, molecular model. This protein molecule is a subunit called a penton, forming the vertices of the capsid of this adenovirus

Background imageMolecular Model Collection: Rhinovirus 16 capsid, molecular model F006 / 9431

Rhinovirus 16 capsid, molecular model F006 / 9431
Rhinovirus 16 capsid, molecular model. This is human rhinovirus 16. The rhinovirus infects the upper respiratory tract and is the cause of the common cold. It is spread by coughs and sneezes

Background imageMolecular Model Collection: Citrate acid cycle enzyme F006 / 9305

Citrate acid cycle enzyme F006 / 9305
Citrate acid cycle enzyme. Molecular model of the enzyme dihydrolipoamide succinyltransferase

Background imageMolecular Model Collection: Chlorine molecule C017 / 3601

Chlorine molecule C017 / 3601
Chlorine molecule. Computer artwork showing the structure of a molecule of chlorine (Cl2). Atoms are colour coded: chlorine (green), with the bonds between them as bars (grey)

Background imageMolecular Model Collection: Pyruvate dehydrogenase complex C018 / 9192

Pyruvate dehydrogenase complex C018 / 9192
Pyruvate dehydrogenase complex, 3D model

Background imageMolecular Model Collection: Rhinovirus and antibody, molecular model C015 / 7138

Rhinovirus and antibody, molecular model C015 / 7138
Rhinovirus. Molecular model of the antigen-binding fragment (Fab) from a strongly neutralising antibody bound to a human rhinovirus 14 (HRV-14) particle

Background imageMolecular Model Collection: Thrombin complexed with fibrinogen C015 / 7149

Thrombin complexed with fibrinogen C015 / 7149
Thrombin complexed with fibrinogen, molecular model. The thrombin molecules (left and right, brown and pink) are bound to the central part of the fibrinogen molecule (centre, multiple colours)

Background imageMolecular Model Collection: Human polio virus, molecular model

Human polio virus, molecular model
Human polio virus capsid, molecular model. Poliovirus causes poliomyelitis, a disease that can cause paralysis in up to 2 percent of patients, and in some cases death

Background imageMolecular Model Collection: Valproic acid anticonvulsant molecule C014 / 2296

Valproic acid anticonvulsant molecule C014 / 2296
Valproic acid. Molecular model of the anticonvulsant and mood-stabilising drug valproic acid

Background imageMolecular Model Collection: MscL ion channel protein structure

MscL ion channel protein structure. Molecular model showing the protein structure of a Mechanosensitive Channel of Large Conductance (MscL) from a Mycobacterium tuberculosis bacterium

Background imageMolecular Model Collection: Immunoglobulin A, molecular model

Immunoglobulin A, molecular model
Immunoglobulin A. Molecular model of the structure of the antibody immunoglobulin A (IgA)

Background imageMolecular Model Collection: Dopamine receptor D3 C016 / 4464

Dopamine receptor D3 C016 / 4464
D(3) dopamine receptor is a protein that in humans is encoded by the DRD3 gene.This gene encodes the D3 subtype of the dopamine receptor

Background imageMolecular Model Collection: Phentermine drug molecule C013 / 9952

Phentermine drug molecule C013 / 9952
Phentermine. Molecular model of the appetite suppressant phentermine. This drug is used to help obese patients lose weight by decreasing their appetite

Background imageMolecular Model Collection: Coagulation factor complex molecule C014 / 0139

Coagulation factor complex molecule C014 / 0139
Coagulation factor complex molecule. Molecular model showing the interaction between coagulation factor VIII (FVIII, pink, blue and yellow) and factor IXa (FIXa, cream and grey)

Background imageMolecular Model Collection: Cucumber mosaic virus, computer model

Cucumber mosaic virus, computer model
Cucumber mosaic virus (CMV), computer model. This image was created using molecular modelling software and data from X-ray crystallography



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EDITORS COMMENTS

Molecular models offer a glimpse into the intricate world of science and medicine, revealing the hidden secrets of life at a microscopic level. In one captivating image, an anaesthetic molecule is seen inhibiting an ion channel C015/6718, unlocking new possibilities for pain management. Another striking model showcases the complex structure of a double-stranded RNA molecule, shedding light on its crucial role in gene regulation and viral defense mechanisms. Delving deeper into genetics, we explore DNA transcription through a mesmerizing molecular model that unravels the intricate process of genetic information transfer. The spotlight then shifts to Immunoglobulin G antibody molecules - powerful defenders against pathogens - as their elegant structures are unveiled with precision. From F007/9894 variant to artwork-inspired representations, these models showcase the diversity within our immune system's arsenal. Venturing beyond traditional boundaries, we encounter 2C-B psychedelic drug's molecular model – offering insights into its unique chemical composition and potential therapeutic applications. Art meets science once again as we marvel at an artistic interpretation showcasing secondary structures of proteins; highlighting their vital roles in cellular functions. Inorganic wonders take center stage with the perovskite crystal structure model – unveiling its remarkable properties that revolutionize solar energy technology. Returning to genetics, we witness a computer-generated DNA molecule model providing us with invaluable insights into our blueprint for life. The complexity continues with the intricately designed nucleosome molecule – unraveling how DNA is packaged within our cells' nucleus while maintaining accessibility for essential processes. Finally, awe-inspiring artwork captures antibodies' beauty and significance as they stand tall against invading antigens. These captivating molecular models serve as windows into worlds unseen by the naked eye; bridging gaps between scientific exploration and artistic expression. They inspire curiosity and ignite imagination while propelling breakthroughs in fields ranging from medicine to materials science.

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