Molecular Structure Collection (page 4)

Haemagglutinin viral surface protein F007 / 9932
Haemagglutinin viral surface protein. Molecular model of haemagglutinin, a surface protein from the influenza virus, complexed with a neutralising antibody

Carbon nanotube F007 / 9910
Buckytube. Molecular model of part of the cage structure of a bucky- or nanotube. The spheres represent carbon atoms. In this structure hundreds of atoms form hexagon shapes along a tube

Haemagglutinin viral surface protein F007 / 9931
Haemagglutinin viral surface protein. Molecular model of haemagglutinin, a surface protein from the influenza virus, complexed with a neutralising antibody

Glycine riboswitch molecule F007 / 9906
Molecular model of the bacterial glycine riboswitch. This is an RNA element that can bind the amino acid glycine. Glycine riboswitches usually consist of two metabolite-binding aptamer domains tandem

Immunoglobulin G antibody molecule F007 / 9901
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

DNA nucleosome, molecular model F007 / 9883
DNA nucleosome. Molecular model of a nucleosome, the fundamental repeating unit used to package DNA (deoxyribonucleic acid) inside cell nuclei

Caffeine drug molecule F007 / 9899
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

Sarin nerve gas molecule F007 / 9933
Sarin nerve gas, molecular model. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (green), oxygen (red), phosphorous (orange) and fluorine (blue)

DNA nucleosome, molecular model F007 / 9888
DNA nucleosome. Molecular model of a nucleosome, the fundamental repeating unit used to package DNA (deoxyribonucleic acid) inside cell nuclei

Flap endonuclease protein F007 / 9914
Molecular model of the flap endonuclease protein. This is a class of nucleolytic enzymes that act as both 5 -3 exonucleases

Heat shock factor 70 protein F007 / 9903
Molecular model of the Heat Shock Protein 70 (HSP).HSPs are a group of proteins whose levels increase when cells are exposed to raised temperatures or other stress

Human serum albumin molecule F007 / 9904
Human serum albumin, molecular model. Albumin is the most abundant protein in human blood plasma. One of albumins functions is to transport fatty acids to the liver

Human 80S ribosome F007 / 9902
Ribosomal subunit. Computer model showing the structure of the RNA (ribonucleic acid) molecules in an 80S (large) ribosomal sub-unit. Ribosomes are composed of protein and RNA

Flap endonuclease protein F007 / 9916
Molecular model of the flap endonuclease protein. This is a class of nucleolytic enzymes that act as both exonucleases and structure-specific endonucleases on specialised DNA structures that occur

Immunoglobulin G antibody molecule F007 / 9920
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

Heat shock factor protein F007 / 9892
Molecular model of a Heat Shock Protein (HSP).HSPs are a group of proteins whose levels increase when cells are exposed to raised temperatures or other stress

Human serum albumin molecule F007 / 9905
Human serum albumin, molecular model. Albumin is the most abundant protein in human blood plasma. One of albumins functions is to transport fatty acids to the liver

Yeast enzyme, molecular model F007 / 9913
Yeast enzyme. Molecular model of an enzyme from bakers yeast (Saccharomyces cerevisiae). This is the 20S proteasome. A proteasome is a complex type of proteinase (protein-digesting enzyme)

Sarin nerve gas molecule F007 / 9938
Leucine, molecular model. Essential alpha-amino acid contained in eggs, soy protein, seaweed, turkey, chicken, lamb, cheese, and fish

Immunoglobulin G antibody molecule F007 / 9889
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

Human 80S ribosome F007 / 9898
Ribosomal subunit. Computer model showing the structure of the RNA (ribonucleic acid) molecules in an 80S (large) ribosomal sub-unit. Ribosomes are composed of protein and RNA

Sarin nerve gas molecule F007 / 9935
Sarin nerve gas, molecular model, The wire-frame map represents the electrostatic potential across the molecules surface. The atoms carbon, hydrogen, oxygen

Type I topoisomerase protein bound to DNA F007 / 9893
Type I topoisomerase bound to DNA. Molecular model showing a type I topoisomerase molecule (blue) bound to a strand of DNA (deoxyribonucleic acid, yellow and red)

Ubiquitin activating enzyme protein E1 F007 / 9919
Molecular model of a ubiquitin-activating enzyme, also known as E1 enzymes. These catalyse the first step in the ubiquitination reaction, which targets a protein for degradation via a proteasome

Yeast enzyme, molecular model F007 / 9887
Yeast enzyme. Molecular model of an enzyme from bakers yeast (Saccharomyces cerevisiae). This is the 20S proteasome. A proteasome is a complex type of proteinase (protein-digesting enzyme)

DNA molecule, artwork F008 / 3371
DNA molecule and chromosome, artwork

Buckyball, artwork F008 / 3355
Buckyball, computer artwork

Buckyball, artwork F008 / 3347
Buckyball, computer artwork

DNA molecules, artwork F008 / 3372
DNA molecules, artwork

Buckyballs, artwork F008 / 3359
Buckyballs, computer artwork

Buckyball, artwork F008 / 3344
Buckyball, computer artwork

DNA molecule, artwork F008 / 2034
DNA molecule, computer artwork

DNA molecule, artwork F008 / 3370
DNA molecule, artwork

Buckyball, artwork F008 / 3358
Buckyball, computer artwork

DNA molecules, artwork F008 / 3264
Deoxyribonucleic acid (DNA) molecules, computer artwork

Buckytube, artwork F008 / 3352
Buckytube, computer artwork

Nanomedicine, conceptual artwork F008 / 3361
Nanomedicine, conceptual computer artwork

Nanomedicine, conceptual artwork F008 / 3360
Nanomedicine, conceptual computer artwork

Buckyballs, artwork F008 / 3349
Buckyballs, computer artwork

Buckyball, artwork F008 / 3354
Buckyball, computer artwork

Buckytube, artwork F008 / 3353
Buckytube, computer artwork

Nanomedicine, conceptual artwork F008 / 3362
Nanomedicine, conceptual computer artwork

Human genome, conceptual artwork F008 / 3292
Human genome, conceptual computer artwork

Buckyball, artwork F008 / 3346
Buckyball, computer artwork

DNA molecule, artwork F008 / 2036
DNA molecule, computer artwork

Buckyball, artwork F008 / 3342
Buckyball, artwork

Buckyball, artwork F008 / 3345
Buckyball, computer artwork

Buckyball, artwork F008 / 3348
Buckyball, computer artwork

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"Molecular Structure: Unlocking the Secrets of Life's Building Blocks" From anaesthetics inhibiting ion channels to antidepressant molecules, the intricate world holds endless wonders. The C015 / 6718 anaesthetic molecule delicately interacts with ion channels, altering their function and providing relief from pain. Meanwhile, Amitriptyline, an antidepressant molecule, works its magic by modulating neurotransmitters in our brains. In the realm of immunity, Immunoglobulin G antibody F007 / 9894 stands tall as a defender against pathogens. Its unique structure allows it to recognize and neutralize foreign invaders effectively. On another front, DNA artwork showcases the elegance and complexity that underlies all life forms on Earth. Creatine amino acid molecule fuels our muscles during intense physical activities while nanotube technology revolutionizes various industries with its exceptional properties. These tiny tubes hold immense potential for advancements in medicine and materials science alike. Zinc fingers bound to a DNA strand demonstrate how proteins can precisely interact with genetic material. This interaction plays a crucial role in gene regulation and expression. Carbon nanotubes take center stage once again as they exhibit remarkable strength and conductivity at the nano-scale level. Oxytocin neurotransmitter molecule reminds us of love's powerful influence on human connections—its presence promotes bonding between individuals. Manganese superoxide dismutase enzyme F006 / 9423 safeguards our cells by combating harmful free radicals that contribute to aging and disease. Even viruses have their own molecular structures; SARS coronavirus protein represents one such example—a key player in viral replication within host cells. Conceptual artwork further explores nanotube technology's limitless possibilities—the fusion of imagination and scientific innovation knows no bounds here. As we delve deeper into understanding molecular structures, we unravel nature's blueprint for life itself—one atom at a time. These captivating glimpses into the microscopic world remind us of both the fragility and resilience found within the building blocks of existence.