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Proteomics Collection

Proteomics, the study of proteins and their functions within an organism, is a fascinating field that unravels the intricate workings of life

Background imageProteomics Collection: Anaesthetic inhibiting an ion channel C015 / 6718

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

Background imageProteomics 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 imageProteomics 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 imageProteomics Collection: Brain protein research

Brain protein research. Computer artwork of a brain and coloured dots from a protein microarray. Protein microarrays can be used to follow protein interactions

Background imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics Collection: RNA-editing enzyme, molecular model

RNA-editing enzyme, molecular model
RNA-editing enzyme

Background imageProteomics Collection: SARS coronavirus protein

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

Background imageProteomics 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 imageProteomics Collection: RNA binding protein and mRNA complex

RNA binding protein and mRNA complex

Background imageProteomics Collection: Myoglobin molecule C015 / 5702

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

Background imageProteomics 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 imageProteomics Collection: Cytochrome b5 molecule C015 / 6696

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

Background imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics Collection: Volume of Jupiter compared to Earth

Volume of Jupiter compared to Earth
Jupiter is the largest planet in the Solar System. Being 11.2 times the radius of the Earth, our home planet could fit inside this gas giant planet well over 1000 times

Background imageProteomics Collection: Adenovirus hexon protein

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

Background imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics Collection: Cell membrane ion channels, artwork C016 / 7689

Cell membrane ion channels, artwork C016 / 7689
Cell membrane ion channels. Computer artwork of a section through the membrane of an animal cell, showing transmembrane ion channel proteins (yellow)

Background imageProteomics 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 imageProteomics 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 imageProteomics 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 imageProteomics Collection: Immunoglobulin G antibody molecule C016 / 4462

Immunoglobulin G antibody molecule C016 / 4462
Immunoglobulin G antibody molecule. Computer artwork of a model of the secondary structure of immunoglobulin G (IgG). This is the most abundant immunoglobulin and is found in all body fluids

Background imageProteomics Collection: X-ray crystallography C016 / 3824

X-ray crystallography C016 / 3824
X-ray crystallography. Researcher using an X-ray machine to obtain crystal diffraction patterns of proteins for 3-D imaging of enzymes

Background imageProteomics Collection: Foot-and-mouth disease virus

Foot-and-mouth disease virus. Computer model of the foot-and-mouth disease (FMD) virus Aphtae epizooticae, showing the symmetrical surface structure of the viruss outer protein coat (capsid)

Background imageProteomics Collection: Conceptual image of polyomavirus

Conceptual image of polyomavirus

Background imageProteomics Collection: Tumour suppressor protein and DNA C017 / 3647

Tumour suppressor protein and DNA C017 / 3647
Tumour suppressor protein and DNA. Computer artwork showing a molecule of the tumour suppressor protein p53 (blue and pink) bound to a molecule of DNA (deoxyribonucleic acid, yellow and orange)

Background imageProteomics Collection: Ricin A-chain, artwork C017 / 3653

Ricin A-chain, artwork C017 / 3653
Ricin A-chain. Computer artwork showing the enzymatically active A-chain from a molecule of the toxic protein ricin. Ricin comprises two entwined amino acid chains; A (seen here) and B (not shown)

Background imageProteomics Collection: TATA box-binding protein complex C017 / 7082

TATA box-binding protein complex C017 / 7082
TATA box-binding protein complex. Molecular model showing a TATA box-binding protein (TBP, green) complexed with a strand of DNA (deoxyribonucleic acid, yellow) and transcription factor IIB

Background imageProteomics Collection: TATA box-binding protein complex C017 / 7088

TATA box-binding protein complex C017 / 7088
TATA box-binding protein complex. Molecular model showing a TATA box-binding protein (TBP, green) complexed with a strand of DNA (deoxyribonucleic acid, yellow) and transcription factor IIB

Background imageProteomics Collection: Ricin molecule, artwork C017 / 3652

Ricin molecule, artwork C017 / 3652
Ricin molecule. Computer artwork showing the structure of a molecule of the toxic protein ricin. Ricin comprises two entwined amino acid chains; A (yellow) and B (blue)

Background imageProteomics Collection: GAL4p activator protein C017 / 7009

GAL4p activator protein C017 / 7009
Molecular structure of the Gal4p activator protein. It consists of two Gal4p, bound to a GAL upstream activator sequence (UAS)

Background imageProteomics Collection: GAL4p activator protein C017 / 7008

GAL4p activator protein C017 / 7008
Molecular structure of the Gal4p activator protein. It consists of two Gal4p, bound to a GAL upstream activator sequence (UAS)

Background imageProteomics Collection: TATA box-binding protein complex C017 / 7084

TATA box-binding protein complex C017 / 7084
TATA box-binding protein complex. Molecular model showing a TATA box-binding protein (TBP, green) complexed with a strand of DNA (deoxyribonucleic acid, yellow) and transcription factor IIB

Background imageProteomics Collection: Sirtuin enzyme and p53, artwork C017 / 3659

Sirtuin enzyme and p53, artwork C017 / 3659
Sirtuin enzyme and p53. Computer artwork of a sirtuin (Sir2) enzyme (pink) bound to a p53 peptide (orange)

Background imageProteomics Collection: Adenine molecule, artwork C017 / 7200

Adenine molecule, artwork C017 / 7200
Adenine molecule. Computer artwork showing the structure of a molecule of the nucleobase adenine

Background imageProteomics Collection: Tumour suppressor protein and DNA C017 / 3644

Tumour suppressor protein and DNA C017 / 3644
Tumour suppressor protein and DNA. Computer artwork showing a molecule of the tumour suppressor protein p53 (blue and pink) bound to a molecule of DNA (deoxyribonucleic acid, yellow and orange)

Background imageProteomics Collection: Ricin molecule, artwork C017 / 3651

Ricin molecule, artwork C017 / 3651
Ricin molecule. Computer artwork showing the structure of a molecule of the toxic protein ricin. Ricin comprises two entwined amino acid chains; A (yellow) and B (blue)

Background imageProteomics Collection: Ricin molecule, artwork C017 / 3650

Ricin molecule, artwork C017 / 3650
Ricin molecule. Computer artwork showing the structure of a molecule of the toxic protein ricin. Ricin comprises two entwined amino acid chains; A (yellow) and B (blue)

Background imageProteomics Collection: Sirtuin enzyme and p53, artwork C017 / 3658

Sirtuin enzyme and p53, artwork C017 / 3658
Sirtuin enzyme and p53. Computer artwork of a sirtuin (Sir2) enzyme (pink) bound to a p53 peptide (orange)

Background imageProteomics Collection: SIRT3 molecule, artwork C017 / 3657

SIRT3 molecule, artwork C017 / 3657
SIRT3 molecule. Computer artwork showing the structure of a molecule of NAD-dependent deacetylase sirtuin-3, mitochondrial (SIRT3)

Background imageProteomics Collection: Tumour suppressor protein and DNA C017 / 3646

Tumour suppressor protein and DNA C017 / 3646
Tumour suppressor protein and DNA. Computer artwork showing a molecule of the tumour suppressor protein p53 (blue and pink) bound to a molecule of DNA (deoxyribonucleic acid, yellow and orange)

Background imageProteomics Collection: Thymine molecule, artwork C017 / 7366

Thymine molecule, artwork C017 / 7366
Thymine molecule. Computer artwork showing the structure of a molecule of the nucleobase thymine

Background imageProteomics Collection: Thymine molecule, artwork C017 / 7365

Thymine molecule, artwork C017 / 7365
Thymine molecule. Computer artwork showing the structure of a molecule of the nucleobase thymine

Background imageProteomics Collection: DNA molecule, artwork F007 / 4200

DNA molecule, artwork F007 / 4200
DNA molecule, computer artwork

Background imageProteomics Collection: DNA molecule, artwork F007 / 4196

DNA molecule, artwork F007 / 4196
DNA molecule, computer artwork

Background imageProteomics Collection: DNA molecule, artwork F007 / 4203

DNA molecule, artwork F007 / 4203
DNA molecule, computer artwork

Background imageProteomics Collection: DNA molecule, artwork F007 / 4207

DNA molecule, artwork F007 / 4207
DNA molecule, computer artwork

Background imageProteomics Collection: Human karyotype, artwork F007 / 6432

Human karyotype, artwork F007 / 6432
Human karyotype, computer artwork. The karyotype is the complete set of chromosomes in an organism

Background imageProteomics Collection: DNA molecule F007 / 6423

DNA molecule F007 / 6423
DNA (deoxyribonucleic acid) molecule

Background imageProteomics Collection: Antibodies attacking a virus, artwork F007 / 6623

Antibodies attacking a virus, artwork F007 / 6623
Antibodies attacking a virus, computer artwork

Background imageProteomics Collection: Antibodies attacking a virus, artwork F007 / 6624

Antibodies attacking a virus, artwork F007 / 6624
Antibodies attacking a virus, computer artwork

Background imageProteomics Collection: Human karyotype, artwork F007 / 6431

Human karyotype, artwork F007 / 6431
Human karyotype, computer artwork. The karyotype is the complete set of chromosomes in an organism

Background imageProteomics Collection: Antibodies attacking a virus, artwork F007 / 6622

Antibodies attacking a virus, artwork F007 / 6622
Antibodies attacking a virus, computer artwork

Background imageProteomics Collection: Restriction enzyme and DNA, artwork F007 / 6436

Restriction enzyme and DNA, artwork F007 / 6436
Restriction enzyme. Compute artwork of a restriction enzyme (orange) complexed with DNA (deoxyribonucleic acid, blue)

Background imageProteomics Collection: DNA polymerase molecule F007 / 6422

DNA polymerase molecule F007 / 6422
DNA polymerase molecule. DNA polymerases are enzymes that synthesise new strands of DNA from a complementary template strand

Background imageProteomics Collection: Amino acid structures F007 / 6424

Amino acid structures F007 / 6424
Amino acid structures. Chemical structures of 20 of the 22 standard amino acids

Background imageProteomics Collection: DNA nucleosome, artwork F007 / 6435

DNA nucleosome, artwork F007 / 6435
DNA nucleosome. Computer artwork of a nucleosome, the fundamental repeating unit used to package DNA (deoxyribonucleic acid) inside cell nuclei

Background imageProteomics Collection: Heat shock factor protein F007 / 9885

Heat shock factor protein F007 / 9885
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

Background imageProteomics Collection: Glycine riboswitch molecule F007 / 9921

Glycine riboswitch molecule F007 / 9921
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

Background imageProteomics Collection: Heat shock factor 70 protein F007 / 9895

Heat shock factor 70 protein F007 / 9895
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

Background imageProteomics Collection: Haemagglutinin viral surface protein F007 / 9932

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

Background imageProteomics Collection: Haemagglutinin viral surface protein F007 / 9931

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

Background imageProteomics Collection: Glycine riboswitch molecule F007 / 9906

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

Background imageProteomics Collection: Immunoglobulin G antibody molecule F007 / 9901

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

Background imageProteomics Collection: DNA nucleosome, molecular model F007 / 9883

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

Background imageProteomics Collection: DNA nucleosome, molecular model F007 / 9888

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

Background imageProteomics Collection: Flap endonuclease protein F007 / 9914

Flap endonuclease protein F007 / 9914
Molecular model of the flap endonuclease protein

Background imageProteomics Collection: Heat shock factor 70 protein F007 / 9903

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

Background imageProteomics Collection: Human serum albumin molecule F007 / 9904

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

Background imageProteomics Collection: Human 80S ribosome F007 / 9902

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

Background imageProteomics Collection: Flap endonuclease protein F007 / 9916

Flap endonuclease protein F007 / 9916
Molecular model of the flap endonuclease protein



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Proteomics, the study of proteins and their functions within an organism, is a fascinating field that unravels the intricate workings of life. From anaesthetics inhibiting ion channels to immunoglobulin G antibody molecules, proteomics delves into the molecular mechanisms that shape our existence. In the realm of brain research, scientists explore how proteins influence cognition and behavior. They investigate DNA nucleosomes' structure and function, unraveling their role in gene regulation. Antibodies take center stage as artwork showcases their diverse forms and crucial role in immune defense. Zinc fingers bound to a DNA strand highlight protein-DNA interactions critical for genetic processes. Meanwhile, manganese superoxide dismutase enzyme aids in protecting cells from oxidative stress. The SARS coronavirus protein becomes a subject of intense scrutiny as researchers strive to understand its pathogenicity. Cytochrome b5 molecule reveals insights into electron transfer reactions within cells while glutamine synthetase enzyme plays a vital role in nitrogen metabolism. Lastly, RNA-editing enzymes offer potential therapeutic targets for various diseases with their ability to modify genetic information at the RNA level. Through proteomics, we unlock nature's secrets one protein at a time - deciphering their structures, unraveling their functions, and ultimately enhancing our understanding of life itself.

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