RM
+
Illustration showing repaglinide (yellow white blue and red spheres centre-left and centre-right) binding to an ATP-dependent potassium channel (mu
RM
+
Illustration showing repaglinide (yellow red and white spheres centre-left and centre-right) binding to an ATP-dependent potassium channel (multicol
RM
+
Illustration showing repaglinide (yellow white blue and red spheres centre-left and centre-right) binding to an ATP-dependent potassium channel (mu
RM
+
Illustration showing repaglinide (yellow white blue and red spheres within pink structures) binding to ATP-dependent potassium channel (multicoloure
RM
+
Illustration of tirzepatide (red blue and grey spheres) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (pinkbeige vertical) A G
RM
+
Illustration of tirzepatide (silver helix) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (multi-coloured helices across membrane)
RM
+
Metformin antidiabetic drug action illustration
RM
+
Metformin antidiabetic drug action illustration
RM
+
Illustration showing repaglinide (white blue and red spheres within helices) binding to an ATP-dependent potassium channel (multicoloured helices) on
ED
+
Cell membrane receptors Computer artwork of a G protein-coupled receptor in a lipid bilayer plasma membrane These receptors are transmembrane protei
RM
+
Illustration of tirzepatide (red blue and grey spheres) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (beige vertical) A G prot
RM
+
Illustration of tirzepatide (silver helix) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (multi-coloured helices across membrane)
RM
+
Illustration of tirzepatide (red blue and grey spheres) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (multi-coloured 3d structur
RM
+
Illustration of tirzepatide (silver helix) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (multi-coloured helices across membrane)
RM
+
Illustration of tirzepatide (red blue and grey spheres) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (beige vertical structure)
RM
+
Illustration of semaglutide (blue red and grey spheres) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (multi-coloured 3D structur
RM
+
Semaglutide antidiabetic drug action illustration
RF
+
Cellular transport illustration
RF
+
Cellular transport illustration
ED
+
Cell membrane Computer artwork of the plasma membrane of a cell showing sugars (red) protruding from the outer surface The sugars are linked to memb
RM
+
Ebolavirus particle illustration Ebolavirus is a filamentous enveloped virus The virus surface has trimeric transmembrane glycoproteins that allow
RF
+
GLP-1 receptors and semaglutide agonists illustration
RF
+
GLP-1 receptors and semaglutide agonists illustration
RF
+
Inactivated GLP-1 receptor near semaglutide illustration
RF
+
GLP-1 receptor activated by semaglutide illustration
RM
+
Perforin-2 molecule illustration
RM
+
BamA beta barrel protein illustration
RM
+
Magnesium transporter molecule illustration
RM
+
Passage of ions through gap junctions illustration
ED
+
Protein synthesis in cell Cutaway artwork of the inside of a cell showing proteins (pink one at bottom left) being synthesized by ribosomes (blue
RM
+
Illustration showing the proteins and other molecules constituting the cell membrane Proteins can associate with the membrane in a few ways Integral
RM
+
Ion transport across cell membrane illustration
RF
+
Illustration of the extracellular V (orange) C1 (magenta) and C2 (cyan) domains of the receptor for advanced glycation endproducts (RAGE) This trans
RF
+
Illustration of the extracellular V (purple) C1 (cyan) and C2 (green) domains of the receptor for advanced glycation endproducts (RAGE) This transme
RF
+
Illustration of the extracellular V (green) C1 (yellow) and C2 (magenta) domains of the receptor for advanced glycation endproducts (RAGE) This tran
RF
+
Illustration of the extracellular V (orange) C1 (magenta) and C2 (cyan) domains of the receptor for advanced glycation endproducts (RAGE) This trans
RF
+
Illustration of a receptor for advanced glycation endproducts (RAGE) within a lipid bilayer membrane This transmembrane protein belongs to the immuno
RF
+
Illustration of a receptor for advanced glycation endproducts (RAGE) within a lipid bilayer membrane Above the membrane the receptors V C1 and C2
RF
+
Illustration of a receptor for advanced glycation endproducts (RAGE) within a lipid bilayer membrane This transmembrane protein belongs to the immuno
ED
+
Animal cell membrane Artwork of the structure of an animal cell membrane The membrane is sectioned and seen as the horizontal layer across centre I
RF
+
Illustration of a receptor for advanced glycation endproducts (RAGE) within a lipid bilayer membrane This transmembrane protein belongs to the immuno
RM
+
Illustration of a cholesterol molecule (spheres) binding to the G-protein coupled receptor (GPCR) Ste2 from the yeast Saccharomyces cerevisiae Sre2 i
RM
+
Illustration of the human transmembrane protein 45A (TMEM45A) Transmembrane proteins span the entire width of the cell membrane lipid bilayer They a
RM
+
Illustration of a cyclic nucleotide-gated (CNG) channel found in the retinal rod cells of a cow in its closed conformation The retina is the light s
RM
+
Illustration of type I amyloid-beta filaments ending at residue 42 from human brains Misfolded amyloid beta peptides aggregate and form amyloid plaqu
RM
+
Illustration of the binding domain of the human insulin receptor complexed with insulin (yellow) The insulin receptor is a transmembrane protein Bin
RM
+
Illustration of the human voltage-gated potassium (Kv) ion channel Kv42 in complex with its dipeptidyl peptidase-related protein 6 (DPP6) modulator
RM
+
Illustration of the human dispatched-1 (DISP1) protein This is a transmembrane protein that is involved in Hedgehog (Hh) signalling Hh signalling pl
RM
+
Illustration of the calcium homeostasis modulator 1 (CALHM1) channel in its open state This pore-forming transmembrane protein is found in nerve cell
ED
+
Diphtheria toxin Molecular graphic of the diphtheria toxin in closed (left) and open form This lethal toxin is secreted by the bacteria Corynebacter
RM
+
Illustration of the translocase of the outer membrane (TOM) protein complex from the outer membrane of mitochondria This complex is the main importer
RF
+
Illustration of molecules passing across a plasma membrane via a transmembrane protein transporter (light blue) The transporters undergo conformation
RF
+
Illustration of ion (blue) transport across the plasma membrane (pink) via a transmembrane protein channel (yellow) When the channel is closed (left
RF
+
Illustration of an activated receptor for advanced glycation endproducts (RAGE) embedded in a cell membrane This transmembrane protein belongs to the
RF
+
Illustration of a receptor for advanced glycation endproducts (RAGE) embedded in a cell membrane This transmembrane protein belongs to the immunoglob
RM
+
Illustration of the OprC copper transporter protein from the bacterium Pseudomonas aeruginosa This protein spans the bacterial outer membrane and bin
RM
+
Illustration of the core signalling unit (CSU) from the bacterium Escherichia coli The CSU is a transmembrane complex of proteins that detects chemic
RM
+
Illustration of an AMPA (a-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor) neurotransmitter receptor This glutamate receptor is the most
RM
+
Illustration of the structure of a human connexin 313 hemichannel in the absence of calcium ions Connexins form large-pore channels that function ei
RF
+
Illustration of a cell membrane showing the proteins involved in the Raf-MEK-ERK or MAPKERK pathway The signal cascade begins when epidermal growt
RF
+
Illustration of a cell membrane showing the proteins involved in the Raf-MEK-ERK or MAPKERK pathway The signal cascade begins when epidermal growt
RF
+
Illustration of amyloid beta peptide (blue upper centre) that has been cleaved from the transmembrane amyloid precursor protein (APP centre left) Am
RF
+
Illustration of amyloid beta peptide in its normal (left) and misfolded (right) forms Misfolded amyloid beta peptides aggregate and form amyloid plaq
RM
+
Insulin receptor molecule illustration
RM
+
Illustration of a cytochrome c oxidase enzyme from the mitochondria of a cows heart in fully oxidized state Cytochrome molecules perform oxidation a
RF
+
Illustration of different types of cell membrane transport protein by ALI DAMOUHSCIENCE PHOTO LIBRARY
RF
+
Illustration of different types of cell membrane transport protein by ALI DAMOUHSCIENCE PHOTO LIBRARY
RF
+
B cell receptor dimer illustration
RF
+
B cell receptor dimer illustration
RF
+
Illustration of B cell receptor on the surface of a B cell (purple and orange phospholipid bilayer) B cells also known as B lymphocytes are a type o
RF
+
Illustration of B cell receptor on the surface of a B cell (purple and orange phospholipid bilayer) B cells also known as B lymphocytes are a type o
RM
+
Illustration of an insulin receptor as a glass surface model with indicated deeper ribbon model on a dark background Insulin receptors are located in
RM
+
Illustration of an insulin receptor as a glass surface model with indicated deeper ribbon model on a white background Insulin receptors are located i
RM
+
Synechocystis halorhodopsin (SyHR) molecular model The image shows Synechocystis halorhodopsin a cyanobacterial halorhodopsin acting as a light-dri
RM
+
Synechocystis halorhodopsin (SyHR) molecular model
RM
+
NMDA receptor illustration
RM
+
Solute carrier protein and cAMP illustration
RM
+
Illustration of the secondary structure of the adenosine A2A receptor This is a transmembrane protein that has a number of important roles in the hum
RM
+
Voltage-gated potassium channel illustration
RM
+
Illustration of the secondary structure of bryoporin a pore-forming protein from the moss Physcomitrium patens Pore-forming proteins are also known
RM
+
Illustration of the sodium potassium (NaK) channel from the bacterium Bacillus cereus This non-selective channel facilitates the transport of sodium
RM
+
Illustration of the human transmembrane protein gap junction alpha-1 (GJA1) also known as connexin43 GJA1 is a component of gap junctions or nexuse
RM
+
Illustration of a genetically-engineered form of the bacterial alpha-hemolysin (alphaHL) toxin complexed with beta-cyclodextrin This toxin is secrete
RM
+
Bacterial cellulose synthase
RM
+
Bacterial cellulose synthase
RM
+
Lymphocyte membrane illustration
RM
+
Fibrodysplasia ossificans progressiva mutant protein
RM
+
Insulin receptors illustration
RM
+
Cell membrane illustration
RM
+
Cell membrane illustration
RM
+
Insulin receptors illustration
RM
+
Insulin receptors illustration
RM
+
Glucose binding to receptor illustration
RM
+
Insulin receptors illustration
RM
+
Permease membrane transport protein illustration
RM
+
Illustration showing repaglinide (yellow white blue and red spheres centre-left and centre-right) binding to an ATP-dependent potassium channel (mu
RM
+
Illustration showing repaglinide (yellow red and white spheres centre-left and centre-right) binding to an ATP-dependent potassium channel (multicol
RM
+
Illustration showing repaglinide (yellow white blue and red spheres centre-left and centre-right) binding to an ATP-dependent potassium channel (mu
RM
+
Illustration showing repaglinide (yellow white blue and red spheres within pink structures) binding to ATP-dependent potassium channel (multicoloure
RM
+
Illustration of tirzepatide (red blue and grey spheres) bound to a glucagon-like peptide-1 (GLP-1) transmembrane receptor (pinkbeige vertical) A G
460
0
https://www.afloimages.com/search/transmembrane.html