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Heme group proteins

Cytochrome c has two cysteine units covalently bonded to the two ethenyl side chains of the heme group protein—SH + CH2=CH—heme---------> protein—S—CH2CH2—heme... [Pg.1250]

Much of the organization is facilitated by receptor/receptee interactions the list includes iron/porphyrin, iron/02, heme group/protein, substrate/protein, cofactor/protein. The immense growth in the... [Pg.62]

Gofactors. Frequendy proteins exist in their native state in association with other nonprotein molecules or cofactors, which are cmcial to their function. These may be simple metal ions, such as Fe " in hemerythrin or Ca " in calmodulin a heme group, as for the globins nucleotides, as for dehydrogenases, etc. [Pg.211]

The most conspicuous use of iron in biological systems is in our blood, where the erythrocytes are filled with the oxygen-binding protein hemoglobin. The red color of blood is due to the iron atom bound to the heme group in hemoglobin. Similar heme-bound iron atoms are present in a number of proteins involved in electron-transfer reactions, notably cytochromes. A chemically more sophisticated use of iron is found in an enzyme, ribo nucleotide reductase, that catalyzes the conversion of ribonucleotides to deoxyribonucleotides, an important step in the synthesis of the building blocks of DNA. [Pg.11]

To answer the first question, Lesk and Chothia examined in detail residues at structurally equivalent positions that are involved in helix-heme contacts and in packing the a helices against each other. After comparing the nine globin structures then known, the 59 positions they found that fulfilled these criteria were divided into 31 positions buried in the interior of the protein and 28 in contact with the heme group. These positions are the principal determinants of both the function and the three-dimensional structure of the globin family. [Pg.42]

Figure 12.14 The three-dimensional structure of a photosynthetic reaction center of a purple bacterium was the first high-resolution structure to be obtained from a membrane-bound protein. The molecule contains four subunits L, M, H, and a cytochrome. Subunits L and M bind the photosynthetic pigments, and the cytochrome binds four heme groups. The L (yellow) and the M (red) subunits each have five transmembrane a helices A-E. The H subunit (green) has one such transmembrane helix, AH, and the cytochrome (blue) has none. Approximate membrane boundaries are shown. The photosynthetic pigments and the heme groups appear in black. (Adapted from L. Stryer, Biochemistry, 3rd ed. New York ... Figure 12.14 The three-dimensional structure of a photosynthetic reaction center of a purple bacterium was the first high-resolution structure to be obtained from a membrane-bound protein. The molecule contains four subunits L, M, H, and a cytochrome. Subunits L and M bind the photosynthetic pigments, and the cytochrome binds four heme groups. The L (yellow) and the M (red) subunits each have five transmembrane a helices A-E. The H subunit (green) has one such transmembrane helix, AH, and the cytochrome (blue) has none. Approximate membrane boundaries are shown. The photosynthetic pigments and the heme groups appear in black. (Adapted from L. Stryer, Biochemistry, 3rd ed. New York ...
HEMOPROTEINS. These proteins are actually a subclass of metalloproteins because their prosthetic group is heme, the name given to iron protoporphyrin IX (Figure 5.15). Because heme-containing proteins enjoy so many prominent biological functions, they are considered a class by themselves. [Pg.127]

Cytochromes were first named and classified on the basis of their absorption spectra (Figure 21.9), which depend upon the structure and environment of their heme groups. The b cytochromes contain iron—protoporphyrin IX (Figure 21.10), the same heme found in hemoglobin and myoglobin. The c cytochromes contain heme c, derived from iron-protoporphyrin IX by the covalent attachment of cysteine residues from the associated protein. UQ-cyt c... [Pg.685]

Fig. 8. (a) Structure of the full-length Rieske protein from bovine heart mitochondrial bci complex. The catalytic domain is connected to the transmembrane helix by a flexible linker, (b) Superposition of the three positional states of the catalytic domain of the Rieske protein observed in different crystal forms. The ci state is shown in white, the intermediate state in gray, and the b state in black. Cytochrome b consists of eight transmembrane helices and contains two heme centers, heme and Sh-Cytochrome c i has a water-soluble catalytic domain containing heme c i and is anchored by a C-terminal transmembrane helix. The heme groups are shown as wireframes, the iron atoms as well as the Rieske cluster in the three states as space-filling representations. [Pg.108]

The biochemical activity and accessibility of biomolecule-intercalated AMP clays to small molecules was retained in the hybrid nanocomposites. For example, the absorption spectrum of the intercalated Mb-AMP nanocomposite showed a characteristic soret band at 408 nm associated with the intact prosthetic heme group of the oxidised protein (Fe(III), met-myoglobin) (Figure 8.9). Treatment of Mb with sodium dithionite solution resulted in a red shift of the soret band from 408 to 427 nm, consistent with the formation of intercalated deoxy-Mb. Reversible binding of CO under argon to the deoxy-Mb-AMP lamellar nanocomposite was demonstrated by a shift in the soret band from 427 to 422 nm. Subsequent dissociation of CO from the heme centre due to competitive 02 binding shifted the soret band to 416nm on formation of intercalated oxy-Mb. [Pg.250]

Smithies vertical starch gel electrophoresis (S7) separates the plasma proteins more distinctly than any other method. If the Hp concentration is normal, the Hp type can generally be recognized directly after the staining for proteins, but sensitive and more specific staining for heme groups, e.g., benzidine, o-dianisidine (04), and malachite green (N5) are preferable. This technique consumes more hydrolyzed starch than the simpler original horizontal electrophoresis technique (S5). [Pg.167]

There are at least two factors that could influence the turnover rate, the site of metabolism (hot spot) and the affinity of a compound toward these enzymes the protein/ligand (substrate or inhibitor) interaction and the chemical reactivity of the compound towards oxidation. Because of the interaction of the protein with the potential ligand, certain atoms of the compound could be exposed to the heme group, and depending on the chemical nature of these moieties the oxidative reaction will take place at different rates, for example celecoxib is metabolized by CYP2C9 at the... [Pg.248]

See other pages where Heme group proteins is mentioned: [Pg.113]    [Pg.113]    [Pg.1147]    [Pg.442]    [Pg.210]    [Pg.211]    [Pg.45]    [Pg.1147]    [Pg.119]    [Pg.688]    [Pg.723]    [Pg.922]    [Pg.168]    [Pg.1481]    [Pg.1483]    [Pg.283]    [Pg.295]    [Pg.48]    [Pg.73]    [Pg.64]    [Pg.483]    [Pg.61]    [Pg.332]    [Pg.20]    [Pg.569]    [Pg.808]    [Pg.105]    [Pg.614]    [Pg.733]    [Pg.734]    [Pg.828]    [Pg.181]    [Pg.126]    [Pg.135]    [Pg.158]    [Pg.168]    [Pg.270]    [Pg.344]    [Pg.253]   
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