Transferrins types

Braend, M. and C. Stormont Studies on hemoglobin and transferrin types of horses. Nord. Veterinarmed. 16, 31 (1964). 

The aluminated brain tissue has a considerably different Al MAS NMR spectrum. In addition to the transferrin-type resonance, additional peaks are seen. From these data it was concluded that brain tissue is susceptible to a broad range of coordination by aluminum. Furthermore, the moderate Al Cq values (all less than 10 MHz) suggest future NMR studies may be performed at 9.4 T and a spin rate of 20 kHz. The P NMR spectrum of octacalcium phosphate was assigned by P double quantum and HETCOR spectroscopy. 

A variety of cellular and viral proteins contain fatty acids covalently bound via ester linkages to the side chains of cysteine and sometimes to serine or threonine residues within a polypeptide chain (Figure 9.18). This type of fatty acyl chain linkage has a broader fatty acid specificity than A myristoylation. Myristate, palmitate, stearate, and oleate can all be esterified in this way, with the Cjg and Cjg chain lengths being most commonly found. Proteins anchored to membranes via fatty acyl thioesters include G-protein-coupled receptors, the surface glycoproteins of several viruses, and the transferrin receptor protein. 

As an alternative to targeting brain tumours which express the TfR, the transferrin approach can be used for the delivery of fusion proteins which bind to pharmacological receptors inside the central nervous system. An example of this is the construct consisting of nerve growth factor (NGF) and transferrin described in Section 11.8.2.3. The transferrin moiety in this type of construct will enable it to enter the brain, upon which the drug moiety will act by binding to its receptor. This approach seems especially suitable for compounds that cannot pass the blood-brain barrier, such as peptides and other hydrophilic substances. 

Detailed pictures of the iron-binding sites in transferrins have been provided by the crystal structures of lactoferrin (Anderson et ai, 1987, 1989 Baker etai, 1987) and serum transferrin (Bailey etal., 1988). Each structure is organized into two lobes of similar structure (the amino- and carboxy-terminal lobes) that exhibit internal sequence homology. Each lobe, in turn, is organized into two domains separated by a cleft (Fig. 3 and 10). The domains have similar folding patterns of the a//3 type. One iron site is present in each lobe, which occupies equivalent positions in the interdomain cleft. The same sets of residues serve as iron ligands to the two sites two tyrosines, one histidine, and one aspartate. Additional extra density completes the octahedral coordination of the iron and presumably corresponds to an anion and/or bound water. The iron sites are buried about 10 A below the protein surface and are inaccessible to solvent. 

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