The expression of transferrin binding protein in the turtle nervous system.

Transferrin binding protein (TfBP) is a cytoplasmic glycoprotein that was originally isolated from the chick oviduct. As we previously demonstrated the constitutive expression of TfBP in the avian nervous system, in this study we examined whether TfBP is expressed in the reptilian nervous system. In accordance with previous findings in the chicken, oligodendrocytes were most prominently labeled by antiserum to TfBP. Great variability was observed between different regions of the central nervous system (CNS) in terms of TfBP-labeled oligodendrocyte numbers. In the retina, TfBP was localized specifically in the cells that are morphologically oligodendrocytes and present in the optic nerve and the ganglion cell layer. TfBP staining was also seen in the Schwann cells of peripheral nerves. Furthermore, choroid plexus cells and capillary endothelial cells similarly exhibited strong reactions. These results may reflect the fact that the homology of nervous system genes is conserved between close phylogenetic lines, and proove the potential of TfBP as a marker for oligodendrocytes in avian as well as reptile.

Expression of transferrin binding protein in the capillaries of the brain in the developing chick embryo.

Transferrin-binding protein (TfBP) has been shown to be a novel protein, structurally related to the chicken heat shock protein 108. The physiological function of this protein, however, has not yet been established. Antiserum to TfBP selectively stains transferrin- and iron-rich oligodendrocytes and choroidal epithelium in the adult and embryonic chick brain, suggesting a role for this protein in transferrin and iron storage in these cells. In this study, we further demonstrate TfBP-immunoreactivity (IR) in the blood vessels of the embryonic chick central nervous system. A strong TfBP-IR was present in blood vessels from E6, declined from E10 and was absent by E18. Thus, the expression of the TfBP in the blood vessels precedes its expression in the oligodendrocytes. At the subcellular level, TfBP-IR was confined to the cytoplasm of capillary pericytes while the Tf-receptor IR was associated with the capillary endothelium of the brain. The up-regulated expression of TfBP, together with the Tf-receptor of the brain capillaries, suggests that pericytes may be associated with the high iron uptake required for the metabolic demands of the developing brain.

Activated cyclic AMP-response element binding protein (CREB) is expressed in a myelin-associated protein in chick.

Cyclic AMP response element (CRE) is a specific DNA sequence, which mediates transcriptional activation in the response to the cyclic AMP-activated and protein kinase A dependent signaling pathway. In the present study, phosphorylated CRE binding protein (CREB) immunoreactivity was mainly localized in the white matter of chick central nervous system (CNS). We have further confirmed the specificity of phospho-CREB immunoreaction in myelin using demyelinated optic nerve induced by lysophophatidylcholine (LPC), which is known to produce demyelination with little axonal damage. Double immunofluorescent analyses with myelin basic protein (MBP) and transferrin binding protein (TfBP), oligodendrocyte marker showed that phospho-CREB recognized a myelin-related protein in chick. Immunoblot analyses showed that phospho-CREB recognized a protein with molecular weights of approximately 70 kDa. Our data suggest that the antigen recognized by phospho-CREB is a myelin-associated protein in the chick CNS.

Distribution of heat shock protein 108 mRNA during the development of the chicken brain.

The developmental expression of heat shock protein 108 (HSP108) mRNA was mapped in chicken brain using in situ hybridization and reverse transcription-polymerase chain reaction (RT-PCR). RT-PCR showed that HSP108 mRNA increased from embryonic day 5 (E5) to 13 (E13), significantly decreased from E17 to E21 and then increased again at the adult stage. In situ hybridization showed that while intense HSP108 positive (HSP108+) signals were localized in the cerebellum from E7 to E14, the intensities of these signals were significantly decreased at E17. However, at the adult stage, HSP108 expression increased in a cell type dependent manner. A decrease in HSP108 mRNA expression during differentiation was also observed in an in vitro study of brain cells treated with nerve growth factor (NGF).

A poly-His tag method for obtaining the C-terminal lobe of human transferrin.

Human serum transferrin is an essential bilobal protein that transports iron in the circulation for delivery to iron-requiring cells. Obtaining the C-terminal lobe of human transferrin in verified native conformation has been problematic, possibly because its 11 disulfide bonds lead to misfolding when the lobe is expressed without its accompanying N-lobe. A recently reported method for preparing the C-lobe free of extraneous residues, with normal iron-binding properties and capable of delivering iron to cells, makes use of a Factor Xa cleavage site inserted into the interlobal connecting strand of the full-length protein. An inefficient step in this method requires the use of ConA chromatography to separate the cleaved lobes from each other, since only the C-lobe is glycosylated. Inserting a 6-His sequence near the start of the N-lobe enhances recovery of the recombinant transferrin from other proteins in the culture medium of the BHK21 cells expressing the mutant transferrin. The new procedure is more economical in time and effort than its predecessor, and offers the additional advantage of isolating C-lobe expressed with or without its glycan chains.

Transferrin-mediated iron acquisition by pathogenic Neisseria.

The pathogenic Neisseria have a siderophore-independent iron-uptake system reliant on a direct interaction between the bacterial cell and transferrin. In the meningococcus this uptake system is dependent on two surface-exposed transferrin-binding proteins. This short account will review our current knowledge of the transferrin-mediated iron-acquisition system of pathogenic Neisseria.