Colour-causing defects and their related optoelectronic transitions in single crystal CVD diamond.

Defects causing colour in nitrogen-doped chemical vapour-deposited (CVD) diamond can adversely affect the exceptional optical, electronic and spintronic properties of the material. Several techniques were used to study these defects, namely optical absorption spectroscopy, thermoluminescence (TL) and electron paramagnetic resonance (EPR). From our studies, the defects causing colour in nitrogen-doped CVD diamond are clearly not the same as those causing similar colour in natural diamonds. The brown colour arises due to a featureless absorption profile that decreases in intensity with increasing wavelength, and a broad feature at 360 nm (3.49 eV) that scales in intensity with it. Another prominent absorption band, centred at 520 nm (2.39 eV), is ascribed to the neutral nitrogen-vacancy-hydrogen defect. The defects responsible for the brown colour possess acceptor states that are 1.5 eV from the valence band (VB) edge. The brown colour is removed by heat treatment at 1600 ° C, whereupon new defects possessing shallow (<1 eV) trap states are generated.

Signal transduction defects in growth hormone insensitivity.

Growth hormone (GH) insensitivity is a heterogeneous condition that can result from mutations within the GH receptor (GHR) and that can be inherited as both an autosomal recessive and a dominant trait. However, evidence from a small number of growth hormone binding protein (GHBP)-positive families indicates that their GH insensitivity is independent of GHR mutations. Two of these families appear to have distinct abnormalities in GH signal transduction. Studies suggest that one family (classic Laron syndrome phenotype; designated family H) have a signalling defect close to the GHR, preventing activation of both the STAT and MAPK pathways, whereas the other family (less marked phenotype; family M) have a defect in activating MAPK but not the STAT pathway. The children studied here are specifically insensitive to GH and their defect must be exclusive to this signalling system. Thus, families with GHBP-positive GH insensitivity without GHR mutations are likely to be important models in which to study the specificity of GH signal transduction and the relationship between GH insensitive phenotype and signalling defect.

Activation of the signal transducers and activators of transcription signaling pathway by growth hormone (GH) in skin fibroblasts from normal and GH binding protein-positive Laron Syndrome children.

We have previously described two families (H and M) with GH binding protein-positive Laron Syndrome (LS), proposed to have one or more post GHR signaling defects. In the present study, we have examined whether the signal transducers and activators of transcription (STAT) pathway is activated by GH in skin fibroblast cultures established from these LS children, to determine the level(s) at which GH insensitivity has occurred. On immunoblots, both normal and LS fibroblasts express JAK2 and STATs 1, 3, and 5. GH induced rapid tyrosine phosphorylation of a protein at approximately 93 kDa in normal fibroblasts, and Western blotting with STAT-specific antibodies revealed STAT5 activation (phosphorylation) by GH. To determine further the identity and the DNA binding characteristics of the STAT proteins that were activated by GH, EMSAs were performed using three DNA elements known to bind STAT proteins; m67, the high affinity c-sis-inducible element (SIE), the interferon response element (IRE), and the lactogenic hormone-responsive region (LHRR). GH failed to induce protein binding to the SIE or IRE in normal skin fibroblasts but did induce the formation of a specific complex with the LHRR. Induction by GH of this LHRR/protein complex, which could be supershifted partially by anti-STAT1 antisera and completely by anti-STAT5 antisera, was transient, maximal between 10 and 30 min and reduced by 60 min. GH also induced distinct LHRR/protein complexes in mouse 3T3-F442A fibroblasts and in human IM-9 lymphocytes, but supershift analysis revealed that these complexes contained STAT5 but not STAT1. Whereas no binding to the LHRR was observed in GH-treated H fibroblasts, GH induced binding to this element in M fibroblasts. These results demonstrate that 1) the JAK-STAT pathway is activated by GH in normal fibroblasts and that STATs 1 and 5 have a role in GH-dependent signaling in these cells; 2) GH activation of DNA/STAT binding is cell type- and species-specific; and 3) GH failed to activate the STAT pathway in H fibroblasts but induced STAT signaling in M fibroblasts, indicating that the site of GH resistance in the latter is likely to be located within another GH signaling pathway. These fibroblast cultures therefore provide unique models with which to further our understanding of the mechanisms of human GH signaling.

Human skin fibroblasts as a model of growth hormone (GH) action in GH receptor-positive Laron's syndrome.

Congenital GH insensitivity (Laron's syndrome, LS) is often associated with a dysfunctional GH receptor (GHR) causing complete insensitivity to GH and absent serum GH-binding protein (GHBP). However, a proportion of children with LS have normal GHBP levels. We have identified four girls from two families with this condition (height SD score, -3.4 to -6.8) and undertaken studies on 1) their GHR genes and 2) their GH responses in cultured skin fibroblasts to define the etiology of their GH insensitivities. No GHR gene mutations were identified in one family. In the other family, the affected siblings, an unaffected brother, and the father were heterozygous for a point mutation within exon 6 (D152H). In addition, use of intron 9 haplotypes to determine linkage to the GHR gene implied inheritance of different maternal GHR alleles in the two affected girls of the latter family. It is unlikely, therefore, that the D152H mutation alone could account for the LS phenotype. End points of GH action [DNA synthesis, insulin-like growth factor-binding protein-3 (IGFBP-3) messenger RNA (mRNA) and peptide production] in skin fibroblast cultures established from three of the LS subjects and four normal children were examined. Whereas normal fibroblasts incorporated [3H]thymidine dose dependently in response to 10-1000 ng/ml GH (increment at 1000 ng/ml, 77 +/- 19%), LS fibroblasts failed to respond significantly above basal levels (P < 0.01). In normal fibroblasts, IGFBP-3 mRNA and peptide increased maximally at 48 h in response to 200 ng/ml GH, as determined by ribonuclease protection assay, Western ligand blotting, and RIA. In comparison, LS fibroblasts produced significantly less IGFBP-3 peptide than normal fibroblasts in response to GH, whereas IGFBP-3 mRNA failed to increase above basal levels. These studies have shown that 1) cultured human skin fibroblasts can be used to define the end points of GH action; 2) fibroblast cultures from the LS children show absent or reduced responses to GH; and 3) GH insensitivity in these children does not appear to be caused exclusively by GHR mutations, but is probably due to dysfunctional GHR signalling. Such patients may prove particularly important to elucidation of the key events in GH signaling.