Glycomics investigation into insulin action.

Defects in glycosylation are becoming increasingly associated with a range of human diseases. In some cases, the disease is caused by the glycosylation defect, whereas in others, the aberrant glycosylation may be a consequence of the disease. The implementation of highly sensitive and rapid mass spectrometric screening strategies for profiling the glycans present in model biological systems is revealing valuable insights into disease phenotypes. In addition, glycan screening is proving useful in the analysis of knock-out mice where it is possible to assess the role of glycosyltransferases and glycosidases and what function they have at the cellular and whole organism level. In this study, we analysed the effect of insulin on the glycosylation of 3T3-L1 cells and the effect of insulin resistance on glycosylation in a mouse model. Transcription profiling of 3T3-L1 cells treated with and without insulin revealed expression changes of several glycogenes. In contrast, mass spectrometric screening analysis of the glycans from these cells revealed very similar profiles suggesting that any changes in glycosylation were most likely on specific proteins rather than a global phenomenon. A fat-fed versus carbohydrate-fed mouse insulin resistant model was analysed to test the consequences of chronic insulin resistance. Muscle and liver N-glycosylation profiles from these mice are reported.

Cell proliferation activities on skin fibroblasts from a short child with absence of one copy of the type 1 insulin-like growth factor receptor (IGF1R) gene and a tall child with three copies of the IGF1R gene.

The type 1 IGF receptor (IGF1R) is required for normal embryonic and postnatal growth. The aim of this study was to determine whether we could detect abnormal IGF1R function in skin fibroblasts from children with an abnormal copy number of the IGF1R gene. We report two children with altered copy number of the IGF1R gene who presented with abnormal growth. Case 1 is a girl with intrauterine growth retardation, postnatal growth failure, and recurrent hypoglycemia. Pituitary function tests were normal. Routine karyotype analysis identified a deletion on 15q26.2, and a fluorescence in situ hybridization study using IGF1R probes showed only a single IGF1R gene. Case 2 was large for gestational age, with birth weight and length at or above 97th percentile, and showed rapid early postnatal growth. He was found to have a recombinant chromosome 15 containing a partial duplication at 15q (q25-qter). A fluorescence in situ hybridization study using the same probes showed three copies of the IGF1R gene. In a mitochondrial activity assay, skin fibroblasts from the subject with only one copy of IGF1R showed slower growth, whereas cells from the subject with three copies of IGF1R showed accelerated growth compared with controls. IGF1R phosphorylation, as assessed by Western blot, and IGF1R binding studies were decreased compared with controls in the child with one copy of the IGF1R and increased in the child with three copies of the gene. Our data are consistent with the concept that IGF1R gene copy number is of functional and clinical importance in humans.