Long-term exposure to diabetes mellitus is associated with metabolic abnormalities such as
chronic hyperglycemia and redox imbalance. Uncontrolled hyperglycaemia and genetic
factors are implicated in the pathogenesis of diabetic microvascular diseases. Genetic
mutation through the genes coding for enzymes involved in glucose metabolism and
immuno-regulatory mechanisms may contribute to the susceptibility to type I diabetes
mellitus (TIDM) and its chronic microvascular diseases. Previous studies have shown that
the transcription factor, nuclear factor kappa 8 (NFκB) and heat shock proteins (HSPs) are
two redox-sensitive cellular responses of most immune and inflammatory diseases
including diabetes and its late vascular complications. NFκB promotes the transcription of
a wide array of proinflammatory mediators and adhesion molecules. HSPs are proposed to
have a cytoprotective effect; in contrast they have the capacity to promote pathogenic
processes. In this study, polymerase chain reaction (PCR)-based microsatellite analysis and
restriction fragment length polymorphism (RFLP) analysis were used to genotype the
genes coding for NFκB, HSP70-A2, sorbitol dehydrogenase (SORD) and protein kinase C-
β(PKC-β). The A10 allele of the NFκB gene and H3 and H7 alleles of the HSP70-A2
gene were identified as risk markers of TIDM (P< 0.01). These alleles were not associated
with microvascular complications. No evidence of associations was obtained between
either PKC-β or SORD genes with TIDM and its late complications. Uncontrolled
hyperglycaemia may alter the transcription mechanism of many genes, which control
vascular homeostasis. The electrophoresis mobility shift assay (EMSA) was used to assess
the transcription factor, heat shock factor-1 (HSF-1) and NFκB-DNA binding activity in
response to a concentration of 31 mM D- glucose in peripheral blood mononuclear
cells (PBMCs) from patients with TIDM with and without microvascular complications.
Hyperglycaemia induced significant increases in both NFκB and HSF-1-DNA binding
activities in PBMCs from patients (p= 0.003 and 0.017 respectively). The protein activity
was more pronounced in PBMCs from patients with microvascular complications.
Hyperglycaemia-induced NFκB-DNA binding activity was correlated to that of HSF-1 (p<
0.0 I). Patients with TIDM with microvascular complications demonstrated a significant
increase in NFκB-DNA binding activity compared to patients with a short duration of
diabetes (SD) or diabetic controls (DC) (p= 0.003 and p = 0.047 respectively).
A significant positive correlation was found between the duration of diabetes and
hyperglycaemia-induced NFκB-DNA binding activity (p=0.035). These results suggest
that hyperactive flux through the polyol pathway is relevant to hyperglycaemia-induced
protein activity since the aldose reductase inhibitors (ARIs) zopolrestat and sorbinil
reduced HSF-1 and NFκB-DNA binding activity in PBMCs. In conclusion, these results
suggest that NFκB and HSP70-A2 genes may contribute to the genetic susceptibility to
TIDM. Uncontrolled hyperglycaemia in diabetes may alter the transcription mechanism
and magnify the proinflammatory responses, which accelerate the development of diabetic
microvascular complications.
Date of Award | 2004 |
---|
Original language | English |
---|
Awarding Institution | |
---|
An Investigation for Genetic Susceptibility to Type 1 Diabetes Mellitus and its Microvascular Complications
Hegazy, D. M. (Author). 2004
Student thesis: PhD