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1.  Genetic polymorphisms, their allele combinations and IFN-β treatment response in Irish multiple sclerosis patients 
Pharmacogenomics  2009;10(7):1177-1186.
IFN-β is widely used as first-line immunomodulatory treatment for multiple sclerosis. Response to treatment is variable (30–50% of patients are nonresponders) and requires a long treatment duration for accurate assessment to be possible. Information about genetic variations that predict responsiveness would allow appropriate treatment selection early after diagnosis, improve patient care, with time saving consequences and more efficient use of resources.
Materials & methods
We analyzed 61 SNPs in 34 candidate genes as possible determinants of IFN-β response in Irish multiple sclerosis patients. Particular emphasis was placed on the exploration of combinations of allelic variants associated with response to therapy by means of a Markov chain Monte Carlo-based approach (APSampler).
The most significant allelic combinations, which differed in frequency between responders and nonresponders, included JAK2–IL10RB–GBP1–PIAS1 (permutation p-value was pperm = 0.0008), followed by JAK2–IL10–CASP3 (pperm = 0.001).
The genetic mechanism of response to IFN-β is complex and as yet poorly understood. Data mining algorithms may help in uncovering hidden allele combinations involved in drug response versus nonresponse.
PMCID: PMC2727921  PMID: 19604093
APSampler; Bayesian statistics; IFN-β; multiple sclerosis; pharmacogenomics; polymorphism
2.  ZnT3 mRNA levels are reduced in Alzheimer's disease post-mortem brain 
ZnT3 is a membrane Zn2+ transporter that is responsible for concentrating Zn2+ into neuronal presynaptic vesicles. Zn2+ homeostasis in the brain is relevant to Alzheimer's disease (AD) because Zn2+ released during neurotransmission may bind to Aβ peptides, accelerating the assembly of Aβ into oligomers which have been shown to impair synaptic function.
We quantified ZnT3 mRNA levels in Braak-staged human post mortem (pm) brain tissue from medial temporal gyrus, superior occipital gyrus, superior parietal gyrus, superior frontal gyrus and cerebellum from individuals with AD (n = 28), and matched controls (n = 5) using quantitative real-time PCR. ZnT3 mRNA levels were significantly decreased in all four cortical regions examined in the AD patients, to 45-60% of control levels. This reduction was already apparent at Braak stage 4 in most cortical regions examined. Quantification of neuronal and glial-specific markers in the same samples (neuron-specific enolase, NSE; and glial fibrillary acidic protein, GFAP) indicated that loss of cortical ZnT3 expression was more pronounced, and occurred prior to, significant loss of NSE expression in the tissue. Significant increases in cortical GFAP expression were apparent as the disease progressed. No gene expression changes were observed in the cerebellum, which is relatively spared of AD neuropathology.
This first study to quantify ZnT3 mRNA levels in human pm brain tissue from individuals with AD and controls has revealed a significant loss of ZnT3 expression in cortical regions, suggesting that neuronal cells in particular show reduced expression of ZnT3 mRNA in the disease. This suggests that altered neuronal Zn2+ handling may be an early event in AD pathogenesis.
PMCID: PMC2806356  PMID: 20030848

Results 1-2 (2)