Over a three-year-period, 310 babies with prolonged jaundice admitted to GHKL were studied, to determine the incidence of alpha-1-antitrypsin deficiency as a cause of the problem. Ninety-two babies (29.7%) were found to be alpha-1-antitrypsin deficient. The percentage incidence was found to be highest in Indians (33.3%), followed by Malays (31.9%) and Chinese (26.7%). There was a male preponderance with a M:F ratio of 1.6:1. Most of these babies presented at the hospital at the age of more than two weeks but less than one month. Apart from the problem of prolonged jaundice and alpha-1-antitrypsin deficiency, 2 had associated bleeding problems, 11 associated infections and 3 respiratory problems. Two babies had clinical features of Down's syndrome, 2 had G6PD deficiency and 1 had congenital hypothyroidism. AST, ALT and ALPO4 were high in 20, 26 and 3 babies respectively.
We conducted a prospective study to determine the role of alpha1-antitrypsin (alpha1AT) deficiency in the pathogenesis of neonatal cholestasis and other childhood liver diseases in a multi-ethnic Southeast Asian population.
Alpha-1 antitrypsin (AAT) augmentation therapy involves infusion of plasma-purified AAT to AAT deficient individuals. Whether treatment affects microRNA expression has not been investigated. This study's objectives were to evaluate the effect of AAT augmentation therapy on altered miRNA expression in monocytes and investigate the mechanism. Monocytes were isolated from non-AAT deficient (MM) and AAT deficient (ZZ) individuals, and ZZs receiving AAT. mRNA (qRT-PCR, microarray), miRNA (miRNA profiling, qRT-PCR), and protein (western blotting) analyses were performed. Twenty one miRNAs were differentially expressed 3-fold between ZZs and MMs. miRNA validation studies demonstrated that in ZZ monocytes receiving AAT levels of miR-199a-5p, miR-598 and miR-320a, which are predicted to be regulated by NFκB, were restored to levels similar to MMs. Validated targets co-regulated by these miRNAs were reciprocally increased in ZZs receiving AAT in vivo and in vitro. Expression of these miRNAs could be increased in ZZ monocytes treated ex vivo with an NFκB agonist and decreased by NFκB inhibition. p50 and p65 mRNA and protein were significantly lower in ZZs receiving AAT than untreated ZZs. AAT augmentation therapy inhibits NFκB and decreases miR-199a-5p, miR-598 and miR-320a in ZZ monocytes. These NFκB-inhibitory properties may contribute to the anti-inflammatory effects of AAT augmentation therapy.
Induced pluripotent stem cells (iPSC) are derived from human somatic cells through ectopic expression of transcription factors. This landmark discovery has been considered as a major development towards patient-specific iPSC for various biomedical applications. Unlimited self renewal capacity, pluripotency and ease of accessibility to donor tissues contribute to the versatility of iPSC. The therapeutic potential of iPSC in regenerative medicine, cell-based therapy, disease modelling and drug discovery is indeed very promising. Continuous progress in iPSC technology provides clearer understanding of disease pathogenesis and ultimately new optimism in developing treatment or cure for human diseases.
It is known that alpha1-antitrypsin deficiency is associated with emphysema in adults and liver cirrhosis in neonates. The phenotypes PiZZ and PiSZ are considered to be high risk groups. alpha1-antitrypsin deficiency is one of the most common lethal congenital disorders in Europe and the USA, occurring in approximately 1 in 2,000 caucasians of North European descent. Studies in Malaysia have found that the phenotypes PiZ and PiS are present in our population. Out of 950 samples analyzed, it was found that 10 samples were shown to be apparently Z homozygous phenotype. The phenotype is determined by high resolution isoelectrofocusing on an ultra-thin polyacrylamide gel embedded with narrow range Pi phamarlyte. The isoelectrofocused bands are confirmed by immunofixation and the plasma alpha1-antitrypsin levels determined by electroimmunoassay. The abnormal phenotypes are further confirmed by polymerase chain reaction using allele specific oligonucleotides.