A novel donor splice-site mutation of major intrinsic protein gene associated with congenital cataract in a Chinese family.

PURPOSE: To identify the disease-causing gene in a Chinese family with autosomal dominant congenital cataract. METHODS: Clinical and ophthalmologic examinations were performed on all members of a Chinese family with congenital cataract. Nine genes associated with congenital cataract were screened using direct DNA sequencing. Mutations were confirmed using restriction fragment length polymorphism (RFLP) analysis. The mutated multi-intronic plasmid (MIP) minigene, which carries the disease-causing splice-site mutation, and the wild-type (WT) MIP minigene were constructed using the pcDNA3.1 expression vector. Wild-type and mutant MIP minigene constructs were transiently transfected into HeLa cells. After 48 h of incubation at 37 °C, total RNA isolation and reverse transcription (RT)-PCR analysis were performed, and PCR products were separated and confirmed with sequencing. RESULTS: Direct DNA sequence analysis identified a novel splice-site mutation in intron 3 (c.606+1 G>A) of the MIP gene. To investigate the manner in which the splice donor mutation could affect mRNA splicing, WT and mutant MIP minigenes were inserted in the pcDNA3.1 (+) vector. Constructs were transfected into HeLa cells. RT-PCR analysis showed that the donor splice site mutation led to deletion of exon 3 in the mRNA encoded by the MIP gene. CONCLUSIONS: The present study identified a novel donor splice-site mutation (c.606+1G>A) in the MIP gene in a Chinese family with congenital cataract. In vitro RT-PCR analysis showed that this splice-site mutation resulted in the deletion of exon 3 from mRNA encoded by the MIP gene. This is the first report to show that donor splice-site mutation in MIP genes can cause autosomal dominant congenital cataract.

Influence of O2 and H2O on carbothermal reduction of SO2 by oil-sand fluid coke.

To develop a new process for removing high-concentration SO2 from industrial flue gases, the carbothermal reduction of SO2 by oil-sand fluid coke at 700 degrees C was investigated by varying the inlet concentration of either O2 or H2O. Concentrations of O2 and H2O ranged from 0 to 20% and from 0 to 30%, respectively, in a stream of SO2 (18%) with the balance helium. Addition of O2 and H2O was found to enhance SO2 reduction. The enhancement was attributed to the reducing gases, CO and H2, produced by solid-gas reactions between carbon and O2 or H2O. The effects of O2 and H2O on sulfur yield, however, were bifacial: adding O2 and/or H2O increased the sulfur yield when SO2 conversion was incomplete, otherwise, it decreased the sulfur yield through the formation of sulfides such as H2S. The results of a thermodynamic analysis were in a good agreementwith the experimental results, suggesting that gas-solid reactions were slow enough to allow gas-phase equilibrium. This study indicates that carbon, such as oil-sand fluid coke, can be utilized to remove SO2 in flue gases containing O2/H2O and to convert it to elemental sulfur.

Adsorption of hydrogen sulfide onto activated carbon fibers: effect of pore structure and surface chemistry.

To understand the nature of H2S adsorption onto carbon surfaces under dry and anoxic conditions, the effects of carbon pore structure and surface chemistry were studied using activated carbon fibers (ACFs) with different pore structures and surface areas. Surface pretreatments, including oxidation and heattreatment, were conducted before adsorption/desorption tests in a fixed-bed reactor. Raw ACFs with higher surface area showed greater adsorption and retention of sulfur, and heat treatment further enhanced adsorption and retention of sulfur. The retained amount of hydrogen sulfide correlated well with the amount of basic functional groups on the carbon surface, while the desorbed amount reflected the effect of pore structure. Temperature-programmed desorption (TPD) and thermal gravimetric analysis (TGA) showed that the retained sulfurous compounds were strongly bonded to the carbon surface. In addition, surface chemistry of the sorbent might determine the predominant form of adsorbate on the surface.