The polymorphism in acetaldehyde dehydrogenase 2 gene, causing a substitution of Glu > Lys(504), is not associated with coronary atherosclerosis severity in Han Chinese.

Alcohol consumption has an important effect on coronary atherosclerotic heart disease (CAD). Acetaldehyde dehydrogenase 2 (ALDH2) is a key enzyme in alcohol metabolism. A G-to-A missense mutation of ALDH2 gene, which causes a Glu > Lys(504) substitution, was recently shown to be associated with carotid atherosclerosis; however, its relationship with coronary atherosclerosis has not been well studied. We, therefore, investigated this relationship in Han Chinese. There are two ALDH2 alleles (1 and 2) and their combination: 1/1 (GG, typical homozygote), 1/2 (GA, heterozygote) and 2/2 (AA, atypical homozygote) in the population. Successive Han Chinese, including 89 with myocardial infarction (MI) and 142 with unstable angina, were recruited, and underwent coronary angiography and gene sequencing. Coronary atherosclerosis severity was expressed by the number of lesioned coronary arteries (>or=50% diameter stenosis) and Gensini score, calculated based on the luminal narrowing degree and its geographic importance, as assessed by angiography. Based on their ALDH2 genotypes, the 231 patients were divided into wild-type (1/1, n = 145) and mutation groups (1/2 and 2/2, n = 86). There were no significant differences in basic clinical data between the two groups; however, the mutation group had significantly higher rates of diabetes mellitus and MI, and lower prevalence of alcohol consumption than wild-type group. Yet, the two groups were not significantly different in coronary atherosclerosis severity. Multiple regression analysis has shown that the ALDH2 genotype 1/2 or 2/2 is an independent risk factor for MI, but is not associated with coronary atherosclerosis severity in Han Chinese.

Apolipoprotein-J prevention of fetal cardiac myoblast apoptosis induced by ethanol.

Over-consumption of ethanol (EtOH) represents a major health problem. This study was to test the cytotoxicity of EtOH in cardiac stem cells or myoblasts, and the potential protective effect of apolipoprotein-J (ApoJ), a stress-responding, chaperone-like protein in high-density lipoprotein, on EtOH-injured cardiac myoblasts. In culture, EtOH-exposed canine fetal myoblasts underwent apoptosis in a concentration- and time-dependent manner. Expression ApoJ by cDNA transfection markedly reduced EtOH-induced apoptosis in the cells. ApoJ expression also restored partially the mitochondrial membrane potential and prevented the release of cytochrome-c from mitochondria into cytoplasma. Thus, ApoJ serves as a cytoprotective protein that protects cardiac stem cells against EtOH cytotoxicity.

Conserved but nonessential interaction of SRP RNA with translation factor EF-G.

4.5S RNA is essential for viability of Escherichia coli, and forms a key component of the signal recognition particle (SRP), a ubiquitous ribonucleoprotein complex responsible for cotranslational targeting of secretory proteins. 4.5S RNA also binds independently to elongation factor G (EF-G), a five-domain GTPase that catalyzes the translocation step during protein biosynthesis on the ribosome. Point mutations in EF-G suppress deleterious effects of 4.5S RNA depletion, as do mutations in the EF-G binding site within ribosomal RNA, suggesting that 4.5S RNA might play a critical role in ribosome function in addition to its role in SRP. Here we show that 4.5S RNA and EF-G form a phylogenetically conserved, low-affinity but highly specific complex involving sequence elements required for 4.5S binding to its cognate SRP protein, Ffh. Mutational analysis indicates that the same molecular structure of 4.5S RNA is recognized in each case. Surprisingly, however, the suppressor mutant forms of EF-G bind very weakly or undetectably to 4.5S RNA, implying that cells can survive 4.5S RNA depletion by decreasing the affinity between 4.5S RNA and the translational machinery. These data suggest that SRP function is the essential role of 4.5S RNA in bacteria.