Measurement of apoptosis of intact human islets by confocal optical sectioning and stereologic analysis of YO-PRO-1-stained islets.

Apoptosis is an established pathway for islet cell demise. Current protocols for assessment of islet cell apoptosis are time-consuming (as with terminal deoxynucleotide transferase-mediated dUTP nick-end labeling reaction) and involve disruption of the islet architecture (as with flow cytometry) or destruction of cell integrity (as with enzyme-linked immunosorbent assay). The membranes of apoptotic cells, but not those of live cells, are permeant to the DNA-intercalant dye YO-PRO-1. We report a novel methodology for the rapid quantification of apoptosis of human islets: confocal laser optical sectioning and stereologic analysis of intact human islets stained with YO-PRO-1 and Hoechst 33342. The advantages include (1) rapid quantification of apoptosis without disrupting islet architecture and (2) identification of significant heterogeneity in the extent of apoptosis among islets from the same isolate. Confocal laser scanning microscopy microscopic imaging of YO-PRO-1-stained islets may advance investigation of islet cell apoptosis and help develop islet parameters predictive of posttransplant function.

Regulation of the cardiac mitochondrial membrane potential by retinoids.

Cardiomyocytes suffering irreversible damage under oxidative stress during ischemia activate their suicide program. Mitochondria play a key role in this process, while they themselves are subject to regulation by a number of signaling pathways. We demonstrate here that retinoids influence mitochondrial function in cardiomyocytes. Depending on their chemical nature, retinoids can either ameliorate or exacerbate stress-related damage. Thus, vitamin A, retinol, was protective because retinol deprivation enhanced oxidative damage, as indicated by rapid loss of mitochondrial membrane potential. Supplementation with a physiological concentration of retinol reversed this effect. Anhydroretinol (AR), a known antagonist, which works by displacing retinol from the common binding sites on serine/threonine kinases, also caused mitochondrial membrane depolarization. The AR effect was both Ca(2+)-dependent and cyclosporin-sensitive, suggesting an upstream signaling mechanism rather than direct membrane effect. Our results agree with a model where retinol supports mitochondrial integrity by enabling upstream signaling processes. The consequences of disrupting these processes by AR are opening of the permeability transition pore, release of cytochrome c, and activation of the suicide program.

Maternally transmitted severe glucose 6-phosphate dehydrogenase deficiency is an embryonic lethal.

Mouse chimeras from embryonic stem cells in which the X-linked glucose 6-phosphate dehydrogenase (G6PD) gene had been targeted were crossed with normal females. First-generation (F(1)) G6PD(+/-) heterozygotes born from this cross were essentially normal; analysis of their tissues demonstrated strong selection for cells with the targeted G6PD allele on the inactive X chromosome. When these F(1) G6PD(+/-) females were bred to normal males, only normal G6PD mice were born, because: (i) hemizygous G6PD(-) male embryos died by E10.5 and their development was arrested from E7.5, the time of onset of blood circulation; (ii) heterozygous G6PD(+/-) females showed abnormalities from E8.5, and died by E11.5; and (iii) severe pathological changes were present in the placenta of both G6PD(-) and G6PD(+/-) embryos. Thus, G6PD is not indispensable for early embryo development; however, severe G6PD deficiency in the extraembryonic tissues (consequent on selective inactivation of the normal paternal G6PD allele) impairs the development of the placenta and causes death of the embryo. Most importantly, G6PD is indispensable for survival when the embryo is exposed to oxygen through its blood supply.