Substitution of the carboxyl-terminal domain of apo AI with apo AII sequences restores the potential of HDL to reduce the progression of atherosclerosis in apo E knockout mice.

HDL metabolism and atherosclerosis were studied in apo E knockout (KO) mice overexpressing human apo AI, a des- (190-243)-apo AI carboxyl-terminal deletion mutant of human apo AI or an apo AI-(1-189)-apo AII-(12-77) chimera in which the carboxyl-terminal domain of apo AI was substituted with the pair of helices of apo AII. HDL cholesterol levels ranked: apo AI/apo E KO approximately apo AI-(1-189)-apo AII- (12-77)/apo E KO > > des-(190-243)-apo AI/apo E KO > apo E KO mice. Progression of atherosclerosis ranked: apo E KO > des-(190-243)-apo AI/apo E KO > > apo AI-(1-189)- apo AII-(12-77)/apo E KO approximately apo AI/apo E KO mice. Whereas the total capacity to induce cholesterol efflux from lipid-loaded THP-1 macrophages was higher for HDL of mice overexpressing human apo AI or the apo AI/apo AII chimera, the fractional cholesterol efflux rate, expressed in percent cholesterol efflux/microg apolipoprotein/h, for HDL of these mice was similar to that for HDL of mice overexpressing the deletion mutant and for HDL of apo E KO mice. This study demonstrates that the tertiary structure of apo AI, e.g., the number and organization of its helices, and not its amino sequence is essential for protection against atherosclerosis because it determines HDL cholesterol levels and not cholesterol efflux. Amino acid sequences of apo AII, which is considered to be less antiatherogenic, can be used to restore the structure of apo AI and thereby its antiatherogenicity.

Apoptosis affects integration frequency: adult stem cells injected in blastocysts show high caspase-3 activity.

Chimeric organisms are commonly generated by injecting stem cells into blastocysts. Embryonic stem cells injected into the blastocoel cavity participate in the further development of the embryo. Adult stem cells have also been used in injection experiments to study their potential plasticity. In this study we focused on the early fate of injected human adult hematopoietic stem cells (HSCs). HSCs were followed immunohistochemically 1-19 h after injection into murine blastocysts. We found that they only rarely attached and integrated into the blastocysts. The high rate of loss of injected cells after prolonged in vitro culture of the chimeras can be explained by apoptosis. Our findings are consistent with previous studies reporting a low rate of integration of adult cells injected to produce chimeric embryos, but this is the first demonstration that the low efficiency of adult stem cell injections into blastocysts is influenced by apoptosis.

Paraffin-embedded manipulated blastocysts: a tool to demonstrate stem cell plasticity?

One of the big question marks in current stem cell research is whether there is true plasticity of adult progenitor cells (APC) or if cell fusion is the principle source of the supposed plasticity. The generation of chimeras by injecting adult progenitor cells into blastocysts is not new. This paper describes an efficient embedding technique for murine blastocysts injected with human APC. This method could help in establishing a novel tool to analyse the process of plasticity, if it truly exists. If this is the case, this technology could be of great help to characterize surface markers of stem cells in great detail. On the other hand, fusion of cells could also be investigated. A system of embedding blastocysts was set up using paraffin for further analysis by means of light microscopy and immunohistochemistry. The embedding of the chimaeras consists of fixing them first with paraformaldehyde in phosphate-buffered saline (PFA/PBS), embedding them in gelatine, fixing the gelatine block with PFA/PBS and finally fixing the gelatine block in a Petri dish by embedding it in paraffin. Using this protocol, the morphology of the blastocysts is well preserved.

Role of the carboxy-terminal domain of human apolipoprotein AI in high-density-lipoprotein metabolism--a study based on deletion and substitution variants in transgenic mice.

Cholesterol levels in high-density lipoprotein (HDL) of transgenic mice overexpressing human apolipoprotein AI (apoAI), a des-(190-243)-apoAI deletion mutant or an apoAI-(1-189)-apoAII-(12-77) chimera were 2.8-fold (P<0.001), 1.3-fold (P<0.05) and 2.2-fold (P<0.001) higher than in control mice, respectively. Human apolipoprotein levels in apoAI and in apoAI-(1-189)-apoAII-(12-77) transgenic mice were 5.2-fold and 3.5-fold higher than in des-(190-243)-apoAI transgenic mice, whereas their HDL cholesterol levels were 2.1-fold and 1.6-fold higher. PAGE of HDL isolated by ultracentrifugation revealed that murine HDL migrated as 9.6-nm and 7.2-nm particles. Overexpression of human apoAI and apoAI-(1-189)-apoAII-(12-77) resulted in the production of polydisperse HDL (9.6, 9.2, 8.4 and 7.2 nm) particles, whereas overexpression of des-(190-243)-apoAI primarily resulted in an increase of 7.2-nm particles. The fractional catabolic rates of human apoAI and apoAI-(1-189)-apoAII-(12-77) were very similar, whereas that of des-(190-243)-apoAI was 4.9-fold higher. The endogenous production rates of human apoAI, des-(190-243)-apoAI and apoAI-(1-189)-apoAII-(12-77) in transgenic mice were very similar. It is concluded that deletion of the carboxy-terminal domain of apoAI reduces its lipoprotein association, resulting in the production of small, phospholipid-rich HDL particles that are cleared more rapidly. Substitution of the carboxy-terminal helices of apoAI with helices of apoAII restores lipoprotein association, resulting in the production of HDL, which migrates as human HDL3 and HDL2. Although the carboxy-terminal domain of the chimera contained more than 80% of the amino acid sequence of apoAII, its HDL-distribution profile in transgenic mice was very similar to that of human apoAI. This study demonstrates the importance of the helical structure of apoAI of the carboxy-terminal domain of apoAI, rather than of its exclusive amino acid sequence, in HDL metabolism.

The Arg123-Tyr166 central domain of human ApoAI is critical for lecithin:cholesterol acyltransferase-induced hyperalphalipoproteinemia and HDL remodeling in transgenic mice.

High density lipoprotein (HDL) metabolism and lecithin:cholesterol acyltransferase (LCAT)-induced HDL remodeling were investigated in transgenic mice expressing human apolipoprotein (apo) AI or an apoAI/apoAII chimera in which the Arg123-Tyr166 domain of apoAI was substituted with the Ser12-Ala75 domain of apoAII. Expression of apoAI and of the apoAI/apoAII chimera resulted in a respective 3. 5-fold and 2.9-fold increase of HDL cholesterol. Human LCAT gene transfer into apoAI-transgenic mice resulted in a 5.1-fold increase of endogenous LCAT activity. This increase was associated with a 2. 4-fold increase of the cholesterol ester-to-free cholesterol ratio of HDL, a shift from HDL(3) to HDL(2), and a 2.4-fold increase of HDL cholesterol levels. Agarose gel electrophoresis revealed that human LCAT gene transfer into human apoAI-transgenic mice resulted in an increase of pre-beta-HDL and of pre-alpha-HDL. In contrast, human LCAT gene transfer did not affect cholesterol levels and HDL distribution profile in mice expressing the apoAI/apoAII chimera. Mouse LCAT did not "see" a difference between wild-type and mutant human apoAI, whereas human LCAT did, thus localizing the species-specific interaction in the central domain of apoAI. In conclusion, the Arg123-Tyr166 central domain of apoAI is not critical for in vivo lipoprotein association. It is, however, critical for LCAT-induced hyperalphalipoproteinemia and HDL remodeling independent of the lipid-binding properties of apoAI.

Effects of alpha-hederin, a saponin extracted from Hedera helix, on cells cultured in vitro.

In this work, we have analysed the effects of alpha-hederin, a monodesmosidic triterpenoid saponin isolated from Hedera helix, on mouse B16 melanoma cells and non-cancer mouse 3T3 fibroblasts cultured in vitro. Our results indicate that, in a serum-free medium, alpha-hederin is cytotoxic and inhibits proliferation in both cell lines at rather low concentrations (< 5 micrograms/ml) after only 8 hours of treatment. Its cytotoxicity decreases in the presence of serum in which BSA seems to be able to bind the saponin. alpha-Hederin also induces vacuolization of the cytoplasm and membrane alterations leading to cell death.