Synthesis of Pyridinium Amphiphiles Used for Transfection and Some Characteristics of Amphiphile/DNA Complex Formation

Pyridinium amphiphiles have found practical use for the delivery of DNA into cells. Starting from 4-methylpyridine, a general synthesis has been devised for the production of pyridinium amphiphiles which allows variation in both the hydrophobic part and in the headgroup area of the compounds. By means of differential scanning microcalorimetry, zeta potential, particle size measurements and cryo electron microscopy, some characteristics of the pyridinium amphiphile/ DNA complexes have been determined.

Parameters influencing the introduction of plasmid DNA into cells by the use of synthetic amphiphiles as a carrier system

Parameters that affect cellular transfection as accomplished by introducing DNA via carriers composed of cationic synthetic amphiphiles, have been investigated with the aim to obtain insight into the mechanism of DNA translocation. Such insight may be exploited in optimizing carrier properties of synthetic amphiphiles for molecules other than nucleic acids. In the present work, the interaction of vesicles composed of the cationic amphiphile dioleyloxy-propyl-trimethylammonium chloride (DOTMA) with cultured cells was examined. The results show that optimal transfection is dependent on the concentration of lipid, which determines the efficiency of vesicle interaction with the target cell membrane. as well as the toxicity of the amphiphiles towards the cell. A low lipid/DNA ratio prevents the complex from interacting with the cell surface, whereas at a relatively high amphiphile concentration the complex becomes toxic. Translocation efficiency is independent of the initial vesicle size but is affected by the size of the DNA. An incubation time of the DNA/amphiphile complex and cells of approx. 2-4 h is required for obtaining efficient transfection. In conjunction with observations on DNA/amphiphile complex-induced hemolysuis of erythrocytes. a mechanism of DNA-entry is proposed which involves translocation of the nucleic acids through pores acrosh the membranes rather than delicery via fusion or endocytosis. Dioleoylphosphatidylethanolamine, a phospholipid frequently used in a mixture with DOTMA ('lipofectin') strongly facilitates this pore formation. Translocation of the DNA is effectively prevented when the cell, are pretreated with Ca2+ or pronase. These observations suggest that Ca2+-sensitive cell surface proteins play a role in amphiphile-mediated DNA translocation.

A Fatal, Systemic Mitochondrial Disease with Decreased Mitochondrial Enzyme Activities, Abnormal Ultrastructure of the Mitochondria and Deficiency of Heat Shock Protein 60

We report on a girl presenting with facial dysmorphic features and breathing difficulties upon birth. She was hypotonic, developed a metabolic acidosis, and died two days old of heart failure. Post-mortem examination revealed abnormalities of brain, lungs, heart and liver. In cultured skin fibroblasts activities of enzymes of oxidative phosphorylation, pyruvate metabolism, beta-oxidation and other mitochondrial (mt) metabolic pathways were markedly decreased. Activities of enzymes localized in the mt outer membrane or in other cell organelles were found to be normal. The mitochondria appeared swollen and were located mainly around the nucleus. Electron micrographs showed locally disintegrated mt inner membranes and large mt vacuoles. The amount of mt heat shock protein 60 (hsp60) was about one fifth of that in controls. We conclude that this mt disorder is most likely caused by defective synthesis and maintenance of mitochondria, possibly due to a defect in mt protein import or enzyme assembly resulting from deficiency of hsp60.