Role of high density lipoproteins in regulation of hepatic fatty acid synthesis by chylomicron and very low density lipoprotein remnants.

High density lipoproteins (HDL) have been implicated in the transformation of native triglyceride-rich lipoproteins into their corresponding remnant particles during the action of peripheral lipoprotein lipase. The subsequent metabolism of these remnant particles by the liver results in the inhibition of hepatic lipogenesis. In the present study, remnant particles of chylomicrons or very low density lipoproteins (VLDL) have been generated in the perfused heart system both in the absence and presence of HDL. These have been characterized chemically, and the effects of both native lipoproteins and their respective remnants on fatty acid synthetic rates of hepatocytes have been assessed. Thirty to sixty-six per cent of the triglyceride moieties of native lymph chylomicrons or VLDL were hydrolyzed during a 45-min heart perfusion whether or not HDL was present in the perfusion media. Chylomicron remnants produced in the absence of HDL (25-300 micrograms/ml) caused only 10-20% inhibition of hepatic fatty acid synthesis, whereas remnants produced in the presence of HDL caused up to 78% inhibition at equivalent protein concentrations. The nonsuppressive remnants (produced in the absence of HDL) were converted to suppressive remnants upon incubation with HDL. Similar results were obtained with VLDL remnants produced in the absence and presence of HDL. The sodium dodecyl sulfate-polyacrylamide gel electrophoresis apoprotein profiles of the nonsuppressive and suppressive remnants indicated a marked loss of the C apoproteins during the conversion of native chylomicrons or the nonsuppressive remnants to the suppressive remnants. Thus, HDL seems to be required for the removal of apoprotein C during the transformation of triglyceride-rich lipoproteins to the suppressive remnants. There was, however, no enrichment of apo-E on the suppressive remnant particles. We, thus, could not verify the suggested role of HDL in enriching the suppressive remnants with apoproteins E.

Phospholipase activity in bacteriophage-infected Escherichia coli. III. Phopholipase A involvement in lysis of T4-infected cells.

Bacteriophage studies with Escherichia coli K-12 (gamma)DR-DS-, a mutant lacking the major known fatty acyl hydrolases (phospholipases), and its wild-type parent showed equivalent phage infection with regard to phage production and time of phage release. Further examination of the DR-DS- mutant, however, revealed that the progeny bacteriophage were released without complete dissolution of the host cell. Prolonged cell integrity of the infected mutant was noted by spectrophotometry and supported by direct microscope examination. The phage release occurred at normal "lysis" time with phage yields comparable to that of the wild-type bacteria. Inner membrane degradation was indicated by the release of beta-galactosidase, a cytoplasmic enzyme, and of trichloracetic acid-precipitable RNA. Thus, outer membrane degradation is required for dissolution of phage-infected cells, and this degradation is at least partly dependent on activation of host phospholipases.

Does phospholipase have a role in killing and sodium dodecyl sulfate lysis of T4 ghost-infected Escherichia coli?

The activation of Escherichia coli phospholipase by T4 ghost attachment was shown not to have a significant role in the killing or in the increased sensitivity of the bacterial cells to lysis by sodium dodecyl sulfate.