Time course of dolichol and dolichyl phosphate in regenerating rat liver

Changes in plasma dolichol levels, transport, and hepatic delivery during rat liver regeneration

During the proliferative process that follows partial hepatectomy in the rat, the dolichol content increases in both plasma and liver. Its transport in the blood by lipoproteins also changes. The difference in the distribution of dolichols of various chain lengths in plasma and in the liver is further enhanced during liver regeneration. The dolichol released by perfused liver shows a homologue distribution more similar to that observable in blood than in the liver, thus confirming the importance of the liver as a regulatory site for the blood dolichol supply.

Plasma membrane-bound carbonic anhydrase activity in the regenerating rat liver

Part of the carbonic anhydrase activity of hepatocytes has been reported to be located in the plasma membrane. This strategic location suggests a physiological role other than that located within the cell and probably related to the specific secretory function of these cells. Furthermore, after two-thirds hepatectomy an enzymatic retrodifferentiation has been reported. We reasoned that liver regeneration probably affects the carbonic anhydrase activity in different ways depending upon its location and hence presumably physiological role. We measured, therefore, carbonic anhydrase activity in a soluble fraction or in a plasma membrane-enriched fraction obtained from liver homogenate from rats undergoing hepatectomy (two-thirds) one, three or seven days before liver resection and homogenation. No changes in carbonic anhydrase activity were found as far as soluble fraction was concerned. However, the carbonic anhydrase activity in plasma membrane was reduced (by 55%) soon after hepatectomy, there after it increased, returning to near control value at seven days. Lactate dehydrogenase activities in soluble and plasma membrane fractions were not modified by the regenerative process. Neither was 5'-nucleotidase activity determined in plasma membrane affected by liver regeneration. In summary, these results indicate a higher sensitivity of plasma membrane carbonic anhydrase activity to the regenerative process than soluble carbonic anhydrase activity. This suggests a different control of the turnover of these isoenzymes during rat liver regeneration. The phenomenon is consistent with a different physiological role for these activities; i.e., one (plasma membrane-bound carbonic anhydrase activity) may be involved in specific functions of differentiated hepatocytes, and another (soluble carbonic anhydrase activity) may be involved in general functions shared by both differentiated and undifferentiated cells.