Ultrastructural changes in the developing chick liver. I. General cytology

Biogenesis and function of lipolysosomes in developing chick hepatocytes

Proliferation of lipolysosomes is one of the characteristic aspects of embryonic chick hepatocytes. Formation of lipolysosomes is observed in the well-developed trans-Golgi network, with the highest frequency occurring from 11 to 14 days of incubation. The lipolysosomes usually contain a small and electron-dense lipid inclusion; however, during development, they gradually enlarge with an accompanying reduction in the electron density of the inclusion. Lipolysosomes isolated from neonatal chick liver homogenates were mainly composed of esterified cholesterol and showed considerably high activity of lysosomal enzymes. Moreover, the lipolysosome fraction is clearly shown to be a function of intralysosomal lipolysis via acid lipase. This accumulation of esterified cholesterol within lipolysosomes might be attributed to an excessive uptake and conversion of plasma lipoproteins to lipolysosomes. This concept is supported by the appearance of an abundance of coated pits and both "early" and "late" endosomes. The major components of plasma lipoprotein are low density lipoprotein (LDL) and high density lipoprotein (HDL), the cholesterol-rich lipoproteins, whose cholesterol content increases during the last week of incubation when the lipolysosomes quickly enlarge. Plasma lipoprotein particles are produced in the yolk sac epithelium from yolk very low density lipoprotein (VLDL) and transferred via the vitelline circulation to the chick liver. After hatching, when the supply of nutrients from the yolk sac is terminated, lipolysosomes immediately decrease in size and number. The cholesterol and fatty acids released are useful as an energy source and lipid metabolism in general, especially after hatching. Food intake induces the use of and accelerates the disappearance of lipolysosomes. Instead of lipolysosomes, lipid droplets appear and increase in number and size with concomitant increases of triglyceride concentrations in the liver homogenates, suggesting that lipogenesis has begun in the chick hepatocyte.

Formation and accumulation of lipolysosomes in developing chick hepatocytes

Formation and accumulation of lipolysosomes in developing chick hepatocytes were investigated by means of electron microscopy in combination with biochemical analyses of the lipid composition in liver homogenates. The lipolysosomes occurred with highest frequency from days 11 to 14 of incubation. They were usually small and electron-dense, but during development they gradually enlarged with an accompanying reduction in electron density. Coinciding with this enlargement was an accumulation of esterified cholesterol in the liver homogenates. After hatching, an immediate decrease in the size and number of lipolysosomes occurred along with a reduction in the concentration of esterified cholesterol, of which only a very small amount remained by 9 days of age. Instead of cholesterol, triglycerides subsequently increased in concentration and accounted for the major lipid content of the liver homogenates. In keeping with the ultrastructural changes, the total volume of cytoplasmic lipid droplets rapidly increased with increasing age. This transient accumulation of esterified cholesterol within lipolysosomes may be attributed to an excessive uptake and processing of plasma lipoprotein particles, probably derived from the egg yolk. This concept is supported by an abundance of coated pits, endosomes and multivesicular bodies in the embryonic hepatocytes.

Expression of the albumin gene in the yolk sac and liver during chick embryogenesis

1. Albumin mRNA is first detectable in vascular yolk sac on the third day of egg incubation, increases to peak level on day 14 and declines to zero by day 19. 2. Vascular yolk sac RNA contains a 6-10-fold higher level of albumin transcripts compared to non-vascularized yolk sac, suggesting a role for vascularization in promoting albumin gene expression. 3. Embryonic liver albumin transcripts are first detectable at day 6.5, increase 6-fold by day 8, continue to rise at a lower rate until day 14 and remain constant thereafter. 4. Albumin protein synthesis in liver cubes also exhibits a large increase over days 7-10. In contrast, another liver-specific constitutive protein, apolipoprotein B, shows a different biosynthetic pattern. 5. The data suggest development of hepatic albumin gene-specific regulatory factors over days 7-10.

Development of the liver in the chicken embryo. I. Hepatic cords and sinusoids

Hemopoiesis in the liver of the chicken embryo begins on day 7 of incubation (Hamburger and Hamilton Stage 30) and peaks on day 14 (Stage 40). During this time frame, the differentiation of hepatic cells was examined by light microscopy, transmission and scanning electron microscopy, and morphometry. The avian liver is a closely packed mass of dendriform cords and discontinuous sinusoids. Hepatocytes are pyramidal in shape, and they ring the bile canaliculi which run through the centers of the cords. Semithin sections, made possible by infiltration and embedding in glycol methacrylate, were stained with hematoxylin and eosin to assess the general architecture of the organ and the lipid content of the hepatocytes and by the periodic acid-Schiff reaction and hematoxylin to visualize the cytoplasmic stores of glycogen. The number of hepatocytes with demonstrable glycogen fluctuates erratically in early hemopoiesis, and the proportion of glycogen-containing cells progressively increases as hemopoiesis climbs to a peak. Most differentiating hepatocytes are devoid of lipid droplets until Stages 39 and 40. From Stage 30 to 35, hepatocyte volume falls to its lowest value. Subsequently (Stages 36 to 40), cell volume increases and hepatocytes achieve a relatively uniform size. Ultrastructural changes in the differentiating hepatocytes, including alterations to the mitochondria, endoplasmic reticulum, and Golgi apparatus, are documented. These morphological and morphometric findings on the prehepatocyte population and hepatic vasculature cover 2 of the 3 elements deemed critical to hepatic hemopoiesis in many vertebrates.

Developmental patterns of peroxisomal enzymes in amphibian liver during spontaneous and triiodothyronine-induced metamorphosis

1. Liver catalase, D-amino acid oxidase, urate oxidase of Alytes obstetricans and Xenopus laevis (anuran amphibians) and fatty acyl-CoA oxidase of Alytes were present at all post-embryonic stages. 2. Catalase and D-amino acid oxidase activities increased during spontaneous metamorphosis of the two species. 3. During triiodothyronine-induced metamorphosis of Alytes larvae, catalase and D-amino acid oxidase activities increased after a latent period. 4. Our results suggest that expression of some hepatic peroxisomal enzymes is modulated by thyroid hormones.

Developmental changes in the activities of peroxisomal and mitochondrial beta-oxidation in chicken liver

The activities of peroxisomal and mitochondrial beta-oxidation and carnitine acyltransferases changed during the process of development from embryo to adult chicken, and the highest activities of peroxisomal beta-oxidation, palmitoyl-CoA oxidase, and carnitine acetyltransferase were found at the hatching stage of the embryo. The profiles of these alterations were in agreement with those of the contents of triglycerides and free fatty acids in the liver. The highest activities of mitochondrial beta-oxidation and palmitoyl-CoA dehydrogenase were observed at the earlier stages of the embryo; then the activities decreased gradually from embryo to adult chicken. The ratio of activities of carnitine acetyltransferase in peroxisomes and mitochondria (peroxisomes/mitochondria) increased from 0.54 to 0.82 during the development from embryo to adult chicken. The ratio of activities of carnitine palmitoyltransferase decreased from 0.82 to 0.25 during the development. The affinity of fatty acyl-CoA dehydrogenase toward the medium-chain acyl-CoAs (C6 and C8) was high in the embryo and decreased with development, whereas the substrate specificity of fatty acyl-CoA oxidase did not change. The substrate specificity of mitochondrial carnitine acyltransferases did not change with development. The affinity of peroxisomal carnitine acyltransferases toward the long-chain acyl-CoAs (C10 to C16) was high in the embryo, but low in adult chicken.

Changes in intercellular junctions. I. Embryonic chick liver development

Quantitation of junctional changes during development may clarify the relation between intercellular junctions and processes such as cell proliferation, morphogenesis, and cytodifferentiation. Chick embryo hepatocytes at 3 days (stage 21) 6 days (stage 28), 14 days (stage 39) of incubation, and 5 days posthatching showed thymidine-labeling indices of 41 +/- 1, 33 +/- 0.8, 13 +/- 0.04, and 7 +/- 1%, respectively. This decline in mitotic activity was correlated with a gradual increase in amount of cell surface occupied by tight junctions. In early embryonic stages these junctions were characteristically linear or macular in form. At embryonic stages 28 and 39 the anastomosing strands of the tight-junction networks characteristically had many free ends while in liver from hatched chicks, tight junction strands frequently ran almost parallel to one another. The area covered by gap junctions increased at embryonic stage 28, then declined with further development. Scanning electron microscopy of developing chick liver showed that the elongated cells of hepatic buds are reorganized into hepatic cords between embryonic stages 21 and 28. Cytochemical demonstration of ATPase at the bile canalicular surface is first apparent at embryonic stage 28 and the cell surface occupied by gap junctions is highest near this time. These findings suggest that modification of proliferative rate or of synthetic activity associated with the maturation of hepatocytes could be correlated with predictable changes in junctional patterns.

Development of peroxisomes in amphibians. III. Study on liver, kidney, and intestine during thyroxine-induced metamorphosis

This investigation was undertaken to study the ontogeny of hepatic, renal, and intestinal peroxisomes and/or microperoxisomes during thyroxine-induced anuran metamorphosis. Catalase activity was localized cytochemically after incubation in DAB medium, and studied biochemically by a spectrophotometric method. Our morphological and biochemical investigations suggest the formation of a new population of peroxisomes during the hormonal treatment. This is obvious especially for microperoxisomes of the intestinal epithelium since the larval tissue is completely replaced by a new layer during thyroxine-induced metamorphosis. For the peroxisomes of hepatocytes and kidney proximal tubule cells, our assumption is based on the following observations: 1) The number of peroxisomes increases in liver and kidney during thyroxine treatment; 2) this proliferation is accompanied by an enlargement of renal peroxisomes; and 3) 16 days after the beginning of the hormonal treatment, 5.4- and 2.4-fold increases are found for the specific activities of hepatic and renal catalase, respectively. A temporal coordination exists between the structure and the metabolism of peroxisomes and mitochondria during thyroxine-induced metamorphosis.

Development of peroxisomes in amphibians. II. Cytochemical and biochemical studies on the liver, kidney, and pancreas

The ontogeny of catalase-containing organelles was studied by cytochemical and biochemical methods in the liver, kidney, and pancreas during the development of Rana catesbeiana. The biochemical differentiation of peroxisome in the liver and kidney was compared to that of Xenopus laevis. Catalase activity was localized after incubation in DAB medium and studied biochemically by a spectrophotometric method. In Rana Catesbeiana the number of catalase-positive organelles per cell section is low in all three organs during premetamorphosis; their number increases substantially in the liver and kidney of froglets, while it remains almost stable in the pancreas. No further increase is observed in the adult. Biochemically, the liver, kidney, and pancreas of tadpoles exhibit, respectively, 12,22 and 63% of the catalase activity found in the adult tissues. After metamorphosis an important increase of catalase activity is particularly noted in liver and kidney, the activity being, respectively, 43 and 77% of that of adult bullfrogs. On the other hand, no change in catalase activity in the liver and kidney is noted during the entire development of Xenopus laevis. The present study illustrates the very different developmental pattern of catalase activity observed during the development of two anuran amphibians. The different development pattern of the same enzyme within the small intestine, liver, kidney, and pancreas in Rana catesbeiana is also stressed.

Ultrastructural and biochemical alterations in the livers from chick embryos maintained in shell-less culture

Ultrastructural and biochemical studies were conducted on the livers from chick embryos maintained in shell-less culture up to stage 39 (Hamburger-Hamilton) and from control embryos developed in ovo up to the same stage. The ultrastructural characteristics of hepatic cells from the cultured embryos were similar to those found in the controls except that they contained many large lipid droplets and were almost devoid of lipoprotein granules normally associated with the Golgi complex and the smooth endoplasmic reticulum. These changes suggest the existence of alterations in the lipid metabolism. The livers from cultured embryos showed also a decreased incorporation of tritiated leucine into proteins, which indicates a reduced rate of protein synthesis. These results are consistent with previous reports showing that cultured embryos possess hypoproteinemia. Lactic dehydrogenase activity was similar and pyruvic kinase higher in the livers from cultured with respect to control embryos. This appears to indicate that both aerobic and anaerobic glycolysis were not depressed and that the changes observed in the rate of protein synthesis should not be attributed to hypoxia. "Fat-storing cells" similar to those described in mammals were found both in control and cultured embryos. They had not been previously described in the livers from chick embryos.

Differential induction of sister chromatid exchanges by indirect-acting mutagen-carcinogens at early and late stages of embryonic development

To examine the development of drug-metabolizing enzyme systems in the early chick embryo, the procarcinogens, aflatoxin B1 (AF-B1) and 2-acetylamino-fluorene (2-AAF), and the direct-acting carcinogen, ethyl methanesulfonate (EMS) (positive control), were given to embryos; the sister-chromatid-exchange (SCE) technique was used as an indicator of conversion to active mutagenic metabolites. Chick embryos at two stages of incubation (3-day and 6-day) were exposed to the same graded series of dosages of the compounds for a period of 22 hours. All three mutagens increased the frequency of SCE above the control rate of 1,8 SCEs/cell. While a dose-dependent increase in SCE was obtained for both procarcinogens at each age, the mean SCE frequency was significantly higher in the 6-day embryos for each dosage given. In contrast, the direct-acting mutagen, EMS,. gave a reduced level of SCEs at the older age. These results suggest that the ability of early chick embryos to activate promutagens to forms capable of inducing SCE increases as development advances from three to six days of incubation (DI). In the 6-day embryo, the metabolic conversion is enhanced, resulting in a significant increase in the mutagenicity of the test chemicals.

Observations on the gastric epithelium of ascidians with special reference to Styela clava

Transmission electron microscopy shows the gastric epithelium of Styela clava to comprise at least three distinct cell types. Ciliated mucous cells which form the crest of each stomach ridge produce mucus by an unexpected route. Vacuolated cells lining the ridge sides appear to be absorptive in function. Gastric enzymes are produced by typical protein secreting cells scattered amongst the vacuolated cells. Undifferentiated cells are found in the crypts between ridges. The structure and function of the gastric epithelium in Styela is discussed with special reference to the wider concepts of ascidian gut organization.

Changes in free and membrane-bound ribosomes during the development of chick liver. A new cell-fractionation approach

A major difficulty in studying quantitative changes in free and membrane-bound ribosomes in a tissue under different physiological conditions is that membrane-bound ribosomes are not usually recovered quantitatively in a conventional microsomal fraction. This problem was resolved for developing chick liver by determining the conditions for the isolation of a microsomal fraction containing the highest practicable yield of rough vesicles, and then separating it into free-ribosome- and rough-vesicle-containing fractions. With the aid of a marker enzyme for the microsomal membranes and the RNA content of the recovered membrane-bound ribosomes, it was possible to correct for the recovery of rough vesicles and hence to determine the concentration of membrane-bound ribosomes in the homogenate. Despite the fact that morphological studies have suggested that most of the cellular ribosomes are not bound to membrane in chick liver cells at the earliest developmental age studied (6 days of egg incubation), 49% of the total ribosomes were found to be membrane-bound by using the new fractionation technique. This fraction increased (to 66%) during development. The discrepancy between the cell-fractionation and morphological approaches could not be attributed to artifacts of the separation method but rather to difficulties inherent in the morphological approach.

Factors controlling development of chick embryo liver cells during organ culture

The 5 day chick embryo liver cell still lacks many of the ultrastructural features of the adult liver cell. During organ culture on rafts over Eagle's medium, it develops electron-opaque mitochondria with granules, biliary microvilli, and compact Golgi complexes containing what appears to be secretory material. Rough ER proliferates and free ribosomes become bound to membrane. Thus, the 5 day cell, exposed only to simple nutrients (glucose, amino acids, vitamins) develops the general appearance of the adult liver cell except for the continued absence of smooth ER and glycogen. The significance of this incomplete differentiation and the factors controlling development are discussed in the light of accompanying metabolic changes.

New observations on microbodies. A cytochemical study on CPIB-treated rat liver

The liver of male rats has been studied after CPIB stimulation by using the peroxidase reaction for localizing catalase in hepatic cells. CPIB administration leads to an increase in the number of microbodies, and it is suggested that one mechanism by which microbody proliferation occurs is a process of fragmentation or budding from preexisting microbodies. Reaction product was observed not only within the microbody matrix, but outside the limiting membrane of the microbody and in association with ribosomes of adjacent rough endoplasmic reticulum. This localization of reaction product is interpreted as evidence that catalase after synthesis on rough endoplasmic reticulum may accumulate near microbodies and may be transferred directly into these organelles without traversing the cisternae of the endoplasmic reticulum or Golgi apparatus.