HeLa cell plasma membranes. Changes in membrane protein composition during the cell cycle.

HeLa cells grown in suspension culture were synchronized by amethopterin block and thymidine reversal. In some cases an additional Colcemid block was used to obtain mitotic cells. From the various phases of the cell cycle, cells were harvested and the plasma membranes isolated. The membrane proteins were solubilized in sodium dodecyl sulphate and separated by gel electrophoresis in the presence of sodium dodecyl sarcosinate. About 35 protein bands, five of which were stained with periodic acid-Schiff reagent, appeared. Most of the bands were identical in all membrane preparations, but a few minor bands seemed to be associated with limited periods of the cell cycle. In particular, the cells in mitosis apparently contained plasma membrane proteins which did not occur in other phases. Amino acid analyses of the plasma membranes revealed no significant cell cycle-dependent changes in the amino acid composition.     

Changes in lysosomal enzyme activity in the mitotic cycle of L cells

Activities of lysosomal enzymes (acid phosphatase, N-acetyl-beta-D-glucosaminidase, acid lipase and cathepsin D) have been examined in a synchronized culture of mouse L-fibroblasts. Cell synchronization was achieved by the double thymidine block with a subsequent mitotic selection after colcemid treatment. Specific activities of the enzymes studied were found to be higher in S-G2 that in G1. There is a linear increase (approximate doubling) in enzyme activities per cell from G1 to M. Activity of galactosyltransferase, a marker of the Golgi apparatus, declined in mitotic cells in comparison with the interphase cells. Ultrastructural examination of L-cells revealed a reduction of the intracellular membrane system including the Golgi apparatus during mitosis. Changes in the Golgi apparatus activity have been considered as a possible regulatory point of lysosome formation. The data presented are compared with the results of morphological studies of lysosomal system in L-cells.     

Acid phosphatase of HeLa cells: properties and regulation of lysosomal activity by serum.

Although the subcellular distribution profile of acid phosphatase in HeLa cells is typical of a lysosomal enzyme, different lysosomal (70–80%) and supernatant forms (20–30%) have been demonstrated by their differences in pH activity curves, substrate specificities, thermal stability, sensitivity to inhibitors, and kinetics. Enzymes of the lysosomal fraction displayed anomalous kinetics in the hydrolysis of p-nitrophenyl phosphate. The major lysosomal acid phosphatase activity appears to be associated with the membrane.The total acid phosphatase activity in the cell is controlled by the concentration of serum in the medium. The specific activity in the homogenates of cells grown in high serum concentration (30%) is about twice that of cells grown in low serum concentration (1%). This doubling of specific activity holds for the lysosomal enzyme (or enzymes), but little change occurs in the supernatant form (or forms). Two other lysosomal enzymes, β-glucuronidase and N-acetyl-β-d-hexosaminidase, do not increase in specific activity. The serum-dependent formation of acid phosphatase is sensitive to cycloheximide, actinomycin D, and cordycepin. Cycloheximide blocks the increase in enzymatic activity immediately, whereas cordycepin and actinomycin D have no effect for at least 8 h. These findings suggest that de novo protein synthesis is involved in the induction of lysosomal acid phosphatase by serum and that the mRNA for this enzyme is relatively stable.     

Distribution of lysosomal enzymes in different types of rat liver cells.

Eight lysosomal enzymes were measured in different types of rat liver cells. Hepatocytes were purified by low speed centrifugation of a cell suspension obtained by treating the perfused liver with collagenase. Nonparenchymal cells (NPC) were purified by centrifugation after treating the initial cell suspension with pronase, which selectively destroys the parenchymal cells (PC). Kupffer cells were found to attach selectively to tissue culture dishes after overnight culture of an NPC suspension. The specific activity of lysosomal enzymes was generally higher in NPC than in hepatocytes, but the different enzymes were concentrated to different degrees in the NPC. Specific activity of acid phosphatase was 1.7 times higher in NPC than in hepatocytes. Specific activity of acid DNAase, on the other hand, was 8 times higher in NPC than in hepatocytes. Other enzymes showed intermediate values. Assuming that 30% of the liver cells are nonparenchymal it may be calculated that from 7% (acid phosphatase) to 25% (acid DNAase) of the hepatic lysosomal enzymes are present in the NPC. The pattern of lysosomal enzymes in cultured Kupffer cells was similar to that of the NPC from which the Kupffer cells were derived. Cathepsin D and β-glucuronidase were, however, elevated in Kupffer cells as compared with NPC. The enzyme pattern in Kupffer cells was almost identical with that of rat peritoneal macrophages.     

Activity and distribution of lysosomal enzymes during collagenous matrix-induced cartilage,bone, and bone marrow development

The appearance of the lysosomal enzymes acid phosphatase, arylsulfatase, and β-glucuronidase was studied during endochondral bone and bone marrow formation induced by implantation of demineralized bone matrix. The activities of acid phosphatase and β-glucuronidase gradually increased from the stage of mesenchymal cell proliferation on Day 3 onward to reach a peak on Day 13, during maximal bone remodeling. However, arysulfatase activity exhibited a sharp increase on Day 9, associated with the onset of cartilage hypertrophy and chondrolysis. The peak of arylsulfatase activity was also attained on Day 13. The activities of all three enzymes declined on Day 15 but acid phosphatase again exhibited an increase during hematopoietic bone marrow differentiation on Days 19–21. Histochemical and ultrastructural studies revealed intense lysosomal enzyme activity in macrophage-like cells on Day 7 and thereafter. During chondrolysis and bone remodeling, these cells were present in a perivascular location. Osteoclasts also exhibited strong reactivity for the lysosomal enzymes. Due to its characteristic temporal appearance during development of endochondral bone, arysulfatase may be used as a marker enzyme for chondrolysis and bone resorption.     

The uptake and degradation of sheep thyroglobulin by macrophages in vitro.

The activities of seven lysosomal and three mitochondrial enzymes from isolated lysosomes and mitochondria of cultivated lymphoid cell lines, obtained from 3 patients with leukemia and from 6 normal individuals, were investigated. The lysosomal enzymes included: α-glucosidase, β-glucosidase, β-galactosidase, β-glucuronidase, N-acetyl-β-glucosaminidase, aryl sulfatase and acid phosphatase. These enzymes are involved in the degradation of glycoprotein, glycolipids, mucopolysaccharide-protein complexes, polysaccharides, mucopolysaccharides, organic sulfates and phosphoric esters. In the mitochondrial fraction, glutamic, succinic and malic dehydrogenases were studied. The range of lysosomal enzyme activities obtained from cell lines of leukemic origin was found to be consistently higher than in the normal controls [200 % (aryl sulfatase) to 732% (β-glucosidase)]. The mitochondrial enzyme activities showed only slight differences between the leukemic and control cell lines. This study demonstrates that the lysosomal functions of lymphoid cells derived from patients with acute lymphoblastic leukemia are fundamentally different from those from healthy donors.     

Clearance of lysosomal hydrolases following intravenous infusion. The role of liver in the clearance of beta-glucuronidase and N-acetyl-beta-D-glucosaminidase.

Certain highly purified forms of rat lysosomal glycosidases, β-glucuronidase and N-acetyl-β-d-glucosaminidase, are rapidly cleared from the circulation following intravenous infusion. Several lines of evidence are presented which indicate that the primary site of enzyme uptake is the liver. Clearance of the two enzymes was unaffected by nephrectomy, whereas it was abolished by evisceration. Tissue distribution experiments with native and [¹²⁵I]β-glucuronidase indicate the liver as the major, if not exclusive, site of enzyme uptake. Experiments with the isolated perfused liver showed clearance of certain enzyme preparations but not others. Those enzymes cleared by the isolated perfused liver were likewise cleared in vivo. Liver fractionation studies following infusion of large doses of β-glucuronidase revealed a rapid, short-lived increase in microsomal β-glucuronidase and a slower but larger increase in lysosomal β-glucuronidase. The results indicate that β-glucuronidase, N-acetyl-β-d-glucosaminidase, and probably other glycosidases are rapidly incorporated into the lysosomal compartment of liver.     

Lysosomal hydrolases in reproductive organs during estrous cycle of the hamster

Changes in the total protein content and the activities of lysosomal hydrolases (arylsulfatase, acid phosphatases, β-glucuronidase, β-N-acetylhexosaminidase, α-L-fucosidase, and β-galactosidase) of the hamster genital tract during the 4 days of estrous cycle and in hormonally superovulated hamsters were measured. Levels of lysosomal hydrolases in uteri and uterine fluid changed significantly during the cycle. Similar changes were observed in uterine wet weight and uterine proteins. The pattern of enzyme activities in both the ovary and the oviduct were different from those in uteri. In the ovary, most enzyme activities and the total protein concentration remained elevated after ovulation. Protein concentration and enzyme activities were significantly higher in the ovary, oviduct, and uteri of superovulated hamsters as compared to controls.     

Modulation of lysosomal enzyme levels in cultured cells: effects of alterations in cell density, balanced growth, and endocytosis

Factors which influence lysosomal enzyme accumulation in cultured cells have been studied. In cell types of both fibroblast (3T6) and epithelial (HeLa) origin, acid phosphatase and β-N-acetylglucosaminidase activities increase with increasing cell density. However, in other cell lines such as BHK or chick embryo fibroblasts, little or no accumulation of lysosomal enzymes occurred with increased cell density. Increased lysosomal enzyme activity need not necessarily be accompanied by alterations in rate of cell growth, rate of pinocytosis, or amount of internalized degradable macromolecules. The stimulus for lysosomal enzyme accumulation appears to require cell contact, since sparsely plated cells do not exhibit lysosomal enzyme accumulation. In 3T6 cells, lysosomal enzymes also accumulate during “step-down” conditions, such as amino acid or serum depletion, or during unbalanced growth resulting from inhibition of cytokinesis or DNA synthesis. Increases in the specific activity of lysosomal enzymes which occur during step-down conditions or unbalanced growth require cell contact, since they are not seen in sparse cells, but are observed in medium- and high-density cells incubated in serum-free medium. Studies employing actinomycin D suggest that lysosomal enzyme levels are regulated primarily via control of enzyme synthesis, rather than enzyme degradation.     

Clearance of lysosomal hydrolases following intravenous infusion. Kinetic and competition experiments with beta-glucuronidase and N-acetyl-beta-D-glucosaminidase.

Clearance experiments with highly purified lysosomal glycosidases, β-glucuronidase and N-acetyl-β-d-glucosaminidase, following intravenous infusion revealed widely varying clearance profiles which depended on the tissue source of the enzyme. Normal rat serum β-glucuronidase and epididymal N-acetyl-β-d-glucosaminidase were cleared slowly from the circulation when compared with rat preputial gland β-glucuronidase, liver lysosomal β-glucuronidase, and liver lysosomal N-acetyl-β-d-glucosaminidase, respectively, which were cleared rapidly. Experiments comparing the catalytic properties and molecular dimensions of the enzymes revealed no differences between rapid and slow clearance forms. Kinetic analysis using the rapid clearance forms of β-glucuronidase has allowed the resolution of at least two components, rapid and slow. Clearance of the rapid component is saturable and appears to reflect binding or uptake by a limited number of sites. By contrast, the clearance rate of the slow component increased linearly with respect to dose and may be due to nonspecific or low-affinity binding. Competition experiments with β-glucuronidase-free lysosomal extract and highly purified lysosomal enzymes, but not serum glycoproteins or colloidal silver, suggest that one lysosomal enzyme inhibits clearance of others and that a common mechanism may be involved in their binding.     

Behavior of subcellular marker enzymes during the Hela cell cycle

Six enzymes associated with the activities of the nucleus (thymidine kinase), mitochondria (succinate dehydrogenase), lysosomes (acid phosphatase), peroxisomes (catalase), (cytosol lactate dehydrogenase), and the intermembranal mitochondrial space (alkaline DNase) were assayed at 2 hr intervals over the division cycle of repetitively resynchronized HeLa cells. The results indicated a high degree of reproductibility for cells synchronized by the method of perpetual resynchronization and may be of direct use to those interested in subcellular organellogenesis.     

Localization of angiotensin-converting enzyme,prolyl endopeptidase and other peptidases in cultured neuronal or glial cells

To determine the cellular localization of nervous tissue peptidases, 7 peptidases and 2 lysosomal marker enzyme activities were measured in cultured mouse and rat cells. Neuronal cells of both species exhibited higher activities of angiotensin-converting enzyme (ACE) and prolyl endopeptidase (Pro-EP) than glial cells did. In contrast, arginyl endopeptidase and lysosomal enzymes (acid phosphatase, β-glucuronidase) in the neuronal cell lines were lower than those in the glial cell lines. Other peptidases (alanyl aminopeptidase, arginyl aminopeptidase, leucyl aminopeptidase, dipeptidyl aminopeptidase) activities were not specifically localized in either cell lines. The effects of cellular differentiation on these peptidase activities in the PC 12h cell line and rat glioblasts were also examined using nerve growth factor (NGF) and glia maturation factor (GMF), respectively. Neuron specific peptidase (ACE and Pro-EP) activities were decreased in PC12h cells cultured with NGF, and Pro-EP activity was increased in the glioblast cells cultured with GMF. These results support the idea that some of the peptidases are differentially localized in neuronal or glial cells, and play physiological roles in central or peripheral neural tissues.     

Sialic acid of mammalian cell lines

Approximately two-thirds of the total sialic acid (S.A.) per cell of a number of cell lines (L-929, L5178Y, HeLa, C13, P183, and CHO) was located at the cell surface but was inaccessible to the action of trypsin, pronase, lysozyme, β-glucuronidase, or hyaluronidase. The mean surface density of S.A. ranged from 5.4 × 10⁵ molecules/μ² surface area for the L5178Y cell to 16.1 × 10⁵ molecules/μ² for the P183 cell. The P183 cell line, which is a polyoma virus-transformed derivative of Stoker's C13 line, consistently contained more S.A. per cell than the latter under a variety of growth conditions, although the two lines did not differ in mean cell volume. When mean cell volume of C13, P183, or CHO cells was experimentally manipulated by thymidine or colcemide blockade, S.A. content per cell followed size changes closely. No evidence could be found for a shift in total S.A. per unit cell volume accompanying the period of maximum mitotic activity of partially synchronized CHO suspension cultures. Comparisons between cells grown on glass and the same cells grown in suspension, or between cells grown to different densities on glass, indicated no differences in the characteristic S.A. content per cell.     

Regulatory volume decrease is actively modulated during the cell cycle

Nasopharyngeal carcinoma cells, CNE-2Z, when swollen by 47% hypotonic solution, exhibited a regulatory volume decrease (RVD). The RVD was inhibited by extracellular applications of the chloride channel blockers tamoxifen (30 microM; 61% inhibition), 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB, 100 microM; 60% inhibition), and ATP (10 mM; 91% inhibition). The level and time constant of RVD varied greatly between cells. Most cells conducted an incomplete RVD, but a few had the ability to recover their volume completely. There was no obvious correlation between cell volume and RVD capacity. Flow cytometric analysis showed that highly synchronous cells were obtained by the mitotic shake-off technique and that the cells progressed through the cell cycle synchronously when incubated in culture medium. Combined application of DNA synthesis inhibitors, thymidine and hydroxyurea arrested cells at the G1/S boundary and 87% of the cells reached S phase 4 h after being released. RVD capacity changed significantly during the cell cycle progression in cells synchronized by shake-off technique. RVD capacity being at its highest in G1 phase and lowest in S phase. The RVD capacity in G1 (shake-off cells sampled after 4 h of incubation), S (obtained by chemical arrest), and M cells (selected under microscope) was 73, 33, and 58%, respectively, and the time constants were 435, 769, and 2,000 sec, respectively. We conclude that RVD capacity is actively modulated in the cell cycle and RVD may play an important role in cell cycle progress.     

Release of cytoplasmic enzymes into culture fluid

The release of enzymatic activities from cells grown in protein-and lipid-free synthetic media into culture fluids was investigated. Cell strains employed were the derivatives from mouse fibroblasts, rat liver parenchymal cells, rat ascites hepatoma cells and HeLa cells. Activities of acid DNase, acid RNase and alkaline phosphatase (ALP)-I were detected in culture fluids as early as one day after renewal of medium, whereas those of β-glucuronidase and acid phosphatase were not found. This release of enzymes was unlikely to be caused by cell disruption during cultivation. The release of Dnase was inhibited by the addition of cycloheximide or actinbomycin D, whereas that of ALP-I was not inhibited.     

Protein synthesis and mitosis. 1. Influence of anti-tubulins on protein synthetic activity in synchronous M-phase and asynchronous populations of HeLa S-3 cells

Asynchronous and synchronous HeLa S-3 suspension cultures treated with colcemid and vinblastine (VLB) resulted, in the former case, in suppression of 3H-leucine incorporation into protein which became increasingly apparent as the percentage of M-phase-arrested cells increased. In the latter case, where no cells were allowed to enter M-phase, no significant inhibition of incorporation occurred. M-phase cells were collected by shake-off from asynchronous monolayers, or alternatively monolayers presynchronised 10 h before shake-off, either in the presence or absence of alkaloids. In both cases, alkaloid-treated cultures showed marked inhibition of protein synthesis, while controls were largely unaffected. The results indicate that marked suppression of protein synthesis in alkaloid-arrested M-phase population is primarily due to the inability of cells to complete mitosis. Arrested cells showed no increase in size or protein content with time, but began disintegrating approximately 6-7 h after alkaloid treatment. The necessity for cells to traverse M-phase quickly is emphasised, otherwise any transient decline of protein synthesis during M-phase becomes grossly exaggerated.     

Nuclear DNA polymerases and the HeLa cell cycle.

Purified nuclei of HeLa S3 cells contain two DNA-dependent DNA polymerases that have distinct physical and enzymatic properties. We have investigated the variations in their activity during the cell cycle of a synchronized culture. Cells were synchronized by a double thymidine block, harvested at various phases of the cycle, and the two DNA polymerases were purified partially by DEAE-cellulose and phosphocellulose chromatography. The activity of DNA polymerase I (low molecular weight, N-ethylmaleimide-insensitive) remains essentially constant throughout the cycle. The activity of DNA polymerase II (high molecular weight, N-ethylmaleimide-sensitive), however, increases during G1 to mid-S and declines, 7- to 10-fold between late-S and G2. Addition of cycloheximide (60 mug/ml) to cultures 12 hours after the release from thymidine block abolishes the rise in the activity of DNA polymerase II. Cycloheximide also reduced the activity of DNA polymerase I by 60%. Addition of hydroxyurea (1mM) at 1 hour after release has no effect on the activity of either enzyme. We conclude that in HeLa cells, DNA polymerase I and II are distinct enzymes, that DNA polymerase II probably functions in DNA replication and is probably induced in response to stimuli for DNA biosynthesis.     

Membranes of animal cells. V. Biosynthesis of the surface membrane during the cell cycle

KB cells grown in suspension culture were synchronized by using a double thymidine block. At various times throughout the life cycle aliquots of cells were pulsed with ¹⁴C-L-leucine, ¹⁴C-D-glucosamine and ¹⁴C-choline for one hour periods. Surface membranes, cell particulates and soluble proteins were isolated and their ¹⁴C specific activities were determined. It was found that there was a marked increase in the rate of incorporation into surface membrane just after division. The pattern of incorporation was the same for all three isotopic precursors. The rate of incorporation of isotopic precursors into soluble proteins was constant throughout the cycle. Some increase in rate of incorporation of isotope into the particulate fraction was observed during division.