Turnover of plasma membrane polypeptides in nonproliferating cultures of Chinese hamster ovary cells and human skin fibroblasts

Coordination of protein synthesis and degradation

The degree of coordination between protein synthesis and protein degradation in developing and mature cels is considered. Studies on specific enzyme and general protein turnover in developing liver and differentiating mammary gland are presented. In the mature liver mitochondrion average protein degradation rates are higher for outer membrane and intermembrane space proteins than for matrix and inner membrane proteins. Significant heterogeneity of protein degradation rates was observed only in the outer mitochondrial membrane. During postnatal development the rates of degradation of proteins in many liver cellular fractions are increased. In the mitochondrion only the average rates of degradation of proteins in the outer membrane and intermembrane space fractions increase during development. Evidence for hormonally regulated changes in both protein synthesis and degradation during mammary cell differentiation is given. The data indicate that a transitory decrease in protein degradation accompanies the increase in protein synthesis on hormonal stimulation of the tissue. The results from the two model systems are collated and used to formulate a phenomenological hypothesis of protein degradation and its integration with protein synthesis in steady-state and non-steady-state conditions.

Rapid cell surface appearance of endocytic membrane proteins in Chinese hamster ovary cells

Lactoperoxidase was used to selectively radiolabel endocytic membrane. CHO cells were incubated with enzyme at 37 degrees C for 10 min to permit lactoperoxidase internalization. Radioiodination was done at 4 degrees C. About 90% of the radioiodinated products pelleted at 100,000 X g. From 12 to 15 different electrophoretic species were detected by one-dimensional gel electrophoresis. When cells labeled by internalized lactoperoxidase were warmed to 37 degrees C, the incorporated radioactivity was lost in a biphasic manner with an overall t1/2 of approximately 20 h. Upon warming cells to 37 degrees C, the labeled species became sensitive to pronase or trypsin digestion. The increase in protease sensitivity was progressive over a 10- to 20-min period. Maximally 45% of the initially intracellular radiolabel could be released. A digest of exterior-radioiodinated cells released 50% of the incorporated radioiodine. These observations strongly suggest a rapid shuttling of approximately 90% of the radioiodinated membrane species initially present within the cell to the cell surface.

Improved yield of plasma membrane from mammalian cells through modifications of the two-phase polymer isolation procedure

Modifications to the two-phase polymer gradient procedure for isolating plasma membrane from mammalian cells have resulted in greatly increased yields of purified plasma membrane. First, the cells were not treated with a membrane stabilizer (ZnCl2) prior to homogenization. This reduced the severity of homogenization required for disruption and allowed a greater proportion of the surface membrane to form large, flattened sheets that are more easily purified than the smaller fragments formed during more severe homogenization. Second, three crude fractions obtained from the homogenate (600g, 2000g, and 12,000g pellets), rather than a single, low-speed pellet (600g) containing only large sheets of membrane, were subjected to gradient centrifugation to obtain plasma membrane. This modification allowed purification of small as well as large fragments of plasmalemma and greatly increased the yield of purified membrane. Mg+2-dependent, Na+-K+-stimulated ATPase, a marker enzyme for plasma membrane, was enriched in the purified fraction by congruent to 17-fold relative to homogenate on a specific activity basis, and the yield of isolated plasma membrane averaged 70%, and was occasionally as high as 90%.

The biosynthesis of crustacean chitin. Isolation and characterization of polyprenol-linked intermediates from brine shrimp microsomes

The biosynthesis of crustacean chitin appears to involve the participation of a lipid-linked intermediate. A microsomal preparation from larval stages of the brine shrimp Artemia salina was found to catalyze the glycosylation of exogenous [3H]dolichol phosphate, yielding a product which was insoluble in chloroform:methanol (2:1) but soluble in chloroform:methanol:water (10:10:3). Artemia microsomes catalyze the transfer of N-acetylglucosamine from UDP-N-acetylglucosamine to a lipid acceptor. After extraction of labeled lipids with either chloroform:methanol (2:1) or chloroform:methanol:water (10:10:3), labeled compounds could be purified by ion-exchange chromatography on DEAE-Sephacel. Mild acid hydrolysis of 3H-N-acetylglucosamine labeled material soluble in chloroform:methanol:water (10:10:3) yielded a series of oligosaccharides ranging from 2 to about 8 glycosyl units in size. The larger components were shown to be sensitive to chitinase digestion but resistant to treatment with alpha-mannosidase. Such 3H-N-acetylglucosamine containing compounds, prepared by both in vivo and in vitro procedures, appear to be chitin oligosaccharides. Brine shrimp microsomes also catalyze the transfer of mannose from GDP-mannose to a lipid acceptor. Mild acid hydrolysis of mannosyl lipids soluble in chloroform:methanol:water (10:10:3) yielded oligosaccharides which were sensitive to alpha-mannosidase digestion and resistant to treatment with endochitinase. The results suggest 3H-N-acetylglucosamine-labeled oligosaccharide-lipids are distinct from the mannose-labeled fraction and may participate in the formation of an endogenous primer for chitin synthesis after their transfer to a protein acceptor.

Relative stability of membrane proteins in Escherichia coli

The relative stability of membrane proteins in Escherichia coli was investigated to determine whether these proteins are degraded at heterogeneous rates and, if so, whether the degradative rates are correlated with the sizes or charges of the proteins. Cells growing in a glucose-limited chemostat with a generation time of 15 h were labeled with [(14)C]leucine. After allowing 24 h for turnover of (14)C-labeled proteins, the cells were labeled for 15 min with [(3)H]leucine. By this protocol, the rapidly degraded proteins have a high ratio of (3)H to (14)C, whereas the stable proteins have a lower ratio. The total cell envelope fraction was collected by differential centrifugation, and the proteins were separated by two-dimensional polyacrylamide gel electrophoresis. The relative ratio for each protein was determined by dividing its (3)H/(14)C ratio by the (3)H/(14)C ratio of the total membrane fraction. Although most of the 125 membrane proteins had relative ratios close to the average for the total membrane fraction, 19 varied significantly from this value. These differences were also observed when the order of addition of [(14)C]leucine and [(3)H]leucine was reversed. In control cultures labeled simultaneously with both isotopes, the relative ratios of these 19 proteins were similar to that of the total membrane fraction. Thirteen of these proteins had low relative ratios, which suggested that they were more stable than the average protein. An experiment in which the normal labeling procedure was followed by a 60-min chase period in the presence of excess unlabeled leucine suggested that the low relative ratios of 3 of these 13 proteins may be due to a slow post-translational modification step. Six membrane proteins had high relative ratios, which indicated that they were degraded rapidly. In contrast to the relationships found for soluble proteins in mammalian cells, there were no strong correlations between the degradative rates and either the isoelectric points or the molecular weights of membrane proteins in E. coli.

Rapid cell surface appearance of endocytic membrane proteins in Chinese hamster ovary cells

Lactoperoxidase was used to selectively radiolabel endocytic membrane. CHO cells were incubated with enzyme at 37 degrees C for 10 min to permit lactoperoxidase internalization. Radioiodination was done at 4 degrees C. About 90% of the radioiodinated products pelleted at 100,000 X g. From 12 to 15 different electrophoretic species were detected by one-dimensional gel electrophoresis. When cells labeled by internalized lactoperoxidase were warmed to 37 degrees C, the incorporated radioactivity was lost in a biphasic manner with an overall t1/2 of approximately 20 h. Upon warming cells to 37 degrees C, the labeled species became sensitive to pronase or trypsin digestion. The increase in protease sensitivity was progressive over a 10- to 20-min period. Maximally 45% of the initially intracellular radiolabel could be released. A digest of exterior-radioiodinated cells released 50% of the incorporated radioiodine. These observations strongly suggest a rapid shuttling of approximately 90% of the radioiodinated membrane species initially present within the cell to the cell surface.

Aging in vitro and D-glucose uptake kinetics of diploid human fibroblasts

By use of a rapid technique, initial rates of D-glucose transport were obtained during the lifespan in vitro of a commercially available strain of human embryo lung fibroblasts (Flow 2000). The apparent Km of the D-glucose carrier did not change during senescence in vitro: x = 1.8 mM (range 1.3-2.3) in phase II, x = 1.8 mM (range 1.5-2.2) in phase III. Transport rates remained constant in stationary phase II cultures, which had completed between 30% and 80% of their replicative lifespan. A wide variation, however, was observed in terminally differentiated cells (phase III), which showed a two- to threefold increase in average cell size and protein content. In some senescent cultures, glucose transport calculated on a per cell basis was also two- to threefold increased, while it was strongly decreased (-75%) in others. When calculated per unit of cell water, protein, and surface area, respectively, transport rates in phase III cultures ranged from values established for stationary phase II cultures down to very low values. Detaching cells flushed off from senescent cultures did not show measurable rates of glucose transport into the inulin impermeable cell space. Present evidence argues against the idea that an impairment of D-glucose transport might precede loss of replicative potential in aging human fibroblasts. Instead our data indicate that the transport capacity of cell membrane finally decreases during postreplicative senescence in terminally differentiated cells.

Isolation of a domain of the plasma membrane in Chinese hamster ovary cells which contains iodinatable, acidic glycoproteins of high molecular weight

A light vesicle fraction, apparently derived from the plasma membrane, was obtained following breakage of Chinese hamster ovary (CHO) cells by means of a fluid pump disrupting device. The final preparation was enriched approx. 40-fold over the homogenate in K+,Na+-stimulated ATPase and phosphodiesterase I, but only approx. 10-fold in 125I specific radioactivity after lactoperoxidase-catalyzed iodination. This preparation was compared with another plasma membrane fraction purified as large sheets via a two-phase centrifugation procedure. Two-dimensional polyacrylamide gel electrophoresis followed by Coomassie blue staining indicated that both fractions were fairly similar in polypeptide composition, although a few consistent differences were evident. However, staining of glycoproteins by the periodic acid-Schiff technique or by overlaying with 125I-labeled concanavalin A showed that the vesicle fraction was highly enriched in groups of high molecular weight, acidic glycoproteins which stain only weakly with Coomassie blue. These glycoproteins also bound 125I-labeled ricin I agglutinin and wheat germ agglutinin. They appear to be the major receptors for wheat germ agglutinin on the CHO cell surface. After surface labeling of cells by the 125I-lactoperoxidase technique, the membrane sheet fraction contained a large number of iodinated polypeptides, whereas labeling in the vesicle fraction was restricted almost entirely to the high molecular weight, acidic glycoproteins. It is proposed that the vesicle fraction constitutes a specific domain of the cell surface which is coated on its exterior by this group of glycoproteins. These components probably mask underlying proteins of the plasma membrane from external labeling.

Plasma membrane proteins and glycoproteins from Chinese hamster cells sensitive and resistant to actinomycin D

Plasma membrane proteins and glycoproteins have been isolated from Chinese hamster cells of the spontaneously transformed DC-3F parental cell line and the DC-3F/AD X line with a high level of acquired resistance to actinomycin D. Plasma membrane preparations from both cell lines band at 1.16 g/ml after isopycnic centrifugation. We present evidence to indicate differences in the leucylpeptide backbones of the antibiotic-sensitive cells and the drug-resistant DC-3F/AD X cells. In addition, there are differences in the plasma membrane glycopeptides of the two cell lines as revealed by sodium dodecyl gel electrophoresis. Drug-resistant cells synthesize a surface glycopeptide which is much larger than the major one present on the drug-sensitive cells. Both of these cell lines are devoid of 5'-nucleotidase and alkaline phosphatase activities. The role of plasma membrane protein differences in drug-resistant cells is discussed.

Influence of fixation and buffer treatment on the release of enzymes from the plasma membrane

1. Pretreatment of frozon cryostat sections with formaldehyde or calcium ions inhibits diffusion of the plasma membrane enzymes 5' nucleotidase, ATP-ase and alkaline phosphatase during incubation. 2. Treatment of fixed sections with different kinds of buffer at 37 degrees C induces diffusion of enzyme activity from the plasma membrane to other sites of the section and into the incubation medium. This buffer influence depends on temperature: at 4 degrees C only a slight diffusion occurs. Addition of phospholipase C, digitonin or taurocholate to the buffer opposes the buffer effect. 3. Pretreatment of frozen cryostat sections with a mixture of equal parts of chloroform and acetone give a good fixation of the plasma membrane enzymes 5'-nucleotidase, ATP-ase, alkaline phosphate and leucyl-beta-naphthylamidase. During this treatment the different kinds of lipids present in the membrane are ex-racted equally. After this fixation buffer treatment does not cause a visible diffusion of enzyme activity in the section. Only a slight diffusion (1 till 7 percent) into the buffer solution takes place. 4. The mentioned treatments open up possibilities to get insight into the membrane anchorage of plasma membrane enzymes.