Limited proteolysis of some egg surface components is an early event following fertilization of the sea urchin, Strongylocentrotus purpuratus.

The surface proteins of eggs from Stronglocentrotus purpuratus were labeled with ¹²⁵I by lactoperoxidase-catalyzed iodination. The eggs were examined after solubilization and disaggregation in sodium dodecyl sulphate (SDS) by electrophoresis on SDS-polyacrylamide slab-gels. Seventy-five percent of the label was found in material with a molecular weight greater than 130,000. About 5% of the radioactivity was excluded from the gels. Upon fertilization, embryos show a redistribution of the radioactively labeled species. There is a decrease in the amount of very high molecular weight material but an increase (35–40%) in material excluded from the gel. In addition, new radioactive bands of lower molecular weight are found. This change of distribution in the radioactive bands is blocked by inclusion of soybean trypsin inhibitor either before or immediately after fertilization, which completely inhibits the cortical granule protease. The disappearance of high molecular weight components is prevented by treatment of the eggs with procaine during fertilization, although the appearance of low molecular weight bands (approximately 20,000 and 30,000) is not completely blocked by procaine treatment. Parthenogenic activation of eggs by butyric acid or partial metabolic activation by ammonia each leads to changes in the egg surface proteins which are similar but not identical to those seen after fertilization. The data suggest that the labeling occurs on the vitelline membrane, plasma membrane and jelly layer. The possible significance of limited proteolysis in fertilization is discussed.     

Cell surface and metabolic labelling of the proteins of normal and transformed chicken cells.

We have studied the surface proteins of normal and transformed chick cells using four-labelling techniques with different specificities, (a) lactoperoxidase catalysed iodination (b) galactose oxidase/B3H4 (c) pyridoxal phosphate/B3H4 and (d) periodate/B3H4. All methods labelled a large external transformation-sensitive (LETS) protein, in agreement with previous studies. In addition, using galactose oxidase and periodate labelling techniques, we present evidence which suggests that the transformed cell surface glycoproteins are more sialylated. The LETS protein was also labelled with (14C) glucosamine and after trypsinization a small band of identical molecular weight to LETS remained, possibly representing an internal pool of the protein. In contrast LETS protein labelled with (3H) fucose was completely removed by trypsin, suggesting that the internal pool of the protein is incompletely glycosylated. Evidence is also presented to show that although the level of the protein is drastically reduced at the transformed cell surface, it is still synthesised and shed into the medium.     

Accumulation and secretion of exoglucanase activity in yeast secretory mutants

Representative conditional yeast secretory mutants, blocked in transport of secretory and plasma membrane proteins from the endoplasmic reticulum (sec 18), from the Golgi body (sec 7) and in transport of secretory vesicles (sec 1), accumulated exoglucanase, a constitutive yeast activity, when incubated at the restrictive temperature (37°C). Different proportions of the accumulated activity were released by mutant cells under permissive conditions. The presence or absence of cycloheximide during the secretion period made no differences in the results. More than 90% of the internal activity was bound to membrane in wild type cells. However, only the soluble pool underwent changes during the accumulation or secretion periods. The bulk of secretory invertase accumulated by sec 1 was also soluble. By contrast sec 7 and sec 18 accumulated membrane-bound as well as soluble invertase forms and both were secreted in similar proportions in each mutant. More than 90% of the accumulated invertase was secreted at the permissive temperature in sec 18 cells. That percentage was significantly lower for exoglucanase (<65%). Concomitantly, invertase accumulated by this mutant exited from the cells with a lower half time (t 1/2=150 min). These results may be interpreted assuming that exoglucanase is exported by a passive flow of the soluble pool.Non-standard abbreviations p-NPG p-nitrophenyl--d-glucopyranoside - Con A concanavalin A - Tris tris(hydroxymethyl)-amino-methane     

Proteinase inhibitor(s) in seminal plasma of teleost fish

Anti-proteinase activity has been found in seminal plasma of three teleost fish: rainbow trout, whitefish and yellow perch. The activity was effective against trypsin (bovine and cod) and acrosin (boar), but not bovine chymotrypsin. Inhibitor activity against fish trypsin was nine- to ten-fold higher than against bovine trypsin. All anti-proteinase activity remained in the retentate after filtration through molecular filter with 30 kDa cut-off membrane and eluted from a column of Sephacryl S-200 HR at the volume characteristic for molecular weight of approximately 90 kDa (data for rainbow trout). Inhibitor(s) had low thermal stability (50–60% activity remained after 15 min at 60° C). The discovery of proteinase inhibitor(s) in the seminal plasma of teleosts raised the question of the regulatory function of this protein in the systematic group of fishes having anacrosomal spermatozoa.     

Secretion-defective mutations in the signal sequence for Saccharomyces cerevisiae invertase.

Nine mutations in the signal sequence region of the gene specifying the secreted Saccharomyces cerevisiae enzyme invertase were constructed in vitro. The consequences of these mutations were studied after returning the mutated genes to yeast cells. Short deletions and two extensive substitution mutations allowed normal expression and secretion of invertase. Other substitution mutations and longer deletions blocked the formation of extracellular invertase. Yeast cells carrying this second class of mutant gene expressed novel active internal forms of invertase that exhibited the following properties. The new internal proteins had the mobilities in denaturing gels expected of invertase polypeptides that had retained a defective signal sequence and were otherwise unmodified. The large increase in molecular weight characteristic of glycosylation was not seen. On nondenaturing gels the mutant enzymes were found as heterodimers with a normal form of invertase that is known to be cytoplasmic, showing that the mutant forms of the enzyme are assembled in the same compartment as the cytoplasmic enzyme. All of the mutant enzymes were soluble and not associated with the membrane components after fractionation of crude cell extracts on sucrose gradients. Therefore, these signal sequence mutations result in the production of active internal invertase that has lost the ability to enter the secretory pathway. This demonstrates that the signal sequence is required for the earliest steps in membrane translocation.     

Cell surface and metabolic labelling of the proteins of normal and transformed chicken cells

We have studied the surface proteins of normal and transformed chick cells using four-labelling techniques with different specificities, (a) lactoperoxidase catalysed iodination (b) galactose oxidase/B³H₄ (c) pyridoxal phosphate/B³H₄ and (d) periodate/B³H₄. All methods labelled a large external transformation-sensitive (LETS) protein, in agreement with previous studies. In addition, using galactose oxidase and periodate labelling techniques, we present evidence which suggests that the transformed cell surface glycoproteins are more sialylated.The LETS protein was also labelled with [¹⁴C]glucosamine and after trypsinization a small band of identical molecular weight to LETS remained, possibly representing an internal pool of the protein. In contrast LETS protein labelled with [³H]fucose was completely removed by trypsin, suggesting that the internal pool of the protein is incompletely glycosylated. Evidence is also presented to show that although the level of the protein is drastically reduced at the transformed cell surface, it is still synthesised and shed into the medium.     

THE INFLUENCE OF PROTEINS ON THE REACTIVATION OF YEAST INVERTASE

1. Acid-inactivated yeast invertase could not be regenerated in the presence of the proteolytic enzymes trypsin, pepsin, and chymotrypsin. 2. Certain foreign proteins of non-enzymatic nature partially inhibited the reactivation of acid-inactivated invertase. 3. Certain proteins as gelatin, lacto-globulin, and carbohydrate-free horse crystalbumin did not prevent the reactivation of invertase at all. 4. Highly purified reactivated invertase was shown to exhibit an effect typical of original native invertase; that is, acceleration of its activity in presence of foreign protein at pH 3.0. 5. Native invertase was not digested by trypsin and chymotrypsin. 6. The addition of trypsin and chymotrypsin to reactivating invertase did not affect the invertase which had already reverted to the active form, but prevented further reactivation of inactive invertase.     

Purification and properties of high-molecular-weight rabbit kininogen]

A preparation of high-molecular weight kininogen (HMWK) was isolated from rabbit citrate blood plasma and purified using chromatography on DEAE-Sephadex A-50 and CM-Sephadex C-50. From 1 mg HMWK, trypsin or kallikreine of human blood plasma release 10 mkg bradykinine. The HMWK preparation is homogeneous during electrophoresis in 7.5% polyacrylamide gel in tris-glycine buffer, pH 8.3; its electrophoretic mobility corresponds to that of alpha2-globulins. The molecular weight of HMWK estimated using the collumn with Sephadex G-200, is 130.000--150.000; the sedimentation constant S20w is 7.6. Rabbit HMWK is neither a dimer, nor a trimer of low molecular weight kininogen (LMWK), since it does not degrade into subunits after treatment by 2.5% solution of sodium dodecyl sulfate, containing 8 M urea. 0.05 M 2-mercaptoethanol and 8 M urea induce HMWK splitting into 2 fragments with respective molecular weights of 80.000 and 30.000, the kinine-containing group being localized in the low-molecular weight fragment. Estimation of rates of kinine formation by different kininogenasses from highly purified HMWK and LMWK preparations showed that those kininogens are functionally different substrates, since blood plasma kallikreines release kinines from HMWK at a greater rates, whereas tissue kallikreines, e. g. human saliva kallikreine release kinines from LMWK. The specificity of kallikreines as kininogenase, to trypsin, was determined. Tripsin removes bradykinine from both kininogens at the same rates, which are an order of magnitude less than those found for kallikreines.     

Identification of 23 complementation groups required for post-translational events in the yeast secretory pathway

Cells of a Saccharomyces cerevisiae mutant that is temperature-sensitive for secretion and cell surface growth become dense during incubation at the non-permissive temperature (37°C). This property allows the selection of additional secretory mutants by sedimentation of mutagenized cells on a Ludox density gradient. Colonies derived from dense cells are screened for conditional growth and secretion of invertase and acid phosphatase. The sec mutant strains that accumulate an abnormally large intracellular pool of invertase at 37°C (188 mutant clones) fall into 23 complementation groups, and the distribution of mutant alleles suggests that more complementation groups could be found. Bud emergence and incorporation of a plasma membrane sulfate permease activity stop quickly after a shift to 37°C. Many of the mutants are thermoreversible; upon return to the permissive temperature (25°C) the accumulated invertase is secreted. Electron microscopy of sec mutant cells reveals, with one exception, the temperature-dependent accumulation of membrane-enclosed secretory organelles. We suggest that these structures represent intermediates in a pathway in which secretion and plasma membrane assembly are colinear.     

A new form of renin in normal human plasma: “big renin” is a mixture of inactive prorenin and the new active high molecular weight renin

A new form of active renin was separated from inactive prorenin in normal human plasma by a new affinity chromatographic method on a column of Cibacron Blue F3GA-agarose. This active renin has a molecular weight of 54,000, considerably higher than the hitherto recognized active renin of 40,000 dalton in human plasma. The molecular weight of inactive prorenin was 56,000±2,000. Active renin produced from the inactive prorenin by trypsin or pepsin digestion or by acid treatment in $\text{in vitro}$ experiments showed a molecular weight of 54,000±2,000. Active renin with a molecular weight of 40,000 was not found in 6 samples of untreated plasma of normal human subjects nor was it formed by treatment with trypsin, pepsin, or acid pH. It is concluded that a large form of active renin (54,000 dalton) exists in normal human plasma which is distinct from a smaller form and that the activatable “big renin” is a mixture of this active renin and totally inactive prorenin. This explains the absence of molecular weight change during the activation of “big renin”.     

Precursor in cotranslational secretion of diphtheria toxin.

By extracellular labeling of peptides of intact Corynebacterium diphtheriae, followed by fractionation of the cells and chain completion by isolated polysomes, it is shown that diphtheria toxin is formed and secreted cotranslationally by membrane-bound polysomes; free polysomes from none. Moreover, when the chains on these polysomes were completed in vitro, in the absence of membrane they were found to include not only diphtheria toxin of a molecular weight of 62,000, but also a larger precursor of a molecular weight of 68,000. The precursor was identified by several properties: immune precipitation; conversion into toxin fragments A and B; adenosine diphosphate ribosyl-transferase activity after activation with trypsin; and cleavage to 62,000 daltons by membrane enzymes. The precursor yields an N-terminal A fragment with a broadened molecular weight distribution, compared with that from authentic toxin, thus supporting the expectation that the extra segment of the precursor is N-terminal.     

Glycoprotein and protein precursors to plasma membranes in vesicular stomatitis virus infected HeLa cells

Vesicular stomatitis virus is known to mature at HeLa cell plasma membranes. To study the process, cells, infected with vesicular stomatitis virus, were fractionated after short term labeling studies (1 min pulse, 1 min chase) to determine the assembly kinetics of G protein and M protein into plasma membranes. Newly synthesized M protein was found released in the supernatant from which free polysomes were sedimented during sucrose gradient analysis of these polysomes. If this M protein is particle bound, it must have a density of less than 1.08 g/ml. About 40% of this M protein so labeled was not sedimentable at 165,000 X g for 16 h. This newly synthesized M protein had not yet assembled into plasma membrane and thus must represent an internal pool. This and previous studies show that it has a subsequent transit time to the plasma membrane of about 2 min. Once associated with plasma membranes, M protein decayed in an approximately logarithmic fashion indicating that newly synthesized M randomly mixes (and turns over) with preexisting M protein. G protein was particle bound in a 1 min pulse, 1 min chase, and was never found released in a soluble form. At the later time when fucose is added to G protein, the oligosaccharide moiety is near to complete, and on completion is about 2,000 in molecular weight. Evidence is presented showing that fucose is probably attached to the N-acetylglucosamine of the protein carbohydrate linkage. G protein to which fucose had just been added was located internally on a membranous fraction of density 1.14 g/ml in sucrose; its subsequent transit time from this pool (which in uninfected cells is between 1–2% of the total cell fucosyl glycoprotein) was about 15 min. Because their densities were different and their transit times were different, internal newly synthesized M and fucosyl G protein which assemble into plasma membranes were not on the same internal membranous component. Association of M protein with the plasma membranes may thus occur from a nonsedimentable soluble cytoplasmic pool by a process of direct adsorption.     

Properties of Invertases in Sugar Storage Tissues of Citrus Fruit and Changes in Their Activities during Maturation

Both acid and alkaline invertases were present in immature juice sacs of satsuma mandarin (Citrus‘Unshu Marcovitch”) fruit, in which sugar content was low. Maturing and mature juice sacs, in which sugar content increased steadily with time, were characterized by the presence of alkaline invertase and the absence of acid invertase. When the immature juice sacs were homogenized with 0.2 M sodium phosphate-citrate buffer (pH 8.0), almost all of the acid invertase activity was found in the solubilized fraction, whereas almost all of the alkaline invertase activity was present in the insoluble fraction. The distribution of alkaline invertase between the solubilized and insoluble fractions changed with the development of fruit. The acid invertase had a molecular weight of 69,000, optimum pH of 4.8–5.3, and K_m value for sucrose of 7.3 mM. The alkaline invertase had a molecular weight of 200,000, pH optimum of 7.2–7.7, and K_m value of 35.7 mM. The hydrolysing activities of both enzymes for raffinose were considerably less than those for sucrose. The alkaline invertase had lower activity for raffinose than the acid invertase.     

The plasma membrane of Saccharomyces cerevisiae. Isolation and some properties.

The isolation of Saccharomyces cerevisiae plasma membrane was carried out after hypotonic lysis of yeast protoplasts treated with concanavalin A by two independent methods: a, at low speed centrifugation and b, at high speed centrifugation in a density gradient. Several techniques (electron microscopic, enzymic, tagging, etc.) were used to ascertain the degree of purification of the plasma membranes obtained. The low speed centrifugation technique as compared with the other method gave a higher yield of plasma membranes with a similar degree of purification. Analysis of the yeast plasma membrane of normally growing cells by sodium dodecyl sulphate polyacrylamide gel electrophoresis showed at least 25 polypeptide bands. Twelve glycoprotein bands were also found, and their apparent molecular weights were determined. Treatment of the protoplasts with cycloheximide resulted in a significant decrease in the carbohydrate and protein content of the plasma membrane. The electrophoretic pattern of the plasma membrane of cycloheximide-treated cells showed a redistribution of the relative amounts of each protein band and a drastic reduction in the number of Schiff-positive bands. The isoelectric point of the most abundant proteins was low (pI 4) or lower than expected from previous data. A large part of the mannosyl transferase activity found in the cell (80%) was associated with the internal membranes, the remaining activity (20%) was located in the plasma membrane preparation. Part of the mannosyl transferase activity of the cells is located at the plasma membrane surface. Invertase (an external mannoprotein) is found in both the plasma and internal membranes, and as the specific activity dropped significantly following cycloheximide treatment of the cells, it is suggested that these membranes systems are the structures for the glycosylation of a precursor invertase and its subsequent release into the periplasmic space. Other transferase found in the plasma membrane preparation transfers glucose residues from UDPglucose to a poly(alpha(1 leads to 4) polymer identified as glycogen.     

Transport and processing of endogenously synthesized ApoE on the macrophage cell surface

We have previously established the presence of a pool of apoE sequestered on the macrophage cell surface by demonstrating its displacement from a cell monolayer at 4 degrees C. In this series of experiments, we use a cell surface biotinylation protocol to directly quantitate apoE on the macrophage cell surface and evaluate its transport to and from this cell surface pool. In human monocyte-derived macrophages labeled to equilibrium and in a mouse macrophage cell line transfected to constitutively express human apoE3, approximately 8% of total cellular apoE was present on the surface, but only a portion of this surface pool served as a direct precursor to secreted apoE. The half-life of apoE on the macrophage cell surface was calculated to be approximately 12 min. On SDS-polyacrylamide gel electrophoresis, the apoE isolated from the surface fraction of cells labeled to equilibrium migrated in an isoform pattern distinct from that observed from the intracellular fraction, with the surface fraction migrating predominantly in a higher molecular weight isoform. Pulse labeling experiments demonstrated that newly synthesized apoE reached the cell surface by 10 min but was predominantly in a low molecular weight isoform. There was also a lag between appearance of apoE on the cell surface and its appearance in the medium. Biotinylated apoE, which accumulated in the medium, even from pulse labeled cells, was predominantly in the high molecular weight isoform. Additional experiments demonstrated that low molecular weight apoE present on the cell surface was modified to higher molecular weight apoE by the addition of sialic acid residues prior to secretion and that this conversion was inhibited by brefeldin A. These results demonstrate an unexpected complexity in the transport and cellular processing of macrophage cell surface apoE. Factors that modulate the size and turnover of the cell surface pool of apoE in the macrophage remain to be identified and investigated.     

A membrane-associated isozyme of invertase in yeast precursor of the external glycoprotein

An enzymatic test is described which allows the localization of yeast invertase activity directly on sodium dodecyl sulfate gels. When crude membrane fractions are prepared from Saccharomyces cerevisiae cells which are actively synthesizing external invertase, these membranes show an activity band on sodium dodecyl sulfate gels additional to the external and the internal invertase. In the soluble fraction this form was completely absent. It has a molecular weight of approximately 190 000 and was 50 000 smaller than the external invertase. It showed kinetic characteristics of a precursor of the external enzyme. Thus it appeared transiently, when yeast cells were shifted from a condition of non-synthesizing external invertase to one where the enzyme was synthesized. When the increase in the external enzyme slowed down after some time, the membrane-associated form almost completely disappeared.The addition of tunicamycin to yeast cells synthesizing external invertase inhibited further synthesis of the enzyme by 97%; also the formation of the membrane-associated form was strongly inhibited. The amount of it present before the addition of tunicamycin completely disappeared in the presence of the antibiotic. The precursor form, therefore, seems to possess already those carbohydrate parts which contain N-acetylglucosamine and are transferred via dolichyl phosphate-bound intermediates. The membrane-associated precursor amounts to less than 5% of the total invertase activity of a yeast cell.     

Proteinase inhibitory activity in the plasma of a mollusc: evidence for the presence of alpha-macroglobulin in Biomphalaria glabrata.

1. A methylamine-sensitive inhibitor was present in the plasma of B. glabrata. 2. This inhibitor decreased trypsin activity against a protein substrate, however trypsin retained activity against a low molecular weight substrate in the presence of the inhibitor. 3. Snail plasma protected trypsin from inhibition by soybean trypsin inhibitor. 4. The results give evidence for an alpha-macroglobulin proteinase inhibitor in the plasma of this gastropod mollusc.     

Isolation and partial characterization of a low molecular weight trypsin inhibitor from human urine

A low molecular weight glycoprotein which completely inhibited trypsin at a 1 : 1 molar ratio was isolated from human urine. It was generated from a precursor molecule which in turn derived from plasma inter-alpha-trypsin inhibitor. It had one polypeptide chain with a molecular weight of about 20 000 and a high content of half-cystine residues. Its amino-terminal amino-acid sequence was Val-Thr-Glu-Val-Thr-X-Leu-Glu-Asp-.     

Chick bone collagenase inhibitor and latency of collagenase

Collagenase and collagenase inhibitor were isolated from the culture fluid of embryonic chick bone. The inhibitor, separated as a high molecular weight aggregate (160,000–200,000 daltons) during gel filtration in 1M NaCl, dissociated in 6M urea to species of approx 25,000 daltons. The inhibition of collagenase activity by the addition of inhibitor was not reversed by the addition of trypsin or p-aminophenylmercuric acetate. However, isolated inhibitor alone was inactivated by treatment with either trypsin or p-aminophenylmercuric acetate. The results suggest that the latent form of chick bone collagenase is a proenzyme which converts into an active form without a detectable change in molecular weight and that this occurs after the inactivation of collagenase inhibitor.