Transfer of concanavalin A between responding lymphocytes and syngeneic stimulating cells in cell-mediated mitogenic response.

We have studied the mechanism of the cell-mediated mitogenic response (CMMR), in which proliferative responses are generated in mouse T lymphocytes co-cultivated with syngeneic mitomycin C-treated spleen cells (Mito-SP), when either responder or stimulator cells are briefly pretreated with concanavalin A (Con A) under nonmitogenic conditions. We present evidence that an intact membrane of the stimulator cells is required in CMMR, since the response was abolished by fixation, or by freezing and thawing of stimulator cells. The fate of cell-bound Con A was studied by tracing I-Con A bound to either stimulator or responder. A lymphoblast that developed from untreated CRT stimulated by I-Con A-coated syngeneic Mito-Sp carried about 105 molecules of 125I-Con A. The amount of Con A released into the culture medium was not sufficient for inducing a mitogenic response by itself, nor to bind to cells at the level found in CMMR, suggesting that 125I-Con A was transferred directly from labeled cells to unlabeled cells. Transferred 125I-Con A found in lymphoblasts was undergraded intact Con A, as demonstrated by gel electrophoresis. Autoradiography allowed visualization of the movement of 125I-Con A from stimulator to responder cells within 60 min of cell contact.     

Studies of the cell surface of Dictyostelium discoideum during differentiation. The binding of 125I-concanavalin A to the cell surface.

125I-concanavalin A (125I-Con A) was found to be equally effective as native Con A in binding to and agglutinating cells of Dictyostelium discoideum, suggesting that iodination of the molecule had no effect on the interaction of the protein with the cell surface. Almost all of the 125I-Con A binding to the cells was inhibited by alpha-methyl glucoside. The binding of 125I-Con A to the cells was extremely rapid, and once bound, the molecule was not readily displaced by prolonged incubation or by the addition of excess native concanavalin A (Con A). In contrast, the 125I-Con A was displaced rapidly from the cell surface by alpha-methyl glucoside. The binding of 125I-Con A to D. discoideum was identical at 22 degrees and 4 degrees, and was unaffected by metabolic inhibitors, suggesting that the protein was not subject to endocytosis. The cell surface Con A binding sites became saturated at high 125I-Con A concentrations. Scatchard plots of the data indicated that growing cells possessed 4 X 10(7) sites/cell, all of equal affinity. Similar plots for "aggregation phase" cells indicated at least two classes of binding sites. A small proportion of the sites had an affinity close to that for the sites on growing cells, but the majority of the sites had a markedly decreased affinity. The total number of binding sites increased only slightly during aggregation to 5.6 X 10(7) sites/cell.     

Concanavalin A Acts as a Factor in Establishing the Dorso-Ventral Gradient in the Ventral Mesoderm of Newt Gastrula Embryos1

Con A induced dorsal differentiation in the ventral mesoderm of Cynops gastrula embryo. This process apparently requires a certain amount of Con A to be internalized as supported by the following evidence: 1) Oligomannose-type oligosaccharide, a potent inhibitor of Con A, considerably inhibited dorsalization of ventral mesoderm by Con A. The incorporation of ¹²⁵I-Con A into the ventral mesoderm was greatly inhibited by this sugar. 2) Sepharose-immobilized Con A did not dorsalize the ventral mesoderm. Con A-induced dorsalization was found to be concentration-dependent. Microautoradiograms of ¹²⁵I-Con A-treated ventral mesoderm suggest that the target site (some receptor molecules) of Con A exists inside the cell. Con A is the first pure substance reported to mimic the two properties of the organizer—neural induction of the competent ectoderm and dorsalization of the ventral mesoderm. In neural induction, Con A acts on the cell surface, while Con A apparently needs to be internalized to trigger dorsal differentiation. Interestingly, Con A-dorsalized ventral mesoderm acquired the neural inducing function of the organizer within the early phase of dorsalization.     

Concanavalin A binding to Chlamydomonas eugametos flagellar proteins and its effect on sexual reproduction

The relative amounts of Concanavalin A (Con A) bound by gamete and vegetative flagella of both mating types (mt ⁺ and mt ^-) of Chlamydomonas eugametos were determined using ¹²⁵I-Con A. Con A agglutinated all cell types by cross-linking their flagella in a random manner. No correlation was found between the extent of Con A-binding and Con A-mediated isoagglutination. Con A inhibited the sexual interaction between gametes at various levels. In mt ⁺ gametes it blocked sexual agglutination, whereas in mt ^- gametes it prevented papillar fusion. By SDS-gel electrophoresis nine Con A-binding components were found to be present in flagella. However, it was not possible to allocate a role in sexual agglutination to any of these components since they were present in all cell types, including vegetative cells which are not able to sexually agglutinate.Abbreviations Con A concanavalin A - SDS sodium dodecyl sulphate - TB Tris buffer - PBS phosphate buffered saline - HRP horse radish peroxidase - SEM scanning electron microscope - PAS periodic acid Schiff     

Triiodothyronine bound to red blood cells is not available for transport through the blood-brain barrier

Many steroid and thyroid hormones and some drugs are bound by circulating red cells. Red cell-bound ligand may not be physiologically inert, as recent studies show that red cell-bound drug is available for uptake by brain. To investigate whether triiodothyronine (T₃) is available for uptake by brain in vivo from the circulating red cell pool, the present investigations measure the effects of human erythrocytes on rat brain uptake of [¹²⁵I]T₃ in vivo. The fraction of circulating T₃ available for uptake in vivo in the presence of 0, 2, 5, 10, 22, or 44% red cells was essentially identical to the fraction of [¹²⁵I]T₃ unbound in vitro. Therefore, [¹²⁵I]T₃ bound to red cells obtained from normal volunteers is not available for uptake by brain in vivo.     

Evidence for reutilization of surface receptors for alpha-macroglobulin.protease complexes in rabbit alveolar macrophages

Rabbit alveolar macrophages internalize α-macroglobulin ¹²⁵I-trypsin complexes subsequent to binding of complexes to high affinity surface receptors. Cells were capable of accumulating a 5–10 fold greater amount of αM · ¹²⁵I-T at 37°C than at 0°C. At 0°C cell-bound αM · ¹²⁵I-T was bound solely to surface receptors, whereas at 37°C the majority (85%) of cell-bound radioactivity was intracellular. The temperature-dependent accumulation of αM · ¹²⁵I-T did not reflect a change in surface receptor number or ligand-receptor affinity. Rather, the greater rate of uptake reflected continued internalization of αM · ¹²⁵I-T complexes. At 37°C cells took up 5–9 fmole αMT per μg cell protein per hr, whereas binding to surface receptors accounted for 0.5–0.7 fmole per μg cell protein. Once bound to surface receptors internalized αM · ¹²⁵I-T was localized in lysosomes, where it was degraded at a rate of 35–45% per hr. Following binding of αM · T to receptors at 37°C, but not at 0°C, unoccupied receptors could be found on the cell surface. Using cycloheximide to probe receptor turnover, I calculated that receptors were replenished at a rate of 15% per hr. Cells incubated in the presence of cycloheximide exhibited unaltered ligand uptake and catabolism for hours. Thus the reappearance of receptor activity during ligand uptake was not primarily due to de novo receptor synthesis. The rate of ligand uptake was a function of the number of surface receptors. Measurement of αM¹²⁵I-T binding to subcellular fractions did not reveal the presence of any intracellular reservoir of receptors. These observations are consistent with the hypothesis that continued ligand uptake reflects receptor reutilization.     

Interaction of 125I-Labeled Colicin E1 with Escherichia coli

Colicin E1 protein was labeled with ¹²⁵I to specific activities of up to 2 × 10⁸ cpm/mg of protein and with no loss of the colicin biological activity. The labeled colicin bound to colicin E1-sensitive, tolerant, and immune E1-colicinogenic Escherichia coli. An E. coli mutant resistant to colicin E1 exhibited a much lower colicin-binding capacity. The average number of bound colicin molecules per sensitive cell increased as a function of the colicin concentration in the colicin cell interaction mixture and continued to increase even after loss of viability of the entire culture. Up to 2,400 colicin E1 molecules bound per cell, but saturation was not reached. Binding kinetics showed that maximum binding occurred within 2 to 5 min of colicin addition. Survival and binding assays indicated that one colicin killing unit corresponded to an average of about 100 colicin molecules bound per bacterial cell. This number, however, decreased to about 8 in more extensively washed cells. Trypsin digestion of the colicin-treated cells removed the majority of the cell-bound colicin, but in general provided little rescue from colicin killing. At low colicin concentrations, a linear relationship existed between survival and the number of trypsin-inaccessible colicin molecules. Under these circumstances and in agreement with single-hit kinetics, the relationship between the number of colicin killing units and the number of trypsin-inaccessible colicin molecules was close to 1. After trypsin digestion, cells that were nearly saturated with colicin retained about 200 trypsin-inaccessible colicin molecules per cell. The trypsin-inaccessible colicin might represent those colicin molecules that bound to the specific E colicin receptors of E. coli cells.     

A device to simplify the assay of ligand binding to cell surfaces

A sensitive and reproducible technique for characterization of the binding of ¹²⁵I-labeled protein ligands to cell surfaces is described. The physical separation of cell-bound and free ligand was accomplished by centrifugation-filtration using an assembly of plastic micro test tubes. This assembly allowed rapid and efficient separation of free and cell-bound ligands with minimal manipulation of the cells.     

Direct linkage of thrombin to its cell surface receptors in different cell types

When ¹²⁵I-thrombin was incubated with foreskin fibroblasts, cervical carcinoma cells or fibrosarcoma cells of human origin, or with secondary chick embryo cells or Chinese hamster lung cells, it became directly linked to its cell surface receptors. The thrombin-receptor complex (TH-R) was derived exclusively from a pool of ¹²⁵I-thrombin that had become specifically bound to the cell surface. The linkage was probably covalent, since the complex was resistant to boiling in sodium dodecyl sulfate and 2-mercaptoethanol. Raising the pH to 12 disrupted TH-R, but did not affect a similar complex between epidermal growth factor and its receptor, suggesting that the linkage of these mitogens to their receptors was different. Mild trypsin treatment removed the ability of cells to form TH-R; however, after a 24-h incubation in serum-free medium, trypsin-treated cells recovered the capacity to form TH-R, suggesting that TH-R resulted from interaction of ¹²⁵I-thrombin with a cellular rather than a serum component. The mitogenic response of cells to thrombin was inversely related to the fraction of specifically bound ¹²⁵I-thrombin represented by TH-R. The role of TH-R in mitogenesis may be clarified in future studies by obtaining clones of Chinese hamster lung cells that vary in their capacities to form TH-R and to respond to the mitogenic action of thrombin.     

Relationship of prolactin receptors to concanavalin A binding

Concanavalin A, which binds to specific carbohydrate determinants on the cell surface, was used to investigate the binding of prolactin to its receptors in liver membranes from female rats. The binding of ¹²⁵I-labeled ovine prolactin to receptors was sharply inhibited by concanavalin A. This effect was reversed by the competitive sugar α-methyl-D-mannopyranoside and thus required the presence of specifically bound lectin. Concentrations of concanavalin A of up to 50 μg/ml caused a progressive decrease in the apparent affinity of the prolactin receptor for hormone. When higher concentrations were used, the number of available binding sites decreased. Concanavalin A-resistant receptors, about 30% of the total, had the same dissociation constant (K_d) as the controls. The binding of ¹²⁵I-labeled concanavalin A in the same membrane preparations showed the presence of two distinct types of concanavalin A binding. At low concentrations, the lectin bound with high affinity (K_d ≈ 6.6 · 10^?8 M). At high lectin concentrations, low affinity (K_d ≈ 6.7 · 10^?5 M) binding predominated. Since high affinity concanavalin A binding was saturated at 50 μg/ml, this class of binding most likely alters the affinity of the prolactin receptor for hormone; low affinity concanavalin A binding may mask prolactin receptors, making them inaccessible to the hormone.Binding sites for concanavalin A and prolactin appear to be independent but closely related since (i) concanavalin A did not displace bound prolactin from its receptor, and (ii) detergent-solubilized ¹²⁵I-labeled prolactin-receptor complexes bound to concanavalin A-Sepharose and were eluted by α-methyl-D-mannopyranoside.     

Interaction between monensin and lysosomotropic amines in the regulation of the processing of epidermal growth factor by BALB/c 3T3 cells

Monensin, like the lysosomotropic amines Chloroquine and methylamine, caused a large accumulation of ¹²⁵I-EGF in BALB/c-3T3 cells that was due to specific increases in the amount of intracellular intact hormone. However using a pulse-chase paradigm of ¹²⁵I-EGF accumulation, marked differences were observed between monensin and the amines. When EGF was accumulated in the presence of monensin, there was a gradual loss of cell-bound radioactivity during a chase in the absence of the drug, and the labeled material recovered in. the medium primarily consisted of degraded hormone. The continued presence of monensin in the chase medium substantively prevented the loss of cell bound material, and what little was recovered in the medium consisted of intact ¹²⁵I-EGF. In contrast, when ¹²⁵I-EGF was accumulated in the presence of methylamine, predominately intact peptide was lost from the cells at a relatively high rate during the chase whether or not methylamine remained in the medium. When monensin was present in the chase medium following accumulation in the presence of either Chloroquine or methylamine, the loss of intracellular ¹²⁵I-EGF was essentially blocked.     

Binding of methylmercury(II) by HeLa S3 suspension-culture cells: Intracellular methylmercury levels and their effect on DNA replication and protein synthesis

HeLa S3 cells were exposed to varied concentrations of methylmercury over varied periods of time and its binding by the cells was studied using ²⁰³Hg-labeled methylmercuric chloride as radioactive marker. Also studied was the effect of cell-bound methylmercury on DNA replication and protein synthesis and on the growth rate of the cells. The results show that methylmercury binding is a rapid process, with much of the organomercurial bound within the the first 60 min of incubation, and that considerable quantities of organic mercury become affixed to the cells. The amounts of bound methylmercury, [CH₃Hg(II)]_bound, given in mol/cell, range from 2 × 10^?16 (at 1 h of incubation and at 1 μM CH₃Hg(II) in the medium) to almost 4 × 10^?14 (at 24 h of incubation and at 100 μM CH₃Hg(II) in the medium). A [CH₃Hg(II)]_bound value of about 30 × 10^?16 mol/cell appears to be the threshold below which cells display a normal growth pattern and below which metabolic events such as DNA replication or protein synthesis are affected only to a minor degree but above which major changes in cell metabolism and cell growth take place. Methylmercury binding by the cells is tight so that only 20% of the bound material is released from the cells over a 3-h incubation period when the cells are placed into fresh, methylmercury-free growth medium. Analysis of the binding data in terms of binding to identical and completely independent sites yields an association constant K of 7.92 × 10⁴ l/mol and for the maximum concentration of cellular binding sites the value 2.40 × 10^?14 mol/cell or 1.45 × 10¹⁰ sites/cell. Evidence is presented which shows that cellular sulfhydryl groups do not suffice to provide all the sites taken up by methylmercury and that binding, in all likelihood, involves basic nitrogen, too. The levels of cell-bound methylmercury are such that binding to HeLa DNA and HeLa chromatin, for instance, can readily take place. Methylmercury binding data obtained by using the technique of particle-induced X-ray emission (PIXE) are in good agreement with the data obtained via isotope dilution.     

High activity extracellular glucose (xylose) isomerase from a Chainia species

Summary A sclerotia-forming actinomycete of the genus Chainia secreted high levels of glucose (xylose) isomerase when grown in submerged culture on a wheat bran - yeast extract medium. Maximum activity (4 units/ml) was obtained after 3–4 days when the cell bound activity was 0.19 units/ml. The two enzymes differed significantly in pH optima (extracellular, 9.5; cell-bound, 7.0) and in their adsorption behaviour on CM and DEAE celluloses. Both Mg⁺⁺ and Co⁺⁺ are required by the cell-bound enzyme for its optimum activity while either Mg⁺⁺ or Co⁺⁺ is necessary for the extracellular enzyme.NCL Communication 3320     

Denaturation of Either Manduca sexta Aminopeptidase N or Bacillus thuringiensis Cry1A Toxins Exposes Binding Epitopes Hidden under Nondenaturing Conditions

The effect of polypeptide denaturation of Bacillus thuringiensis Cry1A toxins or purified Manduca sexta 120-kDa aminopeptidase N on the specificities of their interactions was investigated. Ligand and dot blotting experiments were conducted with ¹²⁵I-labeled Cry1Ac, Cry1Ac mutant ⁵⁰⁹QNR-AAA⁵¹¹ (QNR-AAA), or 120-kDa aminopeptidase N as the probe. Mutant QNR-AAA does not bind the N-acetylgalactosamine moiety on the 120-kDa aminopeptidase. Both ¹²⁵I-Cry1Ac and ¹²⁵I-QNR-AAA bound to 210- and 120-kDa proteins from M. sexta brush border membrane vesicles and purified 120-kDa aminopeptidase N on ligand blots. However, on dot blots ¹²⁵I-QNR-AAA bound brush border vesicles but did not bind purified aminopeptidase except when aminopeptidase was denatured. In the reciprocal experiment, ¹²⁵I-aminopeptidase bound Cry1Ac but did not bind QNR-AAA. ¹²⁵I-aminopeptidase bound Cry1Ab to a limited extent but not the Cry1Ab domain I mutant Y153D or Cry1Ca. However, denatured ¹²⁵I-aminopeptidase detected each Cry1A toxin and mutant but not Cry1Ca on dot blots. The same pattern of recognition occurred with native (nondenatured) ¹²⁵I-aminopeptidase probe and denatured toxins as the targets. The broader pattern of toxin-binding protein interaction is probably due to peptide sequences being exposed upon denaturation. Putative Cry toxin-binding proteins identified by the ligand blot technique need to be investigated under native conditions early in the process of identifying binding proteins that may serve as functional toxin receptors.     

Effect of T- and B-lymphocyte mitogens on interactions between lymphocytes and macrophages.

The mitogenic response of murine T cells ² to Con A, S-Con A and PHA was found to be macrophage-dependent. Optimal mitogenic responses were obtained when macrophage-depleted T-cell populations were reconstituted with 5% normal peritoneal macro-phages. Studies were carried out to investigate the effect of T- and B-cell mitogens on in vitro physical interactions between murine lymphocytes and macrophages. This was done by determining the number of T- or B cells binding to macrophages in the absence and in the presence of T- and B cell mitogens, and comparing the results of these experiments with the induction of lymphocyte proliferation. Con A increased the binding of T cells to macrophages when used in mitogenic doses (1–5 μg/ml). Dose response experiments showed that the same dose of Con A which produced maximal mitogenic stimulation also induced the greatest number of T cells to bind to macrophages. Nonmitogenic doses of Con A (20–50 μg/ml) did not enhance the binding of T cells, while identical doses of S-Con A both induced T cell mitogenesis and increased the number of T cells bound to macrophages. Similar results were obtained with PHA. None of the B-cell mitogens tested (LPS, EPO 127 and LAgl) increased the binding of either T or B cells to macrophages. PWM, which is mitogenic for both T and B cells, increased the binding of T cells to macrophages, but not that of B cells. In brief, the four T-cell mitogens tested (Con A, S-Con A, PHA, and PWM) induced specific physical interactions between T cells and macrophages, while none of the B-cell mitogens had any effect on the physical interactions between either B or T cells and macrophages when used in mitogenic doses.     

A Mechanism of Release of Calreticulin from Cells During Apoptosis

Calreticulin (CRT) is an endoplasmic reticulum (ER) chaperone responsible for glycoprotein folding and Ca²⁺ homeostasis. CRT also has extracellular functions, e.g. tumor and apoptotic cell recognition and wound healing, but the mechanism of CRT extracellular release is unknown. Cytosolic localization of CRT is determined by signal peptide and subsequent retrotranslocation of CRT into the cytoplasm. Here, we show that under apoptotic stress conditions, the cytosolic concentration of CRT increases and associates with phosphatidylserine (PS) in a Ca²⁺-dependent manner. PS distribution is regulated by aminophospholipid translocase (APLT), which maintains PS on the cytosolic side of the cell membrane. APLT is sensitive to redox modifications of its SH groups by reactive nitrogen species. During apoptosis, both CRT expression and the concentration of nitric oxide (NO) increase. By using S-nitroso-l-cysteine-ethyl-ester, an intracellular NO donor and inhibitor of APLT, we showed that PS and CRT externalization occurred together in an S-nitrosothiol-dependent and caspase-independent manner. Furthermore, the CRT and PS are relocated as punctate clusters on the cell surface. Thus, CRT induced nitrosylation and its externalization with PS could explain how CRT acts as a bridging molecule during apoptotic cell clearance.     

Fractionation of human lymphocytes with plant lectins. I. Structural and functional characteristics of lymphocyte subclasses isolated by an affinity technique using Lens culinaris lectin.

We have fractionated human peripheral blood lymphocytes (PBL) into subclasses with an affinity technique that takes advantage of the specific interaction between the plant lectin, Lens culinaris agglutinin (Lentil-PHA), and its cell surface receptors. PBL were incubated in plastic tubes or petri dishes coated with a gelatin layer to which lentil-PHA had been coupled using a water soluble carbodiimide compound. Adherent cells were recovered by melting the gelatin, and bound lectin was removed by exposing the cells to an appropriate sugar hapten. Approximately 25 to 50% of PBL specifically adhered to gelatin-coated tubes derivatized with lentil-PHA. Binding studies with ¹²⁵I-labeled lentil-PHA showed that, compared to unfractionated PBL which bound 2.0 × 10⁶ lentil-PHA molecules per cell, adherent cells bound more (3.7 × 10⁶/cell), and nonadherent cells bound less (1.1 × 10⁶/cell) lentil-PHA. By contrast, there were no differences among these groups for binding of other plant lectins. When stimulated in vitro by optimal mitogenic concentrations of lentil-PHA, lymphocytes adherent to lentil-PHA responded better than their nonadherent counterparts whereas the two groups responded the same to stimulation by the leukoagglutinin from Ph. vulgaris. The data indicate that plant lectins may be used to isolate PBL subclasses with different structural and functional properties.     

Structural insights into substrate specificity of crotonase from the n-butanol producing bacterium Clostridium acetobutylicum

Crotonase from Clostridium acetobutylicum (CaCRT) is an enzyme that catalyzes the dehydration of 3-hydroxybutyryl-CoA to crotonyl-CoA in the n-butanol biosynthetic pathway. To investigate the molecular mechanism underlying n-butanol biosynthesis, we determined the crystal structures of the CaCRT protein in apo- and acetoacetyl-CoA bound forms. Similar to other canonical crotonase enzymes, CaCRT forms a hexamer by the dimerization of two trimers. A crystal structure of CaCRT in complex with acetoacetyl-CoA revealed that Ser69 and Ala24 to be signature residues of CaCRT, which results in a distinct ADP binding mode wherein the ADP moiety is bound at a different position compared with other crotonases. We also revealed that the substrate specificity of crotonase enzymes is determined by both the structural feature of the α3 helix region and the residues contributing the enoyl-CoA binding pocket. A tight formed α3 helix and two phenylalanine residues, Phe143 and Phe233, aid CaCRT to accommodate crotonyl-CoA as the substrate. The key residues involved in substrate binding, enzyme catalysis and substrate specificity were confirmed by site-directed mutagenesis.     

Identification of a cadmium-binding protein from a cadmium-resistant variant of human lymphoblastoid cells (WI-L2)

Cadmium-binding protein synthesis and induction by cadmium chloride were studied in the human lymphoblastoid cell line WI-L2. Lymphoblasts were adapted to growth in 5 μM cadmium chloride (Cd^r) and these cells were 2.5-fold more resistant to cadmium than the parental line. There was no difference in the cellular protein profile between the parental line and lymphoblasts grown for a short period, less than 10 days, in cadmium chloride as measured by [³⁵S]cysteine labelling and SDS-polyacrylamide gel electrophoresis. A basal level of cadmium binding protein was apparent, however, by gel filtration. The Cd^r lymphoblasts were found to synthesize a substantial amount of cadmium-binding protein, approximately 25-fold more than the parental line. The cadmium-binding protein has the following properties which are consistent with its being a metallothionein: (1) [³⁵S]Cysteine-labelled protein eluted at a on a Sephadex G-75 column; (2) the molecular weight was estimated as 11 kDa on 7–17% SDS polyacrylamide gels; (3) the protein was heat-stable; (4) the unlabelled protein bound ¹⁰⁹Cd²⁺.