Green fluorescent protein rendered susceptible to proteolysis: positions for protease-sensitive insertions.

The green fluorescent protein (GFP) is highly resistant to proteolysis and remains uncleaved after prolonged incubation with trypsin or pronase despite several putative tryptic and chymotryptic sites in exposed loops. We have rendered GFP sensitive to proteolysis by inserting five amino acids, IEGRS, in loops at position 157, 172, or 189. Excitation and emission maxima of the three insertion mutants were similar to those of wild type, but quantum yields of mutants Omega172 and Omega189 were lower, indicating increased freedom of the fluorophore. Trypsin cleaved the native (folded) form of each mutant at a unique site defined by the insert. Pronase also yields similar digestion patterns in these variants, but further proteolysis was also observed, suggesting that the primary cleavage relaxes GFP structure and reveals previously inaccessible sites. Fluorescence of Omega189 changed little upon digestion with trypsin but decreased progressively by as much as 40% upon digestion with increasing amounts of pronase. Fluorescence of other variants was not affected significantly by the proteases, further confirming the remarkable stabilities of GFP variants. These constructs define a new conformation-sensitive site around residue 189 of GFP and show that GFP may be useful for design of protease-susceptible molecules for monitoring of specific proteolytic activities in vivo.

Novel antineoplastic isochalcones inhibit the expression of cyclooxygenase 1,2 and EGF in human prostate cancer cell line LNCaP.

Experiments were conducted to determine the effects of novel anti-neoplastic isochalcones (DJ compounds), on cyclooxyegenase 1 and 2 (COX-1 and COX-2) enzyme expression in androgen receptor dependent human prostate cancer cell line LNCaP. Results from Western blot analysis and cell flow cytometry showed that DJ52 and DJ53 decreased the steady state levels of COX-1 and COX-2 protein levels in a dose dependent manner. In addition, DJ52 and DJ53 decreased the levels of epidermal growth factor (EGF) in LNCaP cells. In this study, we report that novel isochalcones decreased COX-1, COX-2 and EGF levels as well as LNCaP cellular growth in a dose responsive manner. Our findings indicate that relative decreases in COX-1, COX-2 and EGF expressions might serve as indicators of tumor growth inhibition in prostate neoplasms.

Heat-shocked A20 lymphoma cells fail to induce degranulation of cytotoxic T lymphocytes: possible mechanism of resistance.

A20 lymphoma cells were subjected to heat shock for 2 h at 42 and 43 +/- 0.1 degrees C and then evaluated at 37 degrees C for sensitivity to lysis by intact allo-specific cytotoxic T lymphocytes (CTLs), perforin-containing granules isolated from CTLs, and Fas-mediated apoptosis. Heat shock at 42 degrees C caused little change in sensitivity of the lymphoma cell line to lysis by intact CTLs or their isolated cytotoxic granules, but caused increased sensitivity to Fas-mediated apoptosis. However, A20 cells shocked at 43 degrees C declined significantly in sensitivity to lysis by intact CTLs, while remaining very sensitive to perforin granules and to Fas-mediated apoptosis. Expression of the inducible heat shock protein was observed in A20 cells incubated at 43 degrees C, but not in those incubated at 42 degrees C, suggesting a role for heat shock proteins. Furthermore, A20 cells shocked at 43 degrees C did not provoke degranulation and secretion of granzymes by antigen-specific CTLs, although formation of CTL-target conjugates and levels of MHC class I molecules remained unchanged. These observations demonstrate that hyperthermia or febrile conditions may reduce susceptibility of target cells to CTL attack due to failure of antigen presentation and the inability of CTLs to recognize heat stressed targets, thus enabling targets to escape CTL attack.

Arrest of the cell cycle reduces susceptibility of target cells to perforin-mediated lysis.

Cytotoxic T lymphocytes secrete a pore-forming cytolysin, perforin, that damages membranes of target cells. They also ligate Fas receptors on target cells and provoke apoptotic death. A20 (B lymphoma) and P815 (mastocytoma) cell lines were examined for their susceptibility to perforin-mediated lysis and to Fas-induced apoptosis after blockade of the cell cycle at the G1/S interface. Cells were arrested at the G1/S interface by inhibition of DNA synthesis with thymidine or aphidicolin. Subsequently, the treated cells were incubated either with CTL cytotoxic granules or the Fas-specific monoclonal antibody Jo-2. We show that arrest of the cell cycle at the G1/S interface markedly reduced the susceptibility of target cells to perforin-mediated lysis. In contrast, growth arrest with thymidine or aphidicolin increased susceptibility of A20 and P815 cells to Fas-mediated apoptosis. Susceptibility to lysis by intact CTLs was not affected significantly by blockade of target cells with aphidicolin or thymidine. When cells surviving exposure to perforin-containing granules were isolated on Ficoll density gradients and cell-cycle profiles were examined by flow cytometry, the ratio of G1 to G2 cells increased among the survivors exposed to granules in contrast to controls incubated with buffer alone. The data suggest that cells in G1 phase of the cell cycle are less susceptible to the perforin pathway than cells in G2 and S phases but are more susceptible to the Fas pathway.

Activity of granzyme A, a serine protease in the killing granules of cytotoxic T lymphocytes, is reduced in cells from HIV-infected hemophiliacs.

Cytotoxic CD8+ lymphocytes (CTLs) kill virally infected target cells by releasing cytotoxic granules. The primary objective of this study was to determine whether the activity of granzyme A, a serine protease in the killing granules of CTLs is altered in HIV-infected hemophiliacs. A sensitive colorimetric assay that measures cleavage of a synthetic substrate, N alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester (BLT), was used to quantitate granzyme A activity. Granzyme A activities from hemophiliacs were normalized to to granzyme A activities of healthy donors run concurrently. Granzyme A activity in CD8+ T cells from HIV-seropositive hemophiliacs was significantly lower than granzyme A activity in cells from HIV-seronegative hemophiliacs (0.48 units +/- 0.086/CD8+ T cell and 1.573 +/- 0.434 units/CD8+ T cell, respectively; p < 0.005). These results indicate that cytotoxic cells in HIV-infected hemophiliacs have reduced granzyme A activity, which may result in a defect in CTL-mediated cell killing in these patients.

Target cell lysis by cytotoxic T lymphocytes that lack detectable hemolytic perforin activity.

When mouse target cells are subjected to cytolytic attack by mouse CTL cell lines that have been cultured for many months in high levels of IL-2, and have abundant perforin-rich secretory granules, they exhibit two prominent changes: 1) rapid and massive increase (greater than 10-fold) in intracellular Ca2+ concentration and 2) fragmentation of DNA into nucleosome-sized fragments. We show here that when the same target cells are subjected to cytolytic attack by perforin-deficient CTL, either human CTL or primary mouse CTL from peritoneal exudates, the same changes are observed, suggesting that perforin-rich and perforin-deficient CTL kill their target cells by similar (if not identical) mechanisms. It is possible that perforin-deficient CTL produce enough perforin to destroy target cells but not enough to be detected by currently available methods.

Resistance of primary CD8+ cytotoxic T lymphocytes to lysis by cytotoxic granules from cloned T cell lines.

Recent evidence has shown that cloned, murine CTL cell lines are resistant to the cytotoxic components of the toxic granules they release upon specific interaction with their target cells. Inasmuch as the resistance might be due to selection in culture over many months by repeated exposure to these cytolytic components (which are released repeatedly as a result of the cultured CTL being periodically stimulated by target cells), we asked whether primary CTL are also resistant. The primary CTL were elicited in vivo by i.p. injection of allogeneic tumor cells or in vitro by 5- to 6-day MLC or by 48-h exposure to the lectin Con A. The responding cells were separated into purified CD8+ (i.e., CD4-, CD8+) and purified CD4+ (i.e., CD4+, CD8-) T cell populations that were analyzed for cytolytic activity and for resistance to lysis by toxic secretory granules derived from cloned CTL cell lines. The CD8+ T cells were highly cytolytic and relatively resistant; they retained their cytolytic activity and were lysed to a minimal extent (0 to 10%) by quantities of isolated granules that lysed 80 to 90% of the P815 tumor cell line (tested as a representative standard cell line). The CD4+ T cells, in contrast, had only minimal cytolytic activity and were far more susceptible to granule-mediated lysis. Although the resistance of primary CD8+ T cells is impressive, it is not as pronounced as the resistance of the cloned CTL cell lines, indicating that during long-term culture there is some selection for increased resistance to granule-mediated lysis. In contrast to T cells (especially CD8+ T cells), Ia+ macrophages, isolated from primary immune peritoneal exudates, were highly susceptible to granule-mediated lysis.

A comparison of the cytolytic properties of murine primary CD8+ cytotoxic T lymphocytes and cloned cytotoxic T cell lines.

Lysates of many highly cytolytic murine primary CD8+ cytotoxic T lymphocytes (CTLs) have no detectable hemolytic activity and only traces of serine esterase activity, indicating a striking paucity or absence of the perforin-rich secretory granules that are abundant in the cytoplasm of murine cloned CTL cell lines. Nevertheless, the primary CTLs are almost as resistant to granule-mediated lysis as CTL cell lines. Moreover, target cells that are lysed by all CTLs so far tested, whether primary or cell lines, show similar rapid and marked increases in intracellular calcium and breakdown of DNA into nucleosome-sized fragments. A parsimonious explanation for all of these findings is that primary CTLs, like the CTL cell lines, exercise their cytolytic activity by means of perforin, but the amounts needed are extremely small and below the level of detection by the current relatively insensitive hemolytic assays.

Calcium ion concentrations and DNA fragmentation in target cell destruction by murine cloned cytotoxic T lymphocytes.

To investigate the destruction of target cells by murine CTLs, we examined intracellular Ca2+ concentrations ([Ca2+]i) and DNA fragmentation in target cells. Changes in [Ca2+]i were followed by flow cytometry by loading the cells with indo-1, a Ca2+-binding fluorescent dye, and determining the ration of fluorescence intensities at 405 nm (emission maximum for Ca2+-bound dye) over 480 nm (emission maximum for the free dye). Within minutes after interacting with the cytolytic granule fraction that had been isolated from CTLs, [Ca2+]i in target cells was strikingly increased. A pronounced increase in [Ca2+]i was also observed in target cells when they were specifically recognized by intact CTLs. Since ionomycin, a Ca2+ ionophore, caused a similar increase in [Ca2+]i and lysed cells (provided that extracellular Ca2+ was present), it appears that a sustained high level of [Ca2+]i is cytolytic. In contrast with other cells, CTLs, which have been shown to be refractory to granule-mediated lysis and to be poor targets for other CTLs, did not manifest an elevation in [Ca2+]i when they were similarly loaded with indo-1 and treated with isolated granules. The characteristic cleavage of target cell DNA into nucleosome-sized fragments was also induced by isolated granules as well as by valinomycin, a K+ ionophore, but not by ionomycin. The results support the view that lysis of most target cells by cloned CTLs is due primarily to target cell membrane changes that are fundamentally equivalent to the formation of nonspecific ion channels. The resulting large increase in [Ca2+]i is probably responsible for target cell lysis; and changes in intracellular ion concentrations also appear to be responsible for DNA fragmentation, probably by activating endogenous target cell endonucleases.

Serine esterase and hemolytic activity in human cloned cytotoxic T lymphocytes.

Target cell lysis by most murine cytotoxic T lymphocytes appears to be mediated by a complement (C9)-like protein called perforin, contained in high-density cytoplasmic granules. These granules also contain high levels of serine esterase activity, which may also play a role in cytolysis. Analysis of 17 cloned human cytotoxic T lymphocytes revealed the presence of serine esterase that is very similar to its murine counterpart in substrate and inhibitor specificities, pH optimum, and molecular mass; dot blot hybridization with synthetic oligonucleotides corresponding to the active sites of two known murine CTL esterases suggests homology to the murine enzyme HF. However, serine esterase was present at only approximately 10% of the level found in murine CTLs, and was not secreted during CTL-target cell interaction; moreover, hemolytic activity could not be detected in any of the seven cell lines tested. The results suggest that the human CTLs examined here kill their target cells by a mechanism different from that used by most cloned murine CTLs.

Resistance of cytotoxic T lymphocytes to the lytic effects of their toxic granules.

A cytotoxic T lymphocyte (CTL) characteristically kills target cells one after the other by releasing toxic granules that contain one or more cytolytic components. To determine how CTLs avoid destroying themselves when they release granules and lyse target cells, 7 murine CD8+ CTL cell lines were compared with 19 other cell lines for susceptibility to lysis by the isolated toxic granules. Murine CD8+ CTLs were clearly the most resistant cells: granules did not lyse them even after they were exposed to azide, cyanide, and 2-deoxyglucose, conditions that were found to enhance the susceptibility of all the other cells tested, including other T cells. Thus, resistance of CD8+ CTLs to cytotoxic granules appears to be independent of cellular ATP. To reconcile these findings with other observations that, under some circumstances, CTLs can be lysed by other CTLs, we suggest a model in which a CTL releases only a limited proportion of its toxic granules at each antigen-specific encounter with a target cell; the amount released is sufficient to kill most target cells but to leave the CTL undamaged and with enough granules to attack other target cells.

An immunosuppressive factor interacts with membrane glycolipid asialo-GM1 structure.

An immunosuppressive factor was isolated from sheep-erythrocyte hyperimmunized mouse serum. Possibilities of the adsorption of the immunosuppressive factor with glycolipid asialo-GM1 incorporated liposome (dipalmitoyl lecithin) and the blockade of immunosuppressive activity by specific anti-asialo-GM1 incorporated antibody were tested. We report here that: The immunosuppressive activity of the immunosuppressive factor decreased quantitatively if the factor was preincubated with asialo-GM1 incorporated liposome (GALP) as compared with that preincubated with liposome (LP) alone; and the presence of specific anti-asialo-GM1 antibody is able to protect in vitro anti-sheep erythrocyte (SRBC) response from the suppressive effect of the immunosuppressive factor in a dose-dependent fashion under similar cell culture condition. The results indicate that asialo-GM1 may be related to the receptor of immunosuppressive factor.

A phosphorylated, disulfide-linked membrane protein in murine cytotoxic T lymphocytes.

The previously determined sequence of the murine T-cell gamma gene and its transcription in cloned T lymphocytes suggests that the polypeptide encoded by this gene is generally present in cytotoxic T cells as a 33-kDa monomer in a disulfide-bonded dimer. The gamma chain is also expected to be phosphorylated because a sequence in its cytoplasmic domain is homologous to an active site for serine phosphorylation in the regulatory subunit of cAMP-dependent protein kinase. We describe here a cytotoxic-T-cell-associated phosphorylated protein, many of whose properties suggest that it may be the product of the T-cell gamma gene. Its phosphorylation is greatly enhanced by interleukin 2 stimulation.

Serine esterase in cytolytic T lymphocytes.

The mechanisms that enable cytotoxic T lymphocytes (Tc cells) to destroy target cells are only vaguely understood. However, recent studies have identified in Tc cells and natural killer cells cytoplasmic granules that contain perforin, a cytolytic protein that resembles the ninth component of complement (C9). Antigen-specific lysis of target cells, traditionally ascribed solely to Tc cells, has now also been demonstrated in some T-helper cell (Th cell) lines, referred to here as T helper-killer or Th/c cells. We recently found a novel serine esterase that is present at greatly elevated levels in cloned murine Tc cell lines and one Th/c cell line, but not in two non-cytolytic Th cell lines. These findings suggest that the serine esterase is involved in cytolytic activity and that a variety of effector cells share a common cytolytic mechanism. To explore the role of the serine esterase in this process, we have been studying additional properties of the enzyme in murine T cells. We show here that it is a membrane-associated, disulphide-linked dimer, it has trypsin-like properties but is not a general protease, in density gradient centrifugation it sediments with perforin, it is secreted by Tc cells during their cytolytic attack on target cells, and antiserum to Tc-cell serine esterase reacts with the enzyme in Th/c cells.

Lipases specifically degrading lipopolysaccharide: fatty acyl amidases from Dictyostelium discoideum.

Two specific fatty acyl amidases that hydrolyze lipopolysaccharide have been isolated from the slime mold Dictyostelium discoideum. Esterases as well as phosphatases acting on lipid A derivatives were also observed. The first amidase (I) hydrolyzes the fatty amide adjacent to the C-1 phosphate on the disaccharide backbone of lipid A. Amidase II cleaves the distal amide, but only after deacylation of the first site. The range of specificity and the structural determinants important to specificity of the amidases were evaluated in studies of specifically modified derivatives of lipid A. In light of the effects of lipopolysaccharide on the biology of D. discoideum, a role for the amidases and other lipopolysaccharide-specific catabolic enzymes is discussed.

Fatty acyl amidases from Dictyostelium discoideum that act on lipopolysaccharide and derivatives. I. Partial purification and properties.

Two amidases have been partially purified from the slime mold Dictyostelium discoideum; these act sequentially on the beta-hydroxymyristyl-amide groups present in the lipopolysaccharide derivative (4'-O-phosphoryl-N-beta-hydroxymyristyl-D-glucosaminyl)-beta-(1 leads to 6)-N-beta-hydroxymyristyl-D-glucosamine-1-phosphate (III). Amidase-I, which specifically removes the myristyl chain near the 1-phosphate of compound III (apparent Km, 3.7 microM), has been purified 110-fold from a lysate of D. discoideum NC4 cultivated on Escherichia coli. The partially purified enzyme contains no other amidase or phosphatase activities; however, an esterase activity can be detected. The second amidase has been purified about 12-fold from the extracellular fluid of D. discoideum AX3 cultured axenically. This amidase hydrolyzes the distal amide linkage in III (apparent Km, approximately 20 microM) only after prior deacylation of the first site by amidase-I. The preparation is free from phosphatases and glycosidases that can act on lipopolysaccharide. The differential expression of the amidases in D. discoideum and some of their kinetic properties have been described. The amidases should prove useful in structure-function studies of lipopolysaccharide.

Fatty acyl amidases from Dictyostelium discoideum that act on lipopolysaccharide and derivatives. II. Aspects of substrate specificity.

The substrate specificities of two fatty acyl amidases partially purified from the slime mold Dictyostelium discoideum have been studied. The amidase act on lipopolysaccharide derivatives, such as (4'-O-phosphoryl-N-beta-hydroxymyristyl-D-glucosaminyl)-beta-(1 leads to 6)-N-beta-hydroxymyristyl-D-glucosamine-1-phosphate (III) in a sequential manner. Amidase-I removes the beta-hydroxymyristyl residue present on the amino group adjacent to the 1-phosphate and the product formed is a substrate for amidase-II; the latter removes the remaining beta-hydroxymyristyl residue from the distal amino group. Compound III itself is resistant to amidase-II. Removal of the C-1 or C-4 phosphate groups does not influence recognition by the amidases or their sequential action. Both amidases are specific for long chain fatty amide linkages. Thus, a formyl group on the glucosamine amino group adjacent to the C-1 phosphate is not hydrolyzed by amidase-I; however, this substituent does not hinder the action of amidase-II on the distal fatty acyl amide. The presence of the beta-hydroxyl group in myristyl-amide residues is not required for hydrolysis. Further, while amidase-I requires disaccharide structures for its action, amidase-II acts on monosaccharides as well. Finally, the effects of a variety of substrate analogs and divalent ions on the activity of the enzymes are reported.