A noncytotoxic mast cell tumor line exhibits potent IgE-dependent cytotoxicity after transfection with the cytolysin/perforin gene

To test the granule exocytosis model for lymphocyte cytotoxicity, we have expressed the gene for the cytotoxic lymphocyte granule protein cytolysin (perforin) in the noncytotoxic rat basophilic leukemia (RBL) cell line, which undergoes granule exocytosis when its high affinity IgE receptor is cross-linked. Homogenates of RBL-cytolysin (RBL-cy) transfectants showed a calcium-dependent hemolytic activity in dense granule fractions, demonstrating that the expressed cytolysin protein was correctly targeted to secretory granules. RBL-cy transfectants showed a potent and calcium-dependent cytolytic activity against IgE-coated RBCs, while the parental RBL line was not cytotoxic under these conditions. RBL-cy cells did not lyse non-IgE-coated RBCs copelleted with targets: this sparing of "innocent bystanders" parallels cytotoxic T lymphocyte lysis and suggests a polarized secretion of cytolysin. In contrast to RBC targets, IgE-coated tumor cells were much less sensitive to lysis by RBL-cy transfectants.     

Purification and properties of cytoplasmic granules from cytotoxic rat LGL tumors

To evaluate the role of NK cell granules in the lytic activity of NK cells, cytoplasmic granules of rat NK tumors were purified by centrifugation of the cell homogenates in a Percoll gradient. Analysis of such gradients showed a band of light-scattering material near the bottom of the tube; assay of gradient fractions for lytic activity against SRBC showed a potent lytic activity giving a sharp peak in this region. Complete lysis of SRBC was achieved with less than 1 microgram/ml protein of the most active fractions. Examination in the electron microscope showed that a pool of fractions containing lytic activity consisted of pure cytoplasmic granules showing similar morphology to those found in the LGL tumors. The lytic band was associated with a peak in the activity of four different lysosomal enzymes. Analysis of Percoll gradient fractions showed that marker enzymes for mitochondria, plasma membrane, and cytosol were well separated from this activity peak. Analysis of the Percoll gradient fractions by SDS gel electrophoresis showed that this granule fraction was free of contamination of proteins from other parts of the gradient. The granules contained major protein bands of 62, 58, 30, 29, and 28 kilodaltons. In addition to protein, the purified granule fractions contain hexose and uronic acid, but no nucleic acids or phospholipids were detected in chemical assays. Major amounts of chymotryptic, tryptic, and elastase activities were not present, nor were peroxidase or lysozyme activities detectable in substantial amounts. These data show that NK tumor cell cytoplasmic granules contain a potent lytic activity and have biochemical properties that distinguish them from granules present in granulocytes and mast cells.     

Molecular cloning of rat cytolysin

Rat cytolysin is one of the cytolytic factors present in the cytoplasmic granules of rat NK-like cytolytic cells and purified cytolysin exhibits an apparent Mr or 70 kDa. Cytolysis produced by cytolysin occurs in the presence of Ca2+ and is accompanied by the formation of membrane lesions of 160 A diameter. We have isolated a cDNA encoding rat cytolysin from the cDNA library of a rat large granular lymphocyte (LGL) cell line, by hybridization of the rat library with a cDNA probe for mouse perforin. The amino acid sequence deduced from the nucleotide sequence of the isolated cDNA insert indicates that the mature cytolysin protein consist of 534 amino acids with a leader peptide of 20 amino acids. The protein contains two functionally important domains: the first domain is believed to contain the transmembrane channel and the second domain consists of an epidermal growth factor-type "class B" cysteine-rich region. A comparison with mouse perforin indicates that the two genes are very similar (89.9% nucleotide and 84.9% amino acid identity). Northern blot hybridization analysis indicates that cytolysin mRNA is expressed in rat lymphocytes (lymphokine-activated killer cells and LGL cells) and LGL cell lines.     

Cell damage by cytolysin. Spontaneous recovery and reversible inhibition by divalent cations

Cytolysin-induced membrane damage (which requires low Ca2+) has been studied 1) in E by assay of hemolysis, 2) in Lettre cells by measurement of transmembrane potential, intracellular content of K+ and Na+, leakage of phosphoryl[3H]choline or 51Cr from [3H]choline-labeled or 51CrO4(2-)-labeled cells and leakage of lactate dehydrogenase, and 3) in phospholipid bilayers by measurement of electrical conductivity changes. In Lettre cells, damage is restricted and reversible: little lactate dehydrogenase leaks from cells that leak substantial amounts of Na+, K+, and phosphoryl[3H]choline; at low amounts of cytolysin, membrane potential and intracellular content of Na+ and K+ recover within minutes. In E and Lettre cells, membrane damage is inhibited by Zn2+, by high Ca2+, or by low pH. Inhibition is reversible: addition of EGTA to Zn2+-protected E or Lettre cells (incubated in the presence of cytolysin, low Ca2+ and Zn2+) initiates leakage; removal of Zn2+ (and cytolysin and Ca2+) by washing also initiates leakage; such leakage is again sensitive to Zn2+, high Ca2+, or H+. In phospholipid bilayers, channels induced by cytolysin (at low Ca2+) are partially closed by negative voltage; Ca2+, Zn2+, or H+ promote channel closure. Channels are re-opened (only partially in the case of Zn2+) by positive voltage. From all these results it is concluded that the action of cytolysin on membranes is similar to that of other pore-forming agents: damage does not necessarily lead to lysis of nucleated cells, and can be prevented by Ca2+, Zn2+, or H+.     

Physiological and structural properties of colchicine-treated chick skeletal muscle cells grown in tissue culture.

Chick muscle cells grown in tissue-culture medium containing colchicine developed into rounded cells called “myosacs.” Electron micrographs of myosacs were similar to untreated myofibers except that microtubules were absent and the contractile material was disorganized. Most of the electrophysiological characteristics of myosacs were similar to those of untreated myofibers. Thus, both cellular types had similar resting potentials, nonlinear current voltage curves, three types of action potentials (Na⁺, Ca²⁺, and Cl^? spikes), and acetylcholine sensitivity with “hot spots.” Both demonstrated contraction with electrical or chemical (acetylcholine, caffeine) stimuli. The one significant difference was that myosacs, unlike myofibers, were always isopotential throughout their intracellular space.     

Computer analysis of organelle translocation in primary neuronal cultures and continuous cell lines

Organelle translocation in a number of cell types in tissue culture as seen by high-resolution Zeiss-Nomarski differential interference contrast optics was filmed and analyzed by computer. Principal cell types studied included primary chick spinal cord, chick dorsal root ganglion, ratbrain, and various clones of continuous cell lines. Organelle translocations in all cell types studied exhibited frequent, large changes in velocity during any one translocation. The appearance of particles as seen with Nomarski optics was correlated with their fine structures in one dorsal root ganglion neurite by fixing the cell as it was being filmed and obtaining electron micrographs of the region filmed. This revealed the identity of several organelles as well as the presence of abundant neurotubules but no neurofilaments. Primary cell cultures exhibited more high-velocity organelle movements than continuous cell lines. The net progress of an organelle in a given direction was greater in primary neuronal cells than in fibroblasts or continuous cell lines. These findings are correlated with the literature on organelle translocation and axoplasmic transport.     

Co-sedimentation of chondroitin sulfate A glycosaminoglycans and proteoglycans with the cytolytic secretory granules of rat large granular lymphocyte (LGL) tumor cells, and identification of a mRNA in normal and transformed LGL that encodes proteoglycans

Rat large granular lymphocyte (LGL) tumor cell lines were analyzed for the presence of proteoglycans and glycosaminoglycans in their cytolytic secretory granules. When isolated rat LGL tumor cells were incubated in vitro for 1 to 3 hr with [35S]sulfate, and the 35S-labeled macromolecules were purified by density-gradient centrifugation, they filtered on Sepharose CL-4B columns predominantly as approximately 500,000 m.w. macromolecules. After 19 hr of incubation with [35S]sulfate, however, an 85,000 m.w. species predominated. Pulse-chase experiments revealed that the larger macromolecules were proteoglycans that with time were processed to glycosaminoglycan-sized macromolecules. As assessed by their susceptibility to chemical and enzymatic degradation and by high pressure liquid chromatography of the chondroitinase ABC-generated unsaturated disaccharides, the cell-associated rat LGL tumor cell proteoglycans bore almost exclusively chondroitin sulfate A glycosaminoglycans. Northern blot analysis using a gene-specific probe revealed that both normal peripheral blood and transformed rat LGL expressed the same approximately 1.3-kb mRNA that encodes the peptide core of the proteoglycans in the secretory granules of rat and mouse mast cells. In vivo radiolabeling of rat LGL tumor cells and isolation of their intact granules after nitrogen cavitation and density sedimentation established that glycosaminoglycans compartmentalized with cytolytic activity. Thus these negatively charged macromolecules may play a role in the regulation of the packaging and delivery of the cytolysins and basically charged serine proteases that have been identified in the cytolytic secretory granules of LGL.