The immunological activity of plant toxins used in the preparation of immunotoxins--II. The immunodepressive activity of gelonin

The immunological activity of Gelonin, a 30,000 dalton plant protein possessing close similarity to Ricin chain A as a protein synthesis inhibitor which may be of interest for the preparation of antibody-toxin conjugates, was studied in mice. At in vitro concentrations not affecting baseline radioactivity uptake, this substance reduced mitogen responses with the following order of sensitivity PHA less than ConA less than LPS. In microgram/ml concentrations it also markedly reduced macrophage-dependent cytotoxicity while not affecting NK activity. Macrophagic (but not NK) cytotoxicity and mitogen responses were similarly depressed after in vivo treatment. When given before (but not after) stimulus, Gelonin also reduced the primary responses to a T-dependent and, although to a lower degree, to a T-independent antigen, and decreased resistance to allogeneic tumor grafts and L. monocytogenes challenges. The immunopharmacological activity of this and similar substances should be considered in the design of antibody-toxin conjugates and in the evaluation of their therapeutic activity.

A metalloproteinase associated with gelonin, a "ribosome inactivating protein"

Gelonin, a single-chain protein which inactivates eukaryotic ribosomes, becomes split into peptides when incubated with SDS. During the chromatographic purification of gelonin on carboxymethylcellulose three overlapping peaks emerge in the gelonin elution region, containing three proteins with small differences in apparent molecular weight (31,500, 30,000 and 29,200). All three proteins are endowed with inhibitory activity on protein synthesis and with proteinase activity, although with different specific activities, and all three give rise to the same peptides upon incubation with SDS, suggesting that they are isoforms of gelonin. The gelonin-associated proteinase acts only on gelonin, while it is inactive on the most common substrates for endoproteinases. The proteolytic activity is not inhibited by inhibitors of serine- or SH-proteinases, while it is completely abolished by chelating agents. Divalent cations restore the proteolytic activity inhibited by EDTA. The stability of the proteinase activity on exposure of gelonin to extreme values of pH or to prolonged incubation has been investigated. The inhibitory activity on protein synthesis and the proteinase activity are differently affected by these treatments.

Dodecandrin, a new ribosome-inhibiting protein from Phytolacca dodecandra

Dodecandrin, a newly discovered ribosome-inhibiting protein, has been isolated and purified from the leaves of the African endod plant, Phytolacca dodecandra. Dodecandrin has a molecular weight of approx. 29 000. It cross-reacts with antiserum prepared against pokeweed antiviral protein from Phytolacca americana and exhibits similar requirements for antiribosomal activity. It is more basic than pokeweed antiviral protein, and comparison of the first 30 amino-terminal residues of the two proteins reveals 83% homology. This level of homology is greater than that between pokeweed antiviral protein and pokeweed antiviral protein S, another antiviral protein found in P. americana. Such conservatism in sequence, coupled with the high efficiency of the proteins in deactivating ribosomes and with their abundance in plant tissue, suggests that they serve an important function in the life of the plant, probably as a defense against infection.

Characterization of translational inhibitors from Phytolacca americana. Amino-terminal sequence determination and antibody-inhibitor conjugates

Two translational inhibitors (pokeweed antiviral protein and pokeweed antiviral protein II) isolated from the leaves of the pokeweed plant, Phytolacca americana, were characterized as to their behavior during reverse-phase HPLC and their amino-terminal sequences. Alignment of the sequences demonstrated that a substantial degree of homology was present (10 of 29 identical residues). Pokeweed antiviral protein was shown by reverse-phase chromatography to be composed of at least two components, pokeweed antiviral proteina and pokeweed antiviral proteinb, which comigrated on sodium dodecyl sulfate polyacrylamide gel electrophoresis, shared identical N-terminal amino-acid sequences through residue 31, and had similar specific activities in a cell-free translation inhibition assay. Pokeweed antiviral protein II was covalently coupled to a monoclonal antibody that recognizes the transferrin receptor (anti-transferrin receptor). The disulfide-linked conjugate inhibited protein synthesis in the human breast tumor cell line MCF-7, whereas anti-transferrin receptor, pokeweed antiviral protein II, or an immunotoxin composed of an irrelevant antiserum and pokeweed antiviral protein II, were nontoxic. The inhibitory dose 50% of anti-transferrin receptor-pokeweed antiviral protein II for MCF-7 cells was 0.7 nM, whereas the corresponding ricin A chain conjugate (anti-transferrin receptor-ricin A chain) was more potent with a inhibitory dose 50% of 0.1 nM. Pokeweed antiviral protein II can be added to the growing list of translation inhibitors that are effective as components of immunotoxins in vitro. Additional studies will be needed to determine whether pokeweed antiviral protein II immunotoxins provide advantageous properties for in vivo applications.

Cytoxicity of erythrocyte ghosts loaded with ribosome-inactivating proteins following fusion with CHO cells

The ribosome-inactivating proteins gelonin, Momordica charantia inhibitor, pokeweed antiviral protein, and one from Saponaria officinalis were enclosed in human erythrocyte ghosts. The proteins once trapped in ghosts and fused with CHO cells inhibited colony formation at concentrations of approximately 1 ng/ml (3 X 10(-11) M), whereas the free proteins only had an effect at concentrations of greater than 1 microgram/ml.

Prevention of growth of leukemia cells in mice by monoclonal antibodies directed against Thy 1.1 antigen disulfide linked to two ribosomal inhibitors:pokeweed antiviral protein or ricin A chain

Pokeweed antiviral protein (PAP) and ricin A chain are potent inhibitors of protein synthesis that inactivate eukaryotic 60S ribosomal subunits. Immunotoxins were prepared by linking monoclonal anti-Thy 1.1 antibodies to PAP and ricin A chain through a disulfide bond. Both the conjugates were shown earlier to specifically inhibit protein synthesis of Thy 1.1-positive target leukemic cells (AKR SL3). In the present study, the efficacy of the immunotoxins to prevent the growth of AKR SL3 cell-induced tumor was checked in vivo in a model system. Injection of AKR SL3 cells s.c. into AKR/Cum (Thy 1.2-positive) mice developed into a solid tumor which was fatal. Administration of 31-E6:PAP and 31-E6:ricin A chain suppressed tumor growth. Suppression was specific, as similar treatment could not prevent the growth of a nontarget Thy 1.2-positive leukemia cell line (AKR SL1) derived from a congenic mouse. Unconjugated anti-Thy 1.1 immunoglobulin antibodies also showed significant tumor protection; however, administration of F(ab')2 fragment could not prevent the tumor growth. Injection of F(ab')2:PAP efficiently protected mice from AKR SL3-induced tumor. All the conjugate-treated mice showed antibody response against the toxin polypeptide. Anti-toxin antibody response was found as early as 26 days after the initiation of therapy and lasted as long as 179 days of observation. Further studies indicate that the presence of anti-toxin antibodies blocked completely the inhibitory ability of the respective immunotoxin in vitro. Anti-ricin antibodies neutralized the activity of 31-E6:ricin A chain conjugate but not OX-7:PAP immunotoxin, and similarly, anti-PAP antibodies inhibited the activity of the latter and not the activity of 31-E6:ricin A chain conjugate. These observations indicate that the use of alternate immunotoxins having an immunologically distinct toxin polypeptide may be necessary for tumor therapy during relapse, as exposure to the conjugates results in the formation of specific neutralizing anti-toxin antibodies. The anti-toxin antibodies did not prevent the binding of immunotoxin to target cells. Nevertheless, preincubation of conjugate with anti-toxin antibodies specifically blocked the respective conjugate-induced inhibition of polyuridylic acid translation in a cell-free assay system.

Inhibition of human acute lymphoblastic leukemia cells by immunotoxins: potentiation by chloroquine

Immunotoxins containing pokeweed antiviral protein and monoclonal antibodies against human T cells or human transferrin receptor efficiently killed acute lymphoblastic leukemia cells. Chloroquine specifically enhanced the rate of protein synthesis inhibition by immunotoxin. Depending on its concentration, chloroquine (10 to 100 micromolar) reduced by up to 65-fold the amount of immunotoxin required to inhibit protein synthesis in the target cells 50 percent.

Comparison of the selective cytotoxic effects of immunotoxins containing ricin A chain or pokeweed antiviral protein and anti-Thy 1.1 monoclonal antibodies

Ricin A chain and pokeweed antiviral protein (PAP), two enzymes that inhibit the action of eukaryotic ribosomes, were coupled by cleavable, N-succinimidyl-3-(2-pyridyldithio)propionate, and noncleavable m-maleimidobenzoyl-N-hydroxysuccinimide ester, cross-linking reagents to monoclonal antibodies directed against Thy 1.1 antigen. Leukemia cells that contained Thy 1.1 antigen were selectively killed compared to Thy 1.2-containing cells. The composition of the conjugates was determined by radioimmunoassay, and most of the immunotoxins contained about equal molar quantities of antibody and ribosomal inhibitor. Ricin A chain linked to antibody by a noncleavable m-maleimidobenzoyl-N-hydroxysuccinimide ester cross-link was not cytotoxic, but PAP coupled to the same antibody was. Both immunotoxins linked by a cleavable disulfide bond were cytotoxic. Disulfide-linked F(ab')2-PAP was cytotoxic, but it was about 45 times less efficient than disulfide-linked IgG-PAP. There was only a 3.2-fold difference in their ability to inhibit ribosomes in vitro. The relative difference between in vitro action and cytotoxicity could be accounted for by differences in the affinity of the immunotoxins to the cell surface. Neither PAP or ricin A chain disulfide linked to a monoclonal antibody against Mr 15,000 envelope protein, a murine leukemia virus coat protein, were not cytotoxic, although both conjugates bound to the cell surface. Because of its stability, ease of purification, and lack of an analogue of ricin B chain, PAP may be more useful than ricin A for immunotoxin synthesis.

Properties of immunotoxins against a glycolipid antigen associated with Burkitt's lymphoma

A monoclonal immunoglobulin M (IgM) antibody (38-13) which recognizes Burkitt's lymphoma (BL) cells, by reacting with the neutral glycolipid Gal alpha 1 leads to 4-Gal beta 1 leads to 4-Glc beta 1 leads to 1-ceramide, was recently characterized. This monoclonal IgM was coupled to either ricin A chain or gelonin. The two different immunotoxins obtained retained the apparent immunological specificity of 38-13 IgM, as shown by flow cytofluorometry analysis and complement-dependent cytotoxicity test. The BL Ramos cells and the apparently irrelevant Epstein-Barr virus-containing lymphoblastoid Priess cells were used as targets in in vitro assays of the cytotoxic properties of the two immunotoxins by measuring the inhibition of protein synthesis. Isolated ricin A chain, gelonin, and 38-13 IgM exhibited very low intrinsic cytotoxicity on both target cells. 38-13 ricin A chain and 38-13 gelonin conjugates exerted toxic effects on both target cells which were about 6000-fold and 3000-fold higher than uncoupled ricin A chain and gelonin, respectively. The toxicity of these conjugates almost reached that of intact ricin. On Ramos BL cells, the kinetics of action of the 38-13 ricin A chain conjugate was almost as fast as that of intact ricin, because 50% protein synthesis inhibition was reached after 3 hr. In contrast, the kinetics of action in the non-BL Priess was much slower (50% protein synthesis inhibition after 10 hr). An obviously irrelevant immunotoxin (anti-trinitrophenol IgM-ricin A chain) had no significant cytotoxic effect on BL Ramos and non-BL Priess cells. An excess of D-galactose was shown previously to inhibit the 38-13 IgM from binding to the reactive glycolipid antigen bearing a terminal galactose. An excess of D-galactose (0.1 M) inhibited the cytotoxic effect of the two 38-13 immunotoxins, whereas it did not prevent the cytotoxic effect of the anti-trinitrophenol immunotoxin on the same trinitrophenol labeled target cells. These data suggest that the cytotoxic effect observed with 38-13 immunotoxins on non-BL Priess cells was mediated through their binding to a very low number of antigenic sites undetectable by conventional immunological methods. The main characteristics of 38-13 immunotoxins appear to be their fast kinetics of action and the very low number of antigenic sites required for the expression of their toxic effects. These properties could be related to the glycolipid nature of the reacting antigen. Such glycolipid antigens would represent valuable targets for therapeutic use of immunotoxins.

Selective killing of target cells by antibody-ricin A chain or antibody-gelonin hybrid molecules: comparison of cytotoxic potency and use in immunoselection procedures

Ricin A chain and gelonin, two plant proteins that can powerfully reduce the protein synthetic capacity of ribosome preparations, were covalently coupled to a monoclonal anti-Thy-1.2 antibody. Two conjugates were prepared by using N-succinimidyl-3-2(-pyridyldithio)propionate, which generates a disulfide linkage between the component molecules. Both conjugates specifically killed Thy-1.2 antigen-bearing EL-4 cells, but had no effect on Thy-1.2- BW5147 cells. The cytotoxic potency of both reagents was determined by comparing the cloning efficiency of E1-4 target cells after treatment with the conjugate. The frequency of cells surviving treatment with 45 micrograms/10(6) cells of the gelonin conjugate was 1/72, whereas this frequency was 1/836 after exposure to 7 micrograms of the Ricin A chain conjugate. Both reagents could be successfully used to select Thy-1.2- cells from cell mixtures consisting of Thy-1.2+ and Thy-1.2- cells.

Seasonal variations in different forms of pokeweed antiviral protein, a potent inactivator of ribosomes

Pokeweed antiviral proteins enzymatically inactivate the 60 S subunit of eucaryotic ribosomes in cell-free preparations. Three different species of the enzyme can be isolated from spring leaves, summer leaves, and seeds of pokeweed. Sequence analyses of the NH2-terminal residues show that pokeweed antiviral protein, isolated from spring leaves and seeds, are homologous and differ in 11 of the 28 residues compared. Ricin contains a polypeptide (ricin A chain) that has functional similarities to pokeweed antiviral protein, yet the sequences of the pokeweed proteins show little similarity with ricin A chain. Ricin B chain is responsible for helping ricin A chain across the plasma membrane; since pokeweed antiviral has no counterpart to ricin B chain, it is not nearly as cytotoxic as ricin. However, when pokeweed antiviral protein was covalently coupled to ricin B chain, a cytotoxic species was formed. Pokeweed antiviral protein fails to interact noncovalently with the ricin B chain to produce a cytotoxic species equivalent in function to ricin.

The protein synthesis inhibitors from wheat, barley, and rye have identical antigenic determinants

We have purified the protein synthesis inhibitors from wheat (tritin) and investigated their antigenic relationship to inhibitors from other grains and more distantly related plants. Three forms of tritin (tritin 1, 2, and 3) indistinguishable with regards to their molecular weight and enzymatic properties were found. Antiserum against the most abundant tritin, tritin 2, cross reacted with tritin 1, tritin 3, and with the translation inhibitors from barley and rye, but not with other plant-derived translational inhibitors. The results indicate that only closely related plants contain antigenically similar protein synthesis inhibitors.

Dianthin 30 and 32 from Dianthus caryophyllus: two inhibitors of plant protein synthesis and their tissue distribution

The ability of dianthin 30 and 32 to inhibit translation in reticulocyte lysates and wheat germ extracts has been studied. The dianthins, like the A chains of the toxins abrin and ricin, inhibited protein synthesis in reticulocyte lysates by inactivating the 60S ribosomal subunit. They also inhibited, at concentrations of 10 ng/ml, a protein-synthesizing system from wheat germ and inactivated isolated wheat germ ribosomes. The concentration of the dianthins in different tissues of the plant was determined by rocket immunoelectrophoresis and by the dianthin's ability to inhibit protein synthesis. Dianthin 32 was found only in the leaves and in growing shoots, while dianthin 30 was present throughout the plant. In the older parts of the plant, the dianthins constituted between 1 and 3% of the total extractable protein whereas much less was found in the younger parts.

Cytotoxicity acquired by ribosome-inactivating proteins carried by reconstituted Sendai virus envelopes

Association of the ribosome-inactivating proteins (RIPs): pokeweed antiviral protein (PAP), gelonin, Momordica charantia inhibitor (MCI), with reconstituted Sendai virus envelopes (RSVE) was obtained without detectable loss of activities either of RIPs or of viral envelope glycoproteins. RIPs are inactive towards intact cells, but, once encapsulated in RSVE, they become cytotoxic. The concentration of RSVE-associated PAP, which causes 50% inhibition of protein synthesis by Friend erythroleukemic cells, is 0.5 ng/ml. Substances capable to inhibit the viral activities block the acquired cytotoxicity of RIPs associated to RSVE.

Requirements for antiribosomal activity of pokeweed antiviral protein

It has been known for some time that pokeweed antiviral protein acts by enzymatically inhibiting protein synthesis on eucaryotic ribosome systems. The site of this action is known to be the ribosome itself. In this paper we show that the pokeweed antiviral protein reaction against ribosomes is a strong function of salt concentrations, where 160 mM K+ and 3 mM Mg2+ retards the reaction, while 20 mM K+ and 2 mM Mg2+ allows maximum reaction rate. It is also shown, however, that an unidentified protein in the postribosomal supernatant solution, together with ATP, allows the ribosome to be attacked even in the presence of high salt. Kinetic analysis of the antiviral protein reaction has been carried out under both sets of conditions, and reveals that the turnover number for the enzyme is about 300-400 mol/mol per min. in each case. The Km for ribosomes is 1 microM in the presence of low salt and 0.2 microM at higher salt in the presence of postribosomal supernatant factors plus ATP. The antiviral protein reaction is also shown to be pH dependent and is controlled by a residue with pKa value of approx. 7.0, apparently a histidine. Stoichiometric reaction of the enzyme with iodoacetamide results in a significant loss of antiribosomal activity.

Inhibition of herpes simplex virus DNA synthesis by pokeweed antiviral protein

Pokeweed antiviral protein at a concentration of 3 microM inhibited both the synthesis and release of infectious herpes simplex virus type 1 in cell culture by 90 and 99%, respectively. Addition of pokeweed antiviral protein to Vero cell monolayers before virus infection was 10 to 15% more effective in reducing virus yields than was the simultaneous addition of the antiviral protein with virus inoculum. Viral DNA synthesis was inhibited by 90% in cells which had been exposed to the antiviral protein, whereas cellular DNA synthesis was unaffected. No significant inhibition in the synthesis of the majority of viral infected-cell polypeptides was observed early postinfection (7 h), with the exception of infected cell polypeptides 4 and 41, whose syntheses were reduced by 38 and 25%, respectively. At 9 to 21 h postinfection, however, the synthesis of individual infected cell polypeptides was reduced by 48 to greater than 99%.

The immunomodulatory activity of the plant proteins Momordica charantia inhibitor and pokeweed antiviral protein

The immunological activity of Momordica Charantia inhibitor (MCI) and of Pokeweed antiviral protein (PAP-S), 30,000 daltons plant proteins possessing close similarity to Ricin A chain as inhibitor of protein synthesis, was investigated in mice. In vivo, single nontoxic injections of microgram amount of these substances delayed H2-incompatible skin allograft rejection, splenocyte responsiveness to ConA and PHA, but not to LPS, and abrogated the PFC response to a T-dependent (SRBC) antigen while totally sparing that to a T-independent (S III) stimulus. Injection of these substances could also reduce NK cell activity while increasing macrophage-mediated spontaneous cytotoxicity. In vitro, MCI and PAP-S at non-cytotoxic concentrations inhibited lymphoid cell responsiveness to PHA and ConA, but not to LPS, and markedly enhanced macrophage-dependent cytotoxicity.

Sugar-specific endocytosis of glycoproteins by Lewis lung carcinoma cells

Lewis lung carcinoma cells from tumors, metastasis nodules, or from culture bind fluorescent derivatives of neoglycoproteins containing alpha-D-glucose residues: This binding is competitively inhibited by neoglycoproteins containing alpha-D-glucose, by mannan, and by several other neoglycoproteins. Cell binding and uptake of the fluorescent derivatives of the neoglycoproteins was quantified by lysing the cells with an alkylpolyol (MAC 19 or MAC 18) and measuring the fluorescence intensity of the supernatant. The amount of cell-associated neoglycoprotein was higher at 37 degrees C than at 4 degrees C with LLC from tumor. The binding and uptake were inhibited by glycoconjugates containing alpha-D-glucose. These results suggest the presence of sugar specific receptors in Lewis lung carcinoma cells which are involved in a sugar-specific binding and endocytosis phenomenon. The implication of the existence of a carbohydrate-binding protein on the surface of Lewis lung carcinoma cells are discussed with regard to the in vivo behaviour of these cells, especially in relation to their metastatic properties and to the possibility of using neoglycoproteins as specific carriers of cytotoxic drugs. Hybrid molecules of gelonin and neoglycoprotein containing alpha-D-glucose were used as targetted toxin: The targetted toxin was found to bind to and to enter the intact cells and was 100 times more toxic than free drug.

Effect of ribosome-inactivating proteins on virus-infected cells. Inhibition of virus multiplication and of protein synthesis

HEp-2 cells were infected with herpes simplex virus-1 (HSV-1) or with polio-virus I in the presence of plant proteins which inactivate ribosomes in cell-free systems, while exerting scarce effect on whole cells. Ribosome-inactivating proteins used were gelonin, from seeds of Gelonium multiflorum, an inhibitor from the seeds of Momordica charantia, dianthin 32, from the leaves of Dianthus caryophyllus (carnation), and PAP-S, from the seeds of Phytolacca americana (pokeweed). All proteins tested had the following effects: 1. They reduced viral yield; 2. They decreased HSV-1 plaque-forming efficiency; 3. They inhibited protein synthesis more in infected than in uninfected cells. These results strongly suggest that ribosome-inactivating proteins impair viral replication by inhibiting protein synthesis in virus-infected cells, in which presumably they enter more easily than in uninfected cells.

Properties of the ribosome-inactivating proteins gelonin, Momordica charantia inhibitor, and dianthins

The amino acid and sugar compositions of four ribosome-inactivating proteins (gelonin, Momordica charantia inhibitor, dianthin 30 and dianthin 32) were determined. The proteins are all basic glycoproteins (pI greater than 8) containing mannose (more abundant in gelonin), glucose, xylose, fucose (absent from gelonin) and glucosamine. The ribosome-inactivating properties of the proteins examined are not modified by pretreatment with N-ethylmaleimide. Precipitating and inactivating antibodies can be raised against ribosome-inactivating proteins; a weak cross-reaction was observed only between dianthin 30 and dianthin 32.

Chemical modifications of pokeweed antiviral protein: effects upon ribosome inactivation, antiviral activity and cytotoxicity

Pokeweed antiviral protein (PAP) is a protein known to inactivate eukaryotic ribosomes by an unknown enzymatic action and inhibit the production of mammalian viruses in tissue culture. This protein was subjected to a variety of chemical modifications to determine their effects upon ribosomal inactivation, antiviral action, and cytotoxicity. It was found that modifications of a number of different amino acid residues had similar effects upon all 3 activities. Also the inactivation of PAP with diethylpyrocarbonate was not due to its reaction with a histidine residue but to a modification of an unidentified amino acid residue.

Liposome-mediated delivery of ribosome inactivating proteins to cells in vitro

This study describes the liposome-mediated delivery of toxins to a variety of cells in vitro. Gelonin, a potent inhibitor of protein synthesis from Gelonium multiflorum, was delivered to the cytoplasm of TLX5 lymphoma cells most effectively by phosphatidylserine vesicles. These liposomes were also capable in inhibiting protein synthesis in XC (transformed rat fibroblasts) and phytohaemagglutinin-stimulated CBA mouse lymphocytes. Phosphatidylcholine liposomes had no capacity to deliver their contents to the cytoplasm, but the addition of cholesterol to the vesicle membrane resulted in an increased capacity. Delivery events were enhanced further by the addition of mixed bovine brain gangliosides to the membrane in the ratio 5:5:1 phosphatidylcholine/ cholesterol/gangliosides. The addition of cholesterol to phosphatidylserine vesicles failed to increase the inhibitory effects of the gelonin liposomes. The A chain of diphtheria toxin encapsulated in phosphatidylserine liposomes had no inhibitory effect on the level of protein synthesis in TLX5 or Daudi cells.

Purification and partial characterization of another form of the antiviral protein from the seeds of Phytolacca americana L. (pokeweed)

1. The pokeweed antiviral protein, previously identified in two forms (PAP and PAP II) in the leaves of Phytolacca americana (pokeweed) [Obrig. Irvin & Hardesty (1973) Arch. Biochem. Biophys. 155, 278-289; Irvin, Kelly & Robertus (1980) Arch. Biochem. Biophys. 200, 418-425] is a protein that prevents replication of several viruses and inactivates ribosomes, thus inhibiting protein synthesis. 2. PAP is present in several forms in the seeds of pokeweed. One of them, which we propose to call 'pokeweed antiviral protein from seeds' (PAP-S) was purified in high yield (180 mg per 100 g of seeds) by chromatography on CM-cellulose, has mol.wt. 30 000, and is similar to, but not identical with. PAP and PAP II. 3. PAP-S inhibits protein synthesis in a rabbit reticulocyte lysate with an ID50 (concentration giving 50% inhibition) of 1.1 ng/ml (3.6 x 10(-11) M), but has much less effect on protein synthesis by whole cells, with an ID50 of 1 mg/ml (3.3 x 10(-5) M), and inhibits replication of herpes simplex virus type 1.