Implication of the proprotein convertases furin, PC5 and PC7 in the cleavage of surface glycoproteins of Hong Kong, Ebola and respiratory syncytial viruses: a comparative analysis with fluorogenic peptides.

Fluorogenic peptides encompassing the processing sites of envelope glycoproteins of the infectious influenza A Hong Kong virus (HKV), Ebola virus (EBOV) and respiratory syncytial virus (RSV) were tested for cleavage by soluble recombinants of the proprotein convertases furin, PC5 and PC7. Kinetic studies with these intramolecularly quenched fluorogenic peptides revealed selective cleavages at the physiological dibasic sites. The HKV peptide is cleaved by both furin and PC5 with similar efficacy; in comparison, PC7 cleaves this substrate poorly. In contrast with the basic tetrapeptide insertion within the haemagglutinin sequence of HKV, two other dipeptide insertions revealed a poorer cleavage with a similar rank order of potency. These results demonstrate that the N-terminal RERR insertion to the wild-type avian RKKR downward arrow sequence is functionally significant, and suggest that the approx. 5-fold increase in cleavage efficacy contributes to the high infectivity of the H5N1 virus subtype. With regard to RSV peptide processing, PC7 is twice as effective as PC5 and furin. The EBOV peptide was processed with similar efficiency by the three enzymes. Our observations that all of these cleavages can be effectively inhibited by a plant andrographolide derivative at 250 microM or less might aid in the design of potent convertase inhibitors as alternative antiviral therapies.

Post-translational processing of beta-secretase (beta-amyloid-converting enzyme) and its ectodomain shedding. The pro- and transmembrane/cytosolic domains affect its cellular activity and amyloid-beta production.

Processing of the beta-amyloid precursor protein (betaAPP) by beta- and gamma-secretases generates the amyloidogenic peptide Abeta, a major factor in the etiology of Alzheimer's disease. Following the recent identification of the beta-secretase beta-amyloid-converting enzyme (BACE), we herein investigate its zymogen processing, molecular properties, and cellular trafficking. Our data show that among the proprotein convertase family members, furin is the major converting enzyme of pro-BACE into BACE within the trans-Golgi network of HK293 cells. While we demonstrate that the 24-amino acid prosegment is required for the efficient exit of pro-BACE from the endoplasmic reticulum, it may not play a strong inhibitory role since we observe that pro-BACE can produce significant quantities of the Swedish mutant betaAPP(sw) beta-secretase product C99. BACE is palmitoylated at three Cys residues within its transmembrane/cytosolic tail and is sulfated at mature N-glycosylated moieties. Data with three different antibodies show that a small fraction of membrane-bound BACE is shed into the medium and that the extent of ectodomain shedding is palmitoylation-dependent. Overexpression of full-length BACE causes a significant increase in the production of C99 and a decrease in the alpha-secretase product APPsalpha. Although there is little increase in the generation of Abeta by full-length BACE, overexpression of either a soluble form of BACE (equivalent to the shed form) or one lacking the prosegment leads to enhanced Abeta levels. These findings suggest that the shedding of BACE may play a role in the amyloidogenic processing of betaAPP.

Alternative proteolytic processing of mouse mammary tumor virus superantigens.

Mouse mammary tumor viruses express a superantigen essential for their life cycle. It has been proposed that viral superantigens (vSags) require processing by prohormone convertases (PCs) for activity. We now observe, using a panel of mutant forms of potential PC cleavage sites and in vitro cleavage assays, that only the CS1 (position 68 to 71) and CS2 (position 169 to 172) sites are utilized by furin and PC5. Other members of the convertase family that are expressed in lymphocytes are not endowed with this activity. Furthermore, mutant forms of two different viral superantigens, vSag7 and vSag9, which completely abrogated in vitro processing by convertases, were efficient in functional presentation to responsive T-cell hybridomas. This effect was observed in both endogenous presentation and paracrine transfer of the vSag. Processing by convertases thus appears not to be essential for vSag function. Finally, we have identified the purified endosomal protease cathepsin L as another protease that is able to cleave convertase mutant vSag in vitro, yielding fragments similar to those detected in vivo, thus suggesting that proteases other than convertases are involved in the activation of vSags.

Endoproteolytic processing of integrin pro-alpha subunits involves the redundant function of furin and proprotein convertase (PC) 5A, but not paired basic amino acid converting enzyme (PACE) 4, PC5B or PC7.

Several integrin alpha subunits undergo post-translational endoproteolytic processing at pairs of basic amino acids that is mediated by the proprotein convertase furin. Here we ask whether other convertase family members can participate in these processing events. We therefore examined the endoproteolysis rate of the integrin subunits pro-alpha5, alpha6 and alphav by recombinant furin, proprotein convertase (PC)5A, paired basic amino acid converting enzyme (PACE)4, PC1, PC2 and PC7 in vitro and/or ex vivo after overexpression in LoVo cells that were deficient in furin activity. We found that 60-fold more PC1 than furin was needed to produce 50% cleavage of pro-alpha subunit substrates in vitro; the defective pro-alpha chain endoproteolysis in LoVo cells was not rescued by overexpression of PC1 or PC2. No endoproteolysis occurred with PC7 either in vitro or ex vivo, although similar primary sequences of the cleavage site are found in integrins and in proteins efficiently processed by PC7, which suggests that a particular conformation of the cleavage site is required for optimal convertase-substrate interactions. In vitro, 50% cleavage of pro-alpha subunits was obtained with one-third of the amount of PC5A and PACE4 than of furin. In LoVo cells, PC5A remained more active than furin, PACE4 activity was quite low, and PC5B, which differs from PC5A by a C-terminal extension containing a transmembrane domain, was very inefficient in processing integrin alpha-subunit precursors. In conclusion, these results indicate that integrin alpha-subunit endoproteolytic processing involves the redundant function of furin and PC5A and to a smaller extent PACE4, but not of PC1, PC2, PC5B or PC7.

Biosynthesis and enzymatic characterization of human SKI-1/S1P and the processing of its inhibitory prosegment.

Biochemical and enzymatic characterization of the novel human subtilase hSKI-1 was carried out in various cell lines. Within the endoplasmic reticulum of LoVo cells, proSKI-1 is converted to SKI-1 by processing of its prosegment into 26-, 24-, 14-, 10-, and 8-kDa products, some of which remain tightly associated with the enzyme. N-terminal sequencing and mass spectrometric analysis were used to map the cleavage sites of the most abundant fragments, which were confirmed by synthetic peptide processing. To characterize its in vitro enzymatic properties, we generated a secreted form of SKI-1. Our data demonstrate that SKI-1 is a Ca(2+)-dependent proteinase exhibiting optimal cleavage at pH 6.5. We present evidence that SKI-1 processes peptides mimicking the cleavage sites of the SKI-1 prosegment, pro-brain-derived neurotrophic factor, and the sterol regulatory element-binding protein SREBP-2. Among the candidate peptides encompassing sections of the SKI-1 prosegment, the RSLK(137)- and RRLL(186)-containing peptides were best cleaved by this enzyme. Mutagenesis of the latter peptide allowed us to develop an efficiently processed SKI-1 substrate and to assess the importance of several P and P' residues. Finally, we demonstrate that, in vitro, recombinant prosegments of SKI-1 inhibit its activity with apparent inhibitor constants of 100-200 nM.

The prosegments of furin and PC7 as potent inhibitors of proprotein convertases. In vitro and ex vivo assessment of their efficacy and selectivity.

All proprotein convertases (PCs) of the subtilisin/kexin family contain an N-terminal prosegment that is presumed to act both as an intramolecular chaperone and an inhibitor of its parent enzyme. In this work, we examined inhibition by purified, recombinant bacterial prosegments of furin and PC7 on the in vitro processing of either the fluorogenic peptide pERTKR-MCA or the human immunodeficiency virus envelope glycoprotein gp160. These propeptides are potent inhibitors that display measurable selectivity toward specific proprotein convertases. Small, synthetic decapeptides derived from the C termini of the prosegments are also potent inhibitors, albeit less so than the full-length proteins, and the C-terminal P1 arginine is essential for inhibition. The bacterial, recombinant prosegments were also used to generate specific antisera, allowing us to study the intracellular metabolic fate of the prosegments of furin and PC7 expressed via vaccinia virus constructs. These vaccinia virus recombinants, along with transient transfectants of the preprosegments of furin and PC7, efficiently inhibited the ex vivo processing of the neurotrophins nerve growth factor and brain-derived neurotrophic factor. Thus, we have demonstrated for the first time that PC prosegments, expressed ex vivo as independent domains, can act in trans to inhibit precursor maturation by intracellular PCs.

Mammalian subtilisin/kexin isozyme SKI-1: A widely expressed proprotein convertase with a unique cleavage specificity and cellular localization.

Using reverse transcriptase-PCR and degenerate oligonucleotides derived from the active-site residues of subtilisin/kexin-like serine proteinases, we have identified a highly conserved and phylogenetically ancestral human, rat, and mouse type I membrane-bound proteinase called subtilisin/kexin-isozyme-1 (SKI-1). Computer databank searches reveal that human SKI-1 was cloned previously but with no identified function. In situ hybridization demonstrates that SKI-1 mRNA is present in most tissues and cells. Cleavage specificity studies show that SKI-1 generates a 28-kDa product from the 32-kDa brain-derived neurotrophic factor precursor, cleaving at an RGLT downward arrowSL bond. In the endoplasmic reticulum of either LoVo or HK293 cells, proSKI-1 is processed into two membrane-bound forms of SKI-1 (120 and 106 kDa) differing by the nature of their N-glycosylation. Late along the secretory pathway some of the membrane-bound enzyme is shed into the medium as a 98-kDa form. Immunocytochemical analysis of stably transfected HK293 cells shows that SKI-1 is present in the Golgi apparatus and within small punctate structures reminiscent of endosomes. In vitro studies suggest that SKI-1 is a Ca2+-dependent serine proteinase exhibiting a wide pH optimum for cleavage of pro-brain-derived neurotrophic factor.

Residues unique to the pro-hormone convertase PC2 modulate its autoactivation, binding to 7B2 and enzymatic activity.

The prohormone convertase PC2 is one of the major subtilisin/kexin-like enzymes responsible for the formation of small bioactive peptides in neural and endocrine cells. This convertase is unique among the members of the subtilisin/kexin-like mammalian serine proteinase family in that it undergoes zymogen processing of its inactive precursor proPC2 late along the secretory pathway and requires the help of a PC2-specific binding protein known as 7B2. We hypothesized that some of these unique properties of PC2 are dictated by the presence of PC2-specific amino acids, which in the six other known mammalian convertases are otherwise conserved but distinct. Accordingly, six sites were identified within the catalytic segment of PC2. Herein we report on the site-directed mutagenesis of Tyr194 and of the oxyanion hole Asp309 and the consequences of such mutations on the cellular expression and enzyme activity of PC2. The data show that the Y194D mutation markedly increases the ex vivo ability of PC2 to process proopiomelanocortin (POMC) into beta-endorphin in cells devoid of 7B2, e.g. BSC40 cells. In these cells, expression of native PC2 does not result in the secretion of measurable in vitro activity against a pentapeptide fluorogenic substrate. In contrast, secreted Y194D-PC2 exhibited significant enzymatic activity, even in the absence of 7B2. Based on co-immunoprecipitations and Western blots, binding assays indicate that Tyr194 participates in the interaction of PC2 with 7B2, and that the oxyanion hole Asp309 is critical for the binding of proPC2 with pro7B2.

Alpha1-antitrypsin Portland inhibits processing of precursors mediated by proprotein convertases primarily within the constitutive secretory pathway.

We studied the extent of cellular inhibitory activity of alpha1-antitrypsin Portland (alpha1-PDX), a potent inhibitor of proprotein convertases of the subtilisin/kexin type. We compared the inhibitory effects of alpha1-PDX on the intracellular processing of two model precursors (pro-7B2 and POMC) mediated by six of the seven known mammalian convertases, namely furin, PC1, PC2, PACE4, PC5-A, PC5-B, and PC7. The substrates selected were pro7B2, a precursor cleaved within the trans-Golgi network (TGN), and pro-opiomelanocortin, which is processed in the TGN and secretory granules. Biosynthetic analyses were performed using either vaccinia virus expression in BSC40, GH4C1, and AtT20 cells, or stable transfectants of alpha1-PDX in AtT20 cells. Results revealed that alpha1-PDX inhibits processing of these precursors primarily within the constitutive secretory pathway and that alpha1-PDX is cleaved into a shorter form by some convertases. Evidence is presented demonstrating that in contrast to the full-length alpha1-PDX (64 kDa), the cleaved (56 kDa) secreted product does not significantly inhibit furin activity in vitro. Cellular expression of alpha1-PDX results in modified contents of mature secretory granules with increased levels of partially processed products. Biosynthetic and immunocytochemical analyses of AtT20/alpha1-PDX cells demonstrated that alpha1-PDX is primarily localized within the TGN, and that a small proportion enters secretory granules where it is mostly stored as the cleaved product.

In vitro characterization of the novel proprotein convertase PC7.

Biochemical and enzymatic characterization of the novel proprotein convertase rat PC7 (rPC7) was carried out using vaccinia virus recombinants overexpressed in mammalian BSC40 cells. Pro-PC7 is synthesized as a glycosylated zymogen (101 kDa) and processed into mature rPC7 (89 kDa) in the endoplasmic reticulum. No endogenously produced soluble forms of this membrane-anchored protein were detected. A deletion mutant (65 kDa), truncated well beyond the expected C-terminal boundary of the P-domain, produced soluble rPC7 in the culture medium. Enzymatic activity assays of rPC7 using fluorogenic peptidyl substrates indicated that the pH optimum, Ca2+ dependence, and cleavage specificity of this enzyme are largely similar to those of furin. However, with some substrates, cleavage specificity more closely resembled that of yeast kexin, suggesting differential processing of proprotein substrates by this novel convertase. We examined the rPC7- and human furin-mediated cleavage of synthetic peptides containing the processing sites of three proteins known to colocalize in situ with rPC7. Whereas both enzymes correctly processed the pro-parathyroid hormone tridecapeptide and the pro-PC4 heptadecapeptide, neither enzyme cleaved a pro-epidermal growth factor hexadecapeptide. Thus, this study establishes that rPC7 is an enzymatically functional subtilisin/kexin-like serine proteinase with a cleavage specificity resembling that of hfurin. In addition, we have demonstrated that rPC7 can correctly process peptide precursors that contain the processing sites of at least two potential physiological substrates.

Histidine-rich human salivary peptides are inhibitors of proprotein convertases furin and PC7 but act as substrates for PC1.

A 32 amino acid peptide called histatin-3 (H3; 22% His) and its N-terminal 24 amino acid fragment histatin-5 (H5, 33% His), are found in human saliva and possess powerful antimicrobial properties. These His-rich peptides have been synthesized by Fmoc-based solid-phase chemistry. Their sequences are: DSHAKRHHGYKRKFHEKHHSHRGYRSNYLYDN (H3) and DSHAKRHHGYKRKFHEKHHSHRGY (H5). In addition, we also prepared two H5 and one H3 mutants. The H5 mutants were: DH5 (all amino acids in D configuration) and H5F (where all His are replaced by Phe at positions 3, 7, 8, 15, 18, 19, 21). The 9-24 segment of H3 with all the His at positions 15,18,19,21 replaced by Tyr was also prepared (delta 1-8 H3Y). The behavior of these five peptides was examined with three proprotein convertases (PC's) which possess cleavage specificity directed towards single and pairs of basic residues. These were: human (h)PC1, an endocrine and neural convertase, hfurin and rat (r)PC7, two widely expressed enzymes. All are serine endoproteases belonging to the kexin/subtilisin family. Our in vitro study revealed that H3 behaves as a substrate for PC1, being cleaved by this endoprotease primarily at a site carboxy terminal to the single Arg25 residue (HRGYR decrease SN). On prolonged incubation some minor cleavage was also observed C-terminal to the first LysArg6 pairs of basic amino acids namely at: HAKR decrease HH, which contains a P4 as well as P'1 and P'2 His residues. The second potential site YKRK12-FH which does not have a P4 basic residues is not cleaved, even upon incubation with excess protease. PC1 only poorly cleaves H5 at the same site mentioned above for H3, i.e., at HAKR decrease HH. As expected, neither the D-amino acid analogue (DH5), nor the Phe and Tyr mutant analogues of the long and short histatins, respectively, are cleaved at all. In contrast to the above findings for hPC1, the convertase hfurin did not cleave any of the five synthetic peptides. Instead, H3 and H5 were found to be moderately potent inhibitors of the furin-mediated cleavage of the pentapeptide pGlu-Arg-Thr-Lys-Arg-MCA fluorogenic substrate. This inhibition was reversible and competitive, with an estimated inhibition constant Ki of 1.98 microM for H3 and 2.98 microM for H5. The other analogs exhibited only a moderate to weak inhibition of furin, suggesting that substitution of all His by aromatic residues (Phe or Tyr) drastically reduces their inhibitory potency. When tested against rPC7, H3 exhibited almost identical inhibition profile with a measured Ki of 2.4 microM. The partial sequence identity of H3 to the inhibitory pro-peptide of furin and PC7 provides a rationale for our observation.

Tissue- and isoform-specific kinetic behavior of the Na,K-ATPase.

The objective of this study has been to delineate the side-specific effects of Na+ and K+ on the transport kinetics of tissue-specific Na/K pumps. Two experimental systems have been used. In one, Na/K pumps of exogenous microsomal membrane sources (rat axolemma, kidney) were delivered by membrane fusion into dog erythrocytes, and in the other, the three isoforms of the catalytic subunit of the rat enzyme were individually transfected into HeLa cells as in previous studies (Jewell, E.A., and Lingrel, J. B (1991) J. Biol. Chem. 266, 16925-16930), with the alpha 2 and alpha 3 isoforms rendered relatively resistant to ouabain by site-directed mutagenesis. Whereas the kidney microsomes comprise the alpha 1 catalytic isoform, the axolemma microsomes were predominantly alpha 3 (approximately 60%) with lesser amounts of alpha 2 (approximately 25%) and alpha 1 (approximately 15%) as measured by the ouabain-sensitive profile of phosphoenzyme as well as by immunoblotting with isoform-specific antibodies using membranes of known specific activity as standards (alpha 1 of kidney, alpha 1 and alpha 2 of muscle). Both systems were analyzed with respect to the effects of varying concentrations of cytoplasmic Na+ and extracellular K+ on pump-mediated 86Rb+(K+) influx. With the individual isoform-transfected HeLa cells and monensin added to vary and control the intracellular Na+ concentration, differences in apparent affinities of the alpha 3 isoform compared with the alpha 1 and alpha 2 isoforms were observed, i.e. a approximately 3-fold higher affinity for extracellular K+ and approximately 4-fold lower affinity for cytoplasmic Na+. Thus, in the presence of 10 mM extracellular Na+, apparent K0.5 values for extracellular K+ activation of K+(Rb+) influxes were 0.22 +/- 0.02 mM for alpha 1, 0.20 +/- 0.02 mM for alpha 2, and 0.09 +/- 0.01 mM for alpha 3. At high intracellular K+ (> or = 100 mM) and saturating extracellular K+ concentrations, apparent K0.5 values for cytoplasmic Na+ activation were 17.6 +/- 1.1 mM for alpha 1, 19.7 +/- 1.0 mM for alpha 2, and 63.5 +/- 9.1 mM for alpha 3. The functional differences observed with the individual isoform-transfected cells were completely consistent with the kinetic differences observed with the axolemma and kidney pumps fused into erythrocytes. Axolemma pumps had a approximately 3-fold lower K0.5 for extracellular K+ and a approximately 2-fold higher K0.5 for cytoplasmic Na+.(ABSTRACT TRUNCATED AT 400 WORDS)

Rat kidney Na-K pumps incorporated into low-K+ sheep red blood cell membranes are stimulated by anti-Lp antibody.

A genetic dimorphism of sheep red blood cells characterized by differences in the intracellular K+ concentration of mature red blood cells (low-K+ or high-K+ cells) reflects differences in their Na-K pumps and is known to be linked to the ML blood group system. We investigated the relationship of Na-K pumps in red blood cells from sheep of the low-K+ phenotype with an antigen, Lp, that is restricted to low-K+ cells. Anti-Lp antibody stimulates the Na-K pumps in these cells presumably by relieving inhibition of the pumps by Lp. The questions addressed were as follows: is Lp a molecular entity distinct from pumps and, if so, can it interact with pumps of exogenous origin? Rat kidney Na-K pumps were incorporated by fusion of microsomes into either low-K+ or high-K+ sheep red blood cells. The activity of the exogenous kidney pumps was distinguished from that of the endogenous red blood cell pumps by the low sensitivity of rodent pumps to ouabain. Anti-Lp stimulated by > 50% rat kidney pumps incorporated into immature low-K+ sheep cells. This indicates that Lp is a distinct molecular entity free to dissociate from endogenous pumps and inhibit exogenous pumps. Anti-Lp did not stimulate kidney pumps incorporated into mature low-K+ cells but did stimulate kidney pumps following in vitro maturation of microsome fused reticulocytes, probably reflecting restriction of lateral movement of pumps and antigens by the cytoskeleton in mature cells.

Delivery of ion pumps from exogenous membrane-rich sources into mammalian red blood cells.

Using polyethylene glycol-mediated fusion of ATP-ase-enriched (native) microsomes with red blood cells, we have delivered sarcoplasmic reticulum (SR) Ca-ATPase and kidney Na,K-ATPase into the mammalian erythrocyte membrane. Experiments involving delivery of the SR Ca-ATPase into human red cells were first carried out to assess the feasibility of the fusion protocol. Whereas there was little detectable 45Ca2+ uptake into control cells in either the absence or presence of extracellular ATP, a marked time-dependent uptake of 45Ca2+ was observed in the presence of ATP in cells fused with SR Ca-ATPase. Comparison of the kinetics of uptake into microsome-fused cells versus native SR vesicles supports the conclusion of true delivery of pumps into the red cell membrane. Thus, the time to reach steady state was more than two orders of magnitude longer in the (large) cells versus the native SR vesicles. Na,K-ATPase from dog and rat kidney microsomes were fused with red cells of humans, sheep, and dogs. Using dog kidney microsomes fused with dog red cells which are practically devoid of Na,K-ATPase, functional incorporation of sodium pumps was evidenced in ouabain-sensitive Rb+ uptake and Na+ efflux energized by intracellular ATP, as well as in ATP-stimulated Na+ influx and Rb+ efflux from inside-out membrane vesicles prepared from the fusion-treated cells. From analysis of the biphasic kinetics of ouabain-sensitive Na+ efflux under conditions of limited intracellular Na+ concentration, it is concluded that the kidney pumps are incorporated into a relatively small fraction (approximately 15%) of the red cells. This system provides a uniquely useful system for studying the behavior of native sodium pumps in a compartment (red cell) of small surface/volume ratio. The newly incorporated native kidney pumps, while of the same isoform as the endogenous red cell pump, behave differently from the endogenous red cell sodium pump with respect to their very low "uncoupled" Na+/O flux activity.

The comparative effects of tumor necrosis factor on tumor cells growing anchorage dependently and independently.

Tumor necrosis factor (TNF) is a macrophage-derived cytokine that has been shown to exert differential cytotoxic and/or cytostatic effects on many human and animal tumor cells. In vitro assays of TNF effects have been performed mainly on cultured tumor cells growing as a monolayer. However, tumor cells may respond differently to the effects of growth factors depending on whether they grow in two-dimensional monolayer cultures or in three-dimensional colonies in soft agar. We have tested the effect of TNF on the anchorage-dependent (monolayer) and anchorage-independent (soft agar) growth of five rat, two mouse, and one human tumor cell lines. The results indicate that tumor cells may demonstrate different growth responses in these two culture conditions, and that some tumor cells that are resistant to the cytostatic effect of TNF in monolayer cultures may demonstrate significant sensitivity when growing in soft agar medium. One of the rat tumor cell lines unaffected by TNF in monolayer culture was actually stimulated in their colony growth in soft agar medium. The clonogenic techniques of cultivating human tumor cells in soft agar may be suitable for the screening of TNF-sensitive tumors for therapeutic consideration with this substance.

Inhibition of murine hepatic tumor growth by liposomes containing a lipophilic muramyl dipeptide.

We have investigated the ability of liposomes containing a lipophilic muramyl dipeptide, N-acetylmuramyl-L-alanyl-D-isoglutamine glycerol dipalmitate (MDP-GDP) to activate Kupffer cell tumoricidal activity in situ and to inhibit the growth of experimental hepatic micrometastases of tumor cell line H-59, a liver-homing variant of the Lewis lung carcinoma. Liposomes prepared from distearoylphosphatidylcholine/dimyristoylphosphatidylglycerol (DSPC/DMPG) and containing MDP-GDP (1 mumol and 2 micrograms, respectively) were efficiently taken up by the liver after i.v. administration. A single i.v. injection of DSPC/DMPG liposomes containing MDP-GDP was capable of inducing Kupffer cell tumoricidal activity against H-59 tumor cells as measured in vitro. Control liposomes or 100 micrograms free MDP were ineffective in inducing Kupffer cell tumoricidal activity in situ. Two treatment regimens were evaluated in vivo: firstly, C57BL/6 mice were injected with tumor cell line H-59 and subsequently treated with multiple injections of liposomal MDP-GDP. Secondly, treatment with liposomal MDP-GDP was initiated prior to tumor cell injection and continued after tumor cell injection. The ability of liposomes containing MDP-GDP to reduce the number of hepatic micrometastases using the first protocol was related to the tumor cell inoculum, significant inhibition being observed at lower liver tumor burdens (less than 25 tumor nodules). Pretreatment of the mice prior to tumor cell challenge followed by treatment afterwards greatly enhanced the efficacy of liposomal MDP-GDP and brought about a highly significant inhibition of the growth of experimental metastases even at high liver tumor burdens (greater than 50 nodules).

Detection of DNA damage and repair by alkaline elution using human lymphocytes.

The repair of DNA alkylation damage in human cells is poorly understood. We have adapted the alkaline elution technique for use with human peripheral blood lymphocytes in culture. We have also established conditions necessary for short-term culture of human lymphocytes. Lymphocyte growth which can be maintained for up to 30 days is dependent upon irradiated TK6 feeder cells and T-cell growth factor (crude TCGF). The amount of damage induced by a given concentration of methyl methane-sulfonate (MMS) is dependent upon cell number per ml of growth medium. The DNA damage measured, in lymphocytes, by alkaline elution is a composite of single strand breaks and alkali-labile lesions. Repair of this damage after appropriate recovery periods is also detectable. The irradiated feeder TK6 cells do not contribute to the number of strand breaks detected or the amount of recovery after treatment. This method offers a quick and reproducible means of detecting DNA damage and repair in human T-lymphocytes.

Deficient DNA repair in amyotrophic lateral sclerosis cells.

We studied survival and DNA repair capacity in cultured sporadic ALS and control skin fibroblasts after treatment with DNA damaging agents producing different types of lesions. Mean survival in ALS and control fibroblasts was similar after exposure to ultraviolet (UV) light, x-rays and mitomycin C (MMC). Both mean survival and mean unscheduled (repair) DNA synthesis (UDS) were significantly reduced in ALS fibroblasts following treatment with the alkylating agent methyl methane sulfonate (MMS). These data suggest that ALS cells are relatively deficient in the repair of alkylation damage, possibly of apurinic/apyrimidinic sites, and that they are not unduly sensitive to DNA damage produced by UV light, x-rays and MMC. Normal survival and UDS seen in some patients' cells after MMS treatment indicate a spectrum of repair efficiency, and suggest heterogeneity of the biochemical defect in ALS.

Alzheimer's disease cells exhibit defective repair of alkylating agent-induced DNA damage.

The most common cause of senile and presenile dementia is Alzheimer's disease, a disorder with an undetermined cause. A number of studies have indicated that neurons from patients with Alzheimer's disease have decreased ribonucleic acid levels and reduced protein synthesis. Recent studies using lymphoblasts from patients with Alzheimer's disease have indicated that these cells are more sensitive to deoxyribonucleic acid (DNA)-alkylating agents. We have used cell survival, unscheduled DNA synthesis, and alkaline elution to assess the capacity for DNA repair in skin fibroblasts from normal control subjects, control subjects with central nervous system disease, and patients with Alzheimer's disease. Our results indicate that the Alzheimer's disease cells, unlike normal cells, fail to repair methylmethane sulfonate-induced DNA damage. Both normal and Alzheimer's disease cells are able to ameliorate the effects of ultraviolet light. These results indicate that a specific pathway for DNA repair is affected in Alzheimer's disease. The repair defect may be related to the cause of the disease or may be the cause of the disease.