Granulocyte alkaline phosphatase. Studies of purified enzymes from normal subjects and patients with polycythemia vera.

To characterize the biological changes which result in increased granulocyte alkaline p-nitrophenyl phosphatase activity in patients with polycythemia vera, the enzyme was purified from granule fractions of sucrose homogenates made from dextran-sedimented leukocytes of normal subjects and patients with polycythemia vera. Polycythemic blood yielded 3-10 times as much granulocyte alkaline phosphatase per 10(9) leukocytes as did normal blood. Sodium dodecyl sulfate extracts of granules were purified by DEAE-cellulose chromatography and sucrose gradient centrifugation to apparent homogeneity as judged by polycarylamide disk gel electrophoresis. Granulocyte alkaline phosphatase from normal subjects was purified 6910-fold with a 60% yield and a specific activity of 47 U/mg. Granulocyte alkaline phosphatase from polycythemic patients was purified 1.166-fold with a 50% yield and a specific activity of 70 U/mg. The two enzymes did not differ in molecular weight; both appeared to be about 160,000 daltons by sucrose gradient centrifugation. Both appeared to be zinc metalloenzymes, in that they were specifically inhibited by o-phenanthroline. Their elution requirements when adsorbed to DEAE-cellulose suggested they were lipoproteins although the content of phosphorus was below the threshold of detection. The identity of the two enzymes was suggested by immunological studies in which antibody prepared against purified polycythemia vera enzyme gave a precipitation reaction of identity with another polycythemia vera enzyme and two pools of normal enzyme. It is possible to account for the difference in alkaline phosphatase activity between the granulocytes of patients with polycythemia vera and normal subjects by differences in the quantity of enzyme synthesized.

Association of poly(adenosine diphosphoribose) synthesis with DNA damage and repair in normal human lymphocytes.

A permeable cell technique was used to measure the alterations in synthesis of DNA and poly-(adenosine diphosphoribose) in normal human lymphocytes after treatment of the cells with different types of DNA-damaging agents. The lymphocytes showed an abrupt increase in the unscheduled synthesis of DNA and poly(adenosine diphosphoribose) in response to ultraviolet (UV) irradiation. The increases were apparent within 1 h and reached a maximum between 2 and 4 h after irradiation. The magnitude of the increases in DNA and poly(adenosine diphosphoribose) synthesis was dependent upon the UV dose. Alkaline CsCl gradient studies, with bromodeoxyuridine triphosphate density labeling of DNA, demonstrated that the unscheduled DNA synthesis, which occurred in response to UV irradiation, was actually a result of the repair mode of DNA synthesis. Similar increases in DNA synthesis, and poly(adenosine diphosphoribose) synthesis occurred when lymphocytes were treated with several other DNA-damaging agents, including bleomycin, N-methyl-N'-nitro-N-nitrosoguanidine or N-acetoxyacetyl aminofluorene. Treatment of lymphocytes with DNase, under conditions which allowed degradation of cellular DNA, also resulted in increased synthesis of poly(adenosine diphosphoribose). Cycloheximide did not inhibit the increase in synthesis of DNA or poly(adenosine diphosphoribose) that occurred in response to treatment with the DNA-damaging agents.

Modulation of nicotinamide adenine dinucleotide and poly(adenosine diphosphoribose) metabolism by the synthetic "C" nucleoside analogs, tiazofurin and selenazofurin. A new strategy for cancer chemotherapy.

Tiazofurin (2-beta-D-ribofuranosylthiazole-4-carboxamide) and selenazofurin (2-beta-D-ribofuranosylselenazole-4-carboxamide) are synthetic "C" nucleosides whose antineoplastic activity depends on their conversion to tiazofurin-adenine dinucleotide and selenazofurin-adenine dinucleotide which are analogs of NAD. The present study was conducted to determine whether these nucleoside analogs and their dinucleotide derivatives interfere with NAD metabolism and in particular with the NAD-dependent enzyme, poly(ADP-ribose) polymerase. Incubation of L1210 cells with 10 microM tiazofurin or selenazofurin resulted in inhibition of cell growth, reduction of cellular NAD content, and interference with NAD synthesis. Using [14C]nicotinamide to study the uptake of nicotinamide and its conversion to NAD, we showed that the analogs interfere with NAD synthesis, apparently by blocking formation of nicotinamide mononucleotide. The analogs also serve as weak inhibitors of poly(ADP-ribose) polymerase, which is an NAD-utilizing, chromatin-bound enzyme, whose function is required for normal DNA repair processes. Continuous incubation of L1210 cells in tiazofurin or selenazofurin resulted in progressive and synergistic potentiation of the cytotoxic effects of DNA-damaging agents, such as 1,3-bis(2-chloroethyl)-1-nitrosourea or N-methyl-N'-nitro-N-nitrosoguanidine. These studies provide a basis for designing chemotherapy combinations in which tiazofurin or selenazofurin are used to modulate NAD and poly(ADP-ribose) metabolism to synergistically potentiate the effects of DNA strand-disrupting agents.

Synthesis of DNA and poly(adenosine diphosphate ribose) in normal and chronic lymphocytic leukemia lymphocytes.

Peripheral blood lymphocytes were isolated from 9 patients with chronic lymphocytic leukemia (CLL) and 12 normal control donors. The cells were assayed for synthesis of DNA and poly-(adenosine diphosphate ribose) (poly[ADPR]) immediately after isolation and on successive days following their treatment with phytohemagglutinin (PHA). Two different techniques were used to measure DNA synthesis. In the standard technique, DNA synthesis was measured by incubating intact cells with [(3)H]deoxythymidine. In the new technique, the lymphocytes were first rendered permeable to nucleotides, then DNA synthesis was measured by incubating them with [(3)H]deoxythymidine triphosphate in the presence of deoxyATP, deoxyGTP, deoxyCTP, ATP, and Mg(++). Both assays showed the anticipated rise in DNA synthesis after PHA stimulation of normal cells. PHA-stimulated lymphocytes from patients with CLL demonstrated low levels of DNA synthesis in both assay systems. The initial levels of poly(ADPR) synthesis were greater in CLL lymphocytes than in normal cells. Studies with a T-cell-depleted population of normal cells showed the same activity for poly(ADPR) synthesis that was demonstrated by the original population of normal cells. PHA stimulation produced an increase in poly(ADPR) synthesis in both the normal and CLL cells. The increase in poly(ADPR) synthesis in normal cells was coincident with the increase in DNA synthesis. The increase in poly(ADPR) synthesis in the CLL cells was dissociated from the delayed and diminished increase in DNA synthesis. Thus, CLL cells have higher than normal initial levels of poly(ADPR) synthesis. Poly(ADPR) synthesis is dissociated from DNA synthesis in CLL cells whereas it varies directly with DNA synthesis in normal lymphocytes.

Mechanism of epipodophyllotoxin-induced cell death in poly(adenosine diphosphate-ribose) synthesis-deficient V79 Chinese hamster cell lines.

Mutant Chinese hamster V79 cells selected for alterations in poly(ADP-ribose) metabolism were shown to be resistant to epipodophyllotoxin (VP-16)-induced cytotoxicity. Cell lines ADPRT 54 and ADPRT 351 have reduced activity of poly(ADP-ribose) polymerase. N2, N3, and N4 cell lines grow in the absence of nicotinamide, with total NAD levels 1.5-3% of those found in parental V79 cells grown in complete medium. When grown in complete medium, the mutant cell lines are 2.3- to 9.6-fold resistant to VP-16-induced cytotoxicity. All of the cell lines respond to VP-16 treatment by formation of protein-cross-linked DNA strand breaks. Upon drug removal, all the cell lines reverse the DNA strand breaks at similar rates. Our studies show a clear dissociation between induction of DNA strand breaks and cytotoxicity. However, there is a good correlation between drug-induced sister chromatid exchanges and cytotoxicity. Thus, N3 cells, with low levels of VP-16-induced sister chromatid exchanges, show reduced levels of cytotoxicity relative to parental V79 cells, despite the fact that both cell lines show similar levels of VP-16-induced protein-cross-linked DNA strand breaks. Additional studies show that the time course of VP-16-induced cytotoxicity correlated better with the time course of sister chromatid exchange formation than with protein-cross-linked DNA strand break formation. These studies provide strong support for the proposal that VP-16-induced cytotoxicity involves the induction of sister chromatid exchanges. Thus, we suggest that drug-induced stabilization of topoisomerase II-DNA complexes stimulates induction of sister chromatid exchanges, which consequently lead to cell death.

Topoisomerase II-dependent and -independent mechanisms of etoposide resistance in Chinese hamster cell lines.

Resistance to etoposide (VP-16), amsacrine (mAMSA), and doxorubicin (Adriamycin) was studied in two Chinese hamster cell lines primarily selected for resistance to the epipodophyllotoxin. Both lines demonstrated profound resistance to VP-16, and mAMSA stimulated DNA breakage. However, the resistance to mAMSA cytotoxicity in both lines was less than expected from the level of resistance to the effects of topoisomerase II inhibition. Similarly, resistance to the cytotoxicity of high VP-16 concentrations in one of the lines was less than expected from the resistance to inhibition of topoisomerase II. An analysis of the relation of DNA breaks to drug cytotoxicity suggests that cross-resistance to mAMSA was mainly conferred through loss of mAMSA-stimulated, topoisomerase II-mediated DNA breaks. This mechanism also contributed towards reduced VP-16 cytotoxicity. However, our studies suggest that additional mechanisms, independent of resistance to VP-16-mediated topoisomerase II effects, greatly increased the resistance to this agent. Resistance to VP-16 cytotoxicity, not dependent on resistance to drug-mediated DNA cleavage, could be overcome at high drug concentrations in one of the resistant lines and might be responsible for the greater relative resistance to VP-16 than to mAMSA. These findings suggest the presence of two distinct mechanisms of resistance to VP-16 cytotoxicity, one presumably mediated by topoisomerase II and dependent on resistance to drug-mediated DNA scission, and a second mechanism independent of the effects of the drug on topoisomerase II.

Relation of poly(adenosine diphosphoribose) synthesis to DNA synthesis and cell growth.

A permeable cell technique has been used to measure the synthesis of DNA and poly(adenosine diphosphoribose) (poly(ADPR)) in mouse L cells subjected to different perturbations of cell growth. Cells leaving log phase growth and entering plateau phase, showed a decrease in DNA synthesis and an associated increase in intrinsic poly(ADPR) synthesis. In contrast to the variations in intrinsic poly(ADPR) synthesis, the total poly(ADPR) synthesis activity, measured in the presence of added DNAase, remained relatively constant during the fluctuations in cell growth status. Cells subjected to acute glucose deficiency also demonstrated a decrease in DNA synthesis and an associated increase in intrinsic poly(ADPR) synthesis. Similarly, cells infected with vaccinia virus demonstrated an abrupt cessation of DNA synthesis associated with an increase in poly(ADPR) synthesis. Treatment of cells with cytosine arabinoside, inhibited cellular DNA synthesis. This was also associated with an increase in the intrinsic activity of poly(ADPR) synthesis. However, in this case, the increase in poly(ADPR) synthesis was associated with an increase in activity of the DNA synthesis complex, despite the overall inhibition of cell DNA synthesis. These studies demonstrate, that in mouse L cells, suppression of DNA synthesis by multiple different physiologic mechanisms is always associated with an increase in intrinsic activity of poly(ADPR) synthesis.

High molecular weight DNA intermediates synthesized by permeabilized L cells.

Mouse L cells rendered permeable to deoxynucleoside triphosphates synthesize DNA as an extension of replication forks that were active in the intact cells. The permeabilization process does not affect the size of the bulk cell DNA. Intermediate molecular weight DNA, synthesized in the intact cells, is neither degraded to small molecular weight DNA nor processed into bulk cell DNA following the permeabilization process. DNA synthesized by the permeable cells demonstrates a heterogenous distribution in alkaline sucrose gradients, with peaks at 26 S and 71 S. Pulse-chase experiments demonstrate that these two classes of DNA intermediates do not have a precursor product relation. They appear to be synthesized independently and at the same rate. The results are compatible with continuous synthesis of DNA along one template strand and discontinuous synthesis along the opposite strand. DNA synthesis in isolated L cell nuclei was compared to the process in permeabilized cells with the results demonstrating that the rate of DNA synthesis is slower in the nuclei than it is in the permeable cells. Alkaline sucrose gradient studies demonstrate that the DNA synthesized by isolated nuclei is smaller than the DNA synthesized by the permeable cells.

Association of poly(ADP-rib) synthesis with cessation of DNA synthesis and DNA fragmentation.

CHO cells and cs-4-D3 cells were used to investigate the association between poly(ADP-rib) synthesis and the cessation of DNA synthesis and DNA fragmentation. The cs4-D3 cells are cold-sensitive DNA synthesis arrest mutants of CHO cells. Upon incubation at 33 degrees C, DNA synthesis in the cs4-D3 cells stops and the cells enter a prolonged G1 or G0 phase. The events that occurred when cs4 cells were incubated at 33 degrees C were similar to those that occurred when wild-type CHO cells grew to high density. (1) In both cases, DNA synthesis and cell growth stopped. (2) The NAD+ concentration/cell was 20-25% lower in growth-arrested cells than in logarithmically growing cells. (3) Poly(ADP-rib) synthesis was 3-4 fold higher in growth-arrested cells than in logarithmically growing cells. (4) The growth-inhibited cells developed DNA strand breaks which resulted in large percentages of their DNA appearing in the low molecular weight range of alkaline sucrose gradients. (5) Both the increased rate of poly(ADP-rib) synthesis and the development of DNA strand breaks appears to be characteristic of the G1 phase of the cell cycle. (6) When growth-inhibited cells were restored to conditions favorable for DNA synthesis and cell growth, the DNA strand breaks were repaired. (7) Prolonged incubation under growth-restrictive conditions resulted in the accumulation of more DNA strand breaks than the cells could repair. This was followed by cell death when the cells were restored to conditions favorable for cell growth.

Modulation of nitrosourea resistance in human colon cancer by O6-methylguanine.

Human colon cancer is resistant to a variety of alkylating agents including the nitrosoureas. To specifically evaluate nitrosourea resistance, we studied the role of O6-alkylguanine-DNA alkyltransferase (alkyltransferase) which is known to repair nitrosourea-induced cytotoxic DNA damage. Alkyltransferase activity varied over a similar wide range in 25 colon cancer biopsies and 14 colon cancer cell lines but the activity was not correlated with differentiation status, Dukes' classification or in vitro growth characteristics. 1,3-Bis-(2-chloroethyl)-1-nitrosourea (BCNU) resistance and alkyltransferase activity were highly correlated (R2 = 0.929, P less than 0.001) in 7 different colon cancer cell lines, suggesting that the alkyltransferase is an important component of nitrosourea resistance in colon cancer cells. In the BCNU-resistant, high alkyltransferase VACO 6 cell line, inactivation of the alkyltransferase by O6-methylguanine caused a proportional decrease in the BCNU IC50, consistent with that predicted by the regression line. Enzyme inactivation was also associated with a marked increase in DNA cross-link formation. Because alkyltransferase correlates with BCNU resistance in colon cancer, and resistance can be reversed by inactivating the protein, the alkyltransferase may have an important role in nitrosourea resistance in human colon cancer cells. These data provide the rationale for clinical trials in colon cancer with biochemical modulators of the alkyltransferase to increase the therapeutic response to nitrosoureas.

Poly(ADP-ribose) polymerase activity in proliferating and quiescent murine mammary carcinoma cells.

Previous studies have shown that the well-oxygenated but nutrient-deprived quiescent (QI) cells of the 67 murine mammary carcinoma line are significantly more sensitive to radiation-induced cell killing than the well-oxygenated proliferating (P) cells. These QI cells also sustain more initial strand breaks per radiation dose and repair them more slowly than do P cells. We now report that NAD+ levels and rates of poly(ADP-ribosylation) show a trend similar in that both these metabolic parameters are lower in QI cells by a factor of two or more. NAD+ levels were measured in acid extracts of intact monolayers using an enzymatic cycling assay, while poly(ADP-ribosylation) was followed through the incorporation of radioactive NAD+ into polymer by permeabilized cells. The major proteins labeled by [32P]NAD+ were the same in P and QI cells. However, qualitative differences exist among minor poly(ADP-ribosylated) proteins, with some bands labeled in P cells but not detectably labeled in QI cells. These studies suggest similarities between the physiological state of QI cells and that of mature resting lymphocytes.

Neutrophil alkaline phosphatase: comparison of enzymes from normal subjects and patients with polycythemia vera and chronic myelogenous leukemia.

To determine whether decreased alkaline phosphatase activity in the granules from neutrophils of patients with chronic myelogenous leukemia (CML) was due to an absence of enzyme or the production of defective enzyme, we compared the immunologic properties of granule alkaline phosphatase derived from patients with CML with that of normal subjects and patients with polycythemia vera (PRV). Antisera prepared in rabbits against granule alkaline phosphatase purified from the neutrophils of a patient with PRV produced a single precipitin line of antigenic identity when reacted with extracts of normal, PRV, and CML neutrophil granules. A histochemical stain for alkaline phosphatase activity (alpha-naphthyl acid phosphate coupled with Fast Blue RR) specifically stained the precipitin line. A variety of quantitative precipitin techniques failed to produce satisfactory precipitation of alkaline phosphatase activity. Comparative analyses were therefore performed by affinity chromatography using goat antirabbit-gammaglobulin linked to Sepharose 4B to adsorb alkaline phosphatase complexed with rabbit gamma globulin. With this method, 100% of CML, normal, and PRV alkaline phosphatase could be adsorbed. Using limiting concentrations of antibody, a proportionally smaller fraction of enzyme activity was absorbed as the concentration of PRV alkaline phosphatase or normal alkaline phosphatase was increased. Extracts of CML granules containing comparable amounts of protein but 200-fold less alkaline phosphatase activity per milligram did not specifically reduce adsorption. Thus, in CML, we found no evidence that the granulocytes contained a large amount of antigenically normal but enzymatically defective alkaline phosphatase. Examination of electron micrographs revealed no significant differences in the number or distribution of granules in the granulocytes of normal subjects or patients with PRV or CML. This suggests that the low level of neutrophil alkaline phosphatase in CML granulocytes is the result of decreased enzyme content and not a consequence of synthesis of catalytically defective enzyme.

Identification of minimal size requirements of DNA for activation of poly(ADP-ribose) polymerase.

Poly(ADP-ribose) polymerase requires DNA as an essential enzyme activator. Using enzyme purified from lamb thymus and double-stranded deoxynucleotide oligomers of defined length, we conducted studies to identify the smallest size DNA fragment capable of successfully activating poly(ADP-ribose) polymerase. These studies revealed that a double-stranded hexadeoxynucleotide activated the enzyme 30% as effectively as highly polymerized calf thymus DNA and a double-stranded octadeoxynucleotide activated the enzyme even more effectively than calf thymus DNA. When histone H1 was also included in the reaction system, the enzyme could be activated by even smaller DNA fragments. Thus, in the presence of histone H1, a double-stranded tetradeoxynucleotide activated the enzyme 25% as effectively as calf thymus DNA, and a double-stranded hexadeoxynucleotide was equally as effective as calf thymus DNA. The time courses for activation and the stabilities of the products were identical when the enzyme was activated by a double-stranded hexadeoxynucleotide or by calf thymus DNA. Double-stranded oligodeoxynucleotides containing dephosphorylated termini were more effective activators than those containing 3'-phosphorylated termini which in turn were more effective than those containing 5'-phosphorylated termini.

Identification of two distinct properties of class II major histocompatibility complex-associated peptides.

We have examined the interactions of various peptides with the mouse class II major histocompatibility complex molecule I-Ak. The peptides were derived from the model protein hen egg white lysozyme (HEL). The immunodominant peptide of HEL is a 10-mer, residues 52-61. Our previous work established that this sequence contains the key residues for binding and presentation to T cells. Now we show that the binding of this 10-mer sequence resulted in complexes of I-Ak and peptide that, in SDS/PAGE (without boiling the protein), rapidly dissociated from the component alpha and beta chains. The binding interactions were studied in vitro, by incubating purified I-Ak and radiolabeled peptide, or ex vivo, by using antigen-presenting cells incubated with peptides. Peptides with additional residues at either the amino or carboxyl terminus behaved dramatically differently. Complexes of I-Ak with the longer peptides were stable to SDS/PAGE. Very few amino acid additions result in the change from unstable to stable complexes. The important issue here is that when cultured with HEL, antigen-presenting cells selected the HEL peptides containing the 52-61 sequences that favored stability [Nelson, C. A., Roof, R. W., McCourt, D. W. & Unanue, E. R. (1992) Proc. Natl., Acad. Sci. USA 89, 7380-7383]. Also, from other studies, such sequences correlate with a high immunogenicity of the peptide. We conclude that there are structural features of peptides that change the stability of the class II molecule and that are independent of the "core" peptide seen by the T cells.

Two flagellotropic phages and one pilus-specific phage active against Asticcacaulis biprosthecum.

Three phages active against cells of Asticcacaulis biprosthecum attach to receptor sites located at the pole of the cell where pili, flagella, and holdfast are produced. Phage phiAcS2, a large phage with a prolate cylindrical head and flexible, noncontractile tail, attaches to flagella as well as to receptor sites at the pole of the cell. Attachment to flagella occurs at the region where head and tail of the phage are joined, leaving the distal end of the tail free for attachment to receptor sites at the cell surface. Phages phiAcM2 and phiAcM4, are identical in appearance to each other, possessing prolate cylindrical heads and flexible, noncontractile tails, and are smaller than phage phiAcS2. Phage phiAcM4, exhibits the same flagellotropic characteristic as described for phage phiAcS2, including the manner of attachment to flagella. Phage phiAcM2 has no affinity for flagella, but attaches by the distal end of the tail to pili and to receptor sites at the pole of the cell. Mechanical removal of flagella and pili protects against infection by all three phages. Studies with phage-resistant mutants and with KCN-treated cells suggest that pili are required for infection by both flagellotropic and pilus-specific phages.

Peptides determine the lifespan of MHC class II molecules in the antigen-presenting cell.

Although many peptides are generated during the intracellular processing of protein antigens, only a few are selected for recognition by the immune system. The immunodominant epitope of hen egg white lysozyme (HEL) for H-2k mice is contained in a tryptic fragment of amino-acid residues 46-61 (refs 6, 7). The core of this T-cell epitope, from amino acids 52 to 61 (DYGILQINSR), contains those residues required for binding to the class II molecule I-Ak (ref. 7). Most of the naturally processed fragments recovered from I-Ak-bearing antigen-presenting cells (APCs) cultured with HEL contained this 52-61 core sequence, presented as a nested set of peptides with extensions at both the amino and carboxyl termini. We now compare the handling by APCs of peptides containing HEL 52-61 to establish whether there is an advantage for the APC in selecting extended peptides: different complexes between peptides and major histocompatibility complex (MHC) molecules varied greatly in the amount of time associated with the APC, and in their immunogenic strength. This difference in persistence is one of the factors contributing to the selection and immune recognition of peptide-MHC complexes by T cells.

Hindering auxiliary anchors are potent modulators of peptide binding and selection by I-Ak class II molecules.

Selection of particular antigen-derived peptides by class II MHC molecules determines the population of complexes represented on the antigen-presenting cell surface and available for T cell receptor engagement. This discriminating selection process results from unique interactions between the spectrum of peptides generated during antigen processing and the MHC molecules. Here, we examined the selection of peptides by the class II MHC, I-A(k). Our results indicate that although peptide primary anchors are key in MHC binding, auxiliary anchors are a powerful regulatory component in the selection of peptides by I-A(k). Study of the segments surrounding the dominant hen egg white lysozome(48-61) epitope demonstrates that auxiliary anchors also are involved in determining the binding register of I-A(k) along an extended peptide. In addition, we found that unique combinations of auxiliary anchors can act in concert to modulate the binding of peptides to I-A(k).

Mutant cells defective in poly(ADP-ribose) synthesis due to stable alterations in enzyme activity or substrate availability.

We used two different approaches to develop cell lines deficient in poly(ADP-ribose) synthesis to help determine the role of this reaction in cellular functions. One approach to this problem was to develop cell lines deficient in enzyme activity; the other approach was to develop cell lines capable of growing with such low nicotinamide adenine dinucleotide (NAD) levels so as to effectively limit substrate availability for poly(ADP-ribose) synthesis. The selection strategy for obtaining cells deficient in activity of poly(ADP-ribose) polymerase was based on the ability of this enzyme to deplete cellular NAD in response to high levels of DNA damage. Using this approach, we first obtained cell lines having 37-82% enzyme activity compared to their parental cells. We now report the development and characterization of two cell lines which were obtained from cells having 37% enzyme activity by two additional rounds of further mutagenization and selection procedures. These new cell lines contain 5-11% enzyme activity compared to the parental V79 cells. In pursuit of the second strategy, to obtain cells which limit poly(ADP-ribose) synthesis by substrate restriction, we have now isolated spontaneous mutants from V79 cells which can grow stably in the absence of free nicotinamide or any of its analogs. These cell lines maintain NAD levels in the range of 1.5-3% of that found in their parental V79 cells grown in complete medium. The pathway of NAD biosynthesis in these NAD-deficient cells is not yet known. Further characterization of these lines showed that under conditions that restricted poly(ADP-ribose) synthesis, they all had prolonged doubling times and increased frequencies of sister chromatid exchanges.

Characterization and quantitation of peptide-MHC complexes produced from hen egg lysozyme using a monoclonal antibody.

Here we describe generation of Aw3.18, a monoclonal antibody that recognizes peptide residues 48-62 of hen egg lysozyme (HEL) bound to the MHC class II molecule I-Ak. Epitope mapping revealed that Aw3.18 detects a change in the solvent-exposed surface of this peptide-MHC complex upon substitution of the peptide side chain at position P1. Furthermore, Aw3.18 blocked recognition by some, but not all, of the HEL 48-62-reactive T cell hybridomas tested, suggesting a heterogeneity in the T cell response toward this complex. Finally, using Aw3.18, it was possible to determine the fraction of I-Ak molecules loaded with 48-62 peptide after culture of an antigen-presenting cell in medium containing HEL.

Purification and properties of poly(ADP-ribose) polymerase from lamb thymus.

Poly(ADP-ribose) polymerase was purified 2900-fold from lamb thymus with a recovery of 5%. Addition of exogenous DNA was essential for activity of the purified enzyme, and the reaction was stimulated by the addition of either a mixture of histones or purified histone H1. The enzyme is inhibited by sulfhydryl binding agents such as phenylmethanesulfonyl fluoride or N-ethylmaleimide. It does not require magnesium or other metal ion cofactors for activity. The enzyme migrated as a single polypeptide chain with an apparent molecular weight of 135 000 when gel electrophoresis was performed in the presence of sodium dodecyl sulfate. The apparent molecular weight was 175 000 when determined by gel filtration on Sepharose CL-6B-200. The isoelectric point was pH 9.6, and the pH optimum for activity was 8.6-8.8. The apparent Km for NAD+ was 160 microM at 37 degrees C. The activity of the purified polymerase was unaffected by the presence of ADP-ribose, 3',5'-cAMP, or NaF. Nicotinamide, 5-methyl-nicotinamide, theophylline, and thymidine markedly inhibited enzyme activity. Lamb thymus DNA, originally associated with the enzyme, was more effective than commercially obtained calf thymus DNA as an enzyme activator.