Effect of phosphorothioate modifications on the ability of GTn oligodeoxynucleotides to specifically recognize single-stranded DNA-binding proteins and to affect human cancer cellular growth

We have previously identified phosphodiester oligonucleotides exclusively made of G and T bases, named GTn, that significantly inhibit human cancer cell growth and recognize specific nuclear single-stranded DNA binding proteins. We wished to examine the ability of the modified GTn oligonucleotides with different degrees of phosphorothioate modifications to bind specifically to the same nuclear proteins recognized by the GTn phosphodiester analogues and their cytotoxic effect on the human T-lymphoblastic CCRF-CEM cell line. We showed that the full phosphorothioate GTn oligonucleotide was neither able to specifically recognize those nuclear proteins, nor cytotoxic. In contrast, the 3'-phosphorothioate-protected GTn oligonucleotides can maintain the specific protein-binding activity. The end-modified phosphorothioate oligonucleotides were also able to elicit the dose-dependent cell growth inhibition effect, but a loss in the cytotoxic ability was observed increasing the extent of sulphur modification of the sequences. Our results indicate that phosphorothioate oligonucleotides directed at specific single-stranded DNA-binding proteins should contain a number of phosphorothioate end-linkages which should be related to the length of the sequence, in order to maintain the same biological activities exerted by their phosphodiester analogues.     

Increase in therapeutic index of doxorubicin and vinblastine by aptameric oligonucleotide in human T lymphoblastic drug-sensitive and multidrug-resistant cells

Aptameric GT oligomers are a new class of potential anticancer molecules that inhibit the growth of human cancer cell lines by binding to specific nuclear proteins. We demonstrated that an aptameric GT oligonucleotide increased the therapeutic index of doxorubicin and vinblastine in T lymphoblastic drug-sensitive and multidrug-resistant (MDR) cells. The doxorubicin ID50 decreased 6.5-fold by coadministration of 1 microM GT to CCRF-CEM cells and by 24-fold by coadministration of 0.75 microM GT to CEM-VLB300 cells. In CEM-VLB300 cells, the vinblastine ID50 decreased 11-fold by coadministration of 0.5 microM GT. Control CT sequence did not potentiate the drugs in either CCRF-CEM or CEM-VLB300 cells. The ability of GT to bind to specific nuclear proteins in cancer cells related to the increase in the therapeutic index of doxorubicin and vinblastine. No cooperation was detected by the administration of GT oligomer together with doxorubicin to rat differentiated thyroid FRTL-5 cells and to normal human lymphocytes. These cells did not show binding of GT to the specific nuclear proteins, and they were not sensitive to the cytotoxic action of the GT sequence. Drug potentiation by GT not involving normal human lymphocytes might be exploited to develop a more selective treatment of drug-sensitive and MDR tumors.     

Identification of different isoforms of eEF1A in the nuclear fraction of human T-lymphoblastic cancer cell line specifically binding to aptameric cytotoxic GT oligomers.

GT oligomers, showing a dose-dependent cytotoxic effect on a variety of human cancer cell lines, but not on normal human lymphocytes, recognize and form complexes with nuclear proteins. By working with human T-lymphoblastic CCRF-CEM cells and by using MS and SouthWestern blotting, we identified eukaryotic elongation factor 1 alpha (eEF1A) as the main nuclear protein that specifically recognizes these oligonucleotides. Western blotting and supershift assays confirmed the nature of this protein and its involvement in forming a cytotoxicity-related complex (CRC). On the contrary, normal human lymphocytes did not show nuclear proteins able to produce CRC in a SouthWestern blot. Comparative bidimensional PAGE and Western-blotting analysis for eEF1A revealed the presence of a specific cluster of spots, focusing at more basic pH, in nuclear extracts of cancer cells but absent in those of normal lymphocytes. Moreover, a bidimensional PAGE SouthWestern blot demonstrated that cytotoxic GT oligomers selectively recognized the more basic eEF1A isoform expressed only in cancer cells. These results suggest the involvement of eEF1A, associated with the nuclear-enriched fraction, in the growth and maintenance of tumour cells, possibly modulated by post-translational processing of the polypeptide chain.     

Aptameric GT oligomers need to be complexed to ethoxylated polyethylenimine as pre-paired duplexes to efficiently exert their cytotoxic activity in human lymphoblastic cancer cells

The aptameric oligonucleotides GT were found to exert a selective, specific and dose-dependent cell growth inhibition effect on a variety of human cancer cells by recognising specific nuclear proteins and among these in particular an isoform of the eukaryotic elongation factor 1A1 (EEF1A1). The potential development of these aptameric oligomers needs that they retain serum and intracellular stabilities. Polycations are safe non-viral carriers of the nucleic acids. We demonstrated that a weakly basic polycation, the ethoxylated polyethylenimine (EPEI), can efficiently deliver cytotoxic GT oligomers when they were complexed as partial pre-paired duplex. In this way, nuclease-resistance of the oligomer was markedly improved and the administration of the duplex complexed with EPEI to lymphoblastic cancer cells caused a specific cytotoxic effect at concentrations lower than that of naked GT. However, the cytotoxic activity of the oligomer-EPEI complex resulted strictly related to the GC content and Tm of the duplex region. The single-stranded GT and the duplex with high GC content and Tm, although complexed with EPEI failed to exert cytotoxicity. Overall results indicated that aptameric oligomers complexed with polycations can be efficiently delivered into the cells and display the desired biological effect designing a balanced partial duplex whose stability can allow oligomer release from the polycation under the physiological cellular conditions.     

Interaction of G-rich GT oligonucleotides with nuclear-associated eEF1A is correlated with their antiproliferative effect in haematopoietic human cancer cell lines

G-rich GT oligonucleotides with a different content of G clusters have been evaluated for their ability to exert cytotoxicity and to bind to nuclear-associated proteins in T-lymphoblast CCRF-CEM cells. Only the oligomers that did not form G-based structures or had a poor structure, under physiological conditions, were able to exert significant cellular growth inhibition effect. The cytotoxicity of these oligomers was related to their binding to the nuclear-associated eEF1A protein, but not to the recognition of nucleolin or other proteins. In particular, GT oligomers adopting a conformation compatible with G-quadruplex, did not exert cytotoxicity and did not bind to eEF1A. The overall results suggest that the ability of oligomers to adopt a G-quadruplex-type secondary structure in a physiological buffer containing 150 mM NaCl is not a prerequisite for antiproliferative effect in haematopoietic cancer cells. The cytotoxicity of G-rich GT oligomers was shown to be tightly related to their binding affinity for eEF1A protein.     

Effect of Oligomer Length and Base Substitutions on the Cytotoxic Activity and Specific Nuclear Protein Recognition of GTn Oligonucleotides in the Human Leukemic CCRF-CEM Cell Line

Abstract

We have identified phosphodiester oligonucleotides composed of G and T bases, named GTn, which are able to inhibit the cellular growth of human cancer cell lines by recognising specific nuclear proteins. We demonstrated that GTn oligonucleotides require a length of at least 20 nucleotides in order to exert a significant cytotoxic effect and to retain the specific protein binding ability. In addition, we found that GTn cytotoxicity was lost when A or C bases were introduced at either 3′ and 5′end or within the GTn sequences.     

Repair of O(6)-methylguanine is not affected by thymine base pairing and the presence of MMR proteins

Methylation at the O(6)-position of guanine (O(6)-MeG) by alkylating agents is efficiently removed by O(6)-methylguanine-DNA methyltransferase (MGMT), preventing from cytotoxic, mutagenic, clastogenic and carcinogenic effects of O(6)-MeG-inducing agents. If O(6)-MeG is not removed from DNA prior to replication, thymine will be incorporated instead of cytosine opposite the O(6)-MeG lesion. This mismatch is recognized and processed by mismatch repair (MMR) proteins which are known to be involved in triggering the cytotoxic and genotoxic response of cells upon methylation. In this work we addressed three open questions. (1) Is MGMT able to repair O(6)-MeG mispaired with thymine (O(6)-MeG/T)? (2) Do MMR proteins interfere with the repair of O(6)-MeG/T by MGMT? (3) Does MGMT show a protective effect if it is expressed after replication of DNA containing O(6)-MeG? Using an in vitro assay we show that oligonucleotides containing O(6)-MeG/T mismatches are as efficient as oligonucleotides containing O(6)-MeG/C in competing for MGMT repair activity, indicating that O(6)-MeG mispaired with thymine is still subject to repair by MGMT. The addition of MMR proteins from nuclear extracts, or of recombinant MutSalpha, to the in vitro repair assay did not affect the repair of O(6)-MeG/T lesions by MGMT. This indicates that the presence of MutSalpha still allows access of MGMT to O(6)-MeG/T lesions. To elucidate the protective effect of MGMT in the first and second replication cycle after N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) treatment, MGMT transfected CHO cells were synchronized and MGMT was inactivated by pulse-treatment with O(6)-benzylguanine (O(6)-BG). Thereafter, the recovered cells were treated with MNNG and subjected to clonogenic survival assays. Cells which expressed MGMT in the first and second cell cycle were more resistant than cells which expressed MGMT only in the second (post-treatment) cell cycle. Cells which did not express MGMT in both cell cycles were most sensitive. This indicates that repair of O(6)-MeG can occur both in the first and second cell cycle after alkylation protecting cells from the killing effect of the lesion.     

Definition of human cytomegalovirus-specific target antigens recognized by cytotoxic T cells generated in vitro by using an autologous lymphocyte system

We developed an in vitro system for the generation of human cytomegalovirus (CMV)-specific cytotoxic T cells (CTL) that avoids the necessity of constituting a panel of HLA-typed fibroblasts. Autologous donor leucocytes were coated with CMV antigens and were used as both stimulator and target cells. With the use of this system, CMV-specific effector cells were efficiently generated from seropositive but not seronegative donors. These CMV-specific effectors were HLA-restricted and had characteristics of T cells. Maximum lymphoproliferation preceded the appearance of maximum CTL activity by 3 to 4 days, and a close correlation was seen between both activities. Mouse anti-CMV monoclonal antibodies were used in blocking experiments in an attempt to define target antigens recognized by CMV-specific cytotoxic lymphocytes. Monoclonal antibodies directed against an early CMV membrane antigen, against neutralization epitopes, or against nuclear inclusion body protein all specifically inhibited CMV-sensitized effector cell activity but did not affect influenza virus-specific lysis. Monoclonal antibodies directed against a normal cell determinant or against poliovirus did not affect CMV-specific CTL activity. CMV-immune cytotoxic T cells could be consistently and specifically inhibited in their lytic activity by pretreating antigen-coated target cells with monoclonal antibodies directed against CMV-related proteins.     

Assembly of DNA polymerase delta and epsilon holoenzymes depends on the geometry of the DNA template.

To study in details the assembly of DNA polymerases delta and epsilon holoenzymes a circular double-stranded DNA template containing a gap of 45 nucleotides was constructed. Both replication factor C and proliferating cell nuclear antigen were absolutely required and sufficient for assembly of DNA polymerase delta holoenzyme complex on DNA. On such a circular DNA substrate replication protein A (or E. coli single-strand DNA binding protein) was neither required for assembly of DNA polymerase delta holoenzyme complex nor for the gap-filling reaction. A circular structure of the DNA substrate was found to be absolutely critical for the ability of auxiliary proteins to interact with DNA polymerases. The linearization of the circular DNA template resulted in three dramatic effects: (i) DNA synthesis by DNA polymerase delta holoenzyme was abolished, (ii) the inhibition effect of replication factor C and proliferating cell nuclear antigen on DNA polymerase alpha was relieved and (iii) DNA polymerase epsilon could not form any longer a holoenzyme with replication factor C and proliferating cell nuclear antigen. The comparison of the effect of replication factor C and proliferating cell nuclear antigen on DNA polymerases alpha, delta and epsilon indicated that the auxiliary proteins appear to form a mobile clamp, which can easily slide along double-stranded DNA.     

A SmD peptide induces better antibody responses to other proteins within the small nuclear ribonucleoprotein complex than to SmD protein via intermolecular epitope spreading

Autoantibody response against the small nuclear ribonucleoprotein (snRNP) complex is a characteristic feature of systemic lupus erythematosus. The current investigation was undertaken to determine whether activation of SmD-reactive T cells by synthetic peptides harboring T cell epitopes can initiate a B cell epitope spreading cascade within the snRNP complex. T cell epitopes on SmD were mapped in A/J mice and were localized to three regions on SmD, within aa 26-55, 52-69, and 86-115. Immunization with synthetic peptides SmD(31-45), SmD(52-66), and SmD(91-110) induced T and B cell responses to the peptides, with SmD(31-45) inducing the strongest response. However, only SmD(52-66) immunization induced T cells capable of reacting with SmD. Analysis of sera by immunoprecipitation assays showed that intermolecular B cell epitope spreading to U1RNA-associated A ribonucleoprotein and SmB was consistently observed only in the SmD(52-66)-immunized mice. Surprisingly, in these mice, Ab responses to SmD were at low levels and transient. In addition, the sera did not react with other regions on SmD, indicating a lack of intramolecular B cell epitope spreading within SmD. Our study demonstrates that T cell responses to dominant epitope on a protein within a multiantigenic complex are capable of inducing B cell responses to other proteins within the complex. This effect can happen without generating a good Ab response to the protein from which the T epitope was derived. Thus caution must be taken in the identification of Ags responsible for initiating autoimmune responses based solely on serological analysis of patients and animals with systemic autoimmune disorders.     

The human cytomegalovirus UL11 protein interacts with the receptor tyrosine phosphatase CD45, resulting in functional paralysis of T cells

Human cytomegalovirus (CMV) exerts diverse and complex effects on the immune system, not all of which have been attributed to viral genes. Acute CMV infection results in transient restrictions in T cell proliferative ability, which can impair the control of the virus and increase the risk of secondary infections in patients with weakened or immature immune systems. In a search for new immunomodulatory proteins, we investigated the UL11 protein, a member of the CMV RL11 family. This protein family is defined by the RL11 domain, which has homology to immunoglobulin domains and adenoviral immunomodulatory proteins. We show that pUL11 is expressed on the cell surface and induces intercellular interactions with leukocytes. This was demonstrated to be due to the interaction of pUL11 with the receptor tyrosine phosphatase CD45, identified by mass spectrometry analysis of pUL11-associated proteins. CD45 expression is sufficient to mediate the interaction with pUL11 and is required for pUL11 binding to T cells, indicating that pUL11 is a specific CD45 ligand. CD45 has a pivotal function regulating T cell signaling thresholds; in its absence, the Src family kinase Lck is inactive and signaling through the T cell receptor (TCR) is therefore shut off. In the presence of pUL11, several CD45-mediated functions were inhibited. The induction of tyrosine phosphorylation of multiple signaling proteins upon TCR stimulation was reduced and T cell proliferation was impaired. We therefore conclude that pUL11 has immunosuppressive properties, and that disruption of T cell function via inhibition of CD45 is a previously unknown immunomodulatory strategy of CMV.     

N protein is the predominant antigen recognized by vesicular stomatitis virus-specific cytotoxic T cells.

The specificity of anti-vesicular stomatitis virus (VSV)-specific cytotoxic T cells was explored with cell lines expressing VSV genes introduced by electroporation. Low levels of nucleocapsid (N) protein were detected on the surface of VSV-infected cells, but N protein could not be detected on the plasma membrane of transfected EL4 cells. Intracellular N protein was detectable by enzyme-linked immunosorbent assay or immunoprecipitation in some of the transfected cell lines but not in others, unless the transfected genes were induced by sodium butyrate. However, all of the stably transfected EL4 cell lines expressing the VSV-Indiana N protein were efficiently lysed by serotype-specific and cross-reactive anti-VSV cytotoxic T cells (CTLs). Primary cross-reactive anti-VSV CTLs appeared to be specific solely for N protein, based on cold-target competition assays using infected and transfected target cells. Cell lines expressing 100- to 1,000-fold less N protein than did VSV-infected cells were efficiently lysed by both primary and secondary anti-VSV CTLs. Cell lines expressing 100-fold less G protein than did VSV-infected cells were not lysed by either population of effectors. Significantly, cold-target competition studies with secondary CTLs demonstrated that N protein-expressing cell lines were more efficient competitors than were VSV-infected cells even though the latter expressed 100- to 1,000-fold more N protein. This was not an artifact of viral infection since infection of the transfected cell lines did not affect their ability to compete. The possibility that cell lines constitutively expressing internal virus proteins present antigen more effectively than infected cells do is discussed.     

T cell activation via CD2 [T, gp50]: the role of accessory cells in activating resting T cells via CD2

Monoclonal antibody (MAb) GT2 defines a unique epitope on the CD2 molecule. GT2 triggers T cell mitosis in combination with any MAb directed against 9.6/T11(1) or D66, two previously defined CD2 epitopes. We have shown already that accessory cells (AC) are required for plenary T-PBL activation by any pair of Ab directed against D66 + 9.6/T11(1). In this study, we further investigated their role and found it to vary with the anti-CD2 pair used. When purified T-PBL preparation is used, the level of [3H]TdR incorporation observed with anti-(GT2 + 9.6/T11(1)) Ab was not significant; however, it did prove significant, although greatly reduced, with the other anti-CD2 pairs tested. This was due to qualitative differences in the process of T-PBL activation, and the role of AC, because: anti-(GT2 + 9.6/T11(1)) did not induce IL 2-R expression on purified T-PBL, whereas the other anti-CD2 pairs tested did; anti-(GT2 + 9.6/T11(1)) did not induce detectable IL 2 secretion from purified T-PBL, whereas the other anti-CD2 pairs tested induced a low amount; and anti-CDw18 Ab inhibited the mitogenic effect of anti-(GT2 + 9.6/T11(1)) on PBMC by preventing both IL 2-R expression and IL 2 secretion, whereas anti-CDw18 Ab enhanced the mitogenic effect of the other anti-CD2 pairs tested. Paraformaldehyde-fixed AC fully restored, and recombinant IL 1 partially restored purified T-PBL mitosis triggered by all anti-CD2 pairs tested. To induce IL 2 synthesis, the necessity to cross-link anti-CD2 Ab was demonstrated by coupling one Ab on Sepharose beads and adding the second Ab in the soluble phase: under these circumstances, anti-CD2 pairs were mitogenic solely in the presence of AC. These data can be interpreted as follows. Most anti-CD2 pairs require minimal contact between AC and T-PBL to induce plenary levels of IL 2 synthesis. When anti-(GT2 + 9.6/T11(1)) are used, additional contact is necessary, both for IL 2-R expression and IL 2 synthesis, which would include CDw18 for stabilization. We believe these differences could be related to different conformational changes on the CD2 molecule, depending on the epitope on which the antibodies bind, and could account for different signaling to T cells.     

Interaction of alpha 1 with alpha 2 region in class I MHC proteins contributes determinants recognized by antibodies and cytotoxic T cells

The structure-function relationship of individual coding regions of class I mouse major histocompatibility complex proteins was studied by a combination of recombinant DNA, gene transfer techniques, and serologic and functional characterization. To examine the role of alpha 1 and alpha 2 regions in antibody and CTL recognition, the third exon of H-2Dd, Kd, and Ld transplantation antigen genes was replaced by the homologous coding region of the Qa-2-coded class I gene, Q6. We have chosen to carry out the exon shuffling experiments between these two different types of class I genes, because they are structurally similar and did not evolve to carry out identical functions. Therefore, it is less likely that the hybrid proteins will fortuitously recreate alpha 1-alpha 2 controlled functionally important determinants. The replacement of H-2 alpha 2 coding region with its Q6 counterpart had different effects on the expression of the three genes. The mutant H-2Dd gene transfected into L cells was expressed at high levels and retained several of the serologic determinants found on parental H-2Dd and Q6 domains. The serologic epitopes on the mutant H-2Kd-transfected cells were detectable at very low levels, whereas the product of the mutant H-2Ld gene could not be identified at all. Analysis of cells transfected with mutant H-2Dd gene with alloreactive and minor antigen(s)-restricted cytotoxic T cells indicated that the hybrid proteins lost the ability to be recognized by T cells. Our data suggest that cytotoxic T cells recognize conformational determinants composed of amino acids from alpha 1 and alpha 2 regions. Alternatively, it could be proposed that T cell recognition sites located in a single alpha 1 or alpha 2 protein region are susceptible to distortion upon alpha 1-alpha 2 interactions. Such susceptibility to conformational changes of the amino-terminal domain of transplantation antigens could be of functional importance for H-2-restricted antigen presentation.     

An essential 45 kDa yeast transmembrane protein reacts with anti-nuclear pore antibodies: purification of the protein, immunolocalization and cloning of the gene.

A yeast membrane protein was isolated by its binding to tRNA Sepharose column. The 45 kDa protein shares characteristics with rat liver nuclear pore proteins in having reactivity with a monoclonal antibody (RL1) raised against rat liver nuclear pore proteins and by the binding of wheat germ agglutinin (WGA), indicating the presence of N-acetylglucosamine (GlcNAc) moieties. Immunofluorescence microscopy and cell fractionation experiments indicate that the protein is located in the nuclear envelope and the endoplasmic reticulum of the cell. The gene for the 45 kDa protein was cloned using degenerate oligonucleotides derived from the N-terminal protein sequence and confirmed by internal peptide sequences. The gene was named WBP1. The protein coding sequence of the WBP1 gene reveals an ER entry signal peptide and a C-terminal membrane spanning domain. Topological studies indicate that the C-terminus of the protein is located in the cytoplasm. The cytoplasmic tail of the protein contains the K-K-X-X signal known to be sufficient for retention of transmembrane proteins in higher eukaryotic cells. Gene disruption experiments show that the 45 kDa protein is essential for the vegetative life cycle of the yeast cell.     

Spleen focus-forming Friend virus: identification of genomic RNA and its relationship to helper virus RNA.

The genome of the defective, murine spleen focus-forming Friend virus (SFFV) was identified as a 50S RNA complex consisting of 32S RNA monomers. Electrophoretic mobility and the molecular weights of unique RNase T1-resistant oligonucleotides (T1-oligonucleotides) indicated that the 32S RNA had a complexity of about 7.4 kilobases. Hybridization with DNA complementary to Friend murine leukemia virus (Fr-MLV) has distinguished two sets of nucleotide sequences in 32S SFFV RNA, 74% which were Fr-MLV related and 26% which were SFFV specific. By the same method, SFFV RNA was 48% related to Moloney MLV. We have resolved 23 large T1-oligonucleotides of SFFV RNA and 43 of Fr-MLV RNA. On the basis of the relationship between SFFV and Fr-MLV RNAs, the 23 SFFV oligonucleotides fell into four classes: (i) seven which had homologous equivalents in Fr-MLV RNA; (ii) six more which could be isolated from SFFV RNA-Fr-MLV cDNA hybrids treated with RNases A and T1; (iii) eight more which were isolated from hybrids treated with RNases A and T1; and (iv) two which did not have Fr-MLV-related counterparts. Surprisingly, the two class iv oligonucleotides had homologous counterparts in the RNA of six amphotropic MLV's including mink cell focus-forming and HIX-MLVs analyzed previously. The map locations of the 23 SFFV T1-oligonucleotides relative to the 3' polyadenylic acid coordinate of SFFV RNA were deduced from the size of the smallest polyadenylic acid-tagged RNA fragment from which a given oligonucleotide was isolated. The resulting oligonucleotide map could be divided roughly into three segments: two terminal segments which are mosaics of oligonucleotides of classes i, ii, and iii and an internal segment between 2 and 2.5 kilobases from the 3' end containing the two oligonucleotides shared with amphotropic MLVs. Since SFFV RNA consists predominantly of sequence elements related to ecotropic and amphotropic helper-independent MLVs, it would appear that the transforming gene of SFFV is not a major specific sequence unrelated to genes of helper viruses, as is the case with Rous sarcoma and probably withe other defective sarcoma and acute leukemia viruses.