Perspectives on the development of a therapeutic HER-2 cancer vaccine

With good reason, the majority of cancer vaccines tested, or being tested, have targeted the induction of anti-tumour CTL responses. However, the clinical success of monoclonal antibodies such as Rituximab/CD20, Trastuzumab/HER-2, Cetuximab/EGFR and Bevacisumab/VEGF suggests that their respective targets may also be relevant for cancer vaccines aiming at the induction of an effective humoral anti-tumour response to mimic, or potentially improve upon, the effects of monoclonal therapies. We report here an overview of the development of a protein vaccine targeting HER-2/neu, with an emphasis on the immunologic results obtained from the testing of the vaccine in animal models of disease and in toxicology programs, to its evaluation in three clinical trials in breast cancer patients.

Linked Foreign T-Cell Help Activates Self-Reactive CTL and Inhibits Tumor Growth

Transgenic mice expressing membrane-bound OVA under the rat insulin promoter, RIP-mOVA, has previously been suggested to display deletional tolerance toward the dominant CTL epitope, SIINFEKL, and provide an elegant model system to test the hypothesis that the lack of T cell help contributes to the tolerance. To understand how the CD8 tolerance is maintained in these mice, a set of neo-self-Ags, OVA, modified to contain a foreign Th peptide, were constructed and tested for their ability to induce CTL responses in RIP-mOVA mice. Immunization with these Th peptide-modified OVA molecules and not with the wild-type OVA induced self-reactive CTLs recognizing dominant CTL peptide, SIINFEKL. Importantly, immunization with the modified OVA constructs also prevented the growth of OVA-expressing tumors in transgenic mice. Since endogenous OVA Th peptides did not contribute toward breaking self CTL tolerance, these results also highlighted a very robust CD4 T cell tolerance toward OVA in RIP-mOVA mice that has not been previously described. These results therefore provide direct evidence that it is the tolerance in the CD4 Th cell compartment that helps maintain the CTL tolerance against self-Ag in these mice. Since the CTL tolerance can be broken or bypassed by foreign Th peptides inserted into a self Ag, potential of using this approach in generating effective therapeutic cancer vaccines is discussed.

HER-2 DNA and protein vaccines containing potent Th cell epitopes induce distinct protective and therapeutic antitumor responses in HER-2 transgenic mice

Overexpression of the growth factor receptor HER-2 (c-erbB-2, neu) has transforming potential and occurs in approximately 20-30% of breast and ovarian cancers. HER-2 is a self Ag, but Abs and T cells specific for HER-2 have been isolated from cancer patients, suggesting HER-2 may be a good target for active immunotherapy. We constructed rat HER-2 DNA and protein vaccines containing potent Th cell epitopes derived from tetanus toxin and studied their potency in two strains of mice transgenic for the rat HER-2 molecule. Vaccination with HER-2 DNA protected nontransgenic mice from tumor challenge, but induced only moderate protection in one of the tumor models. However, vaccination with the modified HER-2 protein resulted in almost complete protection from tumor challenge in both tumor models. This protection could be mediated by Abs alone. In addition, protein vaccination efficiently eliminated pre-established tumors in both models, even when vaccination occurred 9 days after tumor implantation. These data demonstrate the potential of HER-2-based vaccines as therapeutic agents for the treatment of cancers overexpressing HER-2.

Recombination at double-strand breaks and DNA ends: conserved mechanisms from phage to humans

The recombination mechanisms that deal with double-strand breaks in organisms as diverse as phage, bacteria, yeast, and humans are remarkably conserved. We discuss conservation in the biochemical pathways required to recombine DNA ends and in the structure of the DNA products. In addition, we highlight that two fundamentally distinct broken DNA substrates exist and describe how they are repaired differently by recombination. Finally, we discuss the need to coordinate recombinational repair with cell division through DNA damage response pathways.

Recombinational repair of chromosomal DNA double-strand breaks generated by a restriction endonuclease

DNA double-strand break repair can be accomplished by homologous recombination when a sister chromatid or a homologous chromosome is available. However, the study of sister chromatid double-strand break repair in prokaryotes is complicated by the difficulty in targeting a break to only one copy of two essentially identical DNA sequences. We have developed a system using the Escherichia coli chromosome and the restriction enzyme EcoKI, in which double-strand breaks can be introduced into only one sister chromatid. We have shown that the components of the RecBCD and RecFOR 'pathways' are required for the recombinational repair of these breaks. Furthermore, we have shown a requirement for SbcCD, the prokaryotic homologue of Rad50/Mre11. This is the first demonstration that, like Rad50/Mre11, SbcCD is required for recombination in a wild-type cell. Our work suggests that the SbcCD-Rad50/Mre11 family of proteins, which have two globular domains separated by a long coiled-coil linker, is specifically required for the co-ordination of double-strand break repair reactions in which two DNA ends are required to recombine at one target site.

Control of crossing over

The Holliday junction is a central intermediate in homologous recombination. It consists of a four-way structure that can be resolved by cleavage to give either the crossover or noncrossover products observed. We show here that the formation of these products is controlled by the E. coli resolvasome (RuvABC) in such way that double-strand break repair (DSBR) leads to crossing over and single-strand gap repair (SSGR) does not lead to crossing over. We argue that the positioning of the RuvABC complex and its consequent direction of junction-cleavage is not random. In fact, the action of the RuvABC complex avoids crossing over in the most commonly predicted situations where Holliday junctions are encountered in DNA replication and repair. Our observations suggest that the positioning of the resolvasome may provide a general biochemical mechanism by which cells can control crossing over in recombination.

The roles of mutS, sbcCD and recA in the propagation of TGG repeats in Escherichia coli

A 24 triplet TGG.CCA repeat array shows length- and orientation-dependent propagation when present in the plasmid pUC18. When TGG(24) is present as template for leading-strand synthesis, plasmid recovery is normal in all strains tested. However, when it acts as template for lagging-strand synthesis, plasmid propagation is seriously compromised. Plasmids carrying deletions in the 5' side of this sequence can be isolated and products carrying 15 TGG triplets do not significantly interfere with plasmid propagation. Mutations in sbcCD, mutS and recA significantly improve the recovery of plasmids with TGG(24) on the lagging-strand template. These findings suggest that TGG(24) can fold into a structure that can interfere with DNA replication in vivo but that TGG(15) cannot. Furthermore, since the presence of the MutS and SbcCD proteins are required for propagation interference, it is likely that stabilisation of mismatched base pairs and secondary structure cleavage are implicated. In contrast, there is no correlation of triplet repeat expansion and deletion instability with predicted DNA folding. These results argue for a dissociation of the factors affecting DNA fragility from those affecting trinucleotide repeat expansion-contraction instability.

Palindromes as substrates for multiple pathways of recombination in Escherichia coli

A 246-bp imperfect palindrome has the potential to form hairpin structures in single-stranded DNA during replication. Genetic evidence suggests that these structures are converted to double-strand breaks by the SbcCD nuclease and that the double-strand breaks are repaired by recombination. We investigated the role of a range of recombination mutations on the viability of cells containing this palindrome. The palindrome was introduced into the Escherichia coli chromosome by phage lambda lysogenization. This was done in both wt and sbcC backgrounds. Repair of the SbcCD-induced double-strand breaks requires a large number of proteins, including the components of both the RecB and RecF pathways. Repair does not involve PriA-dependent replication fork restart, which suggests that the double-strand break occurs after the replication fork has passed the palindrome. In the absence of SbcCD, recombination still occurs, probably using a gap substrate. This process is also PriA independent, suggesting that there is no collapse of the replication fork. In the absence of RecA, the RecQ helicase is required for palindrome viability in a sbcC mutant, suggesting that a helicase-dependent pathway exists to allow replicative bypass of secondary structures.

Two opposing effects of mismatch repair on CTG repeat instability in Escherichia coli

The expansion of normally polymorphic CTG microsatellites in certain human genes has been identified as the causative mutation of a number of hereditary neurological disorders, including Huntington's disease and myotonic dystrophy. Here, we have investigated the effect of methyl-directed mismatch repair (MMR) on the stability of a (CTG)43 repeat in Escherichia coli over 140 generations and find two opposing effects. In contrast to orientation-dependent repeat instability in wild-type E. coli and yeast, we observed no orientation dependence in MMR- E. coli cells and suggest that, for the repeat that we have studied, orientation dependence in wild-type cells is mainly caused by functional mismatch repair genes. Our results imply that slipped structures are generated during replication, causing single triplet expansions and contractions in MMR- cells, because they are left unrepaired. On the other hand, we find that the repair of such slipped structures by the MMR system can go awry, resulting in large contractions. We show that these mutS-dependent contractions arise preferentially when the CTG sequence is encoded by the lagging strand. The nature of this orientation dependence argues that the small slipped structures that are recognized by the MMR system are formed primarily on the lagging strand of the replication fork. It also suggests that, in the presence of functional MMR, removal of 3 bp slipped structures causes the formation of larger contractions that are probably the result of secondary structure formation by the CTG sequence. We rationalize the opposing effects of MMR on repeat tract stability with a model that accounts for CTG repeat instability and loss of orientation dependence in MMR- cells. Our work resolves a contradiction between opposing claims in the literature of both stabilizing and destabilizing effects of MMR on CTG repeat instability in E. coli.

DNA cleavage and degradation by the SbcCD protein complex from Escherichia coli

The SbcCD protein is a member of a group of nucleases found in bacteriophage T4 and T5, eubacteria, archaebacteria, yeast, Drosophila, mouse and man. Evidence from electron microscopy has revealed a distinctive structure consisting of two globular domains linked by a long region of coiled coil, similar to that predicted for the members of the SMC family. That a nuclease should have such an unusual structure suggests that its mode of action may be complex. Here we show that the protein degrades duplex DNA in a 3'-->5' direction. This degradation releases products half the length of the original duplex suggesting simultaneous degradation from two duplex ends. This may provide a link to the unusual structure of the protein since our data are consistent with recognition and cleavage of DNA ends followed by 3'-->5' nicking by two nucleolytic centres within a single nuclease molecule that releases a half length limit product. We also show that cleavage is not simply at the point of a single-strand/double-stand transition and that despite the dominant 3'-->5' polarity of degradation, a 5' single-strand can be cleaved when attached to duplex DNA. The implications of this mechanism for the processing of hairpins formed during DNA replication are discussed.

CTLA-4 blockade synergizes with tumor-derived granulocyte-macrophage colony-stimulating factor for treatment of an experimental mammary carcinoma

Generation of a T cell-mediated antitumor response depends on T cell receptor engagement by major histocompatibility complex/antigen as well as CD28 ligation by B7. CTLA-4 is a second B7 receptor expressed by T cells upon activation that, unlike CD28, appears to deliver an inhibitory signal to T cells. Recently, we and others demonstrated that administration of an anti-CTLA-4 antibody was sufficient to promote regression of several murine tumors. However, certain tumors, such as the SM1 mammary carcinoma, remain refractory to this type of immunotherapy. In the present study, we report that the combination of both CTLA-4 blockade and a vaccine consisting of granulocyte-macrophage colony-stimulating factor-expressing SM1 cells resulted in regression of parental SM1 tumors, despite the ineffectiveness of either treatment alone. This synergistic therapy resulted in long-lasting immunity to SM1 and depended on both CD4(+) and CD8(+) T cells. Interestingly, synergy was not observed between CTLA-4 and a B7-expressing SM1 vaccine. Given that granulocyte-macrophage colony-stimulating factor promotes differentiation and activation of dendritic cells as well as enhances cross-priming of T cells to tumor-derived antigens and that SM1 is major histocompatibility complex class II-negative, our findings suggest that CTLA-4 blockade acts at the level of a host-derived antigen-presenting cell. In addition, these results also support the idea that the most effective and synergistic vaccine strategy targets treatments that enhance T cell priming at the level of host-derived antigen-presenting cells.

The SbcCD nuclease of Escherichia coli is a structural maintenance of chromosomes (SMC) family protein that cleaves hairpin DNA

Hairpin structures can inhibit DNA replication and are intermediates in certain recombination reactions. We have shown that the purified SbcCD protein of Escherichia coli cleaves a DNA hairpin. This cleavage does not require the presence of a free (3' or 5') DNA end and generates products with 3'-hydroxyl and 5'-phosphate termini. Electron microscopy of SbcCD has revealed the "head-rod-tail" structure predicted for the SMC (structural maintenance of chromosomes) family of proteins, of which SbcC is a member. This work provides evidence consistent with the proposal that SbcCD cleaves hairpin structures that halt the progress of the replication fork, allowing homologous recombination to restore DNA replication.

Replication strand preference for deletions associated with DNA palindromes

We have isolated and sequenced a set of deletions stimulated by DNA palindromes in Escherichia coli. All of the deletions are asymmetric with respect to the parental sequence and have occurred at short direct repeats. This is consistent with deletion by strand slippage during DNA replication. The orientation of the asymmetry in such deletion products is diagnostic of the direction of the strand slippage event. It is therefore also diagnostic of its occurrence on the leading or lagging strand of the replication fork when the direction of replication is known. In all cases in which the orientation of the asymmetry could be determined with respect to DNA replication, the products were consistent with a preference for deletion on the lagging strand of the fork. The data include replication slippage in three situations: on the chromosome of E. coli, in bacteriophage lambda and in high-copy-number pUC-based plasmids.

Secondary structures in d(CGG) and d(CCG) repeat tracts

Several studies have been made to elucidate the nature of secondary structures in the single strands of d(CGG).d(CCG) repeat tracts but with conflicting conclusions. Here, we review this work and attempt to come towards consensus. Some investigators find that the G-rich strand forms hairpins. Of these, some conclude that pairing is in the alignment d(GGC).d(GGC) with two Watson-Crick bonds and one G.G bond per duplex repeat, others conclude that the alignment is d(GCG).d(GCG) with two G.G bonds and one C.C bond per duplex repeat. Others find quadruplex formation and conclude that this is in the latter alignment with two G4-quartets per quadruplex repeat and C.C bonds. We investigate why these different results were obtained and conclude that quadruplexes are likely to form under physiological conditions. We argue that they are probably bonded in the alignment d(GGC).d(GGC) with one G4-quartet and two C.G.C.G. quartets per quadruplex repeat. The C-rich strand does not appear to form quadruplexes under physiological conditions but forms hairpins. Apparently, short hairpins adopt the alignment d(CCG).d(CCG) with mismatched cytosine residues stacked into the helix but with 15 or more repeat units, the dominant form is a distorted hairpin aligned as d(GCC).d(GCC) with unpaired cytosine residues possibly turned outwards and stacked in the minor groove.

Evidence for two preferred hairpin folding patterns in d(CGG).d(CCG) repeat tracts in vivo

Unusual DNA secondary structures have been implicated in the expansion of trinucleotide repeat tracts that has been found to be responsible for a growing number of human inherited disorders and folate-sensitive fragile chromosome sites. By inserting trinucleotide repeat sequences into a palindromic clamp in lambda phage we are able to investigate their tendencies to form hairpins in vivo in any particular alignment and with odd or even numbers of repeat units in the hairpin. We previously showed that with d(CAG).d(CTG) repeat tracts there was a markedly greater tendency to form hairpins with even numbers of repeat units than with odd numbers, whereas d(GAC).d(GTC) repeats showed no such alternation despite having the same base composition. We expected that d(CGG).d(CCG) repeats, might show the same pattern as d(CAG).(CTG) repeats since they are also involved in trinucleotide repeat expansion disorders. The pattern was not so clear and we wondered whether this might be because d(CGG).d(CCG) repeats have more than one possible alignment in which they could self-anneal. We now present results for all three alignments, which suggest that while even-membered hairpins are preferred in the frame d(CGG).d(CCG), hairpins with odd numbers of trinucleotides are more stable in the frame d(GGC).d(GCC). In both cases the base-pair predicted to close the terminal loop of unpaired bases is 5'C.3'G which has previously been found to be a favoured loop-closing pair.

Repair by recombination of DNA containing a palindromic sequence

We report here that homologous recombination functions are required for the viability of Escherichia coli cells maintaining a 240 bp chromosomal inverted repeat (palindromic) sequence. Wild-type cells can successfully replicate this palindrome but recA, recB or recC mutants carrying the palindrome are unviable. The dependence on homologous recombination for cell viability is overcome in sbcC mutants. Directly repeated copies of the DNA containing the palindrome are rapidly resolved to single copies in wild-type cells but not in sbcC mutants. Our results suggest that double-strand breaks introduced at the palindromic DNA sequence by the SbcCD nuclease are repaired by homologous recombination. The repair is conservative and the palindrome is retained in the repaired chromosome. We conclude that SbcCD can attack secondary structures but that repair conserves the DNA sequence with the potential to fold.

Overexpression, purification, and characterization of the SbcCD protein from Escherichia coli

The sbcC and sbcD genes mediate palindrome inviability in Escherichia coli. The sbcCD operon has been cloned into the plasmid pTrc99A under the control of the strong trc promoter and introduced into a strain carrying a chromosomal deletion of sbcCD. The SbcC and SbcD polypeptides were overexpressed to 6% of total cell protein, and both polypeptides copurified in a four-step purification procedure. Purified SbcCD is a processive double-strand exonuclease that has an absolute requirement for Mn2+ and uses ATP as a preferred energy source. Gel filtration chromatography and sedimentation equilibrium analyses were used to show that the SbcC and SbcD polypeptides dissociate at some stage after purification and that this dissociation is reversed by the addition of Mn2+. We demonstrate that SbcD has the potential to form a secondary structural motif found in a number of protein phosphatases and suggest that it is a metalloprotein that contains the catalytic center of the SbcCD exonuclease.

Different structures of selected and unselected araB-lacZ fusions

Formation of araB-lacZ coding-sequence fusions is a key adaptive mutation system. Eighty-four independent araB-lacZ fusions were sequenced. All fusions carried rearranged MuR linker sequences between the araB and lacZ domains indicating that they arose from the standard intermediate of the well-characterized Mu DNA rearrangement process, the strand transfer complex (STC). Five non-standard araB-lacZ fusions isolated after indirect sib selection had novel structures containing back-to-back inverted MuR linkers. The observation that different isolation procedures gave rise to standard and non-standard fusions indicates that cellular physiology can influence late steps in the multi-step biochemical sequence leading to araB-lacZ fusions. Each araB-lacZ fusion contained two novel of DNA junctions. The MuR-lacZ junctions showed 'hot-spotting' according to established rules for Mu target selection. The araB-MuR and MuR-MuR junctions all involved exchanges at regions of short sequence homology. More extensive homology between MuR and araB sequences indicates potential STC isomerization a resolvable four-way structure analogous to a Holliday junction. These results highlight the molecular complexity of araB-lacZ fusion formation, which may be thought of as a multi-step cell biology process rather than a unitary biochemical reaction.

DIR: a novel DNA rearrangement associated with inverted repeats

A novel DNA rearrangement has been characterised that is both a direct and inverted repeat. This rearrangement involves the 2-fold duplication of a plasmid sequence adjacent to the site of insertion of a long palindrome. The sequence of this rearrangement suggests that it has arisen by strand slippage from the leading to the lagging strand of the replication fork as a consequence of the presence of the long palindrome.

Enhancement of antitumor immunity by CTLA-4 blockade

One reason for the poor immunogenicity of many tumors may be that they cannot provide signals for CD28-mediated costimulation necessary to fully activate T cells. It has recently become apparent that CTLA-4, a second counterreceptor for the B7 family of costimulatory molecules, is a negative regulator of T cell activation. Here, in vivo administration of antibodies to CTLA-4 resulted in the rejection of tumors, including preestablished tumors. Furthermore, this rejection resulted in immunity to a secondary exposure to tumor cells. These results suggest that blockade of the inhibitory effects of CTLA-4 can allow for, and potentiate, effective immune responses against tumor cells.

The sbcC and sbcD genes of Escherichia coli encode a nuclease involved in palindrome inviability and genetic recombination

BACKGROUND

Long DNA palindromes have the potential to adopt hairpin or cruciform secondary structures that inhibit DNA replication. In Escherichia coli, this palindrome-mediated inviability results from the activity of the sbcC and sbcD genes, and genetic observations have suggested that they may encode a nuclease. Mutations in these genes also restore the defect in genetic recombination associated with recBC sbcB mutants.

RESULTS

We have purified the E. coli SbcCD protein from an overexpressing strain and have shown that it has an ATP-dependent DNA double-strand exonuclease activity. Co-purification of nuclease with protein, antibody inhibition and the absence of activity in extracts lacking the sbcCD genes confirm that the activity is intrinsic to SbcCD. The purified protein also has an ATP-independent single-strand DNA endonuclease activity.

CONCLUSIONS

We have shown that sbcCD encodes a nuclease. The purified protein has double-strand DNA exonuclease and single-strand DNA endonuclease activities. We propose that SbcCD cleaves secondary structures formed at replication forks and that the broken forks can be repaired by homologous recombination.

Tumor cells engineered to express major histocompatibility complex class II molecules induce T helper cell-dependent responses that protect mice from normally lethal doses of unmodified tumor cells

Tumor cells typically fail to stimulate protective immune response in the autochthonous host. This does not appear to be the result of either inadequate antigenicity or failure to express a normal complement of major histocompatibility complex (MHC) class 1 molecules. To investigate if tumor cells fail to stimulate protective immunity because they fail to activate adequate numbers of T helper cells, we transfected murine fibrosarcoma and melanoma cells with genes encoding syngeneic and allogeneic MHC class II molecules. Fibrosarcoma cells expressing either type of MHC class II molecules failed to induce tumors in syngeneic mice and stimulated T helper cell-dependent antitumor immune responses that protected mice from subsequent challenge with untransfected tumor cells. The antitumor response involved both CD4+ and CD8+ T cells, and appeared to be dependent on at least low levels of innate tumor cell immunogenicity.

The effects of trinucleotide repeats found in human inherited disorders on palindrome inviability in Escherichia coli suggest hairpin folding preferences in vivo

Unusual DNA secondary structures have been implicated in the expansion of trinucleotide repeat tracts that are associated with several human inherited disorders. We present evidence consistent with the folding of these trinucleotide repeats into hairpin loops at the center of a long DNA palindrome in vivo. Our assay utilizes a palindrome in bacteriophage lambda, the center of which determines its ability to inhibit plaque formation in a manner that is consistent with folding into a hairpin or cruciform structure. We show that central inserts of even numbers of d(CAG).d(CTG) repeats inhibit plaque formation more than do odd numbers. Both d(CAG)2.d(CTG)2 and d(CGG)2.d(CCG)2 central sequences behave like DNA sequences known to form two-base loops in vitro, suggesting that they may also form compact and stable loops. By contrast, repeats of d(GAC).d(GTC) do not show any evidence consistent with unusual loop stability. These results agree with in vitro evidence that the unstable repeats can form hairpin secondary structures and suggest a favored position of folding. We discuss the potential roles of secondary structures, DNA replication and recombination in models of repeat tract expansion.

Manipulation of costimulatory signals to enhance antitumor T-cell responses

One of the major goals of tumor immunotherapy is the induction of tumor-specific T-cell responses that will be effective in eradicating disseminated tumors. Emerging information on the role of costimulatory molecules in T-cell activation offers several new strategies for enhancing antitumor responses, including the induction of expression of costimulatory molecules on tumor cells, enhancement of the presentation of transferred tumor antigen by host antigen-presenting cells, and ex vivo antigen priming of autologous antigen-presenting cells.

DNA palindromes adopt a methylation-resistant conformation that is consistent with DNA cruciform or hairpin formation in vivo

Long DNA palindromes present a threat to genomic stability and are not tolerated in Escherichia coli. It has been suggested that this is a consequence of cruciform or hairpin formation by palindromic sequences. This work describes a methylation inhibition assay for unusual DNA secondary structure in vivo that is both internally controlled and non-invasive. If a palindrome with a central GATC target site for Dam methylase assumes a cruciform or hairpin conformation in vivo, then the GATC sequence will be located in a single-stranded loop and will consequently not be modified. The centre of a long perfect palindrome located in bacteriophage lambda is shown to be methylation-resistant in vivo. Changes to the central sequence and insertions of 10 base-pairs of asymmetric sequence do not alter the degree of under-methylation, but insertions of 20 base-pairs or more of asymmetric sequence reduce the under-methylation of the palindrome centre. We also show that the centres of long palindromes are more under-methylated than equivalent sequences in a non-palindromic context. These results are consistent with an unusual secondary structure, such as DNA cruciform or hairpin, and indicate that the formation pathway of the structure detected is independent of the composition and symmetry of the central 10 base-pairs of the palindrome.

Fibrosarcoma cells expressing allogeneic MHC Class II antigens induce protective antitumor immunity

The initiation of effective immune responses usually requires presentation of Ags by MHC class I and class II molecules. Although most tumors express MHC class I molecules, MHC class II molecule expression is generally limited to specialized APCs. One reason spontaneous tumors may fail to elicit effective immune responses is that tumor Ags are inefficiently presented by APCs, and adequate T cell-mediated help is not generated. To test this hypothesis, we investigated the possibility of enhancing Th cell stimulation by inducing expression of MHC class II molecules on tumor cells. We transfected a murine fibrosarcoma, Sa1N, with the genes encoding allogeneic (I-Ad) or syngeneic (I-Ak) MHC class II molecules. We then compared the tumorigenic and immunogeneic potential of these transfectants to parental Sa1N tumor cells. Subcutaneous injection of allogeneic or syngeneic transfectants resulted in dramatically fewer tumors than injection of unmodified fibrosarcoma cells, and mice inoculated with MHC class II gene-transfected cells were resistant to subsequent challenge with parental Sa1N cells. Rejection of allogeneic MHC class II Ag+ tumor cells could be mediated by either CD4+ or CD8+ T cells, whereas rejection of secondary challenge with wild-type Sa1N tumor cells required both T cell subsets. These results demonstrate that allogeneic, as well as syngeneic, MHC class II Ag+ tumor cells can stimulate protective antitumor immunity.

Fibrosarcoma cells expressing allogeneic MHC Class II antigens induce protective antitumor immunity

The initiation of effective immune responses usually requires presentation of Ags by MHC class I and class II molecules. Although most tumors express MHC class I molecules, MHC class II molecule expression is generally limited to specialized APCs. One reason spontaneous tumors may fail to elicit effective immune responses is that tumor Ags are inefficiently presented by APCs, and adequate T cell-mediated help is not generated. To test this hypothesis, we investigated the possibility of enhancing Th cell stimulation by inducing expression of MHC class II molecules on tumor cells. We transfected a murine fibrosarcoma, Sa1N, with the genes encoding allogeneic (I-Ad) or syngeneic (I-Ak) MHC class II molecules. We then compared the tumorigenic and immunogeneic potential of these transfectants to parental Sa1N tumor cells. Subcutaneous injection of allogeneic or syngeneic transfectants resulted in dramatically fewer tumors than injection of unmodified fibrosarcoma cells, and mice inoculated with MHC class II gene-transfected cells were resistant to subsequent challenge with parental Sa1N cells. Rejection of allogeneic MHC class II Ag+ tumor cells could be mediated by either CD4+ or CD8+ T cells, whereas rejection of secondary challenge with wild-type Sa1N tumor cells required both T cell subsets. These results demonstrate that allogeneic, as well as syngeneic, MHC class II Ag+ tumor cells can stimulate protective antitumor immunity.

Protective antitumor immunity induced by immunization with MHC class II gene-transfected tumor cells is unrelated to MHC class II expression

A/JCr mice reject Sa1N fibrosarcoma cells genetically engineered to express major histocompatibility complex (MHC) class II molecules and are highly resistant to subsequent challenge with unmodified Sa1N cells. In this report we examine the mechanism by which this protective antitumor immunity is induced. We found that MHC class II antigen-positive tumor cells were no more effective than irradiated, MHC class II antigen-negative cells at inducing secondary protective immunity. Additionally, therapeutic immunization with MHC class II antigen-positive tumor cells had no effect on the growth of admixed Sa1N cells or preexisting Sa1N tumors. Based on these observations, we conclude that the MHC class II antigen-induced immune response is not related to Sa1N-specific antitumor immunity.

Long DNA palindromes, cruciform structures, genetic instability and secondary structure repair

Long DNA palindromes pose a threat to genome stability. This instability is primarily mediated by slippage on the lagging strand of the replication fork between short directly repeated sequences close to the ends of the palindrome. The role of the palindrome is likely to be the juxtaposition of the directly repeated sequences by intra-strand base-pairing. This intra-strand base-pairing, if present on both strands, results in a cruciform structure. In bacteria, cruciform structures have proved difficult to detect in vivo, suggesting that if they form, they are either not replicated or are destroyed. SbcCD, a recently discovered exonuclease of Escherichia coli, is responsible for preventing the replication of long palindromes. These observations lead to the proposal that cells may have evolved a post-replicative mechanism for the elimination and/or repair of large DNA secondary structures.

Two-base DNA hairpin-loop structures in vivo

In vitro studies have revealed that DNA hairpin-loops usually contain four unpaired bases. However, a small subset of sequences can form two-base loops. We have previously described an in vivo assay that is sensitive to tight loop formation and have set out to test whether DNA sequences known to form two-base loops in vitro also form tight loops in vivo. It is shown that the sequences 5'dCNNG and 5'dTNNA behave as predicted if they favour two-base loop formation in vivo, a result that is consistent with previously described in vitro studies. The ability of specific DNA sequences to form tight loops in vivo has implications for their potential to form transient structures involved in gene regulation, recombination and mutagenesis.

The effects of nucleotide sequence changes on DNA secondary structure formation in Escherichia coli are consistent with cruciform extrusion in vivo

The construction in bacteriophage lambda of a set of long DNA palindromes with paired changes in the central sequence is described. Identical palindrome centers were previously used by others to test the S-type model for cruciform extrusion in vitro. Long DNA palindromes prevent the propagation of carrier phage lambda on a wild-type host, and the sbcC mutation is sufficient to almost fully alleviate this inviability. The plaque areas produced by the palindrome containing phages were compared on an Escherichia coli sbcC lawn. Central sequence changes had a greater effect upon the plaque area than peripheral changes, implying that the residual palindrome-mediated inviability in E. coli sbcC is center-dependent and could be due to the formation of a cruciform structure. The results argue strongly that intrastrand pairing within palindromes is critical in determining their effects in vivo. In addition, the same data suggests that DNA loops in vivo may sometimes contain two bases only.

The effects of central asymmetry on the propagation of palindromic DNA in bacteriophage lambda are consistent with cruciform extrusion in vivo

The propagation of lambda phages carrying long perfect palindromes has been compared with that of phages carrying imperfect palindromes with small regions of central asymmetry. The perfect palindromes confer a more deleterious phenotype than those with central asymmetry and the severity of the phenotype declines with the length of asymmetry in the range from O to 27 base pairs. These results argue that a center-dependent reaction is involved in the phenotypic effects of palindromic DNA sequences, consistent with the idea that cruciform extrusion occurs in vivo.

Identification of sbcD mutations as cosuppressors of recBC that allow propagation of DNA palindromes in Escherichia coli K-12

The function of an open reading frame (orf-45) located upstream of the sbcC gene of Escherichia coli was investigated. Mutations that inactivate sbcC improve the ability to propagate lambda red gam phage that carry a palindromic sequence in their DNA. They also act with sbcB mutations as cosuppressors of the defects in recombination, DNA repair, and cell viability associated with recBC mutations. A 1,282-bp cassette encoding resistance to kanamycin was used to disrupt orf-45. The mutation, which has a polar effect on the expression of sbcC, allowed stable propagation of palindromic lambda phage even when the sbcC gene product was provided in trans. Additional nonpolar mutations in orf-45 were isolated on the basis of their ability to improve the growth of recBC sbcB strains. These mutations also confer resistance to mitomycin C, allow efficient recombination in Hfr crosses, and facilitate stable propagation of palindromic phage. It is concluded that the products of orf-45 and sbcC are functionally related. The orf-45 gene is therefore renamed sbcD.

The SbcCD protein of Escherichia coli is related to two putative nucleases in the UvrA superfamily of nucleotide-binding proteins

The derived amino-acid sequences of the proteins encoded by E. coli genes sbcC and sbcD have been compared with other protein sequences using computer assisted methods. This work has shown that SbcC and D, which inhibit the propagation of replicons containing long palindromic DNA sequences, are distantly related to two putative bacteriophage nucleases. These nucleases both comprise two polypeptide chains which are the products of genes 46 and 47 of bacteriophage T4 (gp 46 and gp 47) and genes D13 and D12 of bacteriophage T5 (gp D13 and gp D12). The comparisons reveal that SbcC, gp 46 and gp D13 are more closely related to each other than are SbcD, gp 47 and gp D12. SbcC appears to have undergone a partial duplication of an ancestral sequence. These proteins all contain motifs common to the superfamily of nucleotide-binding proteins that includes UvrA and the cystic fibrosis transmembrane regulator CFTR.

Persistent cryptosporidiosis in horses with severe combined immunodeficiency

Cryptosporidial infections were established in five young foals with severe combined immunodeficiency following oral administration of 10(8) Cryptosporidium parvum oocysts. All foals shed oocysts (average of 8 x 10(6) to 2 x 10(8)/g of feces) until death. Inflammation and C. parvum organisms were observed in the common bile duct, duodenum, jejunum, and ileum. Since foals with severe combined immunodeficiency lack functional T and B lymphocytes and are incapable of antigen-specific immune responses, they are well suited for evaluating the pathogenesis and treatment of persistent cryptosporidiosis.

Mini-Mu mediates deletion-inversions in vivo by intra-transposon transposition

We have shown that a mini-Mu can transpose into itself in vivo to generate a circle containing only transposon sequences. This deletion-inversion product, which has previously been observed in vitro, is formed by non-replicative transposition and has directly repeated Mu ends. It therefore cannot undergo further rounds of transposition and retains the two copies of the target sequence duplicated in the event. Thus we have been able to confirm that a mini-Mu can undergo non-replicative reactions in vivo and that these generate a 5 bp target site duplication, as has been shown to occur following replicative transposition and lysogenization with Mu.

Molecular organization of sbcC, a gene that affects genetic recombination and the viability of DNA palindromes in Escherichia coli K-12

The sbcC gene product of Escherichia coli interferes with the growth of a lambda red gam phage carrying a long palindrome in its DNA. This phenotype was used to identify recombinant plasmids harbouring the wild-type gene and to isolate sbcC mutant derivatives carrying Tn1000 insertions. Analysis of these plasmids located sbcC between proC and phoR at a slightly different position from that reported before (Lloyd, R.G. and Buckman, C. 1985, J. Bacteriol. 164, 836-844). Nucleotide sequencing revealed that the gene spans a DNA segment of 3.3 kb that encodes a poorly expressed protein of 118 kDa and which lies downstream of a gene of unknown function that encodes a polypeptide of 45 kDa. The amino acid sequence of SbcC contains a nucleotide binding fold similar to that in RecB and other recombination proteins.

Lymphocyte alterations in zinc-deficient calves with lethal trait A46

Lymphocyte numbers and activities were evaluated at 2, 4, 8 and 12 weeks of age in two calves with lethal trait A46 (A46), a genetic disorder affecting intestinal zinc absorption. Plasma zinc concentrations declined to subnormal by 3 weeks of age, after which anorexia, diarrhea, alopecia and hyperkeratosis occurred. Lymphocyte response to phytohemagglutinin-P (PHA), concanavalin A (Con A) and pokeweed mitogen (PWM) stimulation was variably reduced. CD4+ T-lymphocytes were subnormal on at least one observation period following onset of zinc deficiency, and relative numbers of B lymphocytes were decreased at 8 weeks. Secondary antibody responses to bacteriophage phi X 174 were significantly reduced. The results demonstrate that calves homozygous for the A46 trait have normal numbers of functional lymphocyte subpopulations at birth, and that the activity of their lymphocytes is altered once the calves become zinc deficient.

Slow replication of palindrome-containing DNA

Lambda red gam phage carrying a 571 base-pair palindrome are unviable in wild-type Escherichia coli hosts. By using de-methylation to study the fate of DNA strands introduced into E. coli, we have demonstrated that a decrease in the yield of palindrome-containing molecules with two newly synthesized strands can occur without any concomitant loss of replicated molecules containing input strands. This implies that the palindrome-containing DNA is not being destroyed even as a consequence of replication, but rather that its replication rate is reduced. These results demonstrate that a palindrome can mediate unviability without directing cleavage of its carrier replicon.

Viability of lambda phages carrying a perfect palindrome in the absence of recombination nucleases

In Escherichia coli in vitro constructions of perfect palindromes larger than 30 base pairs (bp) long have in general been unstable. A perfect palindrome has the unique possibility of forming a cruciform structure, and it is this feature which probably results in its instability. Negative supercoiling favours the formation of the cruciform conformation, which in turn causes the molecule to relax. This relaxation may render replicons containing large perfect palindromes inviable. An alternative hypothesis for inviability has been that the cruciform interferes with replication by favouring strand switching by polymerase I. Here we show that the simultaneous absence of two recombination nucleases, the recBC product, exonuclease V, and the sbcB product, exonuclease I, confers viability on a derivative of phage lambda carrying a perfect palindrome of inverted repeat length 1,600 bases. This observation suggests a third hypothesis--that nucleolytic cleavage of the cruciform is responsible for the inviability of the phage. Such an activity has been shown in vitro for T4 exonuclease VII.