Antibody Responses to DNA in Normal Immunity and Aberrant Immunity

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Clinical and Diagnostic Laboratory Immunology, January 1998, p. 1-6, Vol. 5, No. 1
1071-412X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

MINIREVIEW
Antibody Responses to DNA in Normal Immunity and Aberrant Immunity

David S. Pisetsky^*

Rheumatology Section, Medical Research Service, Durham Veterans Affairs Medical Center, and Division of Rheumatology, Allergy and Clinical Immunology, Duke University Medical Center, Durham, North Carolina 27705

	INTRODUCTION

Top Introduction Conclusion References

Among antibodies directed to biological macromolecules, antibodies to DNA (anti-DNA) are unique in their association withthe pathological state. These antibodies are the serologic hallmarkof systemic lupus erythematosus (SLE) and serve as markers fordiagnosis and prognosis. Furthermore, as indicated by the correlationof antibody levels with disease activity, anti-DNA play a majorrole in the pathogenesis of lupus nephritis. The close associationof anti-DNA with SLE has implied that immune responses to DNAare an exclusive feature of autoimmune disease (5).

Although assessment of anti-DNA remains clinically valuable, recent data suggest that the current conceptualization of anti-DNAneeds revision. These data provide a new perspective on lupusserology and show clearly that production of anti-DNA occurs inhosts with normal immunity as well as those with aberrant immunity.The salient feature of the production of normal anti-DNA, however,is its specificity for bacterial DNA. Furthermore, as shown instudies with both mice and humans, antibody induction is justone facet of bacterial DNA's far-reaching immunological properties.This review considers current information on antibody responsesto DNA, focusing on their role in SLE as well as normal host defense.

	IMMUNOLOGY OF SLE

As a systemic autoimmune disorder, SLE is associated with protean manifestations that can involve essentially every organin the body. These manifestations occur unpredictably and varyin frequency and intensity among patients (30). Despite themarked heterogeneity in clinical features, patients with SLE almostinvariably express antibodies to components of the cell nucleus(antinuclear antibodies). These antibodies are highly diverseand target a host of nuclear macromolecules. Of these antibodies,however, only two, anti-DNA and anti-Sm antibodies, representcriteria for disease classification. By conventional assays, theseantibodies are found essentially only in the sera of patientswith SLE. Whereas the levels of anti-DNA vary during the courseof disease, anti-Sm antibody levels remain more static, limitingtheir utility in patient monitoring (25, 41).

Of the manifestations of SLE, anti-DNA are most closely linked with glomerulonephritis. The capacity of anti-DNA to causerenal damage has been confusing since DNA, like other nuclearantigens, is ubiquitous among cells and is sequestered intracellularly.Following injury or death, however, cells may release DNA, providinga source of extracellular antigen that can form phlogistic complexes.Since DNA exists in nucleosomes inside the cell, any releasedantigens are likely to exist as complexes whose protein componentsmay also influence pathogenicity (5, 6).

While the mechanisms of lupus nephritis are not well understood, anti-DNA may provoke renal injury by one of four mechanisms:formation of circulating immune complexes, in situ immune complexformation in the kidney with DNA trapped in the glomerulus, cross-reactivebinding to a non-DNA glomerular antigen, and penetration of antibodiesinto glomerular cells. Evidence of the pathogenicity of anti-DNAcomes from both the correlation of the levels of anti-DNA withrenal activity as well the provocation of nephritis in animalsby infusion of preparations of anti-DNA (6, 34, 42, 46,47). Other manifestations of SLE are less clearly related toanti-DNA, although they may result from other pathogenic autoantibodies.

	ANTIGENICITY OF DNA

Because of the role of anti-DNA in the pathogenesis of disease, assays for antibody measurement have been directed to twomajor goals: (i) providing specific markers for patient diagnosisand (ii) providing sensitive markers for disease activity. Underlyingthe use of these assays has been the notion that antibodies thatbind with high affinities to double-stranded DNA (dsDNA) are themost specific and reliable for diagnosis. Assays that detect antibodiesto single-stranded DNA (ssDNA), however, generally yield a higherfrequency of positive responses among patient sera, most likelybecause of the detection of a broader array of specificities,including low-affinity antibodies (1, 19, 25, 41).

The distinction between antibodies to ssDNA and antibodies to dsDNA, while often emphasized in studies on serology, is somewhatartificial because many antibodies can bind to both antigenicDNA forms. Indeed, only a minority of antibodies have exclusivespecificity for either ssDNA or dsDNA. The ability to bind toboth DNA forms suggests reactivity with determinants on the phosphodiesterbackbone that can be present on either the ssDNA or the dsDNAantigen. In its antigenic properties, ssDNA may be more activethan dsDNA since it is structurally flexible and can interactmore readily with antibody in solution than the more rigid androd-like dsDNA (3, 4, 39).

Assays for anti-DNA have used DNA from only a limited number of species on the assumption that all DNAs are antigenicallyalike by virtue of their backbone and, in the case of dsDNA, theirdisplay of the classic Watson-Crick double helix, also calledB DNA. This assumption was never investigated in any detail, inpart, because most assays for anti-DNA perform well in the clinicand produce comparable results for diagnosis and disease assessment.

	INDUCTION OF ANTI-DNA

The strong association of anti-DNA with autoimmunity has been confirmed in experiments replicating lupus by immunizing normalmice with DNA. Even when coupled to a protein carrier and presentedin adjuvant, mammalian DNA fails to elicit significant antibodyproduction (22). This failure is in contrast to animal modelsof disease induced by immunization with protein autoantigens (e.g.,collagen-induced arthritis or experimental allergic encephalomyelitis),suggesting that DNA differs from other biological macromoleculesin its immunological capacity.

The weak activity of DNA in immunization models is in contrast to its apparent strong activity in spontaneous disease. Thus,as shown by molecular analysis of monoclonal antibodies from patientsas well as mice with lupus, anti-DNA bear the features expectedfor an antigen-specific response to DNA. These features includeclonal expression, V-region somatic mutations, and a high contentof heavy-chain CDR3 arginines. Since arginine can bind to DNAby both electrostatic interactions and hydrogen bonds, these findingshave suggested that anti-DNA in SLE are selected by a receptormechanism, with DNA being the relevant antigen in vivo (31).These observations have further suggested that SLE representsa unique setting for the expression of anti-DNA, with flagrantimmunoregulatory disturbances allowing for immune recognitionof an otherwise inert molecule.

	IMMUNOLOGICAL PROPERTIES OF BACTERIAL DNA

While this conceptualization of DNA's immunological properties has long dominated investigations of SLE, it is neverthelessflawed. As recent data show, DNA, rather than being uniform andbland, is immunologically complex, with sequence microheterogeneitycontributing to a variety of immunological properties. Indeed,bacterial DNA, by virtue of characteristic sequence motifs, canactivate the immune system and drive the production of antibodiesto sequential as opposed to backbone DNA determinants (26, 27).In its antigenic properties, foreign DNA resembles foreign proteinsin that it has an epitope structure based on nonconserved sequencesthat are absent from the host and that are therefore not subjectto tolerance.

The existence of antibody responses to bacterial DNA was long missed because of a failure to survey an adequate number ofDNAs for their activities with sera from normal hosts as wellas sera from hosts with SLE. As many studies showed, sera fromhosts with SLE recognize predominantly backbone determinants whichcan be presented by any DNA. Among the commonly used assays, variousDNA sources were in fact used to measure antibodies to these backbonedeterminants. Since these assays effectively distinguished serafrom normal subjects from sera from patients with SLE, there waslittle reason to suspect that differences in the behavior of DNAfrom other sources.

The first clear evidence for the antigenic heterogeneity of DNA came in an analysis of binding of sera to a panel of DNAsfrom various mammalian and bacterial species (15). The goalof these investigations was to determine whether the source ofDNA antigen could influence the quantitative detection of antibodiesin an enzyme-linked immunosorbent assay. These effects could reflecteither the influence of a base sequence on the backbone orientationor the presence in the sera of patients with SLE antibodies thatbound to the sequence as well as to the backbone. A study by Stollaret al. (40) raised these possibilities, although these observationswere never pursued in detail.

As shown by Karonous et al. (15), sera from patients with SLE generally bind to all DNAs equivalently, consistent with theimportance of the backbone to antigenicity. In marked contrastto previous studies, however, those investigators found that normalhuman serum (NHS) shows highly significant binding to DNA fromcertain bacteria, including Staphylococcus epidermidis and Micrococcuslysodeikticus. These antibodies were of the immunoglobulin G (IgG)isotype and were present at levels comparable to those in thesera of patients with SLE. Despite binding to these bacterialDNAs, NHS did not bind to mammalian DNA and therefore differedfrom natural autoantibodies which are IgM and bind to DNA broadly(15).

Subsequent studies on the specificities of these responses have demonstrated that NHS can bind to DNA from many bacterialspecies, although, interestingly, they do not bind to DNA fromEscherichia coli. This binding is very species specific. Thus,antibodies that bind to the DNA of one bacterial species do notbind cross-reactively to the DNA of another bacterial species(48). Furthermore, antibody reactivity extends to viral DNA,since NHS binds to DNA from BK polyomavirus (7). While notanticipated from previous work, anti-DNA in NHS can easily beexplained as a specific response, induced during ordinary encounterswith bacteria or viruses, to sites on foreign DNA that differin sequence from the host DNA.

As shown in an analysis of antibodies to Micrococcus DNA, anti-DNA in NHS differ from anti-DNA in sera from patients withSLE in important immunochemical properties. Thus, anti-DNA inNHS are primarily IgG2 and show restriction to the $kappa$ light chain;in contrast, anti-DNA in sera from patients with SLE are primarilyIgG1 and have more equivalent levels of expression of $kappa$ and $lambda$ .The predominance of IgG2 is reminescent of the response to bacterialpolysaccharide antigens and a T-cell-independent response. Otherdifferences between anti-DNA in NHS and sera from patients withSLE include the high degrees of specificity and avidity of anti-DNAin NHS and the role of nonionic interactions in antibody binding(32, 33). Like anti-DNA in sera from patients with SLE, however,anti-DNA in NHS can bind both ssDNA and dsDNA (2). Together,these properties indicate that anti-DNA in NHS bind selectivelyto nonconserved sequences on foreign DNA. These antibodies areprobably not pathogenic because of their isotype, which does notfix complement well, and the limited availability of their targetantigen, which should disappear as the infection resolves.

To test the possibility that bacterial DNA can drive antibody production, normal mice were immunized with bacterial DNA ascomplexes with methylated bovine serum albumin in complete Freund'sadjuvant. Although mammalian DNA elicits a limited response tossDNA but not to dsDNA under these conditions, bacterial DNA inducesabundant antibody production. By using bacterial dsDNA as theimmunogen, the induced antibodies bind only to bacterial dsDNAwithout cross-reactivity to mammalian dsDNA. In contrast, immunizationwith bacterial ssDNA leads to a cross-reactive response to bothmammalian and bacterial ssDNAs (10, 11).

	IMMUNOSTIMULATION BY BACTERIAL DNA

Although the immunogenicity of bacterial DNA could reflect its content of nonconserved sequences, subsequent studies haveshown that bacterial DNA has immunostimulatory properties thatenhance responsiveness. These properties were initially discoveredin studies of the antitumor effects of extracts of mycobacteria.These extracts promoted tumor resistance by stimulation of naturalkiller cell activity through the action of alpha/beta interferon(IFN- $alpha$ / $beta$ ) and IFN- $gamma$ . As shown by biochemical fractionation studies,mycobacterial DNA is the active component of these extracts, withfurther studies demonstrating that DNAs from many different bacteriaproduce the same stimulatory effects (43, 49, 50).

In a series of elegant experiments with cloned DNA, cytokine induction was shown to result from sequence motifs characteristicof bacterial DNA (16, 51). These sequences, called CpG motifsor immunostimulatory sequences (ISSs), have the general structureof two 5' purines, an unmethylated CpG dinucleotide, and two 3'purines. ISSs occur in bacterial DNA much more frequently thanin mammalian DNA for at least two reasons. In mammalian DNA, cytosineis commonly methylated. Furthermore, cytosine and guanosine occurin tandem much less frequently than predicted by base composition,a phenomenon known as CpG suppression (13, 20). While thebiological advantages of cytosine methylation and CpG suppressionare speculative, the difference in the occurrence of mammalianand bacterial DNAs creates a system for immune recognition.

The immunostimulatory activities of bacterial DNA are varied and encompass the mitogenicity of B cells and the induction ofcytokines including IFN- $alpha$ / $beta$ , IFN- $gamma$ , tumor necrosis factor alpha,interleukin 6 (IL-6), and IL-12 (17, 21, 23). Together,these activities resemble those of endotoxin and suggest thatbacterial DNA may have a similar role in innate immunity. In currentterminology, bacterial DNA may function as a danger signal. Sincethese activities poise the immune system for responsiveness, theymay explain the effectiveness of bacterial DNA as an immunogen.The CpG motifs are common to all bacterial DNAs, however, andmust differ from the target sequences of anti-DNA in NHS whichare variably present in bacterial DNAs, depending on the species.

	ROLE OF BACTERIAL DNA IN SLE

The observations described above suggest a plausible mechanism by which bacterial DNA can drive antibody responses in normalimmunity and aberrant immunity. In normal individuals, bacterialDNA can elicit antibodies that are highly specific for nonconservedsequential determinants on the DNA from infecting or colonizingorganisms. These antibodies may arise from a T-cell-independentmechanism, reflecting the ability of bacterial DNA to both cross-linkB-cell surface receptors and induce cytokine production. In theirinduction, these antibodies would resemble antibodies to bacterialcarbohydrate. While T-cell-dependent induction of antibodies tobacterial DNA is possible, it does not appear to be a major mechanism.The preference for T-cell independence may result from the patternof cytokines produced in the setting of bacterial infection aswell as the manner in which foreign DNA is presented to the immunesystem.

In contrast to the situation in normal immunity, in SLE, bacterial DNA may drive the production of antibodies to conservedbackbone determinants by a T-cell-dependent mechanism. The switchfrom T-cell independence to T-cell dependence may result fromthe presence of aberrantly expressed helper T cells that arisein SLE because of abnormalities of tolerance, T-cell activation,or the cytokine mileu. In this regard, SLE is associated withan expansion of DNA-binding B cells. These B cells can bind toDNA-protein complexes and serve as antigen-presenting cells. Thesecells may facilitate a T-cell-dependent response to DNA as wellas to the attached proteins, a mechanism that does not requiredirect T-cell recognition of DNA.

As these considerations suggest, encounters with bacterial DNA may be particularly hazardous in SLE because this antigen displaysboth self- and non-self-determinants. The self-determinants arethe backbone, while the non-self-determinants are the sequences.In SLE, responses to the self-determinants may reflect a generaltendency for recognition of conformational epitopes as opposedto sequential epitopes. This tendency, which would heighten andbroaden cross-reactivity, is also manifest in the response toprotein autoantigens such as Sm, Ro, and La. Autoantibodies tothese proteins bind to conserved sites on these antigens, leadingto cross-reactivity with antigens from species such as rabbitsor cows. Furthermore, autoantibodies in SLE are less likely tobind to peptidic determinants than antibodies induced in normalanimals by intentional immunization with self-antigen (41).

In SLE, the preferential recognition of conformational determinants may reflect tolerance abnormalities that allow for theretention of B cells that would be deleted or anergized in normalindividuals. These B cells may display V gene sequences that promotecross-reactivity and the binding to conformational determinantson self-antigen and foreign antigen. Evidence for this model comesfrom experiments assessing the response of NZB/NZW autoimmunemice to immunization with bacterial dsDNA. In these mice, bacterialDNA induces cross-reactive autoantibodies that bind to self-DNAas well as foreign dsDNA under conditions in which immunizationelicits antibodies specific for bacterial dsDNA in normal mice.Importantly, the induced antibodies from the autoimmune mice differfrom those from normal mice in certain sequences (e.g., CDR3 arginines)considered important for binding to dsDNA. CDR3 arginines occurrarely in antibodies from normal mice, possibly because theirpresence leads to DNA binding and the induction of tolerance (8,9).

In addition to the production of autoantibodies to dsDNA, SLE may be associated with a diminution in the production of antibodiesspecific for bacterial DNA. As shown by immunoaffinity techniques,absorption of sera from hosts with SLE with mammalian DNA eliminatesessentially all reactivity to both mammalian and bacterial DNA.In contrast, absorption of normal sera with mammalian DNA doesnot affect the response to bacterial DNA. These findings indicatea deficiency in antibodies specific for foreign DNA in SLE (29).This deficiency could be secondary to a shift toward recognitionof conserved DNA determinants during ongoing autoimmune disease.Alternatively, the deficiency may be a primary abnormality and,indeed, a factor predisposing an individual to SLE. Thus, in theabsence of a specific antibody response in SLE, bacterial DNAmay persist in the system, leading to prolonged immune stimulationand the emergence of cross-reactive autoantibodies. This situationwould be analogous to the induction of autoimmunity in animalsby repetitive treatment with polyclonal B-cell activators suchas lipopolysaccharide (14).

	ROLE OF IMMUNOSTIMULATORY DNA IN INFECTION

The discovery of bacterial DNA's immunological properties has broad implications, both theoretical and practical. Certainly,the central dogma of SLE needs revision and the simple equationanti-DNA = autoimmunity needs to be discarded. In the future,any model of production of anti-DNA in SLE must take into accountthe immunological diversity of DNA and the existence of responsesof anti-DNA in both normal immunity as well as SLE. As studieswith both humans and mice suggest, the difference in DNA recognitionin normal immunity and SLE may reside at the level of specificityrather than responsiveness. As such, production of autoantibodiesto DNA may represent a distortion in the response to an ordinarilyactive foreign antigen rather than the acquisition of the responseto an ordinarily inactive self-antigen.

While NHS contains antibodies to many different bacterial and viral DNAs, the rules for antigenicity are not known. It isnot clear why NHS binds well to DNAs from certain bacteria andnot to DNAs from other bacteria. These differences could reflectdifferences in the number and structure of antigenic sequences,the content of ISSs, or the location and extent of contact ofthe bacterium with its host. In this regard, it is reasonableto inquire whether antibody responses to bacterial DNA could beused diagnostically, with elevation of antibody titers to a bacterialDNA antigen being indicative of infection. This serologic approachcould be especially useful for evaluating infections caused byorganisms that are difficult to culture.

The role of immunostimulatory DNA in the pathogenesis of infection is a topic of emerging interest. While purified bacterialDNA as well as synthetic ISSs have impressive immunostimulatoryactivities, the relevance of these activities to human diseaseis much less certain. Recent studies indicate, for example, thatbacterial DNA can cause septic shock and can promote serious pulmonaryinflammation when it is administered to animals (36, 37).Determining whether bacterial DNA exerts these effects duringordinary infection will be a major undertaking, since bacteriahave many immunostimulatory molecules (e.g., lipopolysaccharide)with similar activity. If, during infection, bacterial DNA, aloneor in synergy with other dangerous molecules, provokes harmfulreactions, then the use of strategies that can speed its eliminationmay be worthwhile for future antimicrobial therapy.

The consequences of exposure to DNA to animals and humans may vary somewhat among species. Thus, under ordinary culture conditionsin vitro, bacterial DNA or CpG motifs fail to stimulate humanB cells, although they effectively trigger murine B cells. Inboth humans and mice, however, bacterial DNA can induce cytokineproduction (26, 27). These differences in response patternsmay reflect differences in binding and uptake of DNA by cellsas well as intrinsic differences in cell activation. The inductionof cytokines by bacterial DNA nevertheless appears to be a commonmode of action in both humans and animals, suggesting that foreignDNA can serve the same immediate role in promoting inflammationand inducing host defense in humans as well as animals.

	IMPLICATIONS FOR DNA THERAPEUTICS

While the involvement of bacterial DNA in infection is speculative, the medicinal use of DNA will expose the host to ISSs.Indeed, these ISSs may be key to the success of some of theseapproaches. Among recent advances in DNA therapeutics, DNA vaccineshave attracted enormous interest because of their potential toinduce responses against a broad range of human pathogens. Thesevaccines are plasmids that encode a protein to be targeted forprotective immunity. These vaccines are administered as nakedDNA by the intramuscular or intradermal route and are taken upinto cells and induce both CD4 and CD8 responses (24, 45).While the trafficking of the plasmids in vivo is poorly understood,vaccine responses ultimately involve bone marrow-derived antigen-presentingcells.

Since they are propagated in bacteria, vaccine vectors are potentially an important source of ISSs. These vectors displaythe bacterial pattern of DNA methylation and, in addition, havethe bacterial sequences needed for replication or antibiotic resistance;other foreign DNA sequences may relate to the encoded protein.As such, these vectors can exert adjuvant properties and, throughthe mediation of IL-12, IFN- $alpha$ / $beta$ , and IFN- $gamma$ , promote Th1 responses.As shown in recent studies, plasmid-borne ISSs may be key to theinduction of cellular as well as antibody responses. Indeed, thepotencies of these vaccines may reflect their ability to serveas internal adjuvants as well as provide an intracellular sourceof foreign protein for processing and presentation to T cells(18, 35).

Although ISSs can facilitate vaccination, they may also cause adverse reactions. These reactions include local inflammation,nonspecific immune stimulation, and skewing of responses to aTh1 pattern. Depending on the setting, these reactions could bedetrimental and could, for example, potentiate autoimmunity orimpair the response to infecting organisms. Furthermore, plasmidvaccines could induce the production of anti-DNA, although theoutcome of any induced response would likely vary depending onthe immune status of the host. In a normal individual, the vaccinecould induce antibodies specific for the plasmid, which, likethose in normal individuals, would be nonpathogenic. On the otherhand, in an individual predisposed to autoimmunity, the inducedantibodies could have cross-reactive autoantibody activity.

The likelihood of adverse reactions from a DNA vaccine appears low, however, since bacterial DNA is a normally encounteredantigen and the amount of DNA used for vaccination is small. Indeed,initial experience with DNA vaccines in both animals and humanssuggests that naked DNA is safe. Strategies involving other vaccinecomponents, however, could be more problematic. Agents such aslipofectin, which can coat DNA and promote its uptake into cells,can amplify immunostimulatory effects and increase the likelihoodof inflammatory or autoimmune reactions (52). In this regard,similar issues of safety pertain to the use of naked DNA for genetherapy.

Antisense agents are another innovative form of nucleic acid therapy that may provoke immunostimulatory effects. These agentsare short oligonucleotides complementary to an mRNA sequence fora protein whose functional elimination would be therapeutic; mRNAbinding by these oligonucleotides prevents translation or promotesdegradation. The range of proteins postulated for use in antisensetherapy is enormous and varies from oncogenes to viral proteinsto cellular macromolecules (e.g., cytokines or adhesion molecules)whose overexpression can promote disease. Since phosphodiesteroligonucleotides are rapidly degraded or have difficulty in penetratingcells, antisense agents are usually nucleic acid derivatives withmodified backbones that resist degradation or that have an enhancedpermeation ability (38, 44).

Because of its target sequence, an antisense agent could theoretically display an ISS and therefore induce nonspecific immuneactivation. Furthermore, some nucleic acid derivatives have immunostimulatoryproperties that may not simply reflect the display of an ISS.Phosphorothioates have been tested extensively for in vitro andin vivo antisense activities and have a sulfur substitution forone of the nonbridging oxygens in the phosphodiester backbone(44). In general, an ISS in phosphorothioate chemistry is muchmore active than the comparable phosphodiester. There is evidence,moreover, that sequences other than the classic CpG motifs mayhave immune-activating properties when they are synthesized asphosphorothioates (28). These activities may reflect the uniqueproperties of the phosphorothioate backbone, the long half-livesof these compounds, and different patterns of intracellular trafficking.Since antisense agents can be used as antimicrobial or antiviralagents in infected individuals, the potential for synergisticinteraction with products such as endotoxin could also complicatetheir use (12).

	CONCLUSION

Top Introduction Conclusion References

In the past few years investigators have witnessed a revolution in the conceptualization of immune responses to DNA. Withthe recognition of the epitope structure and immunostimulatoryproperties of bacterial DNA, DNA has been transformed from a uniformand inert molecule into a powerful presence whose activities areextensive and pervasive. The coming years should be exciting asinvestigators elucidate these immune activities and develop techniquesfor their manipulation in the treatment and prevention of humandisease.

	ACKNOWLEDGMENTS

This work was supported by the VA Medical Research Service Merit Review grant and the VA Research Center on AIDS and HIV Infection.

	FOOTNOTES

^* Mailing address: VA Medical Center, Box 151G, 508 Fulton St., Durham, NC 27705. Phone: (919) 286-6835. Fax: (919) 286-6891.E-mail: dpiset{at}acpub.duke.edu.

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32. Robertson, C. R., and D. S. Pisetsky. 1992. Specificity analysis of antibodies to single-stranded micrococcal DNA in the sera of normal human subjects and patients with systemic lupus erythematosus. Clin. Exp. Rheum. 10:589-594[Medline].

33. Robertson, C. R., G. S. Gilkeson, M. M. Ward, and D. S. Pisetsky. 1992. Patterns of heavy and light chain utilization in the antibody response to single-stranded bacterial DNA in normal human subjects and patients with systemic lupus erythematosus. Clin. Immunol. Immunopathol. 62:25-32[Medline].

34. Sabbaga, J., O. G. Pankewycz, V. Lufft, R. S. Schwartz, and M. P. Madaio. 1990. Cross-reactivity distinguishes serum and nephritogenic anti-DNA antibodies in human lupus from their natural counterparts in normal serum. J. Autoimmun. 3:215-235[Medline].

35. Sato, Y., M. Roman, H. Tighe, D. Lee, M. Corr, M.-D. Nguyen, G. J. Silverman, M. Lotz, D. A. Carson, and E. Raz. 1996. Immunostimulatory DNA sequences necessary for effective intradermal gene immunization. Science 273:352-354[Abstract].

36. Schwartz, D. A., T. J. Quinn, P. S. Thorne, S. Sayeed, A.-K. Yi, and A. M. Krieg. 1997. CpG motifs in bacterial DNA cause inflammation in the lower respiratory tract. J. Clin. Invest. 100:68-73[Medline].

37. Sparwasser, T., T. Miethke, G. Lipford, K. Borschert, H. Hacker, K. Heeg, and H. Wagner. 1997. Bacterial DNA causes septic shock. Nature 386:336-337[Medline].

38. Stein, C. A., and Y.-C. Cheng. 1993. Antisense oligonucleotides as therapeutic agents $---$ is the bullet really magical? Science 261:1004-1012[Abstract/Free Full Text].

39. Stollar, B. D. 1994. Molecular analysis of anti-DNA antibodies. FASEB J. 8:337-342[Abstract].

40. Stollar, D., L. Levine, and J. Marmur. 1962. Antibodies to denatured deoxyribonucleic acid in lupus erythematosus serum. II. Characterization of antibodies in several sera. Bioch. Biophys. Acta 61:7-18.

41. Tan, E. M. 1989. Antinuclear antibodies: diagnostic markers for autoimmune diseases and probes for cell biology. Adv. Immunol. 44:93-151[Medline].

42. Termaat, R.-M., K. J. M. Assmann, H. B. P. M. Dijkman, F. V. Gompel, R. J. T. Smeenk, and J. H. M. Berden. 1992. Anti-DNA antibodies can bind to the glomerulus via two distinct mechanisms. Kidney Int. 42:1363-1371[Medline].

43. Tokunaga, T., H. Yamamoto, S. Shimada, H. Abe, T. Fukuda, Y. Fujisawa, Y. Furutani, O. Yano, T. Kataoka, T. Sudo, N. Makiguchi, and T. Suganuma. 1984. Antitumor activity of deoxyribonucleic acid fraction from Mycobacterium bovis BCG. I. Isolation, physicochemical characterization, and antitumor activity. J. Natl. Cancer Inst. 72:955-962.

44. Uhlmann, E., and A. Peyman. 1990. Antisense oligonucleotides: a new therapeutic principle. Chem. Rev. 90:544-584.

45. Ulmer, J. B., J. J. Donnelly, S. E. Parker, G. H. Rhodes, P. L. Felgner, V. J. Dwarki, S. H. Gromkowski, R. R. Deck, C. M. DeWitt, A. Friedman, L. A. Hawe, K. R. Leander, D. Martinez, H. C. Perry, J. W. Shiver, D. L. Montgomery, and M. A. Liu. 1993. Heterologous protection against influenza by injection of DNA encoding a viral protein. Science 259:1745-1749[Abstract/Free Full Text].

46. Valerio, R. D., K. A. Bernstein, E. Varghese, and J. B. Lefkowith. 1995. Murine lupus glomerulotropic monoclonal antibodies exhibit differing specificities but bind via a common mechanism. J. Immunol. 155:2258-2268[Abstract].

47. Vlahakos, D., M. H. Foster, A. A. Ucci, K. J. Barrett, S. K. Datta, and M. P. Madaio. 1992. Murine monoclonal anti-DNA antibodies penetrate cells, bind to nuclei, and induce glomerular proliferation and proteinuria in vivo. J. Am. Soc. Nephrol. 2:1345-1354[Abstract].

48. Wu, Z.-Q., D. Drayton, and D. S. Pisetsky. 1997. Specificity and immunochemical properties of antibodies to bacterial DNA in sera of normal human subjects and patients with systemic lupus erythematosus (SLE). Clin. Exp. Immunol. 109:27-31[Medline].

49. Yamamoto, S., E. Kuramoto, S. Shimada, and T. Tokunaga. 1988. In vitro augmentation of natural killer cell activity and production of interferon- $alpha$ / $beta$ and - $gamma$ with deoxyribonucleic acid fraction from Mycobacterium bovis BCG. Jpn. J. Cancer Res. 79:866-873[Medline].

50. Yamamoto, S., T. Yamamoto, S. Shimada, E. Kuramoto, O. Yano, T. Kataoka, and T. Tokunaga. 1992. DNA from bacteria, but not from vertebrates, induces interferons, activates natural killer cells and inhibits tumor growth. Microbiol. Immunol. 36:983-997[Medline].

51. Yamamoto, S., T. Yamamoto, T. Kataoka, E. Kuramoto, O. Yano, and T. Tokunaga. 1992. Unique palindromic sequences in synthetic oligonucleotides are required to induce INF and augment INF-mediated natural killer activity. J. Immunol. 148:4072-4076[Abstract].

52. Yamamoto, T., S. Yamamoto, T. Kataoka, and T. Tokunaga. 1994. Lipofectin of synthetic oligodeoxyribonucleotide having a palindromic sequence of AACGTT to murine splenocytes enhances interferon production and natural killer activity. Microbiol. Immunol. 38:831-836[Medline].

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29.	Pisetsky, D. S., and D. M. Drayton. 1997. Deficient expression of antibodies specific for bacterial DNA by patients with systemic lupus erythematosus. Proc. Assoc. Am. Phys. 109:237-244[Medline].
30.	Pisetsky, D. S., G. G. Gilkeson, and E. W. St. Clair. 1997. Systemic lupus erythematosus. Diagnosis and treatment. Med. Clin. N. Am. 81:113-128[Medline].
31.	Radic, M. Z., and M. Weigert. 1994. Genetic and structural evidence for antigen selection of anti-DNA antibodies. Annu. Rev. Immunol. 12:487-520[Medline].
32.	Robertson, C. R., and D. S. Pisetsky. 1992. Specificity analysis of antibodies to single-stranded micrococcal DNA in the sera of normal human subjects and patients with systemic lupus erythematosus. Clin. Exp. Rheum. 10:589-594[Medline].
33.	Robertson, C. R., G. S. Gilkeson, M. M. Ward, and D. S. Pisetsky. 1992. Patterns of heavy and light chain utilization in the antibody response to single-stranded bacterial DNA in normal human subjects and patients with systemic lupus erythematosus. Clin. Immunol. Immunopathol. 62:25-32[Medline].
34.	Sabbaga, J., O. G. Pankewycz, V. Lufft, R. S. Schwartz, and M. P. Madaio. 1990. Cross-reactivity distinguishes serum and nephritogenic anti-DNA antibodies in human lupus from their natural counterparts in normal serum. J. Autoimmun. 3:215-235[Medline].
35.	Sato, Y., M. Roman, H. Tighe, D. Lee, M. Corr, M.-D. Nguyen, G. J. Silverman, M. Lotz, D. A. Carson, and E. Raz. 1996. Immunostimulatory DNA sequences necessary for effective intradermal gene immunization. Science 273:352-354[Abstract].
36.	Schwartz, D. A., T. J. Quinn, P. S. Thorne, S. Sayeed, A.-K. Yi, and A. M. Krieg. 1997. CpG motifs in bacterial DNA cause inflammation in the lower respiratory tract. J. Clin. Invest. 100:68-73[Medline].
37.	Sparwasser, T., T. Miethke, G. Lipford, K. Borschert, H. Hacker, K. Heeg, and H. Wagner. 1997. Bacterial DNA causes septic shock. Nature 386:336-337[Medline].
38.	Stein, C. A., and Y.-C. Cheng. 1993. Antisense oligonucleotides as therapeutic agents $---$ is the bullet really magical? Science 261:1004-1012[Abstract/Free Full Text].
39.	Stollar, B. D. 1994. Molecular analysis of anti-DNA antibodies. FASEB J. 8:337-342[Abstract].
40.	Stollar, D., L. Levine, and J. Marmur. 1962. Antibodies to denatured deoxyribonucleic acid in lupus erythematosus serum. II. Characterization of antibodies in several sera. Bioch. Biophys. Acta 61:7-18.
41.	Tan, E. M. 1989. Antinuclear antibodies: diagnostic markers for autoimmune diseases and probes for cell biology. Adv. Immunol. 44:93-151[Medline].
42.	Termaat, R.-M., K. J. M. Assmann, H. B. P. M. Dijkman, F. V. Gompel, R. J. T. Smeenk, and J. H. M. Berden. 1992. Anti-DNA antibodies can bind to the glomerulus via two distinct mechanisms. Kidney Int. 42:1363-1371[Medline].
43.	Tokunaga, T., H. Yamamoto, S. Shimada, H. Abe, T. Fukuda, Y. Fujisawa, Y. Furutani, O. Yano, T. Kataoka, T. Sudo, N. Makiguchi, and T. Suganuma. 1984. Antitumor activity of deoxyribonucleic acid fraction from Mycobacterium bovis BCG. I. Isolation, physicochemical characterization, and antitumor activity. J. Natl. Cancer Inst. 72:955-962.
44.	Uhlmann, E., and A. Peyman. 1990. Antisense oligonucleotides: a new therapeutic principle. Chem. Rev. 90:544-584.
45.	Ulmer, J. B., J. J. Donnelly, S. E. Parker, G. H. Rhodes, P. L. Felgner, V. J. Dwarki, S. H. Gromkowski, R. R. Deck, C. M. DeWitt, A. Friedman, L. A. Hawe, K. R. Leander, D. Martinez, H. C. Perry, J. W. Shiver, D. L. Montgomery, and M. A. Liu. 1993. Heterologous protection against influenza by injection of DNA encoding a viral protein. Science 259:1745-1749[Abstract/Free Full Text].
46.	Valerio, R. D., K. A. Bernstein, E. Varghese, and J. B. Lefkowith. 1995. Murine lupus glomerulotropic monoclonal antibodies exhibit differing specificities but bind via a common mechanism. J. Immunol. 155:2258-2268[Abstract].
47.	Vlahakos, D., M. H. Foster, A. A. Ucci, K. J. Barrett, S. K. Datta, and M. P. Madaio. 1992. Murine monoclonal anti-DNA antibodies penetrate cells, bind to nuclei, and induce glomerular proliferation and proteinuria in vivo. J. Am. Soc. Nephrol. 2:1345-1354[Abstract].
48.	Wu, Z.-Q., D. Drayton, and D. S. Pisetsky. 1997. Specificity and immunochemical properties of antibodies to bacterial DNA in sera of normal human subjects and patients with systemic lupus erythematosus (SLE). Clin. Exp. Immunol. 109:27-31[Medline].
49.	Yamamoto, S., E. Kuramoto, S. Shimada, and T. Tokunaga. 1988. In vitro augmentation of natural killer cell activity and production of interferon- $alpha$ / $beta$ and - $gamma$ with deoxyribonucleic acid fraction from Mycobacterium bovis BCG. Jpn. J. Cancer Res. 79:866-873[Medline].
50.	Yamamoto, S., T. Yamamoto, S. Shimada, E. Kuramoto, O. Yano, T. Kataoka, and T. Tokunaga. 1992. DNA from bacteria, but not from vertebrates, induces interferons, activates natural killer cells and inhibits tumor growth. Microbiol. Immunol. 36:983-997[Medline].
51.	Yamamoto, S., T. Yamamoto, T. Kataoka, E. Kuramoto, O. Yano, and T. Tokunaga. 1992. Unique palindromic sequences in synthetic oligonucleotides are required to induce INF and augment INF-mediated natural killer activity. J. Immunol. 148:4072-4076[Abstract].
52.	Yamamoto, T., S. Yamamoto, T. Kataoka, and T. Tokunaga. 1994. Lipofectin of synthetic oligodeoxyribonucleotide having a palindromic sequence of AACGTT to murine splenocytes enhances interferon production and natural killer activity. Microbiol. Immunol. 38:831-836[Medline].

MINIREVIEW Antibody Responses to DNA in Normal Immunity and Aberrant Immunity

MINIREVIEW
Antibody Responses to DNA in Normal Immunity and Aberrant Immunity