Cell-Mediated Immune Response to Human Papillomavirus Infection

doi:10.1128/CDLI.8.2.209-220.2001

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Clinical and Diagnostic Laboratory Immunology, March 2001, p. 209-220, Vol. 8, No. 2
1071-412X/01/$04.00+0 DOI: 10.1128/CDLI.8.2.209-220.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

MINIREVIEW
Cell-Mediated Immune Response to Human Papillomavirus Infection

Mark Scott,¹^,^* Mayumi Nakagawa,² and Anna-Barbara Moscicki¹

Department of Pediatrics¹ and Department of Laboratory Medicine,² School of Medicine, University of California San Francisco, San Francisco, California 94143

	INTRODUCTION

Top Introduction References

Acquisition of human papillomavirus (HPV) results in an infection of variable duration which may or may not be associatedwith clinically apparent lesions. Lesions caused by skin-tropicHPV types generally manifest as cutaneous warts and most oftenresolve over a period of months to years. On the other hand, anogenitalinfections are more likely to remain clinically inapparent. Thedevelopment of DNA amplification-based tests has demonstratedthat anogenital infections are quite common and generally self-limited.For example, we and others have shown by PCR testing of multiplesamples collected at different points in time-that 70 to 90% ofsexually active adolescents and young women who develop an incidentcervical HPV infection will show clearance of infection within12 to 30 months (47, 61, 94). The factors influencing thenatural history of these infections are not well understood. Giventhat persistent anogenital infection with oncogenic HPV typesis associated with increased risk of neoplasia and invasive cancers(22, 59, 70, 71, 94, 124) and that cervical carcinomaremains a leading cause of death among women in developing countries(129), understanding these factors is of considerableimportance.

Substantial effort has been directed recently at understanding the role of the host's immune response in the natural historyof HPV, and in particular, anti-viral, cell-mediated immunity.Empirical evidence for the importance of cell-mediated immunityin control of HPV infection comes from an extensive body of literaturedocumenting the increased prevalence of HPV infection and associateddisease among immunosuppressed populations, including those withiatrogenic immunosuppression such as renal transplant recipientsand individuals with human immunodeficiency virus (HIV) infection.Sillman and coauthors (128) reported in 1984 on 20 immunosuppressedwomen with various causes of immunosuppression who had lower genitalneoplasia, describing evidence of associated HPV infection inall 20. Penn, in 1986, reported a 100-fold increase in cancerof the vulva and anus in renal transplant recipients (111). Inthe 1990s, as molecular testing for HPV infection came into itsown, several reports confirmed increased incidence of HPV infection(50) and associated morbidities, including warts (77) andcervical squamous intraepithelial lesions (SIL) (104), amongimmunosuppressed renal transplantrecipients.

The most persuasive evidence for the association between cellular immune defects and HPV infection and related morbiditiescomes from persons with HIV infection. Such individuals show increasedprevalence of anogenital HPV infection (31, 32, 60, 105-107)as well as longer periods of HPV persistence (31, 40, 46,90, 136). In addition, infection with multiple HPV types andwith oncogenic types are more common (9, 31, 46, 78,90, 107, 136). Associations between markers of HIV diseasestatus (e.g., viral load and CD4 lymphocyte count) and HPV infectionhave been inconsistent. Most studies have suggested that advanceddisease and greater immunological deficit are associated withhigher prevalence and persistence of HPV infection (8, 31,60, 78, 107, 108). On the other hand, several studies havefound that HIV status influences HPV infection and SIL independentlyof CD4 counts (93, 147). These differences may have been dueto specific population characteristics, such as young age, orearly stages of HIV infection (93). The risk of abnormal cervicalor anal cytology as well as of HPV-related anogenital disease(cervical SIL or anal intraepithelial neoplasia) is also increasedin HIV-infected individuals (9, 33, 46, 60, 73, 78,93, 105, 106, 117, 147). While, as mentioned above, moststudies have suggested that the association between HIV infectionand increased prevalence of HPV infection and disease is relatedto the immunosuppression seen in HIV infection, there is alsosome evidence that mechanisms other than immunosuppression, suchas direct molecular interactions between HIV and HPV viral genes,may influence the natural history of HPV (8, 43, 93, 146).Nonetheless, the bulk of evidence strongly supports the notionthat altered cell-mediated immunity is associated with increasedHPV infection anddisease.

Studies of cell-mediated immune responses to HPV have been hampered by several factors. First, the life cycle and gene transcriptionpatterns of HPV are dependent on the stages of differentiationof keratinocytes (138). Only recently have there been successfulmodels that allow in vitro propagation of HPV. Second, interpretationof published studies is difficult due to the interlaboratory variabilityof target antigens and assays, inadequate assessment of HPV typespecificity, and inadequate HPV characterization of the studypopulation. Third, HPV infection is highly localized to squamousepithelial sites, without significant systemic manifestations.Consequently, demonstrating evidence of HPV-specific immune responsesin peripheral blood has proved challenging. Nonetheless, the lastdecade has seen significant advances in unraveling the role ofcellular immunity in the natural history of HPV infection. Thisreview will cover current understanding and recent advances, startingwith cellular aspects of innate immunity, and then covering therecognition and effector phases of the adaptive cellularresponse.

	INNATE IMMUNITY

Direct antiviral and antiproliferative effects of cytokines. Epithelial cells, once viewed principally as a mechanical barrier, are now regarded as having much more complex roles in cellularimmunity. Keratinocytes, including cervical keratinocytes, constitutivelysecrete low levels of a variety of cytokines (133, 151, 156),including proinflammatory cytokines, growth factors, and chemokines,and can be induced by various stimuli to produce significant amounts(10, 133, 151). In this section on innate immunity, the antiviraland antiproliferative effects of several cytokines will be considered.These include transforming growth factor $beta$ (TGF- $beta$ ), tumor necrosisfactor (TNF), and the type I interferons (alpha and beta interferon[IFN- $alpha$ and - $beta$ , respectively]), which are products of, among othercell types, epithelial cells (133, 151). In the section on adaptiveimmunity, other functions of epithelial cell-derived cytokineswill be reviewed as will the important areas of cytokine productionby T cells and the roles of cytokines in the regulation of T-cellresponses.

A number of studies have investigated the ability of cytokines, particularly TGF- $beta$ , TNF, and the interferons, to inhibit theproliferation in vitro of both normal and HPV-transformed keratinocytes,as well as inhibiting expression of HPV genes including the earlygenes E6 and E7. Expression of the E6 and E7 proteins has beenshown to be critical for malignant transformation of infectedcells (34, 58). E6 has been shown to interact with the anti-oncogeneprotein p53 by enhancing its degradation through ubiquitin-mediatedproteolysis (121) via a mechanism requiring E6-associated protein(13), while E7 interacts with the tumor-suppressing retinoblastomagene protein (45). These examples oversimplify the roles ofthe E6 and E7 proteins in malignancy, since both have also beenshown to interact with numerous other cell cycle functionalgenes.

Studies of the growth-inhibitory effects of cytokines and of the potential for HPV-infected cells to escape growth inhibitionhave, of necessity, relied mainly on cell lines and are highlydependent on experimental conditions. It is therefore not surprisingthat the results have been confusing. TGF- $beta$ provides a good exampleof the range of findings which have been reported. TGF- $beta$ 1 hasbeen shown to be both a product of and a growth inhibitor of nontumorigenicHPV type 16 (HPV-16)- and HPV-18-immortalized cells (17, 18).The growth-inhibitory effect in HPV-16- or -18-transformed cellsappears to be associated with the inhibition of expression ofE6 and E7 (17, 155). For HPV-16, this inhibition occurs atthe level of transcription, and the effects of exogenous TGF- $beta$ 1can be blocked by cycloheximide, indicating a requirement forsynthesis of negative regulatory proteins (17, 155). Woodworthand coauthors (155) concluded that TGF- $beta$ 1 may be an autocrineregulator of HPV gene expression in HPV-infected genital epithelialcells. It has also been shown that the TGF- $beta$ 1-induced growth inhibitionin HPV-16-immortalized cells is accompanied by suppression ofsteady-state levels of RNA for the proliferation-enhancing genec-myc (18). In a pair of recent studies, the expression of severalproliferation-enhancing genes known to be regulated by TGF- $beta$ 1was investigated. In the first of these studies (127), HPV-11-transformedxenografts showed overexpression of TGF- $beta$ 1 and downregulationof the genes bcl-2, c-myc, c-jun, and c-Ha-ras and that encodingNF $kappa$ B, suggesting a mechanistic association between TGF- $beta$ upregulationin HPV-transformed papillomas and growth inhibition. Further supportingthis contention, the same group also reported that TGF- $beta$ 1 treatmentof HPV-16-transformed, but not HPV-18-transformed, cells resultsin downregulation of bcl-2 and NF $kappa$ B gene expression (126). Theauthors postulated that while the different responses in the twocell lines may be virus type specific, they more likely derivefrom the different stages of tumor progression of thelines.

The complexities of interpretation of data derived from studies of cell lines are illustrated by various studies by Woodworthand coauthors. In contrast to the studies described above fromtheir group and several others, they have more recently demonstrated(152) that when HPV-immortalized cells are grown in a mediumthat stimulates an early stage of squamous differentiation, TGF- $beta$ appears to stimulate, rather than inhibit, cell growth. This growthstimulation is seen only in HPV-immortalized, not normal (HPV-negative),cervical keratinocytes. The effect is indirect in that it involvesincreased expression of epidermal growth factor receptor and itsligand, amphiregulin, and the establishment of an autocrine growth-stimulatoryloop. The fact that normal cervical cells grown under these sameconditions exhibit the expected growth inhibition by TGF- $beta$ suggeststhe possibility that HPV-infected cells may escape this growthinhibition (as discussed in more detail below) and that this escapemay occur early, even before malignant transformation. Cultureconditions favoring early squamous differentiation could be arguedto more accurately reflect in vivo physiologic conditions; itis nonetheless clear that conclusions drawn from cell line-basedstudies must be interpretedcautiously.

TNF is another cytokine product of keratinocytes which may have an antiproliferative effect on HPV-infected cells, but thefindings have again been complex and are very similar to thosefor TGF- $beta$ . TNF appears to have an antiproliferative effect onHPV-16-harboring epithelial cells (84, 150), though not onHPV-18-immortalized cells (150). This effect involves growtharrest in G₀-G₁ (149). Malejczyk and coauthors (84) concluded,as it appears to be an autocrine mechanism, that it could provideself-regulatory growth control of HPV-associated neoplasia. LikeTGF- $beta$ , TNF has been shown to repress HPV-16 E6 and E7 expressionat the transcriptional level in an HPV-16-immortalized human keratinocytecell line, sharing this ability with interleukin 1 $alpha$ (IL-1 $alpha$ ) (72).Also like TGF- $beta$ , a growth-stimulatory effect involving an amphiregulin-mediatedautocrine loop has been reported for both TNF and IL-1 $alpha$ in some,but not other, HPV-16- or -18-immortalized cells and cervicalcarcinoma lines (154). This likewise suggests the possibilityof an early escape from growth inhibition in HPV-infectedcells.

Interferons, including IFN- $alpha$ and - $beta$ as well as the T-cell product IFN- $gamma$ , have also been investigated in regard to antiproliferativeeffects. IFN- $alpha$ has been shown to inhibit proliferation of HPV-16-immortalizedhuman keratinocytes at concentrations 10- to 100-fold lower thanthose needed to inhibit growth of normal human keratinocytes (68).The same low dose inhibits transformation of normal human keratinocytesby HPV-16 DNA. IFN- $alpha$ also inhibits HPV-16 E7 protein expressionbut not transcription and not E6 protein expression, suggestingthat growth and transformation inhibition is mediated by an inhibitionin E7 protein expression. Others (101, 112) have shown thatIFN- $alpha$ inhibits transcription of HPV-18 E6 and E7 genes in HeLacells, a cervical carcinoma cell line containing integrated HPV-18DNA. Interestingly, this effect appears to be shared with IFN- $gamma$ (101). The varied effects attributed to different interferonsmay be virus-type specific, cell-line specific, or dependent onother experimental variables. As a further example, one group(153) showed that IFN- $gamma$ but not IFN- $alpha$ inhibits transcriptionof E6 and E7 genes in HPV-16-, -18-, and -33-immortalized keratinocytes,accompanied by growth inhibition, whereas another group (41)demonstrated that IFN- $beta$ reduces the transcription of E6 and E7genes in an HPV-16-transformed keratinocyte line (HPK-IA). NeitherIFN- $alpha$ nor IFN- $gamma$ has this effect in HPK-IA cells (41). Most interestingly,this group (41, 42) also demonstrated a marked cytopathiceffect on HPK-IA cells by IFN- $beta$ but not IFN- $alpha$ , despite the sharingof a common receptor for these two cytokines. They suggested thatthe ability of this cell line to finely discriminate between thetwo cytokines may be secondary to as yet unrecognized receptorcomplexity and also concluded that interferon responsiveness differsamong cell lines (41). These studies again highlight the notionthat data collected from cell lines must be interpreted with caution.Nonetheless, most studies suggest a potential antiviral role forinterferons in HPV-infectedepithelium.

A fair amount of evidence suggests that malignant transformation involves loss of responsiveness to the inhibitory effectsof cytokines (18, 42, 85, 153, 155). TGF- $beta$ 1, for example,has been shown to inhibit the growth and HPV gene transcriptionin nontumorigenic HPV-16-immortalized cells but not in HPV-16⁺ cervical cancer lines (Ca Ski and SiHa) (18). Partial resistanceto TGF- $beta$ 1 can also be induced in HPV-16-immortalized cell linesby malignant transformation in vitro via transfection with thev-Ha-ras oncogene or the herpes simplex virus type 2 BglII N fragment(155). Resistance has likewise been demonstrated to interferon-mediatedinhibition of growth and HPV early gene expression after malignanttransformation (153). De Marco and coauthors (42) reportedthat the cytopathic effect noted above of IFN- $beta$ on HPV-16-immortalizedcells is not induced in malignant, HPV-16-harboring SiHa cells.The authors suggested that a relatively conserved phenotype isrequired for the effect. As mentioned, more recent work suggeststhat resistance to the growth-inhibitory effects of several cytokines,accompanied by an indirect amphiregulin-mediated growth-stimulatoryeffect, may occur in HPV-immortalized cells even prior to malignanttransformation (152, 154). The characterization of this growth-stimulatoryeffect has led to the suggestion that chronic inflammation, withproduction of proinflammatory cytokines, may actually providea selective advantage for abnormal cells in vivo (154). Thesestudies all support a possible escape of cytokine-mediated growthinhibition in HPV infection; the unanswered question is whetherthis is an early event or one associated with malignanttransformation.

In addition to the amphiregulin-mediated loop described above, several other mechanisms by which HPV-infected cells may escapethe growth-inhibitory effects of cytokines have been proposed.For example, Malejczyk and coauthors (85), comparing HPV-16-transformedcell sublines with different levels of tumorigenicity in nude(athymic) mice, showed a correlation between increased tumorigenicity,resistance to TNF-mediated inhibition of proliferation in vitro,and significantly decreased expression of TNF receptors. Theyalso showed increased shedding of soluble type I TNF receptorin the more highly tumorigenic subline (83). Interestingly,levels of soluble type I and type II TNF receptors in serum havebeen shown to be significantly elevated in patients with HPV-16-or -18-associated cervical carcinomas or anogenital Bowen's carcinoma(87). The authors concluded that these soluble receptors mayfacilitate the growth of lesions (87).

Another possible mechanism of escape from antiproliferative cytokines was suggested by a recent report (131) that conversionof nontumorigenic HeLa-fibroblast hybrids to tumorigenic cellsis accompanied by the development of resistance to the abilityof TNF to suppress HPV-18 gene transcription, as well as changesin the composition of the activator protein 1 complex, which playsa role in expression of E6 and E7. The authors proposed that lossof TNF-sensitivity may be causally related to alterations in theactivator protein 1complex.

A possible mechanism by which some HPV types may evade the effects of IFN- $alpha$ was provided by a study (12) that showed thatHPV-16 E7 protein inhibits the induction of IFN- $alpha$ -inducible genesby inhibiting the translocation of p48, the DNA-binding componentof the interferon-stimulated gene factor 3 transcription complex,to the nucleus upon IFN- $alpha$ stimulation. A direct protein-proteininteraction was identified between E7 and p48. This supports aprevious report (4) that patients with condylomas that failto respond to interferon (IFN- $alpha$ and IFN- $gamma$ ) treatment express higherlevels of E7 mRNA thanresponders.

In summary, there appears to be evidence for the contention that various cytokines, notably TGF- $beta$ , TNF, IL-1, the type I interferons,and IFN- $gamma$ , may play roles in checking growth of HPV-infected cellsand that viral persistence, disease progression, and/or malignanttransformation could involve escape from those mechanisms. Sinceepithelial cells are capable of producing these cytokines (exceptIFN- $gamma$ ), some authors have suggested that cytokines may play autocrineroles in keratinocyte growth regulation in HPV infection (84,85, 155). These cytokines are all produced by multiple othercellular sources, of course, including macrophages, T cells, andNK cells, so many cell types probably contribute to the growth-inhibitoryeffects described above. Additional functions of cytokines willbe coveredbelow.

Role of NK cells. In patients with epidermodysplasia verruciformis, chronic infection with HPV leads to disseminated red plaques and verruca-likeskin lesions. Reduced cytotoxicity of NK cells against keratinocytes(isolated from a premalignant lesion of a patient with epidermodysplasiaverruciformis) in peripheral blood mononuclear cells (PBMC) fromepidermodysplasia verruciformis patients (81) suggests the importanceof NK cell activities in preventing lesions fromdeveloping.

Studies investigating the role of NK cells in the development of SIL also suggest protective effects of NK cells. DecreasedNK cell lysis of HPV-16⁺ keratinocytes in subjects with SIL or carcinomas has been reported(82). The same group has shown that decreased recognition ofHPV-16⁺ keratinocytes is related to unresponsiveness of PBMC to immunostimulatorycytokines such as IL-2 and IFN- $alpha$ (86). Other groups have alsoshown similar importance of NK activity in regression of SIL (54,134).

	ADAPTIVE CELL-MEDIATED IMMUNITY

The various cellular components involved in the recognition and effector phases of adaptive epithelial immune responses havebeen demonstrated in both cutaneous and mucosal HPV-infected tissues(63, 89, 91). These include Langerhans cells, which captureantigens for transport to local draining lymph nodes and presentationto naive T cells; clonally expanded T cells that have homed backto infected epithelial tissues via mechanisms involving chemokinesand adhesion molecules; and accessory cells such as macrophages.The adaptive immune response to HPV will be considered in termsof these two phases (recognition and effector), focusing on thecells involved and the soluble and membrane-bound molecules thatmediate and regulate theresponses.

Recognition phase. A number of studies have addressed the potential role for Langerhans cells in viral diseases with cutaneous manifestationsincluding HPV infection. A reduced number of epidermal Langerhanscells has been documented in lesions due to herpes simplex virusand HIV as well as HPV (89). One report (148) documented drasticreductions in CD1⁺ Langerhans cells in cutaneous plantar and hand warts comparedwith normal epithelium, but interestingly no reductions were foundin mucosal genital condylomas and laryngeal papillomas. On theother hand, several investigators have described decreases inLangerhans cell density in genital HPV infection, condylomas,or SIL (91, 92, 140). It is possible that a decrease in Langerhanscell density in the epidermis of HPV-infected tissues simply representsnormal egress of antigen-carrying Langerhans cells from the epidermisto draining lymph nodes for antigen presentation to naïve T cells(89).

The possibility certainly exists that reductions in Langerhans cells, whether due to normal egress or due to other as yetunidentified mechanisms, may contribute to impaired immune surveillance.Some suggest that the depletion of intraepithelial Langerhanscells associated with HPV infection may, along with other localimmune deficiencies, contribute to prolonged infection or possiblymalignancy (89, 140). One study found pretreatment biopsy specimensfrom patients whose genital condylomas failed to respond to interferontherapy to be depleted of Langerhans cells, compared with pretreatmentbiopsy specimens from responding patients (7). Several studieshave suggested that Langerhans cells in HPV lesions may be functionallyimpaired, which again may contribute to persistence of infection.For example, abnormal morphology of Langerhans cells in genitalcondylomas has been reported (25, 91), with blunting of thedendritic architecture. One group (28), using paired biopsiesand two different antibodies (S-100 and CD1) to stain Langerhanscells, recently demonstrated that S-100⁺ cells are significantly reduced in SIL compared with normal cervicalepithelium, in agreement with an earlier report (140), whereasCD1⁺ cells are not, suggesting that there is a defect in S-100 proteinexpression. Since S-100 stains a family of related calcium-bindingproteins, they suggested that these proteins may be importantin the function of Langerhans cells in HPV infection. In contrastto reports suggesting Langerhans cell functional deficits, Cooperand coauthors (30), studying lesions from patients with theHPV-related cutaneous disease epidermodysplasia verruciformis,reported that despite slight reductions in Langerhans cell numberin lesions, as well as abnormal Langerhans cell morphology, isolatedLangerhans cells appear to be functionally intact in their abilityto present alloantigens to Tcells.

Once Langerhans cells have captured antigen, the recognition phase continues with their migration to draining lymph nodes.As recently reviewed by Wang and coauthors (151), cytokines,elaborated principally by keratinocytes with some contributionfrom the Langerhans cells themselves, appear to be crucial mediatorsof this process. Particularly important cytokines are thoughtto include IL-1 $alpha$ and TNF (mainly produced by keratinocytes) andIL-1 $beta$ (mainly produced by Langerhans cells), all of which promoteLangerhans cell migration, and IL-10, produced by keratinocytes,which acts as an inhibitor of Langerhans cell migration (151).Other cytokines, for example granulocyte-macrophage colony-stimulatingfactor, also produced by keratinocytes, promote the initiationof Langerhans cell maturation into mature dendritic cells (74).A possible association between deficits in production of thesecytokines and persistent HPV infections has been postulated (156),based on the findings of reduced cytokine levels (IL-1 $alpha$ and 1 $beta$ ,TNF, and granulocyte-macrophage colony-stimulating factor, amongothers) in several HPV-immortalized cervical cell lines and severalcervical cancer lines, compared with normal cervical cells. Giventhat lower levels of cytokine production were seen with more prolongedperiods of subculture, the results from the HPV-immortalized celllines may not be accurate reflections of in vivo conditions. Nonetheless,the findings provide preliminary evidence for an association betweendiminished production by keratinocytes of various cytokines andpersistent HPV infection. Support also comes from in vivo evidencerecently reported by Mota and coauthors (96), who found thatTNF expression by keratinocytes was absent in some SIL biopsyspecimens studied but present in all biopsy specimens of normalcervical squamous epithelium. Furthermore, fewer high-grade SIL(HSIL) than low-grade SIL (LSIL) biopsy specimens were positivefor TNF expression. Conversely, IL-10 expression by keratinocyteswas present in many SIL biopsy specimens but absent in normalepithelium. Noting the importance of these two cytokines in regulatingLangerhans cell functions, they suggested that these alterationsmay contribute to an altered antigen-presenting environment inpremalignant cervical lesions. The studies described above suggestthe possibility that HPV may evade immunosurveillance by modulatingthe production of cytokines by infected keratinocytes or, alternatively,that individuals with abnormal responses in this regard may beat increased risk of HPV infection or associatedmalignancy.

Effector phase. (i) Proliferation and related studies of T-cell responsiveness to HPV. A large number of studies have investigated the role of helper T lymphocytes in providing protection against the developmentof HPV-associated lesions by measuring T-cell proliferative responses(36, 39, 55, 64, 65, 79, 80, 97, 125) or IL-2release (14, 38, 143). Unlike studies addressing the roleof NK cells which support their protective role (see above), theresults from proliferation assay studies areinconsistent.

Studies to date have focused on helper T-lymphocyte responses to HPV-16 antigens, as HPV-16 is the most prevalent among theoncogenic HPV types and is the type most commonly associated withinvasive cervical cancers (16). Because of the roles of theE6 and E7 gene products in cell transformation described above,responses to HPV-16 E6 and E7 proteins and peptides have beenwidely studied (36, 38, 39, 64, 65, 80, 97, 143).In three of the five studies which were cross-sectional in design,more-frequent responses to these antigens were observed in subjectswho were cytologically normal compared with subjects who had developedSIL (80, 97, 143), suggesting that these antigens are importantin SIL prevention. In one study, more-frequent responses to HPV16 E7 peptides were observed in SIL subjects with HPV-16, -31,or -33 infections compared with controls without SIL (HPV statusunknown) (65), and in another study no correlation between responsesand the presence of SIL was found (36). Although clinical correlationto in vitro assays is essential, interpretation of cross-sectionalstudies remainslimited.

Few studies have investigated T-cell proliferative responses to HPV-16 E6 or E7 gene products using longitudinal designs.One such study reported that the subjects with positive responsesto an E6 peptide (amino acids 1 to 30), an E7 peptide (amino acids72 to 97), or both were likely to have cleared their HPV infectionand SIL at the following visit (64). In contrast, another grouphas reported that positive T-cell proliferative responses (39)and IL-2 release (38) are seen more frequently in subjects withprogressing SIL than subjects with regressingdisease.

The results from studies focusing on HPV-16 proteins other than E6 and E7 have been equally confusing. T-cell proliferativeresponses to HPV-16 L1 are more frequently observed in subjectswith SIL than in healthy age-matched controls (79, 125). Across-sectional analysis (14) of helper T-cell responses toHPV-16 E2 protein in women with SIL showed an association betweenresponses to the C-terminal domain and previous or present HPV-16infection but no association with disease outcome. However, alongitudinal analysis of the same study revealed that these responsesfrequently occur at the time of viral clearance. Therefore, suchresponses may correlate with clearance of viral infection butnot necessarily with the resolution of SIL. A study of proliferativeresponses to HPV-16 E5 (55) showed that these were more frequentlyseen in subjects with HPV-16⁺ LSIL (43%) than subjects with HPV-16⁺ HSIL (22%) or HPV-16⁺ subjects without SIL (20%). A longitudinal analysis of this studypopulation would be of great interest to determine whether higherresponses in subjects with LSIL are associated with itsresolution.

The inconsistencies reported among these studies can be explained by several factors. The first factor is differences in antigens:studies have differed in their choice of peptide versus proteinantigens and in the specific sequences used. Some antigens aresurely more antigenic than others. The second factor is differencesin subject populations: cross-sectional studies are limited sincethe important events such as clearance or regression may not yethave occurred. Even longitudinal studies rarely have sufficientinformation on the women's entire history of HPV exposure (that,is HPV history since first intercourse), making the interpretationof positive responses in current HPV women difficult. The third factor is a lack of a simple correlationbetween helper T-cell responses and the natural history of infection:while helper T lymphocytes have been shown to be necessary ineventual production of antibodies by B lymphocytes (37, 102)and in aiding the development of cytotoxic lymphocytes (CTL) (3,56), the activities of helper T cells themselves may not correlatedirectly with clearance of virus and virus-associated lesionssince they are not themselves thekillers.

(ii) Studies of CTL-mediated killing. CD8-positive, major histocompatibility complex (MHC) class I-restricted CTL are known to be responsible for recognizing andkilling virus-infected host cells and virus-induced tumors (57).Immunohistochemical analysis of SIL and cervical cancer specimenshas demonstrated the presence of activated CTL in lesions (15).Studies using mouse models have demonstrated that immunizationwith HPV-16 E6- or E7-transfected nontumorigenic fibroblasts canlead to regression of tumors expressing E6 or E7, respectively,and that the regression is mediated by CD8⁺ CTL (20, 21).

In humans, HPV-16 E6- and/or E7-specific CTL have been demonstrated in women with cervical cancer and women with SIL. Alexanderand coauthors (1) stimulated PBMC from cervical cancer patientswith a human leukocyte antigen A2 (HLA-A2)-restricted HPV-16 E7peptide [E7 amino acids 11 to 20, or E7 (11-20)] and showed thatCTL were capable of lysing HLA-matched, HPV-16 E7 (11-20)-pulsedtargets in two of three patients. Another group has identifiedHPV-specific CTL in lymph nodes and tumors of cervical cancerpatients (49). CTL to HPV-16 E6 and E7 have also been demonstratedin PBMC stimulated in vitro with the cervical carcinoma line CaSki in some patients with SIL (48).

HPV-16 E6- and E7-specific CTL have also been demonstrated in subjects who had evidence of HPV-16 infection but who had notdeveloped SIL (98-100). In a small cross-sectional study (98),the percentage of subjects who demonstrated HPV-16 E6- and/orE7-specific CTL was higher in a group of women with HPV-16 infectionwho had not developed SIL than in a group of women with HPV-16infection who had developed SIL. The effector cell phenotypesin these assays have been shown to include both CD4⁺ and CD8⁺ T lymphocytes (99).

In a similar subject population, we examined the association between HPV-16 E6- and E7-specific CTL and HPV-16 persistence,in a longitudinal study design involving multiple CTL assays inwomen with evidence of cervical HPV-16 infection as detected byPCR (100). Lack of CTL response to the HPV-16 E6 protein, butnot the E7 protein, was correlated with persistent HPV-16 infection,suggesting that a CTL response to E6 is important in the clearanceof HPV-16 infection. Notably, CTL responses in this study wereshown to be frequently transient. Most women had several repeatedCTL assays performed at 4-month intervals, of which only somewere positive. This most likely reflects the low sensitivity ofcurrent the assay to detect circulating T cells that are specificto localized infections. A similar study looking at women withSIL associated with HPV-16 would be important in elucidating therole of CTL in the regression ofSIL.

Recently, a novel technique for identifying antigen-specific T lymphocytes, using peptide-MHC tetramers, has been used toidentify and isolate T lymphocytes specific for HPV. Youde andcoauthors (158) reported positive tetramer responses to HPV 16E7 (11-20) in patients with cervical cancer and carcinoma in situ.However, the interpretation of positive responses in cancer patientsis unknown since, by definition, these patients have failed immuneresponses in that infection persisted and the development of neoplasiawas notprevented.

(iii) Defining antigenic epitopes of HPV. Considerable effort has been devoted by many investigators to identifying antigenic epitopes of HPV, using both mouse modelsystems (51, 52, 116, 118, 120) and human systems (62,66, 67, 76, 116, 135, 139). Kast and coauthors (67)identified potential CTL epitopes of HPV-16 E6 and E7 proteinsfor five common HLA types by measuring binding of each of 150nonamer peptides. Immunogenicity of nine of these potential antigenicepitopes for HLA-2.1 was tested (116). Using HLA-2.1 transgenicmice four immunogenic peptides were identified in vivo [E6 (29-38),E7 (11-20), E7 (82-90), and E7 (86-93)]. In addition, CTL inductionof PBMC from humans confirmed immunogenicity, in vitro, of threeof the four peptides [E7 (11-20), E7 (82-90), and E7 (86-93)]. CTLto one of these peptides [E7 (11-20)] have been demonstrated inSIL and cancer patients, in studies mentioned above (1, 49,158). Whether this epitope plays an important role in the eliminationof HPV-16 infection and of HPV-associated lesions has not beeninvestigated.

In a recent report (62), one group has succeeded in isolating and expanding a TNF-secreting CD4⁺ tumor infiltrating lymphocyte line, from a cervical cancer patient,which recognizes autologous cervical cancer cells. The cell linewas shown to define an HLA-DR4-presented epitope provided by theE7 genes of HPV-59 and HPV-68.

(iv) Antigen presentation in the effector phase. (a) MHC class II-restricted antigen presentation. A number of studies have examined the expression of MHC class II antigen in HPV infection. IFN- $gamma$ treatment of HPV-16-, -18-,and -33-immortalized keratinocytes has been shown to enhance transcriptionof class II MHC molecules (153). Viac and coauthors (148) demonstratedepithelial cells expressing the MHC class II antigen HLA-DR ingenital condylomas and laryngeal papillomas. They described aclose spatial association between HLA-DR⁺ epithelial cells, T-cell infiltrates, and high densities of Langerhanscells and postulated that the HLA-DR upregulation may be due toIFN- $gamma$ secretion by activated T cells and that the HLA-DR⁺ keratinocytes may participate in immune reactions. Interestingly,they reported that HLA-DR expression on keratinocytes was absentin cutaneous warts, highlighting possible differences betweencutaneous and mucosal anti-HPV immune responses. Another group(25) has also shown HLA-DR upregulation on keratinocytes ingenital condylomas, although they emphasized that the functionalsignificance of this remains an area ofcontroversy.

Another area of controversy is the role of MHC class II expression in persistence of HPV infection or progression of HPV-associateddisease. Several studies report evidence of impaired MHC classII expression (6, 25, 156), whereas other studies offera more confusing picture, showing more frequent expression ofHLA-DR in HSIL than in LSIL (26, 96). The hypothesis thatHPV may evade cellular immune responses by, among other mechanisms,inhibiting upregulation of MHC class II expression, is suggestedby a study (6) comparing patients whose genital condylomasresponded to interferon treatment with those who did not. Impairedupregulation of this antigen in the nonresponders, compared withthe responders, was associated with overexpression of the HPVE7 gene, suggesting a possible causal link between high E7 expressionin the nonresponders and the decreased inducibility of HLA-DRexpression.

(b) MHC class I-restricted antigen presentation. Normal human keratinocytes constitutively express MHC class I molecules and are susceptible to class I-mediated lysis by alloantigen-primedCTL (137). In addition, exogenous IFN- $gamma$ increases this susceptibility(137). Losses of MHC class I expression have been reported inHPV-infected tissues, with some possible differences between cutaneousand mucosal tissues. For example, one group (148) has reporteda drastic reduction in MHC class I expression in cutaneous warts,but only mild reductions in condylomas and laryngeal papillomas.More advanced mucosal lesions, however, do exhibit significantlosses of MHC class I expression, as illustrated by a report (29)showing that specimens from at least 30% of cervical cancer biopsiesstudied demonstrated some alteration in MHC class I expression,varying from complete loss of expression to loss of particularallelic products. While that study found no correlation with tumortype, disease stage, or detection of HPV-16 or -18 DNA in thebiopsy specimens, Torres and coauthors (142) did find that lossof MHC class I expression in cervical cancer biopsy specimenscorrelates with tumor invasiveness and more aggressive histologyas assessed by the Glanz histoprognostic index of malignancy.An interesting recent study (145) correlated downregulation ofMHC class I expression with a more aggressive course of the HPV-relateddisease recurrent respiratory papillomatosis (RRP). They examinedthe expression of the transporter associated with antigen presentation(TAP-1) and MHC class I proteins in laryngeal papilloma biopsiesfrom patients with RRP and showed that downregulation of bothis associated with more frequent disease recurrences. They concludedthat HPV may evade immunological recognition by downregulatingTAP-1. Others have cautioned, however, that MHC class I downregulationmay be the result of altered levels of or sensitivity to cytokines,such as IFN- $gamma$ and TNF, rather than direct effects of viral infection(88). Regardless of the underlying reasons for changes in MHCclass I expression, the data suggest that in persistent HPV infectionor HPV-associated malignancy, loss or downregulation of MHC classI expression may contribute significantly to diminished recognitionand removal of infected cells byCTL.

(v) Regulation of T-cell responses. (a) Chemokines and adhesion molecules. An important component of the effector phase of cutaneous immune responses is the recruitment and retention of activated lymphocytesat sites of inflammation, which reflect processes involving bothsoluble chemokines and membrane-bound adhesion molecules. Schröder(122) reviewed the roles of chemokines in cutaneous immunity,with particular emphasis on the importance of epithelial cellIL-8 production in the recruitment of neutrophils and T cells.Cervical keratinocytes constitutively produce IL-8 (156) and,as with other keratinocytes (122), secretion is enhanced by activationwith IL-1 or TNF (156). The T-cell product IFN- $gamma$ has been shownto synergize with TNF in enhancement of keratinocyte IL-8 production(11), which may provide a positive feedback loop by which Tcells participate in their own enrichment at sites ofinflammation.

Studies of the association between chemokine production and the natural history of HPV infection have been few. In a recentstudy of chemokine levels in cervicovaginal lavage samples fromHIV-seropositive women, Spear and coauthors (132) demonstratedsignificantly higher IL-8 levels in women with genital tract dysplasiaor cytologic or histologic evidence of HPV infection than in womenwithout, whereas the levels of two other chemokines studied (RANTES[regulated-on-activation normal T-expressed and secreted factor]and MIP-1 $alpha$ [macrophage inflammatory protein 1 $alpha$ ]) were not significantlydifferent. They noted, however, that comparisons of cervicovaginallavage samples are confounded by uncertainties about dilutionalartifact which may be introduced during lavage. Furthermore, interpretationof the apparent induction of IL-8 in HPV infection is difficultin the setting of HIV infection and associated immune imbalances.In contrast, other authors (156) have reported significantlydiminished constitutive production of IL-8 in HPV-16- or -18-immortalizedcell lines and in some cervical carcinoma cell lines. Treatmentwith IL-1 or TNF failed to upregulate IL-8 production to the samedegree as in normal cervicalcells.

The chemokine macrophage chemoattractant protein 1 (MCP-1) may also be important in HPV control. It has been reported thatHPV-18⁺ HeLa cells transfected with an expression vector containing cDNAfor MCP-1 show significant growth retardation accompanied by amarked macrophage infiltrate when inoculated into nude mice, whereas,HeLa cells without the vector lead to rapidly growing tumors andno macrophage infiltration (69). Keratinocytes are capable ofproducing MCP-1 (122) and the endogenous gene is also presentin HeLa cells and not structurally rearranged (69). However,its expression appears to be suppressed in HeLa cells and is onlymarginally upregulated by TNF (69). This suggests another potentialmethod of escape from host defenses in HPV-associatedmaligancy.

A larger number of studies have addressed the roles of adhesion molecules, with particular focus on keratinocyte expressionof intercellular adhesion molecule 1 (ICAM-1) and its ligand,leukocyte function-associated antigen 1 (LFA-1). In addition toits role in cell migration, the LFA-1-ICAM-1 interaction appearsto be involved in specific antigen recognition and is criticalfor CTL-mediated killing (103). Constitutive keratinocyte expressionof ICAM-1 is very low but is readily and markedly increased bystimulation with the cytokines TNF and IFN- $gamma$ (103). Morelli andcoauthors (91) showed that in vulvar condylomas with mononuclearinfiltrates, LFA-1⁺ T cells could be seen forming small clusters in the lower halfof the epithelium around ICAM-1⁺ keratinocytes. ICAM-1 expression overlapped with HLA-DR expression,supporting the importance of this adhesion molecule in T-cell-keratinocyteinteractions. Similar findings of foci of epithelial cells expressingICAM-1 and LFA⁺ leukocytes (mainly CD8⁺) have been described in condylomas and laryngeal papillomas (148).In a study comparing regressing and nonregressing genital condylomas(25), there was significant induction in the regressing lesionsof ICAM-1 and two other adhesion molecules, E-selectin and vascularcell adhesion molecule 1. The regressing lesions also containedsignificantly more T cells and macrophages than the nonregressingcontrols. Malignant transformation may be accompanied by diminishedexpression of adhesion molecules, although, to date, studies arenot clear on this. Some investigators (156) have reported evidencethat malignant transformation of cervical keratinocytes is associatedwith impaired ICAM-1 inducibility, whereas others (27) havereported upregulation of ICAM-1, vascular cell adhesion molecule1, and E-selectin in HSIL, compared with LSIL or normal cervicalepithelium. The latter study's findings suggest a role for adhesionmolecules in antineoplastic immune responses in HSIL but do notsupport the contention that impaired expression of adhesion moleculesis associated with progression of HPV-induceddisease.

(b) Cytokines involved in regulating T-cell responses. In recent years, studies of immunoregulation have focused on an apparent functional dichotomy of cytokines, between thosethat support cellular immune responses and those that supporthumoral responses, as well as a parallel dichotomy of cytokine-producinghelper T cells. The phenotypic classification of activated helperT cells into IFN- $gamma$ -, TNF-, and IL-2-producing T helper type 1(Th1) cells, which stimulate cellular responses, and IL-4-, IL-5-,IL-10-, and IL-13-producing T helper type 2 (Th2) cells, whichstimulate humoral responses, has been reviewed elsewhere (95,110). Accessory cell-derived cytokines, such as IL-12, whichpromotes Th1 cell development, are also important regulators ofT-cell functions. Additionally, accessory cells, and even keratinocytes,contribute to production of various Th1 and Th2 cytokines, suchas TNF and IL-10. The existence of Th1 and Th2 cells in humanshas been confirmed by several elegant studies (113, 115). Thehypothesis that the Th1-Th2 model of immunoregulation may playa role in the natural history of HPV infection is suggested bytwo other infections involving infection of epithelial tissuesby intracellular pathogens: cutaneous leishmaniasis (19, 114)and leprosy (119, 157).

Some studies suggest that HPV infection normally elicits a Th1 response. Immune responses to HPV vaccination have been shownin a mouse model to be characterized by the secretion of the Th1cytokines IFN- $gamma$ and IL-2 (44). Tsukui and coauthors (143) havedemonstrated IL-2 production by peripheral blood lymphocytes,in response to HPV-16 peptides, in women with SIL or cervicalcancer, and in cytologically normal women with histories of HPV-16infection.

The contention that a Th1 response is important for clearance of HPV infection, or, conversely, that lack of such a responsemay be associated with persistent infection or the developmentof HPV-related neoplasia, has support from several studies. Ina study of cytokine mRNA patterns in exfoliated cervical cells(123), we identified seven subjects who were HPV⁺ and who subsequently had cleared their infections on examination4 months later. All seven showed a Th1 pattern (expression ofIFN- $gamma$ mRNA and absence of IL-4 mRNA) preceding clearance, comparedwith highly variable patterns in HPV women with previous histories of HPV infection. Another group(109), using cervical biopsy tissue, showed decreased IFN- $gamma$ mRNAexpression in women with SIL or cervical cancer, compared withnormal cervical tissue. The normal cervical tissue was obtainedfrom HPV 16- and 18-negative women, although it is not clear ifthey were positive for any other HPV types. Another recent study(2) examined cervical biopsies by immunohistochemistry andfound that SIL, particularly HSIL, biopsies contained fewer Th1(IL-2⁺) cells and an increased density of Th2 (IL-4⁺) cells, compared with normal cervical epithelium. Two studieshave used peripheral blood lymphocytes. In the study by Tsukuiand coauthors described above (143), the fraction showing IL-2production when stimulated in vitro with HPV-16 peptides correlatedwith cervical disease: highest levels were found in cytologicallynormal HPV-16⁺ women, intermediate levels were found in women with SIL, andthe lowest levels were reported in women with cervical cancer.Another group (23) examined antigen- and mitogen-stimulatedcytokine production by PBMC in women with SIL and reported a shiftfrom Th1 cytokines to Th2 cytokines in women whose HPV infectionextended beyond the cervix to other sites of the lower genitaltract, as evaluated by colposcopic, cytologic, and histologicmethods and by HPV detection via molecular hybridization. Theauthors speculated that augmented IL-10 production may decreaseimmune recognition of HPV-associated tumors by downregulatingexpression of MHC class I and/or class II molecules. As describedabove, both of these molecules have been reported to show diminishedexpression in persistent or progressing HPV-associated lesions,although, as noted, the evidence for loss of MHC class II expressionis confusing atbest.

A couple of recent studies have investigated cytokine production in women coinfected with HPV and HIV. One study (75) assessedperipheral blood T-cell cytokine profiles by flow cytometry. Ashift away from Th1 (IL-2⁺, IFN- $gamma$ ⁺, and/or TNF⁺) and toward Th2 (IL-10⁺) phenotypes was described in women with either abnormal cervicalcytology or SIL, compared with healthy controls. The shift occursboth in women with and without HIV infection, but the decreasein peripheral blood Th1 cells is greatest in coinfected women.Another study (35) examined cytokine protein production in cervicalsecretions collected from adolescents. The investigators showedthat HPV infection is associated with decreased IL-10 levels inHIV-seronegative women but with increased levels in HIV-seropositivewomen. The decreased IL-10 levels in HPV⁺ but HIV women supports the contention that an anti-HPV immune responseis normally associated with a switch away from Th2 cytokines.On the other hand, the finding that coinfected (HPV⁺ and HIV⁺) subjects have significantly higher IL-10 levels than women witheither infection alone is harder to explain. A Th1-to-Th2 shifthas been described in HIV infection (24). Therefore, it maybe that the T cells that have homed to the cervical mucosa, dueto the presence of HPV, have been biased to a Th2 profile by thepatient's concomitant HIV infection. As IL-10 is also a productof macrophages, another possibility is that these cells were asource of the higher IL-10 levels seen in the coinfected subjects.Further support for this hypothesis comes from their finding thatcoinfection with HIV and HPV is also associated with higher levelsof the accessory cell product IL-12 (especially in women witha third sexually transmitted infection), compared with women withonly HIV or HPV infection (35). As cautioned previously, interpretationof HPV-associated immune responses is difficult in the settingof HIV infection. Nonetheless, these studies do lend support tothe notions that HPV infection elicits a Th1 type of response(35) and that a shift toward a Th2 response is associated withthe development of HPV-associated cervical pathology (75).

	EVASION OF CELL-MEDIATED IMMUNITY BY HPV

The possibility that HPV may have evolved mechanisms to evade effective cellular immune responses has been suggested at severalpoints in the preceding discussion. This topic has recently beenreviewed, and several potential mechanisms of escape were proposed(53). First, HPV may have evolved mechanisms to limit the extentto which viral antigens are exposed to immunologic recognition.HPV delays expression of abundant viral proteins (the capsid proteinsencoded by the late viral genes) until the terminal differentiationstage of squamous epithelium, an anatomically superficial locationwhere immunocompetent cells would have less access to them. Incontrast, in the basal epithelium, where the early genes (suchas E6 and E7) are expressed, the level of protein expression islow and confined to a nuclear location, thus potentially limitingan effective immune response against the cells in which the virusis actively replicating. The authors proposed that the delayedexpression of capsid-encoding genes may be due to a pattern ofcodon usage that inhibits their expression in basal epithelialcells. Second, as suggested earlier in this review, viral proteinssuch as E7 may modulate immune responses. For example, the authors(53) suggested that overexpression of E7 protein may inhibitthe antigen presenting function of dendritic cells in the epithelium.Third, keratinocytes may be relatively less susceptible to CTL-mediatedlysis than other infected cells and may even present antigen ina tolerogenic manner. As emphasized by the authors, the role thatthese mechanisms play in affecting the natural history of HPVinfections remains speculative at thispoint.

	IMMUNE MODULATION OF HPV: CLINICAL IMPLICATIONS

An increased understanding of the importance of cellular immunity in clearance of HPV infections has led to therapeutic trials,in patients with anogenital condylomas, with interferons (5-7)and immune response modifiers (130, 144). Patients who respondto interferon (IFN- $alpha$ and IFN- $gamma$ ) treatment show reduced HPV copynumber in biopsy specimens (5). Comparisons of patients whodo or do not respond to interferon treatment has, in turn, contributedfurther to our understanding of effective antipapillomavirus cellularresponses (4, 6, 7). Likewise, use of the immune responsemodifier drug imiquimod has resulted in condyloma clearance, associatedwith tissue production of IFN- $alpha$ , - $beta$ , and - $gamma$ and TNF, as well asdecreases in DNA and mRNA for viral genes (144). Advances intherapeutic methods will no doubt continue to both benefit fromand contribute to a fuller picture of the host's response to HPVinfection.

Similarly, work toward an effective vaccine continues apace (141). Given the worldwide morbidity and mortality resultingfrom anogenital infection by HPV, this approach is likely to eventuallyreap the greatest rewards in preventing HPV-derived disease. Asthe present review suggests, we are beginning to gain a betterunderstanding of what constitues an effective host response toHPV infection, as well as what deficiencies in that response maybe associated with viral persistence and the development of premalignantlesions and carcinoma. Still, much remains to be understood inthe area of immunity andHPV.

	ACKNOWLEDGMENTS

This work was supported by National Institutes of Health grants NCI CA51323, U01 HD32842, N01 HD33162, and NCI K07CA75974.

	FOOTNOTES

^* Corresponding author. Mailing address: University of California San Francisco, Department of Pediatrics, Division of AdolescentMedicine, Box 1374, 513 Parnassus Ave., San Francisco, CA 94143-1374.Phone: (415) 476-3260. Fax: (415) 502-1222. E-mail: mscott{at}itsa.ucsf.edu.

REFERENCES

Top
Introduction
References

1. Alexander, M., M. L. Salgaller, E. Celis, A. Sette, W. A. Barnes, S. A. Rosenberg, and M. A. Steller. 1996. Generation of tumor-specific cytolytic T lymphocytes from peripheral blood of cervical cancer patients by in vitro stimulation with a synthetic human papillomavirus type 16 E7 epitope. Am. J. Obstet. Gynecol. 175:1586-1593[CrossRef][Medline].

2. al-Saleh, W., S. L. Giannini, N. Jacobs, M. Moutschen, J. Doyen, J. Boniver, and P. Delvenne. 1998. Correlation of T-helper secretory differentiation and types of antigen-presenting cells in squamous intraepithelial lesions of the uterine cervix. J. Pathol. 184:283-290[CrossRef][Medline].

3. Alter, B. J., C. Grillot-Courvalin, M. L. Bach, K. S. Zier, P. M. Sondel, and F. H. Bach. 1976. Secondary cell-mediated lympholysis: importance of H-2 LD and SD factors. J. Exp. Med. 143:1005-1014[Abstract/Free Full Text].

4. Arany, I., A. Goel, and S. K. Tyring. 1995. Interferon response depends on viral transcription in human papillomavirus-containing lesions. Anticancer Res. 15:2865-2869[Medline].

5. Arany, I., P. Rady, and S. K. Tyring. 1995. Effect of interferon therapy on human papillomavirus copy number in patients with condyloma acuminatum. Am. J. Med. Sci. 310:14-18[Medline].

6. Arany, I., and S. K. Tyring. 1996. Activation of local cell-mediated immunity in interferon-responsive patients with human papillomavirus-associated lesions. J. Interferon Cytokine Res. 16:453-460[Medline].

7. Arany, I., and S. K. Tyring. 1996. Status of local cellular immunity in interferon-responsive and -nonresponsive human papillomavirus-associated lesions. Sex. Transm. Dis. 23:475-480[Medline].

8. Arany, I., and S. K. Tyring. 1998. Systemic immunosuppression by HIV infection influences HPV transcription and thus local immune responses in condyloma acuminatum. Int. J. STD AIDS 9:268-271[Abstract/Free Full Text].

9. Aynaud, O., D. Piron, R. Barrasso, and J. D. Poveda. 1998. Comparison of clinical, histological, and virological symptoms of HPV in HIV-1 infected men and immunocompetent subjects. Sex. Transm. Infect. 74:32-34[Abstract].

10. Barker, J. N., R. S. Mitra, C. E. Griffiths, V. M. Dixit, and B. J. Nickoloff. 1991. Keratinocytes as initiators of inflammation. Lancet 337:211-214[CrossRef][Medline].

11. Barker, J. N., V. Sarma, R. S. Mitra, V. M. Dixit, and B. J. Nickoloff. 1990. Marked synergism between tumor necrosis factor-alpha and interferon-gamma in regulation of keratinocyte-derived adhesion molecules and chemotactic factors. J. Clin. Investig. 85:605-608.

12. Barnard, P., and N. A. McMillan. 1999. The human papillomavirus E7 oncoprotein abrogates signaling mediated by interferon-alpha. Virology 259:305-313[CrossRef][Medline].

13. Beer-Romero, P., S. Glass, and M. Rolfe. 1997. Antisense targeting of E6AP elevates p53 in HPV-infected cells but not in normal cells. Oncogene 14:595-602[CrossRef][Medline].

14. Bontkes, H. J., T. D. de Gruijl, A. Bijl, R. H. Verheijen, C. J. Meijer, R. J. Scheper, P. L. Stern, J. E. Burns, N. J. Maitland, and J. M. Walboomers. 1999. Human papillomavirus type 16 E2-specific T-helper lymphocyte responses in patients with cervical intraepithelial neoplasia. J. Gen. Virol. 80:2453-2459[Abstract/Free Full Text].

15. Bontkes, H. J., T. D. de Gruijl, J. M. Walboomers, A. J. van den Muysenberg, A. W. Gunther, R. J. Scheper, C. J. Meijer, and J. A. Kummer. 1997. Assessment of cytotoxic T-lymphocyte phenotype using the specific markers granzyme B and TIA-1 in cervical neoplastic lesions. Br. J. Cancer 76:1353-1360[Medline].

16. Bosch, F. X., M. M. Manos, N. Munoz, M. Sherman, A. M. Jansen, J. Peto, M. H. Schiffman, V. Moreno, R. Kurman, and K. V. Shah. 1995. Prevalence of human papillomavirus in cervical cancer: a worldwide perspective. International biological study on cervical cancer (IBSCC) Study Group. J. Natl. Cancer Inst. 87:796-802[Abstract/Free Full Text].

17. Braun, L., M. Durst, R. Mikumo, A. Crowley, and M. Robinson. 1992. Regulation of growth and gene expression in human papillomavirus-transformed keratinocytes by transforming growth factor-beta: implications for the control of papillomavirus infection. Mol. Carcinog. 6:100-111[Medline].

18. Braun, L., M. Durst, R. Mikumo, and P. Gruppuso. 1990. Differential response of nontumorigenic and tumorigenic human papillomavirus type 16-positive epithelial cells to transforming growth factor beta 1. Cancer Res. 50:7324-7332[Abstract/Free Full Text].

19. Caceres, D. G., F. J. Tapia, M. A. Sanchez, M. Yamamura, K. Uyemura, R. L. Modlin, B. R. Bloom, and J. Convit. 1993. Determination of the cytokine profile in American cutaneous leishmaniasis using the polymerase chain reaction. Clin. Exp. Immunol. 91:500-505[Medline].

20. Chen, L., M. T. Mizuno, M. C. Singhal, H. S. L. Hu, D. A. Galloway, I. Hellstrom, and K. E. Hellstrom. 1992. Induction of cytotoxic T lymphocytes specific for a syngeneic tumor expressing the E6 oncoprotein of human papillomavirus type 16. J. Immunol. 148:2617-2621[Abstract].

21. Chen, L. P., E. K. Thomas, H. S. L. Hu, I. Hellstrom, and K. E. Hellstrom. 1991. Human papillomavirus type 16 nucleoprotein E7 is a tumor rejection antigen. Proc. Natl. Acad. Sci. USA 88:110-114[Abstract/Free Full Text].

22. Chua, K. L., and A. Hjerpe. 1996. Persistence of human papillomavirus (HPV) infections preceding cervical carcinoma. Cancer 77:121-127[CrossRef][Medline].

23. Clerici, M., M. Merola, E. Ferrario, D. Trabattoni, M. L. Villa, B. Stefanon, D. J. Venzon, G. M. Shearer, G. De Palo, and E. Clerici. 1997. Cytokine production patterns in cervical intraepithelial neoplasia: association with human papillomavirus infection. J. Natl. Cancer Inst. 89:245-250[Abstract/Free Full Text].

24. Clerici, M., and G. M. Shearer. 1993. A TH1 $right-arrow$ TH2 switch is a critical step in the etiology of HIV infection. Immunol. Today 14:107-111[CrossRef][Medline].

25. Coleman, N., H. D. Birley, A. M. Renton, N. F. Hanna, B. K. Ryait, M. Byrne, R. D. Taylor, and M. A. Stanley. 1994. Immunological events in regressing genital warts. Am. J. Clin. Pathol. 102:768-774[Medline].

26. Coleman, N., and M. A. Stanley. 1994. Analysis of HLA-DR expression on keratinocytes in cervical neoplasia. Int. J. Cancer. 56:314-319[Medline].

27. Coleman, N., and M. A. Stanley. 1994. Characterization and functional analysis of the expression of vascular adhesion molecules in human papillomavirus-related disease of the cervix. Cancer 74:884-892[CrossRef][Medline].

28. Connor, J. P., K. Ferrer, J. P. Kane, and J. M. Goldberg. 1999. Evaluation of Langerhans' cells in the cervical epithelium of women with cervical intraepithelial neoplasia. Gynecol. Oncol. 75:130-135[CrossRef][Medline].

29. Connor, M. E., and P. L. Stern. 1990. Loss of MHC class-I expression in cervical carcinomas. Int. J. Cancer. 46:1029-1034[Medline].

30. Cooper, K. D., E. J. Androphy, D. Lowy, and S. I. Katz. 1990. Antigen presentation and T-cell activation in epidermodysplasia verruciformis. J. Investig. Dermatol. 94:769-776[CrossRef][Medline].

31. Critchlow, C. W., S. E. Hawes, J. M. Kuypers, G. M. Goldbaum, K. K. Holmes, C. M. Surawicz, and N. B. Kiviat. 1998. Effect of HIV infection on the natural history of anal human papillomavirus infection. AIDS 12:1177-1184[CrossRef][Medline].

32. Critchlow, C. W., K. K. Holmes, R. Wood, L. Krueger, C. Dunphy, D. A. Vernon, J. R. Daling, and N. B. Kiviat. 1992. Association of human immunodeficiency virus and anal human papillomavirus infection among homosexual men. Arch. Intern. Med. 152:1673-1676[Abstract].

33. Critchlow, C. W., C. M. Surawicz, K. K. Holmes, J. Kuypers, J. R. Daling, S. E. Hawes, G. M. Goldbaum, J. Sayer, C. Hurt, C. Dunphy, et al. 1995. Prospective study of high grade anal squamous intraepithelial neoplasia in a cohort of homosexual men: influence of HIV infection, immunosuppression and human papillomavirus infection. AIDS 9:1255-1262[Medline].

34. Crook, T., J. P. Morgenstern, L. Crawford, and L. Banks. 1989. Continued expression of HPV-16 E7 protein is required for maintenance of the transformed phenotype of cells co-transformed by HPV-16 plus EJ-ras. EMBO J. 8:513-519[Medline].

35. Crowley-Nowick, P. A., J. H. Ellenberg, S. H. Vermund, S. D. Douglas, C. A. Holland, and A. B. Moscicki. 2000. Cytokine profile in genital tract secretions from female adolescents: impact of human immunodeficiency virus, human papillomavirus, and other sexually transmitted pathogens. J. Infect. Dis. 181:939-945[CrossRef][Medline].

36. Cubie, H. A., M. Norval, L. Crawford, L. Banks, and T. Crook. 1989. Lymphoproliferative response to fusion proteins of human papillomaviruses in patients with cervical intraepithelial neoplasia. Epidemiol. Infect. 103:625-632[Medline].

37. DeFranco, A. L. 1987. Molecular aspects of B-lymphocyte activation. Annu. Rev. Cell Biol. 3:143-178[CrossRef].

38. de Gruijl, T. D., H. J. Bontkes, J. M. Walboomers, M. J. Stukart, F. S. Doekhie, A. J. Remmink, T. J. Helmerhorst, R. H. Verheijen, M. F. Duggan-Keen, P. L. Stern, C. J. Meijer, and R. J. Scheper. 1998. Differential T helper cell responses to human papillomavirus type 16 E7 related to viral clearance or persistence in patients with cervical neoplasia: a longitudinal study. Cancer Res. 58:1700-1706[Abstract/Free Full Text].

39. de Gruijl, T. D., H. J. Bontkes, M. J. Stukart, J. M. Walboomers, A. J. Remmink, R. H. Verheijen, T. J. Helmerhorst, C. J. Meijer, and R. J. Scheper. 1996. T cell proliferative responses against human papillomavirus type 16 E7 oncoprotein are most prominent in cervical intraepithelial neoplasia patients with a persistent viral infection. J. Gen. Virol. 77:2183-2191[Abstract/Free Full Text].

40. Del Mistro, A., E. Insacco, A. Cinel, L. Bonaldi, D. Minucci, and L. Chieco-Bianchi. 1994. Human papillomavirus infections of the genital region in human immunodeficiency virus seropositive women: integration of type 16 correlates with rapid progression. Eur. J. Gynaecol. Oncol. 15:50-58[Medline].

41. De Marco, F., and M. L. Marcante. 1995. Cellular and molecular analyses of interferon beta cytopathic effect on HPV-16 in vitro transformed human keratinocytes (HPK-IA). J. Biol. Regul. Homeost. Agents 9:24-30[Medline].

42. De Marco, F., F. Giannoni, and M. L. Marcante. 1995. Interferon-beta strong cytopathic effect on human papillomavirus type 16-immortalized HPK-IA cell line, unexpectedly not shared by interferon-alpha. J. Gen. Virol. 76:445-450[Abstract/Free Full Text].

43. Dolei, A., S. Curreli, P. Marongiu, A. Pierangeli, E. Gomes, M. Bucci, C. Serra, and A. M. Degener. 1999. Human immunodeficiency virus infection in vitro activates naturally integrated human papillomavirus type 18 and induces synthesis of the L1 capsid protein. J. Gen. Virol. 80:2937-2944[Abstract/Free Full Text].

44. Dupuy, C., D. Buzoni-Gatel, A. Touze, P. Le Cann, D. Bout, and P. Coursaget. 1997. Cell mediated immunity induced in mice by HPV 16 L1 virus-like particles. Microb. Pathog. 22:219-225[CrossRef][Medline].

45. Dyson, N., P. M. Howley, K. Munger, and E. Harlow. 1989. The human papilloma virus-16 E7 oncoprotein is able to bind to the retinoblastoma gene product. Science 243:934-937[Abstract/Free Full Text].

46. Eckert, L. O., D. H. Watts, L. A. Koutsky, S. E. Hawes, C. E. Stevens, J. Kuypers, and N. B. Kiviat. 1999. A matched prospective study of human immunodeficiency virus serostatus, human papillomavirus DNA, and cervical lesions detected by cytology and colposcopy. Infect. Dis. Obstet. Gynecol. 7:158-164[CrossRef][Medline].

47. Evander, M., K. Edlund, A. Gustafsson, M. Jonsson, R. Karlsson, E. Rylander, and G. Wadell. 1995. Human papillomavirus infection is transient in young women: a population-based cohort study. J. Infect. Dis. 171:1026-1030[Medline].

48. Evans, C., S. Bauer, T. Grubert, C. Brucker, S. Baur, K. Heeg, H. Wagner, and G. B. Lipford. 1996. HLA-A2-restricted peripheral blood cytolytic T lymphocyte response to HPV type 16 proteins E6 and E7 from patients with neoplastic cervical lesions. Cancer Immunol. Immunother. 42:151-160[CrossRef][Medline].

49. Evans, E. M., S. Man, A. S. Evans, and L. K. Borysiewicz. 1997. Infiltration of cervical cancer tissue with human papillomavirus-specific cytotoxic T-lymphocytes. Cancer Res. 57:2943-2950[Abstract/Free Full Text].

50. Fairley, C. K., S. Chen, S. N. Tabrizi, J. McNeil, G. Becker, R. Walker, R. C. Atkins, N. Thomson, P. Allan, C. Woodburn, et al. 1994. Prevalence of HPV DNA in cervical specimens in women with renal transplants: a comparison with dialysis-dependent patients and patients with renal impairment. Nephrol. Dial. Transplant. 9:416-420[Abstract/Free Full Text].

51. Feltkamp, M. C., H. L. Smits, M. P. Vierboom, R. P. Minnaar, B. M. de Jongh, J. W. Drijfhout, J. ter Schegget, C. J. Melief, and W. M. Kast. 1993. Vaccination with cytotoxic T lymphocyte epitope-containing peptide protects against a tumor induced by human papillomavirus type 16-transformed cells. Eur. J. Immunol. 23:2242-2249[Medline].

52. Feltkamp, M. C., G. R. Vreugdenhil, M. P. Vierboom, E. Ras, S. H. van der Burg, J. ter Schegget, C. J. Melief, and W. M. Kast. 1995. Cytotoxic T lymphocytes raised against a subdominant epitope offered as a synthetic peptide eradicate human papillomavirus type 16-induced tumors. Eur. J. Immunol. 25:2638-2642[Medline].

53. Frazer, I. H., R. Thomas, J. Zhou, G. R. Leggatt, L. Dunn, N. McMillan, R. W. Tindle, L. Filgueira, P. Manders, P. Barnard, and M. Sharkey. 1999. Potential strategies utilised by papillomavirus to evade host immunity. Immunol. Rev. 168:131-142[CrossRef][Medline].

54. Garzetti, G. G., A. Ciavattini, G. Goteri, M. De Nictolis, S. Menso, M. Muzzioli, and N. Fabris. 1995. HPV DNA positivity and natural killer cell activity in the clinical outcome of mild cervical dysplasia: integration between virus and immune system. Gynecol. Obstet. Investig. 39:130-135[Medline].

55. Gill, D. K., J. M. Bible, C. Biswas, B. Kell, J. M. Best, N. A. Punchard, and J. Cason. 1998. Proliferative T-cell responses to human papillomavirus type 16 E5 are decreased amongst women with high-grade neoplasia. J. Gen. Virol. 79:1971-1976[Abstract].

56. Glasebrook, A. L., and F. W. Fitch. 1979. T-cell lines which cooperate in generation of specific cytolytic activity. Nature 278:171-173[CrossRef][Medline].

57. Greenberg, P. D. 1991. Adoptive T cell therapy of tumors: mechanisms operative in the recognition and elimination of tumor cells. Adv. Immunol. 49:281-355[Medline].

58. Hawley-Nelson, P., K. H. Vousden, N. L. Hubbert, D. R. Lowy, and J. T. Schiller. 1989. HPV 16 E6 and E7 proteins cooperate to immortalize human foreskin keratinocytes. EMBO J. 8:3905-3910[Medline].

59. Hildesheim, A., M. H. Schiffman, P. E. Gravitt, A. G. Glass, C. E. Greer, T. Zhang, D. R. Scott, B. B. Rush, P. Lawler, M. E. Sherman, et al. 1994. Persistence of type-specific human papillomavirus infection among cytologically normal women. J. Infect. Dis. 169:235-240[Medline].

60. Hillemanns, P., T. V. Ellerbrock, S. McPhillips, P. Dole, S. Alperstein, D. Johnson, X. W. Sun, M. A. Chiasson, and T. C. Wright, Jr. 1996. Prevalence of anal human papillomavirus infection and anal cytologic abnormalities in HIV-seropositive women. AIDS 10:1641-1647[Medline].

61. Ho, G. Y., R. Bierman, L. Beardsley, C. J. Chang, and R. D. Burk. 1998. Natural history of cervicovaginal papillomavirus infection in young women. N. Engl. J. Med. 338:423-428[Abstract/Free Full Text].

62. Hohn, H., H. Pilch, S. Gunzel, C. Neukirch, C. Hilmes, A. Kaufmann, B. Seliger, and M. J. Maeurer. 1999. CD4+ tumor-infiltrating lymphocytes in cervical cancer recognize HLA-DR-restricted peptides provided by human papillomavirus-E7. J. Immunol. 163:5715-5722

1.	Alexander, M., M. L. Salgaller, E. Celis, A. Sette, W. A. Barnes, S. A. Rosenberg, and M. A. Steller. 1996. Generation of tumor-specific cytolytic T lymphocytes from peripheral blood of cervical cancer patients by in vitro stimulation with a synthetic human papillomavirus type 16 E7 epitope. Am. J. Obstet. Gynecol. 175:1586-1593[CrossRef][Medline].
2.	al-Saleh, W., S. L. Giannini, N. Jacobs, M. Moutschen, J. Doyen, J. Boniver, and P. Delvenne. 1998. Correlation of T-helper secretory differentiation and types of antigen-presenting cells in squamous intraepithelial lesions of the uterine cervix. J. Pathol. 184:283-290[CrossRef][Medline].
3.	Alter, B. J., C. Grillot-Courvalin, M. L. Bach, K. S. Zier, P. M. Sondel, and F. H. Bach. 1976. Secondary cell-mediated lympholysis: importance of H-2 LD and SD factors. J. Exp. Med. 143:1005-1014[Abstract/Free Full Text].
4.	Arany, I., A. Goel, and S. K. Tyring. 1995. Interferon response depends on viral transcription in human papillomavirus-containing lesions. Anticancer Res. 15:2865-2869[Medline].
5.	Arany, I., P. Rady, and S. K. Tyring. 1995. Effect of interferon therapy on human papillomavirus copy number in patients with condyloma acuminatum. Am. J. Med. Sci. 310:14-18[Medline].
6.	Arany, I., and S. K. Tyring. 1996. Activation of local cell-mediated immunity in interferon-responsive patients with human papillomavirus-associated lesions. J. Interferon Cytokine Res. 16:453-460[Medline].
7.	Arany, I., and S. K. Tyring. 1996. Status of local cellular immunity in interferon-responsive and -nonresponsive human papillomavirus-associated lesions. Sex. Transm. Dis. 23:475-480[Medline].
8.	Arany, I., and S. K. Tyring. 1998. Systemic immunosuppression by HIV infection influences HPV transcription and thus local immune responses in condyloma acuminatum. Int. J. STD AIDS 9:268-271[Abstract/Free Full Text].
9.	Aynaud, O., D. Piron, R. Barrasso, and J. D. Poveda. 1998. Comparison of clinical, histological, and virological symptoms of HPV in HIV-1 infected men and immunocompetent subjects. Sex. Transm. Infect. 74:32-34[Abstract].
10.	Barker, J. N., R. S. Mitra, C. E. Griffiths, V. M. Dixit, and B. J. Nickoloff. 1991. Keratinocytes as initiators of inflammation. Lancet 337:211-214[CrossRef][Medline].
11.	Barker, J. N., V. Sarma, R. S. Mitra, V. M. Dixit, and B. J. Nickoloff. 1990. Marked synergism between tumor necrosis factor-alpha and interferon-gamma in regulation of keratinocyte-derived adhesion molecules and chemotactic factors. J. Clin. Investig. 85:605-608.
12.	Barnard, P., and N. A. McMillan. 1999. The human papillomavirus E7 oncoprotein abrogates signaling mediated by interferon-alpha. Virology 259:305-313[CrossRef][Medline].
13.	Beer-Romero, P., S. Glass, and M. Rolfe. 1997. Antisense targeting of E6AP elevates p53 in HPV-infected cells but not in normal cells. Oncogene 14:595-602[CrossRef][Medline].
14.	Bontkes, H. J., T. D. de Gruijl, A. Bijl, R. H. Verheijen, C. J. Meijer, R. J. Scheper, P. L. Stern, J. E. Burns, N. J. Maitland, and J. M. Walboomers. 1999. Human papillomavirus type 16 E2-specific T-helper lymphocyte responses in patients with cervical intraepithelial neoplasia. J. Gen. Virol. 80:2453-2459[Abstract/Free Full Text].
15.	Bontkes, H. J., T. D. de Gruijl, J. M. Walboomers, A. J. van den Muysenberg, A. W. Gunther, R. J. Scheper, C. J. Meijer, and J. A. Kummer. 1997. Assessment of cytotoxic T-lymphocyte phenotype using the specific markers granzyme B and TIA-1 in cervical neoplastic lesions. Br. J. Cancer 76:1353-1360[Medline].
16.	Bosch, F. X., M. M. Manos, N. Munoz, M. Sherman, A. M. Jansen, J. Peto, M. H. Schiffman, V. Moreno, R. Kurman, and K. V. Shah. 1995. Prevalence of human papillomavirus in cervical cancer: a worldwide perspective. International biological study on cervical cancer (IBSCC) Study Group. J. Natl. Cancer Inst. 87:796-802[Abstract/Free Full Text].
17.	Braun, L., M. Durst, R. Mikumo, A. Crowley, and M. Robinson. 1992. Regulation of growth and gene expression in human papillomavirus-transformed keratinocytes by transforming growth factor-beta: implications for the control of papillomavirus infection. Mol. Carcinog. 6:100-111[Medline].
18.	Braun, L., M. Durst, R. Mikumo, and P. Gruppuso. 1990. Differential response of nontumorigenic and tumorigenic human papillomavirus type 16-positive epithelial cells to transforming growth factor beta 1. Cancer Res. 50:7324-7332[Abstract/Free Full Text].
19.	Caceres, D. G., F. J. Tapia, M. A. Sanchez, M. Yamamura, K. Uyemura, R. L. Modlin, B. R. Bloom, and J. Convit. 1993. Determination of the cytokine profile in American cutaneous leishmaniasis using the polymerase chain reaction. Clin. Exp. Immunol. 91:500-505[Medline].
20.	Chen, L., M. T. Mizuno, M. C. Singhal, H. S. L. Hu, D. A. Galloway, I. Hellstrom, and K. E. Hellstrom. 1992. Induction of cytotoxic T lymphocytes specific for a syngeneic tumor expressing the E6 oncoprotein of human papillomavirus type 16. J. Immunol. 148:2617-2621[Abstract].
21.	Chen, L. P., E. K. Thomas, H. S. L. Hu, I. Hellstrom, and K. E. Hellstrom. 1991. Human papillomavirus type 16 nucleoprotein E7 is a tumor rejection antigen. Proc. Natl. Acad. Sci. USA 88:110-114[Abstract/Free Full Text].
22.	Chua, K. L., and A. Hjerpe. 1996. Persistence of human papillomavirus (HPV) infections preceding cervical carcinoma. Cancer 77:121-127[CrossRef][Medline].
23.	Clerici, M., M. Merola, E. Ferrario, D. Trabattoni, M. L. Villa, B. Stefanon, D. J. Venzon, G. M. Shearer, G. De Palo, and E. Clerici. 1997. Cytokine production patterns in cervical intraepithelial neoplasia: association with human papillomavirus infection. J. Natl. Cancer Inst. 89:245-250[Abstract/Free Full Text].
24.	Clerici, M., and G. M. Shearer. 1993. A TH1 $right-arrow$ TH2 switch is a critical step in the etiology of HIV infection. Immunol. Today 14:107-111[CrossRef][Medline].
25.	Coleman, N., H. D. Birley, A. M. Renton, N. F. Hanna, B. K. Ryait, M. Byrne, R. D. Taylor, and M. A. Stanley. 1994. Immunological events in regressing genital warts. Am. J. Clin. Pathol. 102:768-774[Medline].
26.	Coleman, N., and M. A. Stanley. 1994. Analysis of HLA-DR expression on keratinocytes in cervical neoplasia. Int. J. Cancer. 56:314-319[Medline].
27.	Coleman, N., and M. A. Stanley. 1994. Characterization and functional analysis of the expression of vascular adhesion molecules in human papillomavirus-related disease of the cervix. Cancer 74:884-892[CrossRef][Medline].
28.	Connor, J. P., K. Ferrer, J. P. Kane, and J. M. Goldberg. 1999. Evaluation of Langerhans' cells in the cervical epithelium of women with cervical intraepithelial neoplasia. Gynecol. Oncol. 75:130-135[CrossRef][Medline].
29.	Connor, M. E., and P. L. Stern. 1990. Loss of MHC class-I expression in cervical carcinomas. Int. J. Cancer. 46:1029-1034[Medline].
30.	Cooper, K. D., E. J. Androphy, D. Lowy, and S. I. Katz. 1990. Antigen presentation and T-cell activation in epidermodysplasia verruciformis. J. Investig. Dermatol. 94:769-776[CrossRef][Medline].
31.	Critchlow, C. W., S. E. Hawes, J. M. Kuypers, G. M. Goldbaum, K. K. Holmes, C. M. Surawicz, and N. B. Kiviat. 1998. Effect of HIV infection on the natural history of anal human papillomavirus infection. AIDS 12:1177-1184[CrossRef][Medline].
32.	Critchlow, C. W., K. K. Holmes, R. Wood, L. Krueger, C. Dunphy, D. A. Vernon, J. R. Daling, and N. B. Kiviat. 1992. Association of human immunodeficiency virus and anal human papillomavirus infection among homosexual men. Arch. Intern. Med. 152:1673-1676[Abstract].
33.	Critchlow, C. W., C. M. Surawicz, K. K. Holmes, J. Kuypers, J. R. Daling, S. E. Hawes, G. M. Goldbaum, J. Sayer, C. Hurt, C. Dunphy, et al. 1995. Prospective study of high grade anal squamous intraepithelial neoplasia in a cohort of homosexual men: influence of HIV infection, immunosuppression and human papillomavirus infection. AIDS 9:1255-1262[Medline].
34.	Crook, T., J. P. Morgenstern, L. Crawford, and L. Banks. 1989. Continued expression of HPV-16 E7 protein is required for maintenance of the transformed phenotype of cells co-transformed by HPV-16 plus EJ-ras. EMBO J. 8:513-519[Medline].
35.	Crowley-Nowick, P. A., J. H. Ellenberg, S. H. Vermund, S. D. Douglas, C. A. Holland, and A. B. Moscicki. 2000. Cytokine profile in genital tract secretions from female adolescents: impact of human immunodeficiency virus, human papillomavirus, and other sexually transmitted pathogens. J. Infect. Dis. 181:939-945[CrossRef][Medline].
36.	Cubie, H. A., M. Norval, L. Crawford, L. Banks, and T. Crook. 1989. Lymphoproliferative response to fusion proteins of human papillomaviruses in patients with cervical intraepithelial neoplasia. Epidemiol. Infect. 103:625-632[Medline].
37.	DeFranco, A. L. 1987. Molecular aspects of B-lymphocyte activation. Annu. Rev. Cell Biol. 3:143-178[CrossRef].
38.	de Gruijl, T. D., H. J. Bontkes, J. M. Walboomers, M. J. Stukart, F. S. Doekhie, A. J. Remmink, T. J. Helmerhorst, R. H. Verheijen, M. F. Duggan-Keen, P. L. Stern, C. J. Meijer, and R. J. Scheper. 1998. Differential T helper cell responses to human papillomavirus type 16 E7 related to viral clearance or persistence in patients with cervical neoplasia: a longitudinal study. Cancer Res. 58:1700-1706[Abstract/Free Full Text].
39.	de Gruijl, T. D., H. J. Bontkes, M. J. Stukart, J. M. Walboomers, A. J. Remmink, R. H. Verheijen, T. J. Helmerhorst, C. J. Meijer, and R. J. Scheper. 1996. T cell proliferative responses against human papillomavirus type 16 E7 oncoprotein are most prominent in cervical intraepithelial neoplasia patients with a persistent viral infection. J. Gen. Virol. 77:2183-2191[Abstract/Free Full Text].
40.	Del Mistro, A., E. Insacco, A. Cinel, L. Bonaldi, D. Minucci, and L. Chieco-Bianchi. 1994. Human papillomavirus infections of the genital region in human immunodeficiency virus seropositive women: integration of type 16 correlates with rapid progression. Eur. J. Gynaecol. Oncol. 15:50-58[Medline].
41.	De Marco, F., and M. L. Marcante. 1995. Cellular and molecular analyses of interferon beta cytopathic effect on HPV-16 in vitro transformed human keratinocytes (HPK-IA). J. Biol. Regul. Homeost. Agents 9:24-30[Medline].
42.	De Marco, F., F. Giannoni, and M. L. Marcante. 1995. Interferon-beta strong cytopathic effect on human papillomavirus type 16-immortalized HPK-IA cell line, unexpectedly not shared by interferon-alpha. J. Gen. Virol. 76:445-450[Abstract/Free Full Text].
43.	Dolei, A., S. Curreli, P. Marongiu, A. Pierangeli, E. Gomes, M. Bucci, C. Serra, and A. M. Degener. 1999. Human immunodeficiency virus infection in vitro activates naturally integrated human papillomavirus type 18 and induces synthesis of the L1 capsid protein. J. Gen. Virol. 80:2937-2944[Abstract/Free Full Text].
44.	Dupuy, C., D. Buzoni-Gatel, A. Touze, P. Le Cann, D. Bout, and P. Coursaget. 1997. Cell mediated immunity induced in mice by HPV 16 L1 virus-like particles. Microb. Pathog. 22:219-225[CrossRef][Medline].
45.	Dyson, N., P. M. Howley, K. Munger, and E. Harlow. 1989. The human papilloma virus-16 E7 oncoprotein is able to bind to the retinoblastoma gene product. Science 243:934-937[Abstract/Free Full Text].
46.	Eckert, L. O., D. H. Watts, L. A. Koutsky, S. E. Hawes, C. E. Stevens, J. Kuypers, and N. B. Kiviat. 1999. A matched prospective study of human immunodeficiency virus serostatus, human papillomavirus DNA, and cervical lesions detected by cytology and colposcopy. Infect. Dis. Obstet. Gynecol. 7:158-164[CrossRef][Medline].
47.	Evander, M., K. Edlund, A. Gustafsson, M. Jonsson, R. Karlsson, E. Rylander, and G. Wadell. 1995. Human papillomavirus infection is transient in young women: a population-based cohort study. J. Infect. Dis. 171:1026-1030[Medline].
48.	Evans, C., S. Bauer, T. Grubert, C. Brucker, S. Baur, K. Heeg, H. Wagner, and G. B. Lipford. 1996. HLA-A2-restricted peripheral blood cytolytic T lymphocyte response to HPV type 16 proteins E6 and E7 from patients with neoplastic cervical lesions. Cancer Immunol. Immunother. 42:151-160[CrossRef][Medline].
49.	Evans, E. M., S. Man, A. S. Evans, and L. K. Borysiewicz. 1997. Infiltration of cervical cancer tissue with human papillomavirus-specific cytotoxic T-lymphocytes. Cancer Res. 57:2943-2950[Abstract/Free Full Text].
50.	Fairley, C. K., S. Chen, S. N. Tabrizi, J. McNeil, G. Becker, R. Walker, R. C. Atkins, N. Thomson, P. Allan, C. Woodburn, et al. 1994. Prevalence of HPV DNA in cervical specimens in women with renal transplants: a comparison with dialysis-dependent patients and patients with renal impairment. Nephrol. Dial. Transplant. 9:416-420[Abstract/Free Full Text].
51.	Feltkamp, M. C., H. L. Smits, M. P. Vierboom, R. P. Minnaar, B. M. de Jongh, J. W. Drijfhout, J. ter Schegget, C. J. Melief, and W. M. Kast. 1993. Vaccination with cytotoxic T lymphocyte epitope-containing peptide protects against a tumor induced by human papillomavirus type 16-transformed cells. Eur. J. Immunol. 23:2242-2249[Medline].
52.	Feltkamp, M. C., G. R. Vreugdenhil, M. P. Vierboom, E. Ras, S. H. van der Burg, J. ter Schegget, C. J. Melief, and W. M. Kast. 1995. Cytotoxic T lymphocytes raised against a subdominant epitope offered as a synthetic peptide eradicate human papillomavirus type 16-induced tumors. Eur. J. Immunol. 25:2638-2642[Medline].
53.	Frazer, I. H., R. Thomas, J. Zhou, G. R. Leggatt, L. Dunn, N. McMillan, R. W. Tindle, L. Filgueira, P. Manders, P. Barnard, and M. Sharkey. 1999. Potential strategies utilised by papillomavirus to evade host immunity. Immunol. Rev. 168:131-142[CrossRef][Medline].
54.	Garzetti, G. G., A. Ciavattini, G. Goteri, M. De Nictolis, S. Menso, M. Muzzioli, and N. Fabris. 1995. HPV DNA positivity and natural killer cell activity in the clinical outcome of mild cervical dysplasia: integration between virus and immune system. Gynecol. Obstet. Investig. 39:130-135[Medline].
55.	Gill, D. K., J. M. Bible, C. Biswas, B. Kell, J. M. Best, N. A. Punchard, and J. Cason. 1998. Proliferative T-cell responses to human papillomavirus type 16 E5 are decreased amongst women with high-grade neoplasia. J. Gen. Virol. 79:1971-1976[Abstract].
56.	Glasebrook, A. L., and F. W. Fitch. 1979. T-cell lines which cooperate in generation of specific cytolytic activity. Nature 278:171-173[CrossRef][Medline].
57.	Greenberg, P. D. 1991. Adoptive T cell therapy of tumors: mechanisms operative in the recognition and elimination of tumor cells. Adv. Immunol. 49:281-355[Medline].
58.	Hawley-Nelson, P., K. H. Vousden, N. L. Hubbert, D. R. Lowy, and J. T. Schiller. 1989. HPV 16 E6 and E7 proteins cooperate to immortalize human foreskin keratinocytes. EMBO J. 8:3905-3910[Medline].
59.	Hildesheim, A., M. H. Schiffman, P. E. Gravitt, A. G. Glass, C. E. Greer, T. Zhang, D. R. Scott, B. B. Rush, P. Lawler, M. E. Sherman, et al. 1994. Persistence of type-specific human papillomavirus infection among cytologically normal women. J. Infect. Dis. 169:235-240[Medline].
60.	Hillemanns, P., T. V. Ellerbrock, S. McPhillips, P. Dole, S. Alperstein, D. Johnson, X. W. Sun, M. A. Chiasson, and T. C. Wright, Jr. 1996. Prevalence of anal human papillomavirus infection and anal cytologic abnormalities in HIV-seropositive women. AIDS 10:1641-1647[Medline].
61.	Ho, G. Y., R. Bierman, L. Beardsley, C. J. Chang, and R. D. Burk. 1998. Natural history of cervicovaginal papillomavirus infection in young women. N. Engl. J. Med. 338:423-428[Abstract/Free Full Text].
62.	Hohn, H., H. Pilch, S. Gunzel, C. Neukirch, C. Hilmes, A. Kaufmann, B. Seliger, and M. J. Maeurer. 1999. CD4+ tumor-infiltrating lymphocytes in cervical cancer recognize HLA-DR-restricted peptides provided by human papillomavirus-E7. J. Immunol. 163:5715-5722

MINIREVIEW Cell-Mediated Immune Response to Human Papillomavirus Infection

MINIREVIEW
Cell-Mediated Immune Response to Human Papillomavirus Infection