Human antibodies recognize multiple distinct type-specific and cross-reactive regions of the minor capsid proteins of human papillomavirus types 6 and 11.

Human serum samples derived from a case-control study of patients with cervical carcinoma (n = 174) or condyloma acuminatum (n = 25) were tested for the presence of immunoglobulin G antibodies to human papillomavirus type 6 (HPV6) L2 and HPV11 L2 recombinant proteins in a Western immunoblot assay. Thirty-six samples (18%) were positive for HPV6 L2 antibodies alone, 25 (13%) were positive for HPV11 L2 antibodies alone, and 34 (17%) were positive for both HPV6 L2 and HPV11 L2 antibodies. Thirty samples that were positive for both antibodies were tested for the presence of HPV6-HPV11 L2 cross-reactive antibodies. Fifteen (50%) serum samples contained HPV6-HPV11 L2 cross-reactive antibodies, and 15 (50%) contained independent, type-specific HPV6 L2 and HPV11 L2 antibodies. Altogether, 82% of the HPV6 L2 and HPV11 L2 antibody reactivities were type specific and 18% were HPV6-HPV11 cross-reactive. There was no significant difference in the prevalence of antibody reactivities between samples from patients with cervical carcinoma and those with condyloma acuminatum. Deletion mapping identified five HPV6 L2 regions that reacted with HPV6 type-specific antibodies: 6U1 (amino acids [aa] 152 to 173), 6U2 (aa 175 to 191), 6U3 (aa 187 to 199), 6U4 (aa 201 to 217), and 6U5 (aa 351 to 367). Five HPV11 L2 regions that reacted with HPV11 type-specific antibodies were identified: 11U1 (aa 49 to 84), 11U2 (aa 147 to 162), 11U3 (aa 179 to 188), 11U4 (aa 180 to 200), and 11U5 (aa 355 to 367). Two HPV6-HPV11 cross-reactive regions were identified: 6CR1 (HPV6 L2 aa 106 to 128)/11CR1 (HPV11 L2 aa 103 to 127) and 6CR2 (HPV6 L2 aa 187 to 199)/11CR2 (HPV11 L2 aa 180 to 200).     

人乳头瘤病毒6型L1基因的克隆及蛋白表达

目的：在大肠杆菌中表达经密码子优化的人乳头瘤病毒6型（HPV6）L1的融合蛋白。方法：PCR方法扩增HPV6 L1,基因,测序及序列比对后,对基因进行密码子优化并合成优化后的基因HPV6mLI,将其克隆入原核表达载体pGEX4T-1,IPTG诱导融合蛋白在大肠杆菌BL21（DE3）中表达,SDS-PAGE鉴定表达产物。结果：酶切和测序结果证实HPV6 mL1基因的原核表达载体构建正确;以1mmol／L IPTG于37℃诱导4h,蛋白以包涵体形式表达;表达产物的相对分子质量与预期值一致,为80000。结论：获得大肠杆菌表达的HPV6L1蛋白,为其结构功能研究和疫苗研发提供了基础。     

用昆虫-杆状病毒系统表达的HPV6型L1蛋白检测尖锐湿疣患者血清中抗体

用杆状病毒表达系统表达人乳头瘤病毒6型（human papillomavirus type 6,HPV6）主要衣壳蛋白（major capsid protein,L1）作为抗原,对尖锐湿疣（condyloma acuminata,CA）患者抗体进行检测。采用昆虫杆状病毒系统表达HPV6L1蛋白,通过镍柱亲和层析法获得纯化抗原;以酶联免疫吸附试验（enzyme-linked immunosorbent assay,ELISA）检测30例CA、20例献血员和10例儿童血清中的HPV6 LI IgG抗体。感染重组杆状病毒的昆虫细胞经SDS-PAGE和Western blot检测,在大约55kD处有明显的外源蛋白表达条带。ELISA结果显示,CA组的血清阳性率为66．7％（20／30）,献血员组的阳性率为15％（3／20）,两组之间有显著性差异（P〈0．05）。22例HPV6型感染的CA患者有15例血清阳性（68．2％）,6例HPV11型CA患者4例阳性（66．7％）,1例混合感染者为阳性,1例HPV16型患者为阴性。女性CA患者的血清抗体阳性率高于男性（P=0．0052）。本研究建立的ELISA体系具有敏感性和针对低危型HPV感染的特异性。这不仅对于HPV血清流行病学研究是有价值的,而且对于临床诊断HPV感染可能具有一定的应用价值。     

HPV6L1/CtMOMP多表位融合基因在COS-7细胞的表达及其在小鼠的免疫效果观察

研究人乳头瘤病毒(human papillomavirus,HPV)6b结构蛋白L1(HPV6b L1)基因佐剂增强沙眼衣原体(Chlamydia trachomatis,Ct)主要外膜蛋白(MOMP)多表位(Ct MOMP168)DNA疫苗的免疫效果的可能性.构建pcDNA3.1(+)/HPV6b L1/Ct MOMP168融合重组质粒,转染COS-7细胞,用RT-PCR、激光共聚焦显微技术及Western印迹技术检测其表达.分别用pcDNA3.1(+)/HPV6b L1/Ct MOMP168、pcDNA3.1(+)/Ct MOMP168及pcDNA3.1(+)质粒肌肉免疫BALB/c小鼠,ELISA检测外周血中IgG及阴道分泌物中sIgA.结果表明,pcDNA3.1(+)/HPV6b L1/CtMOMP168可在COS-7细胞中表达;Ct MOMP168组和HPV6b L1/Ct MOMP168组均可刺激小鼠产生抗Ct MOMP特异性的抗体,抗体滴度随免疫次数增加而升高,且HPV6b L1/Ct MOMP168组小鼠产生的抗体滴度明显高于Ct MOMP168组(P0.05).结果提示,分子佐剂HPV6b L1与CtMOMP多表位基因融合能够显著增强Ct MOMP多表位DNA疫苗的体液免疫应答.     

Expression of human papillomavirus types 6b and 16 L1 open reading frames in Escherichia coli: detection of a 56,000-dalton polypeptide containing genus-specific (common) antigens.

The human papillomavirus (HPV) genome contains two large open reading frames (ORFs), designated L1 and L2. To characterize the antigenic properties of the L1 ORF-encoded proteins, we cloned the L1 ORFs of HPV6b and HPV16 in plasmids, and these were expressed in Escherichia coli. First, the HPV6b DNA, representing 85.2% of the L1 ORF, was cloned in pUC19 and expressed in E. coli JM83 and RB791 as a 160,000-molecular-weight (160K) fusion protein with E. coli beta-galactosidase (6bL1/beta-gal). Second, the HPV16 DNA, representing 89.8% of the L1 ORF, was cloned in pKK233-2 and expressed as a 56K protein (16L1) in strain RB791. Both the 6bL1/beta-gal and 16L1 proteins cross-reacted with anti-bovine papillomavirus type 1 (BPV1) antibody raised against disrupted BPV1 particles. An antibody raised against the 6bL1/beta-gal fusion protein reacted with the 16L1 protein and also with native papillomavirus antigens in human genital condyloma and bovine fibropapilloma tissues, as determined by biotin-streptavidin staining. Furthermore, the anti-6bL1/beta-gal antibody recognized a 54K protein which seemed to be a major capsid protein of BPV1 and also a 56K protein of biopsies harboring HPV6 or HPV11. From these results we concluded that the papillomavirus L1 gene product contains genus-specific (common) antigens and that the HPV6 and HPV11 L1 genes specify the 56K capsid protein.     

Human antibodies react with an epitope of the human papillomavirus type 6b L1 open reading frame which is distinct from the type-common epitope.

Recombinant proteins encoded by the human papillomavirus type 6b (HPV6b) L1 open reading frame react with sera from patients with condylomata acuminata and also react with rabbit antiserum raised against sodium dodecyl sulfate-disrupted bovine papillomavirus type 1 (BPV1) virions. To map the immunoreactive epitopes, a series of procaryotic expression plasmids was made which contained a nested set of 3' to 5' deletions in the HPV6b L1 open reading frame. The deleted plasmids expressed a set of carboxy to amino terminus truncated fusion proteins. Regions containing the immunoreactive epitopes were mapped by determining which of the deleted fusion proteins retained reactivity with sera in Western immunoblot assays. The coding sequence for a human antibody-reactive linear epitope mapped between HPV6b nucleotide coordinates 7045 and 7087, and the rabbit anti-BPV1-reactive epitope coding sequence mapped between coordinates 6377 and 6454. Synthetic peptides derived from the epitope mapping were reacted with sera in enzyme-linked immunosorbent assay. Human sera reacted with synthetic peptide QSQAITCQKPTPEKEKPDPYK (HPV6b L1 amino acids 417 through 437). Rabbit anti-BPV1 and rabbit antisera raised against HPV16 L1 recombinant proteins reacted with the synthetic peptide DGDMVDTGFGAMNFADLQTNKSDVPIDI (HPV6b L1 amino acids 193 through 220). Human sera which reacted with HPV6b L1 fusion proteins cross-reacted with an HPV11 L1 fusion protein but did not react with fusion proteins encoded by HPV1a, HPV16, or HPV18. Rabbit anti-BPV1 reacted with L1 fusion proteins encoded by all of these HPV types. In contrast to the type-common (rabbit anti-BPV1-reactive) epitope, the human antibody-reactive epitope appears to be relatively HPV type specific.     

HPV 6b L1基因原核表达系统的构建及鉴定

克隆、构建人乳头瘤病毒6b型(HPV6b)L1基因重组质粒,并进行表达和鉴定。用PCR方法,从尖锐湿疣标本中扩增出HPV6b型L1基因,构建重组克隆质粒pblue-HPV6bL1,测序分析其基因变异。将本地株HPV6b型L1基因酶切后连接到原核表达质粒pBAD,构建原核表达系统pBAD-HPV6bL1/Top10,酶切鉴定证明重组质粒的正确性。经L-Arobinose诱导后表达HPV6b型L1蛋白,利用SDS-PAGE对表达产物进行鉴定。经酶切及序列分析鉴定,重组质粒pBAD-HPV6bL1构建成功,诱导后能够表达L1融合蛋白。HPV6bL1重组质粒构建成功,并获得HPV6bL1蛋白,为该蛋白的功能及HPV的基因工程疫苗研究提供了物质基础。     

Cross-reactivity of antigens and antibodies belonging to different pathogenic types of human papillomaviruses

The analysis of the properties of a quadrivalent peroral vaccine against the cervical cancer, which was created in a plant expression system on the base of transgenic tomato fruits, by immunoassay and Western blot hybridization showed that the antibodies against human papilloma virus 16 L1 (HPV16 L1) actively interacted not only with the antigenic proteins HPV18 L1, HPV31 L1, and HPV45 L1, but also with the antigenic protein HPV6 L1, which belongs to another HPV family. Thus, new data on the possibility of crossreactivity between antibodies and antigens belonging to remote HPV families were obtained.     

Humoral immune response recognizes a complex set of epitopes on human papillomavirus type 6 l1 capsomers

Although epitope mapping has identified residues on the human papillomavirus (HPV) major capsid protein (L1) that are important for binding mouse monoclonal antibodies, epitopes recognized by human antibodies are not known. To map epitopes on HPV type 6 (HPV6) L1, surface-exposed loops were mutated to the corresponding sequence of HPV11 L1. HPV6 L1 capsomers had one to six regions mutated, including the BC, DE, EF, FG, and HI loops and the 139 C-terminal residues. After verifying proper conformation, hybrid capsomers were used in enzyme-linked immunosorbent assays with 36 HPV6-seropositive sera from women enrolled in a study of incident HPV infection. Twelve sera were HPV6 specific, while the remainder reacted with both HPV6 and HPV11 L1. By preadsorption studies, 6/11 of these sera were shown to be cross-reactive. Among the HPV6-specific sera there was no immunodominant epitope recognized by all sera. Six of the 12 sera recognized epitopes that contained residues from combinations of the BC, DE, and FG loops, one serum recognized an epitope that consisted partially of the C-terminal arm, and three sera recognized complex epitopes to which reactivity was eliminated by switching all five loops. Reactivity in two sera was not eliminated even with all six regions swapped. The patterns of epitope recognition did not change over time in women whose sera were examined 9 years after their first-seropositive visit.     

HPV16 L1蛋白在大肠杆菌中的表达、纯化及免疫原性研究

用IPTG诱导目的工程菌pQE31-HPV16L1/M15(pREP4),对表达产物进行SDSPAGE和Western blot分析;用表达的L1蛋白免疫BAL B/C小鼠得到抗血清后,利用真核源性的VLP粗提物验证小鼠抗血清的特异性.利用IMAC金属亲和层析柱纯化L1蛋白.SDSPAGE结果显示表达产物在约57 ku处有蛋白条带;Western blot结果证实此条带可与HPV16 L1蛋白的单克隆抗体反应;纯化后的L1蛋白也同样保留免疫特异性;小鼠抗血清可与HPV16L1 VLP(病毒样颗粒)发生特异性反应,证实重组表达的L1蛋白具有免疫原性.本实验表明HPV16 L1蛋白在工程菌M15(pREP4)中高效表达,为研制HPV16预防性基因工程疫苗和感染的诊断试剂提供了物质基础和技术方法.     

HPV16L1核浆运输的动力学过程

利用增强型绿色荧光蛋白(Enhancegreenflurenscentprotein,EGFP)标记不同的截短型HPV16L1蛋白(Humanpapillomavirustype16L1protein,HPV16L1),分析HPV16L1蛋白核定位信号(Nucleuslocationsignal,NLS)的作用。构建重组pFB-EGFP、pFB-EGFP-HPV16L1、pFB-EGFP-HPV16L1△NLS和pFB-EGFP-NLSHPV16L1p转移载体;在DH10Bac宿主菌内经Tn7转座子介导的同源重组后转染Sf-9细胞,获得重组Ac-EGFP、Ac-EGFP-HPV16L1、Ac-EGFP-HPV16L1△NLS和Ac-EGFP-NLSHPV16L1杆状病毒,感染Sf-9昆虫细胞表达相应截短型HPV16L1融合蛋白;利用荧光显微镜和激光共聚焦显微镜观察不同融合蛋白的荧光特性和核浆转运动力学过程。结果发现Ac-EGFP杆状病毒感染的Sf-9细胞内明亮的绿色荧光均匀分布;重组Ac-EGFP-HPV16L1和Ac-EGFP-NLSHPV16L1杆状病毒感染的Sf-9细胞,明亮的绿色荧光主要位于细胞核内;重组Ac-EGFP-HPV16L1△NLS杆状病毒感染的Sf-9细胞,绿色荧光局限于细胞浆内,细胞核内无绿色荧光。说明HPV16L1蛋白羧基端的23个氨基酸(GKRKATPTTSSTSTTAKRKKRKL)具有完全核定位作用,能引导HPV16L1蛋白和EGFP突破核膜屏障进入Sf-9细胞核内。     

切割HPV-6bE1和HPV-11E1通用核酶Rz 1282的体外活性鉴定

利用计算机分析 HPV- 6b E1和 HPV- 1 1 E1 m RNA的同源序列 ,设计出通用于两者的锤头状核酶—— Rz1 2 82 (HPV- 6b基因 1 2 82位 ) ,通过体外转录建立了体外大量制备 Rz1 2 82的方法 .体外的切割实验表明 ,Rz1 2 82可在体外准确和有效地切割 HPV- 6b/1 1 E1靶 RNA,形成 2 68nt/52nt和 2 31 nt/52 nt大小的切割产物 .对于 HPV- 6b,Km和 kcat值分别为 1 3.8nmol/L和 0 .0 7min-1;对于 HPV- 1 1 ,Km 和 kcat值分别为 2 3.0 nmol/L和 0 .2 4 min-1.结果表明 ,体外制备的 Rz1 2 82具有较好的特异催化切割活性 ,并通用于 HPV- 6b及 HPV- 1 1 .它有望发展成为在细胞内有效抑制HPV- 6b/1 1 DNA复制的核酸药物 .     

Identification of early proteins of the human papilloma viruses type 16 (HPV 16) and type 18 (HPV 18) in cervical carcinoma cells.

We have sequenced 1730 bp of human papilloma virus type 18 (HPV 18) DNA containing the open reading frames (ORF) E6, E7, the N-terminal part of E1 and, additionally, 120 bp of the N-terminal part of L1. Based on these sequencing data, together with the human papilloma virus type 16 (HPV 16) DNA sequence published recently, we identified and cloned the ORF E6, E7, E1 and L1 of HPV 18 and the ORF E6, E7, E1, E4, E5, L2 and L1 of HPV 16 into prokaryotic expression vectors. The expression system used provides fusions to the N-terminal part of the MS2 polymerase gene controlled by the heat-inducible lambda PL promoter. Using the purified fusion proteins as immunogens we raised antisera against the proteins encoded by the ORF E6, E7 and E1 of HPV 18 as well as those encoded by the ORF E6, E7, E4 and L1 of HPV 16. By Western blot analysis we could show that the E7 gene product is the most abundant protein in cell lines containing HPV 16 or HPV 18 DNA. It is a cytoplasmic protein of 15 kd in the SiHa and the CaSki cell lines which contain HPV 16 DNA, and 12 kd in the HeLa, the C4-1 and the SW756 cell lines which contain HPV 18 DNA. These results were confirmed by in vitro translation of hybrid-selected HPV 16 and HPV 18 specific poly(A)+ RNA from SiHa, CaSki and HeLa cells. Additionally, these experiments led to the identification of an 11-kd E6 and a 10-kd E4 protein in the CaSki cell line as well as a 70-kd E1 protein in HeLa cells.     

DNA sequence and genome organization of genital human papillomavirus type 6b.

The complete nucleotide sequence of the circular double-stranded DNA of the genital human papillomavirus type 6b (HPV6b) comprising 7902 bp was determined and compared with the DNA sequences of human papillomavirus type 1a (HPV1a) and bovine papillomavirus type 1 (BPV1). All major open reading frames are located on one DNA strand only. Their arrangement reveals that the genomic organization of HPV6b is similar to that of HPV1a and BPV1. The putative early region includes two large open reading frames E1 and E2 with marked amino acid sequence homologies to HPV1a and BPV1 which are flanked by several smaller frames. The internal part of E2 completely overlaps with another open reading frame E4. The putative late region contains two large open reading frames L1 and L2. The L1 amino acid sequences are highly conserved among analyzed papillomavirus types. By sequence comparison, potential promoter, splicing and polyadenylation signals can be localized in HPV6b DNA suggesting possible mechanisms of genital papillomavirus gene expression.     

A protective and broadly cross-neutralizing epitope of human papillomavirus L2

We generated a monoclonal antibody, RG-1, that binds to highly conserved L2 residues 17 to 36 and neutralizes human papillomavirus 16 (HPV16) and HPV18. Passive immunotherapy with RG-1 was protective in mice. Antiserum to the HPV16 L2 peptide comprising residues 17 to 36 (peptide 17-36) neutralized pseudoviruses HPV5, HPV6, HPV16, HPV 18, HPV31, HPV 45, HPV 52, HPV 58, bovine papillomavirus 1, and HPV11 native virions. Depletion of HPV16 L2 peptide 17-36-reactive antibodies from cross-neutralizing rabbit and human L2-specific sera abolished cross-neutralization and drastically reduced neutralization of the cognate type. This cross-neutralization of diverse HPVs associated with cervical cancer, genital warts, and epidermodysplasia verruciformis suggests the possibility of a broadly protective, peptide-based vaccine.     

Demonstration of evolutionary differences between conserved antigenic epitopes in the minor nucleocapsid protein of human papillomavirus types 6b, 16 and 18.

We studied human papillomavirus (HPV) minor nucleocapsid protein (L2) by epitope scanning. Conserved antigenic epitopes identified by rabbit antiserum to bovine papillomavirus (BPV) were revealed in HPV-6b (amino acids, aa, 196-205); HPV-16 (aa:s 376-85) and HPV-18 (aa:s 221-230). L2 proteins. The first two epitopes were situated in hydrophilic regions of the proteins. Aligning the aa-sequences that corresponded to the epitopes with the total L2 sequences of BPV and HPV1a revealed consensus motifs between BPV, HPV1a and the reactive HPV type. In the non-reactive types amino acid alterations were noted. Mismatch between HPV1a sequences and the corresponding HPV-6b and HPV-16, HPV-6b and HPV-18, and HPV-16 and HPV-18 sequences suggests that the alterations may have evolved to facilitate immune surveillance of the genital HPV types.     

Common Neutralization Epitope in Minor Capsid Protein L2 of Human Papillomavirus Types 16 and 6

Studies of virus neutralization by antibody are a prerequisite for development of a prophylactic vaccine strategy against human papillomaviruses (HPVs). Using HPV16 and -6 pseudovirions capable of inducing beta-galactosidase in infected monkey COS-1 cells, we examined the neutralizing activity of mouse monoclonal antibodies (MAbs) that recognize surface epitopes in HPV16 minor capsid protein L2. Two MAbs binding to a synthetic peptide with the HPV16 L2 sequence of amino acids (aa) 108 to 120 were found to inhibit pseudoinfections with HPV16 as well as HPV6. Antisera raised by immunizing BALB/c mice with the synthetic peptide had a cross-neutralizing activity similar to that of the MAb. The data indicate that HPV16 and -6 have a common cross-neutralization epitope (located within aa 108 to 120 of L2 in HPV16), suggesting that this epitope may be shared by other genital HPVs.     

表达HPV16 L1抗原的1型重组AAV载体免疫效果的研究

为研究1型重组腺病毒伴随病毒(Adeno-associated virus type 1,AAV1)载体作为HPV16预防性疫苗的可行性,构建含密码子优化型HPV16L1基因(mod.HPV16L1)的1型重组AAV载体rAAV1-mod.HPV16L1,将纯化的rAAV1-mod.HPV16L1以肌注和滴鼻途径分别免疫C57BL/6小鼠,使用体外中和实验检测血清中的特异性中和抗体.结果显示,rAAV1-mod.HPV16L1单针肌注及滴鼻免疫均可诱导特异性血清中和抗体,但二组抗体动态变化趋势不同,肌注组血清中和抗体滴度显著高于滴鼻组.rAAV1-mod.HPV16L1单针肌注免疫可诱导强而持久的血清中和抗体,是理想的候选HPV16预防性疫苗.     

Efficient self-assembly of human papillomavirus type 16 L1 and L1-L2 into virus-like particles.

The L1 genes of two human papillomavirus type 16 (HPV16) isolates derived from condylomata acuminata were used to express the L1 major capsid protein in insect cells via recombinant baculoviruses. Both L1 major capsid proteins self-assembled into virus-like particles (VLP) with high efficiency and could be purified in preparative amounts on density gradients. The yield of VLP was 3 orders of magnitude higher than what has been obtained previously, using L1 derived from the prototype HPV16. DNA sequence comparison identified a single nonconserved amino acid change to be responsible for the inefficient self-assembly of the prototype L1. VLP were also obtained by expressing L1 of HPV6, HPV11, and cottontail rabbit papillomavirus, indicating that L1 from a variety of papillomaviruses has the intrinsic capacity to self-assemble into VLP. Coexpression of HPV16 L1 plus L2 by using a baculovirus double-expression vector also resulted in efficient self-assembly of VLP, and the average particle yield increased about fourfold in comparison to when L1 only was expressed. Coimmunoprecipitation of L1 and L2 and cosedimentation of the two proteins in a sucrose gradient demonstrated that L2 was incorporated into the particles. The ability to generate preparative amounts of HPV16 L1 and L1-L2 VLP may have implications for the development of a serological assay to detect anti-HPV16 virion immune responses to conformational epitopes and for immunoprophylaxis against HPV16 infection.