HIV-1 conserved elements p24CE DNA vaccine induces humoral immune responses with broad epitope recognition in macaques.

To target immune responses towards invariable regions of the virus, we engineered DNA-based immunogens encoding conserved elements (CE) of HIV-1 p24gag. This conserved element vaccine is designed to avoid decoy epitopes by focusing responses to critical viral elements. We previously reported that vaccination of macaques with p24CE DNA induced robust cellular immune responses to CE that were not elicited upon wild type p55gag DNA vaccination. p24CE DNA priming followed by p55gag DNA boost provided a novel strategy to increase the magnitude and breadth of the cellular immune responses to HIV-1 Gag, including the induction of strong, multifunctional T-cell responses targeting epitopes within CE. Here, we examined the humoral responses induced upon p24CE DNA or p55gag DNA vaccination in macaques and found that although both vaccines induced robust p24gag binding antibody responses, the responses induced by p24CE DNA showed a unique broad range of linear epitope recognition. In contrast, antibodies elicited by p55gag DNA vaccine failed to recognize p24CE protein and did not recognize linear epitopes spanning the CE. Interestingly, boosting of p24CE DNA primed animals with p55gag DNA resulted in augmentation of antibodies able to recognize p24gag as well as the p24CE proteins, thereby inducing broadest immunity. Our results indicate that an effectively directed vaccine strategy that includes priming with the conserved element vaccine followed by boost with the complete immunogen induces broad cellular and humoral immunity focused on the conserved regions of the virus. This novel and effective strategy to broaden responses could be applied against other antigens of highly diverse pathogens.

Introduction

The development of an effective HIV vaccine is critical to control the AIDS pandemic. Protection against HIV is difficult to obtain in part because the virus readily mutates and generates viable alternatives to the epitopes targeted by the immune system of the host. To address the problem of viral variability many strategies have been tested [1]–[19]. We have focused in conserved elements from the HIV-1 proteome and have based our immunogen designs on (a) stringent conservation among all HIV sequences, (b) selection of epitopes associated with better virologic control in HIV-1 infected individuals, and (c) optimizing immunogen expression and proteolytic cleavage [11], [12], [16]–[25]. We focused on Gag as a prototype vaccine, because Gag-specific CD8+ T cell responses were found to correlate with control of viremia in clade B and C infected individuals [26]–[29], to contribute to control HIV-1 after infection in the Step trial [30], and Gag-specific CD4+ T cell responses were associated with virus control [31], [32]. We selected 7 conserved elements (CE) within HIV-1 p24gag. which cover ∼98% of the HIV-1 Group M viruses worldwide and represent 54% of the p24gag protein. These p24CE sequences were collinearly arranged to express what we refer to as the p24CE immunogen [18]. Using ex vivo transfection of CE-encoding RNA into human dendritic cells, we were able to generate levels of CD4 and CD8 responses comparable to that of the full-length p55Gag protein [25]. C57BL/6 mice immunized with p24CE plasmids developed immune responses of high magnitude and recognized more CE than those induced by the complete p55gag DNA immunogen [18]. Vaccination of macaques with p24CE DNA vaccine showed that all of the 10 animals developed cellular responses against the CE, while only 50% of the macaques vaccinated with the full-length p55gag DNA developed cellular responses targeting any of the CE [19]. Importantly, boosting CE-primed macaques with DNA expressing full-length p55gag increased magnitude and poly-functionality of the CE responses, and breadth of Gag immunity, targeting epitopes within the highly conserved elements and also outside p24gag, and demonstrating alteration of the hierarchy of epitope recognition in the presence of pre-existing CE-specific responses [19].

Although the p24CE vectors were primarily designed as a prototype T cell vaccine to induce optimal cell-mediated responses, the development of humoral immunity is critical to contain HIV transmission. Therefore, we explored whether the CE vaccine approach also elicits humoral immunity and defined the breath of the antibody responses observed. Although antibodies targeting the HIV Gag protein are not expected to prevent viral transmission, this study serves as proof-of-concept that can be translated to other viral antigens, such as Env. In the present work, we performed a detailed analysis of the antibodies induced by p24CE DNA vaccination in macaques [19], including peptide mapping of the different CE that are recognized by those antibody responses. We report that the p24CE DNA vaccine was able to induce robust humoral immune responses that recognized wild type HIV-1 p24gag. Interestingly, we also found that the CE-induced responses were broad, sustained, and could be boosted by heterologous p55gag DNA vaccination. Thus, our finding suggests that inclusion of conserved elements as a priming immunogen provides a novel and effective strategy to broaden responses against highly diverse pathogens like HIV by avoiding decoy epitopes, while focusing responses to critical viral elements for which fewer escape pathways exist. This study serves as proof-of-concept to assess immunogenicity of conserved elements in the macaque model, a concept that can be translated into other viral proteins, such as Env, where the combination of distinct antibody and cellular responses against invariable epitopes may provide an immunologic advantage for the containment of the virus.

Material and Methods

Ethics statement

The animals in this study were Indian rhesus macaques (Macaca mulatta) as described previously [19] and were housed at the Advanced BioScience Laboratories, Inc. (ABL) animal facility. All animals were cared for and procedures performed under a protocol approved by the ABL Animal Care and Use Committee (animal welfare assurance no. A3467-01; protocol no. AUP516) and USDA Certificate number 51-R-0059. Furthermore, the macaques in this study were managed according to the animal husbandry program of the ABL Animal Facility, which aims at providing consistent and excellent care to nonhuman primates at the vivarium. This program operates based on the laws, regulations, and guidelines promulgated by the United States Department of Agriculture (e.g., the Animal Welfare Act and its regulations, and the Animal Care Policy Manual), Institute for Laboratory Animal Research (e.g., Guide for the Care and Use of Laboratory Animals, 8th edition), Public Health Service, National Research Council, Centers for Disease Control, and the Association for Assessment and Accreditation of Laboratory Animal Care (AAALAC) International. The nutritional plan utilized by the ABL Animal Facility consisted of twice daily feeding of Labdiet 5045 High Protein Primate Diet and food intake was closely monitored by Animal Research Technicians. This diet was also supplemented with a variety of fruits, vegetables, and other edible objects as part of the environmental enrichment program established by the Veterinary staff and enrichment Technician. Pairing of animals as part of the environmental enrichment program was managed by the enrichment technician. All primary enclosures and animal rooms were cleaned daily with water and sanitized at least once every two weeks. All macaques (N = 10) used in this study were males, except for four females: M695, P572, P574, M437. Their average weight was 8.5 kg (range: 3.8–11.2 kg) and their average age was 7 years (range: 4–12 years). Vaccinations were performed under anesthesia (Ketamine administered at 10 mg/kg) and all efforts were made to minimize suffering. No adverse effects were found. None of the animals were euthanized as part of this study.

Vaccination regimens

The macaques were vaccinated as part of a previous study [19] with plasmids expressing p24CE1 and p24CE2 or COT-M p55gag DNA, and all the vaccines contained IL-12 DNA, described in detail elsewhere [18], [19]. The DNA vaccines were delivered via intramuscular injection followed by in vivo electroporation [19]. The animals received two vaccinations with p24CE DNA (N = 10) or p55gag DNA (N = 4) (vaccination 1, vaccination 2) followed by a converse boost with p55gag DNA or p24CE DNA (vaccination 3), respectively.

Antibody assays

Blood samples were collected at the day of each vaccination and 2 weeks later. Serial dilutions of plasma samples were tested by standard ELISA (Advanced Bioscience Lab, Rockville, MD) for binding antibodies to HIV-1 clade B p24gag and the absorbance (OD) at 450 nm was determined. Binding titers were reported as the reciprocal of the highest dilution scoring positive (having a value greater than average values obtained with naive macaque plasma +3 standard deviations). Pepscan analysis was performed using 58 peptides covering HIV-1 consensus group M p24gag (15-mers overlapping by 11 AA; #11057 AIDS Research and Reference Reagent Program, Germantown, MD) by standard ELISA. The plasma samples were tested at a dilution of 1:50 and absorbance (OD) was measured at 450 nm.

For Western blot analysis, 106 HEK293 cells were transfected with 1 µg of the p24CE DNAs or 5 µg of the HIV-1 molecular clone pNL4-3. Aliquots of the extracellular fractions containing p24gag (pNL4-3; 1/250) or cell-associated fractions containing p24CE1 and p24CE2, respectively (1/50 of extract) were separated on 12% NuPAGE gels and blotted onto nitrocellulose membranes (Invitrogen, Carlsbad, CA). The membranes were incubated with plasma from vaccinated macaques, followed by anti-monkey–HRP labeled antibody (dilution 1:10,000), and the bands visualized using the enhanced chemiluminescence (ECL) Prime Western blotting detection reagent (GE HealthCare, Piscataway, NJ).

Results

Development of humoral immune responses in macaques vaccinated with p24CE and p55gag plasmid DNA

To focus the immune responses on nearly invariant regions of the HIV-1 proteome, we developed DNA immunogens encoding 7 highly conserved elements (CE) identified within HIV-1 p24gag [18], [19], [23]. Two plasmids were constructed with each of the 7 CE elements, which differed by 1 ‘toggle’ amino acid per CE to include a lesser conserved AA, and were arranged by taking into consideration the hydrophobicity of individual CE and spaced with linkers designed to maximize cleavage between the adjacent CE ( ) as described previously [18], [19], [23]. Each 140-AA CE cassette, p24CE1 and p24CE2, was expressed from expression-optimized DNA vectors.

Figure 1

p24CE Expression plasmids.

Cartoon depicting the HIV p55gag protein and its proteolytic cleavage products p17gag, p24gag and the C-terminal p2, p7, p1 and p6 proteins. The 7 highly conserved elements (CE) identified within p24Gag are indicated. The two p24CE constructs differ by 1 ‘toggle’ AA per CE, indicated by asterisks. The 7 CE were connected via linkers and the p24CE proteins were expressed from the CMV promoter using the mammalian expression vector pCMV.kan [18].

Rhesus macaques received two vaccinations with DNAs expressing either both p24CE1 and p24CE2 (N = 10) or p55gag (N = 4), each delivered by intramuscular injection followed by in vivo electroporation as outlined in and previously reported [18], [19]. Plasma samples were collected on the day of vaccination and 2 and 8 weeks later. We have previously reported that vaccination with p24CE DNA induced strong cellular immunity targeting new epitopes [18], [19]. Here, we examined the development of Gag-specific humoral responses induced by the same immunization regimen. Animals vaccinated with p24CE DNA developed antibody responses against p24gag and the kinetics of these responses were similar to those induced by p55gag DNA vaccination ( ). p24gag antibody responses were detectable upon a single DNA vaccination, and were efficiently boosted by the 2nd DNA immunization resulting in peak antibody titers (∼5.3 log reciprocal end-point dilution) detected 2 weeks later. Similar levels of Gag-specific antibody responses were detected 8 weeks later in both groups of animals, indicating comparable persistence of humoral responses. These results demonstrate that p24CE DNA, an immunogen designed to elicit optimal T-cell responses, is able to induce humoral immune responses to p24gag of similar magnitude as those induced by the p55gag DNA vaccine.

Figure 2

Induction of humoral immune responses upon p24CE DNA vaccination in macaques.

(A) Cartoon depicts the vaccination schedule. Each macaque received 2 vaccinations with a mixture of p24CE1 and p24CE2 DNAs or p55gag DNA at week 0 and 8. Plasma samples were analyzed for bAb to Gag at the time of each vaccination and at the additional indicated time points. (B) Plasma bAb to HIV-1 p24Gag measured by ELISA. Mean and standard error of the reciprocal Gag antibody endpoint titers (in log10) of 10 macaques vaccinated with p24CE DNA mixture and 4 macaques which received the p55gag DNA are shown. (C, D) Western immunoblot analysis was used to identify binding antibodies to HIV-1 p24Gag and the p24CE proteins present in plasma collected after the last vaccination. The membranes contain the soluble processed clade B p24gag protein (lane 1), p24CE1 (lane 2) and p24CE2 (lane 3) protein and were probed with plasma collected after the last vaccination. The data from 2 representative macaques from each vaccine group are shown: (C) p24CE DNA vaccinated animals M437 (plasma dilution 1:2000) and P314 (plasma dilution 1:1000) and (D) p55gag DNA vaccinated animals M114 and M121 (plasma dilution 1:2000 for both). The positions of p24gag and p24CE proteins are indicated.

The ability to recognize the p24CE proteins and processed p24gag by the antibodies induced by either of the vaccination regimens was analyzed by Western immunoblots ( ). Plasma from macaques vaccinated with p24CE DNA contained antibodies that strongly reacted with processed p24gag and both forms of the p24CE proteins (p24CE1 and p24CE2) ( ). As expected from the conservation within p24CE of the AA sequences from the HIV-1 M group, these antibodies strongly reacted with Gag from different subtypes, including subtypes A, B, C, and group M consensus (not shown). In contrast, plasma samples from macaques immunized with p55gag DNA, although able to recognize the viral p24gag, failed to bind to either of the two CE proteins ( ). Similar patterns of antibody recognition were found upon vaccination of mice [18]. Thus, antibodies induced by p24CE DNA vaccination recognized both the full-length p24Gag and the p24CE proteins, but immunization with p55gag DNA vaccination failed to produce antibodies specific for the CE proteins of p24gag.

Humoral responses targeted four of the seven CE

To identify the linear epitopes recognized by the antibodies induced by the vaccination regimens, we performed a peptide scanning analysis (Pepscan) of plasma samples at the time of peak antibody responses (2 weeks after the 2nd vaccination) using a panel of peptides (15-mers overlapping by 11 AA) that cover the entire p24gag protein (see for peptide sequences and association with CE). Data obtained with samples from macaques vaccinated with the p24CE DNA showed that each of the 10 animals developed antibodies that recognized CE1 and CE3 ( ). In addition, the number and locations of the peptides recognized suggest two distinct immunogenic epitopes within CE3. Three macaques (M166, R279 and P302) also developed responses to CE2, while two animals had responses to CE7 (L862, strong responses; P302, low responses) ( ). As expected, none of the macaques immunized with the p24CE recognized any peptide located outside the p24CE. In contrast, we found that the antibodies induced by p55gag DNA vaccination failed to efficiently recognize linear epitopes within the p24gag region ( ). Only one of the 4 animals (P574) had antibodies that recognized linear epitopes in CE1, CE3 and CE7, but we noted that different peptides were recognized compared to those in p24CE DNA vaccinated animals. Two macaques (P574 and R288) were able to recognize some peptides located in the ‘variable’ region between CE6 and CE7. These results demonstrate that vaccination with p24CE DNA triggered broad antibody responses that recognized several continuous epitopes within p24Gag, whereas vaccination with p55gag DNA failed to elicit antibodies against the linear segments in the conserved regions or in HIV-1 p24gag in general.

Table 1

Peptide list and coverage of CE.

ID	Peptidea	CE		ID	Peptidea	CE
1	PIVQNLQGQMVHQAI			31	WMTSNPPIPVGEIYK
2	NLQGQMVHQAISPRT			32	NPPIPVGEIYKRWII	CE5
3	GQMVHQAISPRTLNA	CE1		33	PVGEIYKRWIILGLN	CE5
4	HQAISPRTLNAWVKV	CE1		34	YKRWIILGLNKIVR	CE5
5	SPRTLNAWVKVIEEK	CE1		35	WIILGLNKIVRMYSP	CE5
6	LNAWVKVIEEKAFSP	CE1		36	GLNKIVRMYSPVSIL	CE5
7	VKVIEEKAFSPEVIP	CE2		37	IVRMYSPVSILDIRQ	CE5
8	EEKAFSPEVIPMFSA	CE2		38	YSPVSILDIRQGPK	CE5
9	FSPEVIPMFSALSEG	CE2		39	VSILDIRQGPKEPFR
10	VIPMFSALSEGATPQ	CE2		40	DIRQGPKEPFRDYV
11	FSALSEGATPQDLNT	CE2		41	RQGPKEPFRDYVDRF	CE6
12	SEGATPQDLNTMLNT	CE2		42	KEPFRDYVDRFFKTL	CE6
13	TPQDLNTMLNTVGGH	CE2		43	RDYVDRFFKTLRAEQ	CE6
14	LNTMLNTVGGHQAAM	CE3		44	DRFFKTLRAEQATQ	CE6
15	LNTVGGHQAAMQMLK	CE3		45	FKTLRAEQATQDVKN	CE6
16	GGHQAAMQMLKDTIN	CE3		46	RAEQATQDVKNWMT	CE6
17	AAMQMLKDTINEEAA	CE3		47	EQATQDVKNWMTDTL
18	MLKDTINEEAAEWDR	CE3		48	TQDVKNWMTDTLLVQ
19	TINEEAAEWDRLHPV	CE3		49	KNWMTDTLLVQNANP
20	EAAEWDRLHPVHAGP	CE3		50	TDTLLVQNANPDCKT
21	WDRLHPVHAGPIPPG			51	LVQNANPDCKTILKA
22	HPVHAGPIPPGQMR			52	ANPDCKTILKALGPG
23	HAGPIPPGQMREPRG			53	CKTILKALGPGATL
24	IPPGQMREPRGSDIA	CE4		54	ILKALGPGATLEEMM	CE7
25	GQMREPRGSDIAGTT	CE4		55	LGPGATLEEMMTACQ	CE7
26	EPRGSDIAGTTSTLQ	CE4		56	ATLEEMMTACQGVGG	CE7
27	SDIAGTTSTLQEQIA	CE4		57	EMMTACQGVGGPGHK	CE7
28	GTTSTLQEQIAWMTS	CE4		58	ACQGVGGPGHKARVL	CE7
29	TLQEQIAWMTSNPPI	CE4
30	EQIAWMTSNPPIPVG	CE4

Amino acids indicated in bold cover the respective CE.

Table 2

Responses of individual CE to cellular an humoral immune responses.

Vaccine	Macaques (N = 10)		Cellulara and humoral immune responses to individual CE
			CE1	CE2	CE3	CE4	CE5	CE6	CE7
Conserved Element p24CE DNA	L862	CMIa		+	+		+
		pepscan	+		+				+
	M166	CMIa		+			+	+
		pepscan	+	+	+		+
	M695	CMIa			+		+	+
		pepscan	+		+	+
	R279	CMIa				+	+	+
		pepscan	+	+	+
	P314	CMIa			+	+	+
		pepscan	+		+
	M437	CMIa					+
		pepscan	+		+
	R315	CMIa					+		+
		pepscan	+		+
	P302	CMIa			+		+	+
		pepscan	+	+	+				+
	P307	CMIa			+		+	+
		pepscan	+		+
	P308	CMIa			+		+
		pepscan	+		+
Positive responses among 10 macaques		CMIa	0	2	6	2	10	5	1
		pepscan	10	3	10	1	1	0	2

Cellular immune response data are from [19].

Figure 3

Pepscan analysis of humoral responses induced upon p24CE and p55gag DNA vaccination in macaques.

All macaques vaccinated with (A) p24CE DNA (N = 10) and (B) p55gag DNA (N = 4) were subjected to Pepscan analysis against 58 peptides (15-mers overlapping by 11 AA) spanning p24gag. Peptides corresponding to CE1 to CE7 are indicated and the peptides are listed below as detailed in . OD450 is reported after subtracting the mean OD450 of the values obtained from negative samples plus 3 SD.

Heterologous boost vaccination increased pre-existing antibody responses in p24CE and p55gag DNA primed macaques

We next asked whether boosting with the heterologous DNA plasmid could increase pre-existing humoral responses. Animals from both groups received an additional DNA vaccination as outlined in and the responses were monitored by ELISA. Sustained antibody responses were observed at the day of the heterologous boost vaccination in both groups ( , vaccination 3) as a result of the prior priming vaccination. Plasma samples collected 2 weeks later showed that these responses were further boosted by heterologous DNA vaccination in both vaccine groups. Boosting of p24CE DNA primed responses by p55gag DNA resulted in an average 0.8 log increase in ELISA titers, and boosting of p55gag DNA primed responses by p24CE DNA increase the Gag ELIA titers by 0.9 log.

Figure 4

HIV-1 p55gag DNA vaccination did not prime de novo CE humoral responses but increased pre-existing CE-specific responses.

(A) Cartoon depicts the vaccination schedule. After receiving p24CE or p55gag DNA as priming vaccination (see ) the animals received a heterologous boost vaccination (vaccination 3) with p55gag DNA or p24CE DNA, respectively. (B) Comparison of plasma bAb to HIV-1 p24gag ELISA titers at vaccination 3 and 2 weeks later. The reciprocal Gag antibody endpoint titers (in log10) from individual macaques vaccinated with the p24CE DNA mixture following by a p55Gag DNA boost (N = 10; left panel) and macaques vaccinated with p55Gag DNA followed by a p24CE DNA boost (N = 4; right panel) are shown. Data from day of 3rd vaccination are from Fig. 2B. (C, D) Western immunoblot analysis was used to test macaque plasma for binding antibodies before (after vaccination 2) and after the boost (after vaccination 3). The membranes contain the soluble processed p24gag (lane 1), p24CE1 (lane 2) or p24CE2 (lane 3) proteins and were probed with plasma collected 2 weeks after vaccinations 2 and 3. Data from 2 representative macaques are shown from each vaccine group. The membranes were probed with plasma from (C) macaques (L862, M166), which received the p24CE prime-p55gag DNA boost (plasma dilution 1:2000) and from (D) macaques (P574, R288), which received the p55gag prime-p24CE DNA boost regimen (plasma dilution 1:500).

The responses were further analyzed by Western immunoblot ( ). Prior to boost, macaques primed with p24CE recognized the naturally processed p24gag as well as the p24CE1 and p24CE2 proteins ( ). Following the heterologous p55gag DNA boost, stronger reactivity was found against both p24gag and p24CE proteins and the data from two representative animals (L862 and M166) are shown ( ). Interestingly, although p55gag priming was unable to induce detectable antibody responses to the CE proteins by Western blot analysis, it was able to boost preexisting CE-specific humoral responses.

Macaques primed with p55gag DNA (2 weeks after the 2nd vaccination) developed humoral responses that strongly reacted with p24gag but failed to recognize p24CE proteins ( ), as expected (see above ). However, a single boost of these animals with p24CE DNA not only increased the reactivity to p24gag, but it also elicited antibodies recognizing p24CE proteins as shown by Western immunoblot analysis from two representative animals (P574 and R288) ( ).

We also compared the antibody responses by Pepscan analysis of plasma samples collected after the prime (from ) and after the boost ( and ). In macaques primed with p24CE and boosted with p55gag DNA ( ), we observed no significant changes in the reactivity to linear epitopes except for M695, M437, P314 and R315, which showed increased recognition of 1 or 2 CE (M695:CE4; M437: CE1 and CE2; P314: CE1 and CE3) or new responses (R315: CE5 and CE7). Although p55gag DNA vaccination did not induce antibodies against many linear peptides (see ), it is noteworthy that it was able to alter responses in 4 of 10 animals, suggesting that it increased pre-existing low peptide recognition rather than inducing de novo responses.

Figure 5

Pepscan analysis of humoral responses induced upon heterologous prime-boost regimens of macaques primed with p24CE priming boosted p55gag DNA boost vaccination.

Plasma collected after the prime and after the boost vaccinations were subjected to Pepscan analysis against the 58 overlapping peptides described in . Peptides corresponding to CE1 to CE7 are indicated and the peptides are listed below as detailed in . Samples were analyzed after the priming (data from Figure 3A, left panels) and boost vaccination (right panels).

Figure 6

Pepscan analysis of humoral responses induced upon heterologous prime-boost regimens of macaques primed with p55gag DNA and boosted with p24CE DNA.

Plasma collected after the prime (left panels) and after the boost vaccinations (right panels) were subjected to Pepscan analysis as described in and .

In contrast, p55gag primed macaques boosted with p24CE DNA ( ) showed de novo production of antibodies recognizing multiple CE in 3 of 4 macaques, with the linear peptide recognition pattern found from p24CE primed animals (see ). These macaques (P574, R067 and R288) developed antibody responses mainly targeting CE1 and CE3, the two CE most commonly recognized upon the p24CE vaccination. Macaque L985 was the only animal that did not develop antibodies against CE after a single p24CE DNA boost.

Discussion

A successful vaccine against HIV-1 should induce both cellular and humoral immunity. We previously demonstrated that the p24CE vaccine induced strong cellular responses in both mice and macaques [18], [19]. These responses were mediated by both CD4+ and CD8+ T cells with cytotoxic potential and targeted several of the CE encoded by the vaccine. In this report, we tested whether an immunogen designed to induce efficient cellular immune responses against conserved regions of HIV-1 p24gag was also able to induce antibody responses in vaccinated rhesus macaques. We found that vaccination of macaques with p24CE also induced anti-Gag humoral responses with binding antibody titers and kinetics similar to those induced by p55gag DNA vaccination. Interestingly, we found that the antibodies elicited by the p24CE DNA vaccine are able to recognize the processed p24gag, whereas antibodies induced by p55gag DNA vaccination failed to recognize the p24CE protein.

In addition, humoral responses induced by vaccination with the p24CE vectors targeted multiple linear epitopes within the CE, while antibodies induced by the p55gag vaccine failed to recognize any of the conserved elements and in general only poorly induced antibodies able to recognize linear epitopes. Similar to the induction of cellular immunity [19], the p55gag DNA vaccine was able to boost pre-existing CE-specific humoral responses in p24CE DNA primed animals. Table 2 shows a summary of the mapping of both cellular and humoral immune responses observed in the vaccinated animals. It is noteworthy that all the CEs selected for inclusion in the vaccine were immunogenic (humoral, cellular or both) in macaques, although the epitopes were selected based on association with better virologic control in HIV-1 infected individuals [23], [24]. CE5 (YVDRFYKTLRAEQA) induced cell- mediated responses in all the vaccinated animals, but was poor in inducing humoral responses. In contrast, CE1 (VIPMFSALSEGATPQDLN) elicited humoral responses in all the animals but failed to induce cellular responses in any of the vaccinated macaques. Interestingly, all macaques developed antibody responses against CE3 (PRGSDIAGTTSTLQEQIGW), while several vaccinees (6 of the 10 macaques) also induced strong cellular immunity against this region, suggesting that CE3 is a good immunogen for both arms of the immune system in macaques. Hence, CE3, CE5 and CE6 (LEEMMTACQGVGGPGHK) express the epitopes most efficiently recognized by the cellular immunity, while CE1 and CE3 are most efficient in inducing humoral responses.

In summary, these results demonstrate that an immunogen designed to induce cellular immune responses, and shown to do it efficiently in macaques [19], can also induce broad and distinct humoral immunity (this report). Although a correlation between humoral responses to Gag and improved virus control has been reported [33]–[35], future development of this vaccine concept will, logically, also include Env. It is further possible that analogous immunogens may benefit from both cellular immunity and the development of antibodies that otherwise may not be induced by the native molecule. Antibodies targeting linear epitopes could be useful in mediating protection either by binding to incoming viruses at mucosal surfaces or by mediating ADCC of infected cells. The combination of cellular and humoral responses targeting invariable regions of the virus may be beneficial to achieve protection against HIV-1 infection. Inclusion of conserved elements as a priming immunogen provides an effective vaccine to increase the breadth of the immune response. The concept of focusing responses to critical viral elements for which fewer escape pathways exist and of avoiding decoy epitopes could also be applied against other antigens of highly diverse pathogens.