1. Introduction
HIV-cure research aims to induce long-term HIV control in the absence of antiretroviral therapy (ART) to ultimately eliminate HIV. This is challenging because HIV integrates into cellular DNA after infection, establishing a latent reservoir that is refractory to antiretroviral therapy. ART successfully blocks viral replication but does not eliminate viral reservoirs that reside in lymphatic tissues. These reservoirs typically reseed infection if treatment is interrupted. Potent HIV-specific CD8 T cells can mediate natural HIV control [
1,
2], suggesting that vaccines that effectively enhance HIV-specific CD8 T cells could also induce HIV control. Consistent with this, a recent trial with a vaccine using the HIVACAT T-cell immunogen (HTI) was associated with prolonged time off ART in post hoc analyses [
3]. This virologic control was positively correlated with vaccine-induced HTI-specific T-cell responses. Humoral immunity may also be important for controlling HIV, as envelope binding non-neutralizing antibodies correlated with protection in RV144 vaccine trials [
4]. Although none of the HIV vaccines developed to date has been able to induce long-term HIV control, there are multiple avenues for potential HIV vaccine improvement. One such area is the delivery platform for the vaccine immunogen. Recent advancements in COVID-19 vaccines underscored the utility of mRNA–lipid nanoparticle (LNP) delivery in generating robust humoral immunity. The mRNA-LNP strategy has shown some promise in inducing humoral immunity in non-human primate (NHP) models, where it elicited tier-2 HIV-neutralizing antibodies [
5]. Similarly, adenoviral vectors have elicited robust cellular and humoral immunity in various disease models, including simian immunodeficiency virus (SIV) and HIV [
6,
7]. However, adenoviral vectors are limited by pre-existing immunity and the development of anti-vector immunity after immunization.
Lymphocytic choriomeningitis virus (LCMV) and Pichinde virus (PICV) are arenaviruses that induce robust immune responses but rarely cause infection in humans. LCMV and PICV naturally infect and activate antigen-presenting cells (APCs) such as dendritic cells and macrophages, stimulating CD8 T-cell immunity through direct antigen presentation with co-stimulation [
8,
9]. Replicating LCMV (artLCMV) vectors also infect lymphoid tissue stroma cells, inducing the alarmin IL-33 and potent cytotoxic effector CD8 T lymphocytes [
10]. Pre-existing immunity to these vectors is rare in humans, with reported rates of antibodies to LCMV below 5% [
11,
12,
13,
14,
15]. The glycoproteins of LCMV and PICV are highly glycosylated, minimizing the induction of neutralizing antibodies against these viruses. Previous studies in mice and cynomolgus macaques receiving a homologous prime–boost regimen with non-replicating recombinant LCMV (rLCMV) showed increasing SIV-specific T- and B-cell responses after each immunization [
16]. Consistent with this, a phase 1 clinical trial evaluating the safety and immunogenicity of a rLCMV vector resulted in induction of robust CMV-specific CD8 T cells and no vector-neutralizing antibody induction [
17]. Replicating arenavirus vector-based vaccines (artArena) also induced robust CD8 T-cell responses after vaccination with HPV16 immunogens [
18]. These results suggest that arenavirus-based vectors could be repeatedly used to generate robust T- and B-cell responses for durable HIV-specific immunity.
In the present study, we investigated whether heterologous regimens induced greater SIV immunity than a homologous regimen. We compared the immunogenicity of replicating artArena and non-replicating (rArena) arenavirus-based (LCMV and PICV) vectors, using either intravenous (IV) or intramuscular (IM) injection routes in NHPs. We assessed the magnitude of the SIV-specific ELISpot response, the breadth of the T-cell response, and the Env-specific antibody generation after immunization.
2. Materials and Methods
2.1. Vector Generation and Titration
Non-replicating and replicating arenavirus vectors used in the study are based on old-world LCMV clone 13 (with its glycoprotein [GP] from strain WE) and new-world PICV strain p18 arenaviruses. The non-replicating vectors, rLCMV and rPICV, are bi-segmented vectors that harbor one large segment (L-segment) and one small segment (S-segment). The GP open-reading frame (ORF) was replaced with SIVsmE543 Gag or Env, resulting in a replication-deficient virus.
To generate replication-competent attenuated artArena vectors (artLCMV and artPICV), arenavirus vector genomes were modified from their respective bi-segmented parental arenavirus to include one L-segment and two S-segments.
Genetically engineered viruses with an artificial genome organization that prevents the occurrence of recombination-based reversion were generated by artificially placing the GP-ORF in a non-natural position under 3′UTR control (instead of 5′UTR). SIV
smE543 transgenes Gag and Env were inserted under 5′UTR control (
Figure 1A). The artificial genome arrangement and the less-efficient packaging of all three genomic segments contribute to replication attenuation, as described previously [
19].
Both rArena and artArena vectors were produced by transient transfection of LCMV GP-expressing cells with two expression plasmids (encoding the respective LCMV or PICV nucleoprotein [NP] and polymerase L) and plasmids encoding the viral genomes (S- and L-genome) [
20]. Newly generated vectors were titrated by focus-forming assays and further passaged on suspension HEK293 cells to generate fetal calf serum-free vector stock material [
8,
10]. Vector-containing supernatant was harvested, titrated, and analyzed for stable transgene insertion and growth properties.
2.2. Study Design and Immunization
NHP studies evaluating the safety and immunogenicity of rArena vectors (rLCMV and rPICV) and artArena vectors (artLCMV and artPICV) were conducted at Bioqual, Inc. (Rockville, MD, USA). Four treatment-naïve Indian-origin rhesus macaques per group were immunized on weeks 0, 8, 17, and 33 IV (groups 1–4) or IM with 1 × 10
7 FFU of rLCMV and rPICV or 1 × 10
6 RCV FFU of artLCMV and artPICV vector vaccine, encoding SIV
smE543Gag or SIV
smE543Env antigens. The SIVsmE543 strain was selected based on previous studies where SIVsmE543 antigen was evaluated with Ad26/MVA vaccine. SIVSmE543 antigen immunization showed protection [
6] and control [
21] against heterologous SIV viruses. A 1:1 mixture of vectors expressing SIV
smE543Gag and SIV
smE543Env antigens was produced before performing injections (
Figure 1). A homologous regimen was performed with either rLCMV, artLCMV or rPICV, artPICV vector alone for a total of four doses. Heterologous immunizations were administered as four alternating doses, starting with LCMV or PICV vectors for a total of four groups: rLCMV/rPICV, rPICV/rLCMV, artLCMV/artPICV, and artPICV/artLCMV (
Figure 1B). Homologous immunization was administered IV, whereas heterologous immunizations were administered IV or IM for rPICV/rLCMV and artPICV/artLCMV groups.
2.3. IFN-γ ELISpot
Immune responses to SIV antigens were measured ex vivo by IFN-γ ELISpot analysis upon restimulation of frozen (IV groups up to 10 weeks) or fresh peripheral blood mononuclear cells (PBMCs) with respective peptide pools of Gag and Env at baseline and multiple post-immunization timepoints. Breadth of cellular response was evaluated by ELISpot to 12 Gag and 16 Env peptide subpools comprising 10 peptides each at 2 weeks after IM administration of the fourth dose of rPICV/rLCMV or artPICV/artLCMV regimens. ELISpot was performed using the monkey IFN-γ ELISpot kit from Mabtech (cat# 3421M-4HPW-10) per manufacturer’s recommendations. Briefly, pre-coated 96-well plates provided with the kit were washed four times with PBS (phosphate-buffered saline), followed by the addition of SIVsmE543Gag or Env peptides (antigens); NP-LCMV or NP-PICV peptides were resuspended in assay media (CTL-Test Medium + 1% L-glutamine) at a final concentration of 2 μg/mL. Then, 10 μg/mL PHA (phytohemagglutinin) was used as a positive control for each sample; assay medium alone served as a negative control. Plates were incubated for 30 min at 37 °C, followed by addition of 100 μL of PBMCs resuspended at 2 × 106 cells/mL in assay media. After overnight incubation at 37 °C, plates were washed with PBS. Then, 100 μL of biotinylated antibody was diluted at 1 μg/mL in 5% FBS in PBS and incubated for 2 h at room temperature (RT), followed by a washing and addition of streptavidin–HRP for 1 h at RT. Plates were developed with Vector Novared substrate per the manufacturer’s protocol (Vector Laboratories, Newark, CA, USA). Once the plates were dried, spots were scanned and counted on an ImmunoSpot analyzer (CTL, S6 Ultimate M2; ImmunoSpot, Cleveland, OH, USA)). Gag- and Env-specific IFN-γ SFUs were calculated for 1 × 106 cells and the magnitude of responses (antigen-specific responses minus 1× background) and graphed as median plus IQR. For Gag- and Env-specific breadth, responses were defined as >3× background signal. Data were plotted as median ± IQR.
2.4. Envelope-Binding Antibodies
SIV envelope-binding antibodies were detected against autologous (SIV
sme543) and heterologous (SIV
smE660 and SIV
mac251) SIV strains by ELISA. SIV-gp120 recombinant proteins (Immune Technology Corp., New York, NY, USA) were diluted to 2 μg/mL in sodium bicarbonate buffer at pH 9.4. Then, 25 μL was added to each well of a clear Thermo/Nunc MaxiSorp 384-well assay plate and incubated overnight at 4 °C. Plates were then washed three times with PBS–Tween at pH 7.4 + 0.05% Tween 20 (PBST) using a Biotek 405 plate washer and then blocked for 1 h at RT with 75 μL of the blocking buffer (1% goat serum + DPBS pH 7.4 + 5% skim milk). After blocking, three-fold serially diluted, heat-inactivated sera from vaccinated NHPs were added and incubated in the plate for 1 h at 4 °C. Sera from naïve NHPs were used as a negative control. Plates were washed and incubated for 30 min with 25 uL of goat anti-monkey IgG-HRP secondary antibody (Novus Biologicals, Centennial, CO, USA, NB7215), followed by detection with TMB substrate. Reaction was stopped with 0.16 M sulfuric acid. Plates were read on Envision at 450 nm, and end-point titers were reported as previously described [
19].
2.5. Multiparametric Flow Cytometry
Gag- and Env-specific T-cell polyfunctionality was determined 2 weeks after the fourth vaccination. Fresh (post-vaccination) or frozen (baseline) PBMCs were resuspended in RPMI media supplemented with 10% FBS. Then, 0.5–1 × 106 PBMCs were plated in a 96-well V-bottom plate and treated with DMSO (equal volume to pepmix in media), 2 μg of Gag pepmix, pool of 120 Gag peptides (JPT Peptide Technologies, Berlin, Germany), 2 μg of Env peptide pepmix, pool of 160 Env peptides (JPT Peptide Technologies), and PMA (5 μg/mL) + ionomycin (1 μM) for 1 h at 37 °C in the incubator. After 1 h, Golgi plug and Golgi stop (BD Biosciences, Franklin Lakes, NJ, USA) were added to the cells, and plates were incubated for an additional 12–14 h at 37 °C. After incubation, plates were centrifuged, and cells were washed with PBS and stained with AmCyan dye (live/dead stain, Thermo Scientific, Waltham, MA, USA). After Fc receptor blocking with human TruStain FcX (BioLegend, San Diego, CA, USA), surface staining was performed with anti-CD3 AF700, anti-CD4 BV605, anti-CD8 BV650, anti-CD45RA-PECy7, anti-CD27-BV711, and anti-CCR7-BV785 for 30 min at RT. After two washes with 2% FBS in PBS, cells were fixed with fixation buffer (BD Biosciences) and stained for intracellular markers with anti-human anti-IFN-γ PE-CF594, anti-IL2 PE, and anti-TNF-α PerCPCy5.5 antibodies for 30 min at RT. Cells were washed and resuspended in 2% FBS in PBS for flow data acquisition on BD LSRFortessa. Data were analyzed using FlowJo v.10 and plotted using GraphPad Prism 8.1.2.
2.6. LCMV-Neutralizing Antibodies
In a 384-well tissue culture-treated clear-bottom plate, ARPE-19 cells were seeded at 10,000 cells in 40 µL per well with assay media (2% FBS, 1% PS, and 1% glutamine) at 37 °C overnight. The next day, sera samples from vaccinated NHPs were heat-inactivated at 56 °C for 1 h before an eight-point, three-fold serial dilution. An equal volume of rLCMV-GFP green fluorescent protein) vector (Hookipa Pharma, New York, NY, USA) was then added to the diluted sera samples to achieve a final 10,000 PFU/well of VV1 GFP virus. Sera samples (in duplicate for each animal) and LCMV-GFP vector were incubated for 90 min at 37 °C in 5% CO2 before infecting the cells. Plated ARPE-19 cells were infected by transferring 40 µL of the sera samples and LCMV-GFP vector, and the cells were incubated for 24 h at 37 °C in 5% CO2 before measuring the reduction in the GFP signal. At the end of the 24-h incubation, the medium was removed using a plate washer, without disturbing the cell monolayer. Cells were washed once with 1× PBS. Cells were then fixed with 4% PFA and stained with DAPI (1:1000 dilution) for 30 min at room temperature. Lastly, assay plates were washed three times with 1× PBS before imaging using the Cellomics imager (Thermo Scientific # Cell Insight CX7). Viral vector neutralization results were measured via the reduction of GFP signal and reported as the ID50 (inhibitory dose) titers for the sample evaluated. ID50 values were calculated from the fit of the dose–response curves to a four-parameter equation. All ID50 values represent geometric mean values of a minimum of two determinations. A 1:60 (starting sera dilution) ID50 titer was reported for serum samples with no LCMV neutralization antibodies.
2.7. PICV-Neutralizing Antibodies
In a black 96-well flat-bottom plate, 10,000 cells/well BHK-21 cells were seeded overnight in 100 µL of RPMI medium supplemented with 10% FBS + 1% Pen–Strep (RPMI medium) at 37 °C. Heat-inactivated sera from NHPs were diluted, and seven dilutions (four-fold), starting at 1:40 dilution, in RPMI medium were added for each sample in a 96-well U-bottom plate (sample plate). In a new plate, 3 × 103 RCV of artPICV-NanoLuc virus/well was added and supplemented with diluted serum from the sample plate. Plates were incubated for 2 h at 37 °C, followed by the transfer of the virus + sample mix to previously seeded BHK-21 cells at 100 µL/well. After overnight incubation at 37 °C, the medium was aspirated, and 50 µL OPTI-MEM was added to each well.
Next, 12.5 µL per well of the diluted assay substrate (NanoGlo, Promega, Madison, WI, USA) was added to the wells, followed by luciferase acquisition on an Envision plate reader. Data were analyzed using GraphPad Prism 8.1.2, as previously described [
19].
2.8. Detection of LCMV and PICV in Urine and Plasma
The number of RNA copies per mL was determined using the TAQMAN assay. The assay utilizes primers and a probe specifically designed to amplify and bind to conserved regions of NP and the L gene of LCMV and of PICV. The signal is compared with a known standard curve and calculated to give copies per mL, depending on the source material (i.e., plasma, urine). A 0.2 mL volume of sample (i.e., plasma, urine) was added to 0.2 mL of AL buffer with carrier RNA. A 25 µL volume of protease was added and then incubated at 56 °C degrees for 15 min. The sample was centrifuged at 11,000×
g for 1 min and washed with wash buffer 1. The sample again was centrifuged, washed with wash buffer 2, centrifuged again, and washed with absolute ethanol. The sample was centrifuged at 17,000×
g for 3 min to remove all alcohol. Then, 50 µL of AVE buffer was added, and the sample was centrifuged at 17,000×
g for 1 min. The sequences for the primers and probes used to detect LCMV and PICV using the assay are described (
Table 1).
For RNA controls, the number of copies was known, so the control was diluted accordingly. Then, 20 µL of the master mix containing RNAase inhibitor and Taq-polymerase (Bioline RT-PCR kit, Taunton, MA, USA) was added with 5 µL of RNA sample to each well in a 96-well plate. The plate was sealed, and samples were tested in triplicate.
Two curves were run with eight 10-fold serially diluted RNA controls to obtain a standard curve ranging from 1 to 107 copies/reaction.
Applied Biosystems 7500 sequence detector was used to run the reaction at a program, 48 °C for 30 min and 95 °C for 10 min, followed by 40 cycles of 95 °C for 15 s and 1 min at 56 °C. Standard curve was used to extrapolate and to calculate RNA copies per mL. Values obtained were multiplied by the reciprocal of 0.2 mL extraction volume, i.e., 50. This gave a practical range from 50 to 5 × 108 RNA copies per mL. The 7500 sequence detector was calibrated at least annually by Applied Biosystems. Known standard curve was used to compare the signal and to calculate copies/mL in the samples (i.e., plasma and urine), as per the manufacturer’s recommendation.
2.9. Statistical Analysis
Statistical analysis was performed using GraphPad Prism 8.1.2. Non-parametric Mann–Whitney and two-way ANOVA with Šidák correction for multiple-comparison test were used for statistical analysis. We also used the Rstudio platform and lmer and emmeans packages to perform linear mixed-effects model for our analysis of longitudinal data. Statistical tests used for each dataset are indicated in the figure legends.
4. Discussion
In this study, we demonstrate that arenavirus vaccine vectors encoding SIV
smE543 Gag and Env effectively induce cellular and humoral immunity in treatment-naïve rhesus macaques. To determine the optimal vaccination setting for upcoming studies and potential future clinical development, we investigated and compared the potency of artArena and rArena vectors to elicit SIV-specific immune responses in heterologous and homologous regimens and with two different routes of administration (i.e., IV and IM). Heterologous (alternating PICV/LCMV) immunization with artArena or rArena vectors stimulated significantly stronger T-cell responses when compared with homologous administration (PICV/PICV or LCMV/LCMV), as evident from comparison of magnitude of IFN-γ ELISpot responses against both encoded SIV antigens (Env and Gag;
Figure 2 and
Supplementary Figure S1). To determine a limited safety profile for artArena and rArena vectors after IV administration, we measured viremia and virus shedding (in urine) in these animals by RT-qPCR and detection of viral genomes at various timepoints. Vectors are rapidly cleared from blood (
Figure 3A) for both artPICV/artLCMV and rPICV/rLCMV vaccines. Furthermore, viral shedding into urine was detected only for one animal at a single timepoint (
Figure 3B) after rPICV administration. Body weight and temperature were also monitored for all the animals throughout the study, and no abnormalities were observed. Additionally, a previous clinical study found non-replicating arenavirus vectors to be safe and well tolerated [
17], which aligns with our observations in the present study, as well as other NHP studies with replicating arenavirus vectors [
19]. These data support the strong attenuation and good safety profile of both arenavirus vector platforms.
We further compared two different routes of administration (IM and IV) and discovered that repeated IM administration of PICV and LCMV vectors resulted in a more stable antigen (SIV Env)-specific antibody response and lower induction of anti-vector antibodies than repeated IV administration of the vaccine. When administered intravenously, artArena vectors induced significantly higher SIV antigen-specific T-cell and antibody responses than rArena vectors. Interestingly this difference (between rArena and artArena) was much less pronounced in monkeys that received IM dosing (
Figure 4A,B). The different kinetics of IgG and T-cell responses after IM versus IV dosing are an interesting and unexpected observation. It has been shown that arenaviruses preferentially infect APCs among PBMCs [
22]. Whether IM dosing leads to different target cells compared with IV dosing and delayed transport of the antigen to APCs in draining LNPs is currently unknown and the subject of ongoing preclinical research. It also should be noted that the observed differences in the T-cell response could be due to fresh/frozen samples.
Of note, the quality of a T-cell response, as defined by the polyfunctionality rather than the quantity of T cells, has been associated with effective immune responses against viral infections and disease progression [
23]. And interestingly, polyfunctional CD8+ T cells have been shown to be associated with better viral control in elite HIV controllers and may be critical for therapeutic HIV vaccine efficacy [
23,
24]. Those functional effector T cells produce cytokines such as IFN-γ, IL-2, MIP-1β TNF-α, and CD107a, which, in combination, aid in viral inhibition and potentiate the immune response by activating other immune cells.
Here, we demonstrate that both artArena- and rArena-based heterologous immunization regimens induced SIV-specific polyfunctional CD8 T-cell responses. The strong induction of polyfunctional T-cell responses after heterologous immunization with artArena vectors was recently confirmed in a larger NHP cohort (
n = 24) SIV efficacy study published by our group. This study links the potent induction of cellular (polyfunctional T cells and T-cell breadth) and humoral (antibody) responses, induced by artLCMV and artPICV vectors encoding SIV antigens, to a significant reduction in SIV viral load for peak and setpoint in SIV
mac251-challenged animals [
19]. In the present study, we recapitulated the magnitude and breadth of the SIV-specific T-cell response against the encoded immunogens and investigated different regimens and routes of administration with both artPICV/artLCMV and rPICV/rLCMV vectors to determine the optimal vaccination setting. We found heterologous immunization with artArena vectors (alternating between PICV and LCMV) to be superior in regard to inducing T-cell responses when compared with rArena heterologous immunization. Interestingly, this difference was more pronounced after IV administration (
Figure 4A,C,D). This could be due to the slightly larger cohort size (
n = 8) for IV immunization that was achieved by combining the groups compared with IM immunization (
n = 4).
Generally, we observed higher SIV CD8 T-cell response than CD4 T-cell in our study, which further illustrates the potential of arenavirus vectors in generating strong CD8 T-cell immunity, as reported previously in cancer models in mice [
20] and in clinical-trial settings [
18].
Viral vectors such as Ad5 have been shown to produce vector-neutralizing antibodies that limit the effectiveness of T-cell response in individuals with pre-existing immunity to the vectors or prevent repeated administration with same vectors [
25,
26]. In our study cohorts, we measured anti-LCMV and anti-PICV neutralizing antibodies after immunization with artPICV/artLCMV arenavirus vectors and their impact on vaccine-induced T-cell responses. Although we observed anti-vector-neutralizing antibodies with repeated dosing, they did not negatively impact SIV-specific T-cell responses (
Supplementary Figure S9), as we observed that boosting with LCMV- or PICV-based vectors further enhanced cellular immune responses (
Figure 2). This indicates that the first exposure to these vectors did not prevent them from boosting the response to the immunogen and suggests that anti-vector antibodies against these arenavirus vectors do not affect vaccine antigen responses when delivered as a heterologous prime–boost regimen. Additionally, a larger cohort of 24 NHPs was tested in the scope of the aforementioned efficacy study [
19], and similarly, repeated, alternating administration of artPICV and artLCMV vectors induced anti-LCMV neutralization antibodies but did not negatively impact SIV immunogenicity, as shown by an increase in SIV immunogen-specific humoral and cellular responses. A potential explanation for our observation is the internalization of viral vector–immune complexes (comprising vector and anti-vector nAbs) via FcgR into APCs. This uptake could account for the generation of vaccine-specific responses in the presence of a low level of anti-vector nAbs, as has been hypothesized previously [
27]. A similar mechanism leading to SIV-specific T-cell and B-cell response in the presence of vector nAbs might be responsible for the lack of correlation between SIV T-cell response and vector nAbs in the present study.
Interestingly, in a phase 1 clinical trial of a rLCMV vector-based vaccine against human cytomegalovirus, no LCMV-neutralizing antibodies were detected after repeated homologous dosing of the vaccine [
17]. These differences in observation likely originate from (i) virological and biological differences between artArena and rArena vectors and (ii) differences in species. It was reported that subclinical LCMV infection in rhesus macaques stimulated adaptive immunity that included virus-binding antibodies and cell-mediated immunity [
28]. Concurrent with LCMV and PICV nAbs, we also detected vector backbone-specific T-cell responses, as measured by IFN-γ ELISPOT response against LCMV and PICV NP (
Figure 7B,C). While the route of administration had no detectable impact on the induction of vector NP-specific T-cell responses, we observed significantly lower vector nAb titers upon IM administration (
Figure 6B). An impact of vector-specific cellular and humoral immunity on antigen-specific responses cannot be ruled out, as the repeated administration of the same vector (homologous regimen) results in significantly lower SIV-specific T-cell responses compared with heterologous administration of the two phylogenetically distant vectors (artPICV and artLCMV), directing the cellular response toward the disease-specific antigens and away from responses to the backbone (
Supplementary Figures S10 and S11). This confirms previous findings in mouse tumor models [
20].
This suggests that the arenavirus vector platform can provide an advantage over other viral vectors, for which repeat dosing poses an issue due to pre-existing immunity against the vector platform. However, more research is needed to determine (i) the full extent of the advantages of the arenavirus platform over other platforms for vaccine development. Although an SIV virus challenge was not conducted in this study, a strong induction of polyfunctional T-cell responses after heterologous immunization with artArena vectors was recently confirmed in a larger NHP cohort (
n = 24) SIV efficacy study published by our group. This study links the potent induction of cellular (polyfunctional T cells and T-cell breadth) and humoral (antibody) responses induced by artLCMV and artPICV vectors encoding SIV antigens to a significant reduction in SIV viral load for peak and setpoint in SIVmac251-challenged animals [
19]. Based on the preclinical safety, immunogenicity, and efficacy profile of the vaccine, a phase 1b clinical trial employing artPICV/artLCMV arenavirus vectors that encode conserved regions of HIV antigens is planned (NCT06430905).
The nature of arenaviruses (e.g., LCMV and PICV) to infect professional APCs, such as dendritic cells and macrophages [
8,
10], supports several strategies that could be explored to further potentiate the immunogenicity of arenaviral vectors. For example, immune modulators that further activate, expand, or shape dendritic cells, macrophages, or T cells and their interaction could potentially increase the vaccine immunogenicity of such vectors. Furthermore, arenaviruses could potentially be combined with complementary viral vectors, as suggested by a study that used a recombinant Ad5 vector prime followed by an rLCMV boost [
29]. These findings suggest that SIV vaccine immunogenicity can be further enhanced by combining arenavirus vectors with other vaccine platforms, like chimpanzee adenoviral (ChAd) vectors, modified vaccinia vectors, or mRNA-based lipid nanoparticles.