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Novel Adenovirus Vector-Based Vaccines for HIV-1

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Title: Novel Adenovirus Vector-Based Vaccines for HIV-1

1
Novel Adenovirus Vector-Based Vaccines for HIV-1
Dan H. Barouch Beth Israel Deaconess Medical
Center November 20, 2008
2
Rationale for the Development of Novel Adenovirus
Vector-Based Vaccines for HIV-1

The Merck rAd5-Gag/Pol/Nef vaccine failed to show
efficacy and may have resulted in increased HIV-1
acquisition in individuals with pre-existing
anti-Ad5 immunity
Homologous rAd5 regimens may be limited by
Pre-existing anti-Ad5 immunity
Skewed/inadequate quality of T lymphocyte
responses
Limited magnitude and breadth of responses as a
result of homologous vector re-administration
Minimal protective efficacy against SIV challenge
in rhesus monkeys
Potential advantages of novel rAd vectors
include
Evasion of pre-existing anti-vector immunity
Enhanced polyfunctionality/quality of T
lymphocyte responses
Augmented magnitude and breadth of responses
utilizing heterologous rAd prime-boost regimens
Improved protective efficacy against SIV
challenge in rhesus monkeys

3
Protective Efficacy of Heterologous rAd
Prime-Boost Regimens in Rhesus Monkeys

22 Mamu-A01/B17-negative rhesus monkeys
immunized with various rAd regimens expressing
SIV Gag (week 0, 24)
rAd26-Gag prime, rAd5-Gag boost (N6)
rAd35-Gag prime, rAd5-Gag boost (N6)
rAd5-Gag prime, rAd5-Gag boost (N4)
Sham (N6)
High-dose i.v. SIVmac251 challenge (week 52)
Highly stringent challenge model
(Mamu-A01/B17-negative rhesus monkeys, single
SIV Gag antigen, i.v. SIVmac251)
rAd5 alone and DNA/rAd5 regimens do not reduce
peak or setpoint SIV RNA levels in this model
(Casimiro et al. J. Virol. 79 15547-55 2005)

Liu et al. Nature, Nov 9, 2008 (advance online
publication)
4
Increased Magnitude and Breadth of Gag-Specific
Responses in rAd26/rAd5 Vaccinated Monkeys As
Compared with rAd5/rAd5 Vaccinated Monkeys
Gag ELISPOT Magnitude
Gag Epitope Breadth
Week
5
Improved Polyfunctionality of Gag-Specific
Responses in rAd26/rAd5 Vaccinated Monkeys As
Compared with rAd5/rAd5 Vaccinated Monkeys
6
Significant 1.4 Log Decrease in Peak SIV RNA in
rAd26/rAd5 Vaccinated Monkeys Post-Challenge
Peak SIV RNA Levels Day 14 Post-Challenge
Mean
Two-tailed Wilcoxon rank-sum tests
7
Long-Term Significant 2.4 Log Decrease in SIV RNA
in rAd26/rAd5 Vaccinated Monkeys Post-Challenge
Setpoint SIV RNA Levels Mean Day 112-500
Post-Challenge
Mean
death
Two-tailed Wilcoxon rank-sum tests
8
Clinical Survival Advantage in rAd26/rAd5
Vaccinated Monkeys for gt500 Days Post-Challenge
P0.03
P0.03
Fishers exact test
9
Anamnestic Gag-Specific Cellular Immune Responses
in rAd26/rAd5 Vaccinated Monkeys Post-Challenge
Day 0
Day 28
Day 56
Day 14
10
Anamnestic Gag-Specific Cellular Immune Responses
in rAd26/rAd5 Vaccinated Monkeys Post-Challenge
Gag Cytokine Functionality
Gag Epitope Breadth
11
Breadth and Magnitude of Gag-Specific Cellular
Immune Responses Correlate with Setpoint Viral
Loads
Gag ELISPOT Magnitude
Gag Epitope Breadth
Pre-Challenge
Post-Challenge
Spearman rank-correlation tests
12
Protection Correlated with Reduced Ki67
Proliferation of CCR5 Central and Effector
Memory CD4 T Lymphocytes
Central Memory CCR5 CD4
Effector Memory CCR5 CD4
Day
13
Protection Correlated with Preservation of
Central Memory CD4 T Lymphocytes
CD28CD95CD4/CD4 Cells Day 14 Post-Challenge
two-tailed Wilcoxon rank-sum test
14
Protection Correlated with Preservation of
CCR5CD4 T Lymphocytes
CCR5CD4/CD4 Cells Day 14 Post-Challenge
two-tailed Wilcoxon rank-sum test
15
Protection Correlated with Preservation of
Duodenal Memory CD4 T Lymphocytes
CD4/CD3 Cells Day 21 Post-Challenge
two-tailed Wilcoxon rank-sum test
16
Protective Efficacy of Heterologous rAd
Prime-Boost Regimens in Rhesus Monkeys

The heterologous rAd26/rAd5 regimen elicited
improved quality, breadth, and magnitude of
cellular immune responses as compared with the
homologous rAd5/rAd5 regimen
The heterologous rAd26/rAd5 regimen afforded a
significant 1.4 log reduction of peak and 2.4 log
reduction of setpoint SIV RNA as compared with
controls for gt500 days post-challenge
The homologous rAd5/rAd5 regimen failed to afford
a significant reduction of peak or setpoint SIV
RNA, consistent with prior studies

Liu et al. Nature, Nov 9, 2008 (advance online
publication)
17
Protective Efficacy of Heterologous rAd
Prime-Boost Regimens in Rhesus Monkeys

Thus, heterologous rAd prime-boost regimens can
afford durable partial protection in the
stringent SIV challenge model in which the
homologous rAd5 regimen fails
Protection correlated with Gag epitope-specific T
lymphocyte responses and did not involve a
homologous Env immunogen
These data suggest that T cell based vaccines
that are superior to the homologous rAd5 regimen
may afford better protection against HIV-1
We are not at the end of the road in terms of the
development of T cell-based HIV-1 vaccines

Liu et al. Nature, Nov 9, 2008 (advance online
publication)
18
Safety of Novel rAd Vectors

Are anamnestic Ad5-specific T lymphocyte
responses following rAd5 vaccination a safety
concern in individuals with baseline Ad5 NAb
titers?
Potential concern regarding cross-reactive T
lymphocytes between Ad5 and rare serotype Ads?
Collaborative study with D. Casimiro and M.
Robertson, Merck
116 subjects from Merck phase 1 studies of
rAd5-Gag
Dose 1010 or 1011 vp
Samples week 0 (pre-vaccine) and week 8
(post-2nd vaccine) serum and PBMC
Assays Ad NAb and ELISPOT assays with 104 MOI
virus
Peptide-specific assays and ICS assays in progress

19
Ad5 ELISPOT Responses Are Nearly Universal and Do
Not Correlate with Ad5 NAb Responses at Baseline
Baseline Serum and PBMC Samples
P0.83
20
Higher Ad5 NAb Responses Following Vaccination in
Individuals with Baseline Ad5 NAbs gt18 vs lt18
P2.4x10-3
P5.4x10-4
P2.1x10-5
P2.0x10-6
P5.8x10-4
P2.0x10-6
lt 18
gt18
lt 18
gt18
Baseline Ad5 NAb
1010 vp Ad5-Gag
1011 vp Ad5-Gag
21
No Detectable Ad26 NAb Responses Following
Vaccination
P0.88
P0.87
P0.81
P0.95
P0.79
P0.97
lt 18
gt18
lt 18
gt18
Baseline Ad5 NAb
1010 vp Ad5-Gag
1011 vp Ad5-Gag
22
No Detectable Ad35 NAb Responses Following
Vaccination
P0.48
P0.75
P0.35
P0.86
P0.51
P0.95
lt 18
gt18
lt 18
gt18
Baseline Ad5 NAb
1010 vp Ad5-Gag
1011 vp Ad5-Gag
23
No Detectable Ad48 NAb Responses Following
Vaccination
P0.86
P0.64
P0.84
P0.70
P0.79
P0.99
lt 18
gt18
lt 18
gt18
Baseline Ad5 NAb
1010 vp Ad5-Gag
1011 vp Ad5-Gag
24
Lower Ad5 ELISPOT Responses Following Vaccination
in Individuals with Baseline Ad5 NAbs gt18 vs lt18
P0.95
P0.91
P2.3x10-3
P8.3x10-3
P8.9x10-5
P0.043
P4.2x10-3
P0.53
lt 18
gt18
lt 18
gt18
Baseline Ad5 NAb
1010 vp Ad5-Gag
1011 vp Ad5-Gag
25
No Detectable Ad26 ELISPOT Responses Following
Vaccination
P0.27
P0.85
P0.95
P0.39
P0.32
P0.83
P0.64
P0.80
lt 18
gt18
lt 18
gt18
Baseline Ad5 NAb
1010 vp Ad5-Gag
1011 vp Ad5-Gag
26
No Detectable Ad35 ELISPOT Responses Following
Vaccination
P0.17
P0.49
P0.47
P0.55
P0.57
P0.75
P0.84
P0.56
lt 18
gt18
lt 18
gt18
Baseline Ad5 NAb
1010 vp Ad5-Gag
1011 vp Ad5-Gag
27
No Detectable Ad48 ELISPOT Responses Following
Vaccination
P0.85
P0.59
P0.55
P0.29
P0.40
P0.98
P0.75
P0.90
lt 18
gt18
lt 18
gt18
Baseline Ad5 NAb
1010 vp Ad5-Gag
1011 vp Ad5-Gag
28
Safety of Novel rAd Vectors

Ad5 T cell responses nearly universal in subjects
prior to vaccination likely driven by
cross-reactive hexon-specific T cell responses
among multiple common subgroup C Ads
Ad26, Ad35, Ad48 T cell responses also common
No correlation observed between Ad5 NAb titers
and Ad5 T cell responses prior to vaccination
Suggests that Ad5 NAb titers are not simply a
surrogate marker for Ad5 T cell responses
Similar baseline Ad5 T cell responses in subjects
with baseline Ad5 NAbs gt18 as compared with lt18

29
Safety of Novel rAd Vectors

Following rAd5 vaccination
Ad5 NAb responses higher in subjects with
baseline Ad5 NAbs gt18 as compared with lt18
Ad5 T cell responses lower in subjects with
baseline Ad5 NAbs gt18 as compared with lt18
No detectable increase in NAb or T cell responses
to Ad26, Ad35, Ad48
Consistent with STEP data to date (J. McElrath,
N. Frahm)
These data reduce the plausibility of the
hypothesis that enhancement of HIV-1 acquisition
in subjects with baseline Ad5 NAbs gt18 in the
STEP study was due to anamnestic vaccine-elicited
Ad5 T cell responses
Cross-reactive T cell responses against rare
serotype Ad vectors would pose even less of a
concern
Caveats functional ICS and mucosal responses TBD

30
Rationale for the Development of Novel Adenovirus
Vector-Based Vaccines for HIV-1

Novel rAd vectors are biologically different than
rAd5 vectors
Different cellular receptors
Different tropism
Different intracellular trafficking pathways
Different innate immune responses
Different phenotypes of adaptive immune responses
Novel rAd vectors outperform rAd5 vectors in
rhesus monkeys
Evade pre-existing anti-vector immunity
Enhance polyfunctionality/quality of T lymphocyte
responses
Augment magnitude and breadth of responses when
combined into heterologous rAd prime-boost
regimens
Substantially improve protection against
SIVmac251 in rhesus monkeys
Novel rAd vectors likely safer than rAd5 vectors
in humans
Designed to circumvent anti-vector immunity
No significant cross-reactive anti-vector humoral
immunity with Ad5
Extent of cross-reactive anti-vector cellular
immunity under investigation
NIH, FDA, and IRB approved initiation of our
rAd26 phase 1 study

31
Ad26.ENVA.01 Phase 1A StudyNIH IPCAVD Program

Single-site, randomized, double-blinded,
placebo-controlled phase 1A study to evaluate the
safety and immunogenicity of the Ad26.ENVA.01
vaccine vector (PI L. Baden)
First-in-human study of a rAd26 vector
48 subjects at low risk for HIV infection and
Ad26 seronegative
Groups
109 vp dose months 0, 1, 6 10 vaccinees, 2
placebos
1010 vp dose months 0, 1, 6 10 vaccinees, 2
placebos
1011 vp dose months 0, 1, 6 10 vaccinees, 2
placebos
Max dose months 0, 6 10 vaccinees, 2 placebos
Study in progress vaccine safe and well
tolerated to date

32
Ad5HVR48.ENVA.01 Phase 1A StudyNIH IPCAVD Program

Single-site, randomized, double-blinded,
placebo-controlled phase 1A study to evaluate the
safety and immunogenicity of the Ad5HVR48.ENVA.01
vaccine vector (PI L. Baden)
First-in-human study of a hexon-chimeric rAd5
vector
FDA clinical hold re risk criteria lifted
October 29, 2008
Enrollment expected to begin in Jan 2009
Likely more regulatory challenges for future
development of rAd5HVR48 as compared with rare
serotype rAd vectors

33
Design of Optimal Heterologous rAd Prime-Boost
Regimen rAd5HVR48/rAd26 in Rhesus Monkeys
Prime
Boost
IFN-g ELISPOT responses prior to and following
boost immunization
34
Design of Optimal Heterologous rAd Prime-Boost
Regimen rAd35/rAd26 and rAd48/rAd26 in Mice
Boost
Prime
IFN-g ELISPOT responses following boost
immunization
35
Desired Features of a Next-Generation T
Cell-Based HIV-1 Vaccine Candidate

Key features desired in a next-generation T
cell-based HIV-1 vaccine
Vectors that avoid pre-existing vector-specific
NAbs and that can be combined into a heterologous
prime-boost regimen
Antigens that improve cellular immune breadth and
that optimize coverage of global virus diversity

36
Desired Features of a Next-Generation T
Cell-Based HIV-1 Vaccine Candidate

Importance of cellular immune breadth
increasingly clear
Gag breadth critical for vaccine control of SIV
challenge in NHPs
Gag breadth critical for immune control of HIV in
humans (B. Walker)
In the STEP study, only limited breadth achieved
by Merck rAd5-Gag/Pol/Nef vaccine (J. McElrath,
N. Frahm, F. Li)
Mean of only 2-3 epitopes per vaccinee (and only
1 Gag epitope)
Gag epitopes not directed against conserved
regions of Gag
0 (zero) Gag epitopes in vaccinees with
pre-existing Ad5 NAbs
Trend observed between Gag breadth and setpoint
viral loads
Critical to improve breadth of Gag-specific
cellular immune responses in a next-generation T
cell-based HIV-1 vaccine

37
Desired Features of a Next-Generation T
Cell-Based HIV-1 Vaccine Candidate

We are currently exploring several antigen
strategies together with B. Korber to improve
cellular immune breadth
M mosaic Gag/Pol/Env antigens (2-valent)
M consensus Gag/Pol/Env antigens
Optimal natural clade C Gag/Pol/Env antigens

38
Desired Features of a Next-Generation T
Cell-Based HIV-1 Vaccine Candidate

Next generation T cell-based HIV-1 vaccines will
face a higher bar to advance into efficacy
studies
Novel vector regimen
Heterologous rAd prime-boost regimen using
serologically distinct rare serotype rAd vectors
Preclinical evidence of superior protective
efficacy compared with the homologous rAd5
regimen against SIV challenge in rhesus monkeys
Novel antigen concept
Antigen set optimized for augmented cellular
immune breadth and improved coverage of global
viral diversity
Preclinical evidence of superior breadth compared
with best natural clade C sequences using global
PTE peptides in rhesus monkeys

39
Conclusions

The failure of the Merck rAd5-Gag/Pol/Nef vaccine
clearly represents a product failure but may
not represent a concept failure of T cell based
vaccines in general
SIV challenge studies in rhesus monkeys show that
heterologous rAd prime-boost regimens with rAd26
vectors outperform homologous rAd5 regimens
Prototype rAd26 vector under evaluation in a
phase 1 study
Novel antigen sets aimed at improving cellular
immune breadth under evaluation in NHP studies
Evaluation of a heterologous rAd prime-boost
regimen using two rare serotype rAd vectors
expressing HIV-1 Gag/Pol/Env optimized for global
coverage may therefore be warranted