Post on 24-Aug-2020
KnotBodiesTM: creating ion channel blocking antibodies by fusing Knottins into
peripheral CDR loops
Aneesh Karatt Vellatt
Confidential
Precision Medicine and Ion Channel Retreat 2017
Vancouver
Antibody discovery at IONTAS
Target Selection Protein
production Lead
Isolation Primary Screen
Lead Optimisation
Secondary Screening
Lead/back up
Production
Mammalian display
KnotBodiesTM
Research
Phage library
4 x 1010 clones
High proportion of
insert
IgG
Fab scFv
Bi-specific
Antibody drug discovery company founded in Oct 2012
Powerful track record – 24 antibody discovery projects with 14 European and US organisations to Q1 2017
100% record of success!
Targeting ion channels with antibodies
Challenging target class for antibody generation Difficult to express and purify, low stability Limited epitope availability Dynamic molecules with multiple conformations
Plasma
membrane
VGSC
Conus snail
Casewell et al Trends in Ecology and Evolution (2013)
Mambalgin1
ASIC
blocker
Velvet Tarantula
Sea anemone
Black Mamba
Ziconotide
Cav2.2
blocker
ShK
Kv1.3
blocker
ProTx-II
Nav1.7
blocker
Knottins: nature’s ion channel inhibitor scaffold
30-40 amino acids, 3-4 disulfide bonds Forms a conserved (Inhibitory Cystine Knot) structural motif high sequence and functional diversity despite the structural
conservation Also found in non venomous species and modulate wide variety
of biological functions
PcTx1
ASIC1 blocker
Huwentoxin-IV
Nav blocker
ω-conotoxin-MVIIA
: Cav blocker
Knottins: therapeutic development
Ziconotide (PRIALT®; Primary Alternative to Morphine) ω-conotoxin-MVIIA, blocks N-type calcium channels Approved for the treatment of neuropathic pain
Dalazatide (ShK-186)
Engineered ShK toxin, blocks Kv1.3 In phase II trials for the treatment of psoriasis
Most naturally occurring knottins lack exquisite specificity Huwentoxin-IV block potently both Nav1.7 and Nav1.2 ShK (non-engineered) toxin equally blocks Kv1.3 and Kv1.1
Evolved to paralyse prey hence not specific and requires further engineering for therapeutic use
Challenges in knottin engineering and therapeutic development
Limited compatibility with robust library selection technologies that can sample large mutant libraries
Rational design strategies are laborious and exert less control over the specificity of new binders
Chemical synthesis can be complex and expensive
Half life of minutes to hours: too short for a drug that is expensive to synthesise
Scaffolds within scaffolds: Combining the benefits of knottins and antibodies
KnotBodiesTM concept: Insert knottins into peripheral antibody CDR loops
Engineer other CDR loops for improved potency
and selectivity using phage display technology
Knottins Natural blockers of ion channels
Lack specificity, short half life
Difficult to engineer
Antibodies Large binding surface providing specificity
Amenable to engineering using in vitro
selection technologies
Long half life
Ecballium elaterium (Jumping cucumber)
EETI-II: Trypsin
inhibitor (as model
knottin)
Specific ion channel modulators with long half life!
Inserting EETI-II knottin into VL CDRs
CDR1 CDR3 FR1 FR2 FR3 FR4
Knottin Randomised linkers joining
EETI-II knottin to VL framework
Variation in recipient VL
scaffold
VH VL
Fv
VL
VH
H chain
L chain
IgG
Selecting antibodies by phage display
McCafferty et al (1990) Nature 348 p552-4
Immobilised antigen
(Trypsin)
Genotype Genotype + Phenotype Select for phenotype
i.e. antigen binding
AntibodydisplayedonphageaspIIIfusion
Geneencodingthedisplayedantibody
SigP
Promoter
GeneIII
PhagedisplayVector
VH VL
Antibody(inscFvformat)
0
50000
100000
150000
200000
250000
300000
A B C
Tryp
sin
bin
din
g (F
U)
EETI-II Direct phage display
EETI-II CDR1 Fusion
EETI-II CDR2 Fusion
Insertion into antibody CDRs make knottins amenable to phage display!
0
50000
100000
150000
200000
250000
1 8 15 22 29 36 43 50 57 64 71 78 85 92
Tryp
sin
bin
din
g (F
U)
Clone number
VL-CDR1 2 rounds phage (18/94 binders)
0
50000
100000
150000
200000
250000
1 8 15 22 29 36 43 50 57 64 71 78 85 92
Tryp
sin
bin
din
g (F
U)
Clone number
VL-CDR2 2 rounds phage (42/94 binders)
Monoclonal ELISA of trypsin binding KnotBodiesTM
Confirm specificity with EETI-II
loop 1 (trypsin binding loop)
mutation
CPRILMRC
CGAILMRC
0
10
20
30
40
50
60
70
80
90
100
"Selected linker"
Gly4Ser linker (Gly4Ser)2 linker
"Selected linker"
Gly4Ser linker (Gly4Ser)2 linker
KB_A07 KB_A12
No
rmal
ise
d t
rysp
in b
ind
ing
(%)
Correct linkers are important for function
KB_A12( 2.5Å) KB_A05 (1.95Å)
Crystal structure of KnotBodiesTM
Crystal structure of KnotBodiesTM
Demonstrating the capabilities of the KnotBodyTM format
(i) Improving the existing knottin binding by introducing additional VH contacts
(ii) Create a bispecific molecule by introducing a VH that binds to different target
(iii) Alter the specificity of the original knottin scaffold by loop diversification
(iv) Generate ion channel blocking KnotBodies
0
50000
100000
150000
200000
250000
300000
350000
400000
B0
6
A1
0
B0
7
C0
1
E06
D0
8
F11
D0
9
C0
6
E08
F02
H0
7
A0
7
D0
1
H0
5
F07
C0
2
H0
1
E07
C1
0
G0
3
B0
8
D1
0
E10
B0
3
B1
1
F05
E12
D1
2
G1
2
B1
2
A0
3
Tryp
sin
bin
din
g (F
U)
Clone ID
KB_A07
Affinity ranking using ELISA
KB_A12
Improved affinity of KnotBodyTM through partner VH selection
Ch
an
ge
in
SP
R Affinity improved clone
KB_A07 (Parent clone) KB_A12 (parent clone)
Trypsin
binding
Off-rate analysis using SPR
Time (S)
Trypsin dissociation
cMET
Gas
6
FGFR
4
Tryp
sin
0
10000
20000
30000Parent KnotBody
Bin
din
g (
FU
)
cMET
Gas
6
FGFR
4
Tryp
sin
0
120000
240000
360000
Bin
din
g (
FU
)
cMET bi-specfic KnotBody
cMET
Gas
6
FGFR
4
Tryp
sin
0
120000
240000
360000
Bin
din
g (
FU
)
Gas6 bi-specific KnotBody
cMET
Gas
6
FGFR
4
Tryp
sin
0
120000
240000
360000
Bin
din
g (
FU
)
FGFR4 bi-specific KnotBody
VL VH VL
VL VL VH VH
Bispecific binding through partner VH selection
Altering specificity of knottin “donor”
KB_A12 KnotBody
Randomise L1 loop of EETI-II donor-> 4 x 109 library
(loop lengths= 6, 8, 9, 10 using VNS codons)
Altering specificity of knottin “donor”
0
20000
40000
60000
80000
100000
120000
140000
160000
180000
200000
1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 43 45 47
Clone number
0
50000
100000
150000
200000
250000
300000
350000
400000
450000
500000
550000
600000
1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 43 45 47
Clone number
c-Met b-galactosidase
23/47 unique 11/47 unique
-CPRILMRC-
An
tig
en
bin
din
g (
FU
)
L1 loop
Role of potassium channels in T effector cell signaling
Activated CM
Naïve
effector Naïve
Central
memory
Effector
memory
Activated EM
Kv1.3 Model from: Murray et al. (2015) J. Med Chem.
pore
ShK
mutant
Autoreactive TEM cells depend heavily on Kv1.3, while naïve and central memory T cells depends on KCa3.1
Autoreactive TEM cells can be eliminated via selective inhibition of Kv1.3
Measuring Kv1.3 ion channel currents using automated patch clamp
control, t = 0 min
0.5 nM, t = 4 min
5 nM, t = 8 min
50 nM, t = 12 min
500 nM, t = 16 min
100 ms
0.5
nA
-80 mV
+30 mV, every 10 s
Sophion QPatch
-10 -9 -8 -7 -6 -5
0
25
50
75
100
Log [M]
% c
urr
en
t re
ma
inin
g
KB_HsTX1IC50 = 3.9 nM
-10 -9 -8 -7 -6 -5
0
25
50
75
100
Log [M]
% c
urr
en
t re
ma
inin
g
KB_ShKIC50 = 8.6 nM
-10 -9 -8 -7 -6 -5
0
25
50
75
100
Log [M]
% c
urr
en
t re
ma
inin
g
KB_KalioTxIC50 = 430 nM
Functional inhibition of Kv1.3 by KnotBodiesTM
ShK KnotBody Kaliotoxin KnotBody
-10 -9 -8 -7 -6 -5
0
25
50
75
100
Log [M]
% c
urr
en
t re
ma
inin
g
KB_HsTX1IC50 = 3.9 nM
-10 -9 -8 -7 -6 -5
0
25
50
75
100
Log [M]
% c
urr
en
t re
ma
inin
g
KB_ShKIC50 = 8.6 nM
-10 -9 -8 -7 -6 -5
0
25
50
75
100
Log [M]
% c
urr
en
t re
ma
inin
g
KB_KalioTxIC50 = 430 nM
Functional inhibition of Kv1.3 by KnotBodiesTM
ShK KnotBody inhibited cytokine and Granzyme B secretion by activated PBMCs
Functional inhibition of ASIC1a by KnotBodiesTM
KnotBody A07_PcTX1 KnotBody A12_PcTX1
Therapeutic areas: neuropathic pain, neurological disorders
PcTX1 (Psalmotoxin) - ASIC1a toxin blocker
-9 -8 -7 -6 -5
0
25
50
75
100
Log [M]
% c
urr
en
t re
ma
inin
g
IC50 = 98 nM
-9 -8 -7 -6 -5
0
25
50
75
100
Log [M]
% c
urr
en
t re
ma
inin
g
IC50 = 68 nM
Rapid generation of cell lines for specificity screening
CHO-S cells
Suspension cells
Easy to culture
No dissociation required
Direct use in APC
pINT_ IC Vectors
pIONTAS IC Vectors
Transient expression
Polyclonal stable expression using transposase system
Expression from a specific locus using nuclease mediated integration
MaxCyte STX Electroporation
High transfection efficiency and scalability
High cell viability
Efficient multi plasmid co-transfection
Test Parameters
Kv1.3-CHO Stable Cell Line
(CRL)
Kv1.3 Transient MaxCyte
(24 h after EP)
Kv1.3 + Transposase MaxCyte
(2 weeks after EP)
Cell Viability (%) ≈ 99 ≈ 99 ≈ 98
Mean IK+ (nA) 1.5 ± 1.3 4.7 ± 3.1 2.8 ± 3.4
% IK+ >0.5nA 91 88 87
% seal >1 G 89 83 88
I-V V1/2 (mV) -1.2 2.5 1.1
I-V slope (mV) 26.7 21.7 20.4
Comparison with monoclonal stable cell line
Data obtained using Sophion QPatch, Single hole mode
-12 -11 -10 -9 -8 -7
0
25
50
75
100
Log [M]
% c
urr
en
t re
main
ing
Kaliotoxin
Kv1.1 Transient
Kv1.3 Stable
Kaliotoxin
Kv1.3-CHO stable
Kv1.3 Transient
Kv1.3 +
Transposase
Kv1.1 Transient
IC50 (nM) 0.78 0.68 0.56 2.5
Evaluating the pharmacology of Kaliotoxin
-12 -11 -10 -9 -8 -7
0
25
50
75
100
Log [M]
% c
urr
en
t re
main
ing
Kaliotoxin
Kv1.3 Transient
Kv1.3 +Transp
Kv1.3 Stable
Tapping into nature’s ion channel scaffold
Antibody acquires the ion channel modulating functionality of the knottin
Knottin gains half-life improvement
Increased affinity and specificity from other CDRs
Potential to engineer knottin
Novel bi-specific format
KnotBodiesTM: Summary
Acknowledgement
• John McCafferty
• Damian Bell • Sachin Surade • Edward Masters • Alice Luther • Rachael Leah • Tim Leutkens
• Peter Slavny
• Naja Møller Sørensen • Daniel Sauter
• Payal Roychoudhuri • Caoimhe Nic An tSaoir • Jason Marks
Thank You
Expression and purification of Fab formatted KnotBodiesTM
KnotBody Fabs express well
100 % monomer on SEC
Tm1=76.0°C, Tm2=81.3°C
N.R
R
N.R
R
N.R: Non reducing SDS PAGE
R: Reducing SDS PAGE
Size exclusion chromatography (SEC) profile SDS PAGE
Comparison of KnotBody with bovine antibody with ultralong CDR3
Reshaping antibody diversity
(2013) Wang et al Cell, 153 p1379-1393