Adeno-associated viruses (AAVs) are the vector of choice for the delivery of many gene therapy drugs. However, their bioprocessing can require multiple costly purification steps to remove potentially dangerous process-related impurities.
Now, improved workflows promise to deliver high-yielding, quality AAV-based products from high-titer starting samples in single workflow step. With the latest affinity solutions, biopharmaceutical companies can accelerate drugs to clinic with greater speed and safety.
This poster highlights several methods by which the downstream purification of viral vectors can be improved using chromatography methods to analyse and purify multiple AAV serotypes.
Download this poster to learn more about:
• Viral clearance potential and process yield improvement
• The industrial-scale development of AAV vectors
• Breakthrough analysis and elution recovery methods
Learn more at thermofisher.com/captureselect
Bioprocessing
INTRODUCTION
Adeno-Associated Virus (AAV) has become the vector of choice in many gene therapies.
Recent advances in chromatography resin development for viral vectors have demonstrated
that AAV purification can be scalable and efficient, achieving high purity and yield in a single
step. With an extensively growing pipeline of gene therapy clinical trials, it is evident that
scalable production solutions are needed. Here we outline the benefits of implementing
affinity chromatography in the downstream purification of viral vectors.
Chantelle Gaskin2, Kelly Flook2, Pim Hermans1, Alejandro Becerra2
, Frank Detmers1, Mike Coleman2
1. Thermo Fisher Scientific, Leiden, the Netherlands
2. Thermo Fisher Scientific, Bedford, MA
Accelerating advancement in gene therapy by
improving downstream purification of viral vectors
TRADEMARKS/LICENSING
© 2020 Thermo Fisher Scientific Inc. All rights reserved. All trademarks are the property of Thermo Fisher Scientific and its subsidiaries unless otherwise specified.
This information is not intended to encourage use of these products in any manner that might infringe the intellectual property rights of others.
Intended use: For research use or further manufacturing. Not for use in diagnostic procedures.
POROS™ CAPTURESELECT™ AAVX RESIN: A TRUE PLATFORM
FOR AAV PURIFICATION
Fig.1 CaptureSelect™ ligands are VHH fragments
(single domain antibody fragments – sdAb), the
smallest antigen binding molecule.
The small size of VHH fragments (15kD) allows
binding at difficult to reach epitopes. Overall, VHH
fragments offer high specificity, affinity and stability.
Harvest Clarification
Cation
Exchange
Anion Exchange
(Flow through)
Anion
Exchange
Tangential Flow
Filtration Sterile filtration
Harvest Clarification Affinity Concentration Sterile Filtration
Customer testimonial: “Process yield improvement from
20% to 60% & cost reduction by a factor of 6” CaptureSelect™ Paradigm
•Affinity capture = fewer
chromatography steps
•Simplified process
•Lower cost & speed to market
•Fewer steps = higher yield
AFFINITY SOLUTIONS FOR VIRAL VECTOR PURIFICATION
Thermo Scientific™ resin Binding Capacity (vg/mL) Serotype Affinity
POROS™ CaptureSelect™ AAV8 >1013 AAV8
POROS™ CaptureSelect™ AAV9 >1014 AAV9
POROS™ CaptureSelect™ AAVX >1014*
AAV1, AAV2, AAV3, AAV4, AAV5.
AAV6, AAV7, AAV8, AAV9,
recombinant & chimeric vectors
• Affinity through antibody selectivity (CaptureSelect™ technology) : technology based on
single domain [VHH] antibody fragments.
• Animal origin free production process (Saccharomyces cerevisiae)
• Combined with the large through-pore POROS backbone
* viral genomes per millilitre (vg)/mL, binding capacity will vary based on serotype, feed stream, additives, and mutations to parent serotypes
ü Reduce the number of steps in a purification procedure without
compromising product purity and yield
ü Increase process flexibility and throughput
ENABLING INDUSTRIAL SCALE DEVELOPMENT OF AAV VECTORS
PURITY
SDS-PAGE purity profile of AAV9 Vector recovery using POROS CaptureSelect
AAV9 at various scales
Fig. 3 Vector purity. A 1-step
Comparible purity, as determined
by SDS page, was obtained
between a 1-step AAV9 affinity
step en 3 IEX steps.
Fig. 4 Vector recovery. Yields >
80% were obtained from 10 L tot
200 L scale.
YIELD
Fig. 2 Reduced number of process steps through AAV affinity chromatography resins
ü Combining antibody-based selectivity and process robustness in
unique AAV affinity resins
ü Broad selectivity to both natural and synthetic capsids
ü High dynamic binding capacity
ü High elution recovery at different flow rates
ü Robust, with less process optimization % breakthrough
vg loaded per ml of resin
Fig.6 AAVX resin
serotype specificity
with a large variety
of serotypes.
Experimental settings. Static binding mode experiment: resin was mixed with AAV serotype in tube – no flow
properties performed. vg was determined by qPCR
* Data kindly provided by Massachusetts Eye and Ear
97.8 98.33 98.05 97.88 98.93 98.37 97.76 98.43 96.28 99.29 98.51
77.99
98.39
0
20
40
60
80
100
AAV2
AAV2_HSPG
AAV4
AAV5
AAV6.2
AAV7
AAV8
AAV9
AAVrh10
AAVrh32.33
AAV9PHPB
Anc80
AAV7m8
POROS™ CaptureSelect ™AAVX resin: Serotype specificity
vg distribution (% - eluate)
% binding - eluate
*
ü To date, the AAVX ligand has shown affinity towards all serotypes tested
Fig. 7 AAVX Breakthrough analysis.
Breakthrough as a function of vg loaded per ml of
resin. The breakthrough stayed below 0.5% up to
2e13 VG/ml of resin.
Fig. 8 Elution recovery. Elution recovery was
above 80% at each of the three different flow rates
used. Recovery was not influenced by flow rate or
residence time.
ü High capacity and a high degree of process design flexibility
ü High elution recovery at different flow rates
CONCLUSIONS
POROS™ CaptureSelect™ AAV resins address the current challenges involved
with viral vector purification. Use of these resins will:
• Simplify your purification process and increase process design flexibility
• Increase purity and yield
• Allow for scalable purification of multiple AAV serotypes in a single platform
In addition we have demonstrated that the AAVX resin can be an effective viral
clearance step in the downstream process of AAV manufacturing
Fig. 9 Purification yield is comparable at
various scales. Vector recovery in eluate after
using POROS™ CaptureSelect™ AAVX resin for
the purification of two different serotypes at
various production scales.
Use of AAVX at various scales shows:
ü Robust resin scale up
ü Comparable recoveries at various scales
ü Consistency in resin performance
0%
20%
40%
60%
80%
100%
120%
12 L 500 L1000 L
3 L 7 L 10 L 200 L
Serotype A Serotype C
% Recovery
UNDERSTANDING THE VIRAL CLEARANCE POTENTIAL
Table 1. Clearance of
model viruses. Log
reduction values (LRV)
of enveloped (env) and
non-enveloped (nonenv) model viruses
using the AAVX resin.
ü The AAVX resin can be an effective viral clearance step in the
downstream process of AAV production
AAVX SEROTYPE SPECIFICITY
BREAKTHROUGH ANALYSIS AND ELUTION RECOVERY
DEMONSTRATING SCALABILITY
RNA
env
DNA
non-env
DNA
env
RNA
non-env
Run Description XMuLV MVM Reo-3 HAV PRV HSV-1
Manufacturing process conditions > 6.4 4.4 2.7 > 4.9 4.0 3.1
Higher load ratio + residence time
(worst case scenario) 4.6 3.6 2.5 5.0 3.8 3.6
Clearance Effective Effective Contributing Effective Effective Contributing
≥ 4 LRV Effective
1 - 3 LRV Contributing
< 1 LRV Negligible
Viral clearance data from an AAV8 clinical production process using the AAVX resin.
