Mathematical Biology seminar
Keith Roper
Department of Chemical Engineering,
University of Utah
"Adenovirus binding, Elution and Equilibrium Measured by
Surface Plasmon Resonance"
October 20
3:05pm in LCB 215
Many diseases such as cancer, diabetes, hemophilia, cystic fibrosis,
heart disease and musculoskeletal disorders have an underlying genetic
basis. Using human genome sequence data, correlated DNA mutations can
be identified that could be altered to correct or prevent gene-related
disorders. One treatment approach is gene therapy: inserting correct
copies of the altered gene into non-germline cells using
nanometer-sized viral or synthetic liposome vectors as delivery
vehicles. About 90% of gene vectors used clinically are virus
derivatives, mostly retrovirus (35%), followed by adenovirus (27%).
About six hundred gene therapy clinical trials are in progress to
target cancer (60%), treat monogenic diseases like hemophilia or
cystic fibrosis (10%) or combat infectious disease like HIV (6%).
Manufacture of viral gene vectors begins with propagation in mammalian
cells followed by recovery using consecutive size-selective and
adsorptive purification steps. High-resolution chromatographic
purification of adenovirus is vital, since CBER recommends <100
picograms of residual DNA per dose from mammalian-cell products and
<100 virions per infectious unit. But chromatography of viruses is
limited by size and complexity of viral vectors and availability of
suitable media and protocols for virus adsorption. Existing resins
have been optimized to purify small synthetic organic molecules (�104
Da) or recombinant proteins (10^6 Da). Spherodex( resin, for example,
has 100-nm pores that exclude particles >10^7 Da including adenovirus
(1.65x10^8 Da). ResourceQ( resin has a detection limit for adenovirus
that exceeds 1x10^8 particles. These limitations are cost-prohibitive
and motivate development of more suitable media.
Development of chromatographic media suited to viral gene vector
adsorption requires understanding adsorption, desorption and
equilibrium binding interactions. We measure adsorption and desorption
rate and equilibrium binding constants of Adenovirus Type 5 on model
gold and derivatized gold surfaces using surface plasmon
resonance. Colloidal Ad5-surface interactions arise primarily from
electrostatic potential and van der Waals forces captured by DLVO
theory. Modulation occurs by (1) adsorbed polymers that cause
attractive bridging at low doses and steric repulsion at higher doses;
(2) attraction from free energy reductions that result from exclusion
of water from approaching hydrophobic surfaces; (3) repulsion arising
from dehydration of approaching hydrophilic surfaces; and (4)
heterogeneity of surface charge and structure. We estimate the
magnitude of these effects by adjusting solution components such as
nonionic surfactants that accommodate apolar hydrophobic groups into
the aqueous environment, and small single-charged ions like chloride
or multivalent ions like Ca2+ or Mg2+ that promote hydrophobic
adsorption by structuring water. Our measurements are useful to
optimize adsorbate physicochemistry and binding conditions for
Adenovirus Type 5 and allow screening of candidate surfaces.
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