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(Received for publication, November 28, 1995; and in revised form, December 28, 1995) Recombinant Fv derivative of the high affinity murine
anti-fluorescein monoclonal antibody 4-4-20 was constructed and
expressed in high yields, relative to the single chain antibody (SCA)
derivative (2-3-fold), in Escherichia coli. Both
variable heavy (V
Volume 271,
Number 10,
Issue of March 8, 1996 pp. 5338-5346
©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
RELATIONSHIP BETWEEN INTERDOMAIN INTERACTIONS AND THE HIGH AFFINITY
FOR FLUORESCEIN LIGAND
) and variable light (V
)
domains, that accumulated as insoluble inclusion bodies, were isolated,
denatured, mixed, refolded, and affinity-purified to yield active Fv
4-4-20. Affinity-purified Fv 4-4-20 showed identical ligand binding
properties compared with the SCA construct, both were slightly lower
than the affinities expressed by Fab or IgG 4-4-20. Proper protein
folding was shown to be domain-independent by in vitro mixing
of individually refolded variable domains to yield functional Fv
protein. In solid phase and solution phase assays, Fv 4-4-20 closely
approximated the SCA derivative in terms of both idiotype and metatype,
confirming identical active site structures and conformations. The
equilibrium dissociation constant (K) for
the V
/V association (1.43 
10M), which was determined using the
change in fluorescein spectral properties upon ligand binding, was
relatively low considering the high affinity displayed by the Fv
protein for fluorescein (K
, 2.9
10M). Thus, domain-domain stability in
the Fv and SCA 4-4-20 proteins cannot be the sole cause of reduced
affinity (2-3-fold) for fluorescein as compared with the Fab or
IgG form of 4-4-20. With their identical ligand binding and structural
properties, the decreased SCA or Fv affinity for fluorescein must be an
ultimate consequence of deletion of the C
1 and C constant domains. Collectively, these results verify the
importance of constant domain interactions in antibody variable domain
structure-function analyses and future antibody engineering endeavors.
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