As a potent nonviral system for biomolecular delivery to neurons via their axons, we have studied molecular characteristics of lysinated fluorescent dextran nanoconjugates with degrees of conjugation of 0.54-15.2 mol lysine and 0.25-7.27 mol tetramethyl rhodamine isothiocyanate (TRITC) per mol dextran. We studied the influence of conjugation with lysine and TRITC on the size and structure of different molecular weight dextrans and their mobility within axons. Dynamic light scattering (DLS) and small-angle neutron scattering (SANS) experiments revealed significant differences in the size and structure of unmodified and modified dextrans. Unexpectedly, lower-molecular-weight conjugated dextrans exhibited higher molecular volumes, which we propose is due to fewer intramolecular interactions than in higher-molecular-weight conjugated dextrans. Assessment of retrograde and anterograde movement of lysine- and TRITC-conjugated dextrans in axons in the lumbar spinal cord of chicken embryos showed that lower-molecular-weight dextrans translocate more efficiently than higher-molecular-weight dextrans, despite having larger molecular volumes. This comparative characterization of different molecular weight dextrans will help define optimal features for intracellular delivery.
Keywords: DLS; SANS; anterograde tracing; axonal transport; conjugated dextran; retrograde tracing.