Programmable
DNA Lattices: Design Synthesis and Applications
Contract Plan for FY2003
Duke(Reif) Planned Work: Further development of novel DNA tiles to form patterned 2D and 3D DNA lattices. Experimental demonstration & comparison of various assembly techniques for patterned 2D DNA lattices of moderate size(512 tiles), using techniques of unmediated algorithmic self-assembly, step-wise assembly, and directed nucleation assembly.
We plan to continued work on experimental demonstration and
comparison of a number of assembly techniques for constructing patterned 2D DNA
lattices of modest size, using techniques of unmediated algorithmic
self-assembly(programmed assembly via Wang tiles), step-wise assembly, and the
directed nucleation assembly technique(where an input DNA strand is synthesized
that encodes the required pattern, and then specified tiles assemble around
blocks of this input DNA strand, forming the required 1D or 2D pattern of
tiles).
NYU(Seeman) Planned Work: Improve 3D periodic
assemblies with host-lattice crystals that diffract to 2.5 Å resolution
or better, which is a resolution adequate for crystallography. Tie down
nanocrystals from the Alivisatos laboratory in a 2D DNA lattice.
We plan to continued work on design a variety of DNA motifs
expected to form 3D lattices, both periodic and aperiodic. We plan to complete
the DLS characterization of the melting behaviors of the aggregates so as (i)
to determine proper temperature ranges and preferred lattice periodicities, and
(ii) to establish a relationship between the melting temperatures established
by the DLS and the proper temperature at which to attempt crystallization. We
plan to continue to optimize thermal protocols for 3D assembly experiments so
as to control assembly formation. We also plan to continue to examine the solid materials that we produce
by means of X-ray diffraction experiments on synchrotron sources, to determine
crystal quality.
Caltech(Winfree) Planned Work: Assessment of model
parameters used in optimization algorithms by theoretical/experimental
closed-loop design-test-recalibrate cycle; addition of geometric and structural
energetic terms into the design models. Theoretical classification of reliable
DNA lattice motifs, using existing experimental systems and mathematical
framework. Design of an unbounded
binary counter (a component of the RAM circuit pattern) and characterization of
error rates during unmediated self-assembly of the binary counter.
We plan continued work to demonstrate algorithmic
self-assembly of DNA and controlled nucleation of self-assembled structures
using a binary counter design, which is an initial step toward the
self-assembly of an important circuit element, a RAM memory array. We will
experimentally determine error rates during unmediated self-assembly.
We will continue to develop software technology for design
of DNA nanostructures. Optimization algorithms for DNA design will be
implemented and tested. We plan to implement algorithms for prediction and
design of partition functions for multi-stranded DNA complexes and DNA
pseudo-knots, and for specifying and creating 3D molecular models of DNA
structures.
Further Work:
We will also continue to characterize various novel DNA
tiles, and investigate the use of these and related tiles to form DNA lattices.
We will continue investigation of modifications of the TX molecules with
additional Holiday junctions between the top and bottom dsDNA, so the resulting
tile, a “Cylindrical TX tile” (CTX), has a cylindrical conformation
and we will investigate the use of these and related families of DNA tiles to
form 3D DNA lattices based on hybrids of CTX plus more conventional DX and TX
tiles. We will continue characterizion of 1 D tilings of CTX tiles; we expect
these form long cylinders which may be able to capture linear structures (e.g.,
carbon nanotubes).We will continue design of DNA molecular building blocks
(MBBs) that can be rigidly attached to DNA lattices with a known orientation,
and of unbounded binary counter (a component of demultiplexing RAM lattice).