Boron-dipyrrin dyes, through rational design, yield promising new materials. With strong electron-donor functionalities and anchoring groups for attachment to nanocrystalline TiO 2 , these dyes proved useful as sensitizers in dye-sensitized solar cells. Their applicability in a solid-state electrolyte regime offers additional opportunities for practical applications.
Self-replication
at the molecular level is often seen as essential
to the early origins of life. Recently a mechanism of self-replication
has been discovered in which replicator self-assembly drives the process.
We have studied one of the examples of such self-assembling self-replicating
molecules to a high level of structural detail using a combination
of computational and spectroscopic techniques. Molecular Dynamics
simulations of self-assembled stacks of peptide-derived replicators
provide insights into the structural characteristics of the system
and serve as the basis for semiempirical calculations of the UV–vis,
circular dichroism (CD) and infrared (IR) absorption spectra that
reflect the chiral organization and peptide secondary structure of
the stacks. Two proposed structural models are tested by comparing
calculated spectra to experimental data from electron microscopy,
CD and IR spectroscopy, resulting in a better insight into the specific
supramolecular interactions that lead to self-replication. Specifically,
we find a cooperative self-assembly process in which β-sheet
formation leads to well-organized structures, while also the aromatic
core of the macrocycles plays an important role in the stability of
the resulting fibers.
Our
knowledge regarding the early steps in the formation of evolvable
life and what constitutes the minimal molecular basis of life remains
far from complete. The recent emergence of systems chemistry reinvigorated
the investigation of systems of self-replicating molecules to address
these questions. Most of these studies focus on single replicators
and the effects of replicators on the emergence of other replicators
remains under-investigated. Here we show the cross-catalyzed emergence
of a novel self-replicator from a dynamic combinatorial library made
from a threonine containing peptide building block, which, by itself,
only forms trimers and tetramers that do not replicate. Upon seeding
of this library with different replicators of different macrocycle
size (hexamers and octamers), we observed the emergence of hexamer
replicator consisting of six units of the threonine peptide only when
it is seeded with an octamer replicator containing eight units of
a serine building block. These results reveal for the first time how
a new replicator can emerge in a process that relies critically on
the assistance by another replicator through cross-catalysis and that
replicator composition is history dependent.
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