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Benner, Steven
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Daniel Hutter's Publications
Incorporation of Multiple Sequential Pseudothymidines by DNA Polymerases and Their Impact on DNA Duplex Structure
Havemann, SA
Hoshika, S
Hutter, D
Benner, SA
Nuc. Nuc. Nuc. acids 27
(3)
261-278
(2008)
<Abstract>
In this article, we focus on the synthesis of aryl C-glycosides via
Heck coupling. It is organized based on the type of structures used in
the assembly of the C-glycosides (also called C-nucleosides) with the
following subsections: pyrimidine C-nucleosides, purine C-nucleosides,
and monocyclic, bicyclic, and tetracyclic C-nucleosides. The reagents
and conditions used for conducting the Heck coupling reactions are
discussed. The subsequent conversion of the Heck products to the
corresponding target molecules and the application of the target
molecules are also described.
Artificially expanded genetic information system: a new base pair with an alternative hydrogen bonding pattern
Yang, ZY
Hutter, D
Sheng, PP
Sismour, AM
Benner, SA
Nucl. Acids Res. 34
(21)
6095-6101
(2006)
<Abstract>
To support efforts to develop a 'synthetic biology' based on an
artificially expanded genetic information system (AEGIS), we have
developed a route to two components of a non-standard nucleobase pair,
the pyrimidine analog
6-amino-5-nitro-3-(1'-beta-D-2'-deoxyribofuranosyl)-2(1H)-pyridone (dZ)
and its Watson-Crick complement, the purine analog
2-amino-8-(1'-beta-D-2'-deoxyribofuranosyl)-imidazo[1,2-a]-1,3,5-triazin
-4(8H)-one (dP). These implement the pyDDA:puAAD hydrogen bonding
pattern (where 'py' indicates a pyrimidine analog and 'pu' indicates a
purine analog, while A and D indicate the hydrogen bonding patterns of
acceptor and donor groups presented to the complementary nucleobases,
from the major to the minor groove). Also described is the synthesis of
the triphosphates and protected phosphoramidites of these two
nucleosides. We also describe the use of the protected phosphoramidites
to synthesize DNA oligonucleotides containing these AEGIS components,
verify the absence of epimerization of dZ in those oligonucleotides,
and report some hybridization properties of the dZ:dP nucleobase pair,
which is rather strong, and the ability of each to effectively
discriminate against mismatches in short duplex DNA.
Expanding the genetic alphabet: Non-epimerizing nucleoside with the pyDDA hydrogen-bonding pattern
Hutter, D
Benner, SA
J. Org. Chem. 68
(25)
9839-9842
(2003)
<Abstract>
6-Amino-3-(2'-deoxy-beta-D-ribofuranosyl)-5-nitro-1H-pyridin-2-one (4),
a C-glycoside exhibiting the nonstandard pgammaDDA hydrogen-bonding
pattern, was synthesized via Heck coupling. The nitro group greatly
enhances the stability of the nucleoside toward acid-catalyzed
epimerization without leading to significant deprotonation of the
heterocycle at physiological pH. These results make nucleoside 4 a
promising candidate for an expanded genetic alphabet.
Synthetic biology with artificially expanded genetic information systems. From personalized medicine to extraterrestrial life
Benner, SA
Hutter, D
Sismour, AM
Nucleic Acids Res. Suppl. 3 125-126
(2003)
<Abstract>
Over 15 years ago, the Benner group noticed that the DNA alphabet
need not be limited to the four standard nucleotides known in
natural DNA. Rather, twelve nucleobases forming six base pairs
joined by mutually exclusive hydrogen bonding patterns are
possible within the geometry of the Watson-Crick pair
(Fig. 1). Synthesis and studies on these compounds have brought us
to the threshold of a synthetic biology, an artificial chemical
system that does basic processes needed for life (in particular,
Darwinian evolution), but with unnatural chemical structures. At
the same time, the artificial genetic information systems (AEGIS)
that we have developed have been used in FDA-approved commercial
tests for managing HIV and hepatitis C infections in individual
patients, and in a tool that seeks the virus for severe acute
respiratory syndrome (SARS). AEGIS also supports the next
generation of robotic probes to search for genetic molecules on
Mars, Europa, and elsewhere where NASA probes will travel.
Phosphates, DNA, and the search for nonterrean life: A second generation model for genetic molecules
Benner, SA
Hutter, D
Bioorg. Chem. 30
(1)
62-80
(2002)
<Abstract>
Phosphate groups are found and used widely in biological chemistry. We
have asked whether phosphate groups are likely to be important to the
functioning of genetic molecules. including DNA and RNA. From
observations made on synthetic analogs of DNA and RNA where the
phosphates are replaced by nonanionic linking groups, we infer a set of
rules that highlight the importance of the phosphodiester backbone for
the proper functioning of DNA as a genetic molecule. The polyanionic
backbone appears to give DNA the capability of replication following
simple rules, and evolving. The polyanionic nature of the backbone
appears to be critical to prevent the single strands from folding.
permitting them to act as templates, guiding the interaction between
two strands to form a duplex in a way that permits simple rules to
guide the molecular recognition event, and buffering the sensitivity of
its physicochemical properties to changes in sequence. We argue that
the feature of a polyelectrolyte (polyanion or polycation) may be
required for a "self-sustaining chemical system capable of Darwinian
evolution." The polyelectrolyte structure therefore may be a universal
signature of life, regardless of its genesis. and unique to living
forms as well. (C) 2002 Elsevier Science (USA).
From phosphate to bis(methylene) sulfone: Non-ionic backbone linkers in DNA
Hutter, D
Blaettler, MO
Benner, SA
Helv. Chim. Acta 85
(9)
2777-2806
(2002)
<Abstract>
Chimeric DNA molecules containing four different linking groups, the
natural phosphate, 5'-methylenephosphonate. bis(methylene)phosphinate,
and bis(methylene) sulfone (see Fig.1), were directly compared for
their ability to form duplexes with complementary DNA and DNA chimeras.
From melting temperatures for analogous complementary sequences,
general conclusions about the impact of geometric distortion of the
internucleotide linkage around the two P-O-C bridges were drawn, as
were conclusions about the impact on duplex stability that arises from
the removal of the negative charge in the linking group. Each
structural perturbation diminished the melting temperature, by ca.
-2.5degrees per modification for the 5'-methylenephosphonate,
-3.5degrees per modification for the bis(methylene)phosphinate, and
-4.5degrees per modification for the bis(methylene) sulfone linker.
These results have implications for DNA chemistry including the design
of 'antisense' candidates and the proposal of alternative genetic
materials in the search for non-terrean life.
Redesigning nucleic acids
Benner, SA
Battersby, TR
Eschgfaller, B
Hutter, D
Kodra, JT
Lutz, S
Arslan, T
Baschlin, DK
Blattler, M
Egli, M
Hammer, C
Held, HA
Horlacher, J
Huang, Z
Hyrup, B
Jenny, TF
Jurczyk, SC
Konig, M
von Krosigk, U
Lutz, MJ
MacPherson, LJ
Moroney, SE
Muller, E
Nambiar, KP
Piccirilli, JA
Switzer, CY
Vogel, JJ
Richert, C
Roughton, AL
Schmidt, J
Schneider, KC
Stackhouse, J
Pure Appl. Chem. 70
(2)
263-266
(1998)
<Abstract>
A research program has applied the tools of synthetic organic chemistry
to systematically modify the structure of DNA and RNA oligonucleotides
to learn more about the chemical principles underlying their ability to
store and transmit genetic information. Oligonucleotides (as opposed to
nucleosides) have long been overlooked by synthetic organic chemists as
targets for structural modification. Synthetic chemistry has now
yielded oligonucleotides with 12 replicatable letters, modified
backbones, and new insight into why Nature chose the oligonucleotide
structures that she did.
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