Mateo I. Sánchez

Bis-4-aminobenzamidines: versatile, fluorogenic A/T-selective dsDNA binders.

N(1),N(3)-Bis(4-amidinophenyl)propane-1,3-diamine (BAPPA, R = H) is a bisaminobenzamidine fluorogenic derivative that displays a large increase in its emission fluorescence when bound to the minor groove of specific A/T DNA sites (K(d) for an AATT site approximately 79 +/- 6 nM). Moreover, the structural characteristics of BAPPA allow the easy introduction of functional groups that protrude out of the DNA surface.

Straightforward access to bisbenzamidine DNA binders and their use as versatile adaptors for DNA-promoted processes

Bisbenzamidines are an important family of minor groove DNA-binding agents. We present a one-step synthesis of aromatic aza-bisbenzamidines that allows straightforward and versatile access to a large number of these molecules. One of them, the azide-aza-bisbenzamidine 13, can be readily modified via click-chemistry with a variety of functionalities that can, therefore, be delivered to the vicinity of an A/T-rich DNA minor groove. This strategy, therefore, provides a simple means for triggering site selective, DNA-promoted biochemical and physicochemical processes.

Reversible Supramolecular Assembly at Specific DNA Sites: Nickel-Promoted Bivalent DNA Binding with Designed Peptide and Bipyridyl–Bis(benzamidine) Components†

At specific DNA sites, nickel(II) salts promote the assembly of designed components, namely a bis(histidine)-modified peptide that is derived from a bZIP transcription factor and a bis(benzamidine) unit that is equipped with a bipyridine. This programmed supramolecular system with emergent properties reproduces some key characteristics of naturally occurring DNA-binding proteins, such as bivalence, selectivity, responsiveness to external agents, and reversibility.

Sequence-selective DNA recognition with peptide-bisbenzamidine conjugates.

Transcription factors (TFs) are specialized proteins that play a key role in the regulation of genetic expression. Their mechanism of action involves the interaction with specific DNA sequences, which usually takes place through specialized domains of the protein. However, achieving an efficient binding usually requires the presence of the full protein. This is the case for bZIP and zinc finger TF families, which cannot interact with their target sites when the DNA binding fragments are presented as isolated monomers. Herein it is demonstrated that the DNA binding of these monomeric peptides can be restored when conjugated to aza-bisbenzamidines, which are readily accessible molecules that interact with A/T-rich sites by insertion into their minor groove. Importantly, the fluorogenic properties of the aza-benzamidine unit provide details of the DNA interaction that are eluded in electrophoresis mobility shift assays (EMSA). The hybrids based on the GCN4 bZIP protein preferentially bind to composite sequences containing tandem bisbenzamidine-GCN4 binding sites (TCAT⋅AAATT). Fluorescence reverse titrations show an interesting multiphasic profile consistent with the formation of competitive nonspecific complexes at low DNA/peptide ratios. On the other hand, the conjugate with the DNA binding domain of the zinc finger protein GAGA binds with high affinity (KD≈12 nM) and specificity to a composite AATTT⋅GAGA sequence containing both the bisbenzamidine and the TF consensus binding sites.

Custom-Fit Ruthenium(II) Metallopeptides: A New Twist to DNA Binding With Coordination Compounds

A new bipyridine building block has been used for the solid-phase synthesis of dinuclear DNA-binding ruthenium(II) metallopeptides. Detailed spectroscopic studies suggest that these compounds bind to the DNA by insertion into the DNA minor groove. Moreover, the potential of the solid-phase peptide synthesis approach is demonstrated by the straightforward synthesis of an octaarginine derivative that shows effective cellular internalization and cytotoxicity linked with strong DNA interaction, as evidenced by steady-state fluorescence spectroscopy and AFM studies.

Light‐controlled cellular internalization and cytotoxicity of nucleic acid‐binding agents. Studies in vitro and in zebrafish embryos

We synthesized octa‐arginine conjugates of DNA‐binding agents (bisbenzamidine, acridine and Thiazole Orange) and demonstrated that their DNA binding and cell internalization can be inhibited by appending a (negatively charged) oligoglutamic tail through a photolabile linker. UV irradiation released the parent conjugates, thus restoring cell internalization and biological activity. Assays with zebrafish embryos demonstrates the potential of this prodrug strategy for controlling in vivo cytotoxicity.

Fluorescence‐Labeled Bis‐benzamidines as Fluorogenic DNA Minor‐Groove Binders: Photophysics and Binding Dynamics

In recent decades there has been great interest in the design of highly sensitive sequence-specific DNA binders. The eligibility of the binder depends on the magnitude of the fluorescence increase upon binding, related to its photophysics, and on its affinity and specificity, which is, in turn, determined by the dynamics of the binding process. Therefore, progress in the design of DNA binders requires both thorough photophysical studies and precise determination of the association and dissociation rate constants involved. We have studied two bis-benzamidine (BBA) derivatives labeled by linkers of various lengths with the dye Oregon Green (OG). These fluorogenic binders show a dramatic fluorescence enhancement upon binding to the minor groove of double-stranded (ds) DNA, as well as significant improvement in their sequence specificity versus the parent BBA, although with decreased affinity constants. Detailed photophysical analysis shows that static and dynamic quenching of the OG fluorescence by BBA through photoinduced electron transfer is suppressed upon insertion of BBA into the minor groove of DNA. Fluorescence correlation spectroscopy yields precise dynamic rate constants that prove that the association process of these fluorogenic binders to dsDNA is very similar to that of BBA alone and that their lower affinity is mainly a consequence of their weaker attachment to the minor groove and the resultant faster dissociation process. The conclusions of this study will allow us to go one step further in the design of new DNA binders with tunable fluorescence and binding properties.

MitoBlue: a nontoxic and photostable blue-emitting dye that selectively labels functional mitochondria.

We report the discovery of a fluorogenic dye, N1,N3-di(2-aminidonaphthalen-6-yl) propane-1,3-diamine, MitoBlue, which selectively stains functional mitochondria while displaying low toxicity, bright blue emission, and high resistance to photobleaching. Additionally, we show that a biotin-labeled MitoBlue derivative can be used as a handle for the delivery of streptavidin-tagged species to the mitochondria.