Characterization of Tissue Histology for the Injectable Cellulite Treatment Collagenase Clostridium Histolyticum-aaes: Results in Swine.

Background: Cellulite is a common aesthetic condition that affects predominantly females. Collagenase clostridium histolyticum-aaes (CCH-aaes) injections disrupt native collagen structures, resulting in an improvement in cellulite appearance. However, injection-site bruising is a frequently occurring adverse event with CCH-aaes treatment. Objectives: To characterize tissue histology following CCH-aaes injection in Yorkshire pigs. Methods: In an animal study, female swine with 10 defined dosing sites on the ventral-lateral aspect received 1 or 2 CCH-aaes (0.07 mg/0.3 mL) or placebo subcutaneous injections at a single site at designated time points before tissue sampling. Results: Injection with CCH-aaes was associated with lysis of mature, collagen-rich septa in the subcutaneous layer at and adjacent to the injection site as early as Day 1. On Day 4, an increase in inflammatory cells and a decrease in hemorrhage (vs Day 2) were observed, with inflammation and hemorrhage decreased by Day 8. By Day 21, deposition of new collagen and reorganization of fat lobules were observed. Observations with repeat CCH-aaes treatment were comparable with 1 course of CCH-aaes treatment. Conclusions: In this animal study, targeted enzymatic subcision of collagenous bands and remodeling of subcutaneous tissue were observed following CCH-aaes injection.

Cyanylated Cysteine Reports Site-Specific Changes at Protein-Protein-Binding Interfaces Without Perturbation.

To investigate the cyanylated cysteine vibrational probe group's ability to report on binding-induced changes along a protein-protein interface, the probe group was incorporated at several sites in a peptide of the calmodulin (CaM)-binding domain of skeletal muscle myosin light chain kinase. Isothermal titration calorimetry was used to determine the binding thermodynamics between calmodulin and each peptide. For all probe positions, the binding affinity was nearly identical to that of the unlabeled peptide. The CN stretching infrared band was collected for each peptide free in solution and bound to calmodulin. Binding-induced shifts in the IR spectral frequencies were correlated with estimated solvent accessibility based on molecular dynamics simulations. This work generally suggests (1) that site-specific incorporation of this vibrational probe group does not cause major perturbations to its local structural environment and (2) that this small probe group might be used quite broadly to map dynamic protein-binding interfaces. However, site-specific perturbations due to artificial labeling groups can be somewhat unpredictable and should be evaluated on a site-by-site basis through complementary measurements. A fully quantitative, simulation-based interpretation of the rich probe IR spectra is still needed but appears to be possible given recent advances in simulation techniques.

Conformational Ensembles of Calmodulin Revealed by Nonperturbing Site-Specific Vibrational Probe Groups.

Seven native residues on the regulatory protein calmodulin, including three key methionine residues, were replaced (one by one) by the vibrational probe amino acid cyanylated cysteine, which has a unique CN stretching vibration that reports on its local environment. Almost no perturbation was caused by this probe at any of the seven sites, as reported by CD spectra of calcium-bound and apo calmodulin and binding thermodynamics for the formation of a complex between calmodulin and a canonical target peptide from skeletal muscle myosin light chain kinase measured by isothermal titration. The surprising lack of perturbation suggests that this probe group could be applied directly in many protein-protein binding interfaces. The infrared absorption bands for the probe groups reported many dramatic changes in the probes' local environments as CaM went from apo- to calcium-saturated to target peptide-bound conditions, including large frequency shifts and a variety of line shapes from narrow (interpreted as a rigid and invariant local environment) to symmetric to broad and asymmetric (likely from multiple coexisting and dynamically exchanging structures). The fast intrinsic time scale of infrared spectroscopy means that the line shapes report directly on site-specific details of calmodulin's variable structural distribution. Though quantitative interpretation of the probe line shapes depends on a direct connection between simulated ensembles and experimental data that does not yet exist, formation of such a connection to data such as that reported here would provide a new way to evaluate conformational ensembles from data that directly contains the structural distribution. The calmodulin probe sites developed here will also be useful in evaluating the binding mode of calmodulin with many uncharacterized regulatory targets.

Pteridine cleavage facilitates DNA photocleavage by Ru(II) polypyridyl compounds.

The synthesis, characterization, binding to calf thymus DNA, and plasmid DNA photocleavage studies of two ruthenium(II) pteridinylphenanthroline complexes are reported where the new pteridinylphenantholine ligands in these complexes are additions to a larger family designed to resemble DNA bases. [Ru(bpy)(2)(L-keto)](PF(6))(2)1 is synthesized from ligand substitution of Ru(bpy)(2)Cl(2) by 4-keto-pteridino[6,7-f]phenanthroline (L-keto). Increasing the reaction temperature during synthesis of 1 causes a ring scission of the L-keto ligand within the pyrimidine ring yielding a second Ru complex, [Ru(bpy)(2)(L-aap)](PF(6))(2)2 where L-aap is 2-amino-3-amidopyrazino[5,6-f]phenanthroline. The ring cleavage reaction is accompanied by the loss of one carbon in the pyrimidine ring. Complexes 1 and 2 are characterized by (1)H NMR, UV/visible absorption and FT-IR spectroscopies and by cyclic voltammetry, and these results are presented in comparison to the previously reported related complexes [Ru(bpy)(2)(L-allox)](PF(6))(2), [Ru(bpy)(2)(L-amino)](PF(6))(2), and [Ru(bpy)(2)(dppz)](PF(6))(2). In addition, 2 has been structurally characterized by X-ray diffraction. Both 1 and 2 are good intercalators of calf thymus DNA as determined by viscometry and binding constants obtained from absorption titrations. Only the ring-cleaved complex 2 exhibits a high degree of pBR322 plasmid photocleavage in contrast to the other pteridinyl-phenanthroline complexes, which exhibit no plasmid DNA photocleavage. Complex 1, however, decomposes in buffer forming the photocleaver 2, demonstrating that sample age and reactivity can affect observed photocleavage. Complex 2 appears to photocleave DNA through a singlet oxygen mechanism.

DNA demethylation by TDG.

DNA methylation has long been considered a very stable DNA modification in mammals that could only be removed by replication in the absence of remethylation - that is, by mere dilution of this epigenetic mark (so-called passive DNA demethylation). However, in recent years, a significant number of studies have revealed the existence of active processes of DNA demethylation in mammals, with important roles in development and transcriptional regulation, allowing the molecular mechanisms of active DNA demethylation to be unraveled. In this article, we review the recent literature highlighting the prominent role played in active DNA demethylation by base excision repair and especially by TDG.

DNA binding by Ru(II)-bis(bipyridine)-pteridinyl complexes.

The interactions of five bis(bipyridyl) Ru(II) complexes of pteridinyl-phenanthroline ligands with calf thymus DNA have been studied. The pteridinyl extensions were selected to provide hydrogen-bonding patterns complementary to the purine and pyrimidine bases of DNA and RNA. The study includes three new complexes [Ru(bpy)(2)(L-pterin)](2+), [Ru(bpy)(2)(L-amino)](2+), and [Ru(bpy)(2)(L-diamino)](2+) (bpy is 2,2'-bipyridine and L-pterin, L-amino, and L-diamino are phenanthroline fused to pterin, 4-aminopteridine, and 2,4-diaminopteridine), two previously reported complexes [Ru(bpy)(2)(L-allox)](2+) and [Ru(bpy)(2)(L-Me(2)allox)](2+) (L-allox and L-Me(2)allox are phenanthroline fused to alloxazine and 1,3-dimethyalloxazine), the well-known DNA intercalator [Ru(bpy)(2)(dppz)](2+) (dppz is dipyridophenazine), and the negative control [Ru(bpy)(3)](2+). Reported are the syntheses of the three new Ru-pteridinyl complexes and the results of calf thymus DNA binding experiments as probed by absorption and fluorescence spectroscopy, viscometry, and thermal denaturation titrations. All Ru-pteridine complexes bind to DNA via an intercalative mode of comparable strength. Two of these four complexes--[Ru(bpy)(2)(L-pterin)](2+) and [Ru(bpy)(2)(L-allox)](2+)--exhibit biphasic DNA melting curves interpreted as reflecting exceptionally stable surface binding. Three new complexes--[Ru(bpy)(2)(L-diamino)](2+), [Ru(bpy)(2)(L-amino)](2) and [Ru(bpy)(2)(L-pterin)](2+)--behave as DNA molecular "light switches."