Synthesis of diazeniumdiolates from the reactions of nitric oxide with enolates

[reaction: see text] Reactions of nitric oxide with enolates derived from aliphatic methyl ketones containing alpha-methylene or alpha-methine groups and with enolates derived from alpha,alpha'-dimethylene or alpha,alpha'-dimethine ketones yield mono- or bis(diazeniumdiolate) products. Diazeniumdiolation occurs in the following order: alpha-methine > alpha-methylene > alpha-methyl. The amount of the base used alters the extent of diazeniumdiolation and the course of the reaction. Mono- and bis(diazeniumdiolate)-substituted methyl ketones are cleaved in the presence of excess base before and after the subsequent diazeniumdiolation of the alpha-methyl group. Similar to the trihalogenated methyl groups in the base-assisted halogenation reactions of methyl ketones, the bis(diazeniumdiolate)-substituted alpha-methylene and alpha-methyl groups act as leaving groups in the presence of excess base. The reaction of nitric oxide with a (approximately 20:80, cis/trans) mixture of 2,6-cyclohexananone yields the cis and trans isomers of 2,6-dimethylcyclohexanone-2,6-bis(diazeniumdiolate) in 12.9% and 57.6% yield. Single-crystal X-ray diffraction data determined for potassium cis-2,6-dimethylcyclohexanone-2,6-bis(diazeniumdiolate), cis-14b, reveal that the N(2)O(2-) substituent is planar with considerable delocalization of a double bond over the anionic four-atom group. Except for one of the diazeniumdiolate products, namely, potassium propanoate 2,2-bis(diazeniumdiolate), 8b, all are stable in neutral and basic aqueous media. Compound 8b slowly decomposes in neutral aqueous solution releasing nitrous oxide and nitric oxide gases but is stable in basic aqueous media. Differential scanning calorimetry data measured for the diazeniumdiolate products indicate that they decompose exothermally with most of them undergoing explosive decomposition at moderately high temperatures (181-274 degrees C).     

Gallium(III) protoporphyrin IX]2: a soluble diamagnetic model for malaria pigment

Gallium(III) protoporphyrin IX forms a dimeric propionate-bridged dimer, 2, that is a soluble diamagnetic analogue of hematin anhydride. The single-crystal structure of 2 corresponds to a nondisordered inversion-symmetric dimer similar to malaria pigment but, unlike it, has a six-coordinate metal and an intraporphyrin rather than an interporphyrin hydrogen bond. NMR NOE correlations demonstrate the presence of the propionate linkage in solutions with pyridine. Taken together, this is the first single-crystal X-ray diffraction study of a propionate-linked dimer as found in malaria pigment and the first evidence for its presence in solution.     

Primary amine diazeniumdiolate ions of structure {RNN(O)NOR} as ambident nucleophiles

An O²-substituted primary amine diazeniumdiolate RHN-N(O)NOR′ is ionized to an anion that attacks an electrophile R″X via either of two nitrogens to form both RR″N-N(O)NOR′ and R-NN(O)-N(R″)OR′. The bidentate character of such anions should be kept in mind when planning or evaluating drug discovery efforts involving diazeniumdiolates of structure RHN-N(O)NOR′.     

Stabilizing and Activating Nitrogen Catenates

The remarkably stable catenated hexa‐nitrogen chain in bis(benzotriazene‐4‐one) is structurally, theoretically, and spectroscopically characterized to illustrate the durability of the central N?N bond in this hexaazo chain. The reactions of this species illustrate the potential of these nitrogen catenates for the preparation of other condensed heterocycles, such as bispyrazolones, by thermal nitrogen exclusion or by trapping the single ring‐opened Dimroth intermediates. In these latter reactions, 2‐naphtholate anion condenses with bis(benzotriazene‐4‐one) to trap and retain a zwitterionic diazonium intermediate as an isolated diazo product, whereas transition metals ring effect ring‐extrusion of dinitrogen from the Dimroth intermediate to generate chelating σ‐aryls. The catenated nitrogen species can be stabilized by incorporating strong formal sp²?sp² N?N σ bonds with orthogonal orientations. Extending these stabilization and activation principles may allow these types of nitrogen catenates to be useful synthons for other polyaza species.     

Dreizentren-oxidative Addition von Phosphor-Yliden an Ru3(CO)12

Three-Centre Oxidative Addition of Phosphorus Ylides to Ru₃(CO)₁₂ Phosphorus ylides undergo oxidative addition to Ru₃(CO)₁₂ to yield a wide range of Ru₃ clusters with triply bridging organic ligands derived from the ylides. Ph₃PCH₂ forms HRu₃(CO)₉(μ₃1-Ph₃P — CH — CO) ( 1 ) containing a phosphonio enolate. Ph₃PCH — CHO yields a product mixture containing the phosphonio enolate-bridged cluster and its PPh₃ derivative 6 , the phosphoniomethylidyne-bridged compound H₂Ru₃(CO)₉(μ₃1-C — PPh₃) ( 5 ), and the ketenylidene-bridged compound H₂Ru₃(CO)₈(PPh₃)(μ₃1-C — CO) ( 7 ). Thermal treatment converts the phosphonio enolate ligand (in 1 ) into the phosphoniomethylidyne ligand (in 5 ), and the latter into the ketenylidene ligand (in 7 ). With Ph₃PCH — C(O)Me and Ru₃(CO)₁₂ ortho1-metalated Ru₃ derivatives 10, 11 of the phosphonio ketone R₃P — C — C(O)Me are produced, and likewise with Ph₃PCH — COOEt the ortho1-metalated derivative 12 of the phosphonio ester R₃P — C — CO₂Et. Me₃PCH — COOtBu is oxidatively added to form HRu₃(CO)₉(μ₃1-Me₃P — C — COOtBu) ( 13 ) bearing a phosphonio ester ligand. — The crystal structures of 6 and 13 are reported. The sequence of Ru₃ clusters and the bonding modes of the μ₃ ligands can be related to the surface reactions during Fischer-Tropsch catalysis.     

Substituent Control of the Reductive Nitrosylation of Wilkinson's Catalyst by Diazeniumdiolates

Diazeniumdiolates (RN(O)NO⁻, R=Et, Et₂N) react in an R‐dependent manner with Wilkinson's catalyst to give either a chelated square‐planar complex, Rh(η²‐O₂N₂Et)(PPh₃)₂, 1 , for R=Et, or with initial chelation followed by reductive nitrosylation to give Rh(NO)(PPh₃)₃, in the case of R=Et₂N. Methyl iodide oxidatively adds to 1 to give RhIMe(η²‐O₂N₂Et)(PPh₃)₂, 2 , as a pair of isomers a , major, and b , minor. Both 1 and 2a have been structurally characterized by single‐crystal X‐ray diffraction.     

Crystal Structure Analysis of the Repair of Iron Centers Protein YtfE and Its Interaction with NO

Molecular mechanisms underlying the repair of nitrosylated [Fe–S] clusters by the microbial protein YtfE remain poorly understood. The X‐ray crystal structure of YtfE, in combination with EPR, magnetic circular dichroism (MCD), UV, and ¹⁷O‐labeling electron spin echo envelope modulation measurements, show that each iron of the oxo‐bridged Fe^II–Fe^III diiron core is coordinatively unsaturated with each iron bound to two bridging carboxylates and two terminal histidines in addition to an oxo‐bridge. Structural analysis reveals that there are two solvent‐accessible tunnels, both of which converge to the diiron center and are critical for capturing substrates. The reactivity of the reduced‐form Fe^II–Fe^II YtfE toward nitric oxide demonstrates that the prerequisite for N₂O production requires the two iron sites to be nitrosylated simultaneously. Specifically, the nitrosylation of the two iron sites prior to their reductive coupling to produce N₂O is cooperative. This result suggests that, in addition to any repair of iron centers (RIC) activity, YtfE acts as an NO‐trapping scavenger to promote the NO to N₂O transformation under low NO flux, which precedes nitrosative stress.     

Constrained Willmore surfaces

Constrained Willmore surfaces are conformal immersions of Riemann surfaces that are critical points of the Willmore energy under compactly supported infinitesimal conformal variations. Examples include all constant mean curvature surfaces in space forms. In this paper we investigate more generally the critical points of arbitrary geometric functionals on the space of immersions under the constraint that the admissible variations infinitesimally preserve the conformal structure. Besides constrained Willmore surfaces we discuss in some detail examples of constrained minimal and volume critical surfaces, the critical points of the area and enclosed volume functional under the conformal constraint. C. Bohle, G. P. Peters and U. Pinkall are partially supported by DFG SPP 1154.     

Search for the newM1 mode in156Gd by inelastic proton scattering at low incident energy

The α-decay study of mass-separated nuclei in the region around Z=82 provides a strong spectroscopic tool to investigate intruder states. In this note, this method is applied to the¹⁹⁷At isotope.