Innate and Guided C–H Functionalization Logic Brückl, Tobias; Baxter, Ryan D; Ishihara, Yoshihiro ...
Accounts of chemical research,
06/2012, Letnik:
45, Številka:
6
Journal Article
Recenzirano
Odprti dostop
The combustion of organic matter is perhaps the oldest and most common chemical transformation utilized by mankind. The generation of a C–O bond at the expense of a C–H bond during this process may ...be considered the most basic form of C–H functionalization. This illustrates the extreme generality of the term “C–H functionalization”, because it can describe the conversion of literally any C–H bond into a C–X bond (X being anything except H). Therefore, it may be of use to distinguish between what, in our view, are two distinct categories of C–H functionalization logic: “guided” and “innate”. Guided C–H functionalizations, as the name implies, are guided by external reagents or directing groups (covalently or fleetingly bound) to install new functional groups at the expense of specifically targeted C–H bonds. Conversely, innate C–H functionalizations may be broadly defined as reactions that exchange C–H bonds for new functional groups based solely on natural reactivity patterns in the absence of other directing forces. Two substrates that illustrate this distinction are dihydrojunenol and isonicotinic acid. The C–H functionalization processes of hydroxylation or arylation, respectively, can take place at multiple locations on each molecule. Innate functionalizations lead to substitution patterns that are dictated by the inherent bias (steric or electronic) of the substrate undergoing C–H cleavage, whereas guided functionalizations lead to substitution patterns that are controlled by external directing forces such as metal complexation or steric bias of the reagent. Although the distinction between guided and innate C–H functionalizations may not always be clear in cases that do not fit neatly into a single category, it is a useful convention to consider when analyzing reactivity patterns and strategies for synthesis. We must emphasize that although a completely rigorous distinction between guided and innate C–H functionalization may not be practical, we have nonetheless found it to be a useful tool at the planning stage of synthesis. In this Account, we trace our own studies in the area of C–H functionalization in synthesis through the lens of “guided” and “innate” descriptors. We show how harnessing innate reactivity can be beneficial for achieving unique bond constructions between heterocycles and carbonyl compounds, enabling rapid and scalable total syntheses. Guided and innate functionalizations were used synergistically to create an entire family of terpenes in a controlled fashion. We continue with a discussion of the synthesis of complex alkaloids with high nitrogen content, which required the invention of a uniquely chemoselective innate C–H functionalization protocol. These findings led us to develop a series of innate C–H functionalization reactions for forging C–C bonds of interest to the largest body of practicing organic chemists: medicinal chemists. Strategic use of C–H functionalization logic can have a dramatically positive effect on the efficiency of synthesis, whether guided or innate.
5-Hydroxymethylcytosine (hmC) was recently detected as the sixth base in mammalian tissue at so far controversial levels. The function of the modified base is currently unknown, but it is certain ...that the base is generated from 5-methylcytosine (mC). This fuels the hypothesis that it represents an intermediate of an active demethylation process, which could involve further oxidation of the hydroxymethyl group to a formyl or carboxyl group followed by either deformylation or decarboxylation. Here, we use an ultra-sensitive and accurate isotope based LC-MS method to precisely determine the levels of hmC in various mouse tissues and we searched for 5-formylcytosine (fC), 5-carboxylcytosine (caC), and 5-hydroxymethyluracil (hmU) as putative active demethylation intermediates. Our data suggest that an active oxidative mC demethylation pathway is unlikely to occur. Additionally, we show using HPLC-MS analysis and immunohistochemistry that hmC is present in all tissues and cell types with highest concentrations in neuronal cells of the CNS.
Mind over matter: LC‐MS has allowed the amount of the post‐replicatively formed DNA base 5‐hydroxymethylcytosine (see picture; left) to be quantified in brain tissue. The nucleoside is most abundant ...in areas that are associated with higher cognitive functions, and its content in mouse hippocampi seems to increase with age. The new method enables hydroxymethylcytosine to be quantified with unprecedented accuracy.
Modifications make a difference: An isotope‐based mass spectrometry method allows the facile and quantitative analysis of modified tRNA nucleosides in various types of cells. This method could be ...capable of distinguishing between individual cell lines as well as between healthy tissue and cancer cells.
Systems-Based Analysis of Modified tRNA Bases Globisch, Daniel; Pearson, David; Hienzsch, Antje ...
Angewandte Chemie (International ed.),
October 4, 2011, Letnik:
50, Številka:
41
Journal Article
Recenzirano
Quantification of modified tRNA nucleosides in 16 species reveals evolutionary development of modification levels corresponding to phylogenetic branching. Comparison of modification profiles ...additionally allows characterization of species and differentiation between a number of pathogenic and harmless bacterial strains.
Catalyzed cascade reactions that generate molecular complexity rapidly and in an enantioselective manner are attractive methods for asymmetric synthesis. In the present article, chiral rhodium ...catalysts are shown to effect such a transformation by using a range of 2-diazo-3,6-diketoesters with bicyclo2.2.1alkenes and styrenes as reaction partners. The reactions are likely to proceed by formation of a catalyst-complexed carbonyl ylide from the diazo compound, followed by intermolecular cycloaddition with the alkene dipolarophile. It was possible to obtain high levels of asymmetric induction up to 89% enantiomeric excess (ee) and 92% ee for the two chiral catalysts investigated. Enantioselectivity is not highly sensitive to substituent variation at the ketone that forms the ylide; however, branching does improve ee. Observations of dipolarophile-dependent enantiofacial selectivity in the cycloadditions indicate that the dipolarophile can be intimately involved in the enantiodiscrimination process.
Levulinic acid-derived 6-diazoheptane-2,5-dione (9) serves as a common precursor in a formal synthesis of frontalin 19, and in syntheses of cis-nemorensic acid 1, 4-hydroxy-cis-nemorensic acid 2, ...3-hydroxy-cis-nemorensic acid 3, and nemorensic acid 4. The key step in these syntheses is the Rh(2)(OAc)(4)-catalyzed tandem carbonyl ylide formation-intermolecular 1,3-dipolar cycloadditions of diazodione 9 with formaldehyde, alkynes or allene, which occur with high regioselectivity. Subsequent oxidative cleavage of the ring originally derived from the cyclic carbonyl ylide intermediate provides a straightforward access to polysubstituted tetrahydrofurans, and in particular an efficient entry to the nemorensic acids. Enantioselective cycloadditions with diazodione 9, using chiral rhodium catalysts, gave cycloadducts in up to 51% ee.
Useful diversity: Quantification of modified tRNA nucleobases in different murine and porcine tissues reveals a tissue‐specific overall modification content. The modification content correlates with ...rates of protein synthesis in vitro, suggesting a direct link between tRNA modification levels and tissue‐specific translational efficiency.
Modified nucleosides in tRNAs play an important role in the translational process. They fine tune the codon-anticodon interactions and they influence the folding and stabilisation of the tRNA ...structure. Herein, we present a novel synthetic route to the highly modified nucleosides PreQ(0) and archaeosine. The synthesis involves coupling of a protected 7-cyano-7-deazaguanosine nucleobase with a TBDMS and isopropylidene protected chloro-ribose unit yielding the PreQ(0) nucleoside after deprotection. This PreQ(0) nucleoside is then used as the starting material for the synthesis of archaeosine providing the first total synthetic access to this hypermodified RNA nucleoside.