Full details of the development of a direct coupling of catharanthine with vindoline to provide vinblastine are described along with key mechanistic and labeling studies. Following an Fe(III)-promoted coupling reaction initiated by generation of a presumed catharanthine radical cation that undergoes a subsequent oxidative fragmentation and diastereoselective coupling with vindoline, addition of the resulting reaction mixture to an Fe(III)-NaBH 4 /air solution leads to oxidation of the C15′-C20′ double bond and reduction of the intermediate iminium ion directly providing vinblastine (40-43%) and leurosidine (20-23%), its naturally occurring C20′ alcohol isomer. The yield of coupled products, which exclusively possess the natural C16′ stereochemistry, approaches or exceeds 80% and the combined yield of the isomeric C20′ alcohols is >60%. Preliminary studies of Fe(III)-NaBH 4 /air oxidation reaction illustrate a generalizable trisubstituted olefin scope, identified alternatives to O 2 trap at the oxidized carbon, provides a unique entry into C20′ functionalized vinblastines, and affords initial insights into the observed C20′ diastereoselectivity. The first disclosure of the use of exo-catharanthine proceeding through Δ 19′,20′ -anhydrovinblastine in such coupling reactions is also detailed with identical stereochemical consequences. Incorporating either a catharanthine N-methyl group or a vindoline N-formyl group precludes Fe(III)-promoted coupling, whereas the removal of the potentially key C16 methoxy group of vindoline does not adversely impact the coupling efficiency. Extension of these studies provided a total synthesis of vincristine (2) via N-desmethylvinblastine (36, also a natural product), 16-desmethoxyvinblastine (44) and 4-desacetoxy-16-desmethoxyvinblastine (47) both of which we can now suggest are likely natural products produced by C. roseus, desacetylvinblastine (62) and 4-desacetoxyvinblastine (59), as well as a series of key analogues bearing systematic modifications in the vindoline subunit. Their biological evaluation provided additional insights into the key functionality within the vindoline subunit contributing to the activity and sets the foundation on which further, more deep-seated changes in the structures of 1 and 2 will be explored in future studies.
Proline is unique among the natural amino acids in the similar propensity of its peptide bond to be in the cis or trans conformation. This attribute affects many processes, including the rate at which proteins fold, their structures, and their activities. Other aliphatic amino acids can serve as mimics for proline residues with trans peptide bonds. In contrast, chemical synthesis is needed to create surrogates for cis prolyl peptide bonds. Here, 1,5-disubstituted-[1,2,3]-triazoles were assessed as cispeptide bond surrogates. Huisgen's 1,3-dipolar cycloaddition reaction of amino alkynes and azido acids and a Ru(II) catalyst were used to synthesize a variety of Xaa-1,5-triazole-Ala modules in moderate-to-high yields. Two of these modules, along with their 1,4-triazole regioisomers, were installed in a turn region of bovine pancreatic ribonuclease by using expressed protein ligation. The resulting semisynthetic enzymes displayed full enzymatic activity, indicating the maintenance of native structure. The 1,5-triazole surrogates instilled conformational stability that was comparable to that of Xaa-cis-Pro segments, whereas the 1,4-triazoles conferred markedly less stability. The stability conferred by both surrogates was independent of the Xaa residue, eliminating an uncertainty in protein design. We conclude that Xaa-1,5-triazole-Ala modules can serve as viable mimics of Xaa-cis-Pro segments. The possibility of synthesizing this surrogate by the ligation of fragments in situ and the emergence of biocompatible catalysts for that process portends its widespread use.Proline is unique among the natural amino acids in the similar propensity of its peptide bond to be in the cis or trans conformation. 1 This attribute affects many processes, including the rate at which proteins fold, 2 their structures, 3 and their activities. 4 Other aliphatic amino acids can serve as mimics for proline residues with trans peptide bonds. In contrast, chemical synthesis is needed to create surrogates for cis prolyl peptide bonds. 1,5-7
NAD is an indispensable redox cofactor in all organisms. Most of the genes required for NAD biosynthesis in various species are known. Ribosylnicotinamide kinase (RNK) was among the few unknown (missing) genes involved with NAD salvage and recycling pathways. Using a comparative genome analysis involving reconstruction of NAD metabolism from genomic data, we predicted and experimentally verified that bacterial RNK is encoded within the 3 region of the nadR gene. Based on these results and previous data, the full-size multifunctional NadR protein (as in Escherichia coli) is composed of (i) an N-terminal DNA-binding domain involved in the transcriptional regulation of NAD biosynthesis, (ii) a central nicotinamide mononucleotide adenylyltransferase (NMNAT) domain, and (iii) a C-terminal RNK domain. The RNK and NMNAT enzymatic activities of recombinant NadR proteins from Salmonella enterica serovar Typhimurium and Haemophilus influenzae were quantitatively characterized. We propose a model for the complete salvage pathway from exogenous N-ribosylnicotinamide to NAD which involves the concerted action of the PnuC transporter and NRK, followed by the NMNAT activity of the NadR protein. Both the pnuC and nadR genes were proven to be essential for the growth and survival of H. influenzae, thus implicating them as potential narrow-spectrum drug targets.
The traceless Staudinger ligation is an effective means to synthesize an amide bond between two groups of otherwise orthogonal reactivity: a phosphinothioester and an azide. An important application of the Staudinger ligation is in the ligation of peptides at a variety of residues. Here, we demonstrate that the traceless Staudinger ligation can be achieved in water with a water-soluble reagent. Those reagents that provide a high yield of amide product discourage protonation of the nitrogen in the key iminophosphorane intermediate. The most efficacious reagent, bis(pdimethylaminoethylphenyl)phosphinomethanethiol, mediates the rapid ligation of equimolar substrates in water. This reagent is also able to perform a transthioesterification reaction with the thioester intermediate formed during intein-mediated protein splicing. Hence, the traceless Staudinger ligation can be integrated with expressed protein ligation, extending the reach of modern protein chemistry.
Chang et al. link the RECQ-like helicase BLM and its yeast orthologue Sgs1 to preventing DNA damage caused by the accumulation of DNA:RNA hybrid structures called R-loops. This adds to a growing family of helicases implicated in R-loop resolution.
The bifunctional CO dehydrogenase͞acetyl-CoA synthase (CODH͞ACS) plays a central role in the Wood-Ljungdahl pathway of autotrophic CO 2 fixation. A recent structure of the Moorella thermoacetica enzyme revealed that the ACS active site contains a [4Fe-4S] cluster bridged to a binuclear Cu-Ni site. Here, biochemical and x-ray absorption spectroscopic (XAS) evidence is presented that the copper ion at the M. thermoacetica ACS active site is essential. Depletion of copper correlates with reduction in ACS activity and in intensity of the ''NiFeC'' EPR signal without affecting either the activity or the EPR spectroscopic properties associated with CODH. In contrast, Zn content is negatively correlated with ACS activity without any apparent relationship to CODH activity. Cu is also found in the methanogenic CODH͞ACS from Methanosarcina thermophila. XAS studies are consistent with a distorted Cu ( T he bifunctional enzyme CO dehydrogenase͞acetyl-CoA synthase (CODH͞ACS; EC 1.2.99.2) plays a central role in the Wood-Ljungdahl pathway of autotrophic CO 2 fixation (1, 2). CODH catalyzes the two-electron reduction of CO 2 to CO (Eq. 1). The CO is directed through a 70-Å channel to the ACS active site, where it is condensed with a methyl group (donated by the methylated corrinoid iron-sulfur protein, CH 3 -CFeSP), and CoA to generate acetyl-CoA (Eq. 2) (3).A recent crystal structure reveals that CODH͞ACS is a 300-kDa ␣ 2  2 protein with two core CODH  subunits tethered on each side to two ACS ␣ subunits (4). The A cluster in each ␣ subunit contains 1 Ni, 1 Cu, and 4 Fe ions, whereas the  subunit contains 1 Ni and 10 Fe ions arranged into three clusters, known as B, C, and D. Various studies indicate that Ni is a required component of CODH in acetogenic bacteria (5, 6) and Rhodospirillum rubrum (7). Ni also is essential for ACS activity, and a subpopulation of the Ni ions in the ACS active site, called the ''labile Ni,'' is required for ACS activity and for generation of an EPR signal called the ''NiFeC signal'' (8). When CODH͞ACS is reacted with CO, this EPR signal forms and, upon reaction with the CH 3 -CFeSP, it decays, both reactions occurring at catalytically relevant rates, indicating intermediacy of the NiFeC species in the ACS catalytic cycle (9). Until recently (4), Cu was not known to be a component of CODH͞ACS. The discovery of Cu at the ACS active site was surprising, given that this enzyme has been studied for many years and this metal had never been previously reported in a CODH͞ACS. ¶ Cu was found in the Methanosarcina barkeri CODH (10); however, ACS was not present in this preparation of methanogenic enzyme, and Cu has not been reported in the three CODH crystal structures (4, 11, 12) or in other CODHs that have been characterized. A relationship between Cu content and ACS activity was indicated in an earlier report (4); here we provide convincing biochemical and spectroscopic evidence for the importance of Cu in the ACS mechanism. Materials and MethodsMaterials. CO (99.99%) and N 2 (99.998%) were purchase...
The total synthesis of a systematic series of vinblastine analogues that contain deep-seated structural modifications to the core ring system of the lower vindoline subunit is described. Complementary to the vindoline 6,5 DE ring system, compounds with 5,5, 6,6 and the reversed 5,6 membered DE ring systems were prepared. Both the natural cis and unnatural trans 6,6-membered ring systems proved accessible, with the latter representing a surprisingly effective class for analogue design. Following Fe(III)-promoted coupling with catharanthine and in situ oxidation to provide the corresponding vinblastine analogues, their evaluation provided unanticipated insights into how the structure of the vindoline subunit contributes to activity. Two potent analogues (81 and 44) possessing two different unprecedented modifications to the vindoline subunit core architecture were discovered that matched the potency of the comparison natural products and both lack the 6,7-double bond whose removal in vinblastine leads to a 100-fold drop in activity.
EFTUD2 is mutated in patients with mandibulofacial dysostosis with microcephaly (MFDM). We generated a mutant mouse line with conditional mutation in Eftud2 and used Wnt1-Cre2 to delete it in neural crest cells. Homozygous deletion of Eftud2 causes brain and craniofacial malformations, affecting the same precursors as in MFDM patients. RNAseq analysis of embryonic heads revealed a significant increase in exon skipping and increased levels of an alternatively spliced Mdm2 transcript lacking exon 3. Exon skipping in Mdm2 was also increased in O9–1 mouse neural crest cells after siRNA knock-down of Eftud2 and in MFDM patient cells. Moreover, we found increased nuclear P53, higher expression of P53-target genes, and increased cell death. Finally, overactivation of the P53 pathway in Eftud2 knockdown cells was attenuated by overexpression of non-spliced Mdm2, and craniofacial development was improved when Eftud2-mutant embryos were treated with Pifithrin-α, an inhibitor of P53. Thus, our work indicates that the P53-pathway can be targeted to prevent craniofacial abnormalities and shows a previously unknown role for alternative splicing of Mdm2 in the etiology of MFDM.
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