hapalindole-u and fischerindole

hapalindole-u has been researched along with fischerindole* in 2 studies

Other Studies

2 other study(ies) available for hapalindole-u and fischerindole

Article	Year
Structural basis of the Cope rearrangement and cyclization in hapalindole biogenesis. Nature chemical biology, 2018, Volume: 14, Issue:4 Hapalindole alkaloids are a structurally diverse class of cyanobacterial natural products defined by their varied polycyclic ring systems and diverse biological activities. These complex metabolites are generated from a common biosynthetic intermediate by the Stig cyclases in three mechanistic steps: a rare Cope rearrangement, 6-exo-trig cyclization, and electrophilic aromatic substitution. Here we report the structure of HpiC1, a Stig cyclase that catalyzes the formation of 12-epi-hapalindole U in vitro. The 1.5-Å structure revealed a dimeric assembly with two calcium ions per monomer and with the active sites located at the distal ends of the protein dimer. Mutational analysis and computational methods uncovered key residues for an acid-catalyzed [3,3]-sigmatropic rearrangement, as well as specific determinants that control the position of terminal electrophilic aromatic substitution, leading to a switch from hapalindole to fischerindole alkaloids. Topics: Alkaloids; Calcium; Catalysis; Catalytic Domain; Cloning, Molecular; Cyanobacteria; Cyclization; Dimerization; DNA Mutational Analysis; Indole Alkaloids; Indoles; Ions; Molecular Conformation; Molecular Dynamics Simulation; Molecular Structure; Protein Binding; Quantum Theory; Recombinant Proteins; Stereoisomerism	2018
Total synthesis of marine natural products without using protecting groups. Nature, 2007, Mar-22, Volume: 446, Issue:7134 The field of organic synthesis has made phenomenal advances in the past fifty years, yet chemists still struggle to design synthetic routes that will enable them to obtain sufficient quantities of complex molecules for biological and medical studies. Total synthesis is therefore increasingly focused on preparing natural products in the most efficient manner possible. Here we describe the preparative-scale, enantioselective, total syntheses of members of the hapalindole, fischerindole, welwitindolinone and ambiguine families, each constructed without the need for protecting groups--the use of such groups adds considerably to the cost and complexity of syntheses. As a consequence, molecules that have previously required twenty or more steps to synthesize racemically in milligram amounts can now be obtained as single enantiomers in significant quantities in ten steps or less. Through the extension of the general principles demonstrated here, it should be possible to access other complex molecular architectures without using protecting groups. Topics: Alkaloids; Biological Products; Chemistry, Organic; Cyanobacteria; Indole Alkaloids; Indoles; Nitriles; Seawater	2007

Article

Year

Structural basis of the Cope rearrangement and cyclization in hapalindole biogenesis.

Nature chemical biology, 2018, Volume: 14, Issue:4

Hapalindole alkaloids are a structurally diverse class of cyanobacterial natural products defined by their varied polycyclic ring systems and diverse biological activities. These complex metabolites are generated from a common biosynthetic intermediate by the Stig cyclases in three mechanistic steps: a rare Cope rearrangement, 6-exo-trig cyclization, and electrophilic aromatic substitution. Here we report the structure of HpiC1, a Stig cyclase that catalyzes the formation of 12-epi-hapalindole U in vitro. The 1.5-Å structure revealed a dimeric assembly with two calcium ions per monomer and with the active sites located at the distal ends of the protein dimer. Mutational analysis and computational methods uncovered key residues for an acid-catalyzed [3,3]-sigmatropic rearrangement, as well as specific determinants that control the position of terminal electrophilic aromatic substitution, leading to a switch from hapalindole to fischerindole alkaloids.

Topics: Alkaloids; Calcium; Catalysis; Catalytic Domain; Cloning, Molecular; Cyanobacteria; Cyclization; Dimerization; DNA Mutational Analysis; Indole Alkaloids; Indoles; Ions; Molecular Conformation; Molecular Dynamics Simulation; Molecular Structure; Protein Binding; Quantum Theory; Recombinant Proteins; Stereoisomerism

2018

Total synthesis of marine natural products without using protecting groups.

Nature, 2007, Mar-22, Volume: 446, Issue:7134

The field of organic synthesis has made phenomenal advances in the past fifty years, yet chemists still struggle to design synthetic routes that will enable them to obtain sufficient quantities of complex molecules for biological and medical studies. Total synthesis is therefore increasingly focused on preparing natural products in the most efficient manner possible. Here we describe the preparative-scale, enantioselective, total syntheses of members of the hapalindole, fischerindole, welwitindolinone and ambiguine families, each constructed without the need for protecting groups--the use of such groups adds considerably to the cost and complexity of syntheses. As a consequence, molecules that have previously required twenty or more steps to synthesize racemically in milligram amounts can now be obtained as single enantiomers in significant quantities in ten steps or less. Through the extension of the general principles demonstrated here, it should be possible to access other complex molecular architectures without using protecting groups.

Topics: Alkaloids; Biological Products; Chemistry, Organic; Cyanobacteria; Indole Alkaloids; Indoles; Nitriles; Seawater

2007