Phenanthridines structure

Azonia substitution at a naphthalene bridgehead position gives the quinolizinium ion (16). Oxonia substitution, elsewhere, forms the 1- and 2-benzopyrylium ions (17) and (18). The two most well-known monoaza systems with three aromatie fused rings are aeridine (19), derived structurally from anthraeene, and phenanthridine (20), an azaphenanthrene. The better-known diaza systems inelude phenazine (21) and 1,10-phenanthroline (22), while systems with three linearly fused pyridine rings are ealled anthyridines, e.g. the 1,9,10-isomer (23). 

X-ray crystal structure, 6, 516 Benzophenanthridines synthesis from anils, 2, 416 Benzophenanthridines, tetrahydro-synthesis, 2, 469 Benzo[c]phenanthridines synthesis, 2, 414 from aryl isocyanides, 2, 411 from benzynes, 2, 432 Benzo[i]phenanthridines synthesis, 2, 414 Benzophenanthridinones... 

Protoporphyrin-IX, N-methyl-, 4, 396 Protoporphyrins, 4, 382 photooxygenation, 4, 402 Prototropic tautomerism polyheteroatom six-membered rings, 3, 1055 Prozapine properties, 7, 545 Pschorr reaction carbolines from, 4, 523 dibenzazepines from, 7, 533 dibenzothiophenes from, 4, 107 phenanthridines from, 2, 433 Pseudilin, pentabromo-synthesis, 1, 449 Pseudoazulene synthesis, 4, 526 Pseudobases in synthesis reviews, 1, 62 Pseudocyanines, 2, 331 Pseudothiohydantoin synthesis, 6, 296 Pseudouracil structure, 3, 68 Pseudoyangonin IR spectra, 3, 596 Pseudoyohimbine synthesis, 2, 271 Psicofuranine biological activity, 5, 603 as pharmaceutical, 1, 153, 160... 

Demethylvasconine (85) (9-methoxy-5-methyl-phenanthridin-8-olate) presented in Scheme 31 was found in Crinum kirkii (95P1291) (Amaryllidaceae). Although published as cation, no information about the anion of this alkaloid is given. Its relationship to other alkaloids of this class, however, makes a betainic structure more than likely and this is confirmed by a comparison of the NMR data of 85 with the cationic and betainic alkaloids presented in Table III. This betaine is isoconjugate with the 2-methylphenanthrene anion and thus defined the alkaloid as a member of class 1 (odd alternant hydrocarbon anions). Whereas substitution of the isoconjugate phenanthridinium moiety at the 1-position with an anionic fragment results in zwitterions (cf. Section III.D), the phenanthridinium-2-olate is a mesomeric betaine. 

Benzo[c]phenanthridine alkaloids are widespread in Papaveraceae, Fumariaceae, and Rutaceae. Fagaridine (118), the structure of which had to be revised, is a derivative of the unknown 5-methyl-benzo[c]phenan-thridine-8-olate (119) which is isoconjugate with the 2-methyl-chrysene anion (Scheme 43). Thus, Fagaridine is a member of class 1 of conjugated heterocyclic mesomeric betaines, which are isoconjugate with odd alternant hydrocarbon anions. 

In this chapter, an attempt has been made to present a total number of 20 QSAR models (12 QSAR models for topo I inhibitors and eight QSAR models for topo II inhibitors) on 11 different heterocyclic compound series (an-thrapyrazoles, benzimidazoles, benzonaphthofurandiones, camptothecins, desoxypodophyllotoxins, isoaurostatins, naphthyridinones, phenanthridines, quinolines, quinolones, and terpenes) as well as on some miscellaneous heterocyclic compounds for their inhibition against topo I and II. They have been found to be well-correlated with a number of physicochemical and structural parameters. The conclusion, from the analysis of these 20 QSAR, has been drawn that the inhibition of topo I is largely dependent on the hydrophobicity of the compounds/substituents. On the other hand, steric parameters (molar refractivity, molar volume, and Verloop s sterimol parameters) are important for topo II inhibition. 

Over the years, many spiropyran structures have been prepared. The pyran component consists of benzopyran or naphthopyran and the heterocyclic part consists of indoline, benzothiazoline, benzoxazoline, benzoselen-azoline, phenanthridine, acridine, quinoline, benzopyran, naphthopyran, xanthene, benzodithiole, benzoxathiole, and saturated heterocyclic rings such as pyrolidine and thiazolidine. 

At first, acid-catalyzed cyclization of Hofmann degradation products was undertaken however, the cyclization proceeded via the 5-exo-trigonal mode instead of the 6-endo-trigonal mode, resulting in no benzo[c]phenanthridine skeleton. Dyke and Brown (114-117) reinvestigated Perkin s results (118,119) and established the structure of the cyclized products 196 and 197 derived from the methine base 194 (Scheme 36). Onda et al. (120,121) obtained the five-membered spiro compounds 198 and 199 by treatment of 195 with dilute hydrochloric acid. 

Figure 1. Structures and numbering of benzo[h]quinoline (BhQ), benzoff)quinoline (BfQ), Benzofc]phenanthridine (BcPhen) and their carbon analogues phenanthrene (Phe) and Chrysene (Chry). Adapted from Reference 26.

Dihydropyridines have also been starting points for stereospecific syntheses of hydro-phenanthridines and isoquinolines. Interest exists in these compounds because of the occurrence of this structural feature in alkaloids. For example, isoquinuclidine (263), derived from JV-alkoxycarbonyl-l,2-dihydropyridine, undergoes a Cope rearrangement to give the isoquinoline derivative (264) (80JA6157). Further chemical transformations of (264) provided a formal total synthesis of reserpine (Scheme 50). 

Although most ring systems are numbered according to a fairly straightforward set of rules (see CHEC 1.02), there are several exceptions. Thus numbering in purine molecule follows historical tradition. Acridine now has its meso positions numbered 9 and 10 (see structure 15). (At least two other numbering systems have been widely used in the past.) Phenazine, however, is numbered systematically, as in structure (17). Phenanthridine (16) is now numbered in the systematic fashion as indicated. 

Similar types of nucleophilic substitutions have also been carried out when PIFA is activated by two equivalents of Lewis acids such as trimethylsilyl triflu-oromethanesulfonate (TMSOTf) and BF3 Et20 or heteropolyacid in standard solvents such as CH2C12 and MeCN. These reactions were applied to intramolecular reactions by the same authors leading to biaryls (49) [54-57], quinone imine derivatives (50) [58], and dihydrobenzothiophens (51) [59], which are important structures of bioactive natural products [Eqs. (7)-(9)]. Dominguez and co-workers have expanded the above biaryl coupling reaction to the syntheses of benzo[c]phenanthridine system (52) [60] and heterobiaryl compounds (53) [61] [Eqs. (10,11)]. 

Overlap Geometry A schematic representation of the proposed overlap geometry for proflavine intercalated into a deoxy pyrimidine(3 -5 )purine site is presented below with the (o) symbols representing the location of the phenanthridine ring protons. The mutual overlap of the two base pairs at the intercalation site involves features observed in the crystal structures of a platinum metallointercalator miniature dC-dG duplex complex (55) and the more recent proflavine miniature dC-dG duplex complex (48), as well as features derived in a linked-atom conformational calculation of the intercalation site in the proflavine DNA complex (51). [4]... 

Catalytic hydrogenation of the ketoaldoxime (52) gives a hydro-phenanthridine to which structure 53 has been assigned.95... 

Moore and Snyder121 have employed the Schmidt reaction to determine the structure of the hydrocarbon (71), which is one of the products of the self-condensation of acetophenone in polyphosphoric acid. Treatment with hydrogen bromide and dimethyl sulfoxide (DMSO) gives the fluorenol (72), which yields a mixture of 1-methyl-2,4,6-triphenylphenanthridine (73) and 10-methyl-6,7,9-triphenyl-phenanthridine (74) when treated with hydrazoic acid. 

The structure 213 (R = R1 = H, R2 = COCH2COMe) has been proposed for the adduct formed from phenanthridine and diketene,304 but the corresponding product with dimethylketene has been shown to be 214 rather than the ketoamide 213 (R = R1 = R2 = Me).305... 

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