Nucleophilic substitution reactions of some polyhalogenated compounds

Martin, Peter Arnold

January 1987

Rate measurements for the reactions of a series of polyfluoro - and polychloro - pyridines with aniline and ammonia in 60/40 dioxan/water at 25ºC has shown that chlorine, when ortho and para to the position of attack, is activating with respect to fluorine, but at the position meta to the point of attack, chlorine and fluorine are virtually equivalent in their effect on reaction rate. The trifluoromethyl and nitrile groups were found to be activating relative to fluorine when ortho and para to the position of substitution and the nitrile group was thus found to be ortho/para directing. The ortho/para orienting effect of ring nitrogen was shown to be dominant in heterocyclic systems. It has been demonstrated for several different nucleophiles that nucleophilic attack in polyfluorinated heterocycles occurs so as to maximise the number of ortho and meta fluorines with fluorine being of little significance. Of the nucleophiles examined aniline and ammonia were found to be similar in their behaviour. Benzylamine however showed some propensity for substitution at positions ortho to ring nitrogen whilst N-methylaniline showed strong steric effects due to the N-methyl group, most notably when the heterocylic ring substituents were chlorine, trifluoromethyl and nitrile. Sodium was shown to have a 'salt effect' in the reactions of methoxide and phenoxide, and, a catalytic effect on the reactions of aniline affecting both the rate and position of substitution. The use of transition state, and molecular orbitals to explain the patterns of substitution is discussed. The trifluoromethylsilyl group was found to undergo nucleophilic attack at silicon and the series of mono, di and tri-fluoromethyl-pentafluorobenzenes were used to examine the concept of negative ion hyperconjugation.

547

Aromatic hydrocarbon systems

On the chemistry and spectroscopy of PAHs in circumstellar and interstellar environments

Hammonds, Mark

January 2013

No description available.

523.01

Polycyclic aromatic hydrocarbons

Nitration and chlorination of deactivated aromatic compounds

Melhuish, M. W.

January 1987

No description available.

547

Aromatic compounds nitration

Kinetics and mechanism of thalliation of aromatic petrochemicals in trifluoroacetic acid

Al-Azzawi, S. F. A.

January 1984

No description available.

541

Aromatic compound thalliation

Food mutagens : factors that modulate their metabolic activation

Ayrton, Andrew David

January 1989

No description available.

664

Heterocyclic aromatic amines

Phytodegradation of petroleum aromatic compounds in soil

Williams, Marilyn M.

January 2000

There is no abstract available for this thesis. / Department of Natural Resources and Environmental Management

Aromatic compounds -- Biodegradation.

Phytoremediation.

Synthesis of some pyrene annelated macrocyclic systems

Mahadevan, Ramanathan

14 April 2014

Graduate / 0485

aromatic compounds

annulenes

Formation and reactions of 1, 2-adducts from ipso-nitration of toluene derivatives

Ray Mahasay, Sumit

14 April 2014

Graduate / 0485

nitration

aromatic compounds

toluene

Structural and functional characterization of PaaK1 & PaaK2: phenylacetate CoA ligase paralogs from Burkholderia cenocepacia J2315. / Structural and functional characterization of PaaK1 and PaaK2

Law, Adrienne

18 October 2011

Aromatic compounds comprise approximately 25% of the Earth`s biomass. Accordingly, turnover of these thermostable compounds is essential to the biogeochemical carbon cycle. Specialized microbial enzymatic pathways are largely responsible for mineralization of aromatic compounds, and are extensively studied for bioremediation purposes. The phenylacetic acid degradation pathway (PAA) is of particular interest as it is utilized for degradation of a multitude of aromatic compounds, including environmental pollutants, and appears to be widely distributed among bacteria. Intriguingly, the PAA pathway has also been implicated as a virulence factor in the cystic fibrosis pathogen, Burkholderia cenocepacia. As such, detailed biochemical characterization of the PAA pathway holds great potential for improving bioremediation strategies for aromatic pollutants, as well as understanding carbon source utilization during B. cenocepacia infection. A striking feature of the PAA pathway in B. cenocepacia is the presence of two genes encoding the phenylacetate CoA ligase (PCL) enzyme (paaK1 and paaK2), responsible for the initial CoA activation of phenylacetic acid. PCLs are members of the adenylate forming enzyme superfamily. However, sequence alignments reveal several intriguing features, including a potentially novel microdomain consisting of the initial ~80 N-terminal residues, which possesses percent identity to any structurally characterized family member. Furthermore, this superfamily utilizes a complicated catalytic mechanism, exploiting several conserved motifs during the reaction process. The precise roles of many key conserved residues are not yet well understood, especially during the pre-adenylation, ATP bound state, for which few high quality crystal structures exist. In order to define the early stages of the catalytic mechanism, and to assess how the divergent polypeptide region may impact the PaaK enzymes, we have pursued a detailed structural characterization of the paralogs, complemented with functional assessments. Specifically, we have produced a 1.6 Å resolution crystal structure of PaaK1 in complex with ATP, which reveals a novel helical bundle arrangement at the N-terminal domain never before seen in this superfamily. Remarkably, homodimerization of PaaK1 appears to reconstitute potentially important β sheet interactions observed in the classical N-terminal arrangement of family members. Moreover, our structure is one of few which contain well ordered β and γ phosphates, allowing for detailed examination of significant protein-ATP interactions with conserved catalytic residues. To better comprehend the roles of these residues over the course of the reaction, we have produced additional crystal structures of PaaK1 and PaaK2 in complex with the phenylacetyl adenylate intermediate. Notably, PaaK2 was captured following the domain reorientation, poised to catalyze thioesterification of phenylacetyl adenylate, providing insight into the later stages of the reaction process. Furthermore, the intermediate co-structures divulge the location of the aryl substrate binding pocket for both paralogs. Detailed comparisons of the binding pockets accompanied kinetic characterizations for both paralogs, demonstrating that PaaK2 possesses an apparent KM of 150 μM for phenylacetic acid, more than double that of PaaK1 (62 μM). Our findings provide preliminary evidence for distinct functional roles of the PaaK paralogs in B. cenocepacia, while imparting additional insight into catalytic roles of conserved residues within the adenylate forming superfamily at large. / Graduate

aromatic compounds

phenylacetic acid

Synthesis of some pyrene annelated macrocyclic systems

Mahadevan, Ramanathan

14 April 2014

Graduate / 0485

aromatic compounds

annulenes