Spelling suggestions: "subject:"3picoline alkaloids"" "subject:"3picoline lkaloids""
1 |
LOLINE ALKALOID BIOSYNTHESIS IN <i>NEOTYPHODIUM UNCINATUM</i>, A FUNGAL ENDOPHYTE OF <i>LOLIUM PRATENSE</i>Blankenship, Jimmy Douglas 01 January 2004 (has links)
Some endophytes in mutualistic associations with Festuca, Lolium and other grass species produce insecticidal loline alkaloids (1-aminopyrrolizidines; LA). These loline alkaloids have a saturated pyrrolizidine ring system (two-rings sharing a carbon and nitrogen atom), a 1-amine substituted with methyl, acetyl, or formyl groups, and an oxygen bridge between C-2 and C-7. The development of a reliable system of production of LA in cultures of the Lolium pratense (meadow fescue) endophyte, Neotyphodium uncinatum, facilitated work on the LA biosynthetic pathway. N. uncinatum produced norloline, loline, methylloline, N-acetylnorloline (NANL), N-formylloline (NFL), and N-acetylloline as detected in culture filtrates. The total production of the two most abundant alkaloids, NANL and NFL, approached 1000 g ml-1 of fungal filtrate. 1H and 13C chemical shifts were previously reported for this group of alkaloids. Extraction and synthesis of sufficient quantities of the alkaloids allowed determination of previously unknown 15N chemical shifts of some LA. Knowledge of 13C and 15N chemical shifts allowed identification of precursors by feeding stable-isotope-labeled compounds. Initially, due to structural similarity to other plant pyrrolizidines, this study examined putrescine and spermidine as possible precursors to LA. Feeding of 14C putrescine to the fungal cultures failed to demonstrate any enrichment in the LA, but enriched spermidine. In contrast, cultures fed with positionally labeled 2H, 13C and 15N amino acids namely, L-ornithine, L-proline, L-aspartate, L-homoserine, and L-methionine demonstrated specific isotopic enrichment in NFL. Determination of the enrichment from the labeled amino acids utilized 13C and 15 N NMR (nuclear magnetic resonance) and gas chromatography-mass spectroscopy (GC-MS). This study allowed the biosynthetic origins of all carbons and nitrogens of NFL to be determined. NFL incorporated L-proline into the B-ring and L-homoserine into the A-ring and 1-amine. The results strongly indicated that polyamines are not precursors of LA and implicated a novel biochemical pathway for the synthesis of LA.
|
2 |
Ether Bridge Formation and Chemical Diversification in Loline Alkaloid BiosynthesisPan, Juan 01 January 2014 (has links)
Loline alkaloids, found in many grass-Epichloë symbiota, are toxic or feeding deterrent to invertebrates. The loline alkaloids all share a saturated pyrrolizidine ring with a 1-amine group and an ether bridge linking C2 and C7. The steps in biosynthesis of loline alkaloids are catalyzed by enzymes encoded by a gene cluster, designated LOL, in the Epichloë genome. This dissertation addresses the enzymatic, genetic and evolutionary basis for diversification of these alkaloids, focusing on ether bridge formation and the subsequent modifications of the 1-amine to form different loline alkaloids.
Through gene complementation of a natural lolO mutant and comparison of LOL clusters in strains with different loline alkaloid profiles, I found that lolO, predicted to encode a 2-oxoglutarate-dependent nonheme iron (2OG/Fe) dioxygenase, is required in formation of the ether bridge. Through application of isotopically labeled compound to Epichloë uncinata culture, I established that exo-1-acetamidopyrrolizidine (AcAP) and N-acetylnorloline (NANL) are true pathway intermediates. Application of AcAP to yeast expressing lolO resulted in production of NANL, establishing that LolO is sufficient to catalyze this unusual oxygenation reaction.
After ether formation, modifications on the 1-amino group give loline, N-methylloline (NML), N-formylloline (NFL) and N-acetylloline (NAL). A double knockout of lolN, predicted to encode an acetamidase, and lolM, predicted to encode a methyltransferase, produced only NANL. Complementation of the double knockout with wild-type lolN and lolM restored the loline alkaloid profile. These results indicate that LolN is involved in deacetylating NANL to produce norloline, which is then modified to form the other lolines. Crude protein extract of a yeast transformant expressing LolM converted norloline to loline and NML, and loline to NML, supporting the hypothesis that LolM functions as a methyltransferase in the loline-alkaloid biosynthesis pathway. The alkaloid NAL was observed in some but not all plants symbiotic with Epichloë siegelii, and when provided with exogenous loline, asymbiotic meadow fescue (Lolium pratense) plants produced N-acetylloline (NAL), indicating that a plant acetyltransferase converts loline to NAL.
I further analyzed the basis for loline alkaloid diversity by comparing the LOL clusters in the Epichloë and Atkinsonella species with different loline alkaloid profiles, and found that LOL clusters changed position, orientation and gene content over their evolutionary history. Frequent, independent losses of some or all late pathway genes, lolO, lolN, lolM and lolP, resulted in diverse loline alkaloid profiles. In addition, phylogenetic analyses demonstrated transspecies polymorphism of the LOL clusters.
Based on my findings, I established that in Epichloë and Atkinsonella species the ether bridge is formed on acetamidopyrrolizidine. My study of the loline alkaloid profile of Adenocarpus decorticans (Fabaceae) suggests that these plants probably use a similar strategy at least with respect to ether-bridge formation. Further diversification steps of loline alkaloids in grass-Clavicipitaceae symbiota are carried out by enzymes of both Epichloë species and the host plant. Finally, I present evidence that LOL clusters have evolved by balancing selection for chemical diversity.
|
Page generated in 0.0375 seconds