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Fungal endophyte-infected grasses: Alkaloid accumulation and aphid response (1990)

Siegel, M. R. ; Latch, G. C. M. ; Bush, L. P. ; [et al.]

Springer

Journal of chemical ecology 16 (1990), S. 3301-3315

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ISSN: 1573-1561

Keywords: Endophyte-infected grasses ; Acremonium ; endophytes ; Epichloe typhina ; grass alkaloids ; lolines ; ergovaline ; peramine ; lolitrem B ; aphid responses ; plant resistance to herbivory ; Rhopalosiphum padi ; Schizaphis graminum ; Homoptera ; Aphididae

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Abstract The occurrence of the alkaloidsN-formyl andN-acetyl loline, peramine, lolitrem B, and ergovaline and the response of aphids to plants containing these compounds were determined in species and cultivars ofFestuca,Lolium, and other grass genera infected with fungal endophytes (Acremonium spp., andEpichloe typhina). Twenty-nine of 34 host-fungus associations produced one or more of the alkaloids, most frequently peramine or ergovaline. Three alkaloids (lolines, peramine, and ergovaline) were found in tall fescue and in perennial ryegrass infected withA. coenophialum, while peramine, lolitrem B, and ergovaline were present in perennial ryegrass and in tall fescue infected withA. lolii and inF. longifolia infected withE. typhina. WhileA. coenophialum andA. lolii produced similar patterns of alkaloids regardless of the species or cultivar of grass they infected, isolates ofE. typhina produced either no alkaloids or only one or two different alkaloids in the grasses tested. Aphid bioassays indicated thatRhopalosiphum padi andSchizaphis graminum did not survive on grasses containing loline alkaloids and thatS. graminum did not survive on peramine-containing grasses. Ergovaline-containing grasses did not affect either aphid.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00982100

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Reaktionen an der BC-Doppelbindung von iPr2N=B=C(SiMe3)2 (1989)

Tapper, Alexander ; Schmitz, Thomas ; Paetzold, Peter

Weinheim : Wiley-Blackwell

Berichte der deutschen chemischen Gesellschaft 122 (1989), S. 595-601

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ISSN: 0009-2940

Keywords: Alkylidenoboranes ; 1,2-Oxaboretanes ; 1,2,4-Azasilaboretidines ; 2,3-Diiminoboretane ; Borylsilyldiazomethane ; Chemistry ; Inorganic Chemistry

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology

Description / Table of Contents: Reactions at the BC Double Bond of iPr2N=B=C(SiMe3)2By thermal elimination of propene and migration of a methyl group at 500-600°C, the alkylidenoaminoborane iPr2N=B=C(SiMe3)2 (1b) is transformed to the azasilaboretidine [-N(iPr)=B(Me)-CH(SiMe3)-SiMe2-] (2). Protic agents HX (X = Cl, Br, OMe, OiPr, NMe2, NEt2) are added to 1b to give iPr2N=B(X)-CH(SiMe3)2 (3a-f); products 3g, h of the same type (X = O—CR=CH2, R = tBu, Ph) are formed from 1b and ketones MeRCO. Products iPr2N=B(X)-C(SiMe3)2-Y [X = Y = Br: 4; X = Me, Y = Li(tmeda): 5] are isolated from the reaction of 1b with the unpolar Br2 or with LiMe, respectively; adduct 5 can be hydrolyzed to 3i (X = Me, Y = H) by HCl. The bromoboration of 1b by MeBBr2 or BBr3 gives iPr2N=B(Br)-(Z)C(SiMe3)-BBrMe (Z = SiMe3: 6a; Z = SiMe2Br: 6b). The CO group of aldehydes RCHO [R = Me, tBu, C(Me)=CH2], ketones PhRCO (R = Me, Ph), and ethyl acetate undergo a [2+2] cycloaddition with 1b to give oxaboretanes [-B(NiPr2)-C(SiMe3)2-CRR′-O-] (7a-f); starting with HCONMe2, the cycloaddition to 1b is followed by ring opening and the migration of a silyl group to yield (iPr2N)B(OSiMe3)-C(SiMe3)=CH(NMe2) (8). Azides RN3 (R = Ph, PhCH2) may be added to 1b with loss of N2, azaboriridines [-(iPr2N)B—C(SiMe3)2-NR-] (9a, b) being formed, whereas Me3SiN3 gives the diazo compound (iPr2N)B[N(SiMe3)2]-C(SiMe3)=N2 (10). The formation of the boretane [-(iPr2N)B—C(SiMe3)2-C(=NtBu)-C(=NtBu)-] (11) is observed from the 2:1 reaction of tBuN≡C with 1b. The alkylidenoaminoborane H14C7N=B=C(SiMe3)2 (1c; H14C7N = 2,6-dimethylpiperidino) is synthesized by a procedure similar to the synthesis of 1b and gives reactions similar to those of 1b: thermal cyclisation to the azasilaboretidine 12, addition of HNMe2 to give 3j, [2 + 2] cycloaddition of RCHO (R = tBu, Ph) and Ph2CO to give 7g-i.

Notes: Das Alkylidenaminoboran iPr2N=B=C(SiMe3)2 (1b) geht bei 500-600°C unter Propenabspaltung und Methylwanderung in das Azasilaboretidin [-N(iPr)=B(Me)-CH(SiMe3)-SiMe2-] (2) über. Protische Stoffe HX (X = Cl, Br, OMe, OiPr, NMe2, NEt2) addieren sich an 1b zu iPr2N=B(X)—CH(SiMe3)2 (3a-f); die Produkte 3g, h desselben Typs (X = O—CR=CH2; R = tBu, Ph) erhält man mit Ketonen MeRCO. Weiterhin kann man an 1b das unpolare Br2 sowie LiMe unter Bildung von iPr2N=B(X)—C(SiMe3)2-Y addieren [X = Y = Br: 4; X = Me, Y = Li(tmeda): 5]; 5 wird durch HCl zu 3i verseift (X = Me, Y = H). Die Bromoborierung von 1b mit MeBBr2 und BBr3 führt zu iPr2N=B(Br)—(Z)C(SiMe3)-BBrMe (Z = SiMe3: 6a; Z = SiMe2Br: 6b). Die CO-Gruppe von Aldehyden RCHO [R = Me, tBu, C(Me)=CH2], Ketonen PhRCO (R = Me, Ph) und Ethylacetat geht mit der BC-Bindung von 1b [2 + 2]-Cycloadditionen zu den Oxaboretanen [-B(NiPr2)-C(SiMe3)2-CRR′-O-] (7a-f) ein; im Falle von HCONMe2 folgt der Cycloaddition eine Silylverschiebung unter Ringöffnung zu (iPr2N)B(OSiMe3)-C(SiMe3)=CH(NMe2) (8). Azide RN3 (R = Ph, PhCH2) addieren sich an 1b unter Abspaltung von N2 zu den Azaboriridinen [-(iPr2N)B—C(SiMe3)2-NR-] (9a, b), während das Azid Me3SiN3 unter Silylwanderung die Diazoverbindung (iPr2N)B[N(SiMe3)2]-C(SiMe3)=N2 (10) ergibt. Mit tBuN≡C reagiert 1b im Verhältnis 2:1 zum Boretan [-(iPr2N)B—C(SiMe3)2-C(=NtBu)-C(=NtBu)-] (11). Das Alkylidenaminoboran H14C7Nd—B=C(SiMe3)2 (1c, H14C7N = 2,6-Dimethylpiperidino) bildet sich ähnlich und reagiert analog 1b: thermische Cyclisierung zum Azasilaboretidin 12, Addition von HNMe2 zu 3j, [2+2]-Cycloaddition von RCHO (R = tBu, Ph) und Ph2CO zu 7g-i.

Additional Material: 2 Tab.