@phdthesis{Kunz2023, author = {Kunz, Marcel}, title = {Diffusion kinetics of organic compounds and water in plant cuticular model wax under the influence of diffusing barrier-modifying adjuvants}, doi = {10.25972/OPUS-27487}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-274874}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {To reach their target site, systemic pesticides must enter the plant from a spray droplet applied in the field. The uptake of an active ingredient (AI) takes place via the barrier-forming cuticular membrane, which is the outermost layer of the plant, separating it from the surrounding environment. Formulations are usually used which, in addition to the AI, also contain stabilizers and adjuvants. Adjuvants can either have surface-active properties or they act directly as barrier-modifying agents. The latter are grouped in the class of accelerating adjuvants, whereby individual variants may also have surface-active properties. The uptake of a pesticide from a spray droplet depends essentially on its permeability through the cuticular barrier. Permeability defines a combined parameter, which is the product of AI mobility and AI solubility within the cuticle. In recent decades, several tools have been developed that allowed the determination of individual parameters of organic compound penetration across the cuticular membrane. Nevertheless, earlier studies showed that mainly cuticular waxes are the barrier-determining component of the cuticular membrane and additionally, it was shown that mainly the very-long-chain aliphatic compounds (VLCAs) are responsible for establishing an effective barrier. However, the barrier-determining role of the individual VLCAs, being classified according to their respective functional groups, is still unknown. Therefore, the following objectives were pursued and achieved in this work: (1) A new ATR-FTIR-based approach was developed to measure the temperature-dependent real-time diffusion kinetics of organic models for active ingredients (AIs) in paraffin wax, exclusively consisting of very-long chain alkanes. (2) The developed ATR-FTIR approach was applied to determine the diffusion kinetics of self-accelerating adjuvants in cuticular model waxes of different VLCA composition. At the same time, wax-specific changes were recorded in the respective IR spectra, which provided information about the respective wax modification. (3) The ATR-FTIR method was used to characterize the diffusion kinetics, as well as to determine the wax-specific sorption capacities for an AI-modeling organic compound and water in cuticular model waxes after adjuvant treatment. Regarding the individual chemical compositions and structures, conclusions were drawn about the adjuvant-specific modes of action (MoA). In the first chapter, the ATR-FTIR based approach to determine organic compound diffusion kinetics in paraffin wax was successfully established. The diffusion kinetics of the AI modelling organic compounds heptyl parabene (HPB) and 4-cyanophenol (CNP) were recorded, comprising different lipophilicities and molecular volumes typical for AIs used in pesticide formulations. Derived diffusion coefficients ranged within 10-15 m2 s-1, thus being thoroughly higher than those obtained from previous experiments using an approach solely investigating desorption kinetics in reconstituted cuticular waxes. An ln-linear dependence between the diffusion coefficients and the applied diffusion temperature was demonstrated for the first time in cuticular model wax, from which activation energies were derived. The determined activation energies were 66.2 ± 7.4 kJ mol-1 and 56.4 ± 9.8 kJ mol-1, being in the expected range of already well-founded activation energies required for organic compound diffusion across cuticular membranes, which again confirmed the significant contribution of waxes to the cuticular barrier. Deviations from the assumed Fickian diffusion were attributed to co-occurring water diffusion and apparatus-specific properties. In the second and third chapter, mainly the diffusion kinetics of accelerating adjuvants in the cuticular model waxes candelilla wax and carnauba wax were investigated, and simultaneously recorded changes in the wax-specific portion of the IR spectrum were interpreted as indications of plasticization. For this purpose, the oil derivative methyl oleate, as well as the organophosphate ester TEHP and three non-ionic monodisperse alcohol ethoxylates (AEs) C12E2, C12E4 and C12E6 were selected. Strong dependence of diffusion on the respective principal components of the mainly aliphatic waxes was demonstrated. The diffusion kinetics of the investigated adjuvants were faster in the n-alkane dominated candelilla wax than in the alkyl ester dominated carnauba wax. Furthermore, the equilibrium absorptions, indicating equilibrium concentrations, were also higher in candelilla wax than in carnauba wax. It was concluded that alkyl ester dominated waxes feature higher resistance to diffusion of accelerating adjuvants than alkane dominated waxes with shorter average chain lengths due to their structural integrity. This was also found either concerning candelilla/policosanol (n-alcohol) or candelilla/rice bran wax (alkyl-esters) blends: with increasing alcohol concentration, the barrier function was decreased, whereas it was increased with increasing alkyl ester concentration. However, due to the high variability of the individual diffusion curves, only a trend could be assumed here, but significant differences were not shown. The variability itself was described in terms of fluctuating crystalline arrangements and partial phase separation of the respective wax mixtures, which had inevitable effects on the adjuvant diffusion. However, diffusion kinetics also strongly depended on the studied adjuvants. Significantly slower methyl oleate diffusion accompanied by a less pronounced reduction in orthorhombic crystallinity was found in carnauba wax than in candelilla wax, whereas TEHP diffusion was significantly less dependent on the respective wax structure and therefore induced considerable plasticization in both waxes. Of particular interest was the AE diffusion into both waxes. Differences in diffusion kinetics were also found here between candelilla blends and carnauba wax. However, these depended equally on the degree of ethoxylation of the respective AEs. The lipophilic C12E2 showed approximately Fickian diffusion kinetics in both waxes, accompanied by a drastic reduction in orthorhombic crystallinity, especially in candelilla wax, whereas the more hydrophilic C12E6 showed significantly retarded diffusion kinetics associated with a smaller effect on orthorhombic crystallinity. The individual diffusion kinetics of the investigated adjuvants sometimes showed drastic deviations from the Fickian diffusion model, indicating a self-accelerating effect. Hence, adjuvant diffusion kinetics were accompanied by a distinct initial lag phase, indicating a critical concentration in the wax necessary for effective penetration, leading to sigmoidal rather than to exponential diffusion kinetics. The last chapter dealt with the adjuvant-affected diffusion of the AI modelling CNP in candelilla and carnauba wax. Using ATR-FTIR, diffusion kinetics were recorded after adjuvant treatment, all of which were fully explicable based on the Fickian model, with high diffusion coefficients ranging from 10-14 to 10-13 m2 s-1. It is obvious that the diffusion coefficients presented in this work consistently demonstrated plasticization induced accelerated CNP mobilities. Furthermore, CNP equilibrium concentrations were derived, from which partition- and permeability coefficients could be determined. Significant differences between diffusion coefficients (mobility) and partition coefficients (solubility) were found on the one hand depending on the respective waxes, and on the other hand depending on treatment with respective adjuvants. Mobility was higher in candelilla wax than in carnauba wax only after methyl oleate treatment. Treatment with TEHP and AEs resulted in higher CNP mobility in the more polar alkyl ester dominated carnauba wax. The partition coefficients, on the other hand, were significantly lower after methyl oleate treatment in both candelilla and carnauba wax as followed by TEHP or AE treatment. Models were designed for the CNP penetration mode considering the respective adjuvants in both investigated waxes. Co-penetrating water, which is the main ingredient of spray formulations applied in the field, was likely the reason for the drastic differences in adjuvant efficacy. Especially the investigated AEs favored an enormous water uptake in both waxes with increasing ethoxylation level. Surprisingly, this effect was also found for the lipophilic TEHP in both waxes. This led to the assumption that the AI permeability is not exclusively determined by adjuvant induced plasticization, but also depends on a "secondary plasticization", induced by adjuvant-attracted co-penetrating water, consequently leading to swelling and drastic destabilization of the crystalline wax structure. The successful establishment of the presented ATR-FTIR method represents a milestone for the study of adjuvant and AI diffusion kinetics in cuticular waxes. In particular, the simultaneously detectable wax modification and, moreover, the determinable water uptake form a perfect basis to establish the ATR-FTIR system as a universal screening tool for wax-adjuvants-AI-water interaction in crop protection science.}, subject = {Pflanzen}, language = {en} } @phdthesis{Hansjakob2012, author = {Hansjakob, Anton}, title = {The role of cuticular waxes in the prepenetration processes of Blumeria graminis f.sp. hordei}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-72840}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Der obligat biotrophe Pilz Blumeria graminis f.sp. hordei gilt als Erreger des Gerstenmehltaus, einer destruktiven Erkrankung der Gerste (Hordeum vulgare). Als Folge des Befalls mit B. graminis f.sp. hordei drohen erhebliche Ernteeinbußen. Das kutikul{\"a}re Wachs von Gerstenbl{\"a}ttern besteht haupts{\"a}chlich aus prim{\"a}ren Alkoholen (80\%), Alkylestern (10\%) sowie aus geringf{\"u}gig vorkommenden Bestandteilen wie Fetts{\"a}uren (2\%), Alkanen (2\%) und Aldehyden (1\%). Der initiale Kontakt der asexuellen und durch die Luft verbreiteten Konidien findet auf der Blattoberfl{\"a}che in einer Umgebung statt, die von den kutikul{\"a}ren Wachsen bestimmt ist, welche Keimung und Differenzierung stimulieren. W{\"a}hrend der Keimungs- und Differenzierungsphase durchlaufen die Konidien eine sequenzielle Morphogenese, die so genannten Pr{\"a}penetrationsprozesse. Dabei bilden die Konidien auf der Pflanzenoberfl{\"a}che zun{\"a}chst einen prim{\"a}ren, kurzen und im weiteren Verlauf einen sekund{\"a}ren, elongierten Keimschlauch aus. Im Anschluss daran schwillt dieser an und wird letztlich zu einem septierten Appressorium differenziert. Mit Hilfe des Appressoriums dringt der Pilz dann in die Epidermiszelle der Wirtspflanze ein und bildet ein initiales Haustorium, das die Ern{\"a}hrung des Pilzes sicherstellt. Um den Einfluss von einzelnen Wachsbestandteilen der Wirtspflanze auf die Pr{\"a}penetrationsprozesse systematisch zu untersuchen wurde ein neues in vitro System auf der Basis von Formvar®-Harz etabliert. Dieses System erm{\"o}glicht die Erzeugung homogener Oberfl{\"a}chen als Substrate f{\"u}r den Pilz, bei denen sowohl die aufgelagerten Mengen als auch die Oberfl{\"a}chenhydrophobizit{\"a}t unabh{\"a}ngig von den getesteten Substanzklassen und Kettenl{\"a}ngen der Molek{\"u}le hochgradig reproduzierbar sind. In diesem System haben langkettige Aldehyde die Keimung und die Differenzierung von B. graminis f.sp. hordei Konidien am wirksamsten induziert, wobei die Raten der Appressorienbildung in Abh{\"a}ngigkeit von der Konzentration und der Kettenl{\"a}nge im Vergleich zu n-Hexacosanal (C26), das sich als am effektivsten zeigte, abnahmen (C22<C28>>C30). Die getesteten gerad- und ungeradzahligen Alkane (C24-C33), Fetts{\"a}uren (C20-C28), Alkylester (C40-C44) und prim{\"a}ren Alkohole (C20-C30) hatten keinen signifikanten Einfluss auf die Keimung und die Appressorienbildung des Pilzes. Der prim{\"a}re Alkohol n-Hexacosanol (C26) stellte hierbei eine Ausnahme dar, da er die Keimung und die Bildung des Appressorium-Keimschlauchs signifikant erh{\"o}hte. Um die Rolle von langkettigen Aldehyden auf einer intakten Pflanzenoberfl{\"a}che in vivo genauer zu untersuchen wurden B. graminis f.sp. hordei Konidien auf Bl{\"a}tter von glossy11 Mutanten der Nicht-Wirtspflanze Mais (Zea mays) inokuliert. Anders als der Wildtyp weisen glossy11 Bl{\"a}tter keine langkettigen Aldehyde auf. Auf glossy11 Bl{\"a}ttern keimten 60\% der B. graminis f.sp. hordei Konidien nicht und nur 10\% der Konidien entwickelten ein reifes Appressorium, was einer dreimal geringeren Rate als auf Wildtyp-Bl{\"a}ttern entspricht. Durch das Bespr{\"u}hen von glossy11 Bl{\"a}tter mit synthetischem n-Hexacosanal oder mit Wachs des Wildtyps wurden die pilzlichen Pr{\"a}penetrationsprozesse wieder vollst{\"a}ndig durchlaufen. Wurden im Gegensatz dazu Bl{\"a}tter des Mais-Wildtyps mit nicht induzierenden n-Alkanen, prim{\"a}ren Alkoholen oder langkettigen Fetts{\"a}uren bespr{\"u}ht, konnte das den Aldehyd-defizienten Ph{\"a}notyp von glossy11 imitieren. W{\"a}hrend der Pr{\"a}penetrationsprozesse wird ein Appressorium gebildet, wobei es sich hierbei um eine neu gebildete Zelle handelt. Die Keimung und die anschließende Morphogenese sind wichtige Schritte in der Etablierung der pilzlichen Infektionsstrukturen. Da diese Prozesse in einigen phytopathogenen Pilzen mit dem Zellzyklus gekoppelt sind wurde untersucht, inwieweit die Pr{\"a}penetrationsprozesse von B. graminis f.sp. hordei mit dem Verlauf des Zellzykluses synchronisiert sind. Hierf{\"u}r wurde eine Methode basierend auf DAPI (4,6-diamidino-2-phenylindole) zur F{\"a}rbung der Zellkerne f{\"u}r fixierte Pr{\"a}parate von B. graminis f.sp. hordei Konidien entwickelt. Mittels eines pharmakologischen Ansatzes war es auf diese Weise erstmals m{\"o}glich die Abh{\"a}ngigkeit der Pr{\"a}penetrationsprozesse von der Mitose in vivo und in vitro zu verfolgen. Sechs Stunden nach der Inokulation trat nach Ausbildung des Appressorium-Keimschlauchs eine Mitose in der einkernigen Konidie auf. Die Hemmung der S-Phase mit Hydroxyharnstoff oder die Hemmung der M-Phase mit Benomyl verhinderten eine Bildung des Appressoriums, nicht aber die Entwicklung des Appressorium-Keimschlauchs. Diese Ergebnisse weisen darauf hin, dass die Mitose und eine abgeschlossene Zytokinese notwendige Voraussetzungen f{\"u}r die Appressoriumsbildung, jedoch nicht f{\"u}r die Morphogenese der Konidie, sind. Als Reaktion auf bestimmte Wachsbestandteile der Wirtspflanze werden pilzliche Gene, die w{\"a}hrend der Pr{\"a}penetrationsprozesse eine wichtige Rolle spielen k{\"o}nnen, differenziell exprimiert. Um solche Gene zu identifizieren wurden cDNA Klonbibliotheken mittels der suppression subtractive hybridization (SSH) 22 Minuten nach der Inokulation erstellt. Das auf Formvar®-Harz basierende in vitro System erm{\"o}glichte die selektive Anreicherung von cDNA Sequenzen aus B. graminis f.sp. hordei Konidien, die auf n-Hexacosanal beschichteten Oberfl{\"a}chen inokuliert wurden. Aus einer Reihe von Kandidaten wurde eine cDNA-Sequenz identifiziert, die sowohl auf Gerstenbl{\"a}ttern als auch auf mit n-Hexacosanal oder extrahiertem Gerstenwachs beschichteten Oberfl{\"a}chen hochreguliert war. Mittels 3' und 5' RACE wurde das n-Hexacosanal induzierte Transkript kloniert. Diese cDNA-Sequenz wies keine Homologien zu bekannten Genen, die Funktionen in der pilzlichen Entwicklung und der Ausbildung von Pathogenit{\"a}t in Pflanzen haben, auf.}, subject = {.}, language = {en} } @phdthesis{Leide2008, author = {Leide, Jana}, title = {Cuticular Wax Biosynthesis of Lycopersicon esculentum and Its Impact on Transpiration Barrier Properties during Fruit Development}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-34526}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {Cuticular waxes cover all above-ground growing parts of plants. They provide the outermost contact zone between plants and their environment and play a pivotal role in limiting transpirational water loss across the plant surface. The complex mechanisms in cuticular wax biosynthesis conferring proper barrier function still remain to be elucidated. The present study focuses on biosynthetic pathways in wax formation, cuticular wax accumulation and composition and its impact on the epidermal barrier property of the intact system of the astomatous tomato fruit (Lycopersicon esculentum Mill.). Fruits of all developmental stages of the wild type cultivar MicroTom and its lecer6 mutant defective in a \&\#946;-ketoacyl-CoA synthase involved in very-long-chain fatty acid elongation were analyzed. This 'reverse genetic' approach clarified the importance of the \&\#946;-ketoacyl-CoA synthase LeCER6 for epidermal barrier property in vivo on the biochemical-analytical level, on the transcriptional level and, furthermore, on the physiological level comparatively between MicroTom wild type and MicroTom lecer6. Surfaces of MicroTom wild type and MicroTom lecer6 fruits showed similar patterns of quantitative wax accumulation, but differed considerably in the permeance for water. Qualitative analyses of the chemical composition of fruit cuticular waxes in the course of fruit development revealed the meaning of the \&\#946;-ketoacyl-CoA synthase deficiency in the lecer6 mutant. Fruits of this mutant exhibited a distinct decrease in the proportion of n-alkanes of chain lengths > C28. Moreover, a concomitant increase in pentacyclic triterpenoids became discernible in the mature green fruit stage of the mutant. Since quantitative changes of the cutin matrix were not sufficient to affect transpiration barrier properties of the lecer6 mutant presumably the shift in cuticular wax biosynthesis of the lecer6 mutant is responsible for the observed increase of water permeance. In order to investigate the molecular basis of wax formation, a microarray experiment was established that allows the simultaneous and comprehensive analysis of the timing and abundance of transcriptional changes in MicroTom wild type and MicroTom lecer6. This microarray consists of 167 oligonucleotides corresponding to EST and gene sequences of tomato potentially participating in wax biosynthesis, wax modification, transport processes and stress responsiveness. These parameters were correlated with the course of fruit development. This comparison of gene expression patterns showed a variety of differential expressed transcripts encoding for example lipid transfer proteins and the dehydrin TAS14. On the basis of these findings, it can be proposed that diverse regulatory mechanisms like lipid transfer processes or osmotic stress response are affected by the LeCER6 deficiency, which is primarily accompanied by an impaired water barrier property of the fruit cuticle. This present study correlates the continuous increase of LeCer6 gene expression and the accumulation of very-long-chain n-alkanes within the cuticular waxes during the transition from the immature green to the early breaker fruit phase displaying a developmental regulation of the cuticular wax biosynthesis. Organ-specific wax biosynthesis resulted in different cuticular wax pattern in tomato fruits and leaves. Moreover, in contrast to the fruits, LeCER6-deficient leaves showed a significantly reduced wax accumulation, mainly due to a decrease of n-alkanes with chain lengths > C30, while the proportion of pentacyclic triterpenoids were not affected. Deduced from these biochemical-analytical data on tomato fruits and leaves LeCER6 was characterized as a key enzyme in VLCFA biosynthetic pathway responsible for cuticular wax accumulation. In silico analysis of the LeCER6 sequence revealed the presence of two putative transmembrane domains in the N-terminal position. In addition, highly conserved configurations of catalytic residues in the active site of the enzyme were observed, which are probably essential to its overall structure and function in the fatty acid elongation process. High sequence homology of LeCER6 to the very-long-chain condensing enzymes GhCER6 of Gossypium hirsutum L. and AtCER6 of Arabidopsis thaliana (L.) Heynh. was found, which might be a good evidence for similar biochemical functions. Apart from developmental regulation of the cuticular wax biosynthesis, environmental factors influenced the cuticular wax coverage of tomato fruits. Mechanical removal of epicuticular fruit wax evoked large-scale modifications of the quantitative and qualitative wax composition, such as a reduction of aliphatic wax components, and therewith affected the cuticular water permeability. A subsequent regeneration event was included in the regular wax biosynthesis process and led to the compensation of the detached wax amounts and increased the water barrier properties of the cuticular membrane again. In contrast, water-limited conditions had only minor impact on alterations in cuticular wax biosynthesis and, consequently, on the permeance for water of tomato fruits. Floral organ fusion and conditional sterility, as observed in this study, are caused as pleiotropic effects in cell-cell signaling by the loss-of-function mutation in LeCER6. These findings corroborated the functional impact of LeCER6 on the epidermal integrity and are consistent with the current knowledge on eceriferum mutants of Arabidopsis. Investigations of phenotypic and biochemical characteristics of tomato fruits allowed a broader system-orientated perspective of the fruit development of MicroTom wild type and its lecer6 mutant. These analyses highlight more precisely alterations in the fruit surface area, fresh and dry weight, epidermal cell density, photosynthetic activity or glucose content in the course of fruit development. The differences between MicroTom wild type and MicroTom lecer6 characterize very well the large-scale consequences of the LeCER6 deficiency on the physiological status of tomato fruits. Moreover, the results clearly show a part of the genetic controlled network that governs tomato fruit metabolism and mediates extensive changes of the tomato fruit life cycle. The analyses of the stem scar tissue of the tomato fruit revealed a complex set of responses caused by the harvesting process in detail. Throughout storage of the tomato fruits barrier properties were attributed to the suberized stem scar tissue in regard to water loss limitation and reduction of the fungal infection rate. Thereby the endogenous level of abscisic acid was found to be involved in the molecular signaling pathway that regulates the de novo formation of this tissue. For the first time, the chemical composition and physiological importance could be correlated with molecular changes at the transcriptional level during suberization of the stem scar of tomato fruits. In conclusion, this work indicates a novel intact model system for an integrative functional approach for plant barrier properties that was successfully established and carefully studied. The results highlight correlations between wax biosynthesis, distribution of cuticular waxes, and its relevance on the transpirational water loss across the plant surface and, thus, promote the global understanding of plant cuticle biology.}, subject = {Wachs}, language = {en} }