The analysis of starch degradation in Solanaceae species

Samodien, Mugammad Ebrahim

04 1900

Thesis (PhD)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: This project involved the analysis of genes in Solanaceae species that have previously been shown to be involved in the phosphorylation of starch or its subsequent dephosphorylation. Both these processes are essential for normal starch mobilization. A tomato conditional mutant lacking the starch phosphorylating enzyme glucan water dikinase was analyzed. It is known that starch accumulates transiently in tomato fruit and is degraded throughout the ripening process. The study aimed to determine the effect of inhibited starch degradation on fruit development. Unfortunately no effect on starch mobilisation was found in the fruit of the mutant. Immunoblot analysis revealed expression of Glucan Water Dikinase (GWD) within the fruit of the tomato mutant indicating that the conditionality of the mutation was compromised. The second set of experiments analyzed the roles of Starch Excess4 (SEX4), Like Sex Four-1 and Like Sex Four-2 (LSF1 and LSF2) in starch degradation in potato and Nicotiana benthamiana. These enzymes have, thus far, only been studied in Arabidopsis, with the proposed role for SEX4 and LSF2 being that they are involved in dephosphorylation of the C-6 and C-3 positions of starch breakdown products. The role of LSF1 is unclear, although it is not thought to be a phosphatase. SEX4, LSF1 and LSF2 were repressed individually while the expression of SEX4 and LSF2 were also inhibited simultaneously. Using a transient repression system in N. benthamiana it was shown that all of the genes play a role in leaf starch degradation. The SEX4 and LSF2 enzymes were shown to influence the proportion of phosphate located on the starch which contained an altered ratio of C-3/C-6 phosphate. Stably transformed potato plants were produced where SEX4 and LSF2 were successfully repressed in potato leaves and tubers. Although AtLSF2 had been shown not to be essential for normal starch degradation on its own, in potato plants when LSF2 was repressed, the plants developed a starch-excess phenotype. Taken together with the N. benthamiana data this indicates that LSF2 plays a bigger role in leaf starch degradation in Solanaceae than in Arabidopsis. The ratio of C-3/C-6 phosphate was also altered in tuber starch from some of the silenced plants. Starch from SEX4 repressed potato plants contained increased amounts of glucose-6-phosphate and increased glucose-3-phosphate in the tuber when compared to the WT. An increase in the proportion of C-6 or C-3 phosphate is not surprising with SEX4 being characterized as a phosphatase specific for C-6 position and LSF2 for the C-3 position in Arabidopsis, however the combined increase in C-3 and C-6 amounts in StSEX4 silenced plants is interesting. The differences seen in the phosphate alteration in both N. benthamiana leaves and potato tubers indicates that in Solanaceae species these proteins may have a slightly altered specificity when compared with Arabidopsis, although they are undoubtedly involved in starch degradation. The effect of silencing SEX4 or LSF2 on cold-induced sweetening was also investigated, with no effect being found. This may be because of functional redundancy between the proteins and a better approach in terms of blocking cold sweetening would be to simultaneously repress SEX4 and LSF2. Overall, these enzymes seem to play similar roles in leaves of Solanum species as has been described in Arabidopsis. The starch from the engineered plants did have an altered phosphate ratio and further analysis is needed to determine if this leads to improved or additional functionality. / AFRIKAANSE OPSOMMING: Die projek omhels die ontleding van gene van die Solanaceae spesie wat voorheengetoon het dat hulle deel neem in fosforilering of defosforilering van stysel. Altwee van hierdie reaksies is belangrik vir normale stysel metabolisme. ‘n Tamatie konditionele mutant was geanaliseer waarin die stysel fosforilering ensiem glucan water dikinase nie teenwoordig was nie. Die doel van die studie was om te ondersoek watter effek het n gebrek in stysel afbraak op die rypwording en ontwokkeling vrugte. Ongelukkig was geen effek op stysel metabolism in die munant se vrugte gesien. Immunoklad analise het getoon dat GWD protein wel uitdruk word in die vrugte en dus die mutant nie heeltemal effektief was nie. Die tweede stel van experimente het in aartappels en tabak die rol van SEX4, LSF1 en LSF2 in stysel afbraak ondersoek. Hierdie ensieme was huidiglik nog net deeglik in Arabidopsis bestudeer, waar daar gewys was dat SEX4 and LSF2 in die defosforilering van stysel by die C-6 en C-3 posisie deel neem. Die rol van LSF1 is nog onbekend, maar daar word huiglik gelgo dat dit is nie ‘n fosfatase nie. SEX4, LSF1, en LSF2 was onderdruk op sy eie, waar SEX4 en LSF2 gelyktydig onderdruk was. Met behulp van n verbygaande onderdrukking in tabak, was dit getoon dat al die bogenoemde gene n gedeeltelike rol speel in die afbraak van stysel. Dit was getoon dat SEX4 and LSF2 ensiemedie verhouding van waar fosfaat op stysel gelee is beinvloed en het n verandering in die C-3/C-6 phosphaat verhouding ook gehad. Aardappels was stabiel getransformeer en daar was suksesfol plante waar SEX4 en LSF2 onderdruk was in blare en knolle geproduseer. Alhoewel daar getoon was dat AtLSF2 op sy eie nie n groot rol speel in stysel katabolisme nie was daar wel gesien dat in aardappel wanner hierdie geen afgeskakel was dat daar n stysel oorskot fenotiepe ontwikkel. As die tabak resultate saamgevat word met die aardappel wil dit voorkom asof LSF2 n groter rol binne die stysel katabolisme in Solanaceae speel as in Arabidopsis. Daar was gevind dat die verhouding van C-3/C-6 fosfaat was in die knolle verander in perty van die lyne waar geen afskakeling wel plaasgevind het. Die verhouding van C-3/C-6 fosfaat was verander in knolle stysel van sommige stilgemaak plante. Sysel van SEX4 stilgemaak plante het hoër vlakke glukose-6-fosfaat en glukose-3-fosfaat in die knolle gehad wanner dit met die WT vergelyk was. n Toename in die persentasie van C-6 fosfaat is nie verbasend nie, SEX4 word gekenmerk as die spesifieke fosfatase verantwoordelik vir die fosfaat by die C-6 posisie en LSF2 spesifiek vir die C-3 posisie in Arabidopsis. Die gekombineerde toename in beide C-6 en C-3 bedrae in StSEX4 stilgemaak plante is wel heel interesant. Verandering in beide tabak blare and aartapple knolle dui daarop dat in solanacea spesie hierdie proteiene, n effens verandering in spesifisiteit kan hê as dit met Arabidopsis vergelyk word. Daar kan wel nie getwyfel word dat hulle wel n rol speel in stysel afbraak nie. Die effect watSEX4 of LSF2 op koue-geinduseerde soetheid het is ook ondersoek maar daar was geen effek gevind nie. Dit mag wees asgevolg van die funksionele onslag tussen die twee proteien en better benadering on die koue-soetheids effek te verhoed sou wees om beide protein op die selfde stadium aft e skakel. As daar in gegeheel gekyk word lyk dit asof hierdie protein die selfde rolle het in die Solanum spesies as in Arabidopsis.Die stysel van hierdie die ontwerpte plante het ‘n veranderde fosfaat verhouding getoon en veder analise is nodig om te bepaal of dit lei tot verbeterde einskappe of bykommende funksies.

Solanaceae -- Genetic analysis

Solanaceae -- Leaf starch degradation

UCTD

Theses -- Plant biotechnology

Dissertations -- Plant biotechnology

Substrate levels, carbohydrate degradation rate and their effects on ruminal end-product formation /

Sveinbjörnsson, Johannes,

January 2006

Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniversitet, 2006. / Härtill 4 uppsatser.

Molekulare Untersuchungen zum Stärkeabbau in vegetativen Pflanzenteilen / Molecular investigations in starch degradation in plants

Scheidig, Andreas

January 2006

In der vorliegenden Arbeit wurden cDNAs, kodierend für bisher unbekannte stärkeabbauende Enzyme, aus Kartoffel isoliert und funktionell analysiert. Die Isolation der cDNAs erfolgte mit Hilfe eines Systems, welches sich der funktionellen Expression von cDNA-Bibliotheken in E. coli bediente. Die mit diesem System zur Expression gebrachten cDNA-Bibliotheken wurden im Rahmen dieser Arbeit hergestellt. Zum einen handelte es sich um eine blattspezifische Phagen-cDNA-Bibliothek (Proben wurden während des Tag/Nacht Übergangs genommen), zum anderen um eine knollenspezifische cDNA-Bibliothek aus kaltgelagerten Knollen. Nach der Überführung der Phagen-Bibliotheken in Plasmid-Bibliotheken wurden diese funktionell in dem E. coli Stamm KV832 exprimiert. Der Stamm KV832 wurde aufgrund seiner Fähigkeit, lineare Glucane zu akkumulieren, ausgewählt. Werden Glucan akkumulierende KV832 Kolonien mit Jod bedampft, so zeigen diese eine typische Blaufärbung. Nach der Expression der Plasmid-Bibliotheken in KV832 wurden solche Kolonien weiter untersucht, welche in ihrer Färbung von den blauen Kolonien abwichen. Mittels eines zweiten E. coli Stamms, PGM −, welcher ebenfalls in der Lage ist, lineare Glucane zu akkumulieren, wurden die Ergebnisse für KV832 bestätigt. Die funktionelle Expression der Bibliotheken führte zur Isolation einer Reihe von unbekannten cDNAs. Zwei dieser cDNAs wurden im Rahmen dieser Arbeit weiterführend untersucht. Zum einen handelte es sich um eine cDNA, die für eine bis dahin unbekannte β-Amylase aus Kartoffel kodierte und deren Homolog aus Arabidopsis (CT-BMY) im Laufe dieser Arbeit von Lao et al. (1999) veröffentlicht wurde, zum anderen um eine cDNA, die für ein unbekanntes Enzym kodierte (DSD10). Das Arabidopsis Homolog zu DSD10 wurde im Zuge der Arabidopsis Genominitiative Ende 2000 publiziert. Im Rahmen dieser Arbeit konnte gezeigt werden, dass die isolierte β-Amylase cDNA für eine funktionelle β-Amylase kodiert und dieses Enzym in der Lage ist, neben löslicher auch rohe Stärke anzugreifen. Lokalisationsexperimente zeigten, dass das Enzym in isolierte Erbsenchloroplasten importiert wurde und dass die 100 N-terminalen Aminosäuren für den Import in die Plastiden ausreichten. Die β-Amylase wurde als PCT-BMYI bezeichnet. Die »antisense«-Inhibierung von PCT-BMYI führte zu einem Hochstärke-Phänotyp der Blätter, sowie zu einem Anstieg der Trockenmasse. Der Hochstärke-Phänotyp ist auf eine Reduktion der Stärkemobilisierung und die daraus folgende Akkumulation der Stärke während der Vegetationsperiode zurückzuführen. Damit konnte erstmals die physiologische Bedeutung einer β-Amylase für den Abbau der transitorischen Stärke gezeigt werden. Kein Einfluss zeigte die »antisense« Inhibierung von PCT-BMYI auf den kälteinduzierten Abbau der Speicherstärke in Knollen. Es konnte auch kein Unterschied im Keimverhalten oder der Entwicklung der neuen Pflanze beobachtet werden. Ein Teil der Ergebnisse zu PCT-BMYI wurde bereits publiziert (Scheidig et al., 2002). Die isolierten cDNAs dsd10, sgeI (die Volllängen cDNA zu dsd10) und das Arabidopsis Homolog asgeI kodieren für Enzyme, welche α-Amylase-Aktivität besitzen, aber keine Homologie zu bekannten α-Amylasen aufweisen. Ein mögliches Glucoamylase Motiv erwies sich für die Aktivität des Proteins als essentiell. Lokalisationsexperimente deuteten auf den Import des SGEI Proteins in isolierte Erbsenchloroplasten hin. Die »antisense«-Inhibierung von sgeI führte in den entsprechenden Linien zu einem Hochstärke-Phänotyp in Blättern, einem Anstieg der Trockenmasse in Blättern, sowie zu größeren Stärkekörnern in einer der untersuchten Linien. Ein nicht erwarteter Effekt zeigte sich in Blättern der entsprechenden Linien, welche für längere Zeit dunkel gehalten wurden. Die Blätter der untransformierten Kontrolle waren abgestorben, wohingegen die Blätter der SGEI »antisense« Linien grün und vital erschienen. Die α- und β-Amylase-Aktivität war in Blättern der SGEI »antisense« Linien reduziert, weshalb eine genaue Zuordnung der Funktion von SGEI nicht möglich war. Die vorliegenden Ergebnisse zu den SGEI »antisense« Linien deuten aber darauf hin, dass der beobachtete Hochstärke-Phänotyp nicht alleine auf die Reduktion der β-Amylase-Aktivität zurückzuführen ist. Ein Einfluss von SGEI auf den kälteinduzierten Abbau der Speicherstärke konnte nicht beobachtet werden. Es konnte auch hier kein Unterschied im Keimverhalten oder der Entwicklung der neuen Pflanze beobachtet werden. / In the presented work, previously unidentified starch metabolic genes from potato were isolated and functionally characterized. Gene isolation proceeded using a cDNA library system that allows the functional expression of potato genes in E. coli. The generated libraries included 1) a phage vector-based, leaf-specific cDNA library generated from mRNA isolated during the day/night transition and 2) a phage vector-based, tuber-specific cDNA library generated from mRNA isolated from potato tubers after cold storage. After in vivo mass Excision of the phage library, the resulting plasmid libraries were functionally expressed in E. coli strain, KV832. This strain was selected for its ability to accumulate linear glucans. Reaction with iodine vapour in glucan-producing KV832 colonies results in a characteristic blue hue. The expression library was thus screened for colonies in which the blue hue was diminished, a potential indicator of the expression of starch degrading enzymes. Library clones from the selected colonies were reconfirmed in PGM−, an alternative E. coli that also accumulates linear glucans. The above expression and screening program allowed isolation of a series of previously uncharacterized cDNA clones. Two such clones were investigated in depth in the remainder of the presented work. The first of these cDNA clones comprised a gene for a hitherto unidentified β-amylase function. The second encoded a functional truncation of a previously unknown enzyme, and was designated DSD10. The full length version of this gene was isolated and designated sgeI. Homologs of both full-length genes have since been identified in Arabidopsis: the former was published as CT-BMY by Lao et al. (1999), while the latter was published in the course of the Arabidopsis Genome Initiative at the end of 2000. Demonstrated in the course of this work is that the first of these isolated amylase cDNAs encodes a functional β-amylase enzyme that hydrolyses raw as well as soluble starch. Enzyme localization experiments showed that the 100 N-terminal amino acids are sufficient to effect import into isolated pea chloroplasts, which is supportive of plastid-targeted localization in potato. This novel β-amylase was designated as PCT-BMYI. Whole-plant antisense inhibition of PCT-BMYI in the potato plant resulted in a high-starch phenotype in the leaf, as well as to an increase in leaf dry weight. The high-starch phenotype was caused by a reduction in starch mobilization and the resulting accumulation of starch during the vegetative phase. This represents the first demonstration of the physiological role of a β-amylase in the metabolism of transitory starch deposits. In contrast to its role in the leaf, antisense inhibition of PCT-BMY1 resulted in no observable alteration in cold-induced metabolism of storage starch in the potato tuber. Additionally, inhibition of PCT-BMY1 resulted in no observable alteration in tuber sprouting, nor in the development of the potato plants. A portion of the results regarding PCT-BMYI have been published (Scheidig et al., 2002). The second isolated gene, sgeI, and its Arabidopsis homolog, asgeI, encode enzymes with α-amylase activity, but neither show homology to known α-amylases. A putative glucoamylase motif, however, was found to be essential for activity of the sgeI gene product, SGEI. As was the case for PCT-BMY1, localization experiments demonstrated import of SGEI into isolated pea chloroplasts, again suggesting plastid localization in potato. Antisense inhibition of sgeI in potato lead to a high-starch phenotype in the leaf and an increase in the leaf dry weight, but also to an increase in starch granule size in one of the studied potato lines. Longer term storage of such lines in the absence of light resulted in an unexpected phenomenon. While the wild type control leaves withered and died within days, the sgeI antisense lines appeared green and healthy for over two weeks. The reason for this may be the metabolism of the stored, hyper-accumulated starch, both due to and despite the initial antisense suppression of sgeI. The exact roll of SGEI in these experiments was complicated by the observed simultaneous suppression of both α- und β-amylase activity in the sgeI antisense lines. The clear quantitative differences in the observed high-starch phenotypes of the sgeI and PCT-BMY1 lines, however, suggest that these phenotypic differences were not due to suppression of β-amylase activity alone. SGEI suppression resulted in no observed differences in sprouting, development of potato plants, or in the metabolism of storage starch in the potato tuber.

Screening

Stärkeabbau

Solanum tuberosum

transitorische Stärke

beta-Amylase

starch degradation

solanum tuberosum

transitory starch

beta-amylase

screening

Life sciences

O fator de transcrição bZIP AtbZIP63 interage com o relógio circadiano e afeta a degradação do amido impactando o crescimento e o desenvolvimento de Arabidopsis thaliana / The transcription factor bZIP AtbZIP63 interacts with the circadian clock and affects the starch degradation impacting the growth and development of Arabidopsis thaliana

Viana, Américo José Carvalho, 1984-

06 September 2014

Orientador: Michel Georges Albert Vincentz / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-25T14:21:25Z (GMT). No. of bitstreams: 1 Viana_AmericoJoseCarvalho_D.pdf: 5804951 bytes, checksum: a3c65fa34ad298641a9b177952050af3 (MD5) Previous issue date: 2014 / Resumo: O fator de transcrição do tipo basic leucine leucine zipper (bZIP) de Arabidopsis thaliana AtbZIP63 faz parte da via de resposta a carência energética coordenada pelas quinases KIN10/11, integradoras centrais dos sinais relacionados ao estado de privação de energia. O mutante de inserção de T-DNA atbzip63-2 apresenta uma redução do crescimento e desenvolvimento das folhas assim como um atraso do florescimento em comparação ao tipo selvagem (TS, acesso Ws) quando cultivado em fotoperíodo de dia curto (10 h/14 h). Condições de fotoperíodo de dia longo ou luz contínua promoveram uma reversão parcial ou completa, respectivamente, do fenótipo mutante para o tipo selvagem, levantando a possibilidade de que este fenótipo seja o resultado de uma carência energética. Plantas silenciadas para expressão de AtbZIP63 por RNAi apresentaram características similares a do mutante atbzip63-2 confirmando o envolvimento deste fator de transcrição no crescimento. O perfil de expressão gênica e os níveis de alguns metabólitos do mutante atbzip63-2 indicaram que AtbZIP63 participa do controle da degradação do amido, pois a expressão de alguns genes centrais na degradação deste carboidrato de reserva está desregulada neste mutante. Mostramos que as oscilações no nível do transcrito AtbZIP63 são reguladas pelo relógio circadiano e a fase da oscilação do AtbZIP63 é aparentemente influenciada pela disponibilidade de carboidratos na célula. Além de estar sob o controle do relógio, AtbZIP63 também atua como um ativador direto da expressão de PRR7, que codifica um dos componentes chave do oscilador central do relógio. Portanto, evidenciamos uma interação recíproca entre o relógio e AtbZIP63 que possivelmente está impactando o processo de degradação do amido à noite. Este conjunto de evidências revela novos aspectos do ajuste do relógio circadiano pelo status de açúcar na célula que estão de acordo com trabalhos recentes mostrando que os açúcares afetam diretamente o funcionamento do relógio. Nossa hipótese é que o AtbZIP63 está agindo como um mediador entre a disponibilidade de viii açúcar e o mecanismo oscilatório do relógio circadiano de A. thaliana. Adicionalmente, verificamos que o perfil de transcritos no final do dia no mutante atbzip63-2 é diferente do observado no final da noite, sugerindo a participação do AtbZIP63 na regulação de genes envolvidos em redes regulatórias distintas em função do período do dia. Dentre os genes desregulados no atbzip63-2 no final do dia, observamos um enriquecimento para genes relacionados com metabolismo secundário e síntese de trealose, o que sugere a participação do AtbZIP63 na regulação da síntese destes compostos durante o dia, e possivelmente reflete a ocorrência de stress no mutante / Abstract: he Arabidopsis thaliana basic leucine zipper domain (bZIP) AtbZIP63 transcription factor is part of the response pathway to energy shortage coordinated by kinases KIN10/11. The T-DNA insertion mutant atbzip63-2 shows a reduction in the growth and development of leaves, as well as a delay in flowering compared to wild type (WT; ecotype Ws), when grown in short-day conditions. Long day or continuous light conditions promoted a partial or complete reversion, respectively, of the mutant to wild-type phenotype, raising the possibility that this phenotype is the result of an energy shortage. Plants silenced for AtbZIP63 showed similar characteristics to the atbzip63-2 mutant, confirming the involvement of this transcription factor in the growth. The gene expression profile and the levels of some metabolites of the atbzip63-2 indicated that AtbZIP63 takes part in the control of starch degradation, regulating the expression of some key genes in starch degradation. Diurnal AtbZIP63 mRNA level fluctuation is regulated by the circadian clock, and the phase oscillation is influenced by the availability of carbohydrates. In addition, to be controlled by the circadian clock, AtbZIP63 directly regulates the expression of PRR7 which encodes one of the key regulators of the core clock. We have therefore identified a reciprocal interaction between the clock and AtbZIP63 which is probably affecting the starch degradation process. This set of evidence reveals new aspects of the entrainment of the circadian clock by sugars, and is consistent with recent studies showing that sugars directly regulate the circadian clock. Our hypothesis is that AtbZIP63 is acting as a mediator between the energy status (availability of sugar) and the oscillatory mechanism of the A. thaliana circadian clock. Additionally, we found that the profile of transcripts at the end of the day in atbzip63-2 mutant is different from that observed in the end of the night, suggesting the involvement of AtbZIP63 in the regulation of genes involved in distinct regulatory networks according to the period of day. Among the genes deregulated in atbzip63-2 at the end of the x day, an enrichment for genes related to secondary metabolism and trehalose biosynthesis was observed. Suggesting the involvement of AtbZIP63 in regulating the synthesis of these compounds during the day, and probably reflects the occurrence of stress in the mutant / Doutorado / Genetica Vegetal e Melhoramento / Doutor em Genetica e Biologia Molecular

Arabidopsis

Amido - Degradação

Relógios circadianos

Arabidopsis

Starch - Degradation

Circadian clocks