Rozprawy doktorskie na temat „Myo-inositol 1”

To survive, an organism must constantly adjust its internal state to changes in the environment from which it receives signals. The signals set off a chain of events referred to signal transduction. Signal transduction systems are especially important in multicellular organisms, such as plants and animals, because of the need to coordinate the activities of hundreds to trillions of cells. Plants, in particular, have a special need for perceiving signals from their environment because of their static nature. As in the animal cell, the first steps in perception of a signal include signal interaction with a receptor, signal amplification through second messenger production, and signal termination through second messenger hydrolysis. Myo-inositol polyphosphate 5-phosphatases (5PTases) (EC 3.1.3.56) have unique signal terminating abilities toward the second messenger inositol trisphosphate (Ins (1,4,5)P3, InsP3). In Arabidopsis thaliana there are 15 members of the 5PTase family, the majority of which contain a single 5PTase catalytic domain. Four members of the Arabidopsis 5PTase family, however, have a unique protein domain structure, with additional N-terminal WD40 repeats that are implicated in protein-protein interactions. The research presented here focused on the identification of 5PTase interacting proteins and the characterization of their functional role in Arabidopsis. To accomplish this goal, I examined a 5PTase13-interacting protein, the sucrose (Suc) nonfermenting-1-related kinase, SnRK1.1, an important energy sensor that is highly conserved among eukaryotes. My identification of a 5PTase13:SnRK1.1 complex points to the novel interaction of this metabolic modulator and inositol signaling/metabolism. 5PTase13 , however, plays a regulatory role in other plant specific processes as well, since I also identified the Arabidopsis homolog (Atp80) of the human WDR48 (HsWDR48, Hsp80) as a novel protein interactor of 5PTase13. My results indicate that Atp80 is important for leaf emergence, development and senescence likely via a regulatory interaction with 5PTase13 and PINOID â binding protein (PBP1).<br>Ph. D.

CoordenaÃÃo de AperfeiÃoamento de NÃvel Superior<br>A Diabetes mellitus à uma doenÃa de causa mÃltipla, ocorrendo quando hà falta de insulina ou quando a mesma nÃo atua de forma eficaz, causando um aumento da taxa de glicose no sangue (hiperglicemia). Ainda nÃo se sabe precisamente o mecanismo de aÃÃo da insulina, alguns trabalhos sugerem que pode ser possivelmente mediado atravÃs do fosfoglicano inositol (IPGs), cujas algumas formas foram identificadas como: mioinositol e D-quiroinositol. Hà estudos que relacionam a reduÃÃo da glicemia em indivÃduos diabÃticos com o aparecimento desses inositÃis nas secreÃÃes corpÃreas, embora ainda nÃo haja registro de identificaÃÃo dessas molÃculas na composiÃÃo salivar. O objetivo deste estudo foi determinar a relaÃÃo salivar do mioinositol e quiroinositol em crianÃas com diabetes tipo 1 e comparar a presenÃa e concentraÃÃo dessas substÃncias com um grupo de crianÃas sadias (nÃo diabÃticas). Um total de 45 (quarenta e cinco) voluntÃrios, 25 com diabetes tipo 1 descompensados e 20 sadios (nÃo diabÃticos), de ambos os sexos, com idades de 3 a 12 anos, foram selecionados e convidados a participar do estudo. Amostras de saliva foram coletadas e centrifugadas. Os sobrenadantes foram separados, liofilizados e purificados. Logo em seguida, foram analisados por cromatografia lÃquida de alta eficiÃncia (HPLC) para a identificaÃÃo do mioinositol e quiroinositol. A partir dessa anÃlise, foi observado uma menor concentraÃÃo de quiroinositol (p=0,001, Kruskal- Wallis ANOVA seguido por mÃtodo de Dunnâs) e uma maior da concentraÃÃo de mioinositol (p=0,001, Kruskal- Wallis ANOVA seguido por mÃtodo de Dunnâs) nas crianÃas afetadas em comparaÃÃo com as crianÃas saudÃveis. Os pacientes com diabetes tiveram a razÃo mio/quiroinositol maior que do grupo controle (p=0,001, Kruskal- Wallis ANOVA seguido por mÃtodo de Dunnâs) e apresentaram uma correlaÃÃo entre sua proporÃÃo o DM1(p= 0,001). O resultado desse estudo sugere que o mioinositol e o quiroinositol encontrado na saliva de crianÃas com DM1 podem influenciar no controle metabÃlico e desempenhar um papel de marcadores da DM1.<br>Diabetes mellitus is a disease of multiples causes that occurs either when the pancreas does not produce enough insulin or when the body cannot effectively use the insulin it produces, causing a rise in blood glucose levels (hyperglycemia). It is not clear the action mechanism of insulin but it has been suggested that inositol phosphoglicans, such as myoinositol and D-chiro-inositol, can be important secondary messengers in insulin signal transduction. Although there are some studies linking a reduction in blood glucose levels in diabetic patients with the presence of these inositols in body secretions, there are not reports about the presence of these molecules in salivary composition. Thus, this study aimed to determinate the myoinositol and D-chiro-inositol salivary relation in children with type 1 diabetes and to compare the presence and concentration of these molecules with healthy children (non-diabetic). It has been selected and invited 45 volunteers of both sexes aged 3-12 years, 25 with decompensate type 1 diabetes and 20 healthy children. Saliva samples were collected and centrifuged. The supernatants were separated, purified and lyophilized. The identification of myoinositol and D-chiro-inositol were carried out by means of high-performance liquid chromatography (HPLC). The results showed that children with type 1 diabetes have a lower concentration of D-chiro-inositol and a higher concentration of myoinositol than healthy children. Consequently, the myo/chiro-inositol rate was higher in type 1 diabetes children and there is a correlation between the rate and type 1 diabetes incidence. In conclusion, our data suggests that myoinositol and chiroinositol found in the saliva of children with type 1 diabetes may influence in metabolic control and plays an important role as markers of type 1 diabetes.

Myo-inositol is ubiquitous in nature and is found at the structural core of a diverse range of biologically important derivatives, including phosphatidylinositols, inositol phosphates and mycothiol. The synthesis of myo-inositol derivatives is notoriously difficult due to the need to control both regio- and enantioselectivity. As a result, synthetic routes to derivatives of this type are often lengthy and low yielding. The first biosynthetic step in the production of all myo-inositol metabolites is the isomerisation of D-glucose 6- phosphate to L-myo-inositol 1-phosphate as mediated by L-myo-inositol 1-phosphate synthase (INO1). For the protozoan parasite Trypanosoma brucei, INO1 is essential for survival and its version of the enzyme (TbINO1) has a high turnover. This makes TbINO1 an attractive candidate for the biocatalytic production of L-myo-inositol 1- phosphate, and a potential starting point for drastically shortened syntheses of important myo-inositol derivatives. The production of L-myo-inositol 1-phosphate by TbINO1 has been optimised to achieve complete conversion in reaction conditions that facilitate product isolation. Due to problems with an in-batch process, the TbINO1 enzyme was immobilised and the process was transferred to a flow system. This has allowed for production of significant quantities of L-myo-inositol 1-phosphate with a high level of purity. L-myo-inositol 1- phosphate obtained from the flow system has been used to prepare mycothiol glycosylation acceptor, 1,2,4,5,6-penta-O-acetyl-D-myo-inositol, in a concise synthesis with a greatly improved yield over the literature.

Includes bibliographical references.<br>Myo-inositol I-phosphate synthase (INO 1) catalyses the conversion of glucose-6-phosphate to myo-inositol I-phosphate, which is subsequently dephosphorylated to myo-inositol. Myo-inositol is a precursor for a number of important metabolites that include membrane components, storage molecules, phytohormones and a variety of osmoprotectants. Xerophyta viscosa Baker (Family Velloziaceae) is a monocotyledonous angiosperm which has the ability to resume full physiological function after desiccation. The full-length cDNA for INO1 from X viscosa was isolated using the RACE technique.

Un procede original de syntheses de myo-inositol phosphates a ete mis au point permettant d'obtenir en une seule preparation plusieurs myo-inositol phosphates a la fois. On fait reagir le myo-inositol avec un dioxa-2,8 aza-5 phospha-1 bicyclo(3. 3. 0) octane. Quand la phosphoranylation est totale on obtient les myo-inositol mono, bis, tris, tetrakis phosphates

The objective of this research was to isolate and characterize soybean genes involved in phytic acid metabolism for use in genetic engineering strategies to improve phosphorus utilization. A soybean phytase from germinated cotyledons was purified 28,000-fold to apparent homogeneity and was determined to be a glycosylated homodimer with 70 kD subunits. Soybean phytase preferred phytate as substrate (Km = 60 mM) and was capable of removing of all six phosphate groups from phytate. The pH and temperature optima for soybean phytase activity were 4.5 and 58*C, respectively. The N-terminus and four internal peptides from the purified soybean phytase were sequenced by Edman degradation. The amino acid sequence data were used to design degenerate oligonucleotide primers for PCR amplification of the soybean phytase coding sequence. A protein 547 amino acids in length was predicted from the 1641 bp coding sequence. The phytase protein showed significant similarity to plant purple acid phosphatases (PAPs) and contained the conserved metallo-phosphomonoesterase active site motif. The soybean phytase coding sequence was placed under the control of a constitutive 35S CaMV promoter in a soybean biolistic transformation vector and was introduced into "Williams 82" suspension culture cells by particle bombardment. Stably transformed cell suspension lines were recovered. DNA blot analysis demonstrated that the recombinant soybean phytase coding sequence had integrated into the genomes of two cell lines. Expression of the transgene was confirmed by RNA blot analysis. Phytase activity was three to four fold higher in these two lines compared to control non-transformed cultures. A soybean L-myo-insoitol-1-phosphate synthase (MIPS) cDNA was isolated from total RNA from developing seeds. The protein encoded by the soybean MIPS cDNA showed 87-91% homology to MIPS protein sequences from other plant species. RNA blot analysis of staged developing soybean seeds revealed that MIPS is transcribed early in the cotyledonary stage of development. Compared to other soybean tissues, MIPS expression levels were highest in developing seeds. DNA blot analysis demonstrated that multiple copies of the MIPS gene are present within the soybean genome.<br>Ph. D.

Ziele: Mittels absolutquantifizierender Protonen-Magnet-Resonanz-Spektroskopie (1H-MRS) wollten wir das Ergebnis einer Vorstudie bestätigen, die im Frontallappen einen reduzierten Quotienten von myo-Inositol/Gesamtcreatin (mI/tCr) bei Depressiven fand. Darüber hinaus testeten wir den antidepressiven Effekt von Inositol als Add-on-Therapie. Methodik: Wir untersuchten Einzelvoxel (2 x 2 x 2 cm3) in der weißen Substanz der rechten und linken Präfrontalregion mit Hilfe eines 3-Tesla Bruker Medspec Systems (STEAM Sequenz, TR/TE/TM = 6000/20/30 ms). Die einzelnen Metabolite wurden anhand des cerebralen Wassers als internem Standard quantifiziert (nach dem LCModell). Es wurden 24 unmedizierte Patienten mit unipolaren depressiven Episoden mit 24 alters- und geschlechtsgematchten gesunden Kontrollen verglichen. In doppelblindem, Plazebo-kontrollierten Parallelgruppen-Design erhielten die Patienten täglich 18 Gramm Inositol oder Plazebo zusätzlich zu Citalopram über vier Wochen. Ergebnisse: An der Baseline unterschieden sich die mI-, Cholin- und N-Acetyl-Aspartat-Konzentrationen der Patienten nicht von jenen der Kontrollen. Es fanden sich keine sich keine signifikanten Unterschiede zwischen Inositol- und Plazebo-Gruppe. Überraschenderweise zeigten die depressiven Patienten an der Baseline gegenüber den Kontrollen signifikant höhere tCr-Konzentrationen (mmol/kg) links (5,57 ± 0,96 vs. 4,87 ± 0,63; + 15 %, p < 0,01) und rechts präfrontal (5,29 ± 0,92 vs. 4,46 ± 0,41; + 17 %, p < 0,01). Nach der Behandlung ergab sich eine Reduktion der tCr-Konzentration links- (Tag 28: 5,05 ± 1,16; – 12 %, p = 0,08) und rechtsfrontal (Tag 28: 4,61 ± 1,07; – 9 %, p = 0,09). Die tCr-Konzentrationen der Patienten am Tag 28 unterschieden sich nicht mehr von jenen der Kontrollen. Zusammenfassung: Wir zeigten eine reversible Steigerung der tCr-Konzentration der Patienten im Vergleich zu Kontrollen, die auf Veränderungen des Creatin-Transports oder der ATP-Synthese bei unmedizierter unipolarer Depression hinweisen könnte.<br>Objectives: By means of proton magnetic resonance spectroscopy (1H-MRS) with absolute quantification we wanted to confirm our previous finding of decreased ratios of the metabolites myo-Inositol/total creatine (mI/tCr) in the right frontal brain of depressives. Moreover, we tested the antidepressive effect of oral Inositol ingestion as add-on-therapy. We measured concentrations (mmol/kg ww) of mI, tCr (= Creatine + Phosphocreatine), Choline (Cho) and N-Acetyl-Aspartate (NAA) in the frontal brain. Methods: Single voxels (2x2x2 cm3) in the white matter of the left and right prefrontal region were examined in a three Tesla Bruker Medspec System (STEAM sequence, TR/TE/TM = 6000/20/30 ms). Metabolites were quantified using the LCModel. At baseline, 24 drug-free patients with unipolar depressive episodes were compared to 24 age and sex matched healthy controls. In a double blind, placebo controlled parallel-group design patients received daily 18 grams Inositol or placebo as an add on therapy to Citalopram over four weeks. Results: At baseline, mI, Cho and NAA concentrations showed no significant differences between patients and controls. The treatment with Inositol did not result in any significant differences to the treatment with placebo. Surprisingly the patients showed significant higher tCr concentrations in the left (5.57 ± 0.96 vs. 4.87 ± 0.63; + 15 %, p < 0.01) as well as in the right prefrontal region (5.29 ± 0.92 vs. 4.46 ± 0.41; + 17 %, p < 0.01) compared to controls. The treatment caused a trend towards a decrease of tCr in the left (day 28: 5.05 ± 1.16; – 12 %, p = 0.08) and in the right frontal hemisphere (day 28: 4.61 ± 1.07; – 9 %, p = 0.09) compared to baseline. The differences between the patients’ tCr at day 28 and the tCr of controls were no more significant. Conclusion: We have found a state dependent increase of tCr concentration indicating bifrontal deviations in Creatine transport or ATP synthesis in drug free unipolar depressives.

碩士<br>國立成功大學<br>生物學系碩博士班<br>91<br>The MIPS (myo-inositol-1-phosphate synthase)enzyme plays an important physiological role in organisms, catalyzing D-glucose 6-phosphate to MI-1-P (myo-inositol-1-phosphate) that participates many development processes. The genetic analysis of AtMIPS1 gene of Arabidopsis thaliana and examination of its function in embryogenesis were perfomed. The seeds of mips1 mutant, generated by T-DNA were provided by NASC. Using scanning electron microscopy and light microscopy to observe seed morphology, the cell arrangement of seed coat was abnormal and failed to develop to mature embryo. Another mips1 mutant had the different Salk number which obtained from SIGnAL with the same phenotype, proved that the mutant seeds were also caused by the mutation of AtMIPS1 gene. Southern blotting of genomic DNA with AtMIPS1 coding region suggested that AtMIPS1 was a single copy gene in Arabidopsis thaliana. To determine the genotype of mutant seeds, seeds from siliques of normal phenotype T3 plant that cultivated from the normal seeds of T2 plants which had mips1 mutant were collected. The ratio of normal seeds to mutant seeds in each silique were close to 3:1 (X2 = 3.841, P < 0.05), fitting to the law of segregation. This result confirmed that the genotype of normal and mutant seeds in siliques were MIPS1/MIPS1(or MIPS1/mips1) and mips1/mips1, respectively. T2 plant were further allowed to self-pollinate, pollens from plant which had mutant seeds cross to wild type serving as maternal parents. The presence of mutant seeds in siliques from hybriding plants indicated that mips1 was transmitted by pollens. In development processes, the embryo of mutant seed which occurred variants during the stage of globular to heart embryo was observed by using light microscopy. The phenomenon of non-suspensor in mutant heart embryo may be caused by the wrong direction of cell division in embryogenesis. The AtMIPS1 promoter::GUS expression was detected only in embryo. These results suggest that AtMIPS1 gene may play a critical role in embryo development of Arabidopsis thaliana.