Abstract Drug metabolite profiling and identification studies are nowadays regularly conducted with liquid chromatography (LC) coupled with mass spectrometry (MS) as an analytical tool. The speed, selectivity and sensitivity of modern LC–MS instruments have been significantly increased in recent years. Especially the use of ultra-high-performance LC (UHPLC) in combination with a modern high-resolution MS instrument offers high full scan detection sensitivity, mass accuracy and the detection of both expected and unexpected metabolites in a single LC–MS run. The present study showed that no single LC–MS conditions were suitable for the analysis of a large group of structurally diverse compounds. The testing of optimum conditions for each individual compound led to more high-quality data when chromatographic retention behavior and mass spectrometric ionization efficiency for in vitro metabolite profiling were considered. The developed LC–MS methods were applicable for measuring both the disappearance of the parent compound and the formation of metabolites. Tentative metabolite identification was based on the measured accurate mass time-of-flight (TOF) MS data. In the second part, a rapid and sensitive assay was designed and built for the trapping, screening and characterization of reactive metabolites in vitro. In total, 78 trapped reactive metabolite conjugates were detected and identified based on accurate mass data using 12 structurally different test compounds. The majority of the detected conjugates were reported for the first time. Amine-containing compounds, that formed methylated and cyanide-trapped products after CYP-mediated reaction steps in human liver microsomal (HLM) incubations, were studied further. The observed methylated cyano conjugates were shown to be experimental artifacts, i.e., metabonates. The study also describes the use of traditional high-performance LC (HPLC) and the more modern UHPLC coupled to time-of-flight, triple quadrupole and hybrid linear ion trap mass spectrometers in drug metabolism studies, and reviews on how to choose the most suitable LC–MS system for metabolite profiling purposes in drug discovery and early drug development.

Tiivistelmä Nestekromatografia (LC) yhdistettynä massaspektrometriaan (MS) on nykyaikana yleisesti käytetty analyysimenetelmä lääkeaineiden aineenvaihduntatuotteiden (metaboliittien) havaitsemisessa ja tunnistamisessa. Modernien LC–MS -laitteiden nopeus, selektiivisyys ja herkkyys ovat merkittävästi parantuneet viime vuosina. Käytettäessä ultrakorkean suorituskyvyn nestekromatografia (UHPLC) yhdessä nykyaikaisen korkean massaresoluution MS-laitteen kanssa on mahdollista havaita kaikki sekä odotetut että odottamattomat metaboliitit yhdellä kertaa. Tutkimalla suurta joukkoa rakenteellisesti erilaisia yhdisteitä voitiin todeta, että yksittäiselle yhdisteelle optimoidut mittausolosuhteet johtivat korkealaatuisempaan dataan kuin yleiset ei-optimoidut olosuhteet, kun arvioitiin sekä kromatografista piikin profiilia ja pidättymistä että…

Abstract To date, plant endophytic bacteria have mainly been studied in roots of crop plants. However, shoot-associated endophytes are less diverse than root-associated ones. Hence, endophytic bacteria of plant shoots evolved different traits, than root colonizers, especially with types of host tissues infected and patterns of growth and development. This study found Methylobacterium extorquens colonized pine seedlings similarly to stem-colonizing rhizobia of other plants. M. extorquens DSM13060 was isolated from meristematic cells in shoot tip cultures of Scots pine (Pinus sylvestris L.). M. extorquens infected the plant stem through epidermis or stomatal apertures, forming infection pockets in the root and stem epidermis, or cortex. Post-infection, thread-like infection structures passed through the endoderm, invading vascular tissues. This led to systemic colonization of above and below ground-parts, observed in in vitro grown Scots pine. A novel mechanism enabling development of endophyte-host symbiosis is discovered within the M. extorquens – Scots pine model. This mechanism involves ability of M. extorquens to produce polyhydroxybutyrates (PHB) to protect itself from host-induced oxidative stress during infection. Upon initial colonization on the host surface, M. extorquens DSM13060 consumes methanol as a carbon source, using it to biosynthesize PHB. PHB are then degraded, upon host infection, by PHB depolymerases (PhaZ) to yield methyl-esterified 3-hydroxybutyrate oligomers. These oligomers have substantial antioxidant activity towards host-induced oxidative stress, enabling the bacterium to bypass host defenses and colonize further tissues. The bacteria can also store PHBs for future protection. The capacity for PHB production and, thus, protection from oxidative stress, is discovered in a wide taxonomic range of bacteria. This study also shows meristematic endophytes are important in growth and development of their hosts. Unlike many bacterial root endophytes, M. extorquens DSM13060 does not induce plant growth through hormones. However, this bacterium can colonize the interior of living host cells, where it aggregates around the nucleus of the host plant. M. extorquens DSM13060 genome encodes nucleomodulins, eukaryotic-like transcription factors, which may intervene in host transcription and metabolism.

Tiivistelmä Kasvin sisällä elävien endofyyttisten bakteerien tutkimus on perinteisesti keskittynyt viljelykasveihin ja niiden juuristoon. Kasvien maanpäällisissä versoissa elävät endofyytit eroavat merkittävästi juuriston bakteereista lajirikkauden suhteen. Versoissa eläville bakteereille on todennäköisesti kehittynyt erilaisia sopeumia kuin juuriston endofyyttilajeille. Endofyyttinen Methylobacterium extorquens DSM13060 elää männyn silmujen kasvusolukossa lisäten isäntäkasvin kasvua. Tässä tutkimuksessa M. extorquens –bakteerin todettiin siirtyvän männyn taimiin samoja mekanismeja käyttäen kuin Rhizobium –suvun typensitojabakteerit. Metylobakteeri tunkeutui isäntäkasviin aktiivisesti soluseinien läpi…

Abstract Reactive metabolites are believed to be responsible for rare but serious idiosyncratic adverse drug reactions (IADRs) that have led to the withdrawal of numerous drugs from the market. This has resulted in major harm to patients, economic losses for the pharmaceutical companies and represents a serious problem in drug development. Reactive metabolites can be studied by trapping them with suitable nucleophiles, most commonly with glutathione. The glutathione conjugates formed in these reactions can be analyzed with liquid chromatography mass spectrometry (LC/MS) techniques. In this study, new in vitro methods for the detection and analysis of reactive metabolites were developed. The suitability for reactive metabolite screening of different enzyme sources commonly used in vitro were compared. It was found that sub-cellular fractions yielded significantly larger amounts of glutathione-trapped reactive metabolites as compared to the amounts obtained from intact hepatocytes. Additionally, different metabolites were detected in some cases. Biomimetic metalloporphyrin catalysts were tested for their ability to produce larger amounts of glutathione-trapped metabolites relative to liver S9 fraction incubations. An increase in reactive metabolite production was observed with biomimetic models, but not all of the metabolites produced by liver S9 were observed. The glutathione conjugates of pulegone and of its metabolite menthofuran were analyzed with LC/MS/MS, and the fragmentation spectra of N- and S-/N- di-linked glutathione conjugate were interpreted in detail for the first time. These results will enable more efficient screening of reactive metabolites of furan-containing compounds. Acyl glucuronides are metabolites produced from carboxylic acid-containing compounds and can be reactive. A good correlation was found between the acyl migration half-life and the tendency of a drug to cause IADRs. The carboxylic moiety can also be metabolized to yield acyl coenzyme A (CoA) conjugates that may be more reactive than their corresponding acyl glucuronides. The formation of CoA conjugates and additional conjugates formed from them was found to be more likely with drugs that cause IADRs.

Tiivistelmä Reaktiivisten metaboliittien uskotaan olevan syypää tietyntyyppisiin harvinaisiin, mutta vakaviin idiosynkraattisiin lääkehaittavaikutuksiin, jotka ovat johtaneet useiden lääkeaineiden poistamiseen markkinoilta. Ne ovat aiheuttaneet merkittäviä haittoja potilaille, tappioita lääkeyhtiöille ja ovat vakava ongelma lääkekehityksessä. Reaktiivisia metaboliitteja voidaan tutkia vangitsemalla niitä sopivilla nukleofiileillä, yleisimmin glutationilla. Muodostuneet glutationikonjugaatit voidaan sitten analysoida nestekromatografia / massaspektrometrisin tekniikoin. Tässä tutkimuksessa kehitettiin uusia in vitro tapoja havaita ja analysoida reaktiivisia metaboliitteja. Tavallisimmin käytettyjen entsyymilähteiden soveltuvuutta testattiin reaktiivisten metaboliittien seulontaan. Solufraktioiden havaittiin tuottavan huomattavasti…

Abstract Liquid chromatography (LC) combined with mass spectrometry (MS) is one of the most widely used techniques in modern analytical laboratories. Remarkable developments during the two previous decades in both techniques has made LC-MS the method of choice in various environmental, pharmaceutical and biochemical laboratories due to selectivity, sensitivity and versatility. The main focuses in this study were to develop new LC-MS methods to identify and quantify phenolic secondary metabolites in bilberry, lingonberry and hybrid bilberry, to study the biosynthesis of the main secondary metabolites (hypericin and hyperforin and their derivatives) in St John’s wort (SJW) both in vitro and in vivo (in plant), to identify in vitro metabolites of hyperforin in human liver microsomes and to identify the cytochrome P450 (CYP) enzymes responsible for their formation. Both high-performance liquid chromatography (HPLC) and ultra high-performance liquid chromatography (U-HPLC) in combination with time-of-flight (TOF) and triple quadrupole (QqQ) mass spectrometry were used in this study. Identification of 52 phenolic compounds from the leaves of bilberry, lingonberry and hybrid bilberry was accomplished. In total, seven of the identified compounds were reported for the first time in Vaccinium plants and several other compounds were reported for the first time in the studied plants. Incorporation of valine and isoleucine into acyl side chains of phloroglucinols (hyperforin and adhyperforin) via biosynthesis in shoot cultures of SJW was confirmed by using isotopically labeled amino acids and HPLC-MS/MS. Also, 29 biosynthetic in vitro products for HpPKS2 enzyme originating from SJW were identified based on accurate mass data. The metabolism of hyperforin was studied in human liver microsomes (HLM) for the first time. 57 metabolites for hyperforin were identified in the incubations with HLMs, using a substrate concentration of 1 μM. The phase I metabolism of hyperforin was suggested to rely mainly on CYP3A4 and on CYP2C family.

Tiivistelmä Nestekromatografia (LC) yhdistettynä massaspektrometriaan (MS) on yksi eniten käytetyistä analyysimenetelmistä nykyaikaisissa analytiikkalaboratorioissa. Viimeisten parin vuosikymmenen aikana LC-MS -laitteet ovat kehittyneet merkittävästi, ja nykyään LC-MS onkin paras menetelmä moniin ympäristö-, lääkeaine- ja biokemiallisiin laboratorioihin sen selektiivisyyden, herkkyyden ja monipuolisuuden vuoksi. Tässä väitöskirjassa kehitettiin uusia LC-MS –menetelmiä mustikan, puolukan ja mustikkapuolukan fenolisten sekundäärimetaboliittien tunnistamiseksi ja kvantitoimiseksi, mäkikuisman pääasiallisten sekundäärimetaboliittien (hyperisiini, hyperforiini ja niiden johdannaiset) tutkimiseksi in vitro- ja kasvinäytteistä sekä hyperforiinin aineenvaihduntatuotteiden tunnistamiseksi ja niitä muodostavien sytokromi P450 (CYP) entsyymien tunnistamiseksi ihmisen maksamikrosomeissa in vitro -menetelmin. Tässä työssä käytettiin sekä korkean erotuskyvyn nestekromatografia (HPLC) että ultra-korkean…