Dissertations / Theses on the topic 'Molekuläre Systematik'

The group of pleurocarpous mosses comprises approximately 5000 species, which corresponds to about half of all mosses. The pleurocarpous mosses (i.e. “the Core Pleurocarps”) form a monophylum, which consists typically of perennial mosses with creeping stems and abundant lateral branches. In pleurocarpous mosses the archegonium and thus also sporophyte development is restricted to the apices of short, specialized lateral branches, in contrast to most other mosses, where archegonia and sporophytes develop terminally on the main axis (acrocarpous) or on major branches (cladocarpous). Traditionally, pleurocarpous mosses have been divided into three orders based mainly on their sporophytic characters. Brotherus described the Neckeraceae in 1925 and placed it into the Leucodontales, later the family has alternatively been divided into two or three separate families: the Thamnobryaceae, the Neckeraceae and the Leptodontaceae. These families have been placed even in different orders (Neckeraceae and Leptodontaceae among the leucodontalean mosses and Thamnobryaceae among hypnalean mosses) according to their peristome structure and the grade of peristome reduction. A growing amount of evidence indicates that a grouping based on sporophytic characters is artificial and based on convergent evolution. According to the latest phylogenetic studies of pleurocarpous mosses, based on molecular data, the Neckeraceae belong to the order Hypnales and share a sister group relationship with the Lembophyllaceae. In the most recent comprehensive classification 28 genera were included in the Neckeraceae family. This classification was based on both morphological and molecular data, but done with limited taxon sampling that did not cover all species of the family. Some previous studies based on molecular data have challenged the family concept of the Neckeraceae, indicating the need for a revision of the family. Here the family concept of the Neckeraceae is revisited, the closest relatives of the family are resolved and its position within pleurocarpous mosses is shown. In addition, new insights into the morphological evolution of the family are provided. Previous phylogenetic studies indicated that branch lengths among pleurocarpous mosses are usually extremely short. Therefore we chose to use mainly non-coding DNA sequences from rapidly evolving DNA regions. The phylogenetic reconstructions are based on extensive sequence data from all genomes: plastid trnS-trnF and rpl16, nuclear ITS1 & 2 and mitochondrial nad5. Both parsimony (PAUP and PRAP2) and Bayesian statistics (MrBayes) were employed for phylogenetic reconstructions. In order to use the information provided by length mutations indels were included in the analyses as binary data using a simple indel coding approach. No severe conflicts appeared between the different methods used, but the indel coding affected the support values of the inferred topologies. Therefore, all support values resulting from different methods are shown along the phylogenetic trees. The morphological features are studied and synapomorphies for each clade formed in the phylogenetic analyses are interpreted. A new delimitation of the family makes it necessary to reconsider the relevance of the morphological description and the morphological features characteristic of the family need to be reconsidered. Due to new groupings, some changes in the morphological circumscriptions of the genera are necessary, resulting in two new genera and several new combinations. Chapter 1 gives a broad overview of the relationships of the pleurocarpous mosses and shows the need for changes in the definition of genera, families and the corresponding nomenclature in this group. Chapter 2 is a population genetic study on the genus Thamnobryum. The main aim of this chapter is to test the species concept in Thamnobryum that are endemic to strictly restricted regions showing only minor differences in the morphological features in comparison to some more common species. In Chapter 3 the monophyly of the Neckeraceae is tested. In addition, in this chapter the ancestral character states of some morphological characters within the Neckeraceae are reconstructed. Chapters 4 and 5 resolve the genus composition and the relationships within the family in more detail. The results of this thesis show that the Neckeraceae need re-circumscription; this includes changes in the genus composition. The Lembophyllaceae is confirmed to be the sister group of the Neckeraceae. In addition to the new phylogeny, the potential evolution of several characters as a result of environmental selection pressures is analyzed. From the ancestral state reconstructions made (using BayesTraits) for both the habitat and a selection of morphological characters, character state distributions and habitat shift appear congruent, peristome reduction being a good example. However, some character states do not correlate with the habitat, suggesting very complex evolutionary patterns underlying these morphological characters. Many widely distributed genera that are composed of several species and seem to be morphologically coherent (Echinodium, Homalia, Thamnobryum, partly Neckera), are shown in this thesis to be polyphyletic. They are replaced by smaller, geographically more restricted genera that at least in some cases (e.g. Thamnomalia, Homalia s.str., Neckera s.str.) seem to form morphologically heterogeneous genera. In other words, morphology can be misleading in the family Neckeraceae even at the genus level and convergent evolution in both morphological and sequence level characters are common within the family. Special habitat conditions have been shown to result in similar morphological structures also in several other moss groups. This kind of convergent evolution occurs in aquatic mosses, and seems to have occurred among the neckeraceous species Thamnobryum alopecurum and its allies. However, similar morphological structure in similar aquatic habitats can also be due to true phylogenetic relationships as is the case within the Neckeraceae for Handeliobryum sikkimense and Hydrocryphae wardii, or the members of Touwia. The geographical grouping seems to be more strongly correlated with the phylogenetic grouping than thought before.

Dermatophyten sind keratinophile Pilze, d.h. sie besiedeln und infizieren die Haut und ihre Anhangsgebilde (Haare, Nägel) bei Mensch und Tier. Die derzeit häufigsten durch Dermatophyten hervorgerufenen Infektionen sind die Onychomykose, Tinea pedis, Tinea capitis und Tinea corporis. Da Antimykotika nicht bei alle Erregern von Dermatophytosen gleich wirksam sind, sollte im Vordergrund einer Behandlung zunächst die korrekte Erregerdifferenzierung stehen. Konventionell erfolgt diese Differenzierung über morphologische Merkmale wie Form und Farbe der auf dem Nährmedium gewachsenen Pilzkolonie, charakteristische mikromorphologische Elemente (Konidien) und biochemische Eigenschaften. Diese Merkmale werden jedoch oftmals nicht exprimiert. Damit ist in diesen Fällen keine Speziesdiagnose möglich. Eine zuverlässige Diagnostik sollte zudem das natürliche Klassifizierungssystem direkt reflektieren. Die Studien zur molekularen Biodiversität innerhalb der Dermatophyten sollten deshalb zur Klärung evolutionärer, taxonomischer und populationsgenetischer Zusammenhänge bei den verschiedenen Spezies der Gattungen Arthroderma, Trichophyton, Microsporum und Epidermophyten beitragen und helfen, geeignete DNA-Marker für die Anwendung in der medizinischen Diagnostik zu finden und einzusetzen. Dazu wurden verschiedene Methoden und Zielsequenzen genutzt, wie die Sequezierung der internal transcribed spacer (ITS) Region der ribosomalen DNA, das PCR-Fingerprinting, single strand conformation polymorphism (SSCP) und amplified fragment length polymorphism (AFLP)-Analyse. Es wurden weit über 200 Stämme, die bisher ca. 100 verschiedenen Taxa zuzuordnen waren, analysiert. Die molekularen Studien zeigen, dass die phylogenetisch ältesten Dermatophytenspezies geophil sind und sich die wärmeliebenden, zoophilen Arten erst später durch Koevolution mit warmblütigen Tieren entwickelt haben. Die anthropophilen scheinen dagegen erst mit Entstehung des Menschen evolviert und demzufolge am jüngsten zu sein. Damit kann man ihre geringe Biodiversität und ihr verändertes pathogenetisches Verhalten erklären. Es konnte gezeigt werden, dass die molekularen Phylogenie der Spezies besser mit ihrer Ökologie und dem Krankheitsbild als mit morphologischen Eigenschaften übereinstimmt und dass etliche Dermatophytenspezies überklassifiziert sind. Aus diesem Grunde wurde eine neue Systematik vorgeschlagen. Für den Nachweis des häufigsten Erreger, Trichophyton rubrum wurde eine Gensonde entwickelt, die in der medizinischen Diagnostik einsetzbar ist.
Dermatophytes are keratinophilic fungi which colonise and infect skin, hair and nails of man and animals. The most common infections caused by dermatophytes are onychomycosis, tinea pedis, tinea capitis and tinea corporis. Antimycotics may have different spectra of activity even in related dermatophyte species. Therefore a correct species identification is necessary before onset of antifungal therapy. Conventionally, the identification of dermatophytes is performed by the use of morphological features, such as shape and colour of the colony, micromorphological characteristics (conidia) and biochemical properties. However, these characters may not be expressed and then identification down to the species level is frequently impossible. Reliable diagnostics directly reflects the natural system. Studies of biodiversity in dermatophytes should therefore focus on elucidation of the connection of evolution, taxonomy and population genetics of the species of the genera Arthroderma, Trichophyton, Microsporum and Epidermophyten and thus contribute to development of stable DNA markers to be applied in routine diagnostics. Several methods and targets were applied such as sequencing of the internal transcribed spacer region (ITS) of the ribosomal DNA, PCR fingerprinting, single strand conformation polymor phism (SSCP) and amplified fragment length polymorphism (AFLP) analysis. More than 200 strains belonging to about 100 dermatophyte taxa were analysed. Phylogenetically, the molecular data show the oldest dermatophyte species to be geophilic and subsequently co-evolved as zoophilic dermatophytes with warm blooded animals. In contrast, the anthropophilic dermatophytes are much younger as they evolved in association with humans. This hypothesis is supported by their low biodiversity and changing pathogenicity. The molecular data show correspondence between phylogeny of species and their ecology and clinical picture, rather than with morphological features. Many dermatophyte species were shown to be overclassified. A new systematic system was proposed. For the identification of Trichophyton rubrum, the most common dermatophyte species, an oligonucleotide probe was developed which is applicable in medical routine diagnostics.

Evolution of Piperales – matK gene and trnK intron sequence data reveal lineage specific resolution contrast. Piperales are one of the largest basal angiosperm orders with a nearly worldwide distribution. The order includes three species rich genera, Piper (ca. 1,000 species), Peperomia (ca. 1,500-1,700 species), and Aristolochia s. l. (ca. 500 species). Sequences of the matK gene and the non-coding trnK group II intron are analysed for a dense set of 105 taxa representing all families (except Hydnoraceae) and all generic segregates (except Euglypha within Aristolochiaceae) of Piperales. A large number of highly informative indels are found in the Piperales trnK/matK dataset. Within a narrow region approximately 500 nt downstream in the matK coding region (CDS), a length variable simple sequence repeat (SSR) expansion segment occurs, in which insertions and deletions have led to short frame-shifts. These are corrected shortly afterwards, resulting in a maximum of 6 amino acids being affected. Furthermore, additional non-functional matK copies were found in Zippelia begoniifolia, which can easily be discriminated from the functional open reading frame (ORF). The trnK/matK sequence data fully resolve relationships within Peperomia, whereas they are not effective within Piper. The resolution contrast is correlated with the rate heterogenity between those lineages. Parsimony, Bayesian and likelihood analyses result in virtually the same topology, and converge on the monophyly of Piperaceae and Saururaceae. Lactoris gains high support as sister to Aristolochiaceae subf. Aristolochioideae, but the different tree inference methods yield conflicting results with respect to the relationships of subfam. Asaroideae. In Piperaceae, a clade formed by the monotypic genus Zippelia and the small genus Manekia (=Sarcorhachis) is sister to the two large genera Piper and Peperomia. Systematics of pipevines – Combining morphological and fast-evolving molecular characters to investigate the relationships within subfamily Aristolochioideae (Aristolochiaceae) A combined phylogenetic analysis of the Aristolochioideae was conducted based on 72 morphological characters and molecular datasets (matK gene, trnK intron, trnL intron, trnL-trnF spacer). The analysis sampled 33 species as the ingroup, including two species of Thottea and 30 species of Aristolochia and the monotypic genus Euglypha, which represent all the infrageneric taxa formally described; Saruma henryi and Asarum caudatum were used as the outgroup. The results corroborate a sister-group relationship between Thottea and Aristolochia, and the paraphyly of Aristolochia with respect to Euglypha that consequently should be included into Aristolochia. Two of the three subgenera within Aristolochia (Isotrema and Pararistolochia) are shown to be monophyletic, whereas the signal obtained from the different datasets about the relationships within subg. Aristolochia is low and conflicting, resulting in collapsed or unsupported branches. The relationship between the New World and the Old World species of subgenus Aristolochia is conflictive because morphological data support these two groups as monophyletic, whereas molecular data show the monophyletic Old World species of Aristolochia nested within the New World species. A sister group relationship is proposed between A. lindneri and pentandrous species, which suggests that a group of five species from central and southern South America (including A. lindneri) could be monophyletic and sister to Aristolochia subsection Pentandrae, a monophyletic taxon consisting of about 35 species from southern USA, Mesoamerica, and the West Indies. Colonisation, phylogeography and evolution of endemism in Mediterranean Aristolochia (Aristolochiaceae). This study provides evidence for a multiple colonisation of the western Old World from Asian ancestors within Aristolochia section Diplolobus (subsection Aristolochia and Podanthemum). Within subsection Podanthemum it is assumed, that the colonisation of the African continent happened at least two times independently. In contrast, for subsection Aristolochia, a rapid morphological radiation in the Near East (or close to this area) with subsequent star like colonisation of the different current distribution areas, which is not paralleled on the molecular level, appears to be more likely. Phylogenetic tree reconstruction is unsupported for these clades, but most clades are highly supported as monophyletic. Interestingly the Mediterranean and temperate Eurasian species, which are morphologically distinct (A. pistolochia, A. clematitis) are not clustering within the main clades, but are independent lineages. Analogue, A. rigida a species from Somalia is well-supported sister to the subsection Aristolochia. Within subsection Podanthemum the colonisation event from an Asian ancestor is clearly traceable, whereas in subsection Aristolochia the path is not traceable, since the ancestors are extinct or not present in the connecting areas. Within the Mediterranean, Near East and Caucasian species of subsection Aristolochia two morphologically and biogeographically well supported groups can be identified: the Near East/Caucasian species and the West Mediterranean species. The previous groupings for the latter, based on morphological characters, could be substantiated only partly by our results. This study provides the first phylogeny of all West Mediterranean species. In addition an independent complex is established including some micro endemic species. The phylogenetic results are discussed with respect to biogeography, and morphology, to give a first insight into the radiation and colonisation of the genus Aristolochia in the Mediterranean region. Universal primers for a large cryptically simple cpDNA microsatellite region in Aristolochia. We provide a new and valuable marker to study species relationships and population genetics in order to trace evolutionary, ecological, and conservational aspects in the genus Aristolochia. Universal primers for amplification and subsequent sequencing of a chloroplast microsatellite locus inside the trnK intron are presented. Utility of the primers has been tested in 32 species representing all clades of Aristolochia, including population studies within the A. pallida complex, A. clusii and A. rotunda. The microsatellite region is characterized as a (AnTm)k repeat of 22–438 bp containing a combination of different repeats arranged as ‘cryptically simple’. Trapped! Pollination of Aristolochia pallida Willd. in the Mediterranean A first study of the pollination biology of a Mediterranean Aristolochia species in its natural habitat is presented. 183 flowers of Aristolochia pallida were investigated, which in total contained 73 arthropods, dominated by two groups of Diptera, Sciaridae (37%) and Phoridae (19%). However, only Phoridae are regarded as potential pollinators, since pollen has been found exclusively on the body surfaces of these insects. All Phoridae belong to the genus Megaselia and are recognised as four undescribed species. The measurements of flower and insect dimensions suggest that size is an important constrain for successful pollination: 1) the insects must have a definitive size for being able to enter the flower and 2) must be able to get in touch with the pollen. Only very few insect groups found in Aristolochia pallida fulfil these size requirements. However, size alone is not a sufficient constrain as too many fly species of the same size might be trapped but not function as pollinators. Instead, specific attraction is required as otherwise pollen is lost. Since all trapped Phoridae are males, a chemical attraction (pheromones) is proposed as an additional constrain. Since A. pallida flowers are protogynous, the record of Megaselia loaded with pollen found in a flower during its female stage proves that this insect must have been visited at least one different flower during its male stage before. Further on, this observation provides strong evidence that the flowers are cross-pollinated. All these factors indicate a highly specialised pollination of Aristolochia pallida by Megaselia species.

Evolution of Piperales – matK gene and trnK intron sequence data reveal lineage specific resolution contrast. Piperales are one of the largest basal angiosperm orders with a nearly worldwide distribution. The order includes three species rich genera, Piper (ca. 1,000 species), Peperomia (ca. 1,500-1,700 species), and Aristolochia s. l. (ca. 500 species). Sequences of the matK gene and the non-coding trnK group II intron are analysed for a dense set of 105 taxa representing all families (except Hydnoraceae) and all generic segregates (except Euglypha within Aristolochiaceae) of Piperales. A large number of highly informative indels are found in the Piperales trnK/matK dataset. Within a narrow region approximately 500 nt downstream in the matK coding region (CDS), a length variable simple sequence repeat (SSR) expansion segment occurs, in which insertions and deletions have led to short frame-shifts. These are corrected shortly afterwards, resulting in a maximum of 6 amino acids being affected. Furthermore, additional non-functional matK copies were found in Zippelia begoniifolia, which can easily be discriminated from the functional open reading frame (ORF). The trnK/matK sequence data fully resolve relationships within Peperomia, whereas they are not effective within Piper. The resolution contrast is correlated with the rate heterogenity between those lineages. Parsimony, Bayesian and likelihood analyses result in virtually the same topology, and converge on the monophyly of Piperaceae and Saururaceae. Lactoris gains high support as sister to Aristolochiaceae subf. Aristolochioideae, but the different tree inference methods yield conflicting results with respect to the relationships of subfam. Asaroideae. In Piperaceae, a clade formed by the monotypic genus Zippelia and the small genus Manekia (=Sarcorhachis) is sister to the two large genera Piper and Peperomia. Systematics of pipevines – Combining morphological and fast-evolving molecular characters to investigate the relationships within subfamily Aristolochioideae (Aristolochiaceae) A combined phylogenetic analysis of the Aristolochioideae was conducted based on 72 morphological characters and molecular datasets (matK gene, trnK intron, trnL intron, trnL-trnF spacer). The analysis sampled 33 species as the ingroup, including two species of Thottea and 30 species of Aristolochia and the monotypic genus Euglypha, which represent all the infrageneric taxa formally described; Saruma henryi and Asarum caudatum were used as the outgroup. The results corroborate a sister-group relationship between Thottea and Aristolochia, and the paraphyly of Aristolochia with respect to Euglypha that consequently should be included into Aristolochia. Two of the three subgenera within Aristolochia (Isotrema and Pararistolochia) are shown to be monophyletic, whereas the signal obtained from the different datasets about the relationships within subg. Aristolochia is low and conflicting, resulting in collapsed or unsupported branches. The relationship between the New World and the Old World species of subgenus Aristolochia is conflictive because morphological data support these two groups as monophyletic, whereas molecular data show the monophyletic Old World species of Aristolochia nested within the New World species. A sister group relationship is proposed between A. lindneri and pentandrous species, which suggests that a group of five species from central and southern South America (including A. lindneri) could be monophyletic and sister to Aristolochia subsection Pentandrae, a monophyletic taxon consisting of about 35 species from southern USA, Mesoamerica, and the West Indies. Colonisation, phylogeography and evolution of endemism in Mediterranean Aristolochia (Aristolochiaceae). This study provides evidence for a multiple colonisation of the western Old World from Asian ancestors within Aristolochia section Diplolobus (subsection Aristolochia and Podanthemum). Within subsection Podanthemum it is assumed, that the colonisation of the African continent happened at least two times independently. In contrast, for subsection Aristolochia, a rapid morphological radiation in the Near East (or close to this area) with subsequent star like colonisation of the different current distribution areas, which is not paralleled on the molecular level, appears to be more likely. Phylogenetic tree reconstruction is unsupported for these clades, but most clades are highly supported as monophyletic. Interestingly the Mediterranean and temperate Eurasian species, which are morphologically distinct (A. pistolochia, A. clematitis) are not clustering within the main clades, but are independent lineages. Analogue, A. rigida a species from Somalia is well-supported sister to the subsection Aristolochia. Within subsection Podanthemum the colonisation event from an Asian ancestor is clearly traceable, whereas in subsection Aristolochia the path is not traceable, since the ancestors are extinct or not present in the connecting areas. Within the Mediterranean, Near East and Caucasian species of subsection Aristolochia two morphologically and biogeographically well supported groups can be identified: the Near East/Caucasian species and the West Mediterranean species. The previous groupings for the latter, based on morphological characters, could be substantiated only partly by our results. This study provides the first phylogeny of all West Mediterranean species. In addition an independent complex is established including some micro endemic species. The phylogenetic results are discussed with respect to biogeography, and morphology, to give a first insight into the radiation and colonisation of the genus Aristolochia in the Mediterranean region. Universal primers for a large cryptically simple cpDNA microsatellite region in Aristolochia. We provide a new and valuable marker to study species relationships and population genetics in order to trace evolutionary, ecological, and conservational aspects in the genus Aristolochia. Universal primers for amplification and subsequent sequencing of a chloroplast microsatellite locus inside the trnK intron are presented. Utility of the primers has been tested in 32 species representing all clades of Aristolochia, including population studies within the A. pallida complex, A. clusii and A. rotunda. The microsatellite region is characterized as a (AnTm)k repeat of 22–438 bp containing a combination of different repeats arranged as ‘cryptically simple’. Trapped! Pollination of Aristolochia pallida Willd. in the Mediterranean A first study of the pollination biology of a Mediterranean Aristolochia species in its natural habitat is presented. 183 flowers of Aristolochia pallida were investigated, which in total contained 73 arthropods, dominated by two groups of Diptera, Sciaridae (37%) and Phoridae (19%). However, only Phoridae are regarded as potential pollinators, since pollen has been found exclusively on the body surfaces of these insects. All Phoridae belong to the genus Megaselia and are recognised as four undescribed species. The measurements of flower and insect dimensions suggest that size is an important constrain for successful pollination: 1) the insects must have a definitive size for being able to enter the flower and 2) must be able to get in touch with the pollen. Only very few insect groups found in Aristolochia pallida fulfil these size requirements. However, size alone is not a sufficient constrain as too many fly species of the same size might be trapped but not function as pollinators. Instead, specific attraction is required as otherwise pollen is lost. Since all trapped Phoridae are males, a chemical attraction (pheromones) is proposed as an additional constrain. Since A. pallida flowers are protogynous, the record of Megaselia loaded with pollen found in a flower during its female stage proves that this insect must have been visited at least one different flower during its male stage before. Further on, this observation provides strong evidence that the flowers are cross-pollinated. All these factors indicate a highly specialised pollination of Aristolochia pallida by Megaselia species.

Innerhalb der Arthropodensystematik sind die phylogenetischen Beziehungen der höheren Crustaceataxa seit langem von besonderen Interesse. Ziel dieser Arbeit ist die Rekonstruktion der phylogenetischen Verwandtschaftsverhältnisse mit Hilfe molekularer Datensätze für die Phyllopoda, die zusammen mit den Anostraca die Branchiopoda bilden und der Astacoidea (Astacida), einer Teilgruppe der Flusskrebse. Folgende molekulare Marker kamen zum Einsatz: 1) Für die Phyllopoda: Die 3. Domäne der mitochondrial codierten 12S rRNA, unter Berücksichtigung von Sekundärtrukturinformationen, das nukleare Gen EF-1 alpha und die Positionen von Introns im Gen EF-1 alpha. 2) Für die Astacoidea: Die 3. Domäne der 12S rRNA und das mitochondrial codierte Gen cox1. Durch die Wahl der molekularen Marker, die mit unterschiedlichen computerkladistischen Methoden ausgewertet wurden, konnten für die meisten Fragen eine eindeutige und im Fall der Astacoidea überraschende phylogenetische Aussage getroffen werden. Die gewonnenen Hypothesen werden ausführlich im Licht morphologischer Hypothesen diskutiert.
The phylogenetic relationships of the higher arthropod taxa are still of special interest. Especially the interrelationships of the different Crustacea taxa have long been debated. The focus of this investigation is to make a contribution to the phylogenies of two Crustacea taxa using molecular markers: The Phyllopoda which belong together with the Anostraca to the branchiopods, and of the Astacoidea, one of the two higher crayfish taxa (Astacida). The following molecular markers were used: 1) Phyllopoda: the 3rd domain of the mitochondrial encoded 12S rRNA taking into account informations of the secondary structure, the nuclear encoded proteingene EF-1 alpha and the positions of introns found in the coding region of EF-1 alpha. 2) Astacoidea: the 3rd domain of the 12S rRNA and the mitochondrial encoded proteingene cox1. The choice of the mentioned markers in combination with different computercladistical methods allowed to give a satisfying, and in the case of the Astacoidea a more surprising answer to most addressed phylogenetic questions. The gained hypotheses are then discussed in detail in the light of morphological features and hypotheses.

In dieser Arbeit wurde die progenetische Evolution der Dinophilidae innerhalb der Eunicida („Polychaeta“, Annelida) sowie der Ursprung weiterer vermutlich progenetischer Arten des Euniciden-Taxons „Dorvilleidae“ (Parapodrilus psammophilus und Microdorvillea sp. n.) mit Hilfe molekularer Daten untersucht. Ein etwa 1800 bp langer Abschnitt der 18S-rDNA wurde erfolgreich von den in Tabelle 1 aufgeführten Arten (s. S. 5-7), mit Ausnahme von Ophryotrocha puerilis und Pusillotrocha akessoni, sequenziert. Von der 28S-rDNA wurde ein etwa 2250 bp langer Abschnitt von Trilobodrilus heideri, Protodorvillea kefersteinii, Eunice sp. und Hyalinoecia tubicola sequenziert. Von den folgenden Arten wurden 488 bzw. 482 bp der CO I bestimmt: Rheomorpha neiswestonovae, Trilobodrilus axi, Trilobodrilus heideri, Ophryotrocha gracilis, Ophryotrocha puerilis, Protodorvillea kefersteinii, Schistomeringos rudolphi, Eunice sp., Marphysa sanguinea, Lumbrineris funchalensis, Hyalinoecia tubicola, Potamodrilus fluviatilis und Sabella crassicornis. Zusätzliche Sequenzen der 18S-rDNA, der 28S-rDNA und der CO I wurden der Datenbank GenBank entnommen. Weitere Sequenzen der 28S-rDNA und der CO I wurden freundlicherweise von Frau Jördens zur Verfügung gestellt. Vor den phylogenetischen Analysen wurden Bereiche unterschiedlicher Variabilität definiert. Unterschiede zwischen den Substitutions-, Transitions-, Transversions- und allgemeinen Mutationsraten sowohl untereinander als auch zwischen den Variabilitätsbereichen sowie Sättigungen wurden ermittelt. Das phylogenetische Signal wurde mittels Likelihood Mapping verdeutlicht. Phylogenetische Analysen der einzelnen Gene sowie in Kombination der beiden nukleären ribosomalen Gene und aller drei Gene wurden durchgeführt. Dabei wurden die Parsimonie-, die ML- und die Bayes´sche Analyse parallel angewendet. Soweit möglich wurden Signifikanztests durchgeführt. Die zum einen die beiden Hypothesen der Monophylie der Eunicida mit und ohne Dinophilidae gegeneinander und zum anderen die beste Lösung gegen diese beiden Hypothesen und die Hypothese einer Monophylie der Taxa der ehemaligen „Archiannelida“ verglichen. Die Voruntersuchungen an den Datensätzen der einzelnen Gene zeigen bei den drei Genen deutliche Unterschiede der Substitutionsraten sowohl zwischen den einzelnen Variabilitätsbereichen als auch untereinander. Die Muster in den beiden Genen der 28S‑rDNA und der 18S-rDNA sind sich relativ ähnlich, allerdings ist die 28S‑rDNA variabler. Die CO I unterscheidet sich deutlich von den beiden anderen Genen in ihrem Muster und in ihrer Variabilität. Es wurde in allen drei Analysen Substitutionsmodelle gewählt die diese Unterschiede adäquat berücksichtigten. In der ML- und der Bayes´schen Analyse wurden die Modelle mittels dem Programm Modeltest bzw. MrModeltest bestimmt. In den Analysen der einzelnen Gene zeichnet sich die 18S-rDNA für diese Fragestellungen durch die beste Auflösung aus. Dieses ist auf die niedrige Variabilität sowie die große Anzahl an OTUs zurückzuführen. Die 28S-rDNA ist in der Auflösung wesentlich besser als die CO I und etwa so gut wie die 18S-rDNA. Die CO I alleine ist für Fragestellungen, die die Phylogenie der höheren taxonomischen Einheiten der Polychaeten betreffen, nicht geeignet. Die Kombination meherer Gene führte ebenfalls zu einer Verbesserung der Auflösung. Dabei wird die Auflösung mit steigender Zahl der Gene besser. Auch in diesen Analysen unterstützen die „posterior probabilities“ mehr Gruppen mit signifikanten Werten und sind immer höher als die BS-Werte. Es konnte gezeigt werden, dass die Verwendung der besten Phylogenie der ML-Analyse als Startbaum in der Bayes´schen Analyse schneller und sicherer ins stabile optimale Gleichgewicht führt. Es wird daher empfohlen, diese Option wenigstens als Test für die Etablierung des stabilen optimalen Gleichgewichtes in zukünftigen Analysen zu verwenden. Die molekularen Daten lehnen eine nähere Verwandtschaft der Dinophilidae zu den Eunicida sowie zu den Taxa der ehemaligen „Archiannelida“ mit hoher Wahrscheinlichkeit, allerdings nicht signifikant, ab. Eine mögliche Verwandtschaft zu einem in die Analysen nicht eingegangenem Taxon der Eunicida kann nicht ausgeschlossen werden, da die Monophylie der Eunicida nur in den Analysen aller drei Gene bestätigt wird. Ebenfalls kann eine nähere Verwandtschaft der Dinophilidae zu einem anderen Taxon der „Polychaeta“ nicht mit signifikanter Unterstützung nachgewiesen werden. Da weder die molekularen noch die morphologischen Daten zurzeit eine eindeutige systematische Einordnung der Dinophilidae innerhalb der „Polychaeta“ erlauben, sollten die Dinophilidae wieder als eigenständiges Taxon innerhalb der „Polychaeta“ geführt und keinem anderen Taxon zugeordnet werden. Der progenetische Urspung der Dinophilidae ist aufgrund morphologischer Untersuchungen gut belegt. Die enge Verwandtschaft sowohl von Parapodrilus psammophilus als auch Microdorvillea sp. n. zu großen kiefertragenden Dorvilleiden mit polytrochen Larven wird mit signifikanten Werten in allen Analysen unterstützt. Die molekularen Daten unterstützen somit die vermutete progenetische Evolution von wenigstens Parapodrilus psammophilus. Dadurch dass die Dinophilidae mit hoher Wahrscheinlichkeit nicht in die „Dorvilleidae“ oder Eunicida eingeordnet werden können, ist auch die systematische Einordnung der Gattungen ohne muskulöses Pharynx-Organ (Apodotrocha und Apharyngtus) in die „Dorvilleidae“ nicht mehr mit eindeutiger Sicherheit gegeben. Sie wurden aufgrund der gleichen morphologischen Merkmale wie die Dinophilidae den „Dorvilleidae“ zu geordnet. Die molekular-phylogenetischen Analysen unterstützen nur in den kombinierten Analysen aller drei Gene die Monophylie der Eunicida. Dieser ist wahrscheinlich auf die „explosive Radiation“ dieses Taxons sowie der Taxa der Polychaeten im Allgemeinen zurückzuführen. Die nahe Verwandtschaft von Eunicidae und Onuphidae wird in allen Analysen, außer in denen mit der CO I, signifikant unterstützt. Die molekularen Daten unterstützen eine Monophylie der „Dorvilleidae“ nicht. Da der ctenognathe Kieferapparat der „Dorvilleidae“ sehr wahrscheinlich ein plesiomorphes Merkmal innerhalb der Eunicida ist, wird das Taxon auch morphologisch durch kein autapomorphes Merkmal charakterisiert. Die „Dorvilleidae“ sollten deshalb als parapyhletisch innerhalb der Eunicida betrachtet werden und mit Anführungsstrichen geführt werden. Die systematische Position der Histriobdellidae innerhalb der Eunicida kann basierend auf den Analysen der 18S-rDNA nicht eindeutig geklärt werden. Allerdings legt die Analyse, die eine Monophylie der Eunicida ohne Dinophilidae erzwingt, eine Verwandtschaft mit Ophryotrocha gracilis nahe. Zukünftige molekular-phylogenetische Analysen sowohl die Phylogenie der Annelida und im Besonderen der Eunicida als auch die systematische Einordnung der Dinophilidae betreffend sollten vor allem bei den Genen der 28S-rDNA und CO I noch mehr Taxa und Arten umfassen, um der geringen Auflösung der basalen Verzweigungen in allen Analysen und Problemen wie der „long branch attraction“ in zwei der Analysen mit der 28S-rDNA besser zu begegnen. Ferner sollte der Datensatz noch um andere Gene, wie zum Beispiel dem Elongationsfaktor 1a oder den Histonen, mit einer möglichst großen Zahl an Taxa erweitert werden.