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The evolution of neuronal progenitor cell division in mammals: The role of the abnormal spindle-like microcephaly associated (Aspm) protein and epithelial cell polarityFish, Jennifer 19 July 2007 (has links) (PDF)
Among mammals, primates are exceptional for their large brain size relative to body size. Relative brain size, or encephalization, is particularly striking among humans and their direct ancestors. Since the human-chimp split 5 to 7 million years ago, brain size has tripled in the human lineage (Wood & Collard 1999). The focus of this doctoral work is to investigate some of the cell biological mechanisms responsible for this increase in relative brain size. In particular, the processes that regulate symmetric cell division (ultimately generating more progenitors), the constraints on progenitor proliferation, and how neural progenitors have overcome these constraints in the process of primate encephalization are the primary questions of interest. Both functionally analyses in the mouse model system and comparative neurobiology of rodents and primates are used here to address these questions. Using the mouse model system, the cell biological role of the Aspm (abnormal spindle-like microcephaly associated) protein in regulating brain size was investigated. Specifically, Aspm function in symmetric, proliferative divisions of neuroepithelial (NE) cells was analyzed. It was found that Aspm expression in the mouse neuroepithelium correlates in time and space with symmetric, proliferating divisions. The Aspm protein localizes to NE cell spindle poles during all phases of mitosis, and is down-regulated in cells that undergo asymmetric (neurogenic) cell divisions. Aspm RNAi alters the division plane in NE cells, increasing the likelihood of premature asymmetric division resulting in an increase in non-NE progeny. At least some of the non-NE progeny generated by Aspm RNAi migrate to the neuronal layer and express neuronal markers. Importantly, whatever the fate of the non-NE progeny, their generation comes at the expense of the expansion of the proliferative pool of NE progenitor cells. These data have contributed to the generation of an hypothesis regarding evolutionary changes in the regulation of spindle orientation in vertebrate and mammalian neural progenitors and their impact on brain size. Specifically, in contrast to invertebrates that regulate the switch from symmetric to asymmetric division through a rotation of the spindle (horizontal versus vertical cleavage), asymmetric NE cell division in vertebrates is accomplished by only a slight deviation in the cleavage plane away from the vertical, apical-basal axis. The requirement for the precise alignment of the spindle along the apical-basal axis in symmetric cell divisions may have contributed to selection on spindle “precision” proteins, thus increasing the number of symmetric NE cell division, and contributing to brain size increases during mammalian evolution. Previous comparative neurobiological analyses have revealed an increase in basally dividing NE cells in the brain regions of highest proliferation and in species with the largest brains (Smart 1972a,b; Martinez-Cerdeno et al. 2006). The cell biological characteristics of these basally dividing cells are still largely unknown. We found that primate basal progenitors, similar to rodent apical progenitors, are Pax6+. This suggests that primate basal progenitors may share other properties with rodent apical progenitors, such as maintenance of apical contact. Our previous finding that artificial alteration of cleavage plane in NE cells affects their ability to continue proliferating supports the hypothesis that the apical membrane and junctional complexes are cell fate determinants (Huttner & Kosodo 2005). As such, the need to maintain apical membrane contact appears to be a constraint on proliferation (Smart 1972a,b; Smart et al. 2002). Together, these data favor the hypothesis that primate basally dividing cells maintain apical contact and are epithelial in nature.
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Evolution of the genus Aristolochia (Aristolochiaceae) in the Eastern Mediterranean including the Near East and CaucasiaMahfoud, Hafez M. 19 February 2010 (has links) (PDF)
The Aristolochiaceae are one of the largest angiosperm families, the family has been divided into two subfamilies: Asaroideae, which include Asarum and Saruma, and Aristolochioideae, which includes Thottea sensu lato and Aristolochia sensu lato (Kelly and Gonzales, 2003). Aristolochia sensu lato comprise between 450 and 600 species, distributed throughout the world with centers of diversities in the tropical and subtropical regions (Neinhuis et al., 2005, Wanke et al., 2006a, 2007).
However, the extended Mediterranean region including Turkey, the Caucasus and the Near East is likely to be the only diversity hotspot of the genus Aristolochia in the northern hemisphere were up to 60 species and subspecies could be observed (Wanke 2007). Most important contributions to the knowledge of these species were published by Nardi (1984, 1988, 1991, 1993) and Davis & Khan (1961, 1964, 1982), all of these studies were based on morphological characters only. In recent years, with the progress of molecular techniques and in light of the systematic chaos, a detailed study was needed to unravel the evolutionary history prior to a taxonomic revision of this group. The first chapter of my thesis should be regarded as the starting point for more detailed investigation on population level.
Preliminary molecular phylogenitic analysis recovered the Mediterranean Aristolochia species as monophyletic (de Groot et al 2006). However, only very few members were included in that study. The latest phylogenetic study by Wanke (2007) dealed with west Mediterranean Aristolochia species and sampled also few members belonging to the east Mediterranean and Caucasian species (3 from Greece, 2 from Georgia and 1 from Turkey). This study reported the Mediterranean Aristolochia species as two molecular and morphologically well supported clades, which were sister to each other. Furthermore, the two closely related species A. sempervirens and A. baetica which have an east west vicariance and are known as Aristolochia sempervirens complex has been recovered as sister group to the remaining west Mediterranean species. A detailed investigation of the evolutionary history of this group is the topic of the second chapter of my thesis (Chapter 2). The Aristolochia sempervirens complex is characterized by an unusual growth form and has a circum Mediterranean distribution. The investigation of these species complex seem to be of great importance to understand speciation and colonization of the Mediterranean by the genus Aristolochia and might shade light in historical evolutionary processes of other plant lineages in the Mediterranean. Furthermore, I test applicability and phylogenetic power of a nuclear single copy gene (nSCG) region to reconstruct well resolved and highly supported gene genealogies as a prerequisite to study evolutionary biology questions in general.
Furthermore, a comprehensive overview of leaf epicuticular waxes, hairs and trichomes of 54 species from the old and new world taxa of the genus Aristolochia were investigated using scanning electron microscopy (SEM) to clarify taxonomic status of theses species in contrast to their molecular position. Also this study which is the third chapter of this thesis (Chapter 3), has a strong focus on Mediterranean Aristolochia and tries to provide additional support for molecular findings based on epicuticular waxes and to test them as synapomorphies.
Each chapter has its own introduction and abstract resulting in a short general introduction here.
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Physikalische Berechnungen zu Fragen der Tumoren, der Mutationen und der Evolution / Physical calculations to questions of the tumors, the mutations and the evolutionDrechsel, Dieter 07 March 2012 (has links) (PDF)
Bei der Replikation monotoner Sequenzen tritt theoretisch ein Vorgang auf, den wir als „Basenkonkurrenz“ bezeichnen: Da sich an jeder Replikations-Stelle mehrere Basenbausteine bewerben, aber immer nur einer benötigt wird, bewerben sich die übrig gebliebenen Bausteine an den jeweils nächsten Replikations - Positionen und erlangen wegen der fortwährenden Beschleunigung durch elektrostatische Anziehung immer größere kinetische Energien. Das führt dazu, dass an einer bestimmten Stelle der replizierenden monotonen Sequenz der eine Partner der Wasserstoffbrückenbindung ein hohes Energieniveau erreicht.
Es wird berechnet, dass sich dadurch kurzzeitig eine sehr hohe Bindungsenergie zwischen den beiden Partnern der Wasserstoffbrückenbindung einstellt, wodurch der in dieser kurzen Zeitspanne wirkende DNA-Reparaturmechanismus unterdrückt wird.
Die Auswirkungen der hohen Basenkonkurrenz – Energien werden berechnet (hohe Bindungsenergien der Wasserstoffbrückenbindungen, Tunnelvorgänge, irreparable Mutationen). Die Folgen dieser Erscheinung sind Tumorbildung, Alterung, Veränderung der DNA – Struktur, Beeinflussung der Evolution, worauf im Einzelnen eingegangen wird.
Es zeigt sich, dass die negativen Auswirkungen der Basenkonkurrenz vorwiegend bei zu niedriger Viskosität des Zellplasmas auftreten.
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Evolution of the genus Aristolochia - Systematics, Molecular Evolution and Ecology / Evolution der Gattung Aristolochia - Systematik, Molekulare Evolution und ÖkologieWanke, Stefan 24 January 2007 (has links) (PDF)
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.
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