Introgresní zóna druhů Arabidopsis lyrata a A. arenosa ve střední Evropě / Introgressive zone of Arabidopsis lyrata and A. arenosa in Central Europe

Hojka, Jakub

January 2018

Genetic composition of hybrid zones often reflects geographical and ecological gradients. Hybrid zone of Arabidopsis lyrata and A. arenosa in Central Europe can be convenient model system for testing such hypothesis. These are well circumscribed but still interfertile, and their offspring is fully fertile. Besides repeated hybridisation events, the current state is complicated by the autopolyploidisation events of one of the parents, namely A. lyrata, which is present in the area studied both as diploid and tetraploid. This hybrid zone was already described in previous publications, which showed certain gradient of introgression. Moreover, the area of the hybrid zone represents a transition between Alpine and Pannonian climate along an altitudinal gradient leading from the Prealps to the lowland Wienerwald. The current thesis is the as yet most detailed study of this hybrid zone both in respect of number of studied populations and the amount of data acquired using the methods of RAD Sequencing, multivariate morphometrics and flow cytometry. The analysis of genetic data showed a gradient of introgression, where parental populations are placed at opposite ends, whereas genetically intermediate hybrids are placed in its centre. Analysis of the genome size showed an additional gradient, where hybrids...

Polyploidní speciace u rodu Anthoxanthum v Evropě / Polyploid speciation of the genus Anthoxanthum in Europe

Khodlová, Zuzana

January 2011

Eight of fifteen species in genus Anthoxanthum (Poaceae) can be found in Europe. Five of them are perennials forming A. odoratum complex, the remaining three are annual, more or less mediterranean taxa (A. aristatum, A. ovatum and A. gracile). Within the A. odoratum s. l. complex the following taxa are distinguished: widely spread A. odoratum s. str. (4x; 2n = 20), arcto-alpine A. alpinum (2x a 4x; 2n = 10 and 20), Madeiran endemic species A. maderense (2x; 2n = 10), endemic species of Balkan mountains A. pauciflorum (2x; 2n = 10) and the Iberian peninsula endemic A. amarum (?x; 2n ~ 90). The aim of this thesis is to clearify the unknown evolutionary relationships between the taxa, between the annuals and perennials, diploids and polyploids. The following questions should be answered in this study: 1) What is the origin and distribution of the rediscovered diploid perennial taxon and what is its relationship to the other members of the group; 2) What is the distribution pattern of the perennial taxa of the genus Anthoxanthum in Europe and what is their haplotype differenciation (overall distribution of the taxa and haplotypes and the existence of their sympatric occurence); 3) What evolutionary ties exist among the species and what is the origin of allotetraploid taxon A. odoratum s.str. The...

Patterns of Genome Size in the Copepoda

Wyngaard, G. A., Rasch, E. M.

01 January 2000

Adult somatic nuclear DNA contents are reported for eleven cyclopoid species (Megacyclops latipes, Mesocyclops edax, M. longisetus, M. ruttneri, M. leuckarti, M. woutersi, Macrocyclops albidus, Cyclops strenuus, Acanthocyclops robustus, Diothona oculata, Thermocyclops crassus) and for the harpacticoid Tigriopus californicus and range from 0.50 to 4.1 pg DNA per nucleus. These diploid genome sizes are consistent with previously published values for four Cyclops species (0.28-1.8 pg DNA per nucleus), but are strikingly smaller than those reported for marine calanoids (4.32-24.92 pg DNA per nucleus). We discuss three explanations, none of them exclusive of another, to account for the smaller size and range of cyclopoid genome sizes relative to calanoid genome sizes: (1) higher prevalence of chromatin diminution in the Cyclopoida, (2) phylogenetic structure or older age of the Calanoida relative to Cyclopoida and (3) nucleotypic selection that may influence life history variation and fitness. Measurements of genome size were made on Feulgen stained, somatic cell nuclei, using scanning microdensitometry which is well suited to the sparse and heterogeneous populations of copepod nuclei. The importance of measuring large numbers of nuclei per specimen, possible sources of variation associated with cytophotometric measurements, and appropriate use of internal reference standards and stoichiometry of the Feulgen stained nuclei are discussed.

C-value paradox

calanoida

chromatin diminution

copepoda

cyclopoida

cytophotometry

genome size

harpacticoida

phylogeny

Genetic Architecture of the Cryptic Species Complex of Acanthocyclops Vernalis (Crustacea: Copepoda). II. Crossbreeding Experiments, Cytogenetics, and a Model of Chromosomal Evolution

Grishanin, Andrey, Rasch, Ellen M., Dodson, Stanley I., Wyngaard, Grace A.

01 February 2006

Collectively, populations of Acanthocyclops vernalis, a species complex of freshwater copepods, are remarkably similar as to morphology and DNA content, despite variability in chromosome number. Reproductive isolation had been reported among some populations, but with each new investigation the species boundaries and factors that may influence them appeared less clear. To clarify the pattern of biological species within this group of populations, we adopted a comprehensive approach and examined patterns of reproductive isolation in populations for which morphology, chromosome number, DNA content, and 18S rDNA sequences are known. In this study we established nine isofemale lines from four sites in Wisconsin and performed 266 crosses. Crosses within and among these lines were used to relate the degree of reproductive isolation to chromosome differences and to construct a model to explain the origin and maintenance of chromosome number variability. Different gametic and somatic chromosome numbers were observed among specimens within some isofemale lines. In a few cases, gametes with different haploid numbers were produced by a single female. Matings within isofemale lines always produced at least some reproductively successful replicate crosses (produced viable, fertile offspring). Crosses between lines from the same site showed reduced success relative to within-line crosses. Crosses between populations from distant sites showed limited genetic compatibility, producing viable, fertile F1 offspring but infertile F2 adults. One cross between lines with different chromosome numbers (one with 2n = 8 and one with 2n = 10) produced fertile viable offspring, which reproduced for at least 60 generations. These hybrids had either eight or nine chromosomes in the third generation of inbreeding, and eight chromosomes after 20 generations. These hybrids also had reduced nuclear DNA contents at the third generation, a level that persisted through the 20th generation. Successful backcrosses between some hybrids and their parental lines further demonstrated the potential for genetic compatibility among forms with different chromosome numbers. We propose a model in which alterations due to Robertsonian fusions, translocations, and/or loss of chromosomal fragments generate heritable variation, only some of which leads to reproductive isolation. Hence, some of the criteria traditionally used to recognize species boundaries in animals (morphology, DNA content, chromosome number) may not apply to this species complex.

acanthocyclops vernalis

chromosomal rearrangements

copepod

crossbreeding

genome size

karyotype

reproductive isolation

Nuclear DNA Content Correlates With Depth, Body Size, and Diversification Rate in Amphipod Crustaceans From Ancient Lake Baikal, Russia

Jeffery, Nicholas W., Yampolsky, Lev, Gregory, T. Ryan

01 January 2017

Lake Baikal in Russia is a large, ancient lake that has been the site of a major radiation of amphipod crustaceans. Nearly 400 named species are known in this single lake, and it is thought that many more await description. The size and depth of Lake Baikal, in particular, may have contributed to the radiation of endemic amphipods by providing a large number of microhabitats for species to invade and subsequently experience reproductive isolation. Here we investigate the possibility that large-scale genomic changes have also accompanied diversification in these crustaceans. Specifically, we report genome size estimates for 36 species of Baikal amphipods, and examine the relationship between genome size, body size, and the maximum depths at which the amphipods are found in the lake. Genome sizes ranged nearly 8-fold in this sample of amphipod species, from 2.15 to 16.63 pg, and there were significant, positive, phylogenetically corrected relationships between genome size, body size, maximum depth, and diversification rate among these species. Our results suggest that major genomic changes, including transposable element proliferation, have accompanied speciation that was driven by selection for differences in body size and habitat preference in Lake Baikal amphipods.

ancient lakes

C-value

Crustaceans

flow cytometry

genome size

speciation

Biological Sciences

Dispersal, distribution and genetic diversity of Melampyrum subalpinum group

CHLUMSKÝ, Jan

January 2016

This thesis is focused on the dispersal, distribution, and genetic diversity of the taxonomically highly diverse Melampyrum subalpinum group. A complete revision of the localities of M. subalpinum in the Czech Republic and Slovakia is presented. The genetic variation and population structure of the M. subalpinum group across its distribution range is described based on allozymes, nuclear and chloroplast gene sequencing, and genome size. Signs of historical hybridization with M. nemorosum were found in some populations. A comparison of seed dispersal by ants between the co-occurring M. subalpinum and M. pratense and the influence of differences in this process are presented. A new mean of seed dispersal (endozoochory) is introduced for Melampyrum. Myrmecochorous dispersal distances are tested and Holocene migration possibilities are discussed taking into account endozoochory.

Nuclear Genome Size Diversity Of Marine Invertebrate Taxa Using Flow Cytometric Analysis

Roebuck, Kyle

06 December 2017

Genomic analysis provides a substantial amount of information on evolutionary history, novel genes, transcriptomic expression and regulation in response to environmental stimuli, how efficiently organisms utilize their genome, and directional genome evolution. Genome size analysis serves as the first step in the sequencing process, because sequencing and annotation costs are directly correlated with genome size. Invertebrates represent the vast majority of faunal diversity on the planet, and, to a greater extent, the marine environment, although they are vastly understudied when compared to vertebrate genomes. Flow cytometry is a widely used, reliable, and accurate means of estimating genome sizes and has yielded valid measurements in this comparatively broad taxonomic study. This methodology quantifies genome sizes by measuring the fluorescent re-emission from nuclei that have been saturated with DNA- intercalating dyes, such as propidium iodide. Genome sizes of 19 species across five phyla were estimated by comparison with the known genome size of chicken (Gallus domesticus). Several estimates reported here are the first for their species or class. In addition to estimating new marine invertebrate genome sizes, analyses of some common preservation methods of tissue viability for flow cytometric estimations were performed. Generally, in comparison to RNAlater or ethanol, DMSO-based storage buffer was most successful at preserving nuclear membrane integrity, a requirement for flow cytometric genome size estimations. Recommendations of cost-effective species eligible for current next-generation sequencing technology (<3.5 Gb) are given for invertebrate genomicists seeking potential novel species to sequence.

genome size

C-value

invertebrate

propidium iodide

flow cytometry

Biodiversity

Cell Biology

Genomics

Marine Biology

Molecular Biology

Exploration génétique de la polyploïdie du genre Juniperus (Cupressaceae) / Genetic exploration of polyploidy in the genus Juniperus (Cupressaceae)

Farhat, Perla

31 May 2019

La polyploïdie est un processus important et un moteur de la diversification et de l'évolution des plantes. Peu de polyploïdes naturels ont été décrits chez Juniperus, un genre de conifère représenté par 75 espèces d'arbres ou arbustes à feuilles persistantes, largement réparties dans l'hémisphère nord. Dans ce travail de recherche, l’implication de la polyploïdie dans l'évolution de Juniperus et l’élucidation des mécanismes sous-jacents à ces événements de polyploïdisation sont explorées. La taille du génome (TG) et le niveau de ploïdie ont été évalués chez 111/115 taxons en utilisant la cytométrie en flux et les comptages chromosomiques. Le taux de polyploïdie chez les genévriers s’est avéré être exceptionnellement élevé : 15 taxons sont des tétraploïdes et un seul taxon (J. foetidissima) est hexaploïde. Juniperus foetidissima représente le seul conifère hexaploïde découvert à ce jour à part Sequoia sempervirens. Nous avons également utilisé des approches de modélisation phylogénétique pour déterminer la TG ancestrale dans les trois clades de Juniperus et pour reconstruire le processus évolutif de la polyploïdisation chez ce genre. Au moins 10 événements de polyploïdisation ont eu lieu au cours de l'évolution et de la diversification de Juniperus. Nous avons ensuite exploré l’origine de la polyploïdie chez certaines espèces méditerranéennes. La variation de la TG et le niveau de ploïdie de deux variétés de J. sabina ont été estimés : Les populations échantillonnées de J. sabina var. sabina se sont avérées être diploïdes, tandis que les populations de J. sabina var. balkanensis étaient toutes tétraploïdes. Ces derniers auraient été issus d'une ancienne hybridation entre le tétraploïde J. thurifera et le diploïde J. sabina. Dans les Alpes françaises, où J. sabina var. sabina et J. thurifera sont en sympatrie, des individus présentant des morphologies intermédiaires entre ces deux espèces sont observés. Suite à des estimations des TG, de séquençage des ITS et de régions chloroplastiques, ces individus sont considérés comme des hybrides triploïdes. Enfin, l’utilisation des marqueurs AFLP pour déchiffrer les relations phylogénétiques entre des espèces méditerranéenne a montré que plusieurs pools génétiques contribuent à la diversité de Juniperus. Aussi ces marqueurs ont contribué à la découverte des contributions de ces pools génétiques aux taxons polyploïdes. Alors que les populations libanaises de l'hexaploïde J. foetidissima sont issues d'une lignée ancestrale unique, la population grecque semble résulter d'un mélange inégal de deux lignées anciennes. Ces deux lignées contribuent également au tétraploïde J. thurifera. Cette analyse a également montré que l’espèce méditerranéenne J. excelsa et l’espèce africaine J. procera partagent la même lignée ancestrale. Cependant, des analyses supplémentaires sont nécessaires pour une interprétation plus complète des données. L'importance de l'hybridation interspécifique et de la polyploïdie dans l'évolution des espèces de Juniperus nécessite d’amples recherches visant à comprendre le lien entre ces mécanismes et l'adaptation de ces espèces à un large spectre d'habitats extrêmes. Ces recherches futures devraient aussi contribuer à découvrir comment les espèces de conifères peuvent s’adapter aux changements climatiques. / Polyploidy is considered as an important phenomenon and a key driving force for plant diversification and evolution. Few natural polyploid species have been described in Juniperus, a coniferous genus represented by 75 species of evergreen trees or shrubs widely distributed in the North Hemisphere. The occurrence of polyploidy in the evolution of this genus as well as a more comprehensive view of pathways that were involved in these polyploidization events are explored in this research work. Genome size (GS) and ploidy level assessments were conducted on 111/115 taxa using flow-cytometry and chromosome counts. Juniperus holds an exceptionally high rate of polyploidy, 15 taxa being tetraploids and just one (J. foetidissima) being hexaploid. It represents the only hexaploid conifer discovered to date after Sequoia sempervirens. We also used phylogenetically-informed trait evolution modelling approaches to determine ancestral GS in the three clades of Juniperus and to reconstruct the evolutionary process of polyploidization in Juniperus. At least 10 polyploidization events have occurred during Juniperus evolution and diversification. We then explored the origin of polyploidy in selected Mediterranean species. The GS variation and the ploidy level of two J. sabina varieties were estimated: J. sabina var. sabina sampled populations were shown to be diploid, while J. sabina var. balkanensis populations were all tetraploid. The latter has been postulated to have arisen from an ancient hybridization between the tetraploid J. thurifera and the diploid J. sabina. In the French Alps, where J. sabina var. sabina and J. thurifera occur in sympatry, individuals with intermediate morphologies between these two species are observed. Evidences based on GS assessments, ITS and chloroplastic sequences demonstrated these individuals as triploid hybrids. Finally, the use of AFLP markers to decipher phylogenetic relationships between Mediterranean and Eastern Mediterranean species showed that multiple lineages contributes to Juniperus diversity and shed light on some polyploid taxa origins. While the Lebanese populations of the hexaploid J. foetidissima are issued from a unique ancestral lineage, the Greek population seems to be the result of an unequal admixture of two ancient lineages. These two lineages contribute also to the tetraploid J. thurifera. This analysis showed also that the Mediteranean J. excelsa and the African taxa J. procera shares the same ancestral lineage. However, further analyses are needed for a more complete interpretation of the data. The importance of interspecific hybridization and of polyploidization in the evolution of Juniperus species argues in favor of the development of researches aiming at understanding the link between these mechanisms and the adaptation of those species to a wide range of extreme habitats. Such future researches should contribute to predict how conifer species may adapt to dramatic changes in the Earth’s climate.

Diversité génétique

Hybridation interspécifique

Évolution des plantes

Polyploïdie

Conifères

Taille du génome

Genetic diversity

Interspecific hybridization

Plant evolution

Polyploidy

Conifer

Genome size

Velikost genomu v evoluci švábů / Genome size in the evolution of cockroaches

Stuchlíková, Magdalena

January 2020

Genome size or nuclear DNA content is a a trait which varies greatly among living organisms, with no apparent relashionship between genome size and organismal complexity. It is usually described using the C-value as either a number of base pairs or picograms of DNA. Unresolved questions regarding mechanisms influencing genome size and relationships between genome size and other organismal traits are together known as the C-value enigma. Genome size is known to positively correlate with cell size and negatively with developmental and cell division rate. A maximum constraint of 2 pg has also been proposed for haploid genome sizes of holometabolous insects. Despite the fact that there are about one million described insect species, genome sizes are only known in a fraction of them. This thesis thus aims to extend the dataset of known insect genome sizes by as many species of cockroaches (Blattodea) as possible. Another aim is to compare results with known phylogeny and also to compare difference in genome size between sexes. Flow cytometry was used for genome size estimations, which is a rapid, simple and effective method, also suitable for study of ploidy levels and other cellular charasteristics.

Orchideje jako model studia ekofyziologických adaptací mykoheterotrofních rostlin / Orchids as a model for research in ecophysiological adaptations of mycoheterotropic plants

Ponert, Jan

January 2018

Perhaps all orchids are mycotrophic at early developmental stages, while majority of species photosynthesize at adulthood and only about 200 species remain fully mycotrophic for the whole life. Mycotrophy affects orchids at many levels. In this thesis, I focus on four aspects of orchid biology, which could be connected with mycotrophy: (i) systematics, (ii) genome size and endoreduplication, (iii) regulation of seed germination and (iv) mechanism of transfer of carbon and energy from fungi to orchids. There are over 27,000 recently recognized orchid species, nevertheless new ones are still discovering and old ones are revisiting. In this work I present a description of new species, Cleisostoma yersinii, and its morphological, anatomical, ecological and systematic characterization. Phylogeny reconstruction confirmed relationship with C. birmanicum. In the subtribe Podochileae, I reappraised the genus Campanulorchis to establish monophyletic but also morphologically defined group. For both abovementioned genera I prepared the artificial identification key. In the genus Dactylorhiza I revised taxa present in our country and I prepared an identification key which firstly mentions D. maculata subsp. elodes from Czech Republic. Orchid species diversity is probably reflected in genome structure. Results...