Evolutionary Relationships Among Duiker Antelope (Bovidae: Cephalophinae)

Johnston, Anne

17 December 2011

Duikers are a species rich subfamily of threatened African antelope whose recent origin poses a challenge to the molecular identification of taxa and estimation of their phylogeny. I test the ability of DNA barcodes to identify all taxa within this group. I then use mitochondrial and nuclear genes to estimate a multi-locus species tree and to date divergence times. DNA barcodes are unable to distinguish many sister taxa, calling into question the utility of barcodes for the regulation of duiker trade or in identification of field-collected feces. The multi-locus phylogeny provides support for the relationships among major duiker lineages and placement of two problematic taxa, but challenges the validity of the savanna genus and identifies hybridization between taxa. This study reveals that most duikers diverged during the Pleistocene, meriting further inquiry into the role that Pleistocene glacial cycling played in the diversification and population structuring of duikers.

Barcode

Cytochrome c oxidase subunit 1 (COX1)

Bushmeat, Pleistocene

Phylogeny

Africa

Evolution

Analysis of early steps in Assembly of Cytochrome c Oxidase

Bareth, Bettina

26 February 2014

No description available.

572

mitochondria

respiratory chain

COX assembly

Cox1 maturation

heme synthase Cox15

Biologie (PPN619462639)

Molecular and morphological characterisation of species of \kur{Plagiorchis} Lühe, 1899 (Digenea: Plagiorchiidae) in lymnaeid snails from freshwater ecosystems in central Europe

ROHÁČOVÁ, Jana

January 2014

This study applies molecular and morphological approaches addressing the identification of morphologically similar larval stages (cercariae) of Plagiorchis spp. (Digenea: Plagiorchiidae) parasitising lymnaeid snail populations in the freshwater ecosystems of central Europe. Five morphologically homogeneous and genetically distinct lineages of Plagiorchis spp. were identified via matching molecular data for the mitochondrial cox1 gene with detailed morphometric data. Phylogenetic and comparative sequence analyses using partial 28S rDNA and ITS1-5.8S-ITS2 sequences allowed molecular identification of three species (P. elegans, P. maculosus and P. koreanus) via matching sequences from larval and adult digenean stages. A key for the identification of the cercariae of Plagiorchis spp. parasitising lymnaeid populations in central Europe is provided.

Phylogenetic and population genetic studies on some insect and plant associated nematodes

Saeb, Amr

22 September 2006

No description available.

Biology, Genetics

Heterorhabditis

H. bacteriophora

Bursaphelenchus conicaudatus

phylogenetics

population genetics

cox1

ITS1

nd4

msp

Study of cox1 trans-splicing in Diplonema papillatum mitochondria

Yan, Yifei

07 1900

Diplonema papillatum est un organisme unicellulaire qui vit dans l’océan. Son génome mitochondrial possède une caractéristique spéciale: tous les gènes sont brisés en de multiples fragments qui s’appellent modules. Chaque module est codé par un chromosome différent. L’expression d’un gène exige des épissages-en-trans qui assemblent un ARN messager complet à partir de tous les modules du gène. Nous avons précédemment montré que le gène cox1 est encodé dans neuf modules avec six Us non encodés entre le module 4 et le module 5 de l’ARN messager mature [1]. Nous n’avons identifié aucune séquence consensus connue de site d’épissage près des modules. Nous spéculons qu’un ARN guide (gRNA) a dirigé l’épissage-en-trans du gène cox1 par un mécanisme qui est semblable à l’édition d’ARN par l’insertion/la suppression des Us chez les kinétoplastides, le groupe sœur des diplonémides. Nous avons trouvé que les six Us sont ajoutés au bout 3’ de l’ARN d’une façon semblable à ceux ajoutés par le TUTase lors de l’édition de l’insertion des Us chez les kinétoplastides. Nous avons construit des profils de gRNA de l’épissage-en-trans avec les expressions régulières basé sur notre connaissance des gRNAs dans l’édition d’ARN chez les kinétoplastides. Selon la complémentarité partielle entre le gRNA et les deux modules adjacents, nous avons généré des amorces pour RT-PCR visant à détecter des séquences qui sont assorties à un des profils de gRNA. Une expérience pilote in vitro n’a pas permis de reconstituer l’épissage-en-trans des modules 3, 4, et 5, suggérant que nous devons améliorer nos techniques. / Diplonema papillatum is a single cellular organism that lives in the ocean. Its mitochondrial genome possesses a special feature: all genes are fragmented in multiple pieces that are called modules and each module is encoded by a different chromosome. Expression of a gene requires trans-splicing that successfully assemble a full-length mRNA from all modules of the gene. It was previously shown that the cox1 gene is encoded in nine modules that are all located on different chromosomes; moreover, a stretch of six non-encoded Us exist between Module 4 and 5 in the mature mRNA [1]. No consensus sequence of known splicing sites was identified near the modules. We speculate that trans-splicing of the cox1 gene is directed by guide RNAs (gRNAs) via a mechanism that is similar to U-insertion/deletion editing in kinetoplastids, the sister group of diplonemids. We have detected populations of small RNA molecules that could come from mitochondrial. We found that the six Us were added to the 3’ end of Module 4 in a similar way to the Us added by the TUTase in kinetoplastid U-insertional editing. Sequence profiles of possible trans-splicing gRNAs were constructed in regular expressions based on our knowledge of known gRNAs in kinetoplastid RNA editing. According to the complementarity between the gRNA and the two adjacent modules, primers were designed for RT-PCR that aims to detect gRNA sequences. Among the results, we identified sequences that match or partially match the gRNA profiles. A pilot in vitro assay did not reconstitute trans-splicing of module 3, 4 and 5, suggesting that further technical improvements are needed.

Diplonema papillatum

cox1

RT-PCR

guide RNA

trans-splicing

mitochondria

kinetoplastids

Diplonema papillatum

cox1

RT-PCR

ARN guide

épissage-en-trans

mitochondrie

kinétoplastides

Study of cox1 trans-splicing in Diplonema papillatum mitochondria

Yan, Yifei

07 1900

Diplonema papillatum est un organisme unicellulaire qui vit dans l’océan. Son génome mitochondrial possède une caractéristique spéciale: tous les gènes sont brisés en de multiples fragments qui s’appellent modules. Chaque module est codé par un chromosome différent. L’expression d’un gène exige des épissages-en-trans qui assemblent un ARN messager complet à partir de tous les modules du gène. Nous avons précédemment montré que le gène cox1 est encodé dans neuf modules avec six Us non encodés entre le module 4 et le module 5 de l’ARN messager mature [1]. Nous n’avons identifié aucune séquence consensus connue de site d’épissage près des modules. Nous spéculons qu’un ARN guide (gRNA) a dirigé l’épissage-en-trans du gène cox1 par un mécanisme qui est semblable à l’édition d’ARN par l’insertion/la suppression des Us chez les kinétoplastides, le groupe sœur des diplonémides. Nous avons trouvé que les six Us sont ajoutés au bout 3’ de l’ARN d’une façon semblable à ceux ajoutés par le TUTase lors de l’édition de l’insertion des Us chez les kinétoplastides. Nous avons construit des profils de gRNA de l’épissage-en-trans avec les expressions régulières basé sur notre connaissance des gRNAs dans l’édition d’ARN chez les kinétoplastides. Selon la complémentarité partielle entre le gRNA et les deux modules adjacents, nous avons généré des amorces pour RT-PCR visant à détecter des séquences qui sont assorties à un des profils de gRNA. Une expérience pilote in vitro n’a pas permis de reconstituer l’épissage-en-trans des modules 3, 4, et 5, suggérant que nous devons améliorer nos techniques. / Diplonema papillatum is a single cellular organism that lives in the ocean. Its mitochondrial genome possesses a special feature: all genes are fragmented in multiple pieces that are called modules and each module is encoded by a different chromosome. Expression of a gene requires trans-splicing that successfully assemble a full-length mRNA from all modules of the gene. It was previously shown that the cox1 gene is encoded in nine modules that are all located on different chromosomes; moreover, a stretch of six non-encoded Us exist between Module 4 and 5 in the mature mRNA [1]. No consensus sequence of known splicing sites was identified near the modules. We speculate that trans-splicing of the cox1 gene is directed by guide RNAs (gRNAs) via a mechanism that is similar to U-insertion/deletion editing in kinetoplastids, the sister group of diplonemids. We have detected populations of small RNA molecules that could come from mitochondrial. We found that the six Us were added to the 3’ end of Module 4 in a similar way to the Us added by the TUTase in kinetoplastid U-insertional editing. Sequence profiles of possible trans-splicing gRNAs were constructed in regular expressions based on our knowledge of known gRNAs in kinetoplastid RNA editing. According to the complementarity between the gRNA and the two adjacent modules, primers were designed for RT-PCR that aims to detect gRNA sequences. Among the results, we identified sequences that match or partially match the gRNA profiles. A pilot in vitro assay did not reconstitute trans-splicing of module 3, 4 and 5, suggesting that further technical improvements are needed.

Diplonema papillatum

cox1

RT-PCR

guide RNA

trans-splicing

mitochondria

kinetoplastids

Diplonema papillatum

cox1

RT-PCR

ARN guide

épissage-en-trans

mitochondrie

kinétoplastides

Development of a DNA barcode for species identification of tuna

Nordquist, Clara, Edwall, Jonathan, Eriksson, Leonora, Mäkinen, Nelly, Sayehban, Minna, Styfberg, Matilda

January 2022

Today, DNA-barcoding with the gene COI is regularly used in the identification of fish. However, this is not an adequate way of identifying species of tuna due to COI lacking sufficient interspecies divergence. This is problematic since fraud and mislabeling are a major concern within the fish and tuna industries. Thus, there is a need for a new genetic barcode region when identifying the 15 tuna species within the tribe Thunnini. This study has considered six mitochondrial genetic regions (16S, ATP8, COII, CR, CytB, and ND2) and their potential as barcodes in comparison to COI. To be of practical use, the barcode has to be able to differentiate between all 15 tuna species, as well as contain conserved primer binding sites and be approximately 400 bp, or shorter. Analyses of the regions were made through Multiple Sequence Alignments built using ClustalW in Mega 11.0. The candidates were first evaluated through neighbor-joining trees and plots of inter- and intraspecies variation, and then analyzed further in search of conserved regions for primer binding, flanking a segment of approximately 400 bp (or shorter). This resulted in two possible barcode candidates with corresponding primers from the CR and ND2 genes. As a final step, these two were analyzed for specificity using BLAST, to evaluate their actual utility in differentiating the tuna species. The results show that they both can identify the different tuna species, but that ND2 is superior with 100% identification accuracy. In addition to the theoretical analysis, the ability of the primers was measured through a real PCR amplification. Unfortunately, only the CR barcode could be evaluated, but the results show it to be practically useful. Even though the utility of ND2 in PCR could not be analyzed, it is highly recommended as a region for further investigations. Given the strong theoretical support, it definitely shows promise as a new barcode for species identification of tuna.

Thunnini

D-loop

mitochondrial control region

CR

16S

ATP8

COII

Cox2

CytB

COI

Cox1

ND2

NADH dehydrogenase 2

Bioinformatics and Systems Biology

Bioinformatik och systembiologi

Consequences of Insect Flight Loss for Molecular Evolutionary Rates and Diversification

Mitterboeck, T. Fatima

25 May 2012

This thesis investigates the molecular evolutionary and macroevolutionary consequences of flight loss in insects. Chapter 2 tests the hypothesis that flightless groups have smaller effective population sizes than related flighted groups, expected to result in a consistent pattern of increased non-synonymous to synonymous ratios in flightless lineages due to the greater effect of genetic drift in smaller populations. Chapter 3 tests the hypothesis that reduced dispersal and species-level traits such as range size associated with flightlessness increase extinction rates, which over the long term will counteract increased speciation rates in flightless lineages, leading to lower net diversification. The wide-spread loss of flight in insects has led to increased molecular evolutionary rates and is associated with decreased long-term net diversification. I demonstrate that the fundamental trait of dispersal ability has shaped two forms of diversity—molecular and species—in the largest group of animals, and that microevolutionary and macroevolutionary patterns do not necessarily mirror each other. / Generously funded by NSERC with a Canada Graduate Scholarship and the Government of Ontario with an Ontario Graduate Scholarship to T. Fatima Mitterboeck; NSERC with a Discovery Grant to Dr. Sarah J. Adamowicz

evolution

flight

transitions

insects

molecular rates

diversification

flightless

flight loss

dispersal

holometabola

insect species

species richness

effective population size

population size

population subdivision

macroevolution

microevolution

comparative method

substitution rates

dN/dS ratios

non-synonymous substitutions

nearly neutral theory

molecular clock

mitochondrial DNA

nuclear DNA

OXPHOS

COI

COX1

Cytochrome c oxidase subunit I

pterygota

speciation

extinction

whole-tree method

sister-group method