Phylogeny and Biogeography of the Genus Capricornis (Artiodactyla: Bovidae) Based on Mitochondrial DNA Sequences and Cranial Morphometrics

Chang, Hsun-Cheng

27 June 2002

The genus Capricornis Ogilby, 1837, is divided into three species and widely distributed in sourthern China, Tibet, Myanmar, IndoChinese peninsula, Malaysia peninsula, Sumatra, Japanese archipelagos and Taiwan. Using complete cytochrome b sequences (1140 bp) analyzes the genetic variation and phylogeny of genus Capricornis from Taiwan, Japan and Mainland China. Constructed by both distance and maximum parsimony methods, the phyloenetic tree distinguish the Capricornis to three clades: Formosan serow, Japanese serow, and Sumatran serow from mainland China. Formosan serow is more familiar with Sumatran serow than Japanese serow. Local populations of Formosan serow of Taiwan island and Japanese serow of the Japanese archipelagos are already differentiated. Serow and goral are apparently distinguishable. The results of Principal Component Analysis and Discriminant Analysis show that serows from Taiwan, Japan and mainland China and goral are apparently distinguishable at morphological characters. The variation of morphological analysis may be a good tool to identify serow and goral. From the paleogeology and fossil records of serow of Quaternary, we could infer that ancestors of serow from southwestern mountain of mainland China migrated to Taiwan island and Japanese archipelagos through the land bridge of east Asian islands to mainland China in the early Pleistocene caused by the glaciation of Quaternary, then separated from mainland of east Asia and speciation of serow occured in Taiwan island and Japanese archipelagos after the end of the glaciation of Quaternary.

phylogeny

Capricornis

Bovidae

cranial morphometrics

biogeography

Artiodactyla

mitochondrial DNA

Sexual differences in proteomics of the sonic muscles in three Johnius (Sciaenidae) species.

Nien, Pei-yuang

02 September 2009

Johnius specis (Sciaenidae) in Taiwanese waters include five species, Johnius amblycephalus, Johnius belengerii, Johnius macrohynus, Johnius dussumieri and Johnius distinctus. They are soniferous fishes. Contraction and relaxation of the sonic muscles cause the swim bladder to pulsate thus generating and amplifying the sounds. Among these species, only males of J. belengerii and J. macrohynus possess sonic muscle, whereas both sexes of the other three species possess sonic muscles. Proteomic characteristics in the male and female sonic muscles are studied in order to observe if obvious dimorphism exists. CO1-gene sequences were used to reconstruct the phylogenetic tree for these five species. The evolutionary pathway of this tree should suggest the evolutionary change of the sexual dimorphism in the sonic system. Various indices relating to muscle size were higher in male. 17 protein spots were shown in the 2D page for male and female sonic muscles, including 5 structural proteins (Actin alpha skeletal muscle, Tropomyosin-1, Myosin light chain 2, Myosin light chain 3, Myosin light polypeptide 4) and 10 metabolic proteins (Parvalbumin, ATP synthase subunit beta, GTP cyclohydrolase, creatine kinase isoform £\, Muscle-type creatine kinase, Putative pterin-4-alpha-carbinolamine dehydratase, Beta-1,4-galactosyltransferase, Protein-glutamine gamma-glutamyltransferase 4, Triosephosphate isomerase, creatine kinase1 ) and stress protein(Heat shock protein 70) . Differences in expression between the sexes were discussed. The resulted phylogenetic trees show that J. belengerii and J. macrohynus are more closely related than to the other three species, which are more basal and members not belong to a specific clade. Whether the common ancestor of Johnius possessed the sonic muscles remains unclear.

Johnius distinctus

Johnius dussumieri

sonic muscle

Johnius amblycephalus

phylogeny

proteomics

Rekernelisation algorithms in hybrid phylogenies : a thesis submitted in partial fulfilment of the requirements of the degree for Master of Science in Mathematics at the University of Canterbury /

Collins, Joshua

January 2009

Thesis (M. Sc.)--University of Canterbury, 2009. / Typescript (photocopy). Includes bibliographical references (leaves 73-77) and index. Also available via the World Wide Web.

Phenotypic covariance through geologic time : micro- and macroevolution in the deep-sea Ostracode genus Poseidonamicus /

Hunt, Eugene.

January 2003

Thesis (Ph. D.)--University of Chicago, Committee on Evolutionary Biology, August 2003. / Includes bibliographical references. Also available on the Internet.

Complete Genome Sequences and Phylogeny of West Nile Virus Isolates from Southeastern United States, 2003-2012

Wedin, Crystal

01 January 2013

The study of the evolution and phylogeny of West Nile virus (WNV) has been an important area of research since the introduction of WNV in 1999. However, genome sequencing of isolates from the Southeastern part of the United States has been somewhat limited. To determine how WNV has evolved at a more localized level, ten isolates from Florida and Georgia from 2003-2012 were completely sequenced using Illumina's next-generation technology. In addition, a phylogenetic comparison of both the complete genome and select partial genomes was completed to ensure consistency among the results. This study further demonstrated the dominance of the North American WN02 genotype within the Southeastern United States. In addition, phylogenetic analyses revealed the continued presence of genetic variance in 2012 with the finding of a new group within the North American clade. In conclusion, WNV has continued to evolve within the Southeastern US.

evolution

Flavivirus

phylogeny

sequencing

West Nile virus

Virology

Phylogeny and evolutionary ecology of thalassiosiroid diatoms

Alverson, Andrew James

05 August 2013

Salinity is a significant barrier to the distribution of diatoms, and though it is generally understood that diatoms are ancestrally marine, the number of times diatoms independently colonized fresh waters and the adaptations that facilitated these colonizations remain outstanding questions in diatom evolution. Resolving the exact number of freshwater colonizations will require large-scale phylogenetic reconstruction with dense sampling of marine and freshwater taxa. A more tractable approach to understanding the marine--freshwater barrier is to study a group of diatoms with high diversity in each habitat. The "centric" diatom order Thalassiosirales affords an excellent opportunity to study the origin and evolution of diatoms in fresh waters. Thalassiosirales is a well-supported monophyletic group common in marine, brackish, and freshwater habitats. Thalassiosirales species historically are classified into the marine Thalassiosiraceae or freshwater Stephanodiscaceae, reflecting the more generally held hypothesis that diatoms are naturally split along marine--freshwater lines. The fossil record suggests that Stephanodiscaceae traces to a single colonization of freshwater in the mid-Miocene, and in addition, Stephanodiscaceae species share a suite of complex cell wall characters, which has been interpreted as corroborating evidence for their monophyly. I reconstructed the phylogeny of Thalassiosirales and used the phylogeny to test these and other hypotheses and to address a number of other problems related to the marine--freshwater boundary in diatoms. Phylogenetic analyses showed strong evidence for multiple colonizations of freshwater and reject all previous colonization hypotheses. Results further show that part of Stephanodiscaceae is an early diverging lineage within Thalassiosirales, indicating that these two distantly related and separately derived Stephanodiscaceae lineages independently evolved a similar set of complex morphological features upon or shortly after the colonization of fresh waters. Finally, marine and freshwater diatoms, including Thalassiosirales, show several important differences in silicon physiology. In addition to containing an order of magnitude more silica in their cell walls, freshwater diatoms have a drastically lower enzymatic affinity for silicic acid, the dissolved form of silica used by diatoms. I sequenced the silicon transporter genes from marine and freshwater Thalassiosirales and show that physiological differences are not due to differences in the coding sequence. / text

Diatoms

Phylogeny

Thalassiosirales

Marine water

Freshwater

Salt water

Evolution

Stephanodiscaceae

Fossils, phylogeny, and anatomical regions : insights exemplified through turtles

Burroughs, Robert Wayne

15 November 2013

There are more than 300 species of extant turtles, the majority of which belong to the Testudinoidea. Here I describe a new box turtle from the Eocene-Oligocene boundary of west Texas. This specimen impacts the phylogeny of Testudinoid turtles by pulling the divergence of extant Testudinoid turtles back in time approximately 25 million years. This results in a need to refocus on paleontological research of Testudinoid turtles into the late Paleogene and early Neogene to identify fossil localities and specimens that can help further elucidate the evolution of the group. New work on the fossil record of turtles also requires a re-evaluation of methods used for identifying and evaluating the evolutionary history of turtles as a group. An implicit assumption over the last 150 years of turtle paleontology was that both turtle shells and turtle heads reveal congruent and complimentary evolutionary relationships. This assumption was never adequately tested. I utilized a series of methods to evaluate the congruency of phylogenetic hypotheses using disparate anatomical regions. Using a dataset of extant Emydid turtles, I evaluated whether turtle shells and turtle heads provided congruent and complimentary phylogenetic hypotheses. My methods employed parsimony-based reconstruction, maximum-likelihood-based reconstruction, and Bayesian-based reconstruction, including Bayesian-partition analyses. My conclusions are that heads and shells do not provide fully congruent topologies, and that in many cases there is a loss of phylogenetic resolution when only turtle sklls are used to generate phylogenies. The implication is that a focus on a robust and complete dataset of anatomical features will provide the best basis for further investigation of fossils. My work also provides a framework for dataset exploration by providing a method to identify the most robust phylogenetic signal found within a dataset. This framework will allow non-turtle paleontologists and systematists the ability to further investigate their own datasets and develop robust hypotheses of evolutionary relationships across the diversity of the tree of Life. / text

Paleontology

Herpetology

Phylogeny

Box turtle

Anatomical region

Bayesian analysis

The molecular phylogeny of Pectis L. (Tageteae, Asteraceae), with implications for taxonomy, biogeography, and the evolution of C4 photosynthesis

Hansen, Debra Rae

18 November 2013

This study examines the evolutionary history of Pectis L., a neotropical genus of ~90 species of xeric-adapted, herbaceous, annuals and perennials. Pectis is rare among the Asteraceae, as it uses C₄ photosynthesis, a complex suite of traits that concentrates carbon around Rubisco. Plants with C₄ photosynthesis do well in environments of high light and high heat, and the C₄ syndrome is thought to have evolved as a response to such environments. Pectis is most diverse in Mexico, the Caribbean Islands, and South America, and its distribution mirrors the disjunctions of patches of desert, thornscrub, coastal plains, savanna, and openings in seasonally-dry tropical forests and oak-pine woodlands. Vicariance and long-distance dispersal theories can explain the patchy distribution of xeric-adapted plants, as well as the origin of Caribbean species. To answer evolutionary questions about a group, one must understand how its members are related. The most comprehensive taxonomic treatment of Pectis is over 100 years old, and includes only North American species. Recent revisions still leave half the species unassigned to section. Molecular studies have found Pectis sister to, or encompassing, the genus Porophyllum. To infer evolutionary relationships between and within Pectis and Porophyllum, DNA from the nuclear and chloroplast genomes of 78 Pectis and 22 Porophyllum species were sampled, sequenced, and analyzed. The molecular phylogeny was used to suggest updated sections based on monophyletic groups. To infer the photosynthetic pathway of Pectis and Porophyllum species, carbon isotope ratios were obtained from 62 Pectis and 18 Porophyllum species. The timing and location of the evolution of Pectis and Porophyllum has implications for the evolution of C₄ photosynthesis. The carbon isotope data were combined with the phylogeny to determine the extent and direction of the evolution of C₄ photosynthesis, and the timing of its evolution was inferred from a fossil-calibrated analysis using chloroplast data from species across the Asteraceae. Distribution data was combined with the Pectis phylogeny to answer questions regarding the biogeographical history of Pectis, including questions regarding its disjuncted distribution, the timing of the evolution of desert species, and the timing and pattern of dispersal to and from the Caribbean Islands. / text

Asteraceae

Biogeography

C₄ photosynthesis

Pectis

Phylogeny

Porophyllum

Tageteae

Emerging epizootic diseases of amphibians and fish : approaches to understanding Ranavirus emergence and spread

Abrams McLean, Audrey Jeanine

25 February 2014

Ranaviruses are large dsDNA viruses that are considered emerging pathogens, and they are known to cause mortality events in amphibian and fish populations. This research utilizes experimental and genomic data to elucidate the mechanisms driving the evolution and spread of ranaviruses, with a focus on host switching within the genus. In Chapter 1, we utilize virus challenge assays to examine potential transfer of ranaviruses between cultured juvenile largemouth bass (M. salmoides) and bullfrog tadpoles (Rana catesbeiana). Additionally, a commonly used antiparasitic treatment containing malachite green and formalin (MGF) was utilized to suppress the immune system of largemouth bass to assess the susceptibility of immunocompromised fish to ranaviruses. The results indicate that tadpoles are not susceptible to Largemouth Bass Virus (LMBV), but that bass are susceptible to ranaviruses isolated from amphibians. Furthermore, immunocompromised fish were more susceptible to both LMBV and FV3 infections than immunocompetent fish. In Chapter 2, we used eight sequenced ranavirus genomes and two selection-detection methods (site-based and branch-based) to identify genes that exhibited signatures of positive selection, potentially due to the selective pressures at play during host switching. We found evidence of positive selection acting on four genes via the site-based method, three of which are newly-acquired genes unique to ranavirus genomes. Our results suggest that the group of newly acquired genes in the ranavirus genome may have undergone recent adaptive changes that have facilitated interspecies and interclass host switching. In Chapter 3, we annotated and analyzed the nearly complete genomic sequence of LMBV to determine its taxonomic classification. The available genomic content and phylogenetic evidence suggests that LMBV is more closely related to amphibian-like ranaviruses (ALRVs) than grouper ranaviruses, and this is further supported by greater genomic collinearity between LMBV and ALRVs. This data suggests that the classification of LMBV as a ranavirus is warranted. The results presented here will help to clarify the taxonomic relationships of ranaviruses, and will also be useful in developing management strategies to limit interspecific and intraspecific viral spread. The information garnered from this research will have far-reaching implications in studies of amphibian conservation, disease evolution, and virology. / text

Ranavirus

Adaptive evolution

Phylogeny

Host switching

Viral challenge assay

PRRSV-webtool: a web-based database and phylogenetic tool to study molecular epidemiology and evolution ofporcine reproductive and respiratory syndrome virus, and related tooland algorithm

Wong, Lai-yin, Charles., 王禮賢.

January 2013

Porcine Reproductive and Respiratory Syndrome virus (PRRSV) causes the disease - Porcine Reproductive and Respiratory Syndrome (PRRS) which is one of the most economically important diseases for pig farmers. Since it was discovered in the United States and Europe, it has quickly affected the swine industry all over the world. Studying and controlling PRRSV has become an important issue in swine industry and scientific community, and has raised the concerns of governments like US and China. By using different bioinformatics and phylogenetics tools, scientists could understand the epidemiology and evolution of PRRSV from genomic data. However, a well-designed database for PRRSV sequence and relevant meta-information are generally required for the tools to produce insightful results. Therefore, I would like to introduce an easily accessible web platform for PRRSV analysis - PRRSV-Webtool. The core component of PRRSV-Webtool is phylogenetic reconstruction. Instead of using traditional phylogenetic reconstruction, a new method of reconstruction was introduced - Reconstruction by Addition of Taxon (RAT). RAT could build a phylogenetic tree from known existing phylogeny. Simulation tests were performed to evaluate the accuracies of RAT using PRRSV dataset. The percentages of correct branch reconstruction are 73.81% for type 1 PRRSV dataset and 80.68% for type 2 PRRSV dataset. Another important function of PRRSV-Webtool is genotyping. RAT could correctly identify the genotype of all sequences in the testing datasets. PRRSV-Webtool combined three main components: database, phylogenetic tool and World Wide Web. By using PRRSV-Webtool, the users can study their own PRRSV genome data easily via the web browser. Tools in PRRSV-Webtool can allow users to know more about their PRRSV isolates related to other field samples. With our PRRSV-Webtool, scientists and veterinaries can help to improve their understanding of PRRSV and help to control the virus by accelerating the process of virus surveillance and field sampling. / published_or_final_version / Biological Sciences / Master / Master of Philosophy

Viruses - Phylogeny.

Swine - Virus diseases.