Genus

About: Genus is a research topic. Over the lifetime, 68921 publications have been published within this topic receiving 590966 citations. The topic is also known as: monospecies genus & genus (zoology).

Phylogeny of some of the major genera of dinoflagellates based on ultrastructure and partial LSU rDNA sequence data, including the erection of three new genera of unarmoured dinoflagellates

Abstract: Evidence from partial large-subunit (LSU) rDNA sequencing has been combined with ultrastructure, including details of the flagellar apparatus, in a number of phototrophic dinoflagellates, with the aim of trying to solve some of the most pressing taxonomic problems and to contribute to an improved understanding of the phylogeny within the group. Special attention has been paid to the unarmoured (naked) genera, many of which were described during the 1800s or early 1900s and whose taxonomy is artificial and misleading. This is particularly unsatisfactory because many of the species cause extensive plankton blooms, fish kills and other harmful events. Our studies have indicated that the path of the so-called apical groove (acrobase) is of particular importance for the taxonomy of the unarmoured genera of dinoflagellates. Features presently used to characterize many of the genera, such as the relative size of the epicone and hypocone, are misleading. Our data have resulted in the splitting of the large genus Gymnodinium into four genera. The fish-killing species are confined to two genera, Karenia G. Hansen & Moestrup gen. nov. and Karlodinium J. Larsen gen. nov. The paralytic shellfish poisoning-producing species Gymnodinium catenatum is retained within Gymnodinium, together with a number of harmless species. The fourth genus, Akashiwo G. Hansen & Moestrup gen. nov., presently comprises only the large nontoxic species previously known as Gymnodinium sanguineum. The genus Gyrodinium is redefined. The genus Amphidinium is artificial, but more data are needed before redescription of the genus can be made with any confidence. Within the armoured dinoflagellates, LSU and previously published small-subunit rDNA data show the Gonyaulacales to be a natural group. Peridiniella catenata, sometimes included in the Gonyaulacales based on gross morphology, falls outside this order both genetically and ultrastructurally. Based on the DNA data, the genus Peridinium appears to be artificial. Ultrastructure as well as gene sequences confirm that the genus Heterocapsa is unusual, since it includes both apparently unarmoured species (but with very thin plates) and armoured species.

The Genus Rhipicephalus (Acari, Ixodidae): A Guide to the Brown Ticks of the World

Abstract: Acknowledgements Introduction Relationships of the ticks (Ixodida) and definition of the genus Rhipicephalus Format for accounts of different species Glossary Rhipicephalus species names of the world Species occurring in the Afrotropical region Species occurring outside the Afrotropical region Species groups based on the immature stages The transmission of tick-borne diseases by Rhipicephalus species Index.

Evolution in the genus Drosophila

Abstract: The most extensive treatment of any living genus thus far attempted, this book deals with the evolution of Drosophila as demonstrated by living forms, and is mainly concerned with isolating mechanisms, genetic systems shown by hybrids and the cytology of over one third of the known species of the genus.

The family Parvoviridae

Abstract: A set of proposals to rationalize and extend the taxonomy of the family Parvoviridae is currently under review by the International Committee on Taxonomy of Viruses (ICTV). Viruses in this family infect a wide range of hosts, as reflected by the longstanding division into two subfamilies: the Parvovirinae, which contains viruses that infect vertebrate hosts, and the Densovirinae, encompassing viruses that infect arthropod hosts. Using a modified definition for classification into the family that no longer demands isolation as long as the biological context is strong, but does require a near-complete DNA sequence, 134 new viruses and virus variants were identified. The proposals introduce new species and genera into both subfamilies, resolve one misclassified species, and improve taxonomic clarity by employing a series of systematic changes. These include identifying a precise level of sequence similarity required for viruses to belong to the same genus and decreasing the level of sequence similarity required for viruses to belong to the same species. These steps will facilitate recognition of the major phylogenetic branches within genera and eliminate the confusion caused by the near-identity of species and viruses. Changes to taxon nomenclature will establish numbered, non-Latinized binomial names for species, indicating genus affiliation and host range rather than recapitulating virus names. Also, affixes will be included in the names of genera to clarify subfamily affiliation and reduce the ambiguity that results from the vernacular use of “parvovirus” and “densovirus” to denote multiple taxon levels.