Molecular evolution and phylogeny of methanogenic archael genomes

Li, Jun, 李俊

January 2014

Methane (CH4) is the major chemical component of natural gas, as well as a particularly potent greenhouse gas. Methanogens are the archaeal organisms that produce methane and play a key role in biological methanogenesis. A total of six taxonomic orders of archaeal methanogens have been discovered and almost all previous phylogenetics studies have confirmed that these methanogens are genetically diversified and do not belong to a phylogenetically monophyletic group. To date, the relationships between methanogens and closely related non-methanogen species at the taxonomic order level remain unresolved and different studies have often produced contradictory results based on different gene markers. These studies suggest the complicated and distinct evolutionary histories between different genes in these genomes. In this thesis, 74 fully sequenced archaeal genomes, including 41 methanogens, were collected and used in a comprehensive comparative genomics and evolutionary analysis. First, numerous phylogenomic trees were reconstructed based on various datasets using several methods and the results show that Methanopyrales is close to Methanobacteriales (or Methanopyrales) in the statistically best species tree. In addition, Methnocellales and Methanosarcinales, and as well as Methanomicrobiales and Halobacteriales are sister clades in the best species tree, but the confidence level is low. Further incongruence tests among the phylogenetic forest, which is composed of 3,694 ortholog gene families, reveal that the archaeal core genes have much stronger consistent vertical evolutionary signals than other genes, but these core genes are not topologically fully congruent with each other. Secondly, a series of weighted network analyses were implemented to decompose the hierarchical structure and to reveal the co-evolved gene modules, global and local features in the archaeal methanogen phylogenetic forest. The results show that this co-evolution network contains 7 statistical robust modules, and the module with the highest average node strength includes the majority of the core genes located in the central position of the network. Further in-depth evolutionary analysis reveals that the modularized evolution in the archaeal phylogenetic forest is closely related to the time of origin, HGT rate and ubiquitous vertical inheritance in gene families. Lastly, to investigate the causes for and factors related to the pervasive topology incongruence in the phylogenetic forest, in-depth clanistics analysis and HGT detection were carried out. These results show that (1) about 63% of gene families experienced at least 1 HGT event in their whole history; (2) core genes are not immune to HGT but they do have much lower HGT rates than other genes; (3) methanogens have distinct trends of HGTs from non-methanogen species; and (4) highly frequent inter-order HGTs, even for core genes, in methanogen genomes lead to their scrambled phylogenetic relationships. Further clanistics analysis screened out 119 candidate genes related to methanogenic pathways adaptation and most of these gene families have experienced at least one HGT. In conclusion, a complex evolutionary scenario for methanogenic archaeal species was described in this thesis as a combination of complicated vertical and non-vertical evolutionary processes in a modularized phylogenetic forest. / published_or_final_version / Biological Sciences / Doctoral / Doctor of Philosophy

Methanobacteriaceae - Genetics

Tolerance limits and survival potential of methanogenic archaea from Siberian permafrost under extreme living conditions = Toleranzgrenzen und Überlebensstrategien von methanogenen Archaeen aus sibirischen Permafrosthabitaten unter Extrembedingungen /

Morozova, Daria.

January 2007

Thesis (doctoral)--Universität Potsdam, 2007. / Includes bibliographical references (p. 71-82).

Archaebacteria Methanobacteriaceae

Tolerance limits and survival potential of methanogenic archaea from Siberian permafrost under extreme living conditions = Toleranzgrenzen und Überlebensstrategien von methanogenen Archaeen aus sibirischen Permafrosthabitaten unter Extrembedingungen /

Morozova, Daria.

January 2007

Univ., Diss.--Potsdam, 2007. / Enth. außerdem 4 Papers.

Archaebacteria Methanobacteriaceae

The molecular biology of methanogens: cell lysis, plasmid survey and the characterization of a novel plasmid.

Meakin, Stephanie Asalyn, Carleton University. Dissertation. Biology.

January 1992

Thesis (M. Sc.)--Carleton University, 1992. / Also available in electronic format on the Internet.

Methanobacteriaceae. Plasmids

The development of an integrated anaerobic system for the cultivation and characterization of methanogenic bacteria /

Corder, Robert Elwin

January 1982

No description available.

Biology

Methanobacteriaceae

The microbial composition of a natural methanogenic consortium.

Mashaphu, Nthabiseng

January 2005

Wetlands account for approximately 20% of annual global methane emissions. Many wetlands receive inputs of organic matter, nutrients, metals and various toxic compounds from adjacent agricultural and industrial areas. The present study aimed to investigate the microbial composition of a natural methanogenic consortium. A consortium-based molecular approach to study diversity of methanogenic microbial communities in a natural wetland at the primary inflow was used. Key microorganisms of a nethane producing consortium were identified. Extracted high molecular mss DNA ws analysed by PCR combined with denaturing gradient gel electrophoresis and subsequent sequencing of 16S rDNA. This study was also aimed to identify syntrophic microorganisms in the wetland system. The data obtained suggest a well established syntrophic relationship within the wetland.

Methanobacteriaceae

Microbial populations.

The effect of environmental conditions on the reductive dechlorination of pentachlorophenol by a mixed, methanogenic culture

Stuart, Sheryl L.

28 October 1996

Graduation date: 1997

Pentachlorophenol

Methanobacteriaceae

Chlorination

The microbial composition of a natural methanogenic consortium.

Mashaphu, Nthabiseng

January 2005

Wetlands account for approximately 20% of annual global methane emissions. Many wetlands receive inputs of organic matter, nutrients, metals and various toxic compounds from adjacent agricultural and industrial areas. The present study aimed to investigate the microbial composition of a natural methanogenic consortium. A consortium-based molecular approach to study diversity of methanogenic microbial communities in a natural wetland at the primary inflow was used. Key microorganisms of a nethane producing consortium were identified. Extracted high molecular mss DNA ws analysed by PCR combined with denaturing gradient gel electrophoresis and subsequent sequencing of 16S rDNA. This study was also aimed to identify syntrophic microorganisms in the wetland system. The data obtained suggest a well established syntrophic relationship within the wetland.

Methanobacteriaceae

Microbial populations.

Osmotics of halophilic methanogenic archaeobacteria /

Menaia, Jose Antonio Gomes Ferreira,

January 1992

Thesis (Ph. D.), Oregon Graduate Institute of Science & Technology, 1992.

Studies on two nickel-containing enzymes from Methanosarcina thermophila TM-1 /

Jablonski, Peter Edward,

January 1992

Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1992. / Vita. Abstract. Includes bibliographical references (leaves 148-161). Also available via the Internet.