Abstract
Methanogenic archaeas are found in aquatic and terrestrial environments and are fundamental in the conversion of organic matter into methane, a gas that has a potential use as renewable source of energy, which is also considered as one of the main agents of the greenhouse effect. The vast majority of microbial genomes can be identified by a conservative molecular marker, the 16S ribosomal gene. However, the mcrA gene have been using in studies of methanogenic archaea diversity as an alternative marker, highly conserved and present only in methanogens. This gene allows the expression of the enzyme Methyl-coenzyme M reductase, the main agent in converting by-products of anaerobic digestion into methane. In this context, we aimed to study the genetic diversity of mcrA and 16S rRNA genes sequences available in databases. The nucleotide sequences were selected from the NCBI. The heterozygosity and molecular diversity indexes were calculated using the Arlequin 3.5 software, with plots generated by package R v3.0. The diversity and heterozygosity indices for both genes may have been influenced by the number and size of the sequences. Descriptive analysis of genetic diversity generated by sequences deposited in databases allowed a detailed study of these molecules. It is known that the organisms in a population are genetically distinct, and that, despite having similarities in their gene composition, the differences are essential for their adaptation to different environments.
Highlights
Archaea is a domain present in the tree of life
We aimed to study the genetic diversity of mcrA and 16S rRNA genes sequences available in databases
Descriptive analysis of genetic diversity generated by sequences deposited in databases allowed a detailed study of these molecules
Summary
Archaea is a domain present in the tree of life. This group, considered polymorphic, is directly involved in the anaerobic digestion process and is responsible for performing methanogenesis steps. Hydrogenotrophic methanogenic archaea are capable of converting hydrogen and carbon dioxide into methane, while acetoclastic methanogenic archaea converts acetate to methane (Amaral, Steinmetz, & Kunz, 2019). Studies of these organisms are carried out mainly through metagenomics, because cultivation in laboratory is difficult. The current knowledge about archaea is due to the development of a way to study environmental samples without the need to cultivate microorganisms. There is currently a wide range of metagenomic data that can be accessed at several databases, such as NCBI – (National Center for Biotechnology Information), and which allows various microbiome studies to be performed
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