Nitrate Respiration in Thermus thermophilus NAR1: from Horizontal Gene Transfer to Internal Evolution

Nitrate reduction to ammonium: a phylogenetic, physiological, and genetic aspects in Prokaryotes and eukaryotes

The microbe-mediated conversion of nitrate (NO3-) to ammonium (NH4+) in the nitrogen cycle has strong implications for soil health and crop productivity. The role of prokaryotes, eukaryotes and their phylogeny, physiology, and genetic regulations are essential for understanding the ecological significance of this empirical process. Several prokaryotes (bacteria and archaea), and a few eukaryotes (fungi and algae) are reported as NO3- reducers under certain conditions. This process involves enzymatic reactions which has been catalysed by nitrate reductases, nitrite reductases, and NH4+-assimilating enzymes. Earlier reports emphasised that single-cell prokaryotic or eukaryotic organisms are responsible for this process, which portrayed a prominent gap. Therefore, this study revisits the similarities and uniqueness of mechanism behind NO3- -reduction to NH4+ in both prokaryotes and eukaryotes. Moreover, phylogenetic, physiological, and genetic regulation also shed light on the evolutionary connections between two systems which could help us to better explain the NO3--reduction mechanisms over time. Reports also revealed that certain transcription factors like NtrC/NtrB and Nit2 have shown a major role in coordinating the expression of NO3- assimilation genes in response to NO3- availability. Overall, this review provides a comprehensive information about the complex fermentative and respiratory dissimilatory nitrate reduction to ammonium (DNRA) processes. Uncovering the complexity of this process across various organisms may further give insight into sustainable nitrogen management practices and might contribute to addressing global environmental challenges.

From accurate genome sequence to biotechnological application: The thermophile Mycolicibacterium hassiacum as experimental model

Mycobacteria constitute a large group of microorganisms belonging to the phylum Actinobacteria encompassing some of the most relevant pathogenic bacteria and many saprophytic isolates that share a unique and complex cell envelope. Also unique to this group is the extensive capability to use and synthesize sterols, a class of molecules that include active signalling compounds of pharmaceutical use. However, few mycobacterial species and strains have been established as laboratory models to date, Mycolicibacterium smegmatis mc2 155 being the most common one. In this work, we focus on the use of a thermophilic mycobacterium, Mycolicibacterium hassiacum, which grows optimally above 50°C, as an emerging experimental model valid to extend our general knowledge of mycobacterial biology as well as for application purposes. To that end, accurate genomic sequences are key for gene mining, the study of pathogenicity or lack thereof and the potential for gene transfer. The combination of long- and short-massive sequencing technologies is strictly necessary to remove biases caused by errors specific to long-reads technology. By doing so in M. hassiacum, we obtained from the curated genome clues regarding the genetic manipulation potential of this microorganism from the presence of insertion sequences, CRISPR-Cas, type VII ESX secretion systems, as well as lack of plasmids. Finally, as a proof of concept of the applicability of M. hassiacum as a laboratory and industrial model, we used this high-quality genome of M. hassiacum to successfully knockout a gene involved in the use of phytosterols as source of carbon and energy, using an improved gene cassette for thermostable selection and a transformation protocol at high temperature.

ThermusQ: Toward the cell simulation platform for Thermus thermophilus

ThermusQ is a website (https://www.thermusq.net/) that aims to gather all the molecular information on Thermus thermophilus and to provide a platform to easily access the whole view of the bacterium. ThermusQ comprises the genome sequences of 22 strains from T. thermophilus and T. oshimai strains, plus the sequences of known Thermus phages. ThermusQ also contains information and map diagrams of pathways unique to Thermus strains. The website provides tools to retrieve sequence data in different ways. By gathering the whole data of T. thermophilus strains, the strainspecific characteristics was found. This bird's-eye view of the whole data will lead the research community to identify missing important data and the integration will provide a platform to conduct future biochemical simulations of the bacterium.

Incomplete denitrification phenotypes in diverse Thermus species from diverse geothermal spring sediments and adjacent soils in southwest China

A few members of the bacterial genus Thermus have been shown to be incomplete denitrifiers, terminating with nitrite (NO₂⁻) or nitrous oxide (N₂O). However, the denitrification abilities of the genus as a whole remain poorly characterized. Here, we describe diverse denitrification phenotypes and genotypes of a collection of 24 strains representing ten species, all isolated from a variety of geothermal systems in China. Confirmed terminal products of nitrate reduction were nitrite or N₂O, while nitric oxide (NO) was inferred as the terminal product in some strains. Most strains produced N₂O; complete denitrification was not observed. Denitrification phenotypes were largely consistent with the presence of denitrification genes, and strains of the same species often had the same denitrification phenotypes and largely syntenous denitrification gene clusters. Genes for nirS and nirK coexisted in three Thermus brockianus and three Thermus oshimai genomes, which is a unique hallmark of some denitrifying Thermus strains and may be ecologically important. These results show that incomplete denitrification phenotypes are prominent, but variable, within and between Thermus species. The incomplete denitrification phenotypes described here suggest Thermus species may play important roles in consortial denitrification in high-temperature terrestrial biotopes where sufficient supply of oxidized inorganic nitrogen exists.

Genomic characterization of denitrifying methylotrophic Pseudomonas aeruginosa strain AAK/M5 isolated from municipal solid waste landfill soil

Municipal landfills are known for methane production and a source of nitrate pollution leading to various environmental issues. Therefore, this niche was selected for the isolation of one-carbon (C1) utilizing bacteria with denitrifying capacities using anaerobic enrichment on nitrate mineral salt medium supplemented with methanol as carbon source. Eight axenic cultures were isolated of which, isolate AAK/M5 demonstrated the highest methanol removal (73.28%) in terms of soluble chemical oxygen demand and methane removal (41.27%) at the expense of total nitrate removal of 100% and 33% respectively. The whole genome characterization with phylogenomic approach suggested that the strain AAK/M5 could be assigned to Pseudomonas aeruginosa with close neighbours as type strains DVT779, AES1M, W60856, and LES400. The circular genome annotation showed the presence of complete set of genes essential for methanol utilization and complete denitrification process. The study demonstrates the potential of P. aeruginosa strain AAK/M5 in catalysing methane oxidation thus serving as a methane sink vis-à-vis utilization of nitrate. Considering the existence of such bacteria at landfill site, the study highlights the need to develop strategies for their enrichment and designing of efficient catabolic activity for such environments.

ARAMIS: From systematic errors of NGS long reads to accurate assemblies

NGS long-reads sequencing technologies (or third generation) such as Pacific BioSciences (PacBio) have revolutionized the sequencing field over the last decade improving multiple genomic applications like de novo genome assemblies. However, their error rate, mostly involving insertions and deletions (indels), is currently an important concern that requires special attention to be solved. Multiple algorithms are available to fix these sequencing errors using short reads (such as Illumina), although they require long processing times and some errors may persist. Here, we present Accurate long-Reads Assembly correction Method for Indel errorS (ARAMIS), the first NGS long-reads indels correction pipeline that combines several correction software in just one step using accurate short reads. As a proof OF concept, six organisms were selected based on their different GC content, size and genome complexity, and their PacBio-assembled genomes were corrected thoroughly by this pipeline. We found that the presence of systematic sequencing errors in long-reads PacBio sequences affecting homopolymeric regions, and that the type of indel error introduced during PacBio sequencing are related to the GC content of the organism. The lack of knowledge of this fact leads to the existence of numerous published studies where such errors have been found and should be resolved since they may contain incorrect biological information. ARAMIS yields better results with less computational resources needed than other correction tools and gives the possibility of detecting the nature of the found indel errors found and its distribution along the genome. The source code of ARAMIS is available at https://github.com/genomics-ngsCBMSO/ARAMIS.git.