Diversity and salinity adaptations of ammonia oxidizing archaea in three estuaries of China

Spatio-temporal variability of nitrogen-cycling potentials in particle-attached and free-living microbial communities in the Yangtze River estuary and adjacent regions

Particle-attached (PA) and free-living (FL) microorganisms regulate coastal biogeochemical cycles, yet their roles in nitrogen transformation remain unclear. To address this knowledge gap, we seasonally sampled PA and FL from seawater along salinity gradients in the Yangtze River estuary (YRE) and adjacent regions to investigate the spatio-temporal variability of microbial communities, abundances of nitrogen-cycling genes, and key microbial groups affiliated with the nitrogen cycle in PA and FL. Compared to FL, the composition, structure and diversity of PA exhibited more pronounced variations in response to salinity and [NO3-]. Metagenomic analyses indicated a predominant role of denitrification in both PA and FL, with greater abundances of genes involved in most nitrogen transformation processes observed in the estuarine region. The potential for the nitrogen cycle in PA was relatively lower in May, while greater in FL, potentially due to competition for nitrogen substrates between PA and phytoplankton during spring. PERMANOVA and Mantel tests showed that gene abundances exhibited spatio-temporal dynamics and were associated with species and environmental factors. Gene-affiliated taxa identification and the Weighted Correlation Network Analysis revealed that the differences in environmental factors and taxa responsible for the nitrogen transformation drove spatio-temporal variations of the nitrogen cycle between PA and FL, and implied the significance of their interaction in nitrogen fates in coastal ecosystem. Gammaproteobacteria and Betaproteobacteria were highly affiliated with nitrogen-cycling genes, while Nitrososphaeria played an important role in nitrification and denitrification. This study offered practical insights for mitigating eutrophication through targeted regulation of microbial-mediated nitrogen fluxes.

Nitrosarchaeum haohaiensis sp. Nov. CL1T: Isolation and Characterisation of a Novel Ammonia-Oxidising Archaeon From Aquatic Environments

Following a 3.5-year enrichment cultivation period, a novel ammonia-oxidising archaeon (AOA), designated strain CL1T, was isolated from Yangshan Harbour (East China Sea). Strain CL1T demonstrates a maximum ammonia tolerance of up to 10 mM. Its optimal growth conditions include a pH range of 7-8, a salinity of 2%-3%, and a temperature range of 20°C-25°C. Under these conditions, strain CL1T achieved a maximum specific growth rate of 0.87 d-1, with cell yields estimated at 3.92 × 106 cells mL-1 μM ammonia-1. Genomic sequencing revealed that strain CL1T possesses a genome size of 1.63 megabases with a high completeness of 99.95%. Phylogenetic analysis based on the 16S rRNA gene and whole-genome data placed strain CL1T within the genus Nitrosarchaeum. The average nucleotide identity (ANI) between the genome of strain CL1T and its closest relative was 92.01%, confirming that strain CL1T represents a novel species within Nitrosarchaeum. Metabolic pathway analysis demonstrated that strain CL1T encodes key enzymes for ammonia oxidation, including ammonia monooxygenase (amoA, amoB, amoC) and copper oxidase, indicating its capacity for ammonia oxidation. Additionally, strain CL1T likely assimilates ammonia through the GS-GOGAT and GDH pathways. Consistent with the observation of extracellular vesicles (EVs) in strain CL1T via electron microscopy, genome annotation identified core genes associated with EVs function, such as vps4 and FtsZ. The isolation of strain CL1T provides a valuable model system for investigating its ammonia metabolism and exploring its ecological interactions with other AOA, ammonia-oxidising bacteria (AOB) and nitrite-oxidising bacteria (NOB), thereby contributing to a deeper understanding of nitrogen cycling mechanisms in aquatic environments.

The archaeal and bacterial community structure in composted cow manures is defined by the original populations: a shotgun metagenomic approach

Introduction

Organic wastes are composted to increase their plant nutritional value, but little is known about how this might alter the bacterial and archaeal community structure and their genes.

Methods

Cow manure was collected from three local small-scale farmers and composted under controlled conditions, while the bacterial and archaeal communities were determined using shotgun metagenomics at the onset and after 74 days of composting.

Results

The bacterial, archaeal, methanogen, methanotrophs, methylotroph, and nitrifying community structures and their genes were affected by composting for 74 days, but the original composition of these communities determined the changes. Most of these archaeal and bacterial groups showed considerable variation after composting and between the cow manures. However, the differences in the relative abundance of their genes were much smaller compared to those of the archaeal or bacterial groups.

Discussion

It was found that composting of different cow manures did not result in similar bacterial or archaeal communities, and the changes that were found after 74 days were defined by the original populations. However, more research is necessary to determine if other composting conditions will give the same results.

Do restoration strategies in mangroves recover microbial diversity? A case study in the Yucatan peninsula

Mangrove forests are fundamental coastal ecosystems for the variety of services they provide, including green-house gas regulation, coastal protection and home to a great biodiversity. Mexico is the fourth country with the largest extension of mangroves of which 60% occurs in the Yucatan Peninsula. Understanding the microbial component of mangrove forests is necessary for their critical roles in biogeochemical cycles, ecosystem health, function and restoration initiatives. Here we study the relation between the microbial community from sediments and the restoration process of mangrove forests, comparing conserved, degraded and restored mangroves along the northern coast of the Yucatan peninsula. Results showed that although each sampling site had a differentiated microbial composition, the taxa belonged predominantly to Proteobacteria (13.2-23.6%), Desulfobacterota (7.6-8.3%) and Chloroflexi (9-15.7%) phyla, and these were similar between rainy and dry seasons. Conserved mangroves showed significantly higher diversity than degraded ones, and restored mangroves recovered their microbial diversity from the degraded state (Dunn test p-value Benjamini-Hochberg adjusted = 0.0034 and 0.0071 respectively). The structure of sediment microbial β-diversity responded significantly to the mangrove conservation status and physicochemical parameters (organic carbon content, redox potential, and salinity). Taxa within Chloroflexota, Desulfobacterota and Thermoplasmatota showed significantly higher abundance in degraded mangrove samples compared to conserved ones. This study can help set a baseline that includes the microbial component in health assessment and restoration strategies of mangrove forests.