Your search keyword '"Berlemont R"' showing total 4 results

1. Microbial legacies alter decomposition in response to simulated global change.

Author

Martiny JB, Martiny AC, Weihe C, Lu Y, Berlemont R, Brodie EL, Goulden ML, Treseder KK, and Allison SD

Subjects

Bacteria genetics, Bacteria growth & development, Carbohydrate Metabolism, Ecosystem, Fungi genetics, Fungi growth & development, Metagenomics, Nitrogen metabolism, Plant Leaves microbiology, Rain, Seasons, Sequence Analysis, DNA, Time Factors, Bacteria classification, Climate Change, Fungi classification, Microbial Consortia

Abstract

Terrestrial ecosystem models assume that microbial communities respond instantaneously, or are immediately resilient, to environmental change. Here we tested this assumption by quantifying the resilience of a leaf litter community to changes in precipitation or nitrogen availability. By manipulating composition within a global change experiment, we decoupled the legacies of abiotic parameters versus that of the microbial community itself. After one rainy season, more variation in fungal composition could be explained by the original microbial inoculum than the litterbag environment (18% versus 5.5% of total variation). This compositional legacy persisted for 3 years, when 6% of the variability in fungal composition was still explained by the microbial origin. In contrast, bacterial composition was generally more resilient than fungal composition. Microbial functioning (measured as decomposition rate) was not immediately resilient to the global change manipulations; decomposition depended on both the contemporary environment and rainfall the year prior. Finally, using metagenomic sequencing, we showed that changes in precipitation, but not nitrogen availability, altered the potential for bacterial carbohydrate degradation, suggesting why the functional consequences of the two experiments may have differed. Predictions of how terrestrial ecosystem processes respond to environmental change may thus be improved by considering the legacies of microbial communities.

Published

2017

2. Microbial response to simulated global change is phylogenetically conserved and linked with functional potential.

Author

Amend AS, Martiny AC, Allison SD, Berlemont R, Goulden ML, Lu Y, Treseder KK, Weihe C, and Martiny JB

Subjects

Bacteria classification, Bacteria isolation & purification, Bacteria metabolism, DNA, Ribosomal genetics, Droughts, Fungi classification, Fungi isolation & purification, Fungi metabolism, Nitrogen analysis, Nitrogen metabolism, Phylogeny, Bacteria genetics, Ecosystem, Fungi genetics, Soil Microbiology

Abstract

The high diversity of microbial communities hampers predictions about their responses to global change. Here we investigate the potential for using a phylogenetic, trait-based framework to capture the response of bacteria and fungi to global change manipulations. Replicated grassland plots were subjected to 3+ years of drought and nitrogen fertilization. The responses of leaf litter bacteria and fungi to these simulated changes were significantly phylogenetically conserved. Proportional changes in abundance were highly correlated among related organisms, such that relatives with approximately 5% ribosomal DNA genetic distance showed similar responses to the treatments. A microbe's change in relative abundance was significantly correlated between the treatments, suggesting a compromise between numerical abundance in undisturbed environments and resistance to change in general, independent of disturbance type. Lineages in which at least 90% of the microbes shared the same response were circumscribed at a modest phylogenetic depth (τD 0.014-0.021), but significantly larger than randomized simulations predict. In several clades, phylogenetic depth of trait consensus was higher. Fungal response to drought was more conserved than was response to nitrogen fertilization, whereas bacteria responded equally to both treatments. Finally, we show that a bacterium's response to the manipulations is correlated with its potential functional traits (measured here as the number of glycoside hydrolase genes encoding the capacity to degrade different types of carbohydrates). Together, these results suggest that a phylogenetic, trait-based framework may be useful for predicting shifts in microbial composition and functioning in the face of global change.

Published

2016

3. Temporal variation overshadows the response of leaf litter microbial communities to simulated global change.

Author

Matulich KL, Weihe C, Allison SD, Amend AS, Berlemont R, Goulden ML, Kimball S, Martiny AC, and Martiny JB

Subjects

Biomass, California, Carbon Cycle, Climate, Droughts, Ecosystem, Nitrogen chemistry, Plants, RNA, Ribosomal, 16S genetics, RNA, Ribosomal, 28S genetics, Seasons, Sequence Analysis, DNA, Bacteria classification, Fungi classification, Plant Leaves microbiology, Soil Microbiology

Abstract

Bacteria and fungi drive the decomposition of dead plant biomass (litter), an important step in the terrestrial carbon cycle. Here we investigate the sensitivity of litter microbial communities to simulated global change (drought and nitrogen addition) in a California annual grassland. Using 16S and 28S rDNA amplicon pyrosequencing, we quantify the response of the bacterial and fungal communities to the treatments and compare these results to background, temporal (seasonal and interannual) variability of the communities. We found that the drought and nitrogen treatments both had significant effects on microbial community composition, explaining 2-6% of total compositional variation. However, microbial composition was even more strongly influenced by seasonal and annual variation (explaining 14-39%). The response of microbial composition to drought varied by season, while the effect of the nitrogen addition treatment was constant through time. These compositional responses were similar in magnitude to those seen in microbial enzyme activities and the surrounding plant community, but did not correspond to a consistent effect on leaf litter decomposition rate. Overall, these patterns indicate that, in this ecosystem, temporal variability in the composition of leaf litter microorganisms largely surpasses that expected in a short-term global change experiment. Thus, as for plant communities, future microbial communities will likely be determined by the interplay between rapid, local background variability and slower, global changes.

Published

2015

4. Insights into bacterial cellulose biosynthesis by functional metagenomics on Antarctic soil samples.

Author

Berlemont R, Delsaute M, Pipers D, D'Amico S, Feller G, Galleni M, and Power P

Subjects

Amino Acid Sequence, Antarctic Regions, Cellobiose metabolism, Cellulase isolation & purification, Cellulose biosynthesis, DNA, Bacterial isolation & purification, Enzyme Stability, Hydrogen-Ion Concentration, Molecular Sequence Data, Phylogeny, Sequence Analysis, DNA, Sequence Homology, Amino Acid, Substrate Specificity, Temperature, Carboxymethylcellulose Sodium metabolism, Cellulase genetics, DNA, Bacterial genetics, Genes, Bacterial, Soil Microbiology

Abstract

In this study, the mining of an Antarctic soil sample by functional metagenomics allowed the isolation of a cold-adapted protein (RBcel1) that hydrolyzes only carboxymethyl cellulose. The new enzyme is related to family 5 of the glycosyl hydrolase (GH5) protein from Pseudomonas stutzeri (Pst_2494) and does not possess a carbohydrate-binding domain. The protein was produced and purified to homogeneity. RBcel1 displayed an endoglucanase activity, producing cellobiose and cellotriose, using carboxymethyl cellulose as a substrate. Moreover, the study of pH and the thermal dependence of the hydrolytic activity shows that RBcel1 was active from pH 6 to pH 9 and remained significantly active when temperature decreased (18% of activity at 10 degrees C). It is interesting that RBcel1 was able to synthetize non-reticulated cellulose using cellobiose as a substrate. Moreover, by a combination of bioinformatics and enzyme analysis, the physiological relevance of the RBcel1 protein and its mesophilic homologous Pst_2494 protein from P. stutzeri, A1501, was established as the key enzymes involved in the production of cellulose by bacteria. In addition, RBcel1 and Pst_2494 are the two primary enzymes belonging to the GH5 family involved in this process.

Published

2009