Fine-Scale Temporal Dynamics of a Fragmented Lotic Microbial Ecosystem

Microbial ecosystems are often assumed to be relatively stable over short periods of time, but this assumption is seldom tested. An urban stream influenced by both flow and varying levels of anthropogenic influences is expected to have high temporal variability in microbial composition, and short-term ecological instability. Thus, we analyzed the bacterioplankton composition of a weir-fragmented urban stream using Automated rRNA Intergenic Spacer Analysis (ARISA). A total of 46 sequential samples were collected in July 2009 for 7 days, every 7 hours, from both the up-stream side of the weir (stream water) and the downstream side of the weir (estuarine) water. Bray-Curtis similarity based analysis showed a clear division between upstream and downstream communities. A sudden pH drop induced change in both communities, but composition stability partially recovered within less than a day. Thus, our results show that microbial ecosystems can change rapidly, but re-establish a new equilibrium relatively quickly

Sediment respiration pulses in intermittent rivers and ephemeral streams

Intermittent rivers and ephemeral streams (IRES) may represent over half the global stream network, but their contribution to respiration and carbon dioxide (CO2) emissions is largely undetermined. In particular, little is known about the variability and drivers of respiration in IRES sediments upon rewetting, which could result in large pulses of CO2. We present a global study examining sediments from 200 dry IRES reaches spanning multiple biomes. Results from standardized assays show that mean respiration increased 32–66‐fold upon sediment rewetting. Structural equation modelling indicates that this response was driven by sediment texture and organic matter quantity and quality, which, in turn, were influenced by climate, land use and riparian plant cover. Our estimates suggest that respiration pulses resulting from rewetting of IRES sediments could contribute significantly to annual CO2 emissions from the global stream network, with a single respiration pulse potentially increasing emission by 0.2–0.7%. As the spatial and temporal extent of IRES increases globally, our results highlight the importance of recognizing the influence of wetting‐drying cycles on respiration and CO2 emissions in stream networks

A global analysis of terrestrial plant litter dynamics in non-perennial waterways

Perennial rivers and streams make a disproportionate contribution to global carbon (C) cycling. However, the contribution of intermittent rivers and ephemeral streams (IRES), which sometimes cease to flow and can dry completely, is largely ignored although they represent over half the global river network. Substantial amounts of terrestrial plant litter (TPL) accumulate in dry riverbeds and, upon rewetting, this material can undergo rapid microbial processing. We present the results of a global research collaboration that collected and analysed TPL from 212 dry riverbeds across major environmental gradients and climate zones. We assessed litter decomposability by quantifying the litter carbon-to-nitrogen ratio and oxygen (O2) consumption in standardized assays and estimated the potential short-term CO2 emissions during rewetting events. Aridity, cover of riparian vegetation, channel width and dry-phase duration explained most variability in the quantity and decomposability of plant litter in IRES. Our estimates indicate that a single pulse of CO2 emission upon litter rewetting contributes up to 10% of the daily CO2 emission from perennial rivers and stream, particularly in temperate climates. This indicates that the contributions of IRES should be included in global C-cycling assessments

Promoter of the Mycoplasma pneumoniae rRNA operon.

RNA transcripts starting from the 5' end of the single Mycoplasma pneumoniae rRNA operon were analyzed by several methods. By primer extension analysis a start site was found 62 nucleotides upstream from the start site of the 16S rRNA. This site was preceded by a putative Pribnow box; however, a defined -35 recognition region was absent. The cloned rRNA operon was transcribed in vitro by using purified RNA polymerase of Escherichia coli. A single start site could be demonstrated within a few nucleotides of the start site found by primer extension analysis of M. pneumoniae transcripts. When fragments from the cloned operon were used as hybridization probes, S1 nuclease mapping yielded a single transcript extending approximately 193 nucleotides upstream from the 16S rRNA start site. The region surrounding this endpoint did not resemble any known promoter sequence. Dot blot hybridization of M. pneumoniae RNA to three oligonucleotides consisting of nucleotides -5 to -21, -38 to -54, and -112 to -132 (from the start of the 16S rRNA gene) indicated that most rRNA transcripts were processed at the stem site preceding the 16S rRNA gene. The majority of the longer precursor transcripts, extending beyond this point, did not extend further upstream to an oligonucleotide consisting of nucleotides -112 to -132. It was concluded that transcription of the rRNA operon of M. pneumoniae is initiated by a single promoter. The nucleotide sequence of the region is presented