Organic micropollutant removal in full-scale rapid sand filters used for drinking water treatment in The Netherlands and Belgium

Biological treatment processes have the potential to remove organic micropollutants (OMPs) during water treatment. The OMP removal capacity of conventional drinking water treatment processes such as rapid sand filters (RSFs), however, has not been studied in detail. We investigated OMP removal and transformation product (TP) formation in seven full-scale RSFs all treating surface water, using high-resolution mass spectrometry based quantitative suspect and non-target screening (NTS). Additionally, we studied the microbial communities with 16S rRNA gene amplicon sequencing (NGS) in both influent and effluent waters as well as the filter medium, and integrated these data to comprehensively assess the processes that affect OMP removal. In the RSF influent, 9 to 30 of the 127 target OMPs were detected. The removal efficiencies ranged from 0 to 93%. A data-driven workflow was established to monitor TPs, based on the combination of NTS feature intensity profiles between influent and effluent samples and the prediction of biotic TPs. The workflow identified 10 TPs, including molecular structure. Microbial community composition analysis showed similar community composition in the influent and effluent of most RSFs, but different from the filter medium, implying that specific microorganisms proliferate in the RSFs. Some of these are able to perform typical processes in water treatment such as nitrification and iron oxidation. However, there was no clear relationship between OMP removal efficiency and microbial community composition. The innovative combination of quantitative analyses, NTS and NGS allowed to characterize real scale biological water treatments, emphasizing the potential of bio-stimulation applications in drinking water treatment. © 2020 The Author

In Vivo SELEX of Single-Stranded Domains in the HIV-1 Leader RNA

The 5' untranslated leader region of the human immunodeficiency virus type 1 (HIV-1) RNA genome is a strongly conserved sequence that encodes several regulatory motifs important for viral replication. Most of these motifs are exposed as hairpin structures, including the dimerization initiation signal (DIS), the major splice donor site (SD), and the packaging signal (psi), which are connected by short single-stranded regions. Mutational analysis revealed many functions of these hairpins, but only a few studies have focused on the single-stranded purine-rich sequences. Using the in vivo SELEX (systematic evolution of ligands by exponential enrichment) approach, we probed the sequence space in these regions that is compatible with efficient HIV-1 replication and analyzed the impact on the RNA secondary structure of the leader RNA. Our results show a strong sequence requirement for the DIS hairpin flanking regions. We postulate that these sequences are important for the binding of specific protein factors that support leader RNA-mediated functions. The sequence between the SD and psi hairpins seems to have a less prominent role, despite the strong conservation of the stretch of 5 A residues in natural isolates. We hypothesize that this may reflect the subtle evolutionary pressure on HIV-1 to acquire an A-rich RNA genome. In silico analyses indicate that sequences are avoided in all 3 single-stranded domains that affect the local or overall leader RNA folding. IMPORTANCE Many regulatory RNA sequences are clustered in the untranslated leader domain of the HIV-1 RNA genome. Several RNA hairpin structures in this domain have been proposed to fulfill specific roles, e. g., mediating RNA dimer formation to facilitate HIV-1 recombination. We now focus on the importance of a few well-conserved single-stranded sequences that connect these hairpins. We created libraries of HIV-1 variants in which these segments were randomized and selected the best-replicating variants. For two segments we document the selection of the (nearly) wild-type sequence, thus demonstrating the importance of these primary nucleotide sequences and the power of the in vivo SELEX approach. However, for the third segment a large variety of sequences is compatible with efficient HIV-1 replication. Interestingly, the A-rich sequence of this segment is highly conserved among HIV-1 isolates, which likely reflects the evolutionary tendency of HIV-1 to adopt A-rich sequence

Milieuwinst en waterkwaliteitseffecten van thermische energie uit drinkwater

Vrijwel alle drinkwaterbedrijven hebben ambities voor een klimaatneutrale bedrijfsvoering. Een aantal drinkwaterbedrijven probeert met opwekking van duurzame energie hun CO2-voetafdruk te verlagen. Een bijzondere manier van energieopwekking is de levering van thermische energie uit drinkwater, kortweg TED. Toepassing van TED moet een positieve milieu-impact hebben en de drinkwaterkwaliteit mag nooit in gevaar komen. Daarom is het voor drinkwaterbedrijven belangrijk om meer inzicht te krijgen in de risico’s van deze technologie. KWR Watercycle Research Institute heeft twee bestaande TED-systemen nader onderzocht op microbiologische risico’s, economisch rendement en milieu-impact (LCA). In dit artikel zijn de resultaten van het onderzoek kort samengevat

HIV-1 splicing at the major splice donor site is restricted by RNA structure

The 5' leader region of the HIV-1 RNA contains the major 5' splice site (ss) that is used in the production of all spliced viral RNAs. This splice-donor (SD) region can fold a stem-loop structure. We demonstrate that whereas stabilization of this SD hairpin reduces splicing efficiency, destabilization increases splicing. Both stabilization and destabilization reduce viral fitness. These results demonstrate that the stability of the SD hairpin can modulate the level of splicing, most likely by controlling the accessibility of the 5'ss for the splicing machinery. The natural stability of the SD hairpin restricts splicing and this stability seems to be fine-tuned to reach the optimal balance between unspliced and spliced RNAs for efficient virus replication. The 5'ss region of different HIV-1 isolates and the related SIVmac239 can fold a similar structure. This evolutionary conservation supports the importance of this structure in viral replicatio

HIV-1 splicing at the major splice donor site is restricted by RNA structure

The 5' leader region of the HIV-1 RNA contains the major 5' splice site (ss) that is used in the production of all spliced viral RNAs. This splice-donor (SD) region can fold a stem-loop structure. We demonstrate that whereas stabilization of this SD hairpin reduces splicing efficiency, destabilization increases splicing. Both stabilization and destabilization reduce viral fitness. These results demonstrate that the stability of the SD hairpin can modulate the level of splicing, most likely by controlling the accessibility of the 5'ss for the splicing machinery. The natural stability of the SD hairpin restricts splicing and this stability seems to be fine-tuned to reach the optimal balance between unspliced and spliced RNAs for efficient virus replication. The 5'ss region of different HIV-1 isolates and the related SIVmac239 can fold a similar structure. This evolutionary conservation supports the importance of this structure in viral replicatio

Milieuwinst en waterkwaliteitseffecten van thermische energie uit drinkwater

Vrijwel alle drinkwaterbedrijven hebben ambities voor een klimaatneutrale bedrijfsvoering. Een aantal drinkwaterbedrijven probeert met opwekking van duurzame energie hun CO2-voetafdruk te verlagen. Een bijzondere manier van energieopwekking is de levering van thermische energie uit drinkwater, kortweg TED. Toepassing van TED moet een positieve milieu-impact hebben en de drinkwaterkwaliteit mag nooit in gevaar komen. Daarom is het voor drinkwaterbedrijven belangrijk om meer inzicht te krijgen in de risico’s van deze technologie. KWR Watercycle Research Institute heeft twee bestaande TED-systemen nader onderzocht op microbiologische risico’s, economisch rendement en milieu-impact (LCA). In dit artikel zijn de resultaten van het onderzoek kort samengevat.Water Resource

Microbiologisch veilig water: oude en nieuwe bedreigingen vragen om een hernieuwde aanpak

Een groot deel van de wereld heeft geen toegang tot microbiologisch veilig drinkwater. Maar ook in landen met veilig drinkwater moeten we alert zijn op ziekteverwekkende virussen en bacteriën in water als dat wordt gebruikt voor recreatie, landbouw of als bron voor drinkwater. Naast de bekende microbiologische bedreigingen zijn er ook nieuwe bedreigingen waarvoor snellere en nieuwe meetmethoden en waterzuiveringstechnieken moeten worden ontwikkeld. Op veel vlakken in de watercyclus vindt vernieuwing plaats die kan worden toegepast om het water microbiologisch veilig te maken en te houden