Effects of extreme meteorological conditions in 2018 on European methane emissions estimated using atmospheric inversions.

The effect of the 2018 extreme meteorological conditions in Europe on methane (CH4) emissions is examined using estimates from four atmospheric inversions calculated for the period 2005-2018. For most of Europe, we find no anomaly in 2018 compared to the 2005-2018 mean. However, we find a positive anomaly for the Netherlands in April, which coincided with positive temperature and soil moisture anomalies suggesting an increase in biogenic sources. We also find a negative anomaly for the Netherlands for September-October, which coincided with a negative anomaly in soil moisture, suggesting a decrease in soil sources. In addition, we find a positive anomaly for Serbia in spring, summer and autumn, which coincided with increases in temperature and soil moisture, again suggestive of changes in biogenic sources, and the annual emission for 2018 was 33 ± 38% higher than the 2005-2017 mean. These results indicate that CH4 emissions from areas where the natural source is thought to be relatively small can still vary due to meteorological conditions. At the European scale though, the degree of variability over 2005-2018 was small, and there was negligible impact on the annual CH4 emissions in 2018 despite the extreme meteorological conditions. This article is part of a discussion meeting issue 'Rising methane: is warming feeding warming? (part 2)'.

[Percutaneous nephrolithotomy for kidney stones in elderly patients: Meta-analysis of results and complications]. / Néphrolithotomie percutanée des calculs rénaux des personnes âgées : méta-analyse des résultats et complications.

INTRODUCTION AND OBJECTIVE: Percutaneous nephrolithotomy (PCNL) is the gold standard treatment for kidney stones regardless of age. Elderly patients (EP)≥65years old, in growing numbers, have more comorbidities than the general population, may alter results of PCNL. The aim of this meta-analysis was to compare efficacy and complications of this procedure between EP and young patients (YP). METHODS: Original studies of prospective and historical cohorts, in English or French, presenting PCNL series published on PubMed until 2015 were identified using the keywords percutaneous nephrolithotomy, elderly patients, kidney stones and staghorn calculi. Our analysis focused on therapeutic efficacy, defined by absence of residual fragment or the presence of residual fragments<4mm at 3 postoperative months, and postoperative complications according to patient age: YP<65 years old and EP≥65 years old. Binary qualitative data were analyzed using odds ratio (OR) and quantitative data by estimating the difference of means. RESULTS: In total 397 studies were identified among which 23 were checked and 8 included in the meta-analysis for methodological quality corresponding to 4995 YP and 820 EP. No efficacy difference (OR=0.96; [IC95 %: 0.80; 1.17]; P=0.71), operating time (+1.15min in EP [IC95 %: -2.83; 5.12]; P=0.57) and average length of stay (+0.29 days in EP [IC95 %: -0.14; 0.72]; P=0.19) has been reported. It was a trend to more urinary infections (OR=2.24; [IC95 %: 0.74-6.80]; P=0.16) and a significantly increase of postoperative blood transfusions in EP (OR=1.41; [IC95 %: 1.00-1.97]; P=0.04). CONCLUSIONS: PCNL for kidney stones n EP is effective with a significantly increase the risk of postoperative blood transfusions compared to YP.

Specific Follicular Helper T Cell Signature in Takayasu Arteritis.

OBJECTIVE: Our aim was to compare transcriptome and phenotype profiles of CD4+ T cells and CD19+ B cells in patients with Takayasu arteritis (TAK), patients with giant cell arteritis (GCA), and healthy donors. METHODS: Gene expression analyses, flow cytometry immunophenotyping, T cell receptor (TCR) gene sequencing, and functional assessments of cells from peripheral blood and arterial lesions from TAK patients, GCA patients, and healthy donors were performed. RESULTS: Among the most significantly dysregulated genes in CD4+ T cells of TAK patients compared to GCA patients (n = 720 genes) and in CD4+ T cells of TAK patients compared to healthy donors (n = 1,447 genes), we identified a follicular helper T (Tfh) cell signature, which included CXCR5, CCR6, and CCL20 genes, that was transcriptionally up-regulated in TAK patients. Phenotypically, there was an increase in CD4+CXCR5+CCR6+CXCR3- Tfh17 cells in TAK patients that was associated with a significant enrichment of CD19+ B cell activation. Functionally, Tfh cells helped B cells to proliferate, differentiate into memory cells, and secrete IgG antibodies. Maturation of B cells was inhibited by JAK inhibitors. Locally, in areas of arterial inflammation, we found a higher proportion of tertiary lymphoid structures comprised CD4+, CXCR5+, programmed death 1+, and CD20+ cells in TAK patients compared to GCA patients. CD4+CXCR5+ T cells in the aortas of TAK patients had an oligoclonal α/ß TCR repertoire. CONCLUSION: We established the presence of a specific Tfh cell signature in both circulating and aorta-infiltrating CD4+ T cells from TAK patients. The cooperation of Tfh cells and B cells might be critical in the occurrence of vascular inflammation in patients with TAK.

In vivo oligo(A) insertions in phage MS2: role of Escherichia coli poly(A) polymerase.

Previously we introduced an RNase III site into the genome of RNA phage MS2 by extending a hairpin with a perfect 18 bp long stem. One way in which the phage escaped from being killed by RNase III cleavage was to incorporate uncoded A residues on either side of the stem. This oligo(A) stretch interrupts the perfect stem that forms the RNase III site and thus confers resistance. In this paper we have analyzed the origin of these uncoded adenosines. The data strongly suggest that they are added by the host enzyme poly(A) polymerase. Apparently the 3'-OH created by RNase III cleavage becomes a substrate for poly(A) polymerase. Subsequently, MS2 replicase makes one contiguous copy from the two parts of the genome RNA. The evolutionary conversion from RNase III sensitivity to resistance provides a large spectrum of solutions that could be an important tool to understand what essentially constitutes an RNase III site in vivo.

Decay of mRNA encoding ribosomal protein S15 of Escherichia coli is initiated by an RNase E-dependent endonucleolytic cleavage that removes the 3' stabilizing stem and loop structure.

The transcripts of the rpsO-pnp operon of Escherichia coli, coding for ribosomal protein S15 and polynucleotide phosphorylase, are processed at four sites in the 249 nucleotides of the intercistronic region. The initial processing step in the decay of the pnp mRNA is made by RNase III, which cuts at two sites upstream from the pnp gene. The other two cleavages are dependent on the wild-type allele of the rne gene, which encodes the endonucleolytic enzyme RNase E. The cuts are made 37 nucleotides apart at the base of the stem-loop structure of the rho-independent attenuator located downstream from rpsO. The cleavage downstream from the attenuator generates an rpsO mRNA.nearly identical with the monocistronic attenuated transcript, while the cleavage upstream from the transcription attenuator gives rise to an rpsO mesage lacking the terminal 3' hairpin structure. The rapid degradation of the processed mRNA in an rne+ strain, compared to the slow degradation of the transcript that accumulates in an rne- strain, suggests that RNase E initiates the decay of the rpsO message by removing the stabilizing stem-loop at the 3' end of the RNA.

Initiation, attenuation and RNase III processing of transcripts from the Escherichia coli operon encoding ribosomal protein S15 and polynucleotide phosphorylase.

The rpsO gene of Escherichia coli, which encodes ribosomal protein S15 is located at 69 minutes on the chromosome. It is adjacent to the pnp gene, which encodes polynucleotide phosphorylase. The two genes are separated by 249 nucleotides and are transcribed in the same direction. We report here in vivo S1 nuclease mapping and in vitro transcription experiments that demonstrate that rpsO and pnp are cotranscribed from a promoter P1, located 108 nucleotides upstream from rpsO, and that another promoter P2, located between the two genes 158 nucleotides upstream from pnp, also directs the transcription of pnp. Transcription from P1 can either terminate at the terminator t1 identified in vivo and in vitro, 18 nucleotides downstream from rpsO, or transcribe through t1 and into pnp. Comparison of the transcripts synthesized in wild-type and RNase III-deficient strains of E. coli shows that all the P1 readthrough transcripts and P2 transcripts are cleaved by RNase III. Two specific cuts are made by RNase III in a double-stranded structure about 100 nucleotides upstream rpsO. We also found that some transcripts of this operon start 47 nucleotides downstream from rpsO, in the region of t1. No promoter has been identified in this region. This mRNA is attributed to an endonucleolytic cleavage of the polycistronic transcripts and the location of the cut is named M. The order of the transcription signals and of the maturation sites in relation to rpsO and pnp can be summarized as follows: P1, rpsO, t1, M, P2, RNase III-processing sites, pnp. The possible roles of mRNA processing events in the expression of rpsO-pnp operon are discussed.

E. coli RpsO mRNA decay: RNase E processing at the beginning of the coding sequence stimulates poly(A)-dependent degradation of the mRNA.

The rpsO mRNA of E. coli encoding ribosomal protein S15 is destabilized by poly(A) tails posttranscriptionally added by poly(A)polymerase I. We demonstrate here that polyadenylation also contributes to the rapid degradation of mRNA fragments generated by RNase E. It was already known that an RNase E cleavage occurring at the M2 site, ten nucleotides downstream of the coding sequence of rpsO, removes the 3' hairpin which protects the primary transcript from the attack of polynucleotide phosphorylase and RNase II. A second RNase E processing site, referred to as M3, is now identified at the beginning of the coding sequence of rpsO which contributes together with exonucleases to the degradation of messengers processed at M2. Cleavages at M2 and M3 give rise to mRNA fragments which are very rapidly degraded in wild-type cells. Poly(A)polymerase I contributes differently to the instability of these fragments. The M3-M2 internal fragment, generated by cleavages at M3 and M2, is much more sensitive to poly(A)-dependent degradation than the P1-M2 mRNA, which exhibits the same 3' end as M3-M2 but harbours the 5' end of the primary transcript. We conclude that 5' extremities modulate the poly(A)-dependent degradation of mRNA fragments and that the 5' cleavage by RNase E at M3 activates the chemical degradation of the rpsO mRNA.

Cleavage by RNase III in the transcripts of the met Y-nus-A-infB operon of Escherichia coli releases the tRNA and initiates the decay of the downstream mRNA.

The metY gene coding for a minor form of the initiator tRNA is the first gene of a complex polycistronic operon also encoding the transcription termination factor NusA and the translation initiation factor IF2. The mixed tRNA-mRNA polycistronic transcript is cleaved by RNase III in a hairpin structure downstream from the tRNA. This cleavage separates the tRNA from the mRNA and initiates the rapid degradation of the 5' extremity of the downstream mRNA. Dissociation of the structural (tRNA) and informational (mRNA) RNAs from this operon is also achieved by independent transcription in vivo. The presence of two transcription terminators located downstream from metY produces a small tRNAMetf2 precursor transcript, whereas an internal promoter situated between metY and the first open reading frame directs the transcription of only the protein-coding part of the operon.

Nucleolytic inactivation and degradation of the RNase III processed pnp message encoding polynucleotide phosphorylase of Escherichia coli.

The two cleavages made by RNase III in the transcripts of the pnp gene of Escherichia coli, 80 nucleotides upstream of the coding sequence of polynucleotide phosphorylase, were previously demonstrated to trigger the rapid degradation of the pnp messenger. In this paper, we demonstrate that the 5' end of the RNase III processed pnp mRNA is attacked by ribonucleases more efficiently than the rest of the molecule. Several 5' extremities resulting from cleavages occurring in the first 500 nucleotides of the pnp transcript have been identified. Three of them referred to as X, Y and W occur in the wild-type strain at the beginning of the coding sequence of the pnp mRNA. The mRNA appears to be cleaved more efficiently at the X site, proximal to the initiation codon, than at sites Y and W located downstream. In vitro, the maturation at X is catalysed by RNase E but not by RNase III. Accumulation of RNA processed at X in RNase E deficient strains leads us to postulate that X is a high affinity primary site which is slowly cleaved by the residual activity of thermosensitive RNase E at non-permissive temperature and that secondary sites located downstream are processed less efficiently than X. Taken together, our results suggest that in wild-type E. coli the degradation of the RNase III processed mRNA is mediated by RNase E.

Both temperature and medium composition regulate RNase E processing efficiency of the rpsO mRNA coding for ribosomal protein S15 of Escherichia coli.

Cleavage by RNase E is believed to be the rate-limiting step in the degradation of many RNAs. These cleavages are modulated by 5' end-phosphorylation, folding and translation of the mRNA in question. Here, we present data suggesting that these cleavages are also regulated by environmental conditions. We report that rpsO mRNA, 15 minutes after a shift to 44 degrees C, is stabilized in cells grown in minimal medium. This stabilization is correlated with a reduction in the efficiency of the RNase E cleavage which initiates its decay. We also observe the appearance of RNA fragments previously detected following RNase E inactivation and a defect in the adaptation of RNase E concentration. These observations, coupled to the fact that RNase E overproduction slightly reduces the accumulation of the rpsO mRNA, suggest that this stabilization is caused in part by a limitation in RNase E concentration. An increase in the steady-state level of rpsT mRNA is also observed following a shift to 44 degrees C in minimal medium; however, processing of the 9 S rRNA precursor is not affected under these conditions. We thus propose that RNase E concentration changes in the cell in response to environmental conditions and that these changes can selectively affect the processing and the stability of individual mRNAs. Our data also indicate that the efficiency of cleavage of the rpsO mRNA by RNase E is modified by other factor(s) which remain to be identified.

Study on the localization of proteases of mitochondrial origin.

A marked proteolytic activity against casein can be demonstrated in rat liver mitochondria. The proteases degrading casein appear distributed between a sedimentable fraction (Po) and a soluble extract (So). Part of the soluble fraction activity, which may be recovered in the mitochondrial intermembrane space, results from a contamination by lysosomal proteases and can be eliminated by previously washing the mitochondria with digitonin. The pre-exposure to digitonin causes an enhancement of the caseinolytic activity associated with the membrane fragments, proving that this activity is not due to lysosomal enzymes. When rats have been injected in vivo with the compound 48/80 which, by degranulating the mast cells prevents contamination of the mitochondrial preparations by mast cell proteases, the membrane fraction (Po) retains a caseinolytic activity of the order of 80 per cent of the control preparations. A similar value of activity is observed in the membranes of brain mitochondria, isolated by a method which removes the rare mast cells they may contain. This shows that the greater part of the caseinolytic activity associated with the rat liver membranes does not originate from mast cell granules. Liver mitochondria pre-exposed to digitonin to eliminate lysosomal contaminants, have been subfractionated into matrix, intermembrane space, inner and outer membrane. Each of the fractions exhibits a caseinolytic activity, but the largest part is localized in the inner compartments of mitochondria: the matrix and the inner membrane. The optimal pH and the sensitivity to inhibitors of the proteases in the different compartments indicate that we are dealing with distinct enzymes.

RNase III cleavages in non-coding leaders of Escherichia coli transcripts control mRNA stability and genetic expression.

The primary transcripts of the rpsO-pnp, rnc-era-recO and metY-nusA-infB operons of E coli are each processed by RNase III, upstream of the first translated gene, in hair-pin structures formed by the 5' non-coding leader. The mRNAs of the 3 operons, of which the 5' terminal motifs have been removed by RNase III, decay significantly more rapidly than the uncut transcripts which accumulate in the RNase III deficient strain. The rapid decay of a primary transcript of the metY-nusA-infB operon, initiated at a secondary promoter in the vicinity of the RNase III sites, suggests that the 5' features upstream of the RNase III cutting sites are responsible for the stability of the uncut RNAs. RNase III autocontrols its own expression by removing the 5' motif which stabilizes its mRNA. Similarly, the synthesis of polynucleotide phosphorylase and of protein Era are also controlled by RNase III cleavages which trigger the degradation of their messengers. The role of RNase III in the regulation of gene expression and the possible mechanisms of mRNA stabilization and of 5' to 3' decay initiated by RNase III processing are discussed.

Multiple degradation pathways of the rpsO mRNA of Escherichia coli. RNase E interacts with the 5' and 3' extremities of the primary transcript.

The degradation process of the rpsO mRNA is one of the best characterised in E coli. Two independent degradation pathways have been identified. The first one is initiated by an RNase E endonucleolytic cleavage which allows access to the transcript by polynucleotide phosphorylase and RNase II. Cleavage by RNase E gives rise to an rpsO message lacking the stabilising hairpin of the primary transcript; this truncated mRNA is then degraded exonucleolytically from its 3' terminus. This pathway might be coupled to the translation of the message. The second pathway allows degradation of polyadenylated rpsO mRNA independently of RNase II, PNPase and RNase E. The ribonucleases responsible for degradation of poly(A) mRNAs under these conditions are not known. Poly(A) tails have been proposed to facilitate the degradation of structured RNA by polynucleotide phosphorylase. In contrast, we believe that removal of poly(A) by RNase II stabilises the rpsO mRNA harbouring a 3' hairpin. In addition to these two pathways, we have identified endonucleolytic cleavages which occur only in strains deficient for both RNase E and RNase III suggesting that these two endonucleases protect the 5' leader of the mRNA from the attack of unidentified ribonuclease(s). Looping of the rpsO mRNA might explain how RNase E bound at the 5' end can cleave at a site located just upstream the hairpin of the transcription terminator.

The role of endonucleases in the expression of ribonuclease II in Escherichia coli.

Ribonuclease II (RNase II), encoded by the rnb gene, is one of the two major Escherichia coli exonucleases involved in mRNA degradation. Some of the ribonucleases implicated in this process have recently been shown to be inter-regulated. In this paper we studied the effects of the endonucleases RNase E and RNase III in rnb expression. We have shown that RNase E cleaves the rnb message internally: when this ribonuclease is inactivated rnb mRNA accumulates with a concomitant increase in RNase II activity. RNase III also affects RNase II expression but in an indirect way. We discuss these implications for the regulation of mRNA degradation.

Reactive dispersive contaminant transport in coastal aquifers: numerical simulation of a reactive Henry problem.

The reactive mixing between seawater and terrestrial water in coastal aquifers influences the water quality of submarine groundwater discharge. While these waters come into contact at the seawater groundwater interface by density driven flow, their chemical components dilute and react through dispersion. A larger interface and wider mixing zone may provide favorable conditions for the natural attenuation of contaminant plumes. It has been claimed that the extent of this mixing is controlled by both, porous media properties and flow conditions. In this study, the interplay between dispersion and reactive processes in coastal aquifers is investigated by means of numerical experiments. Particularly, the impact of dispersion coefficients, the velocity field induced by density driven flow and chemical component reactivities on reactive transport in such aquifers is studied. To do this, a hybrid finite-element finite-volume method and a reactive simulator are coupled, and model accuracy and applicability are assessed. A simple redox reaction is considered to describe the degradation of a contaminant which requires mixing of the contaminated groundwater and the seawater containing the terminal electron acceptor. The resulting degradation is observed for different scenarios considering different magnitudes of dispersion and chemical reactivity. Three reactive transport regimes are found: reaction controlled, reaction-dispersion controlled and dispersion controlled. Computational results suggest that the chemical components' reactivity as well as dispersion coefficients play a significant role on controlling reactive mixing zones and extent of contaminant removal in coastal aquifers. Further, our results confirm that the dilution index is a better alternative to the second central spatial moment of a plume to describe the mixing of reactive solutes in coastal aquifers.