Infection fatality rate of SARS-CoV2 in a super-spreading event in Germany.

A SARS-CoV2 super-spreading event occurred during carnival in a small town in Germany. Due to the rapidly imposed lockdown and its relatively closed community, this town was seen as an ideal model to investigate the infection fatality rate (IFR). Here, a 7-day seroepidemiological observational study was performed to collect information and biomaterials from a random, household-based study population. The number of infections was determined by IgG analyses and PCR testing. We found that of the 919 individuals with evaluable infection status, 15.5% (95% CI:[12.3%; 19.0%]) were infected. This is a fivefold higher rate than the reported cases for this community (3.1%). 22.2% of all infected individuals were asymptomatic. The estimated IFR was 0.36% (95% CI:[0.29%; 0.45%]) for the community and 0.35% [0.28%; 0.45%] when age-standardized to the population of the community. Participation in carnival increased both infection rate (21.3% versus 9.5%, p < 0.001) and number of symptoms (estimated relative mean increase 1.6, p = 0.007). While the infection rate here is not representative for Germany, the IFR is useful to estimate the consequences of the pandemic in places with similar healthcare systems and population characteristics. Whether the super-spreading event not only increases the infection rate but also affects the IFR requires further investigation.

UCP3 Regulates Single-Channel Activity of the Cardiac mCa1.

Mitochondrial Ca(2+) uptake (mCa(2+) uptake) is thought to be mediated by the mitochondrial Ca(2+) uniporter (MCU). UCP2 and UCP3 belong to a superfamily of mitochondrial ion transporters. Both proteins are expressed in the inner mitochondrial membrane of the heart. Recently, UCP2 was reported to modulate the function of the cardiac MCU related channel mCa1. However, the possible role of UCP3 in modulating cardiac mCa(2+) uptake via the MCU remains inconclusive. To understand the role of UCP3, we analyzed cardiac mCa1 single-channel activity in mitoplast-attached single-channel recordings from isolated murine cardiac mitoplasts, from adult wild-type controls (WT), and from UCP3 knockout mice (UCP3(-/-)). Single-channel registrations in UCP3(-/-) confirmed a murine voltage-gated Ca(2+) channel, i.e., mCa1, which was inhibited by Ru360. Compared to WT, mCa1 in UCP3(-/-) revealed similar single-channel characteristics. However, in UCP3(-/-) the channel exhibited decreased single-channel activity, which was insensitive to adenosine triphosphate (ATP) inhibition. Our results suggest that beyond UCP2, UCP3 also exhibits regulatory effects on cardiac mCa1/MCU function. Furthermore, we speculate that UCP3 might modulate previously described inhibitory effects of ATP on mCa1/MCU activity as well.

By Regulating Mitochondrial Ca2+-Uptake UCP2 Modulates Intracellular Ca2+.

INTRODUCTION: The possible role of UCP2 in modulating mitochondrial Ca2+-uptake (mCa2+-uptake) via the mitochondrial calcium uniporter (MCU) is highly controversial. METHODS: Thus, we analyzed mCa2+-uptake in isolated cardiac mitochondria, MCU single-channel activity in cardiac mitoplasts, dual Ca2+-transients from mitochondrial ((Ca2+)m) and intracellular compartment ((Ca2+)c) in the whole-cell configuration in cardiomyocytes of wild-type (WT) and UCP2-/- mice. RESULTS: Isolated mitochondria showed a Ru360 sensitive mCa2+-uptake, which was significantly decreased in UCP2-/- (229.4±30.8 FU vs. 146.3±23.4 FU, P<0.05). Single-channel registrations confirmed a Ru360 sensitive voltage-gated Ca2+-channel in mitoplasts, i.e. mCa1, showing a reduced single-channel activity in UCP2-/- (Po,total: 0.34±0.05% vs. 0.07±0.01%, P<0.05). In UCP2-/- cardiomyocytes (Ca2+)m was decreased (0.050±0.009 FU vs. 0.021±0.005 FU, P<0.05) while (Ca2+)c was unchanged (0.032±0.002 FU vs. 0.028±0.004 FU, P>0.05) and transsarcolemmal Ca2+-influx was inhibited suggesting a possible compensatory mechanism. Additionally, we observed an inhibitory effect of ATP on mCa2+-uptake in WT mitoplasts and (Ca2+)m of cardiomyocytes leading to an increase of (Ca2+)c while no ATP dependent effect was observed in UCP2-/-. CONCLUSION: Our results indicate regulatory effects of UCP2 on mCa2+-uptake. Furthermore, we propose, that previously described inhibitory effects on MCU by ATP may be mediated via UCP2 resulting in changes of excitation contraction coupling.

Glycogen synthase kinase 3ß transfers cytoprotective signaling through connexin 43 onto mitochondrial ATP-sensitive K+ channels.

Despite compelling evidence supporting key roles for glycogen synthase kinase 3ß (GSK3ß), mitochondrial adenosine triphosphate-sensitive K(+) (mitoK(ATP)) channels, and mitochondrial connexin 43 (Cx43) in cytoprotection, it is not clear how these signaling modules are linked mechanistically. By patch-clamping the inner membrane of murine cardiac mitochondria, we found that inhibition of GSK3ß activated mitoK(ATP). PKC activation and protein phosphatase 2a inhibition increased the open probability of mitoK(ATP) channels through GSK3ß, and this GSK3ß signal was mediated via mitochondrial Cx43. Moreover, (i) PKC-induced phosphorylation of mitochondrial Cx43 was reduced in GSK3ß-S9A mice; (ii) Cx43 and GSK3ß proteins associated in mitochondria; and (iii) SB216763-mediated reduction of infarct size was abolished in Cx43 KO mice in vivo, consistent with the notion that GSK3ß inhibition results in mitoK(ATP) opening via mitochondrial Cx43. We therefore directly targeted mitochondrial Cx43 by the Cx43 C-terminal binding peptide RRNYRRNY for cardioprotection, circumventing further upstream pathways. RRNYRRNY activated mitoK(ATP) channels via Cx43. We directly recorded mitochondrial Cx43 channels that were activated by RRNYRRNY and blocked by the Cx43 mimetic peptide (43)GAP27. RRNYRRNY rendered isolated cardiomyocytes in vitro and the heart in vivo resistant to ischemia/reperfusion injury, indicating that mitochondrial Cx43- and/or mitoK(ATP)-mediated reduction of infarct size was not undermined by RRNYRRNY-related opening of sarcolemmal Cx43 channels. Our results demonstrate that GSK3ß transfers cytoprotective signaling through mitochondrial Cx43 onto mitoK(ATP) channels and that Cx43 functions as a channel in mitochondria, being an attractive target for drug treatment against cardiomyocyte injury.

Subcellular localization and characterization of the ParAB system from Corynebacterium glutamicum.

Faithful segregation of chromosomes and plasmids is a vital prerequisite to produce viable and genetically identical progeny. Bacteria use a specialized segregation system composed of the partitioning proteins ParA and ParB to segregate certain plasmids. Strikingly, homologues of ParA and ParB are found to be encoded in many chromosomes. Although mutations in the chromosomal Par system have effects on segregation efficiency, the exact mechanism by which the chromosomes are segregated into the daughter cells is not fully understood. We describe the polar localization of the ParB origin nucleoprotein complex in the actinomycete Corynebacterium glutamicum. ParB and the origin of replication were found to be stably localized to the cell poles. After replication, the origins move toward the opposite pole. Purified ParB was able to bind to the parS consensus sequence in vitro. C. glutamicum possesses two ParA-like partitioning ATPase proteins. Both proteins interact with ParB but show a slightly different subcellular localization and phenotype. While ParA might be part of a conventional partitioning system, PldP seems to play a role in division site selection.

Connexin 43 acts as a cytoprotective mediator of signal transduction by stimulating mitochondrial KATP channels in mouse cardiomyocytes.

Potassium (K+) channels in the inner mitochondrial membrane influence cell function and survival. Increasing evidence indicates that multiple signaling pathways and pharmacological actions converge on mitochondrial ATP-sensitive K+ (mitoKATP) channels and PKC to confer cytoprotection against necrotic and apoptotic cell injury. However, the molecular structure of mitoKATP channels remains unresolved, and the mitochondrial phosphoprotein(s) that mediate cytoprotection by PKC remain to be determined. As mice deficient in the main sarcolemmal gap junction protein connexin 43 (Cx43) lack this cytoprotection, we set out to investigate a possible link among mitochondrial Cx43, mitoKATP channel function, and PKC activation. By patch-clamping the inner membrane of subsarcolemmal murine cardiac mitochondria, we found that genetic Cx43 deficiency, pharmacological connexin inhibition by carbenoxolone, and Cx43 blockade by the mimetic peptide 43GAP27 each substantially reduced diazoxide-mediated stimulation of mitoKATP channels. Suppression of mitochondrial Cx43 inhibited mitoKATP channel activation by PKC. MitoKATP channels of interfibrillar mitochondria, which do not contain any detectable Cx43, were insensitive to both PKC activation and diazoxide, further demonstrating the role of Cx43 in mitoKATP channel stimulation and the compartmentation of mitochondria in cell signaling. Our results define a role for mitochondrial Cx43 in protecting cardiac cells from death and provide a link between cytoprotective stimuli and mitoKATP channel opening, making Cx43 an attractive therapeutic target for protection against cell injury.

Genetic and biochemical analysis of the serine/threonine protein kinases PknA, PknB, PknG and PknL of Corynebacterium glutamicum: evidence for non-essentiality and for phosphorylation of OdhI and FtsZ by multiple kinases.

We previously showed that the 2-oxoglutarate dehydrogenase inhibitor protein OdhI of Corynebacterium glutamicum is phosphorylated by PknG at Thr14, but that also additional serine/threonine protein kinases (STPKs) can phosphorylate OdhI. To identify these, a set of three single (DeltapknA, DeltapknB, DeltapknL), five double (DeltapknAG, DeltapknAL, DeltapknBG, DeltapknBL, DeltapknLG) and two triple deletion mutants (DeltapknALG, DeltapknBLG) were constructed. The existence of these mutants shows that PknA, PknB, PknG and PknL are not essential in C. glutamicum. Analysis of the OdhI phosphorylation status in the mutant strains revealed that all four STPKs can contribute to OdhI phosphorylation, with PknG being the most important one. Only mutants in which pknG was deleted showed a strong growth inhibition on agar plates containing glutamine as carbon and nitrogen source. Thr14 and Thr15 of OdhI were shown to be phosphorylated in vivo, either individually or simultaneously, and evidence for up to two additional phosphorylation sites was obtained. Dephosphorylation of OdhI was shown to be catalysed by the phospho-Ser/Thr protein phosphatase Ppp. Besides OdhI, the cell division protein FtsZ was identified as substrate of PknA, PknB and PknL and of the phosphatase Ppp, suggesting a role of these proteins in cell division.