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Die COVID-19 Pandemie ist die bisher verheerendste Pandemie des 21. Jahrhunderts. Durch die Einführung neuer mRNA-basierter Impfstoffe sowie der hohen Rate natürlicher Infektionen konnte die weltweite SARS-CoV-2-Immunität gesteigert werden. Trotz aller Erfolge zur Eindämmung der Pandemie kann eine Infektion auch heute noch zu schweren Verläufen und Tod führen. Eine adäquate COVID-19-Therapie ist folglich auf potente Virostatika angewiesen. Eine durch Umgehung zeitaufwändiger klinischer Studien schnell verfügbare Alternative zu neu entwickelten Arzneimitteln ist die Anwendung etablierter Medikamente. Wir isolierten und charakterisierten ein von einem Patienten stammendes SARS-CoV-2-Virus. Dieses Virusisolat wurde bisher in elf Publikationen verwendet. Mittels quantitativer Echtzeit-Polymerasekettenreaktion untersuchten wir eine Substanzbibliothek mit mehr als 300 neuen und bereits zugelassenen Wirkstoffen auf ihre Wirksamkeit gegen SARS-CoV-2. Dabei konnten wir zeigen, dass der selektive Serotonin-Wiederaufnahmehemmer Fluoxetin die SARS-CoV-2-Replikation ab einer Dosis von 0,8 μg/ml signifikant inhibiert, einer bei der Behandlung von Depressionen häufig angewandten Dosierung. Der EC50-Wert lag bei 387 ng/ml. Die Behandlung mit Fluoxetin resultierte in einer reduzierten Zahl an Virusprotein-produzierenden Zellen, was darauf hindeutet, dass es die virale Reinfektion und/oder Proteinexpression inhibiert. Fluoxetin ist ein racemisches Gemisch, wobei das (S)-Enantiomer der potentere Serotonin-Wiederaufnahmehemmer ist. Wir konnten zeigen, dass beide Enantiomere einen vergleichbaren antiviralen Effekt gegen SARS-CoV-2 aufweisen, wodurch das (R)-Enantiomer bei virologischer Indikation gegebenenfalls präferiert werden sollte. Fluoxetin hat keinen Einfluss auf die Replikation des Tollwut-Virus und des Humanen Respiratorischen Synzytial-Virus, was auf eine Virusspezifität hindeutet. Weitere aus der Bibliothek stammende signifikante Inhibitoren der SARS-CoV-2-Replikation sind die am Institut für Organische Chemie Würzburg entwickelten Substanzen AKS 232 und AKS 128. Neben der medikamentösen Therapie ist die akkurate Bestimmung neutralisierender Antikörper gegen SARS-CoV-2 zur Quantifizierung des bestehenden (Re-) Infektionsschutzes sowie zur Planung zukünftiger Impfstrategien von großer Bedeutung. Im Rahmen dieser Arbeit entwickelten wir unter Verwendung der quantitativen Echtzeit-Polymerasekettenreaktion erfolgreich ein zuverlässiges Testverfahren zur Detektion neutralisierender anti-SARS-CoV-2 Antikörper.
Im sechsten Semester des Medizinstudiums an der Julius-Maximilians-Universität Würzburg findet das verpflichtende Praktikum „Impfkurs“ statt. Im Rahmen dieses Kurses wurde vom Sommersemester 2020 bis zum Sommersemester 2021 ein standardisierter online Fragebogen erhoben, der unter anderem demographische Daten sowie Expositionsmöglichkeiten gegenüber SARS-CoV-2 im privaten, beruflichen und universitären Umfeld erfragte. Zusätzlich wurde im gleichen Zeitraum der SARS-CoV-2 Serostatus der Medizinstudierenden erhoben und ausgewertet und dieser mit den Daten des Fragebogens zusammengeführt. Dafür wurden Blutproben entnommen, welche im Labor des Instituts für Virologie der Universität Würzburg mittels Western Blot auf IgG/IgM/IgA Antikörper gegen SARS-CoV-2 untersucht wurden.
COVID-19 Patientinnen und Patienten haben ein hohes thrombotisches Risiko. Die
Sicherheit und Wirksamkeit verschiedener Antikoagulationsschemata bei COVID-19
Patientinnen und Patienten sind unklar. Acht RCTs mit 5580 Patientinnen und Patienten
wurden identifiziert, wovon zwei RCTs Antikoagulation in halbtherapeutischer und sechs
RCTs Antikoagulation in therapeutischer Dosierung mit der Standard
Thromboembolieprophylaxe verglichen haben. Die halbtherapeutische Antikoagulation
kann wenig oder gar keinen Einfluss auf thrombotische Ereignisse oder Todesfälle haben
(RR 1,03, 95% KI 0,86-1,24), kann aber schwere Blutungen (RR 1,48, 95% KI 0,53-4,15) bei
mittelschweren bis schweren COVID-19 Patientinnen und Patienten verstärken.
Therapeutische Antikoagulation kann thrombotische Ereignisse oder den Tod bei
Patientinnen und Patienten mit mittelschwerem COVID-19 (RR 0,64, 95% KI 0,38-1,07)
verringern, kann aber bei Patientinnen und Patienten mit schwerer Erkrankung (RR 0,98,
95% KI 0,86-1,12) wenig oder keine Wirkung haben. Das Risiko schwerer Blutungen kann
unabhängig vom Schweregrad der Erkrankung zunehmen (RR 1,78, 95% KI 1,15-2,74). Die
Evidenzsicherheit ist immer noch gering. Mäßig betroffene COVID-19 Patientinnen und
Patienten können von einer therapeutischen Antikoagulation profitieren, jedoch ist das
Blutungsrisiko erhöht.
Beyond the four canonical nucleosides as primary building blocks of RNA, posttranscriptional modifications give rise to the epitranscriptome as a second layer of genetic information. In eukaryotic mRNA, the most abundant posttranscriptional modification is N6-methyladenosine (m6A), which is involved in the regulation of cellular processes. Throughout this thesis, the concept of atomic mutagenesis was employed to gain novel mechanistic insights into the substrate recognition by human m6A reader proteins as well as in the oxidative m6A demethylation by human demethylase enzymes. Non-natural m6A atomic mutants featuring distinct steric and electronic properties were synthesized and incorporated into RNA oligonucleotides. Fluorescence anisotropy measurements using these modified oligonucleotides revealed the impact of the atomic mutagenesis on the molecular recognition by the human m6A readers YTHDF2, YTHDC1 and YTHDC2 and allowed to draw conclusions about structural prerequisites for substrate recognition. Furthermore, substrate recognition and demethylation mechanism of the human m6A demethylase enzymes FTO and ALKBH5 were analyzed by HPLC-MS and PAGE-based assays using the modified oligonucleotides synthesized in this work.
Modified nucleosides not only expand the genetic alphabet, but are also extensively researched as drug candidates. In this thesis, the antiviral mechanism of the anti-SARS-CoV-2 drug remdesivir was investigated, which causes delayed stalling of the viral RNA-dependent RNA polymerase (RdRp). Novel remdesivir phosphoramidite building blocks were synthesized and used to construct defined RNA-RdRp complexes for subsequent studies by cryogenic electron microscopy (cryo-EM). It was found that the 1'-cyano substituent causes Rem to act as a steric barrier of RdRp translocation. Since this translocation barrier can eventually be overcome by the polymerase, novel derivatives of Rem with potentially improved antiviral properties were designed.
As central components of life, DNA and RNA encode the genetic information. However, RNA performs several functions that exceed the competences stated in the ‘central dogma of life‘. RNAs undergo extensive post-transcriptional processing like chemical modifications. Among all classes of RNA, tRNAs are the most extensively modified. Their modifications are chemically diverse and vary from simple methylations (e.g. m3C, m6A) to more complex residues, like isopentenyl group (e.g. i6A, hypermodifications: e.g. ms2i6A) or even amino acids (e.g. t6A). Depending on their location within the overall structure, modifications can have an impact on tRNA stability and structure, as well as affinity for the ribosome and translation efficiency and fidelity. Given the importance of tRNA modifications new tools are needed for their detection and to study their recognition by proteins and enzymatic transformations.
The chemical synthesis of these naturally occurring tRNA modifications as phosphoramidite building blocks is a prerequisite to incorporate the desired modification via solid-phase synthesis into oligonucleotides. With the help of the m3C, (ms2)i6A, and t6A oligonucleotides, the importance and impact of tRNA modifications was investigated in this thesis. To this end, the role of METTL8 as the methyltransferase responsible for the installation of the methyl group at C32 for mt-tRNAThr and mt-tRNASer(UCN) was resolved. Thereby, the respective adenosine modification on position 37 is essential for the effectiveness of the enzyme. Besides, by means of NMR analysis, CD spectroscopy, thermal denaturation experiments, and native page separation, the impact of m3C32 on the structure of the tRNA ASLs was shown. The modification appeared to fine-tune the tRNA structure to optimize mitochondrial translation. To investigate the regulation of the dynamic modification pathway of m3C, demethylation assays were performed with the modified tRNA-ASLs and the (α-KG)- and Fe(II)-dependent dioxygenase ALKBH1 and ALKHB3. A demethylation activity of ALKBH3 on the mt-tRNAs was observed, even though it has so far only been described as a cytoplasmic enzyme. Whether this is physiologically relevant and ALKBH3 present a mitochondrial localization needs further validation. In addition, ALKBH1 was confirmed to not be able to demethylate m3C on mt-tRNAs, but indications for a deprenylation and exonuclease activity were found. Furthermore, the aforementioned naturally occurring modifications were utilized to find analytical tools that can determine the modification levels by DNAzymes, which cleave RNA in the presence of a specific modification. Selective DNA enzymes for i6A, as well as the three cytidine isomers m3C, m4C, and m5C have been identified and characterized.
Besides the naturally occurring tRNA modifications, the investigation on artificially modified nucleosides is also part of this thesis. Nucleosides with specific properties for desired applications can be created by modifying the scaffold of native nucleosides.
During the pandemic, the potential of antiviral nucleoside analogues was highlighted for the treatment of the SARS-CoV-2 infection. For examinations of the potential drug-candidate Molnupiravir, the N4-hydroxycytidine phosphoramidite building block was synthesized and incorporated into several RNA oligonucleotides. A two-step model for the NHC-induced mutagenesis of SARS-CoV-2 was proposed based on RNA elongation, thermal denaturation, and cryo-EM experiments using the modified RNA strands with the recombinant SARS-CoV-2 RNA-dependent RNA polymerase. Two tautomeric forms of NHC enable base pairing with guanosine in the amino and with adenosine in the imino form, leading to error catastrophe after the incorporation into viral RNA. These findings were further corroborated by thermal melting curve analysis and NMR spectroscopy of the NHC-containing Dickerson Drew sequence. In conclusion, the anti-amino form in the NHC-G base pair was assigned by NMR analysis using a 15N-labeld NHC building block incorporated into the Dickerson Drew sequence.
This thesis also addressed the synthesis of a 7-deazaguanosine crosslinker with a masked aldehyde as a diol linker for investigations of DNA-protein interactions. The diol functional group can be unmasked to release the reactive aldehyde, which can specifically form a covalent bond with amino acids Lys or Arg within the protein complex condensin. The incorporation of the synthesized phosphoramidite and triphosphate building blocks were shown and the functionality of the PCR product containing the crosslinker was demonstrated by oxidation and the formation of a covalent bond with a fluorescein label.
The development of assays that detect changes in this methylation pattern of m6A could provide new insights into important biological processes. In the last project of this thesis, the influence of RNA methylation states on the structural properties of RNA was analyzed and a fluorescent nucleoside analog (8-vinyladenosine) as molecular tools for such assays was developed. Initial experiments with the fluorescent nucleoside analog N6-methyl-8-vinyladenosine (m6v8A) were performed and revealed a strong fluorescence enhancement of the free m6v8A nucleoside by the installation of the vinyl moiety at position 8.
Overall, this thesis contributes to various research topics regarding the application of naturally occurring and artificial nucleoside analogues. Starting with the chemical synthesis of RNA and DNA modifications, this thesis has unveiled several open questions regarding the dynamic (de-)methylation pathway of m3C and the mechanism of action of molnupiravir through in-depth analysis and provided the basis for further investigations of the protein complex condensin, and a new fluorescent nucleoside analog m6v8A.
Mit dem Auftreten des SARS-CoV-2 Virus im Jahr 2020 war der Informationsgewinn für vulnerable Patientengruppen essentiell. Ziel dieser Arbeit war es maternale Charakteristika und das klinische Bild SARS-CoV-2 positiver Frauen mit Notwendigkeit einer intensivmedizinischen Behandlung während der Schwangerschaft und postpartal darzustellen, und diese Kohorte mit den SARS-CoV-2 positiven Schwangeren ohne intensivmedizinischen Handlungsbedarf zu vergleichen. Die Daten stammten aus dem deutschen CRONOS-Register, einem prospektiven, multizentrischen Register für SARS-CoV-2 positive schwangere Frauen. Eingeschlossen wurden alle schwangeren und postpartalen Frauen, die während ihrer SARS-CoV-2 Infektion auf eine ITS aufgenommen wurden. Diese wurden hinsichtlich maternaler Charakteristika, Krankheitsverlauf, sowie Outcomes verglichen.
In 101 von 2650 Fällen (4%) der Patientinnen des CRONOS-Registers, kam es zu einer Aufnahme auf die ITS. Als invasivste Form der COVID-19 Behandlung war bei 6 Patientinnen nur eine Überwachung notwendig, 30 Patientinnen benötigten eine Sauerstoffinsufflation, 22 wurden nicht-invasiv beatmet, 28 erhielten eine invasive Beatmung und bei 15 Frauen wurde die Behandlung zur ECMO-Therapie eskaliert. Es wurden keine klinisch signifikanten Unterschiede zwischen Patientinnen gefunden, die unterschiedliche Behandlungsformen benötigten. Die Gruppe der ITS und Non-ITS Patientinnen unterschied sich statistisch signifikant beim Einfluss von Alter, BMI bei Einschluss und der Herkunft. Die Prävalenz der Frühgeburtlichkeit war unter den invasiv behandelten Patientinnen signifikant höher und auch im Vergleich der ITS mit den Non-ITS Patientinnen zeigte sich ein signifikanter Unterschied. Vier Frauen verstarben an COVID-19 und sechs Feten der ITS-Gruppe waren Totgeburten.
Diese Kohorte zeigt, dass schwere COVID-19 Erkrankung bei schwangeren Frauen und Wöchnerinnen selten sind. Die Frühgeburtenrate ist hoch und COVID-19 mit Notwendigkeit einer Atemunterstützung erhöht das Risiko für ein schlechtes maternales und neonatales Outcome. Unter anderem ein höheres Alter und BMI sind mit einem höheren Risiko für eine ITS-Aufnahme verbunden.
At the beginning of the COVID-19 pandemic, patients with primary and secondary immune disorders — including patients suffering from cancer — were generally regarded as a high-risk population in terms of COVID-19 disease severity and mortality. By now, scientific evidence indicates that there is substantial heterogeneity regarding the vulnerability towards COVID-19 in patients with immune disorders. In this review, we aimed to summarize the current knowledge about the effect of coexistent immune disorders on COVID-19 disease severity and vaccination response. In this context, we also regarded cancer as a secondary immune disorder. While patients with hematological malignancies displayed lower seroconversion rates after vaccination in some studies, a majority of cancer patients’ risk factors for severe COVID-19 disease were either inherent (such as metastatic or progressive disease) or comparable to the general population (age, male gender and comorbidities such as kidney or liver disease). A deeper understanding is needed to better define patient subgroups at a higher risk for severe COVID-19 disease courses. At the same time, immune disorders as functional disease models offer further insights into the role of specific immune cells and cytokines when orchestrating the immune response towards SARS-CoV-2 infection. Longitudinal serological studies are urgently needed to determine the extent and the duration of SARS-CoV-2 immunity in the general population, as well as immune-compromised and oncological patients.
The recent pandemic has reminded the public that basic research in virology is pivotal for human health. Understanding the mechanisms of successful viral replication and the role of host factors can help to combat viral infections and prevent future pandemics.
Our lab has published the first SARS-CoV-2 RNA-protein interaction atlas, laying the foundation to investigate the interplay between viral RNA and host RNA binding proteins (RBP). Based on this, my project created the largest collection of binding profiles of host and viral RBPs on SARS-CoV-2 RNA to date. This revealed the host protein SND1 as the first human RBP that specifically binds negative sense viral RNA at the 5´ end, a region associated with viral transcription initiation. The binding profile shares similarities with the viral RBP nsp9, which binds the 5´ ends of positive and negative sense SARS-CoV-2 RNA. Depletion of SND1 shows reduced levels of viral RNA revealing it as a proviral host factor. To decode the underlying molecular mechanism, I characterized the protein-protein interactions of SND1 in SARS-CoV-2 infected and uninfected cells. Infection remodels the protein interactors of SND1 from general RNA biology to membrane association and viral RNA synthesis. Upon infection, SND1 specifically interacts with nsp9, the RBP that shares the same binding region on the negative strand of SARS-CoV-2 RNA. Recent work demonstrates that nsp9 is NMPylated in vitro suggesting a functional role of nsp9 in priming of viral RNA synthesis. I was able to show that nsp9 is covalently linked to the 5´ ends of SARS-CoV-2 RNA during infection of human cells. Analysing the covalent bond of nsp9 with the viral RNA on nucleotide level shows close proximity to the initiation sites of viral RNA synthesis, suggesting that nsp9 acts as a protein-primer of SARS-CoV-2 RNA synthesis. SND1 modulates the distribution of nsp9 on the viral RNA, since depletion of SND1 results in imbalanced occupancy of nsp9 at the 5´ends of viral RNA.
This study is the first to provide evidence for the priming mechanism of SARS-CoV-2 in authentic viral replication and further reveals how this mechanism is modulated by the host RBP SND1. Detailed knowledge about priming of viral RNA synthesis can help to find targeted antivirals that could be used to fight coronaviral infections.
Recently, Tummino et al. reported that 34 compounds, including Chloroquine and Fluoxetine, inhibit SARS-CoV-2 replication by inducing phospholipidosis, although Chloroquine failed to suppress viral replication in Calu-3 cells and patients. In contrast, Fluoxetine represses viral replication in human precision-cut lung slices (PCLS) and Calu-3 cells. Thus, it is unlikely that these compounds have similar mechanisms of action. Here, we analysed a subset of these compounds in the viral replication and phospholipidosis assays using the Calu-3 cells and PCLS as the patient-near system. Trimipramine and Chloroquine induced phospholipidosis but failed to inhibit SARS-CoV-2 replication in Calu-3 cells, which contradicts the reported findings and the proposed mechanism. Fluoxetine, only slightly induced phospholipidosis in Calu-3 cells but reduced viral replication by 2.7 orders of magnitude. Tilorone suppressed viral replication by 1.9 orders of magnitude in Calu-3 cells without causing phospholipidosis. Thus, induction of phospholipidosis is not correlated with the inhibition of SARS-CoV-2, and the compounds act via other mechanisms. However, we show that compounds, such as Amiodarone, Tamoxifen and Tilorone, with antiviral activity on Calu-3 cells, also inhibited viral replication in human PCLS. Our results indicate that antiviral assays against SARS-CoV-2 are cell-line specific. Data from Vero E6 can lead to non-transferable results, underlining the importance of an appropriate cell system for analysing antiviral compounds against SARS-CoV-2. We observed a correlation between the active compounds in Calu-3 cells and PCLS.
Recently, we have shown that C6-ceramides efficiently suppress viral replication by trapping the virus in lysosomes. Here, we use antiviral assays to evaluate a synthetic ceramide derivative α-NH2-ω-N3-C6-ceramide (AKS461) and to confirm the biological activity of C6-ceramides inhibiting SARS-CoV-2. Click-labeling with a fluorophore demonstrated that AKS461 accumulates in lysosomes. Previously, it has been shown that suppression of SARS-CoV-2 replication can be cell-type specific. Thus, AKS461 inhibited SARS-CoV-2 replication in Huh-7, Vero, and Calu-3 cells up to 2.5 orders of magnitude. The results were confirmed by CoronaFISH, indicating that AKS461 acts comparable to the unmodified C6-ceramide. Thus, AKS461 serves as a tool to study ceramide-associated cellular and viral pathways, such as SARS-CoV-2 infections, and it helped to identify lysosomes as the central organelle of C6-ceramides to inhibit viral replication.
Recently, we have described novel pyridyl indole esters and peptidomimetics as potent inhibitors of the severe acute respiratory syndrome coronavirus type 2 (SARS-CoV-2) main protease. Here, we analysed the impact of these compounds on viral replication. It has been shown that some antivirals against SARS-CoV-2 act in a cell line-specific way. Thus, the compounds were tested in Vero, Huh-7, and Calu-3 cells. We showed that the protease inhibitors at 30 µM suppress viral replication by up to 5 orders of magnitude in Huh-7 cells, while in Calu-3 cells, suppression by 2 orders of magnitude was achieved. Three pyridin-3-yl indole-carboxylates inhibited viral replication in all cell lines, indicating that they might repress viral replication in human tissue as well. Thus, we investigated three compounds in human precision-cut lung slices and observed donor-dependent antiviral activity in this patient-near system. Our results provide evidence that even direct-acting antivirals may act in a cell line-specific manner.
Introduction
Pro-thrombotic events are one of the prevalent causes of intensive care unit (ICU) admissions among COVID-19 patients, although the signaling events in the stimulated platelets are still unclear.
Methods
We conducted a comparative analysis of platelet transcriptome data from healthy donors, ICU, and non-ICU COVID-19 patients to elucidate these mechanisms. To surpass previous analyses, we constructed models of involved networks and control cascades by integrating a global human signaling network with transcriptome data. We investigated the control of platelet hyperactivation and the specific proteins involved.
Results
Our study revealed that control of the platelet network in ICU patients is significantly higher than in non-ICU patients. Non-ICU patients require control over fewer proteins for managing platelet hyperactivity compared to ICU patients. Identification of indispensable proteins highlighted key subnetworks, that are targetable for system control in COVID-19-related platelet hyperactivity. We scrutinized FDA-approved drugs targeting indispensable proteins and identified fostamatinib as a potent candidate for preventing thrombosis in COVID-19 patients.
Discussion
Our findings shed light on how SARS-CoV-2 efficiently affects host platelets by targeting indispensable and critical proteins involved in the control of platelet activity. We evaluated several drugs for specific control of platelet hyperactivity in ICU patients suffering from platelet hyperactivation. The focus of our approach is repurposing existing drugs for optimal control over the signaling network responsible for platelet hyperactivity in COVID-19 patients. Our study offers specific pharmacological recommendations, with drug prioritization tailored to the distinct network states observed in each patient condition. Interactive networks and detailed results can be accessed at https://fostamatinib.bioinfo-wuerz.eu/.
Die COVID-19-Pandemie stellte die Gesundheitssysteme weltweit vor große Herausforderungen. Um die weitere Verbreitung von SARS-CoV-2 zu verhindern, verhängten zahlreiche Staatsregierungen einen Lockdown mit Kontakt- und Ausgangsbeschränkungen. Auch in Bayern wurde das öffentliche Leben zwischen 16. März und 26. April 2020 reguliert. Krankenhäuser und Kliniken sollten sich auf eine Notfallversorgung beschränken, um ihre Kapazitäten für SARS-CoV-2-Infizierten freizuhalten. Das ZMK reduzierte im Zuge dessen ebenfalls seinen Klinikbetrieb und setzte für sechs Wochen alle planbaren Behandlungen aus. Ziel dieser retrospektiven Studie war es, den Einfluss der COVID-19-Pandemie auf die Inanspruchnahme des Notdienstes des ZMK zu untersuchen. Hierzu wurden die Behandlungsdokumente der 1299 NotfallpatientInnen, die sich zwischen 3. Februar und 7. Juni 2020 vorstellten, analysiert. Besonderes Augenmerk lag auf PatientInnen höheren Alters und/oder mit Grunderkrankung, die anfällig für einen schweren COVID-19-Verlauf sind.
Während des Lockdowns halbierte sich die Anzahl der NotfallpatientInnen des ZMK. Der Anteil der COVID-19-RisikopatientInnen änderte sich jedoch nicht signifikant. Auch hinsichtlich des Geschlechtes und der Vorerkrankungen konnten keine signifikanten Änderungen festgestellt werden. Die häufigste Diagnose im Notdienst waren unkontrollierbare Schmerzen, meist endodontischen oder parodontologischen Ursprungs, gefolgt vom Abszess und vom dentalen Trauma. Zudem stieg während des Lockdowns der Anteil der NotfallpatientInnen, die stationär aufgenommen werden mussten, um 4% an.
Das pandemiebedingt ohnehin stark ausgelastete Gesundheitssystem sollte nicht zusätzlich belastet werden, insbesondere wenn im Pandemieverlauf mit einem Anstieg des zahnmedizinischen Behandlungsbedarfes zu rechnen ist. Notfälle sind frühzeitig zu behandeln, Routineuntersuchungen aufrecht zu erhalten und PatientInnen über die etablierten Hygiene- und Infektionsschutzmaßnahmen und das geringe Infektionsrisiko in zahnmedizinischen Einrichtungen aufzuklären. Ziel ist, die Mundgesundheit der PatientInnen während der Pandemie aufrecht zu erhalten und einer Verschlimmerung bestehender Erkrankungen vorzubeugen.
Die frühe Phase der Pandemie und der ersten Lockdown bedeuteten keine übermäßige Mehrbelastung für das ZMK. Nach meiner Einschätzung kann eine Notfallversorgung aller PatientInnen im Pandemieverlauf oder während einer zukünftigen Pandemie mit konsequentem Hygienekonzept neben dem regulären Klinikbetrieb ermöglicht werden.
After implementing a reliable mass spectrometry based kinetic study the indole conjugation with different organometallic indoles led to questions about the electronical and sterical influences on reactivity. The substitution pattern of the ferrocene functionalized indoles at the six-membered ring determines the electron density on the C3 atom, which reacts with the formed Schiff base. Since the experimental results showed the exact opposite trend, covalent docking studies were performed elucidating the importance of surface interactions. These studies were in harmony with the experimental results and determined lysine 33 as most preferable conjugation site as well as substitution in 6-position as most favourable pattern. The amine motif in compounds 6, 7 and 8 proofed to be easily fragmented by the ESI method used. The amide linker in 10 remains intact but shows a lower conversion. Those two inherent characteristics are however preferable for well-defined and site-specific bioconjugation. The synthesis and evaluation of piano stool complex derivatives with manganese and rhenium metal centre 15, 16, 18 and 22 gave additional guidance by the interpretation of applicable structural motifs. The electron-withdrawing carbonyl groups lead to the hindrance of fulvene formation and thus to no fragmentation as seen with the ferrocene group. The total conversion is low compared to 8, only 22 shows a good enough conversion to mainly monoconjugate of 45% and a possible radio-labelling application as 99mTc analogue. As consequence manganese complexes with a stable facial tricarbonyl unit and a tridentate chelator with 4-, 5- and 6-substituted aminomethylindole conjugated through an amide bond were synthesized and consecutively evaluated. The resulting organometallic indole derivatives 29, 30 and 31 all showed a total conversion around 40% similar to 16, but at the same time a rate constant in the range of 10-4 s-1 like the organic indole. Besides the similar conversion, the rate constants followed the trend of the 6-substituted derivative as fastest and then 5- and 4- substituted derivative with decreasing reactivity. For underlining the usage as technetium label for the best out of the series 31, a rhenium analogue was prepared. The resulting compound 32 was especially interesting, because the conversion was even higher than the 70% of 8 with a total of 88%. Additionally, the rate constant was a tenfold higher as well. This rendered compound 32 as best possible 99mTc analogue for further application as radio-label. After the success of 32 and realizing the sterical benefits resulting from the flexible tridentate ligand-system, substitution at the five-membered ring was explored. The complexes 33, 34 and 35 are based on indole-2-carboxylic acid and with the difference of the length of the alkyl spacer between amide and complex to probe for the influence and sterical hindrance, but all three derivatives showed no conjugation which excludes functionalization in 2-position. As the C3 is used for the actual bioconjugation, the last possible derivatization was realized on the indole-N1 by using 1-(3-bromopropyl)indole as building block during the synthesis of the ligand-system. The corresponding manganese 36 and rhenium 37 complexes both showed similar properties of a moderate conversion like 22 and a rate constant in the range of 10-5 s-1. In conclusion the rhenium complex 32 with the 6-substitution pattern at the tridentate indole-bearing ligand remains the most promising structure.
The here developed liquid chromatography coupled mass spectrometry-based assay for the determination of inhibitory activity of drug candidates against the 3CLpro of the sever acute respiratory syndrome coronavirus type 2 was successfully implemented and especially designed to give, due to the available absorption spectra and corresponding mass traces, further insight in the otherwise through fluorescence resonance energy transfer-based assays neglected influences on the inhibition results. Starting with a literature-known quinolone containing covalent inhibitor 42 an N1-methylated derivative 43 and their analogues 44 and 45 in which the benzoic acid was exchanged for ferrocene carboxylic acid were synthesized. The inhibition of 3CLpro was evaluated by the concentration of initial 15mer peptide left after incubation and for that purpose the for 280 nm defined molar attenuation coefficient of (26.41±0.59) L*mol-1*cm-1 determined and used. The results showed a reaction of DL dithiothreitol with the less stable benzoic acid esters leading to a moderate inhibitory effect. The methylation in N1-position showed an increase in stability. The methylated and with ferrocene carboxylic acid functionalized derivative showed a complete inhibition during the timeframe of the assay. In search of a fluorescent and therefore traceable inhibitor, 4 hydroxycoumarin was used to synthesize the analogue with benzoic acid 49 and ferrocene carboxylic acid 50. Both derivatives were less stable than their analogues but exhibited the same trend of a more stable ferrocene-derived compound, which exerted a higher inhibition as well. After preparing and testing the model thioester 53 and showing an inactivation of the established inhibitor ebselen, it was concluded that the reaction with DL dithiothreitol reduces the concentration of active intact inhibitor and therefore decreases the inhibition rate during the assay. The next step was proofing the reducing agent as non-essential for the fast assay conducted in a timeframe of 5 min to circumvent the negative influence of DL dithiothreitol. By excluding every inhibition-altering part, the resulting method is the perfect tool for precise statements in relation of inhibitory activity. Then the inhibition assay was repeated for ebselen and the best out of the here introduced organometallic inhibitors 45. Both give equivalent results of a complete inhibition during the measurement. The implemented liquid chromatography coupled mass spectrometry-based assay has many advantages over the fluorescence resonance energy transfer-based assays in which all the information and insight accumulated by the evaluation of uv/vis traces and mass spectra are not available leading to wrong or deviating results regarding the inhibitory capacity of inhibitor candidates.
Individuals with chronic conditions have been faced with many additional challenges during the COVID-19 pandemic. Individual health literacy (HL) as the ability to access, understand, evaluate, and apply pandemic-related information has thus become ever more important in these populations. The purpose of this study was to develop and content-validate a comprehensive HL survey instrument for people with asthma based on an integrated framework, and on previous surveys and other instruments for use in the general population and vulnerable groups. Beside HL, assumed determinants, mediators, and health outcomes were embraced in the framework. A mixed-method design was used. A comprehensive examination of the available literature yielded an initial pool of 398 single items within 20 categories. Based on content validity indices (CVI) of expert ratings (n = 11) and the content analysis of cognitive interviews with participants (n = 9), the item pool was reduced, and individual items/scales refined or modified. The instrument showed appropriate comprehensibility (98.0%), was judged relevant, and had an acceptable CVI at scale level (S-CVI/Ave = 0.91). The final version comprises 14 categories measured by 38 questions consisting of 116 single items. In terms of content, the instrument appears a valid representation of behavioural and psychosocial constructs pertaining to a broad HL understanding and relevant to individuals with asthma during the COVID-19 pandemic. Regular monitoring of these behavioural and psychosocial constructs during the course of the pandemic can help identify needs as well as changes during the course of the pandemic, which is particularly important in chronic disease populations.
In early 2022, the Coronavirus disease 2019 (COVID-19) remains a global challenge. COVID-19 is caused by an increasing number of variants of the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2). Here, we report an outbreak of SARS-CoV-2 breakthrough infections related to a student festive event with 100 mostly vaccinated guests, which took place in Northern Bavaria, Germany, in October 2021. The data were obtained by retrospective guest interviews. In total, 95 students participated in the study, with 94 being fully vaccinated and 24 reporting infection by the delta variant. Correlation analyses among 15 examined variables revealed that time spent at the event, conversation with the supposed index person, and a homologous viral vector vaccination regime were significant risk factors for infection. Non-significant observations related to higher rates of infection included time since last vaccination, shared use of drinking vessels, and number of individual person-to-person contacts at the event. Our data suggest that a high rate of breakthrough infections with the delta variant occurs if no preventive measures are practiced. To limit infection risk, high-quality testing of participants should be considered a mandatory measure at gatherings, irrespective of the participants' vaccination status.
For SARS-CoV-2, R0 calculations in the range of 2–3 dominate the literature, but much higher estimates have also been published. Because capacity for RT-PCR testing increased greatly in the early phase of the Covid-19 pandemic, R0 determinations based on these incidence values are subject to strong bias. We propose to use Covid-19-induced excess mortality to determine R0 regardless of RT-PCR testing capacity. We used data from the Robert Koch Institute (RKI) on the incidence of Covid cases, Covid-related deaths, number of RT-PCR tests performed, and excess mortality calculated from data from the Federal Statistical Office in Germany. We determined R0 using exponential growth estimates with a serial interval of 4.7 days. We used only datasets that were not yet under the influence of policy measures (e.g., lockdowns or school closures). The uncorrected R0 value for the spread of SARS-CoV-2 based on RT-PCR incidence data was 2.56 (95% CI 2.52–2.60) for Covid-19 cases and 2.03 (95% CI 1.96–2.10) for Covid-19-related deaths. However, because the number of RT-PCR tests increased by a growth factor of 1.381 during the same period, these R0 values must be corrected accordingly (R0corrected = R0uncorrected/1.381), yielding 1.86 for Covid-19 cases and 1.47 for Covid-19 deaths. The R0 value based on excess deaths was calculated to be 1.34 (95% CI 1.32–1.37). A sine-function-based adjustment for seasonal effects of 40% corresponds to a maximum value of R0January = 1.68 and a minimum value of R0July = 1.01. Our calculations show an R0 that is much lower than previously thought. This relatively low range of R0 fits very well with the observed seasonal pattern of infection across Europe in 2020 and 2021, including the emergence of more contagious escape variants such as delta or omicron. In general, our study shows that excess mortality can be used as a reliable surrogate to determine the R0 in pandemic situations.
Background
While all efforts have been undertaken to propagate the vaccination and develop remedies against SARS-CoV-2, no satisfactory management of this infection is available yet. Moreover, poor availability of any preventive and treatment measures of SARS-CoV-2 in economically disadvantageous communities aggravates the course of the pandemic. Here, we studied a new immunomodulatory phytotherapy (IP), an extract of blackberry, chamomile, garlic, cloves, and elderberry as a potential low-cost solution for these problems given the reported efficacy of herbal medicine during the previous SARS virus outbreak.
Methods
The key feature of SARS-CoV-2 infection, excessive inflammation, was studied in in vitro and in vivo assays under the application of the IP. First, changes in tumor-necrosis factor (TNF) and lnteurleukin-1 beta (IL-1β) concentrations were measured in a culture of human macrophages following the lipopolysaccharide (LPS) challenge and treatment with IP or prednisolone. Second, chronically IP-pre-treated CD-1 mice received an agonist of Toll-like receptors (TLR)-7/8 resiquimod and were examined for lung and spleen expression of pro-inflammatory cytokines and blood formula. Finally, chronically IP-pre-treated mice challenged with LPS injection were studied for “sickness” behavior. Additionally, the IP was analyzed using high-potency-liquid chromatography (HPLC)-high-resolution-mass-spectrometry (HRMS).
Results
LPS-induced in vitro release of TNF and IL-1β was reduced by both treatments. The IP-treated mice displayed blunted over-expression of SAA-2, ACE-2, CXCL1, and CXCL10 and decreased changes in blood formula in response to an injection with resiquimod. The IP-treated mice injected with LPS showed normalized locomotion, anxiety, and exploration behaviors but not abnormal forced swimming. Isoquercitrin, choline, leucine, chlorogenic acid, and other constituents were identified by HPLC-HRMS and likely underlie the IP immunomodulatory effects.
Conclusions
Herbal IP-therapy decreases inflammation and, partly, “sickness behavior,” suggesting its potency to combat SARS-CoV-2 infection first of all via its preventive effects.
Acetylsalicylic acid and salicylic acid inhibit SARS-CoV-2 replication in precision-cut lung slices
(2022)
Aspirin, with its active compound acetylsalicylic acid (ASA), shows antiviral activity against rhino- and influenza viruses at high concentrations. We sought to investigate whether ASA and its metabolite salicylic acid (SA) inhibit SARS-CoV-2 since it might use similar pathways to influenza viruses. The compound-treated cells were infected with SARS-CoV-2. Viral replication was analysed by RTqPCR. The compounds suppressed SARS-CoV-2 replication in cell culture cells and a patient-near replication system using human precision-cut lung slices by two orders of magnitude. While the compounds did not interfere with viral entry, it led to lower viral RNA expression after 24 h, indicating that post-entry pathways were inhibited by the compounds.
After the recent emergence of SARS-CoV-2 infection, unanswered questions remain related to its evolutionary history, path of transmission or divergence and role of recombination. There is emerging evidence on amino acid substitutions occurring in key residues of the receptor-binding domain of the spike glycoprotein in coronavirus isolates from bat and pangolins. In this article, we summarize our current knowledge on the origin of SARS-CoV-2. We also analyze the host ACE2-interacting residues of the receptor-binding domain of spike glycoprotein in SARS-CoV-2 isolates from bats, and compare it to pangolin SARS-CoV-2 isolates collected from Guangdong province (GD Pangolin-CoV) and Guangxi autonomous regions (GX Pangolin-CoV) of South China. Based on our comparative analysis, we support the view that the Guangdong Pangolins are the intermediate hosts that adapted the SARS-CoV-2 and represented a significant evolutionary link in the path of transmission of SARS-CoV-2 virus. We also discuss the role of intermediate hosts in the origin of Omicron.