COVID-19 and erosion of democracy.

The main research question of this study is about the drivers of democracy backsliding during the COVID-19 pandemic, with a special focus on the rule of law and the state of democracy just before the shock. There is growing interest in the political implications of the coronavirus pandemic, debating mostly the misuse of emergencies and violations of various norms by governments; however the links between the current democracy erosion with institutional environment remain unclear. We use a novel global dataset covering the period of the first two waves of the pandemic (January-December 2020), and apply various econometric and machine learning tools to identify institutional, economic and social factors influencing democracy. Our results are of scientific and practical importance and imply that the stronger the rule of law and the higher the level of democracy, the lower the risk of democracy backsliding in the face of the pandemic.

Lethal and mutagenic properties of MMS-generated DNA lesions in Escherichia coli cells deficient in BER and AlkB-directed DNA repair.

Methylmethane sulphonate (MMS), an S(N)2-type alkylating agent, generates DNA methylated bases exhibiting cytotoxic and mutagenic properties. Such damaged bases can be removed by a system of base excision repair (BER) and by oxidative DNA demethylation catalysed by AlkB protein. Here, we have shown that the lack of the BER system and functional AlkB dioxygenase results in (i) increased sensitivity to MMS, (ii) elevated level of spontaneous and MMS-induced mutations (measured by argE3 --> Arg(+) reversion) and (iii) induction of the SOS response shown by visualization of filamentous growth of bacteria. In the xth nth nfo strain additionally mutated in alkB gene, all these effects were extreme and led to 'error catastrophe', resulting from the presence of unrepaired apurinic/apyrimidinic (AP) sites and 1-methyladenine (1meA)/3-methylcytosine (3meC) lesions caused by deficiency in, respectively, BER and AlkB dioxygenase. The decreased level of MMS-induced Arg(+) revertants in the strains deficient in polymerase V (PolV) (bearing the deletion of the umuDC operon), and the increased frequency of these revertants in bacteria overproducing PolV (harbouring the pRW134 plasmid) indicate the involvement of PolV in the error-prone repair of 1meA/3meC and AP sites. Comparison of the sensitivity to MMS and the induction of Arg(+) revertants in the double nfo alkB and xth alkB, and the quadruple xth nth nfo alkB mutants showed that the more AP sites there are in DNA, the stronger the effect of the lack of AlkB protein. Since the sum of MMS-induced Arg(+) revertants in xth, nfo and nth xth nfo and alkB mutants is smaller than the frequency of these revertants in the BER(-) alkB(-) strain, we consider two possibilities: (i) the presence of AP sites in DNA results in relaxation of its structure that facilitates methylation and (ii) additional AP sites are formed in the BER(-) alkB(-) mutants.

Contribution of transcription-coupled DNA repair to MMS-induced mutagenesis in E. coli strains deficient in functional AlkB protein.

In Escherichia coli the alkylating agent methyl methanesulfonate (MMS) induces defense systems (adaptive and SOS responses), DNA repair pathways, and mutagenesis. We have previously found that AlkB protein induced as part of the adaptive (Ada) response protects cells from the genotoxic and mutagenic activity of MMS. AlkB is a non-heme iron (II), alpha-ketoglutarate-dependent dioxygenase that oxidatively demethylates 1meA and 3meC lesions in DNA, with recovery of A and C. Here, we studied the impact of transcription-coupled DNA repair (TCR) on MMS-induced mutagenesis in E. coli strain deficient in functional AlkB protein. Measuring the decline in the frequency of MMS-induced argE3-->Arg(+) revertants under transient amino acid starvation (conditions for TCR induction), we have found a less effective TCR in the BS87 (alkB(-)) strain in comparison with the AB1157 (alkB(+)) counterpart. Mutation in the mfd gene encoding the transcription-repair coupling factor Mfd, resulted in weaker TCR in MMS-treated and starved AB1157 mfd-1 cells in comparison to AB1157 mfd(+), and no repair in BS87 mfd(-) cells. Determination of specificity of Arg(+) revertants allowed to conclude that MMS-induced 1meA and 3meC lesions, unrepaired in bacteria deficient in AlkB, are the source of mutations. These include AT-->TA transversions by supL suppressor formation (1meA) and GC-->AT transitions by supB or supE(oc) formation (3meC). The repair of these lesions is partly Mfd-dependent in the AB1157 mfd-1 and totally Mfd-dependent in the BS87 mfd-1 strain. The nucleotide sequence of the mfd-1 allele shows that the mutated Mfd-1 protein, deprived of the C-terminal translocase domain, is unable to initiate TCR. It strongly enhances the SOS response in the alkB(-)mfd(-) bacteria but not in the alkB(+)mfd(-) counterpart.

Evaluation of Anti-cancer Activity of Stilbene and Methoxydibenzo[b,f] oxepin Derivatives.

BACKGROUND: Stilbenes, 1,2-diphenylethen derivatives, including resveratrol and combretastatins, show anticancer features especially against tumor angiogenesis. Fosbretabulin, CA-4, in combination with carboplatin, is in the last stages of clinical tests as an inhibitor of thyroid cancer. The mode of action of these compounds involves suppression of angiogenesis through interfering with tubulin (de)polymerization. OBJECTIVE: We have previously synthesized five E-2-hydroxystilbenes and seven dibenzo [b,f]oxepins in Z configuration, with methyl or nitro groups at varied positions. The aim of the present work was to evaluate the anticancer activity and molecular mechanism(s) of action of these compounds. RESULTS: Two healthy, EUFA30 and HEK293, and two cancerous, HeLa and U87, cell lines were treated with four newly synthetized stilbenes and seven oxepins. Two of these compounds, JJR5 and JJR6, showed the strongest cytotoxic effect against cancerous cells tested and these two were selected for further investigations. They induced apoptosis with sub-G1 or S cell cycle arrest and PARP cleavage, with no visible activation of caspases 3 and 7. Proteomic differential analysis of stilbene-treated cells led to the identification of proteins involved almost exclusively in cell cycle management, apoptosis, DNA repair and stress response, e.g. oxidative stress. CONCLUSION: Among the newly synthesized stilbene derivatives, we selected two as potent anticancer compounds triggering late apoptosis/necrosis in cancerous cells through sub-G1 phase cell cycle arrest. They changed cyclin expression, induced DNA repair mechanisms, enzymes involved in apoptosis and oxidative stress response. Compounds JJR5 and JJR6 can be a base for structure modification(s) to obtain even more active derivatives.

AlkB dioxygenase in preventing MMS-induced mutagenesis in Escherichia coli: effect of Pol V and AlkA proteins.

The deleterious effect of defective alkB allele encoding 1meA/3meC dioxygenase on reactivation of MMS-treated phage DNA has been frequently studied. Here, it is shown that: (i) AlkB protects the cells not only against the genotoxic but also against the potent mutagenic activity of MMS; (ii) mutations arising in alkB-defected strains are umuDC-dependent, and deletion of umuDC dramatically reduce MMS-induced mutations resulting from the presence of 1meA/3meC in DNA; (iii) specificity of MMS-induced argE3-->Arg+ reversions in AB1157 alkB-defective cells are predominantly AT-->TA transversions and GC-->AT transitions; (iv) overproduction of AlkA and the resultant decrease in 3meA residues in DNA dramatically reduce MMS-induced mutations. This reduction is most probably a secondary effect of AlkA due to a decrease in 3meA residues in DNA and, in consequence, suppression of SOS induction and Pol V expression. Overproduction of UmuD'C proteins reverses this effect.

Effect of SOS-induced Pol II, Pol IV, and Pol V DNA polymerases on UV-induced mutagenesis and MFD repair in Escherichia coli cells.

Irradiation of organisms with UV light produces genotoxic and mutagenic lesions in DNA. Replication through these lesions (translesion DNA synthesis, TSL) in Escherichia coli requires polymerase V (Pol V) and polymerase III (Pol III) holoenzyme. However, some evidence indicates that in the absence of Pol V, and with Pol III inactivated in its proofreading activity by the mutD5 mutation, efficient TSL takes place. The aim of this work was to estimate the involvement of SOS-inducible DNA polymerases, Pol II, Pol IV and Pol V, in UV mutagenesis and in mutation frequency decline (MFD), a mechanism of repair of UV-induced damage to DNA under conditions of arrested protein synthesis. Using the argE3-->Arg(+) reversion to prototrophy system in E. coli AB1157, we found that the umuDC-encoded Pol V is the only SOS-inducible polymerase required for UV mutagenesis, since in its absence the level of Arg(+) revertants is extremely low and independent of Pol II and/or Pol IV. The low level of UV-induced Arg(+) revertants observed in the AB1157mutD5DumuDC strain indicates that under conditions of disturbed proofreading activity of Pol III and lack of Pol V, UV-induced lesions are bypassed without inducing mutations. The presented results also indicate that Pol V may provide substrates for MFD repair; moreover, we suggest that only those DNA lesions which result from umuDC-directed UV mutagenesis are subject to MFD repair.

Mutator activity and specificity of Escherichia coli dnaQ49 allele--effect of umuDC products.

The high fidelity of DNA replication in Escherichia coli is ensured by the alpha (DnaE) and epsilon (DnaQ) subunits of DNA polymerase providing insertion fidelity, 3'-->5' exonuclease proofreading activity, and by the dam-directed mismatch repair system. dnaQ49 is a recessive allele that confers a temperature-sensitive proofreading phenotype resulting in a high rate of spontaneous mutations and chronic induction of the SOS response. The aim of this study was to analyse the mutational specificity of dnaQ49 in umuDC and DeltaumuDC backgrounds at 28 and 37 degrees C in a system developed by J.H. Miller. We confirmed that the mutator activity of dnaQ49 was negligible at 28 degrees C and fully expressed at 37 degrees C. Of the six possible base pair substitutions, only GC-->AT transitions and GC-->TA and AT-->TA transversions were appreciably increased. However, the most numerous mutations were frameshifts, -1G deletions and +1A insertions. All mutations which increased in response to dnaQ49 damage were to a various extent umuDC-dependent, especially -1G deletions. This type of mutations decreased in CC108dnaQ49DeltaumuDC to 10% of the value found in CC108dnaQ49umuDC+ and increased in the presence of plasmids producing UmuD'C or UmuDC proteins. In the recovery of dnaQ49 mutator activity the plasmid harbouring umuD'C genes was more effective than the one harbouring umuDC. Analysis of mutational specificity of pol III with defective epsilon subunit indicates that continuation of DNA replication is allowed past G:T, C:T, T:T (or C:A, G:A, A:A) mismatches but does not allow for acceptance of T:C, C:C, A:C (or A:G, G:G, T:G) (the underlined base is in the template strand).

Inducible repair of alkylated DNA in microorganisms.

Alkylating agents, which are widespread in the environment, also occur endogenously as primary and secondary metabolites. Such compounds have intrinsically extremely cytotoxic and frequently mutagenic effects, to which organisms have developed resistance by evolving multiple repair mechanisms to protect cellular DNA. One such defense against alkylation lesions is an inducible Adaptive (Ada) response. In Escherichia coli, the Ada response enhances cell resistance by the biosynthesis of four proteins: Ada, AlkA, AlkB, and AidB. The glycosidic bonds of the most cytotoxic lesion, N3-methyladenine (3meA), together with N3-methylguanine (3meG), O(2)-methylthymine (O(2)-meT), and O(2)-methylcytosine (O(2)-meC), are cleaved by AlkA DNA glycosylase. Lesions such as N1-methyladenine (1meA) and N3-methylcytosine (3meC) are removed from DNA and RNA by AlkB dioxygenase. Cytotoxic and mutagenic O(6)-methylguanine (O(6)meG) is repaired by Ada DNA methyltransferase, which transfers the methyl group onto its own cysteine residue from the methylated oxygen. We review (i) the individual Ada proteins Ada, AlkA, AlkB, AidB, and COG3826, with emphasis on the ubiquitous and versatile AlkB and its prokaryotic and eukaryotic homologs; (ii) the organization of the Ada regulon in several bacterial species; (iii) the mechanisms underlying activation of Ada transcription. In vivo and in silico analysis of various microorganisms shows the widespread existence and versatile organization of Ada regulon genes, including not only ada, alkA, alkB, and aidB but also COG3826, alkD, and other genes whose roles in repair of alkylated DNA remain to be elucidated. This review explores the comparative organization of Ada response and protein functions among bacterial species beyond the classical E. coli model.

Pseudomonas putida AlkA and AlkB proteins comprise different defense systems for the repair of alkylation damage to DNA - in vivo, in vitro, and in silico studies.

Alkylating agents introduce cytotoxic and/or mutagenic lesions to DNA bases leading to induction of adaptive (Ada) response, a mechanism protecting cells against deleterious effects of environmental chemicals. In Escherichia coli, the Ada response involves expression of four genes: ada, alkA, alkB, and aidB. In Pseudomonas putida, the organization of Ada regulon is different, raising questions regarding regulation of Ada gene expression. The aim of the presented studies was to analyze the role of AlkA glycosylase and AlkB dioxygenase in protecting P. putida cells against damage to DNA caused by alkylating agents. The results of bioinformatic analysis, of survival and mutagenesis of methyl methanesulfonate (MMS) or N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) treated P. putida mutants in ada, alkA and alkB genes as well as assay of promoter activity revealed diverse roles of Ada, AlkA and AlkB proteins in protecting cellular DNA against alkylating agents. We found AlkA protein crucial to abolish the cytotoxic but not the mutagenic effects of alkylans since: (i) the mutation in the alkA gene was the most deleterious for MMS/MNNG treated P. putida cells, (ii) the activity of the alkA promoter was Ada-dependent and the highest among the tested genes. P. putida AlkB (PpAlkB), characterized by optimal conditions for in vitro repair of specific substrates, complementation assay, and M13/MS2 survival test, allowed to establish conservation of enzymatic function of P. putida and E. coli AlkB protein. We found that the organization of P. putida Ada regulon differs from that of E. coli. AlkA protein induced within the Ada response is crucial for protecting P. putida against cytotoxicity, whereas Ada prevents the mutagenic action of alkylating agents. In contrast to E. coli AlkB (EcAlkB), PpAlkB remains beyond the Ada regulon and is expressed constitutively. It probably creates a backup system that protects P. putida strains defective in other DNA repair systems against alkylating agents of exo- and endogenous origin.

Mutagenic potency of MMS-induced 1meA/3meC lesions in E. coli.

The mutagenic activity of MMS in E. coli depends on the susceptibility of DNA bases to methylation and their repair by cellular defense systems. Among the lesions in methylated DNA is 1meA/3meC, which is recently recognized as being mutagenic. In this report, special attention is focused on the mutagenic properties of 1meA/3meC which, by the activity of AlkB-dioxygenase, are quickly and efficiently converted to natural A/C bases in the DNA of E. coli alkB(+) strains, preventing 1meA/3meC-induced mutations. We have found that in the absence of AlkB-mediated repair, MMS treatment results in an increased frequency of four types of base substitutions: GC-->CG, GC-->TA, AT-->CG, and AT-->TA, whereas overproduction of PolV in CC101-106 alkB(-)/pRW134 strains leads to a markedly elevated level of GC-->TA, GC-->CG, and AT-->TA transversions. It has been observed that in the case of AB1157 alkB(-) strains, the MMS-induced and 1meA/3meC-dependent argE3-->Arg(+) reversion occurs efficiently, whereas lacZ(-)--> Lac(+) reversion in a set of CC101-106 alkB(-) strains occurs with much lower frequency. We considered several reasons for this discrepancy, namely, the possible variance in the level of the PolV activity, the effect of the PolIV contents that is higher in CC101-106 than in AB1157 strains and the different genetic cell backgrounds in CC101-106 alkB(-) and AB1157 alkB(-) strains, respectively. We postulate that the difference in the number of targets undergoing mutation and different reactivity of MMS with ssDNA and dsDNA are responsible for the high (argE3-->Arg(+)) and low (lacZ(-) --> Lac(+)) frequency of MMS-induced mutations.