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[
Int J Food Microbiol,
2016]
The current study explores the in vitro and in vivo antibiofilm efficacy of morin against a leading foodborne pathogen-Listeria monocytogenes (LM). Minimum inhibitory concentration (MIC) of morin against LM strains was found to be 100g/ml. The non-antibacterial effect of morin at its sub-MICs (6.25, 12.5 and 25g/ml) was determined through growth curve and XTT assay. Morin at its sub-MICs demonstrated a significant dose dependent inhibitory efficacy against LM biofilm formation which was also evidenced through light, confocal and scanning electron microscopic analyses. However, morin failed to disperse the mature biofilm of LM even at its MIC. Our data also revealed the anti-virulence efficacy of morin, as it significantly inhibited the production of hemolysin and motility of LM. Concentration-dependent susceptibility of morin treated LM cells to normal human serum was observed. In vivo studies revealed that morin extended the lifespan of LM infected Caenorhabditis elegans by about 85%. Furthermore, the non-toxic nature and in vivo anti-adherence efficacy of morin were also ascertained through C. elegans-LM infection model. Overall, the data of the current study identifies morin as a promising antibiofilm agent and its suitability to formulate protective strategies against biofilm associated infections caused by LM.
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[
ACS Chem Neurosci,
2020]
The gyloxalase pathway (GP) is an antioxidant defense system that detoxifies metabolic byproduct methylglyoxal (MG). Through sequential reactions, reduced glutathione (GSH), glyoxalase I (
glo-1), and glyoxalase II (
glo-2) convert MG into D-lactate. Spontaneous reactions involving MG alter the structure and function of cellular macromolecules through the formation of inflammatory advanced glycation endproducts (AGEs). Accumulation of MG and AGEs in neural cells contributes to oxidative stress (OS), a state of elevated inflammation commonly found in neurodegenerative diseases including Alzheimer's Disease (AD). Morin is a common plant-produced flavonoid polyphenol that exhibits the ability to enhance the GP-mediated detoxification of MG. We hypothesize that structural modifications to morin will improve its inherent GP enhancing ability. Here we synthesized a morin derivative, dibromo-morin (DBM) and formulated a morin encapsulated nanoparticle (MNP) - and examined their efficacy in enhancing neural GP activity. Cultured mouse primary cerebellar neurons and Caenorhabditis elegans were induced to a state of OS with MG, and treated with morin, DBM, and MNP. Results indicated the morin derivatives were more effective compared to the parent compound in neural GP enhancement and preventing MG-mediated OS.
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[
Neurochem Res,
2012]
Substantial evidence suggests that the aggregation of amyloid- (A) peptide into fibrillar structures that is rich in -sheets is implicated as the cause of Alzheimer's disease. Therefore, an attractive therapeutic strategy is to prevent or alter A aggregation. Phenolic compounds are natural substances that are composed of one or more aromatic phenolic rings and present in wine, tea, fruits, vegetables and a wide variety of plants. In this work, we investigated the effects of ferulic acid, morin, quercetin and gossypol against A aggregation. From the ThT and turbidity assays, it is observed that in addition to the fibril aggregate, another type of aggregate is formed in the presence of morin, quercetin, and gossypol. On the other hand, ferulic acid did not prevent fibril formation, but it did appear to reduce the average length of fibrils compared to A alone. To study the protective effects of phenolic compounds on A-induced toxicity, we utilized the nematode Caenorhabditis elegans (C. elegans) as an in vivo model organism, human A is expressed intracellularly in the body wall muscle. We found that exposure of Caenorhabditis elegans to ferulic acid give more protection against A toxicity than morin, quercetin and gossypol.
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[
Worm Breeder's Gazette,
1976]
We have studied maternal effects in 23 zyg ts mutants to estimate the times of expression of genes whose products are required in embryogenesis. We have used the following three tests, called arbitrarily A, B, and C. A test: Heterozygous (m/+) L4's are shifted to 25 C and allowed to self-fertilize. If 100% of their eggs yield larvae (25% of which express the mutant phenotype as adults), then the mutant is scored as maternal (M). If 25% of the F1 eggs fail to hatch, then the mutant is scored as non-maternal (N). An M result indicates that expression of the + allele in the parent allows m/m zygotes to hatch and grow to adulthood. A result of N indicates the opposite: that the + allele must be expressed in the zygote for hatching to occur. Out of 23 zyg mutants tested, 3 were scored N and 20 were scored M in the A test. Therefore, for most of the genes defined by these mutants, expression in the parent is sufficient for zygote survival, even if the gene is not expressed in the zygote. B test: Homozygous (m/m) hermaphrodites reared at 25 C are mated with N2 (+/+) males. If eggs fail to hatch at 25 C, but mated hermaphrodites shifted to 16 C produce cross progeny to give proof of mating, then the mutant is scored M. If cross progeny appear in the 25 C mating, then the mutant is scored N. An M result indicates that expression of the + allele in the zygote is not sufficient to allow m/+ progeny of an m/m hermaphrodite to survive. Conversely an N result indicates either that zygotic expression of the + allele is sufficient for survival, or that a sperm function or factor needed for early embryogenesis can be supplied paternally (see C test below). Out of the 23 zyg mutants tested, 11 were scored M and 12 were scored N. The combined results of A and B tests and their simplest interpretation are as follows. Ten mutants are M,M; the genes defined by these mutants must be expressed in the hermaphrodite parent for the zygote to survive. Ten mutants are M,N; these genes can be expressed either in the parent or in the zygote. Two mutants are N,N; these genes must be expressed in the zygote. One mutant is N,M; this gene must be expressed both in the maternal parent and in the zygote. C test: Homozygous (m/m) hermaphrodites reared at 25 C are mated with heterozygous (m/+) males. If rescue by a +/+ male in the B test depends on the + allele, then only half the cross progeny zygotes of a C test mating (m/+ male x m/m hermaphrodite) should survive. However, if rescue depends on a function or cytoplasmic component from the male sperm, then all the cross progeny zygotes in a C test should survive. Of the 10 M,N mutants, 6 have been C tested; one exhibited paternal rescue independent of the + allele. The A and B tests also were carried out on 16 mutants that arrest before the L3 molt (acc mutants). In the A test on 2 of these mutants, all m/m progeny of m/+ parents grew to adulthood at 25 C. Therefore, parental contributions are sufficient to overcome a progeny mutational block as late as the L2 stage. All 16 acc mutants scored N in the B test.
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Miska EA, Legrand C, Braukmann F, Jordan D, Navarro IC, Lyko F, Akay A, Price J, Helm M, Tuorto F, Kotter A, Hendrick AG
[
EMBO J,
2020]
Methylation of carbon-5 of cytosines (m<sup>5</sup> C) is a post-transcriptional nucleotide modification of RNA found in all kingdoms of life. While individual m<sup>5</sup> C-methyltransferases have been studied, the impact of the global cytosine-5 methylome on development, homeostasis and stress remains unknown. Here, using Caenorhabditis elegans, we generated the first organism devoid of m<sup>5</sup> C in RNA, demonstrating that this modification is non-essential. Using this genetic tool, we determine the localisation and enzymatic specificity of m<sup>5</sup> C sites in the RNome in vivo. We find that NSUN-4 acts as a dual rRNA and tRNA methyltransferase in C.elegans mitochondria. In agreement with leucine and proline being the most frequently methylated tRNA isoacceptors, loss of m<sup>5</sup> C impacts the decoding of some triplets of these two amino acids, leading to reduced translation efficiency. Upon heat stress, m<sup>5</sup> C loss leads to ribosome stalling at UUG triplets, the only codon translated by an m<sup>5</sup> C34-modified tRNA. This leads to reduced translation efficiency of UUG-rich transcripts and impaired fertility, suggesting a role of m<sup>5</sup> C tRNA wobble methylation in the adaptation to higher temperatures.
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[
Wellcome Open Res,
2022]
<b>Background:</b> Methylation of carbon-5 of cytosines (m <sup>5</sup>C) is a conserved post-transcriptional nucleotide modification of RNA with widespread distribution across organisms. It can be further modified to yield&#
xa0;5-hydroxymethylcytidine (hm <sup>5</sup>C), 5-formylcytidine (f <sup>5</sup>C), 2&#
xb4;-O-methyl-5-hydroxymethylcytidine (hm <sup>5</sup>Cm) and 2&#
xb4;-O-methyl-5-formylcytidine (f <sup>5</sup>Cm).&#
xa0;How m <sup>5</sup>C, and specially its derivates, contribute to biology mechanistically is poorly understood. We recently showed that m <sup>5</sup>C is required for <i>Caenorhabditis elegans</i> development and fertility under heat stress. m <sup>5</sup>C has been shown to participate in mRNA transport and maintain mRNA stability through its recognition by the reader proteins ALYREF and YBX1, respectively. Hence, identifying readers for RNA modifications can enhance our understanding in the biological roles of these modifications. <b>Methods:</b> To contribute to the understanding of how m <sup>5</sup>C and its oxidative derivatives mediate their functions, we developed RNA baits bearing modified cytosines in diverse structural contexts to pulldown potential readers in <i>C. elegans</i>. Potential readers were identified using mass spectrometry. The interaction of two of the putative readers with m <sup>5</sup>C was validated using immunoblotting. <b>Results:</b> Our mass spectrometry analyses revealed unique binding proteins for each of the modifications. <i>In silico</i> analysis for phenotype enrichments suggested that hm <sup>5</sup>Cm unique readers are enriched in proteins involved in RNA processing, while readers for m <sup>5</sup>C, hm <sup>5</sup>C and f <sup>5</sup>C are involved in germline processes. We validated our dataset by demonstrating that the nematode ALYREF homologues ALY-1 and ALY-2 preferentially bind m <sup>5</sup>C <i>in vitro</i>. Finally, sequence alignment analysis showed that several of the putative m <sup>5</sup>C readers contain the conserved RNA recognition motif (RRM), including ALY-1 and ALY-2. <b>Conclusions:</b> The dataset presented here serves as an important scientific resource that will support the discovery of new functions of m <sup>5</sup>C and its derivatives. Furthermore, we demonstrate that ALY-1 and ALY-2 bind to m <sup>5</sup>C in <i>C. elegans</i>.
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[
International Worm Meeting,
2019]
Purpose: The balance between cellular identity maintenance and cellular plasticity (as the potential to change identity on a functional and morphological level) is a major challenge for organismal tissues. Uncontrolled cell fate changes can cause dysfunctional cellular behaviors such as cancer. Unraveling the mechanisms behind cell type conversion will further help to develop a safe environment for regenerative medicine. Here, we describe how chromatin remodeling as well as several external factors impacts on cellular identity and increase a cell's plasticity potential. Methods: We use a natural cell identity conversion in the worm to determine how a cell can change or maintain its identity. C. elegans rectal to neuronal Y-to-PDA transition is a bona fide robust transdifferentiation (Td) event: During L2 larval stage the rectal identity of the Y cell is erased completely, followed by redifferentiation into a fully functional motoneuron, named PDA. Results: We previously described a subset of essential factors driving Td initiation. We identified two novel positive regulators of Td:
lin-15A and
lin-56. In null mutants for these genes, PDA neurons are not made and Y cells remain epithelial. Genetic interactions suggest that these two genes act in a parallel pathway to the previously described "drivers" during Td initiation and that they antagonize a SynMuvB-based identity maintenance mechanism to "license" Td in the Y cell. Our data suggest that this brake is represented by a defined chromatin state, and genetic alterations of chromatin architecture are able to suppress
lin-15A phenotype. Excitingly, we found that this suppression is phenocopied under different environmental conditions: in particular, starvation and caloric restriction decrease PDA defects. Our data point to a food signal mediated by IIS and TOR pathways impacting cellular plasticity. Conclusion: Our data suggest that Td initiation requires not only drivers TF but also "licensers" such as
lin-15A and
lin-56 that allow Td to occur by removing negative regulators and enabling chromatin remodelling, whereas several environmental conditions can bypass the need for the licensers, and thus, increase plasticity and allow transdifferentiation to occur.
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[
Biochemistry,
2012]
Decapping scavenger (DcpS) enzymes catalyze the cleavage of a residual cap structure following 3' 5' mRNA decay. Some previous studies suggested that both m(7)GpppG and m(7)GDP were substrates for DcpS hydrolysis. Herein, we show that mononucleoside diphosphates, m(7)GDP (7-methylguanosine diphosphate) and m(3)(2,2,7)GDP (2,2,7-trimethylguanosine diphosphate), resulting from mRNA decapping by the Dcp1/2 complex in the 5' 3' mRNA decay, are not degraded by recombinant DcpS proteins (human, nematode, and yeast). Furthermore, whereas mononucleoside diphosphates (m(7)GDP and m(3)(2,2,7)GDP) are not hydrolyzed by DcpS, mononucleoside triphosphates (m(7)GTP and m(3)(2,2,7)GTP) are, demonstrating the importance of a triphosphate chain for DcpS hydrolytic activity. m(7)GTP and m(3)(2,2,7)GTP are cleaved at a slower rate than their corresponding dinucleotides (m(7)GpppG and m(3)(2,2,7)GpppG, respectively), indicating an involvement of the second nucleoside for efficient DcpS-mediated digestion. Although DcpS enzymes cannot hydrolyze m(7)GDP, they have a high binding affinity for m(7)GDP and m(7)GDP potently inhibits DcpS hydrolysis of m(7)GpppG, suggesting that m(7)GDP may function as an efficient DcpS inhibitor. Our data have important implications for the regulatory role of m(7)GDP in mRNA metabolic pathways due to its possible interactions with different cap-binding proteins, such as DcpS or eIF4E.
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[
Arch Environ Contam Toxicol,
2005]
Fungi (Cunninghamella elegans ATCC 9245, Mucor ramannianus R-56, Aspergillus niger VKMF-1119, and Phanerochaete chrysosporium BKMF-1767) were tested to elucidate the biologic fate of the topical insect repellent N,N-diethyl-m-toluamide (DEET). The elution profile obtained from analysis by high-pressure liquid chromatography equipped with a reverse-phase C-18 column, showed that three peaks occurred after incubation of C. elegans, with which 1 mM DEET was combined as a final concentration. The peaks were not detected in the control experiments with either DEET alone or tested fungus alone. The metabolites produced by C. elegans exhibited a molecular mass of 207 with a fragment ion (m/z) at 135, a molecular mass of 179 with an m/z at 135, and a molecular mass of 163 with an m/z at 119, all of which correspond to N,N-diethyl-m-toluamide-N-oxide, N-ethyl-m-toluamide-N-oxide, and N-ethyl-m-toluamide, respectively. M. ramannianus R-56 also produced N, N-diethyl-m-toluamide-N-oxide and N-ethyl-m-toluamide but did not produce N-ethyl-m-toluamide-N-oxide. For the biologic toxicity test with DEET and its metabolites, the freshwater zooplankton Daphnia magna was used. The biologic sensitivity in decreasing order was DEET > N-ethyl-m-toluamide > N,N-diethyl-m-toluamide-N-oxide. Although DEET and its fungal metabolites showed relatively low mortality compared with other insecticides, the toxicity was increased at longer exposure periods. These are the first reports of the metabolism of DEET by fungi and of the biologic toxicity of DEET and its fungal metabolites to the freshwater zooplankton D. magna.
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[
Worm Breeder's Gazette,
1994]
LOOKING FOR EXTRACELLULAR MATRIX PROTEINASES IN C. ELEGANS. James A. Butler and James M. Kramer, Northwestern University Medical School. Department of CMS Biology, Chicago IL 60611