First Detection of the SARS-CoV-2 Omicron BA.5/22B in Monaco.

The Omicron BA.5/22B variant has been designated as a "variant of concern" by the World Health Organization. We describe, here, the first evidence in Monaco of infection with an Omicron BA.5/22B variant, probably imported from the Republic of Seychelles, harboring a rare combination of non-BA.5/22B signature amino acid changes. SARS-CoV-2 neutralizing antibodies were measured with a surrogate virus neutralization test. SARS-CoV-2 genotype screening was performed on nasopharyngeal samples with a multiplex qPCR assay. The SARS-CoV-2 genome was obtained by next-generation sequencing with the Illumina COVID-seq protocol, then assembly using bioinformatics pipelines and software was performed. The BA.5/22B spike protein structure was obtained by molecular modeling. Two spouses were SARS-CoV-2-diagnosed the day they returned from a one-week trip in the Republic of Seychelles. SARS-CoV-2 qPCR screening for variant-specific mutations identified an Omicron variant BA.1/21K, BA.4/22A, or BA.5/22B. A SARS-Co-2 BA.5/22B variant genome was recovered from one of the spouses. Aside from BA.5/22B-defining amino acid substitutions, four other amino acid changes were encoded including Q556K in ORF1a, K2557R in ORF1b, and A67V and A829T in spike; only 13 genomes in sequence databases harbored these four mutations concurrently. Structural analysis of this BA.5/22B variant predicted that A829T in spike may result in a compaction that may affect conformational plasticity. Overall, our findings warrant performing genome-based genotypic surveillance to survey accurately the emergence and circulation of SARS-CoV-2 variants worldwide and point out that their first occurrence in a country is often through international travel despite implemented countermeasures.

CRDSAT Generated by pCARGHO: A New Efficient Lectin-Based Affinity Tag Method for Safe, Simple, and Low-Cost Protein Purification.

Purification of recombinant proteins remains a bottleneck for downstream processing. The authors engineered a new galectin 3 truncated form (CRDSAT ), functionally and structurally characterized, with preserved solubility and lectinic activity. Taking advantage of these properties, the authors designed an expression vector (pCARGHO), suitable for CRDSAT -tagged protein expression in prokaryotes. CRDSAT binds to lactose-Sepharose with a high specificity and facilitates solubilization of fusion proteins. This tag is structurally stable and can be easily removed from fusion proteins using TEV protease. Furthermore, due to their basic isoelectric point (pI), CRDSAT , and TEV are efficiently eliminated using cationic exchange chromatography. When pI of the protein of interest (POI) and CRDSAT are close, other chromatographic methods are successfully tested. Using CRDSAT tag, the authors purified several proteins from prokaryote and eukaryote origin and demonstrated as examples, the preservation of both Escherichia coli Thioredoxin 1 and human CDC25Bcd activities. Overall, yields of proteins obtained after tag removal are about 5-50 mg per litre of bacterial culture. Our purification method displays various advantages described herein that may greatly interest academic laboratories, biotechnology, and pharmaceutical companies.

Inducibility of Tn916 conjugative transfer in Enterococcus faecalis by subinhibitory concentrations of ribosome-targeting antibiotics.

Background: Some antibiotics induce the dissemination of their own resistance genes by interfering with the regulation of specific mobile genetic elements. In Tn916, subinhibitory concentrations of tetracycline activate the transfer of the element through an anti-attenuation mechanism that relies on the Tet(M) resistance protein, itself encoded by the element. Objectives: This work explores the effects of a broad range of antibiotics on the transfer of Tn916 and for which the element does not provide any selective advantage. Methods: A sensitive promoter-reporter fusion approach was developed to test the effects of full antibiotic concentration gradients on gene promoter expression. Sixty molecules, covering most classes of antibiotics, were screened for their ability to modulate the activity of promoter Porf12 controlling the transfer of Tn916. Induction of Tn916 transfer was further demonstrated in mating assays with Enterococcus faecalis donors pre-exposed to subinhibitory concentrations of modulating antibiotics. Results: Several antibiotics, other than tetracyclines, were identified as interfering with Tn916 regulation. Macrolides, lincosamides and streptogramins appeared to activate the transfer of Tn916 at unprecedented levels, in a Tet(M)-independent way that implies a yet undescribed regulatory mechanism for controlling the mobility of the element. Conclusions: These results demonstrate that some ribosome-targeting antibiotics can induce the transfer of a given mobile genetic element, here Tn916, although it does not provide any resistance determinant for most of the triggering drugs. This implies that specific antibiotic therapies can have dramatic impacts on the dissemination of unexpected and unlinked resistance genes, with the clear risk of reducing our therapeutic potential for later treatments.

Human umbilical cord derived matrix: A scaffold suitable for tissue engineering application.

BACKGROUND: Human tissue derived natural extracellular matrix (ECM) has great potential in tissue engineering. OBJECTIVE: We sought to isolate extracellular matrix derived from human umbilical cord and test its potential in tissue engineering. METHODS: An enzymatic method was applied to isolate and solubilized complete human umbilical cord derived matrix (hUCM). The obtained solution was analyzed for growth factors, collagen and residual DNA contents, then used to coat 2D and 3D surfaces for cell culture application. RESULTS: The hUCM was successfully isolated with trypsin digestion to acquire a solution containing various growth factors and collagen but no residual DNA. This hUCM solution can form a coating on 2D and 3D substrates suitable cell culture. CONCLUSION: We developed a new matrix derived from human source that can be further used in tissue engineering.