GJB2 mutation spectrum in deaf population in a typical southeastern area of China

Mutations in GJB2 gene are the most frequently found mutations in patients with nonsyndromic hearing impairment. However, the spectrum and prevalence of mutations in this gene vary among different ethnic groups. In China, 30,000 infants are born with congenital hearing impairment annually. In order to provide appropriate genetic testing and counseling to the families, we investigated the molecular etiology of nonsyndromic deafness in 103 unrelated school children attending Nantong School for the Deaf and Mute in Jiangsu Province, China. The coding exon of the GJB2 gene was PCR amplified and sequenced. Sixty two GJB2 mutant alleles were identified in 35.9% (37/103) of the patients. Twenty five patients carried two pathogenic mutations and 12 patients carried one mutant allele. The 235delC was the most common mutation accounting for 69.4% (43/62) of GJB2 mutant alleles. The GJB2 mutant alleles accounted for 30.1% (62/206) of all chromosomes responsible for nonsyndromic hearing impairment. Testing of the 3 most prevalent deleterious frame shift mutations in this cohort detected 100% of all GJB2 mutant alleles. These results demonstrate that an effective genetic testing of GJB2 gene for patients and families with nonsyndromic hearing impairment is possible.

Spectrum of Glycidyl Methacrylate-induced Mutation in Plasmid-Escherichia coli System

In order to chitracterizc the speclrum of mutallon indueed by glyeidyl methacrylule(GMA ), the plasmid pBR322 was modificed with this mutagen in vitro , transttclcd intoapproprate Escherichia colii host HB101. The mutants were then sereened and defined by DNA sequencing . Sequence analysis reveals that G MA induces two classes of mulations deletion of the mono-. di' or fetra-base or the insertion of mono' or di-base. Both typesof mutations, with about 10 % frequency. occur predominantly at C-G runs and at5'-CNCCN-3' sequence ,which are hotspots for GMA damage and may cause frameshift mutation.

Spontaneous mutations and mutational responses to penicillin treatment in the bacterial pathogen Streptococcus pneumoniae D39

Bacteria with functional DNA repair systems are expected to have low mutation rates due to strong natural selection for genomic stability.However,our study of the wild-type Streptococcus pneumoniae D39,a pathogen responsible for many common diseases,revealed a high spontaneous mutation rate of 0.02 per genome per cell division in mutation-accumulation(MA)lines.This rate is orders of magnitude higher than that of other non-mutator bacteria and is characterized by a high mutation bias in the A/T direction.The high mutation rate may have resulted from a reduction in the overall efficiency of selection,conferred by the tiny effective population size in nature.In line with this,S.pneumoniae D39 also exhibited the lowest DNA mismatch-repair(MMR)efficiency among bacteria.Treatment with the antibiotic penicillin did not elevate the mutation rate,as penicillin did not induce DNA damage and S.pneumoniae lacks a stress response pathway.Our findings suggested that the MA results are applicable to within-host scenarios and provide insights into pathogen evolution.

Contribution of the SOS response and the DNA repair systems to norfloxacin induced mutations in E.coli

Antibiotic-resistant bacteria severely threaten human health.Besides spontaneous mutations generated by endogenous factors,the resistance might also originate from mutations induced by certain antibiotics,such as the fluoroquinolones.Such antibiotics increase the genome-wide mutation rate by introducing replication errors from the SOS response pathway or decreasing the efficiency of the DNA repair systems.However,the relative contributions of these molecular mechanisms remain unclear,hindering understanding of the generation of resistant pathogens.Here,using newly-accumulated mutations of wild-type and SOS-uninducible Escherichia coli strains,as well as those of the strains deficient for the mismatch repair(MMR)and the oxidative damage repair pathways,we find that the SOS response is the major mutagenesis contributor in mutation elevation,responsible for~30–50%of the total base-pair substitution(BPS)mutation-rate elevation upon treatment with sublethal levels of norfloxacin(0~50 ng/mL).We further estimate the significance of the effects on other mutational features of these mechanisms(i.e.,transversions,structural variations,and mutation spectrum)in E.coli using linear models.The SOS response plays a positive role in all three mutational features(mutation rates of BPSs,transversions,structural variations)and affects the mutational spectrum.The repair systems significantly reduce the BPS mutation rate and the transversion rate,regardless of whether antibiotics are present,while significantly increasing the structural variation rate in E.coli.Our results quantitatively disentangle the contributions of the SOS response and DNA repair systems in antibiotic-induced mutagenesis.

CTNS Molecular Genetics Profile in a Portuguese Cystinosis Population

Background: Cystinosis is a multisystemic autosomal recessive deficiency of the lysosomal membrane transporter protein (cystinosin) caused by mutations in CTNS gene. Objective: This study summarizes the Portuguese experience in the diagnosis and management of patients with this rare disease over the past few years and reports recurrent mutations in the CTNS gene. Methods: Unrelated patients from different pediatric and adult hospitals all over Portugal with non-nephrotic proteinuria, hypercalciuria, hypokalemia impaired proximal reabsorption of amino acids, glycosuria and hypophosphatemia, suggestive of a Fanconi syndrome and ocular problems, were studied. Intra-leukocyte cystine levels were determined and molecular analysis was performed, to determine the presence or absence of the 57-kb deletion in CTNS, followed by direct sequencing of the coding exons of CTNS. Results: From 1998 to 2017, twenty-one cystinotic patients were biochemically diagnosed. From the remaining seventeen (four deceased), eleven were studied for CTNS gene. Five out of eleven patients were homozygous for the 57-kb deletion (10/22;45.5%), and other five were compound heterozygous for this variant (15/22;68.2%). The other mutations found were p.Q128X (c.721 C>T;2/22), p.S139F (c.755 C>T;4/22) and c.18-21delGACT (p.T7FfsX7;1/22). All of these seventeen cystinotic patients are in treatment. Approximately 84% are adults, 16% are young children, and 54.5% are kidney transplant recipient. Conclusions: The authors would like to emphasize the importance of first screening for the 57-kb deletion since it is very common in our population. This genetic study is the first in our country and it could be the basis for future genetic counseling in Portuguese population.

Frequency and type of inheritable mutations induced by γ rays in rice as revealed by whole genome sequencing

Mutation breeding is based on the induction of genetic variations; hence knowledge of the frequency and type of induced mutations is of paramount importance for the design and implementation of a mutation breeding program. Although γ ray irradiation has been widely used since the 1960 s in the breeding of about 200 economically important plant species, molecular elucidation of its genetic effects has so far been achieved largely by analysis of target genes or genomic regions. In the present study, the whole genomes of six γ-irradiated M2 rice plants were sequenced; a total of 144–188 million high-quality（Q〉20） reads were generated for each M2 plant, resulting in genome coverage of 45 times for each plant. Single base substitution（SBS） and short insertion/deletion（Indel） mutations were detected at the average frequency of 7.5×10^-6～9.8×10^-6 in the six M2 rice plants（SBS being about 4 times more frequent than Indels）. Structural and copy number variations, though less frequent than SBS and Indel, were also identified and validated. The mutations were scattered in all genomic regions across 12 rice chromosomes without apparent hotspots. The present study is the first genome-wide single-nucleotide resolution study on the feature and frequency of γ irradiation-induced mutations in a seed propagated crop; the findings are of practical importance for mutation breeding of rice and other crop species.

Compositional Variability and Mutation Spectra of Monophyletic SARS-CoV-2 Clades

COVID-19 and its causative pathogen SARS-CoV-2 have rushed the world into a staggering pandemic in a few months,and a global fight against both has been intensifying.Here,we describe an analysis procedure where genome composition and its variables are related,through the genetic code to molecular mechanisms,based on understanding of RNA replication and its feedback loop from mutation to viral proteome sequence fraternity including effective sites on the replicase-transcriptase complex.Our analysis starts with primary sequence information,identity-based phylogeny based on 22,051 SARS-CoV-2 sequences,and evaluation of sequence variation patterns as mutation spectra and its 12 permutations among organized clades.All are tailored to two key mechanisms:strand-biased and function-associated mutations.Our findings are listed as follows:1)The most dominant mutation is C-to-U permutation,whose abundant second-codon-position counts alter amino acid composition toward higher molecular weight and lower hydrophobicity,albeit assumed most slightly deleterious.2)The second abundance group includes three negative-strand mutations(U-to-C,A-to-G,and G-to-A)and a positive-strand mutation(G-to-U)due to DNA repair mechanisms after cellular abasic events.3)A clade-associated biased mutation trend is found attributable to elevated level of negative-sense strand synthesis.4)Within-clade permutation variation is very informative for associating non-synonymous mutations and viral proteome changes.These findings demand a platform where emerging mutations are mapped onto mostly subtle but fast-adjusting viral proteomes and transcriptomes,to provide biological and clinical information after logical convergence for effective pharmaceutical and diagnostic applications.Such actions are in desperate need,especially in the middle of the War against COVID-19.

The insect-killing bacterium Photorhabdus luminescens has the lowest mutation rate among bacteria

Mutation is a primary source of genetic variation that is used to power evolution.Many studies,however,have shown that most mutations are deleterious and,as a result,extremely low mutation rates might be benefcial for survival.Using a mutation accumulation experiment,an unbiased method for mutation study,we found an extremely low base-substitution mutation rate of 5.94×10^(-11) per nucleotide site per cell division(95%Poisson confdence intervals:4.65×10^(-11),7.48×10^(-11))and indel mutation rate of 8.25×10^(-12) per site per cell division(95%confdence intervals:3.96×10^(-12),1.52×10^(-11))in the bacterium Photorhabdus luminescens ATCC29999.The mutations are strongly A/T-biased with a mutation bias of 10.28 in the A/T direction.It has been hypothesized that the ability for selection to lower mutation rates is inversely proportional to the efective population size(drift-barrier hypothesis)and we found that the efective population size of this bacterium is signifcantly greater than most other bacteria.This fnding further decreases the lower-bounds of bacterial mutation rates and provides evidence that extreme levels of replication fdelity can evolve within organisms that maintain large efective population sizes.

Evidence for a mouse origin of the SARS-CoV-2 Omicron variant

The rapid accumulation of mutations in the SARS-CoV-2 Omicron variant that enabled its outbreak raises questions as to whether its proximal origin occurred in humans or another mammalian host. Here, we identified 45 point mutations that Omicron acquired since divergence from the B.1.1 lineage. We found that the Omicron spike protein sequence was subjected to stronger positive selection than that of any reported SARS-CoV-2 variants known to evolve persistently in human hosts, suggesting a possibility of hostjumping. The molecular spectrum of mutations(i.e., the relative frequency of the 12 types of base substitutions) acquired by the progenitor of Omicron was significantly different from the spectrum for viruses that evolved in human patients but resembled the spectra associated with virus evolution in a mouse cellular environment. Furthermore, mutations in the Omicron spike protein significantly overlapped with SARS-CoV-2 mutations known to promote adaptation to mouse hosts, particularly through enhanced spike protein binding affinity for the mouse cell entry receptor. Collectively, our results suggest that the progenitor of Omicron jumped from humans to mice, rapidly accumulated mutations conducive to infecting that host,then jumped back into humans, indicating an inter-species evolutionary trajectory for the Omicron outbreak.