An allelic series of spontaneous mutations in Rorb cause a gait phenotype, retinal abnormalities, and transcriptomic changes relevant to human neurodevelopmental conditions

Rorb encodes the Retinoic Acid Receptor-related orphan receptor beta. Mutations in either of the two transcripts of Rorb cause defects in multiple systems, including abnormal photoreceptor abundance and morphology in the retina and a characteristic high-stepper or duck-like gait arising from dysfunction of interneurons in the spinal cord. Rorb is also important for cortical development and cell fate specification in mice. Rorb variants segregate with epilepsy and comorbidities such as intellectual disability in numerous clinical cases. Here we describe five mouse strains with spontaneous mutations in Rorb identified by their gait phenotype. These mutations affect different domains and isoforms of Rorb, which correspond to the spectrum of anatomical and physiological phenotypes exhibited by these mice. Gene set analysis in Rorb mutants implicates pathways associated with development and nervous system function, and differential gene expression analysis indicates changes in numerous genes related to epilepsy, bipolar disorder, and autism spectrum disorder (ASD). Many of these genes and their protein products are known to interact during synapse formation and neuronal activity. These findings further illuminate the role of Rorb in nervous system development, provide further evidence for an association between Rorb and several neurological conditions, and describe an allelic series of Rorb mutant mice that will be useful for dissecting thalamocortical afferent(TCA) development, neural cell fate determination, and as animal models exhibiting transcriptomic shifts in neurological conditions such as epilepsy, bipolar disorder, and ASD.

DNA Replication-Transcription Conflicts Do Not Significantly Contribute to Spontaneous Mutations Due to Replication Errors in Escherichia coli

Because DNA replication and transcription occur on the same DNA template, encounters between the two machines occur frequently. When these encounters are head-to-head, genomic disruption can occur.

Epigenetic modifications affect the rate of spontaneous mutations in a pathogenic fungus

Mutations are the source of genetic variation and the substrate for evolution. Genome-wide mutation rates appear to be affected by selection and are probably adaptive. Mutation rates are also known to vary along genomes, possibly in response to epigenetic modifications, but causality is only assumed. In this study we determine the direct impact of epigenetic modifications and temperature stress on mitotic mutation rates in a fungal pathogen using a mutation accumulation approach. Deletion mutants lacking epigenetic modifications confirm that histone mark H3K27me3 increases whereas H3K9me3 decreases the mutation rate. Furthermore, cytosine methylation in transposable elements (TE) increases the mutation rate 15-fold resulting in significantly less TE mobilization. Also accessory chromosomes have significantly higher mutation rates. Finally, we find that temperature stress substantially elevates the mutation rate. Taken together, we find that epigenetic modifications and environmental conditions modify the rate and the location of spontaneous mutations in the genome and alter its evolutionary trajectory.

Evaluation Of The Mutagenic Potential Of The Polyphenol Extract From Blueberries In The Ames Test

In this research, mutagenic properties of blueberry polyphenol extract were studied in gene mutation induction test (Ames test) on four strains of Salmonella typhimurium TA98, TA100, TA1535, TA1537. None of the strains of Salmonella typhimurium showed statistically reliable dose-dependent increase in number of revertant colonies in the presence of investigated drug in the studied dose range from 4,0 to 40,0 mg/ml relative to baseline of spontaneous mutations. The blueberry extract does not have any mutagenic activity in the researched dose range in relation to TA98, TA100, TA1535, TA1537 strains of Salmonella typhimurium.

The distribution of fitness effects of spontaneous mutations in Chlamydomonas reinhardtii inferred using frequency changes under experimental evolution

The distribution of fitness effects (DFE) for new mutations is fundamental for many aspects of population and quantitative genetics. In this study, we have inferred the DFE in the single-celled alga Chlamydomonas reinhardtii by estimating changes in the frequencies of 254 spontaneous mutations under experimental evolution and equating the frequency changes of linked mutations with their selection coefficients. We generated seven populations of recombinant haplotypes by crossing seven independently derived mutation accumulation lines carrying an average of 36 mutations in the homozygous state to a mutation-free strain of the same genotype. We then allowed the populations to evolve under natural selection in the laboratory by serial transfer in liquid culture. We observed substantial and repeatable changes in the frequencies of many groups of linked mutations, and, surprisingly, as many mutations were observed to increase as decrease in frequency. We developed a Bayesian Monte Carlo Markov Chain method to infer the DFE. This computes the likelihood of the observed distribution of changes of frequency, and obtains the posterior distribution of the selective effects of individual mutations, while assuming a two-sided gamma distribution of effects. We infer that the DFE is a highly leptokurtic distribution, and that approximately equal proportions of mutations have positive and negative effects on fitness. This result is consistent with what we have observed in previous work on a different C. reinhardtii strain, and suggests that a high fraction of new spontaneously arisen mutations are advantageous in a simple laboratory environment.

Ease of de novo gene birth through spontaneous mutations predicted in a parsimonious model

Contrary to long-held views, recent evidence indicates that de novo birth of genes is not only possible but is surprisingly prevalent: a substantial fraction of eukaryotic genomes are composed of orphan genes, which show no homology with any conserved genes. And a remarkably large proportion of orphan genes likely originated denovo from non-genic regions. Here, using a parsimonious mathematical model, we investigate the probability and timescale of de novo gene birth due to spontaneous mutations. We trace how an initially non-genic locus accumulates beneficial mutations to become a gene. We sample across a wide range of biologically feasible distributions of fitness effects (DFE) of mutations, and calculate the conditions conducive to gene birth. We find that in a time frame of millions of years, gene birth is highly likely for a wide range of DFEs. Moreover, when we allow DFEs to fluctuate, which is expected given the long time frame, gene birth in the model becomes practically inevitable. This supports the idea that gene birth is a ubiquitous process, and should occur in a wide variety of organisms. Our results also demonstrate that intergenic regions are not inactive and silent but are more like dynamic storehouses of potential genes.

Evidence for a force favoring GC over AT at short intronic sites in Drosophila simulans and D. melanogaster

Population genetics studies often make use of a class of nucleotide site free from selective pressures, in order to make inferences about population size changes or natural selection at other sites. If such neutral sites can be identified, they offer the opportunity to avoid any confounding effects of selection. Here we investigate evolution at putatively neutrally evolving short intronic sites in natural populations of Drosophila melanogaster and D. simulans, in order to understand the properties of spontaneous mutations and the extent of GC-biased gene conversion in these species. Use of data on the genetics of natural populations is advantageous because it integrates information from large numbers of individuals over long timescales. In agreement with direct evidence from observations of spontaneous mutations in Drosophila, we find a bias in the spectrum of mutations towards AT basepairs. In addition, we find that this bias is stronger in the D. melanogaster lineage than in the D. simulans lineage. The evidence for GC-biased gene conversion in Drosophila has been equivocal. Here we provide evidence for a weak force favoring GC in both species, which is correlated with the GC content of introns and is stronger in D. simulans than in D. melanogaster.

Spontaneous and targeted mutations in the decapping enzyme enhance replication of modified vaccinia virus Ankara (MVA) in monkey cells

Modified vaccinia virus Ankara (MVA) was derived by repeated passaging in chick fibroblasts, during which deletions and mutations rendered the virus unable to replicate in most mammalian cells. Marker rescue experiments demonstrated that the host range defect could be overcome by replacing DNA that had been deleted from near the left end of the genome. One virus isolate, however, recovered the ability to replicate in monkey BS-C-1 cells but not human cells without added DNA suggesting it arose from a spontaneous mutation. Here we showed that variants with enhanced ability to replicate in BS-C-1 cells could be isolated by blind passaging MVA and that in each there was a point mutation leading to an amino acid substitution in the D10 decapping enzyme. The sufficiency of these single mutations to enhance host range was confirmed by constructing recombinant viruses. The D10 mutations occurred at N- or C-terminal locations distal from the active site, suggesting an indirect effect on decapping or on another previously unknown role of D10. Although increased amounts of viral mRNA and proteins were found in BS-C-1 cells infected with the mutants compared to parental MVA, the increase was much less than the one to two logs higher virus yields. Nevertheless, a contributing role for diminished decapping in overcoming the host range defect was consistent with increased replication and viral protein synthesis in BS-C-1 cells infected with an MVA engineered to have active site mutations that abrogate decapping activity entirely. Optimal decapping may vary depending on the biological context. IMPORTANCE Modified vaccinia virus Ankara (MVA) is an attenuated virus that is approved as a smallpox vaccine and is in clinical trials as a vector for other pathogens. The safety of MVA is due in large part to its inability to replicate in mammalian cells. Although, host-range restriction is considered a stable feature of the virus, we describe the occurrence of spontaneous mutations in MVA that increase replication considerably in monkey BS-C-1 cells but only slightly in human cells. The mutants contain single nucleotide changes that lead to amino acid substitutions in one of the two decapping enzymes. Although the spontaneous mutations are distant from the decapping enzyme active site, engineered active site-mutations also increased virus replication in BS-C-1 cells. The effects of these mutations on the immunogenicity of MVA vectors remain to be determined.

Collateral damage: Identification and characterisation of spontaneous mutations causing deafness from a targeted knockout programme

Mice carrying targeted mutations are important for investigating gene function and the role of genes in disease, but the process of culturing embryonic stem cells during the making of a targeted allele offers opportunities for spontaneous mutations to arise. Identifying spontaneous mutations relies on the detection of phenotypes segregating independently of targeted alleles, and many phenotypes are easy to miss if not specifically looked for. Here we present data from a large, targeted knockout programme in which mice were analysed through a phenotyping pipeline. Twenty-five lines out of 1311 displayed different deafness phenotypes that did not segregate with the targeted allele. We have identified 8 different mutations causing deafness in 16 of these 25 lines and characterised the resulting phenotypes. Our data show that spontaneous mutations with observable effects on phenotype are a common side effect of intensive breeding programmes, including those underlying targeted mutation programmes.

Mismatch Repair: From Preserving Genome Stability to Enabling Mutation Studies in Real-Time Single Cells

Mismatch Repair (MMR) is an important and conserved keeper of the maintenance of genetic information. Miroslav Radman’s contributions to the field of MMR are multiple and tremendous. One of the most notable was to provide, along with Bob Wagner and Matthew Meselson, the first direct evidence for the existence of the methyl-directed MMR. The purpose of this review is to outline several aspects and biological implications of MMR that his work has helped unveil, including the role of MMR during replication and recombination editing, and the current understanding of its mechanism. The review also summarizes recent discoveries related to the visualization of MMR components and discusses how it has helped shape our understanding of the coupling of mismatch recognition to replication. Finally, the author explains how visualization of MMR components has paved the way to the study of spontaneous mutations in living cells in real time.