Insertion Mutants Research Articles

Molecular Biodiversity in Fusarium subglutinans and F. temperatum: A Valuable Tool to Distinguish the Two Sister Species and Determine the Beauvericin Chemotype

Fusarium subglutinans and F. temperatum are widely distributed maize pathogens recognized as distinct species with a species-specific chemotype based on patterns of mycotoxins. Recent comparative genomic analysis revealed that genomes of both species carry a complete beauvericin (Bea) biosynthetic genes cluster, but the key gene Bea1 in F. subglutinans is not functional likely due to a large insertion (NRPS22ins) and multiple mutations (SNP298 and SNP528). We used the recently published genome sequences for these species to develop PCR markers for investigating the distribution of three main mutations in the Bea1 gene in a large collection of strains of both species from around the world. We also designed a PCR assay for a rapid and reliable discrimination of both species in the evaluation of crop exposure to mycotoxins. Overall, our results showed that SNP528 was the most common mutation, followed by NRPS22ins and SNP298. Moreover, phylogenetic analyses suggest that non-synonymous SNPs have occurred first, and that the resulting inactivation of BEA production has caused the accumulation of other polymorphisms, including the NRPS22ins, in the entire gene-coding region. The screening for genetic differences between these species could guide future crop management strategies.

The Validation of Whole β-Globin Gene Sequencing for Detecting β-Thalassemia Mutations Found in Thailand Using Next-Generation Sequencing (NGS)

Beta-thalassemia is an inherited disorder prevalent in Thailand and Southeast Asia. Several molecular techniques for identifying β-thalassemia mutations have been reported. Next-generation sequencing (NGS) is a type of effective molecular testing with high throughput and accuracy. Hence, this study aims to evaluate a novel barcode-tagged NGS approach based on a short-read assay. A total of 258 samples with 54 different β-thalassemia genotypes related to 32 mutations were gathered and evaluated. A library was constructed with the BTSeqTM kit and sequencing was performed on the Illumina NGS machine. The validation results showed 98.45% concordance with conventional genotypes. Less discordant results (1.55%) were limited to insertional mutations and included one case of each of the following: HBB:c.27dupG, HBB:c.85dupC, HBB:c.216dupT, and HBB:c.440_441dupAC. Five single-nucleotide polymorphisms that derived from the NGS results were also analyzed in terms of allele frequency and revealed significant differences between the wild types and other β-genotypes. Furthermore, this paper is the first to describe rare single-nucleotide polymorphisms including IVS II-109 (C/T), IVS II-258 (G/A), IVS II-613 (T-C), and IVS II-806 (G/C). Interestingly, the C allele of IVS II-806 was found to have 100% linkage with two cases of Hb Tak. The haplotype and phylogenetic analysis was also constructed based on variants and revealed three clusters in the Hb variants, which represented their evolution and genetic background. Finally, NGS with the barcode-tagged method has a high throughput, which is suitable for large population screening. Its cost effectiveness and less complicated process promote its application in further works.

A real‑world study of clinical characteristics, treatment sequence and outcomes of patients with non-small cell lung cancer and EGFR exon 20 insertion mutations.

EGFR exon 20 insertion (EGFRex20ins) mutations are found in up to 4% of all patients with non-small cell lung cancer (NSCLC). These patients are often insensitive to EGFR-tyrosine kinase inhibitors (TKIs) and have worse prognosis than patients with more common EGFR mutations. In this multicenter, retrospective, real-world study, we sought to determine whether the administration of recently approved treatments that specifically target EGFRex20ins mutations could significantly improve outcomes in this patient population. We evaluated the clinical features of 41 patients diagnosed with NSCLC and EGFRex20ins mutations, their evolution, and response to treatments received across 7 hospitals in the Valencian Community, Spain, between 31st December 2012 and 31st December 2022. 32 patients (72%) developed metastatic disease, and 29 (71%) of them received oncological treatment. We found that administering a targeted therapy against EGFRex20ins mutations (amivantamab, mobocertinib and/or sunvozertinib) at some point during the course of treatment, significantly increased the median OS of metastatic patients from 8months (95% CI 0-21.7) to 30months (95% CI 11.1-48.8; Hazard ratio = 0.297, p = 0.02). Our findings contribute to the evolving standard of care for this specific population and highlight the clinical benefits of targeted cancer therapies.

The role of cydB gene in the biofilm formation by Campylobacter jejuni

Campylobacter jejuni is a major cause of food- and water-borne bacterial infections in humans. A key factor helping bacteria to survive adverse environmental conditions is biofilm formation ability. Nonetheless, the molecular basis underlying biofilm formation by C. jejuni remains poorly understood. Around thirty genes involved in the regulation and dynamics of C. jejuni biofilm formation have been described so far. We applied random transposon mutagenesis to identify new biofilm-associated genes in C. jejuni strain 81–176. Of 1350 mutants, twenty-four had a decreased ability to produce biofilm compared to the wild-type strain. Some mutants contained insertions in genes previously reported to affect the biofilm formation process. The majority of identified genes encoded hypothetical proteins. In the library of EZ-Tn5 insertion mutants, we found the cydB gene associated with respiration that was not previously linked with biofilm formation in Campylobacter. To study the involvement of the cydB gene in biofilm formation, we constructed a non-marked deletion cydB mutant together with a complemented mutant. We found that the cydB deletion-mutant formed a weaker biofilm of loosely organized structure and lower volume than the parent strain. In the present study, we demonstrated the role of the cydB gene in biofilm formation by C. jejuni.

PPM1D/Wip1 is amplified, overexpressed, and mutated in human non-Hodgkin's lymphomas.

Wip1, is a p53-dependent Ser/Thr phosphatase involved in the timely termination of DDR. The PPM1D gene encoding Wip1 is deregulated and thus gained an oncogene character in common human solid tumors and cell lines. This study assessed the oncogenic potential of the PPM1D gene in human non- Hodgkin's lymphomas (NHL), the most common hematological malignancy worldwide. FFPE human lymphoid hyperplasia (LH) (n = 17) and NHL tumor lymph node samples (n = 65) and human NHL cell lines were used to assess the oncogenic potential of the PPM1D gene in the present study. Copy number gain and mRNA expression analysis of the PPM1D/Wip1 gene were assessed by qRT-PCR analysis. Mutational analysis of Exon 6 of the PPM1D gene was performed by PCR amplification and Sanger sequencing. Expressions of Wip1 and p53 proteins were assessed by immunohistochemistry and Western blot analysis. We found that PPM1D gained gene copy number in NHL tumors by 0.7-8 times compared to the control (p < 0.01). Increased PPM1D/Wip1 gene copy number was associated with higher mRNA and protein expression in human NHL samples (p < 0.01). Overexpression of Wip1 in NHL tumors and NHL cell lines was associated with amplification level and was unaffected by p53 status. Furthermore, a heterozygous type insertion mutation was detected in exon 6 (c.1553_1554insA) of the PPM1D gene particularly in DLBCL samples. Wip1 may have oncogenic potential, perhaps playing a role in the onset and progression of human NHL. The possible significance of Wip1 overexpression to chemotherapy response in NHL remains an intriguing question that requires more exploration.

In silico analysis of point mutation (c.687dupC; p. Met230Hisfs*6) in PGAM2 gene that causes Glycogen Storage Disease (GSD) Type X

Glycogen storage disease (GSD) type X is an autosomal recessive disorder that affects skeletal muscles and is caused by PGAM-2 (Phosphoglycerate Mutase-2) enzyme deficiency. This deficiency is due to a mutation in the PGAM-2 gene at chromosome number 7p13. A novel insertion mutation (c.687dupC) was reported recently in the Pakistani population. This study aimed to computationally study the effect of that mutation at the molecular level. Several in silico approaches were employed to understand the molecular mechanism behind PGAM2 enzyme deficiency. Modeling the wild-type and mutant PGAM2 protein revealed an absence of an alpha helix from the c-terminus. Binding site analysis showed the absence of a critical residue, Lysine-100, from the mutant. Moreover, changes in the binding affinities, intramolecular interactions, and intermolecular interactions were also observed.

Fine-tuning the N-glycosylation of recombinant human erythropoietin using Chlamydomonas reinhardtii mutants.

Microalgae are considered as attractive expression systems for the production of biologics. As photosynthetic unicellular organisms, they do not require costly and complex media for growing and are able to secrete proteins and perform protein glycosylation. Some biologics have been successfully produced in the green microalgae Chlamydomonas reinhardtii. However, post-translational modifications like glycosylation of these Chlamydomonas-made biologics have poorly been investigated so far. Therefore, in this study, we report on the first structural investigation of glycans linked to human erythropoietin (hEPO) expressed in a wild-type C. reinhardtii strain and mutants impaired in key Golgi glycosyltransferases. The glycoproteomic analysis of recombinant hEPO (rhEPO) expressed in the wild-type strain demonstrated that the three N-glycosylation sites are 100% glycosylated with mature N-glycans containing four to five mannose residues and carrying core xylose, core fucose and O-methyl groups. Moreover, expression in C. reinhardtii insertional mutants defective in xylosyltransferases A and B and fucosyltransferase resulted in drastic decreases of core xylosylation and core fucosylation of glycans N-linked to the rhEPOs, thus demonstrating that this strategy offers perspectives for humanizing the N-glycosylation of the Chlamydomonas-made biologics.

Intramuscular hemangioma capillary type with HRAS mutation: Expanding the molecular genetic spectrum with an emphasis on overlap with arteriovenous malformations and distinct from infantile hemangioma

AimsIntramuscular hemangioma capillary type (IHCT) is a rare entity that refers to fast-flow vascular lesions. This study aims to elucidate the relationships between clinicopathological, radiological, and molecular characteristics in IHCT patients. Methods and resultsWe reviewed all IHCT cases which were treated surgically in our pathology database from 2014 to 2023. Ten cases were analyzed via next-generation sequencing (NGS) and Sanger sequencing. The cohort consisted of 10 patients (6 males, 4 females) with a median age of 18 years (range: 1–37). Disease lesions were located in the trunk (n = 4), upper extremity (n = 2), lower extremity (n = 2), shoulder (n = 1), and neck (n = 1). IHCT is most commonly a progressively increasing painless mass. Histopathologically, all lesions exhibited aggregates, lobules, and anastomosing cords of capillary-type vessels separating or infiltrating the skeletal muscles. Four cases exhibited irregularly dilated vessels with thick walls, such as arteriovenous malformations (AVM) in the lesion's periphery. MRI findings commonly demonstrated a well-delineated, homogeneous mass. Somatic mutations were detected in seven of the ten IHCT cases. Four cases harbored mutations in MAP2K1 (p.Q58_E62del, p.K57_G61del, p.K57 N), two cases harbored mutations in KRAS (p.Q61R and p.L56V, p.G13R), and one case harbored a mutation in HRAS (p.D69_Q70insRWYSAMRD). Mutant allele frequencies detected by sequencing ranged from 9.98% to 15.97%. ConclusionsThe hemodynamic and molecular genetic phenotypes of IHCT closely resemble those observed in AVMs. Newly identified KRAS missense mutations, including cases with coexisting mutation types, and HRAS insertion mutations offer valuable insights into the genetic basis of vascular anomalies. These findings may also present potential targets for the development of novel pharmacotherapeutic interventions.

Towards the genomic sequence code of DNA fragility for machine learning.

Genomic DNA breakages and the subsequent insertion and deletion mutations are important contributors to genome instability and linked diseases. Unlike the research in point mutations, the relationship between DNA sequence context and the propensity for strand breaks remains elusive. Here, by analyzing the differences and commonalities across myriads of genomic breakage datasets, we extract the sequence-linked rules and patterns behind DNA fragility. We show the overall deconvolution of the sequence influence into short-, mid- and long-range effects, and the stressor-dependent differences in defining the range and compositional effects on DNA fragility. We summarize and release our feature compendium as a library that can be seamlessly incorporated into genomic machine learning procedures, where DNA fragility is of concern, and train a generalized DNA fragility model on cancer-associated breakages. Structural variants (SVs) tend to stabilize regions in which they emerge, with the effect most pronounced for pathogenic SVs. In contrast, the effects of chromothripsis are seen across regions less prone to breakages. We find that viral integration may bring genome fragility, particularly for cancer-associated viruses. Overall, this work offers novel insights into the genomic sequence basis of DNA fragility and presents a powerful machine learning resource to further enhance our understanding of genome (in)stability and evolution.

L-asparaginase-driven antibiosis in Pseudomonas fluorescens EK007: A promising biocontrol strategy against fire blight

Fire blight, caused by Erwinia amylovora, is a destructive bacterial disease affecting pear and apple trees. The biocontrol ability of Pseudomonas fluorescens EK007 suppresses E. amylovora through competitive exclusion. In this study, EK007 was isolated from the pear phylloplane and characterized as an effective biological agent through antibacterial compounds. To identify the mechanisms underlying EK007's biocontrol activity, physiological tests, transposon insertion mutant libraries, allelic exchange, and whole-genome sequencing were performed. A transposon mutation in the massC homolog gene, part of the massetolide A lipopeptide biosynthesis cluster, reduced the biocontrol efficiency. Allelic exchange confirmed cyclic lipopeptide (CLP) as part of the mechanism. Additionally, a gacA mutant isolated by transposon mutagenesis showed deficient inhibition activity. Culture conditions and nutritional sources clearly influenced EK007's antimicrobial activity against E. amylovora. Growth yield generally correlated with antibiotic production, with amino acids and iron affecting production. Asparagine and aspartate shut down biocontrol activity. This study presents preliminary findings on a novel CLP that may contribute to EK007's antibacterial activity against E. amylovora. While EK007 shows promise as a biocontrol candidate compared to related strains, these results are based solely on in vitro studies, highlighting the need for further investigations to evaluate its efficacy in natural environments.

Viral coexistence and insertional mutations in the ORF8 region of SARS-CoV-2: A possible mechanism of nucleotide insertion

The virus obtained from a swab sample ID: S66 in Hiroshima was reported to have a single T-base insertion in the ORF8 coding region. However, no T insertion was observed when we determined the genomic sequence using another method. We then extracted RNA from the S66 swab sample and sequenced the insertion site using the Sanger method. The resulting waveform was disrupted beyond the insertion site, suggesting the presence of a mixed population of viruses with different sequences. Through plasmid cloning of RT-PCR amplification fragments and virus cloning by limiting dilution, along with TIDE analysis to determine the ratio of components from the Sanger sequencing waveform, it was confirmed that the sample contained a mixture of viruses with varying numbers of T-base insertions. The virus with one T insertion (T1+) was predominant in 70–75 % of the genomes, and genomes with T0, T2+, T3+, T4+, and T5+ were also detected. No T-base insertion mutations were observed in the ORF8 region in three other SARS-CoV-2 samples. In the S66 sample, a C27911T point mutation near the insertion site in the ORF8 region resulted in a sequence of seven or more consecutive T bases, which was the cause of the T-base insertion. When the cloned S66 virus (T1+) was passaged in cultured cells, there was a tendency for viruses with more insertion bases to become dominant with successive generations, suggesting that the T-base insertion was due to polymerase stuttering. The insertion of T bases resulted in synthesis of deletion mutants of the ORF8 protein, but no significant change was observed in the proliferation of the viruses in cultured cells. A search of the GenBank database using NCBI BLAST for viruses similar to S66 with T-base insertion mutations revealed hundreds of viruses widely distributed on the molecular phylogenetic tree. These base insertion viruses were thought to have occasionally arisen during the virus infection process. This study suggests one mechanism of insertion mutations in SARS-CoV-2, and it is important to consider the emergence of future mutant strains.

Environment-independent distribution of mutational effects emerges from microscopic epistasis.

Predicting how new mutations alter phenotypes is difficult because mutational effects vary across genotypes and environments. Recently discovered global epistasis, in which the fitness effects of mutations scale with the fitness of the background genotype, can improve predictions, but how the environment modulates this scaling is unknown. We measured the fitness effects of ~100 insertion mutations in 42 strains of Saccharomyces cerevisiae in six laboratory environments and found that the global epistasis scaling is nearly invariant across environments. Instead, the environment tunes one global parameter, the background fitness at which most mutations switch sign. As a consequence, the distribution of mutational effects is predictable across genotypes and environments. Our results suggest that the effective dimensionality of genotype-to-phenotype maps across environments is surprisingly low.

InSeq analysis of defined Legionella pneumophila libraries identifies a transporter-encoding gene cluster important for intracellular replication in mammalian hosts.

Legionella pneumophila is an intracellular bacterial pathogen that replicates inside human alveolar macrophages to cause a severe pneumonia known as Legionnaires' disease. L. pneumophila requires the Dot/Icm Type IV secretion system to deliver hundreds of bacterial proteins to the host cytosol that manipulate cellular processes to establish a protected compartment for bacterial replication known as the Legionella-containing vacuole. To better understand mechanisms apart from the Dot/Icm system that support survival and replication in this vacuole, we used transposon insertion sequencing in combination with defined mutant sublibraries to identify L. pneumophila fitness determinants in primary mouse macrophages and the mouse lung. This approach validated that many previously identified genes important for intracellular replication were critical for infection of a mammalian host. Further, the screens uncovered additional genes contributing to L. pneumophila replication in mammalian infection models. This included a cluster of seven genes in which insertion mutations resulted in L. pneumophila fitness defects in mammalian hosts. Generation of isogenic deletion mutants and genetic complementation studies verified the importance of genes within this locus for infection of mammalian cells. Genes in this cluster are predicted to encode nucleotide-modifying enzymes, a protein of unknown function, and an atypical ATP-binding cassette (ABC) transporter with significant homology to multidrug efflux pumps that has been named Lit, for Legionella infectivity transporter. Overall, these data provide a comprehensive overview of the bacterial processes that support L. pneumophila replication in a mammalian host and offer insight into the unique challenges posed by the intravacuolar environment.IMPORTANCEIntracellular bacteria employ diverse mechanisms to survive and replicate inside the inhospitable environment of host cells. Legionella pneumophila is an opportunistic human pathogen and a model system for studying intracellular host-pathogen interactions. Transposon sequencing is an invaluable tool for identifying bacterial genes contributing to infection, but current animal models for L. pneumophila are suboptimal for conventional screens using saturated mutant libraries. This study employed a series of defined transposon mutant libraries to identify determinants of L. pneumophila fitness in mammalian hosts, which include a newly identified bacterial transporter called Lit. Understanding the requirements for survival and replication inside host cells informs us about the environment bacteria encounter during infection and the mechanisms they employ to make this environment habitable. Such knowledge will be key to addressing future challenges in treating infections caused by intracellular bacteria.

Characterization of the Clostridioides difficile 630Δerm putative Pro-Pro endopeptidase CD1597.

Clostridioides difficile is the leading cause of antibiotic-associated infections worldwide. Within the host, C. difficile can transition from a sessile to a motile state by secreting PPEP-1, which releases the cells from the intestinal epithelium by cleaving adhesion proteins. PPEP-1 belongs to the group of Pro-Pro endopeptidases (PPEPs), which are characterized by their unique ability to cleave proline-proline bonds. Interestingly, another putative member of this group, CD1597, is present in C. difficile. Although it possesses a domain similar to other PPEPs, CD1597 displays several distinct features that suggest a markedly different role for this protein. We investigated the proteolytic activity of CD1597 by testing various potential substrates. In addition, we investigated the effect of the absence of CD1597 by generating an insertional mutant of the cd1597 gene. Using the cd1597 mutant, we sought to identify phenotypic changes through a series of in vitro experiments and quantitative proteomic analyses. Furthermore, we aimed to study the localization of this protein using a fluorogenic fusion protein. Despite its similarities to PPEP-1, CD1597 did not show proteolytic activity. In addition, the absence of CD1597 caused an increase in various sporulation proteins during the stationary phase, yet we did not observe any alterations in the sporulation frequency of the cd1597 mutant. Furthermore, a promoter activity assay indicated a very low expression level of cd1597 in vegetative cells, which was independent of the culture medium and growth stage. The low expression was corroborated by our comprehensive proteomic analysis of the whole cell cultures, which failed to identify CD1597. However, an analysis of purified C. difficile spores identified CD1597 as part of the spore proteome. Hence, we predict that the protein is involved in sporulation, although we were unable to define a precise role for CD1597 in C. difficile.

106 (PB094): Discovery of potent, selective, and orally bioavailable HER2 tyrosine kinase inhibitors targeting HER2 exon20 insertion mutants and HER2WT

106 (PB094): Discovery of potent, selective, and orally bioavailable HER2 tyrosine kinase inhibitors targeting HER2 exon20 insertion mutants and HER2WT

Mobocertinib antagonizes multidrug resistance in ABCB1- and ABCG2-overexpressing cancer cells: In vitro and in vivo studies.

Overexpression of ATP-binding cassette (ABC) transporters, particularly ABCB1 and ABCG2, strongly correlates with multidrug resistance (MDR), rendering cancer chemotherapy ineffective. Exploration and identification of novel inhibitors targeting ABCB1 and ABCG2 are necessary to overcome the related MDR. Mobocertinib is an approved EGFR/HER2 inhibitor for non-small cell lung cancer (NSCLC) with EGFR exon 20 insertion mutations. This study demonstrates that mobocertinib can potentially reverse ABCB1- and ABCG2-mediated MDR. Our findings indicate a strong interaction between mobocertinib and these two proteins, supported by its high binding affinity with ABCB1 and ABCG2 models. Through inhibiting the drug efflux function of ABCB1 and ABCG2, mobocertinib facilitates substrate drugs accumulation, thereby re-sensitizing substrate drugs in drug-resistant cancer cells. Additionally, mobocertinib inhibited the ATPase activity of ABCB1 and ABCG2 without changing the expression levels or subcellular localization. In the tumor-bearing mouse model, mobocertinib boosted the antitumor effect of paclitaxel and topotecan, resulting in tumor regression. In summary, our study uncovers a novel potential for repurposing mobocertinib as a dual inhibitor of ABCB1 and ABCG2, and suggests the combination of mobocertinib with substrate drugs as a strategy to counteract MDR.

Uncovering Candidate Pathogenicity Genes in Erwinia pyrifoliae YKB12327 via Tn5-insertion Mutagenesis

&lt;i&gt;Erwinia pyrifoliae&lt;/i&gt; is a gram-negative bacterial pathogen that commonly causes black shoot blight in pear and apple tree. Although the pathogenicity of this bacterial species is very similar to &lt;i&gt;E. amylovora&lt;/i&gt;, there is no specific explanation of its pathogenic genes and mechanisms. In this study, our investigation into &lt;i&gt;E. pyrifoliae&lt;/i&gt; pathogenicity involved generating seven YKB12327 mutant strains using Tn5 transposon mutagenesis. Observations revealed weakened growth rate and loss of pathogenicity in these mutants. Whole-genome sequencing and alignment analysis identified transposon insertions within the coding sequences of five strains and in the intergenic region of two strains. Annotation analysis elucidated genes directly or indirectly associated with pathogenicity. Notably, mutant strain MT16 displayed a transposon insertion mutation in the cyclic-di-GMP phosphodiesterase (&lt;i&gt;pdeF&lt;/i&gt;) gene, a key player in bacterial signaling, governing microbial behavior and adaptation to environmental changes. Our findings provide insights into the genetic regulation of &lt;i&gt;E. pyrifoliae&lt;/i&gt; pathogenicity, suggesting potential avenues for further research aimed at understanding and controlling this bacterial pathogen by targeting &lt;i&gt;pdeF&lt;/i&gt; to mitigate apple black shoot blight disease.

Optimization of Potent, Efficacious, Selective and Blood-Brain Barrier Penetrating Inhibitors Targeting EGFR Exon20 Insertion Mutations.

Herein, we report the optimization of a series of epidermal growth factor receptor (EGFR) Exon20 insertion (Ex20Ins) inhibitors using structure-based drug design (SBDD), leading to the discovery of compound 28, a potent and wild type selective molecule, which demonstrates efficacy in multiple EGFR Ex20Ins xenograft models and blood-brain barrier penetration in preclinical species. Building on our earlier discovery of an in vivo probe, SBDD was used to design a novel bicyclic core with a lower molecular weight to facilitate blood-brain barrier penetration. Further optimization including strategic linker replacement and diversification of the ring system interacting with the c-helix enabled photolytic and metabolic stability improvements. Together with refinement of molecular properties important for achieving high brain exposure, including molecular weight, H-bonding, and polarity, 28 was identified.

Retrotransposon-driven environmental regulation of FLC leads to adaptive response to herbicide.

The mobilization of transposable elements is a potent source of mutations. In plants, several stransposable elements respond to external cues, fuelling the hypothesis that natural transposition can create environmentally sensitive alleles for adaptation. Here we report on the detailed characterization of a retrotransposon insertion within the first intron of the Arabidopsis floral-repressor gene FLOWERING LOCUS C (FLC) and the discovery of its role for adaptation. The insertion mutation augments the environmental sensitivity of FLC by affecting the balance between coding and non-coding transcripts in response to stress, thus expediting flowering. This balance is modulated by DNA methylation and orchestrated by IBM2, a factor involved in the processing of intronic heterochromatic sequences. The stress-sensitive allele of FLC has spread across populations subjected to recurrent chemical weeding, and we show that retrotransposon-driven acceleration of the life cycle represents a rapid response to herbicide application. Our work provides a compelling example of a transposable element-driven environmentally sensitive allele that confers an adaptive response in nature.

How pairs of insertion mutations impact protein structure: An exhaustive computational study

How pairs of insertion mutations impact protein structure: An exhaustive computational study