Closure times of neurocranial sutures and synchondroses in Persian compared to Domestic Shorthair cats

Human-directed selective breeding has modified the phenotype of the modern Persian cat towards an extreme brachycephalic phenotype (‘peke-face’ Persian), which originates from a spontaneous mutation that first appeared in the 1950s in traditional Persian types. It was suggested that the peke-face phenotype results from pathologic skull development and might represent a craniosynostosis of the coronal sutures. We followed this hypothesis and investigated the time dependent status of the neurocranial sutures and synchondroses in an ontogenetic series of doll-faced and peke-faced Persian cats compared to Domestic Shorthair cats (DSHs). Cranial suture closure was assessed by examining an ontogenetic series of formalin-fixed head specimens (n = 55) and dry skulls (n = 32) using micro-computed tomography. Sagittal, metopic, coronal and lambdoid sutures as well as intersphenoidal, spheno-occipital and spheno-ethmoid synchondroses were examined. Logistic regression analysis was performed to test the global effect of age on suture closure within a group of peke-face Persians, doll-face Persians and DSHs and the 50% probability of having a closed suture was calculated and compared between groups. Age was a perfect predictor for the condition of the coronal sutures in peke-face Persians. Coronal sutures were found to be closed at 0–0.3 months. In doll-face and DSHs, coronal sutures were open throughout the lifetime with the exception of a few very old cats. Results of this study confirmed a coronal craniosynostosis that likely causes the extreme brachycephalic skull morphology in the peke-face Persian.

Spontaneous mutation rate estimates for the principal malaria vectors Anopheles coluzzii and Anopheles stephensi

Using high-depth whole genome sequencing of F0 mating pairs and multiple individual F1 offspring, we estimated the nuclear mutation rate per generation in the malaria vectors Anopheles coluzzii and Anopheles stephensi by detecting de novo genetic mutations. A purpose-built computer program was employed to filter actual mutations from a deep background of superficially similar artifacts resulting from read misalignment. Performance of filtering parameters was determined using software-simulated mutations, and the resulting estimate of false negative rate was used to correct final mutation rate estimates. Spontaneous mutation rates by base substitution were estimated at 1.00 × 10−9 (95% confidence interval, 2.06 × 10−10—2.91 × 10−9) and 1.36 × 10−9 (95% confidence interval, 4.42 × 10−10—3.18 × 10−9) per site per generation in A. coluzzii and A. stephensi respectively. Although similar studies have been performed on other insect species including dipterans, this is the first study to empirically measure mutation rates in the important genus Anopheles, and thus provides an estimate of µ that will be of utility for comparative evolutionary genomics, as well as for population genetic analysis of malaria vector mosquito species.

Development and Evaluation of Stable Sugarcane Mosaic Virus Mild Mutants for Cross-Protection Against Infection by Severe Strain

Sugarcane mosaic virus (SCMV; genus Potyvirus) induces maize dwarf mosaic disease that has caused serious yield losses of maize in China. Cross-protection is one of the efficient strategies to fight against severe virus strains. Although many mild strains have been identified, the spontaneous mutation is one of the challenging problems affecting their application in cross-protection. In this study, we found that the substitution of cysteine (C) at positions 57 or 60 in the zinc finger-like motif of HC-Pro with alanine (A; C57A or C60A) significantly reduced its RNA silencing suppression activity and SCMV virulence. To reduce the risk of mild strains mutating to virulent ones by reverse or complementary mutations, we obtained attenuated SCMV mutants with double-mutations in the zinc finger-like and FRNK motifs of HC-Pro and evaluated their potential application in cross-protection. The results showed that the maize plants infected with FKNK/C60A double-mutant showed symptomless until 95 days post-inoculation and FKNK/C60A cross-protected plants displayed high resistance to severe SCMV strain. This study provides theoretical and material bases for the control of SCMV through cross-protection.

Fast neutron mutagenesis in soybean enriches for small indels and creates frameshift mutations

The mutagenic effects of ionizing radiation have been used for decades to create novel variants in experimental populations. Fast neutron (FN) bombardment as a mutagen has been especially widespread in plants, with extensive reports describing the induction of large structural variants, i.e., deletions, insertions, inversions, and translocations. However, the full spectrum of FN-induced mutations is poorly understood. We contrast small insertions and deletions (indels) observed in 27 soybean lines subject to FN irradiation with the standing indels identified in 107 diverse soybean lines. We use the same populations to contrast the nature and context (bases flanking a nucleotide change) of single nucleotide variants. The accumulation of new single nucleotide changes in FN lines is marginally higher than expected based on spontaneous mutation. In FN treated lines and in standing variation, C→T transitions and the corresponding reverse complement G→A transitions are the most abundant and occur most frequently in a CpG local context. These data indicate that most SNPs identified in FN lines are likely derived from spontaneous de novo processes in generations following mutagenesis rather than from the FN irradiation mutagen. However, small indels in FN lines differ from standing variants. Short insertions, from 1–6 base pairs, are less abundant than in standing variation. Short deletions are more abundant and prone to induce frameshift mutations that should disrupt the structure and function of encoded proteins. These findings indicate that FN irradiation generates numerous small indels, increasing the abundance of loss of function mutations that impact single genes.

Spontaneous Mutation in the Movement Protein of Citrus Leprosis Virus C2, in a Heterologous Virus Infection Context, Increases Cell-to-Cell Transport and Generates Fitness Advantage

Previous results using a movement defective alfalfa mosaic virus (AMV) vector revealed that citrus leprosis virus C (CiLV-C) movement protein (MP) generates a more efficient local movement, but not more systemic transport, than citrus leprosis virus C2 (CiLV-C2) MP, MPs belonging to two important viruses for the citrus industry. Here, competition experiment assays in transgenic tobacco plants (P12) between transcripts of AMV constructs expressing the cilevirus MPs, followed by several biological passages, showed the prevalence of the AMV construct carrying the CiLV-C2 MP. The analysis of AMV RNA 3 progeny recovered from P12 plant at the second viral passage revealed the presence of a mix of progeny encompassing the CiLV-C2 MP wild type (MPWT) and two variants carrying serines instead phenylalanines at positions 72 (MPS72F) or 259 (MPS259F), respectively. We evaluated the effects of each modified residue in virus replication, and cell-to-cell and long-distance movements. Results indicated that phenylalanine at position 259 favors viral cell-to-cell transport with an improvement in viral fitness, but has no effect on viral replication, whereas mutation at position 72 (MPS72F) has a penalty in the viral fitness. Our findings indicate that the prevalence of a viral population may be correlated with its greater efficiency in cell-to-cell and systemic movements.

Rapid multilocus adaptation of clonal cabbage leaf curl virus populations to Arabidopsis thaliana

Cabbage leaf curl virus (CabLCV) has a bipartite single-stranded DNA genome and infects the model plant Arabidopsis thaliana. CabLCV serves as a model for the genus Begomovirus, members of which cause tremendous crop losses worldwide. We have used CabLCV as a model for within-plant virus evolution by inoculating individual plants with infectious clones of both wild-type and mutagenized versions of the CabLCV genome. Consistent with previous reports, detrimental substitutions in the Replication-associated gene (Rep) were readily compensated for by direct reversion and/or alternative mutations. A surprising number of common mutations were detected elsewhere in both viral segments (DNA-A and DNA-B) indicating convergent evolution and suggesting that CabLCV may not be as well adapted to A. thaliana as commonly presumed. Consistent with this idea, a spontaneous coat protein variant consistently rose to higher allele frequency in a hypersusceptible A. thaliana accession (Sei-0) than in another susceptible accession (Col-0). Numerous high-frequency mutations were also detected in a candidate Rep binding site in DNA-B. Our results reinforce the fact that spontaneous mutation of this type of virus occurs rapidly and can change the majority consensus sequence of a within-plant virus population in weeks.

Defining Fluoroquinolone Resistance-Mediating Mutations from Non-Resistance Polymorphisms in Mycoplasma hominis Topoisomerases

Often dismissed as a commensal, Mycoplasma hominis is an increasingly prominent target of research due to its role in septic arthritis and organ transplant failure in immunosuppressed patients, particularly lung transplantation. As a mollicute, its highly reductive genome and structure render it refractile to most forms of treatment and growing levels of resistance to the few sources of treatment left, such as fluoroquinolones. We examined antimicrobial susceptibility (AST) to fluoroquinolones on 72 isolates and observed resistance in three (4.1%), with corresponding mutations in the quinolone resistance-determining region (QRDR) of S83L or E87G in gyrA and S81I or E85V in parC. However, there were high levels of polymorphism identified between all isolates outside of the QRDR, indicating caution for a genomics-led approach for resistance screening, particularly as we observed a further two quinolone-susceptible isolates solely containing gyrA mutation S83L. However, both isolates spontaneously developed a second spontaneous E85K parC mutation and resistance following prolonged incubation in 4 mg/L levofloxacin for an extra 24–48 h. Continued AST surveillance and investigation is required to understand how gyrA QRDR mutations predispose M. hominis to rapid spontaneous mutation and fluoroquinolone resistance, absent from other susceptible isolates. The unusually high prevalence of polymorphisms in M. hominis also warrants increased genomics’ surveillance.

1007. Hypermutability in Clinical Strains of Klebsiella pneumoniae: Role of the V76G Mutation in MutH

Background Hypermutator (HM) bacteria exhibit high spontaneous mutation rates due to DNA mismatch repair (MMR) gene mutations, which may facilitate antibiotic resistance. HM is best described for chronic infections or colonization, in particular with P. aeruginosa. HM K. pneumoniae (KP) and carbapenem resistant Enterobacterales (CRE) are rarely studied. Methods Longitudinal isolates from 5 patients (pts) with long-term ST258 CRKP infections (median: 1.4 yr, 0.5-4.1 yr) underwent Illumina HiSeq whole genome sequencing. Strains from 1 pt were tested for HM and resistance. Mutant strains were created by complementation and CRISPR. Results In each pt, initial and recurrent isolates were genetically related (≤7 core genome (cg) SNP). In 1 pt, infection recurred 3.3 yrs after initial infection; baseline and recurrent (T0) isolates differed by 7-10 cgSNP. 4 ceftazidime-avibactam (CAZ) resistant isolates (T1-T4) were recovered ≥2 wks after treatment of T0 infection. Strains T1-T4 differed from T0 and each other by 109-214 and 58-137 cgSNP (Fig.1), respectively, and carried mutations in MMR genes (mutS -149∆C (∆pmutS); mutH V76G) and blaKPC3 (D179Y). T1-T4 mutations were enriched for genes involved in metabolism (adjusted p=1.46e-10), ABC transport (p=4.1e-7), 2-component systems (p=9.2e-5), signal transduction (p=6e-4), and transcription regulation (p=2.1e-4). mutS and mutH expression was 46-49% lower in T1-T4 than in T0. T1-T4 demonstrated rifampin mutational frequency >10-6.4, compared to < 10-7.3 for earlier strains. Upon passage in meropenem-vaborbactam (MV), colistin and gentamicin, T1-T4 developed resistance faster and higher MICs than T0 (Fig 2). MV resistance was associated with IS5 ompk36 promoter insertions or point, deletion or STOP mutations in ompK36 coding region. Complementation of T1-T4 with wild-type (WT) mutH restored phenotypes. Introduction of V76G to WT mutH in T0 established HM and in vitro passage resistance phenotypes. SNP matrix of 11 clinical isolates from a single patient with recurrent KPC-Kp infections The first 6 isolates were recovered within 6 months of transplant (Tinitial). The later 5 isolates were recovered ~40 months after intial GI colonization. Number of SNPs for each pariwise comparision on isolates are shown. Gray highlighted boxes shown SNP defferences between the 5 later strains. Serial passages of 4 clinical isolates. T1 and T4 harbored ΔpmutS. Ti=Tinitial (baseline) isolates Conclusion MMR mutations emerged in longitudinal CRKP, which conferred HM phenotypes and were associated with CAZ and other anti-CRE antibiotic resistance. mutH V76 is crucial in MMR. Long-term colonization or recurrent infections in face of antibiotic exposure might predispose CRKP strains to HM. Disclosures Cornelius J. Clancy, MD, Merck (Grant/Research Support)

Subinhibitory Levels of Oxytetracycline in Earthworm Meal Significantly Boost Resistance-Mutation Rates in Bacillus spp. within the Gut of Eisenia fetida

Aims: To estimate changes in the number of oxytetracycline -resistant strains, a dynamic population of Bacillus in the gut of Eisenia fetida cultured in processed-cow-dung (PrCD) supplemented with subinhibitory amounts of oxytetracycline, was studied. Study Design: Sterile water containing oxytetracycline was sprayed over PrCD at concentration of 0.012 µg per mg dehydrated PrCD per spraying. The number of oxytetracycline-resistant Bacillus spp. microbiota of E. fetida’s gut was compared to the number of oxytetracycline-resistant Bacillus spp. in its feed (PrCD). For this purpose, Luria Agar (LA) and Bacillus Agar (BA) plates amended with or without oxytetracycline were used. Place and Duration of Study: The study was carried out in the Omics Laboratory of Department of Biotechnology, University of North Bengal situated in Darjeeling district of West Bengal, India during 2017-18. Methodology: E. fetida gut content and PrCD samples were collected on different days of the experiment for bacteriological analysis. Dilution plating on LA yielded the total number of cultivable heterotrophic bacteria. LA plates amended with oxytetracycline (15 µg/ml) were used to acquire the fraction of heterotrophic bacteria resistant to oxytetracycline. BA plates were also utilized to obtain the fraction of resistant Bacillus spp. population. The frequency of mutation was determined using a conventional formula. Results: In the gut of E. fetida reared in PrCD supplemented with sub-inhibitory concentration of oxytetracycline, a rise in the oxytetracycline-resistant Bacillus population was observed. On day 1, the frequency of oxytetracycline-resistant Bacillus spp. (5×10-8) matched the spontaneous mutation frequency, however higher frequencies on days 2 and 7 (1.6×10-4 and 3.5 x 10-6 respectively) suggested significant dissemination of oxytetracycline resistance in the gut environment. Conclusion: Subinhibitory oxytetracycline concentrations in earthworm diet had a significant effect on mutation rates, showing that evolutionary forces on the gut microbiota may be determining their responses to antibiotic stress.

Genetic barriers to gene flow separate divergent substitution rates across a butterfly hybrid zone

Substitution rate defines the fundamental timescale of molecular evolution which often varies in a species-specific manner. However, it is unknown under what conditions lineage-specific rates can be preserved between natural populations with frequent hybridization. Here, we show in a hybrid zone between two butterflies, Papilio syfanius and Papilio maackii, that genome-wide barriers to gene flow can effectively separate different rates of molecular evolution in linked regions. The increased substitution rate in the lowland lineage can be largely explained by temperature-induced changes to the spontaneous mutation rate. A novel method based on entropy is developed to test for the existence of barrier loci using a minimal number of samples from the hybrid zone, a robust framework when system complexity far exceeds sample information. Overall, our results suggest that during the process of speciation, the separation of substitution rates can occur locally in the genome in parallel to the separation of gene pools.