Distinct monkeypox virus lineages co-circulating in humans before 2022.

The 2022 global mpox outbreak raises questions about how this zoonotic disease established effective human-to-human transmission and its potential for further adaptation. The 2022 outbreak virus is related to an ongoing outbreak in Nigeria originally reported in 2017, but the evolutionary path linking the two remains unclear due to a lack of genomic data between 2018, when virus exportations from Nigeria were first recorded, and 2022, when the global mpox outbreak began. Here, 18 viral genomes obtained from patients across southern Nigeria in 2019-2020 reveal multiple lineages of monkeypox virus (MPXV) co-circulated in humans for several years before 2022, with progressive accumulation of mutations consistent with APOBEC3 activity over time. We identify Nigerian A.2 lineage isolates, confirming the lineage that has been multiply exported to North America independently of the 2022 outbreak originated in Nigeria, and that it has persisted by human-to-human transmission in Nigeria for more than 2 years before its latest exportation. Finally, we identify a lineage-defining APOBEC3-style mutation in all A.2 isolates that disrupts gene A46R, encoding a viral innate immune modulator. Collectively, our data demonstrate MPXV capacity for sustained diversification within humans, including mutations that may be consistent with established mechanisms of poxvirus adaptation.

Chromosomal view of Lippia alba, a tropical polyploid complex under genome stabilization process.

Lippia alba is a phenotypically variable tropical shrub thought to comprise a young autopolyploid complex. Chromosome numbers in L. alba include 2n = 30, 38, 45, 60, and 90. High levels of chemical and phenotypic variation associated with economic and medicinal importance were reported. However, the genetic background including chromosome composition remains under-explored. Furthermore, the occurrence of at least four ploidal levels in L. alba and the lack of data for polyploid plants in tropical areas also merit further study of L. alba. Here we assessed the chromosome composition using two new satellite repeats (CL98 and CL66) applied as FISH probes to mitotic chromosomes, and we proposed to calculate the degree of homozygosis for CL66 satDNA (named as index h) and to associate it to meiotic instability. The CL98 mapping showed few variations in both number of signals and position. However, the levels of structural homozygosity for a satellite repeat CL66 were very variable. The numbers of CL66-bearing-chromosomes were under-represented in tetraploids relative to diploids implying that CL66 arrays have been lost in tetraploid lineages as a result of increased meiotic instability. High percentage of irregularities was observed in meiotic cells, especially in polyploids. L. alba complex comprised a mixture of homomorphic and heteromorphic chromosomes. Overall, the polyploid complex presents features typical of both young and older stable polyploids. It seems that L. alba genome is still in the process of stabilization.

Development of microsatellite markers for Lippia alba and related Lippia species.

Microsatellite primers were developed in Lippia alba complex to better understanding the origins and evolution of the species. We sought to increase the numbers of available simple sequence repeat (SSR) markers. We performed low-coverage (~ twofold) genomic DNA sequencing of a diploid accession and generated a de novo assembly comprising 175,572 contigs. Sixteen SSR loci were selected and of these 13 SSR loci were successfully amplified in 20 L. alba tetraploid accessions and in 12 other Lippia species. Only one SSR locus was monomorphic, whereas 12 loci were polymorphic, yielding one to nine alleles. The heterozygosity was similar among markers, with values of 0.274-0.485; the polymorphism information content values varied from 0.237 to 0.367. These markers were successfully amplified in related species with 85% of transferability on average. Thus, we demonstrate the utility of including a de novo assembly step to obtain SSR markers from low-coverage genomic datasets.

The Mutation Rate and the Age of the Sex Chromosomes in Silene latifolia.

Many aspects of sex chromosome evolution are common to both plants and animals [1], but the process of Y chromosome degeneration, where genes on the Y become non-functional over time, may be much slower in plants due to purifying selection against deleterious mutations in the haploid gametophyte [2, 3]. Testing for differences in Y degeneration between the kingdoms has been hindered by the absence of accurate age estimates for plant sex chromosomes. Here, we used genome resequencing to estimate the spontaneous mutation rate and the age of the sex chromosomes in white campion (Silene latifolia). Screening of single nucleotide polymorphisms (SNPs) in parents and 10 F1 progeny identified 39 de novo mutations and yielded a rate of 7.31 × 10-9 (95% confidence interval: 5.20 × 10-9 - 8.00 × 10-9) mutations per site per haploid genome per generation. Applying this mutation rate to the synonymous divergence between homologous X- and Y-linked genes (gametologs) gave age estimates of 11.00 and 6.32 million years for the old and young strata, respectively. Based on SNP segregation patterns, we inferred which genes were Y-linked and found that at least 47% are already dysfunctional. Applying our new estimates for the age of the sex chromosomes indicates that the rate of Y degeneration in S. latifolia is nearly 2-fold slower when compared to animal sex chromosomes of a similar age. Our revised estimates support Y degeneration taking place more slowly in plants, a discrepancy that may be explained by differences in the life cycles of animals and plants.

Karyotypic variation and pollen stainability in resynthesized allopolyploids Tragopogon miscellus and T. mirus.

PREMISE OF THE STUDY: Polyploidy has extensively shaped the evolution of plants, but the early stages of polyploidy are still poorly understood. The neoallopolyploid species Tragopogon mirus and T. miscellus are both characterized by widespread karyotypic variation, including frequent aneuploidy and intergenomic translocations. Our study illuminates the origins and early impacts of this variation by addressing two questions: How quickly does karyotypic variation accumulate in Tragopogon allopolyploids following whole-genome duplication (WGD), and how does the fertility of resynthesized Tragopogon allopolyploids evolve shortly after WGD? METHODS: We used genomic in situ hybridization and lactophenol-cotton blue staining to estimate the karyotypic variation and pollen stainability, respectively, of resynthesized T. mirus and T. miscellus during the first five generations after WGD. KEY RESULTS: Widespread karyotypic variation developed quickly in synthetics and resembled that of naturally occurring T. mirus and T. miscellus by generation S4 . Pollen stainability in resynthesized allopolyploids was consistently lower than that of natural T. mirus and T. miscellus, as well as their respective diploid progenitor species. Logistic regression showed that mean pollen stainability increased slightly over four generations in resynthesized T. mirus but remained at equivalent levels in T. miscellus. CONCLUSIONS: Our results clarify some of the changes that occur in T. mirus and T. miscellus immediately following their origin, most notably the rapid onset of karyotypic variation within these species immediately following WGD.

Rapid Y degeneration and dosage compensation in plant sex chromosomes.

The nonrecombining regions of animal Y chromosomes are known to undergo genetic degeneration, but previous work has failed to reveal large-scale gene degeneration on plant Y chromosomes. Here, we uncover rapid and extensive degeneration of Y-linked genes in a plant species, Silene latifolia, that evolved sex chromosomes de novo in the last 10 million years. Previous transcriptome-based studies of this species missed unexpressed, degenerate Y-linked genes. To identify sex-linked genes, regardless of their expression, we sequenced male and female genomes of S. latifolia and integrated the genomic contigs with a high-density genetic map. This revealed that 45% of Y-linked genes are not expressed, and 23% are interrupted by premature stop codons. This contrasts with X-linked genes, in which only 1.3% of genes contained stop codons and 4.3% of genes were not expressed in males. Loss of functional Y-linked genes is partly compensated for by gene-specific up-regulation of X-linked genes. Our results demonstrate that the rate of genetic degeneration of Y-linked genes in S. latifolia is as fast as in animals, and that the evolutionary trajectories of sex chromosomes are similar in the two kingdoms.

250 years of hybridization between two biennial herb species without speciation.

Hybridization between plant species can generate novel morphological diversity and lead to speciation at homoploid or polyploid levels. Hybrids between biennial herbs Tragopogon pratensis and T. porrifolius have been studied in experimental and natural populations for over 250 years. Here we examine their current status in natural populations in southeast England. All hybrids found were diploid; they tended to grow taller and with more buds than their parental species; many showed partial fertility; a few showed evidence of backcrossing. However, we found no evidence to suggest that the hybrids are establishing as a new species, nor can we find literature documenting speciation of these hybrids elsewhere. This lack of speciation despite at least 250 years of hybridization contrasts with the fact that both parental species have formed new allopolyploid species through hybridization with another diploid, T. dubius. Understanding why hybrids often do not speciate, despite repeated opportunities, would enhance our understanding of both the evolutionary process and risk assessments of invasive species.

Multiple origins and chromosomal novelty in the allotetraploid Tragopogon castellanus (Asteraceae).

Tragopogon includes two classic examples of recently formed allopolyploid species in North America: T. mirus and T. miscellus. Older Tragopogon allotetraploids from Eurasia offer ideal taxa for comparing the longer term outcomes of allopolyploidy. To help resolve the ancestry of one of these older polyploids, phylogenetic analyses of multiple populations of the allotetraploid T. castellanus (2n = 24) and its putative diploid parents, T. crocifolius and T. lamottei, were conducted using sequences from nuclear (internal transcribed spacer, ITS; and alcohol dehydrogenase 1A, Adh) and plastid (trnT-trnL spacer, trnL intron, trnL-trnF spacer and rpl16 intron) loci. Fluorescence in situ hybridization (FISH) and genomic in situ hybridization (GISH) were used to investigate the chromosomal constitution of T. castellanus. Our data confirm that the widely distributed T. crocifolius and the Iberian endemic, T. lamottei, are the diploid parents of T. castellanus, and that this polyploid formed at least three times. One group of populations of T. castellanus is distinct in exhibiting two pairs of rearranged chromosomes. These data suggest that some of the chromosomal variants that originate in young polyploids (here, an intergenomic translocation) may become fixed in populations, contributing to novelty in older polyploid lineages. The geographical distributions of the allopolyploids and parents are also complex, with allotetraploid populations being disjunct from one or both of the most closely related diploid parental populations.

Natural hybrids between Tragopogon mirus and T. miscellus (Asteraceae): a new perspective on karyotypic changes following hybridization at the polyploid level.

PREMISE OF THE STUDY: Natural hybrids have formed in Pullman, Washington, United States between the recently formed allotetraploids Tragopogon miscellus and T. mirus. In addition to forming spontaneously, these hybrids are semifertile, propagating via achenes. Previous work indicated that the tetraploid hybrids have genetic contributions from three progenitor diploids: T. dubius, T. pratensis, and T. porrifolius. Because the hybrids contain genomes from three species, they should be karyotypically variable and have very low fertility. To better understand how these hybrids are semifertile, we applied fluorescent probes to determine chromosome composition. • METHODS: We sequentially conducted fluorescence and genomic in situ hybridization to generate karyotypes for five hybrid individuals grown from field-collected achenes. • KEY RESULTS: All plants had the expected somatic chromosome number (2n = 24), but none showed an additive F1 chromosome complement, i.e., two sets of chromosomes from T. dubius and one set of chromosomes each from T. porrifolius and T. pratensis. No individuals shared an identical karyotype, but chromosomal variation followed a compensatory pattern of substitutions, with all groups of putatively homeologous chromosomes consistently totaling four. • CONCLUSIONS: The hybrids appear to be shifting away from a parentally additive F1 karyotype to chromosomal compositions that are mostly, or entirely, disomic. We hypothesize that this process may eventually lead to the elimination of chromosomes from a population and produce a stabilized karyotype distinct from both allotetraploid parents. This work has implications for other hybrids formed between polyploids, in that they may be hard to detect using sequence data alone due to multilateral patterns of chromosome elimination.

An assessment of karyotype restructuring in the neoallotetraploid Tragopogon miscellus (Asteraceae).

Tragopogon miscellus and Tragopogon mirus are two rare examples of allopolyploids that have formed recently in nature. Molecular cytogenetic studies have revealed chromosome copy number variation and intergenomic translocations in both allotetraploids. Due to a lack of interstitial chromosome markers, there remained the possibility of additional karyotype restructuring in these neopolyploids, via intrachromosomal and intragenomic rearrangements. To address this issue, we searched for additional high-copy tandem repeats in genomic sequences of the diploid progenitor species-Tragopogon dubius, Tragopogon pratensis and Tragopogon porrifolius-for application to the chromosomes of the allotetraploids. Eight novel repeats were localised by fluorescence in situ hybridisation (FISH) in the diploids; one of these repeats, TTR3, provided interstitial coverage. TTR3 was included in a cocktail with other previously characterised probes, producing better-resolved karyotypes for the three diploids. The cocktail was then used to test a hypothesis of karyotype restructuring in the recent allotetraploid T. miscellus by comparing repeat distributions to its diploid progenitors, T. dubius and T. pratensis. Five individuals of T. miscellus were selected from across the range of karyotypic variation previously observed in natural populations. FISH signal distributions mostly matched those observed in the diploid progenitors, with the exception of several losses or gains of signal at chromosomal subtermini and previously noted intergenomic translocations. Thus, in T. miscellus, we find most changes restricted to the subterminal regions, and although some were recurrent, none of the changes were common to all individuals analysed. We consider these findings in relation to the gene loss reported previously for T. miscellus.

Independent, rapid and targeted loss of highly repetitive DNA in natural and synthetic allopolyploids of Nicotiana tabacum.

Allopolyploidy (interspecific hybridisation and polyploidy) has played a significant role in the evolutionary history of angiosperms and can result in genomic, epigenetic and transcriptomic perturbations. We examine the immediate effects of allopolyploidy on repetitive DNA by comparing the genomes of synthetic and natural Nicotiana tabacum with diploid progenitors N. tomentosiformis (paternal progenitor) and N. sylvestris (maternal progenitor). Using next generation sequencing, a recently developed graph-based repeat identification pipeline, Southern blot and fluorescence in situ hybridisation (FISH) we characterise two highly repetitive DNA sequences (NicCL3 and NicCL7/30). Analysis of two independent high-throughput DNA sequencing datasets indicates NicCL3 forms 1.6-1.9% of the genome in N. tomentosiformis, sequences that occur in multiple, discontinuous tandem arrays scattered over several chromosomes. Abundance estimates, based on sequencing depth, indicate NicCL3 is almost absent in N. sylvestris and has been dramatically reduced in copy number in the allopolyploid N. tabacum. Surprisingly elimination of NicCL3 is repeated in some synthetic lines of N. tabacum in their forth generation. The retroelement NicCL7/30, which occurs interspersed with NicCL3, is also under-represented but to a much lesser degree, revealing targeted elimination of the latter. Analysis of paired-end sequencing data indicates the tandem component of NicCL3 has been preferentially removed in natural N. tabacum, increasing the proportion of the dispersed component. This occurs across multiple blocks of discontinuous repeats and based on the distribution of nucleotide similarity among NicCL3 units, was concurrent with rounds of sequence homogenisation.

Extensive chromosomal variation in a recently formed natural allopolyploid species, Tragopogon miscellus (Asteraceae).

Polyploidy, or whole genome duplication, has played a major role in the evolution of many eukaryotic lineages. Although the prevalence of polyploidy in plants is well documented, the molecular and cytological consequences are understood largely from newly formed polyploids (neopolyploids) that have been grown experimentally. Classical cytological and molecular cytogenetic studies both have shown that experimental neoallopolyploids often have meiotic irregularities, producing chromosomally variable gametes and progeny; however, little is known about the extent or duration of chromosomal variation in natural neoallopolyploid populations. We report the results of a molecular cytogenetic study on natural populations of a neoallopolyploid, Tragopogon miscellus, which formed multiple times in the past 80 y. Using genomic and fluorescence in situ hybridization, we uncovered massive and repeated patterns of chromosomal variation in all populations. No population was fixed for a particular karyotype; 76% of the individuals showed intergenomic translocations, and 69% were aneuploid for one or more chromosomes. Importantly, 85% of plants exhibiting aneuploidy still had the expected chromosome number, mostly through reciprocal monosomy-trisomy of homeologous chromosomes (1:3 copies) or nullisomy-tetrasomy (0:4 copies). The extensive chromosomal variation still present after ca. 40 generations in this biennial species suggests that substantial and prolonged chromosomal instability might be common in natural populations after whole genome duplication. A protracted period of genome instability in neoallopolyploids may increase opportunities for alterations to genome structure, losses of coding and noncoding DNA, and changes in gene expression.

Next-generation sequencing and genome evolution in allopolyploids.

PREMISE OF THE STUDY: Hybridization and polyploidization (allopolyploidy) are ubiquitous in the evolution of plants, but tracing the origins and subsequent evolution of the constituent genomes of allopolyploids has been challenging. Genome doubling greatly complicates genetic analyses, and this has long hindered investigation in that most allopolyploid species are "nonmodel" organisms. However, recent advances in sequencing and genomics technologies now provide unprecedented opportunities to analyze numerous genetic markers in multiple individuals in any organism. METHODS: Here we review the application of next-generation sequencing technologies to the study of three aspects of allopolyploid genome evolution: duplicated gene loss and expression in two recently formed Tragopogon allopolyploids, intergenomic interactions and chromosomal evolution in Tragopogon miscellus, and repetitive DNA evolution in Nicotiana allopolyploids. KEY RESULTS: For the first time, we can explore on a genomic scale the evolutionary processes that are ongoing in natural allopolyploids and not be restricted to well-studied crops and genetic models. CONCLUSIONS: These approaches can be easily and inexpensively applied to many other plant species-making any evolutionarily provocative system a new "model" system.

Next generation sequencing reveals genome downsizing in allotetraploid Nicotiana tabacum, predominantly through the elimination of paternally derived repetitive DNAs.

We used next generation sequencing to characterize and compare the genomes of the recently derived allotetraploid, Nicotiana tabacum (<200,000 years old), with its diploid progenitors, Nicotiana sylvestris (maternal, S-genome donor), and Nicotiana tomentosiformis (paternal, T-genome donor). Analysis of 14,634 repetitive DNA sequences in the genomes of the progenitor species and N. tabacum reveal all major types of retroelements found in angiosperms (genome proportions range between 17-22.5% and 2.3-3.5% for Ty3-gypsy elements and Ty1-copia elements, respectively). The diploid N. sylvestris genome exhibits evidence of recent bursts of sequence amplification and/or homogenization, whereas the genome of N. tomentosiformis lacks this signature and has considerably fewer homogenous repeats. In the derived allotetraploid N. tabacum, there is evidence of genome downsizing and sequences loss across most repeat types. This is particularly evident amongst the Ty3-gypsy retroelements in which all families identified are underrepresented in N. tabacum, as is 35S ribosomal DNA. Analysis of all repetitive DNA sequences indicates the T-genome of N. tabacum has experienced greater sequence loss than the S-genome, revealing preferential loss of paternally derived repetitive DNAs at a genome-wide level. Thus, the three genomes of N. sylvestris, N. tomentosiformis, and N. tabacum have experienced different evolutionary trajectories, with genomes that are dynamic, stable, and downsized, respectively.

Cost-effectiveness of enhanced external counterpulsation (EECP) for the treatment of stable angina in the United Kingdom.

OBJECTIVES: The objective of this study is to assess the cost-effectiveness of enhanced external counterpulsation (EECP) compared with no treatment as additional therapy to usual care for the treatment of chronic stable angina from the perspective of the UK National Health Service. METHODS: The study design was a systematic review of published evidence, use of expert clinical opinion, and decision analytic cost-effectiveness model. The systematic review was conducted and statistical methods used to synthesize the effectiveness evidence from randomized control trials. Formal methods were used to elicit opinion from clinical experts where no evidence was available. These provide informed "priors" on key model parameters. A decision analytic model was developed to assess the costs and health consequences associated with the primary outcome of the trials over a lifetime time horizon. The main outcome measures were costs from a health service perspective and outcomes measured as quality-adjusted life-years (QALYs). RESULTS: The incremental cost-effectiveness ratio of EECP was 18,643 pound sterling for each additional QALY, with a probability of being cost-effective of 0.44 and 0.70 at cost-effectiveness thresholds of 20,000 pound sterling and 30,000 pound sterling per QALY gained, respectively. Results were sensitive to the duration of health-related quality of life (HRQoL) benefits from treatment. CONCLUSIONS: The long-term maintenance of HRQoL benefits of EECP is central to the estimate of cost-effectiveness. The results from a single randomized control trial do not provide firm evidence of the clinical or cost-effectiveness of EECP in stable angina. Long-term follow-up trials assessing quality of life from EECP are required.

Review of the Application of Modern Cytogenetic Methods (FISH/GISH) to the Study of Reticulation (Polyploidy/Hybridisation).

The convergence of distinct lineages upon interspecific hybridisation, including when accompanied by increases in ploidy (allopolyploidy), is a driving force in the origin of many plant species. In plant breeding too, both interspecific hybridisation and allopolyploidy are important because they facilitate introgression of alien DNA into breeding lines enabling the introduction of novel characters. Here we review how fluorescence in situ hybridisation (FISH) and genomic in situ hybridisation (GISH) have been applied to: 1) studies of interspecific hybridisation and polyploidy in nature, 2) analyses of phylogenetic relationships between species, 3) genetic mapping and 4) analysis of plant breeding materials. We also review how FISH is poised to take advantage of nextgeneration sequencing (NGS) technologies, helping the rapid characterisation of the repetitive fractions of a genome in natural populations and agricultural plants.

Linkage of 35S and 5S rRNA genes in Artemisia (family Asteraceae): first evidence from angiosperms.

Typically in plants, the 5S and 35S ribosomal DNA (rDNA) encoding two major ribosomal RNA species occur at separate loci. However, in some algae, bryophytes and ferns, they are at the same locus (linked arranged). Southern blot hybridisation, polymerase chain reactions (PCR), fluorescent in situ hybridisation, cloning and sequencing were used to reveal 5S and 35S rDNA genomic organisation in Artemisia. We observed thousands of rDNA units at two-three loci containing 5S rDNA in an inverted orientation within the inter-genic spacer (IGS) of 35S rDNA. The sequenced clones of 26-18S IGS from Artemisia absinthium appeared to contain a conserved 5S gene insertion proximal to the 26S gene terminus (5S rDNA-1) and a second less conserved 5S insertion (5S rDNA-2) further downstream. Whilst the 5S rDNA-1 showed all the structural features of a functional gene, the 5S-rDNA-2 had a deletion in the internal promoter and probably represents a pseudogene. The linked arrangement probably evolved before the divergence of Artemisia from the rest of Asteraceae (>10 Myrs). This arrangement may have involved retrotransposons and once formed spread via mechanisms of concerted evolution. Heterogeneity in unit structure may reflect ongoing homogenisation of variant unit types without fixation for any particular variant.