Friday, September 20, 2024

BOTANY

From Mount Etna to the UK: genetics unveil the Oxford ragwort unique journey and resilience

Faculty of Sciences of the University of Lisbon

image:
*Senecio squalidus.*
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Credit: Bruno Nevado

A descendant of Sicilian progenitors, this daisy-family plant appeared in the UK, escaped from a botanical garden, and began its conquest of the region during the Industrial Revolution.

It is rare to uncover the details of a story as fascinating as this, especially since there are few cases where the emergence of a new species can be traced across just 300 years. The Oxford ragwort, Senecio squalidus, a yellow-flowered plant from the daisy family, first appeared in the 17th century at the Oxford Botanic Garden after a crossbreeding of two plants native only to Mount Etna in Sicily.

Bruno Nevado, researcher at the Centre for Ecology, Evolution, and Environmental Changes (CE3C) at the Faculty of Sciences of the University of Lisbon (CIÊNCIAS), leads the study now published in the scientific journal Current Biology. The research reveals key moments in the existence of this species—from its origins to its colonization of the United Kingdom during the Industrial Revolution—through the lens of genetics.

Between the late 17th and early 18th centuries, Senecio chrysanthemifolius and Senecio aethnensis, plants endemic to the rugged slopes of Mount Etna in Italy, were introduced to the gardens of the Duchess of Beaufort in Gloucestershire, England, by botanists Francesco Cupani and William Sherard. On Mount Etna, these plants rarely mingled due to their distinct habitats — S. chrysanthemifolius at altitudes below 1,000 meters and S. aethnensis above 2,000 meters. However, in the UK, conditions brought them into closer proximity, resulting in hybrid individuals. By the first two decades of the 18th century, these hybrids were cultivated in the renowned Oxford Botanic Garden, where they eventually gave rise to a new hybrid species, Senecio squalidus (hence Oxford ragwort). By the end of the 18th century, S. squalidus had escaped its confines and spread into the urban environment of Oxford, beginning its naturalization and eventual colonization of the UK.

Possibly due to its descent from species adapted to the harsh volcanic landscape, this hybrid species managed to thrive, later spreading via the expanding railway network of the Industrial Revolution in the 19th century. It was “by train” that the yellow flowered Oxford ragwort reached nearly every corner of the UK over a span of 150 years. Today, the species can be found from Scotland to Wales, and even in Ireland, thriving along railway lines, roadsides, footpaths, industrial zones, and other disturbed habitats.

Senecio squalidus is one of a few hybrid species with a very recent origin. Bruno Nevado highlights this rarity: “Normally, hybrid species are much older, and it’s difficult to disentangle the processes that contributed to speciation from those that affected the hybrid species later on during its evolution. But with this species, we can study the processes involved in the very early stages of speciation”.

In this new study, conducted in collaboration with researchers from several British universities and the Wellcome Sanger Institute in Cambridge, the genome of S. squalidus was sequenced. Genetic analysis of both S. squalidus and its parental species revealed a rapid reorganization of the hybrid species' genome, driven by the resolution of genetic incompatibilities between the parental species and natural selection. These processes shaped a unique genome, combining traits from both parents, allowing the new species to thrive in an environment where neither parent could survive. Thanks to this unique evolutionary journey, “The Oxford ragwort serves as a small, exceptional laboratory for studying hybridization and its role in the emergence of new species and the colonization of challenging environments,” concludes Bruno Nevado.

Senecio squalidus

Credit

Bruno Nevado

Senecio squalidus

Credit

John Baker

Journal

Current Biology

DOI

10.1016/j.cub.2024.08.009

Article Title

Genomic changes and stabilization following homoploid hybrid speciation of the Oxford ragwort Senecio squalidus

Super golden lettuce richer in vitamin A

A team from the IBMCP (UPV-CSIC) has developed a technique that multiplies the beta-carotene content in plant leaves.

Universitat Politècnica de València

Super golden lettuce richer in vitamin A — image:
A team from the IBMCP (UPV-CSIC) has developed a technique that multiplies the beta-carotene content in plant leaves.
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Credit: UPV

The work demonstrates that by using biotechnological techniques and treatments with high light intensity, the levels of beta-carotene in leaves can be multiplied up to 30 times by creating new places to store it without affecting vital processes such as photosynthesis. The results are published in the Plant Journal.

Beta-carotene is one of the main carotenoids, pigments found naturally in plants and other photosynthetic organisms that benefit health, with antioxidant, immunostimulant and cognitive-enhancing properties.

Specifically, beta-carotene is the primary precursor of retinoids, chemical compounds with essential bodily functions (vision, cell proliferation and differentiation, immune system...), including vitamin A.

Using tobacco plants (Nicotiana benthamiana) as a laboratory model and lettuce (Lactuca sativa) as a cultivation model, the team led by Manuel Rodríguez Concepción, CSIC researcher at the IBMCP, has managed to increase the beta-carotene content in the leaves without negatively affecting other vital processes such as photosynthesis.

'Leaves need carotenoids such as beta-carotene in the photosynthetic complexes of chloroplasts for their proper functioning,' explains the CSIC researcher. 'When too much or too little beta-carotene is produced in the chloroplasts, they stop functioning, and the leaves eventually die. Our work has successfully produced and accumulated beta-carotene in cellular compartments where it is not normally found by combining biotechnological techniques and treatments with high light intensity,' he summarises.

Higher accumulation and bioaccessibility

The results of this study, published in the Plant Journal, show that it is possible to multiply beta-carotene levels in leaves by creating new places to store them outside the photosynthetic complexes. On the one hand, they have managed to store high levels of beta-carotene in plastoglobules, and fat storage vesicles are naturally present inside chloroplasts. These vesicles do not participate in photosynthesis and do not usually accumulate carotenoids.

‘Stimulating the formation and development of plastoglobules with molecular techniques and intense light treatments not only increases the accumulation of beta-carotene but also its bioaccessibility, i.e. the ease with which it can be extracted from the food matrix to be absorbed by our digestive system,’ says Luca Morelli, first author of the study.

Biofortification of vegetables

The study also shows that beta-carotene synthesis in plastoglobules can be combined with its production outside chloroplasts by means of biotechnological approaches. In this case, co-author Pablo Pérez Colao says, 'beta-carotene accumulates in vesicles similar to plastoglobules but located in the cytosol, the aqueous substance that surrounds the organelles and nucleus of cells’.

The combination of both strategies achieved up to a 30-fold increase in accessible beta-carotene levels compared to untreated leaves. The massive accumulation of beta-carotene also gave the lettuce leaves a characteristic golden colour.

According to the researchers, the discovery that beta-carotene can be produced and stored at very high levels and in a more bioaccessible form outside the places where it is usually found in leaves 'represents a very significant advance for improving nutrition through biofortification of vegetables such as lettuce, chard or spinach without giving up their characteristic scent and flavour'.

Journal

The Plant Journal

DOI

10.1111/tpj.16964

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Boosting pro-vitamin A content and bioaccessibility in leaves by combining engineered biosynthesis and storage pathways with high-light treatments

Plant-derived secondary organic aerosols can act as mediators of plant-plant interactions

University of Eastern Finland

A new study published in Science reveals that plant-derived secondary organic aerosols (SOAs) can act as mediators of plant-plant interactions. This research was conducted through the cooperation of chemical ecologists, plant ecophysiologists and atmospheric physicists at the University of Eastern Finland.

It is well known that plants release volatile organic compounds (VOCs) into the atmosphere when damaged by herbivores. These VOCs play a crucial role in plant-plant interactions, whereby undamaged plants may detect warning signals from their damaged neighbours and prepare their defences. “Reactive plant VOCs undergo oxidative chemical reactions, resulting in the formation of secondary organic aerosols (SOAs). We wondered whether the ecological functions mediated by VOCs persist after they are oxidated to form SOAs,” said Dr. Hao Yu, formerly a PhD student at UEF, but now at the University of Bern.

The study showed that Scots pine seedlings, when damaged by large pine weevils, release VOCs that activate defences in nearby plants of the same species. Interestingly, the biological activity persisted after VOCs were oxidized to form SOAs. The results indicated that the elemental composition and quantity of SOAs likely determines their biological functions.

“A key novelty of the study is the finding that plants adopt subtly different defence strategies when receiving signals as VOCs or as SOAs, yet they exhibit similar degrees of resistance to herbivore feeding,” said Professor James Blande, head of the Environmental Ecology Research Group. This observation opens up the possibility that plants have sophisticated sensing systems that enable them to tailor their defences to information derived from different types of chemical cue.

“Considering the formation rate of SOAs from their precursor VOCs, their longer lifetime compared to VOCs, and the atmospheric air mass transport, we expect that the ecologically effective distance for interactions mediated by SOAs is longer than that for plant interactions mediated by VOCs,” said Professor Annele Virtanen, head of the Aerosol Physics Research Group. This could be interpreted as plants being able to detect cues representing close versus distant threats from herbivores.

The study is expected to open up a whole new complex research area to environmental ecologists and their collaborators, which could lead to new insights on the chemical cues structuring interactions between plants.

Journal

Science

DOI

10.1126/science.ado6779

Article Title

Biogenic secondary organic aerosol participates in plant interactions and herbivory defense.

Unbiased look at plants uncovers how surprisingly transcription is regulated in plants

Gregor Mendel Institute of Molecular Plant Biology

image:
A GATC-motif downstream of the transcription start site acts like a rheostat, finetuning transcription in different cell types.
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Credit: GMI

Our world today is populated by multicellular organisms, from big trees to climate-wrecking humans. This multicellularity arose independently in plants and animals. Both animals and plants cope differently with the challenges of corralling individual cells together to form a larger organism, such as the need to communicate and coordinate between cells, to share and transport nutrients, and to form specialized structures. One challenge posed by multicellularity is that all cells carry the same genetic code, but the cells look and behave differently: A root cell needs to elongate towards water sources and gravity, while cells in the leaves drive photosynthesis. To achieve different outcomes from the same underlying code, cells tinker with how the code is read out, in what is called transcriptional regulation. Plants and animals also differ fundamentally in how they achieve this transcriptional regulation, as a new paper by the group of Magnus Nordborg at the GMI shows. The results, published in Nature Genetics on September 12, open a new perspective on how plants achieve transcriptional regulation.

New perspective from studying plants

“Much of what we know about transcriptional regulation in plants so far is informed by research on animals and yeast”, says Yoav Voichek, postdoc in the lab of Magnus Nordborg and co-author of the study. “We wanted to look at plants in an unbiased way, thereby making it possible to uncover mechanisms and processes that are unique to plants.” Using a parallel reporter assay in four plant species – maize, Arabidopsis, tomato and Nicotiana benthamiana – the researchers searched for sequences that influence transcription. The transcription start site (TSS) is the specific location on a gene where transcription begins. The researchers identified a region downstream of the TSS that is central for transcriptional regulation.

Looking more closely at how the sequences regulate transcription, the researchers uncovered a novelty in transcriptional regulation. “Most surprisingly, when we swap the position of this regulatory sequence, placing it upstream of the transcriptional start site, it no longer drives transcription”, Voichek says. This finding runs counter to what would be expected from looking at transcriptional regulation in animals: In animals, regulatory sequences are position-independent, as swapping their position does not change how they regulate transcription.

Fine-tuning transcription

Within the regulatory sequence, the scientists uncovered a sequence-motif, consisting of the bases GATC, that strongly drives gene expression. “The sequence motif has a more potent influence on transcription than any DNA motif identified upstream of the transcriptional start site”, Voichek explains. The motif is evolutionarily conserved and found in all vascular plants, i.e. all land plants except for mosses, hornworts and liverworts.

The way in which the GATC-motif influences transcription illustrates how regulatory sequences can fine tune transcription in different cell types. “The higher the number of these motifs downstream of the TSS, the more strongly the gene is expressed”, Voichek says. “The motif acts like a rheostat, finely tuning genes that need to be expressed in all cell types, but at different levels.” In the future, Voichek plans to investigate how the GATC-motif exerts control over transcription. “Our study not only shifts the understanding of transcription regulation in plants but also underscores that we need to study transcription in a diverse set of organisms to broaden our understanding of biology.”

Journal

Nature Genetics

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Widespread position-dependent transcriptional regulatory sequences in plants

Global warming's economic blow: Risks rise more rapidly for the rich

Potsdam Institute for Climate Impact Research (PIK)

In a new study by the Potsdam Institute for Climate Impact Research (PIK), researchers analysed how erratic weather events, increasingly intensified by global warming, affect global production and consumption across different income groups. The results confirm previous studies that the poorest people worldwide bear the greatest economic risks from climate change. Surprisingly, the risk for the wealthy is growing the fastest. Economies in transition like Brazil or China are also highly vulnerable to severe impacts and negative trade effects. Across countries, these countries face the highest risks due to severe impacts of volatile weather and adverse trade effects. As the planet continues to warm, these risks are expected to worsen across most countries, with ripple effects along global supply chains, impacting goods and services worldwide.

“In the next 20 years, climate change will increase economic risks from erratic weather”, states PIK scientist Anders Levermann. “The highest risks remain with the poorest around the world. But the increase of economic risk is strongest for the wealthy, in countries like the US and the EU. Consumers all around the world, regardless of their income, will thus face increasing challenges due to global warming – without a transition towards carbon neutrality we will eventually not be able to meet these challenges.”

Lennart Quante, Sven N. Willner, Christian Otto, Anders Levermann (2024): Global economic impact of weather variability on the rich and the poor. Nature Sustainability. [DOI: 10.1038/s41893-024-01430-7]

Journal

Nature Sustainability

DOI

10.1038/s41893-024-01430-7

Article Title

Global economic impact of weather variability on the rich and the poor.

You are what you eat – ERC grant supports research into past people’s identities based on their dietary practices

Estonian Research Council

Ester Oras, Associate Professor in Analytical Chemistry and Archaeology at the University of Tartu, has received a Starting Grant from the European Research Council (ERC) to study the identities of our distant ancestors based on their diet. Over the next five years, Oras and her team plan to conduct an in-depth biomolecular analysis of at least 150 ancient burials to uncover new layers in the lives of people from a thousand years ago and broaden the range of research methods available to archaeologists.

Messages from the distant past are carried to the present day by different archaeological finds and ancient burial sites, whilst the latter reveal the moment in history when a community buried a member according to how they saw the deceased in society at the time. Often, however, the life of the deceased, the aspects of their group identity and how it changed over their lifetime remain hidden. However, detailed biomolecular analysis of ancient skeletal remains and pottery food residues can shed light on these multiple and dynamic identity categories.

"The study of what people ate is crucial in archaeology because it allows, thanks to modern high-resolution analysis, to reconstruct the intricate details of the human diet from infancy to death at the biomolecular level."

“The study of what people ate is crucial in archaeology because it allows, thanks to modern high-resolution analysis, to reconstruct the intricate details of the human diet from infancy to death at the biomolecular level. The human skeleton and bone tissues develop throughout the lifespan. Thus, an analysis of samples from different bone elements can show us how the person spent their childhood, whether they grew up where they were buried, whether they consumed, for example, typical women’s food or the food of a wealthy family, and how their identity evolved over their lifetime,” Oras explained.

Until now, identity categories have mostly been studied in isolation – comparing and opposing e.g. men or women, peasants or noblemen. Food, however, can be a common denominator for all these social groups and the molecular information stored in the skeletal remains makes it possible to analyse several social categories at the same time. For the analysis, the researchers use cemetery materials dating from 1000–1400: skeletons, teeth, dental plaque, but also pottery buried as grave goods. Altogether, they plan to analyse at least 150 finds, mainly from burial sites in different parts of Estonia.

The project will have a significant impact on archaeological research. Differently from earlier research that has focused primarily on single molecules, such as lipids or proteins, this project will for the first time combine all known methods, including the analysis of different biomolecules and high-resolution methods. These make it possible to obtain more nuanced dietary data, e.g. not only to determine whether a person ever ate fish but also whether the fish was cod or herring. The skeletons will be also examined for DNA to identify possible family links. Machine learning will be used to combine analytical methods and identify relations. According to Oras, such combining of methods is entirely new and allows a qualitative leap forward for archaeological research, both in terms of the methods developed and the novel concepts of social archaeology and identity studies.

The grants from the European Research Council support innovative frontier research in various disciplines. The Starting Grant is awarded to early-stage researchers with outstanding ideas. Ester Oras, the founder and leader of the interdisciplinary research group Archemy at the University of Tartu, combines archaeology with cutting edge analytical methods to study ancient and medieval nutrition and health issues. The Archemy team will also implement the upcoming five-year ERC project “Food identities: biomolecular archaeology reveals multiple and dynamic social identities”. The project budget will be 2.4 million euros

Trees in tropical logged forests release carbon at greater rate despite faster growth, study finds

University of Leicester-led research focusing on the carbon dioxide produced by tree stems shows that individual trees in tropical forests impacted by logging produce more carbon dioxide per m2 of woody stem area than those in unaffected forests

University of Leicester

image:
Old-growth tropical forest at Maliau Basin Conservation Area in Sabah, Malaysian Borneo. Credit: Maria Mills
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Credit: Maria Mills

Tree stems in tropical forests recovering from logging produce carbon dioxide at a greater rate than those in unlogged forests, according to a new study from the University of Leicester.

With fewer surrounding trees to compete with, the tree stems in logged forests are able to grow and take up carbon dioxide at a faster rate than stems in unlogged forests, but this faster growth is combined with faster release of carbon dioxide as well.

Collectively when considering the all the trees in the logged forest they are giving out as much carbon dioxide as an equivalent area of unlogged forest.

In the new study, led by the University of Leicester and published in the journal New Phytologist, researchers were able to break down how much respiration, the process that produces carbon dioxide in tree stems, was used for tree growth and how much for maintenance. They have shown that the increase in respiration from tree stems in logged forests was due to growth, producing new wood, whereas in the old-growth forests most of the respiration was from tree maintenance, supporting the existing tree structure.

Their conclusions make the case for greater research attention on logged landscapes. These are currently understudied despite logged forests now being more prominent than old-growth forests across the tropics.

Tropical forests capture carbon from the atmosphere but they also release a similar amount through respiratory processes in the ecosystem, including metabolic activity of plant growth and maintenance. A previous study by the same author found that logged forests are a net source of carbon – as they emit more carbon dioxide than what they absorb. It is now important to keep learning about logged forests and understand what drives their carbon fluxes.

A common method to study carbon fluxes in forests is to measure net carbon balance, but this doesn’t provide much information about where the fluxes are coming from – it is like knowing your bank balance without any information on the transactions. If we don’t know where the fluxes are coming from we also don’t know why we are getting certain fluxes and what is driving those fluxes.

Instead, for this study the scientists focused on the stems or woody trunk of the trees, which is where most of the forest’s biomass is stored. Data were gathered from forests in Malaysian Borneo as part of a long-term ecological monitoring programme. This region, alike most of the tropical forests of Southeast Asia, has a long history of logging and timber extraction.

By measuring the individual components of the forest carbon cycle and carbon fluxes they can learn a lot more about why certain patterns and fluxes occur. Understanding these is important for understanding the forest ecosystem and then extrapolating this information to future climate change and land use change scenarios.

The scientists studied stem respiration of a sample of trees and then estimated the values for all the trees in the one-hectare study plots. Tree-level results showed higher carbon release levels per unit of stem surface area in logged vs old-growth plots, with 37 grams of carbon per metre squared of woody stem every month in a logged plot versus only 26 grams in an old-growth plot (g C m-2 month-1). However, because old-growth forests have bigger trees and therefore more stem surface area in total, there was no difference between logged and old-growth results when scaled across the entire one-hectare plots.

Lead author Maria Mills, a PhD student in the University of Leicester School of Geography, Geology and the Environment, said: “This study was about considering individual trees versus the whole ecosystem, and what drives carbon emissions at both levels. There are differences between individual trees, and between individual ecosystems, for example logged versus unlogged forests.

“We see higher respiration per square metre in logged plots because the trees in those plots are growing faster. Growth has a metabolic cost, so we get respiration following growth. The trees in logged plots grow faster because they have access to more light – as there are more gaps in logged plots from when timber trees have been extracted. In logged plots we see a lot more investment in growth so these trees will respire more. There are also other reasons for these differences which link back to the trees’ functional traits and soil nutrients, but ultimately it comes down to the priority for trees in logged forests to invest in growth. In old-growth plots, alternatively, we see a lot more investment and priority for tree maintenance.

“Most importantly, our results tell us that the carbon dynamics in logged forests are very different to those of old-growth forests. But given how expansive logged forests are, they could be considered as the ‘new normal’ for contemporary tropical forests. We need to put more research efforts into understanding what goes on in logged forests, both in terms of their carbon fluxes and their wider ecological functioning.”

‘From tree to plot: investigating stem CO2 efflux and its drivers along a logging gradient in Sabah, Malaysian Borneo’ is published in New Phytologist, DOI: 10.1111/nph.20043 Link: https://doi.org/10.1111/nph.20043

Journal

New Phytologist

DOI

10.1111/nph.20043

Article Title

From tree to plot: investigating stem CO2 efflux and its drivers along a logging gradient in Sabah, Malaysian Borneo

Millions of depressed Americans could benefit from psychedelic therapy, study finds

New analysis reveals over half of patients treated for depression may be eligible for psilocybin-assisted therapy if FDA-approved

Genomic Press

Atlanta, Georgia - In the wake of mounting evidence for the efficacy of psychedelic-assisted therapies, the U.S. Food and Drug Administration (FDA) is considering approving psilocybin, the active ingredient in “magic mushrooms,” for treating depression in the near future. As this watershed moment approaches, a critical question arises: Just how many people might stand to benefit from this promising but still unproven therapy?

Shedding light on this high-stakes inquiry, a first-of-its-kind peer-reviewed study led by researchers at Emory University, the University of Wisconsin-Madison and UC Berkeley, and that will be published in Psychedelics (ISSN: 2997-2671, Genomic Press, New York) on 24 September 2024 has generated initial estimates of the potential demand for psilocybin-assisted therapy for depression in the United States. By analyzing national survey data on depression prevalence and treatment in conjunction with the eligibility criteria from recent landmark clinical trials, the researchers determined that between 56% and 62% of patients currently receiving treatment for depression—amounting to a staggering 5.1 to 5.6 million individuals—could qualify for psilocybin therapy if approved.

“Our findings suggest that if the FDA gives the green light, psilocybin-assisted therapy has the potential to help millions of Americans who suffer from depression” said Syed Fayzan Rab, an Emory MD candidate and the study's lead author. “This underscores the importance of understanding the practical realities of rolling out this novel treatment on a large scale.”

To arrive at their projections, the researchers first determined that of the nearly 15 million American adults with depression, about 9 million receive treatment in a given year. They then evaluated this population against various eligibility criteria used in recent clinical trials of psilocybin for depression. Their analysis generated a range of estimates: a “lower-bound” of 24% of patients eligible if the strict criteria of initial trials were applied, a “mid-range” of 56% based on criteria likely to be used in real-world medical settings, and an “upper-bound” of 62% after accounting for patients with multiple exclusionary conditions.

Notably, nearly a third of the lower-bound to mid-range jump resulted from the inclusion of patients with alcohol and substance use disorders, for whom growing evidence suggests psilocybin may actually be beneficial rather than contraindicated. However, even the 62% upper-bound estimate is likely conservative, as the analysis focused only on currently treated individuals and did not account for the potential influx of new patients drawn by the appeal of psychedelic medicine.

The researchers caution that these projections are highly contingent on the precise FDA approval parameters and subsequent real-world implementation factors. Insurance coverage decisions, availability of trained practitioners, and regional variations in access could all considerably constrain the ultimate uptake of psilocybin therapy. Additionally, if approval encompasses off-label use for conditions beyond depression, demand could further surge in unpredictable ways.

“While our analysis is a crucial first step, we've only scratched the surface in understanding the true public health impact psilocybin therapy may have,” said Dr. Charles Raison, a collaborator on the study and the lead investigator on one of the largest clinical trials looking at the efficacy of psilocybin therapy for depression. "Ultimately, the realizable potential of this treatment rests in the hands of regulatory bodies, policymakers, insurers, and the healthcare community at large. It's our hope that these findings spur productive discussions and proactive preparations to optimize the benefit to patients while minimizing unintended consequences."

As the psychedelic renaissance continues to gather momentum, this study provides a vital glimpse into the promise and challenges that may lie ahead. With millions of lives potentially in the balance, it underscores the urgency of further research to refine demand estimates and inform equitable, effective delivery of psilocybin therapy should it gain approval.

The peer-reviewed study, “An Estimate of the Number of People with Clinical Depression Eligible for Psilocybin-Assisted Therapy in the United States,” will be published on 24 September 2024 and will be freely available online at the website of Psychedelics (Genomic Press, New York): https://pp.genomicpress.com/aop/.

About Psychedelics – Psychedelics: The Journal of Psychedelic Pharmacology (ISSN: 2997-2671) is a peer-reviewed journal published by Genomic Press, New York. The journal is exclusively dedicated to the latest advancements in the realm of psychedelic substances and their potential therapeutic uses. Psychedelics embraces the full spectrum of research, from fundamental investigations to cutting-edge clinical studies and welcomes diverse perspectives and contributions, advancing the understanding of psychedelic compounds.

To obtain a confidential pre-print before the embargo date, contact: Fayzan Rab. Emory University School of Medicine: syed.f.rab@emory.edu

Method of Research

Data/statistical analysis

Subject of Research

People

Article Title

An Estimate of the Number of People with Clinical Depression Eligible for Psilocybin-Assisted Therapy in the United States

Article Publication Date

13-Sep-2024

COI Statement

Syed Fayzan Rab serves as a consultant at Sunstone Therapies. Elliot Marseille serves as adjunct faculty at UC Berkeley's Collaborative for the Economics of Psychedelics, which has received financial support from the Usona Institute. Charles Raison serves as a consultant to Usona Institute and Novartis.

UK’s first menopause education and support network to trial two new courses

University College London

Details of two new courses to help individuals before and during the menopause have been published as part of the launch of the UK’s first menopause education and support programme, created by UCL researchers.

The United Kingdom’s National Menopause Education and Support Programme (InTune), is being developed by Professor Joyce Harper (UCL EGA Institute for Women’s Health), Dr Shema Tariq (UCL Institute for Global Health) and Dr Nicky Keay (UCL Division of Medicine).

The work has been undertaken in partnership with two charities, Wellbeing of Women and Sophia Forum. The programme also has the support of the Royal College of Obstetricians and Gynaecologists and British Menopause Society (BMS).

A core aim of the UCL team is to co-design InTune with a diverse range of women and people who are affected by the menopause, to ensure that it is relevant, accessible and inclusive.

Over the last 12 months, the team have conducted two workshops (involving academics, clinicians, charity representatives, activists and other professionals working in menopause), focus groups and a public consultation survey. Through this work, they have established the need for two separate but interrelated programmes: Be Prepared for Menopause and the Perimenopause Programme.

Professor Joyce Harper said: “Our previous research has highlighted an urgent need for accessible, evidence-based menopause education and support. We now wish to use our research expertise to respond to this.

“Our vision is of high quality, inclusive menopause awareness, education and support, for everyone. We will achieve this by developing and delivering a non-commercial programme of holistic support and education about menopause, co-designed with stakeholders and the public.”

Be Prepared for Menopause is a two-hour interactive session aimed at individuals under 40 who have not yet reached perimenopause, but anyone can attend. The session will cover what menopause is, symptoms, diagnosis, management (including lifestyle modification) and life post menopause. The UCL team are using a novel teaching style, including showing short videos by key experts in the field, followed by opportunities for course attendees to reflect and discuss the issues raised.

The first version of the course has already been developed and has started to be piloted across the UK.

The Perimenopause Programme will be for individuals who are already experiencing menopause-related symptoms to ensure they have peer support and learn more about the perimenopause.

The perimenopause usually occurs around three to five years before the onset of menopause. During this stage women’s oestrogen and progesterone levels begin to fluctuate, causing them to experience mood changes, irregular menstrual cycles and other menopausal symptoms.

This stage of the menopause continues until one year after a woman’s last period and can often last for between four and eight years in total.

Inspired by antenatal classes, the Perimenopause Programme will be between six and eight weeks long and delivered in a group setting. The team hope that eventually the course will be available through employers and in communities, fusing education with coaching and peer support.

The team will ensure that both courses will be available online and in-person, and that the content will be adapted for a diverse range of target audiences, including people who are neurodivergent, racially or sexually minoritised, and those living with an existing health condition.

Dr Nicky Keay added: “We believe that the time is right for InTune, a national programme that will allow people to be in tune with menopause, in tune with their bodies and in tune with each other.”

Plans for the programme were first announced last year* following research led by Professor Harper, that showed that more than 90% of women were never educated about the menopause at school and over 60% only started looking for information about it once they began experiencing menopausal symptoms**.

New details published in Women’s Health reveal how InTune can help address this lack of information and ensure that people reaching menopause have a greater understanding of what is happening to their bodies.

Dr Shema Tariq said: “InTune recognises that with the right information and support, delivered to the right people, at the right time, we can empower communities to manage their health and wellbeing through this key life shift.”

The team recently showcased InTune at a House of Commons event - chaired by Carolyn Harris MP, who is Chair of the All-Party Parliamentary Group on Menopause, and Professor Dame Lesley Regan, the Women’s Health Ambassador for England - where they discussed the need to provide education and support for menopause***.

The team are now hoping to secure further funding to ensure the programme is refined and robustly evaluated.

*https://www.ucl.ac.uk/news/2023/aug/plans-uks-first-menopause-education-programme-launched-ucl-academics

** https://www.ucl.ac.uk/news/2023/apr/nine-ten-women-were-never-educated-about-menopause

*** https://www.ucl.ac.uk/news/2024/may/details-uks-first-menopause-education-and-support-network-announced-parliament

Journal

Women s Health

DOI

10.1177/17455057241277535

Article Title

The time has come for a UK-wide menopause education and support programme IN TUNE

Towards the realization of compact and portable nuclear clocks

Scientists control the thorium-229 isomeric state population in CaF2 crystals using X-ray

Okayama University

Exploring production and decay dynamics of thorium-229 (229Th) isomer for ultra-precise nuclear clocks — image:
(Left) The VUV signal immediately after X-ray beam irradiation on 229Th doped CaF2 crystal vs. irradiation time. The VUV signal according to irradiation time reaches its saturation value faster than the expected decay half-life by a factor of about 10. (Right) The observed temporal profile of the isomeric decay signal with a half-life of ~ 450 seconds. This suggests that the isomeric state decays faster during X-ray irradiation, indicating quenching.

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Credit: Assistant Professor Takahiro Hiraki from Okayama University, Japan https://www.nature.com/articles/s41467-024-49631-0

Scientists use atomic clocks to measure ‘second,’ the smallest standard unit of time, with great precision. These clocks use natural oscillations of electrons in atoms, similar to how pendulums work in old grandfather clocks. The quest for an even more precise timekeeper led to the discovery of nuclear clocks, which use the transitions of atomic nuclei instead of electrons to keep time.

A rising contender for the development of ultra-precise nuclear optical clocks is the nuclear first-excited state of 229Th isotope. Its long half-life of 103 seconds and low excitation energy of a few electron volts make it ideal for excitation by VUV lasers, providing a precise reference transition for nuclear clocks. Besides, nuclear clocks can also be used in compact solid-state metrology devices and fundamental physics research. To explore the potential application of 229Th isomer, it is essential to understand its fundamental properties like isomeric energy, half-life, and the dynamics of excitation and decay in detail.

Working in this direction, Assistant Professor Takahiro Hiraki from Okayama University, Japan and his team including Akihiro Yoshimi and Koji Yoshimura have developed an experimental setup to effectively assess the population of the 229Th isomeric state and detect its radiative decay. In their recent study published in Nature Communications on 16 July 2024, they synthesized 229Th-doped VUV transparent CaF2 crystals and demonstrated their ability to control 229Th isomeric state population using X-rays. “Our group is working on fundamental physics using atoms and lasers. To realize a solid-state nuclear clock using 229Th, it is necessary to control the excitation and de-excitation state of the nucleus. In this study, we successfully controlled the nuclear states using X-rays, bringing us one step closer to building a nuclear clock,” stated Assistant Professor Hiraki while explaining the motivation behind their study.

To investigate the radiative decay (de-excitation), the team created excitation from the ground state of 229Th nucleus to an isomer state, via the second excited state using a resonant X-ray beam. They found that the doped 229Th nucleus underwent radiative decay back to the ground state, along with the emission of a VUV photon.

One of the key findings was the rapid decay of the isomer state when exposed to X-ray beam irradiation and the “X-ray quenching” effect, which allowed de-population of the isomer on demand. The researchers believe that this controlled quenching could advance nuclear clock development, alongside other potential applications, such as portable gravity sensors and higher precision GPS systems.

Emphasizing the potential of nuclear optical clocks, Assistant Professor Hiraki says, “When the nuclear clock under development is completed, it will enable us to test whether ‘physical constants,’ especially fine structure constant, which were previously believed to remain unchanged, might vary over time. If time variation of physical constants is observed, it may lead to the elucidation of dark energy, one of the greatest mysteries of the universe.”

About Okayama University, Japan

As one of the leading universities in Japan, Okayama University aims to create and establish a new paradigm for the sustainable development of the world. Okayama University offers a wide range of academic fields, which become the basis of the integrated graduate schools. This not only allows us to conduct the most advanced and up-to-date research, but also provides an enriching educational experience.

Website: https://www.okayama-u.ac.jp/index_e.html

About Assistant Professor Takahiro Hiraki from Okayama University, Japan

Dr. Takahiro Hiraki is an Assistant Professor at Research Institute for Interdisciplinary Science at Okayama University, Japan. In 2012, he completed his Master’s and then went on to pursue his doctoral course at Department of Physics and Astrophysics, Kyoto University. He is a member of The Physical Society of Japan and The Japanese Society for Synchrotron Radiation Research. Over the course of his research career, he has published more than 60 papers and received over 7,300 citations. His current areas of interest include thorium laser atomic nucleus, atomic physics, elementary particles, and muons.

Journal

Nature Communications

DOI

10.1038/s41467-024-49631-0

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Controlling 229Th isomeric state population in a VUV transparent crystal