Sex lives of orchids reads like science fiction

A global database of pollination data for almost 3000 orchid species

Peer-Reviewed Publication

LA TROBE UNIVERSITY

 

IMAGE: AS IS THE CASE FOR MANY ORCHIDS, THE DRAGON ORCHID (CALADENIA BARBAROSSA) IS POLLINATED BY JUST A SINGLE SPECIES OF INSECT. HERE, POLLINATION OCCURS VIA A MALE THYNNINE WASP, WHICH IS SEXUALLY ATTRACTED TO THE FLOWER THROUGH MIMICRY OF THE WASP'S SEX PHEROMONES. IN THIS PHOTO THE MALE WASP REMOVES AND DEPOSITS POLLEN IN THE PROCESS OF ATTEMPTING TO COPULATE WITH THE FLOWER view more 

CREDIT: DR RYAN PHILLIPS, LA TROBE UNIVERSITY

Recent research, published in the Botanical Journal of the Linnean Society, used the database to reveal that orchids show remarkable diversity of highly specialised pollination strategies that differ across global regions.

The recently published database contains over 2900 orchid species, detailing information on the identity of their pollinators and how they attract them. Importantly, the database reveals patterns of reproductive biology by habitat, geography and taxonomy.

“From these data, we identify general patterns and knowledge gaps limiting our understanding of orchid biology at the global level,” Dr Phillips said.

Charles Darwin used orchids to study evolution, believing their elaborate flower was an adaptation to enhance the probability of transferring pollen between plants – thereby increasing their offspring’s fitness. 

“Because of the unusual floral traits and often unconventional pollination attraction strategies, orchids have been at the forefront of understanding floral adaptations to pollinators,” Dr Phillips said. 

Indeed, Darwin famously predicted that the Madagascan orchid Angraecum sesquipedale – with its 40 cm long nectar spur - would be pollinated by a moth with an equally long and outlandish proboscis.

Using the new database, the research paper, led by Dr James Ackerman from the University of Puerto Rico, found that over 75% of orchid species are dependent on pollinators for reproduction. Interestingly, almost half of the orchids studied did not provide any kind of reward for visiting animals – instead they used deceit to attract pollinators. 

Orchids tended to be specialised on just one main pollinator species – be they living in the rainforests of Costa Rica or the montane grasslands of South Africa – but this trend was even stronger for those using deception. 

Study co-author, Dr Noushka Reiter, said that “specialising on one pollinator species leaves many orchids particularly vulnerable to anthropogenic threats including climate change. With the loss of pollinators we would also loose these pollinator dependent orchid species.”

The pollination strategies developed by orchids reads like a crime thriller – indeed, Australia is the world epicentre of pollination by sexual mimicry, where a host of different insect groups – from wasps to bees to gnats – are duped by this elaborate rouse. 

In South Africa, orchids mimic carrion, on Reunion Island they mimic rainforest fruits and in Brazil they mimic the smell of aphids – all in the aim of deceiving pollinators. 

More romantically, in the American tropics, 100s of orchid species provide fragrance to certain bees, which collect them and incorporate them into their courtship bouquet. 

Science fiction? 

In Australia, there is even a sexually deceptive orchid known as Caladenia barbarella – which means little beard in Latin (in reference to the flower) but also refers to the comic book character of the same name who was infamous for her sexual exploits.

Dr Phillips said that a surprising finding of the database was that “a hallmark of the orchid family is the high proportion of species that employ deceit to attract pollinators by exploiting the sensory abilities of pollinators via chemical, visual or tactile stimuli, generally in combination,” he said.

Orchids exhibit two major forms of deceit. The first involves food deception, whereby the orchid may look or smell like a type of food to attract a pollinator. The second form of deceitful pollination is sexual deception, where male pollinators are enticed to visit flowers that provide visual, tactile and/or olfactory signals that are indicative of a female insect. 

“The floral signals can be so persuasive that insects attempt copulation and may even ejaculate,” Dr Phillips said. 

“I’ve even had the wasps fly in through the car window at the traffic lights and start making love to the orchids specimens on the front seat”. 

Far from being a freak occurrence, this strategy is now known from 20 genera around the world, including 100s of orchid species.

To date a third means of deception, known as brood-site deception, which typically involves mimicry of larval food such as mushrooms, dung, carrion to attract female flies looking for a food source on which to lay eggs – was considered more common in some other families of flowering plants and rarely seen in orchids. 

According to the database:

* In terms of scientific study, Australasia and Africa have 15 and 20% coverage of their orchid diversity, respectively, whereas orchid floras of Temperate Asia, Tropical Asia and South America are much under-represented 

* Approximately 76% of orchid species are entirely dependent on pollinators for reproduction. 

* Highly specialised pollination systems are frequent, with approximately 55% of orchids studied having just a single known pollinator species.

* 54% of orchid species offer pollinator rewards, and about half of those (51%) produce nectar. Orchids that are pollinated by insect collecting floral fragrances, account for 24% of the rewarding species, whereas those that produce floral oils account for c. 15%. The remaining 10% comprises species that offer trichomes (food hairs, pseudopollen), resins, pollen or sleep sites. 

* Deception, including food, brood-site and sexual deception, was recorded in 46% of the species in the database. Food deception was the most frequently recorded means of deception accounting for 60% of deceptive species. Sexual deception accounted for 38% of the records for pollination by deceit and is present in 20 orchid genera. 

* Wasps and bees are the group that make up the most common type of pollinator with flies and mosquitoes coming in a close second

The authors caution that there is much data collecting yet to be done. 

“Despite containing over 2900 species, our database covers less than 10% of the family. While they are centres of orchid diversity, the tropical regions of Africa, Southern America and Asia, are significantly under-represented in orchid pollination studies, especially among epiphytic orchids,” Dr Phillips said.

“The study of orchid pollination provides tremendous opportunity to discover new and bizarre pollination strategies, and to understand the adaptations that flowering plants to attract pollinators. While the tropics is the big unknown in orchid biology, many of best-known Australian orchids have not been studied in detail.

“Aside from scientific interest, this has important practical implications for conservation, given that many orchid species are reliant on one primary pollinator species for their persistence,” Dr Phillips said.

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JOURNAL

Botanical Journal of the Linnean Society

DOI

10.1093/botlinnean/boac082 

METHOD OF RESEARCH

Literature review

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Beyond the various contrivances by which orchids are pollinated: global patterns in orchid pollination biology

Supercomputer used to simulate winds that cause clear air turbulence

Peer-Reviewed Publication

NAGOYA UNIVERSITY

 

IMAGE: RED AND BLUE AREAS SHOW WIND SPEED DIFFERENCES WITHIN THE TURBULENCE CAUSED BY KELVIN–HELMHOLTZ INSTABILITY view more 

CREDIT: RYOICHI YOSHIMURA

A research group from Nagoya University has accurately simulated air turbulence occurring on clear days around Tokyo using Japan’s fastest supercomputer. They then compared their findings with flight data to create a more accurate predictive model. The research was reported in the journal Geophysical Research Letters.

Although air turbulence is usually associated with bad weather, an airplane cabin can shake violently even on a sunny and cloudless day. Known as clear air turbulence (CAT), these turbulent air movements can occur in the absence of any visible clouds or other atmospheric disturbances. Although the exact mechanisms that cause CAT are not fully understood, it is believed to be primarily driven by wind shear and atmospheric instability.

CAT poses a high risk to aviation safety. The sudden turbulence on an otherwise calm day can lead to passenger and crew member injuries, aircraft damage, and disruptions to flight operations. Pilots rely on reports from other aircraft, weather radar, and atmospheric models to anticipate and avoid areas of potential turbulence. However, since CAT shows no visible indicators, such as clouds or storms, it is particularly challenging to detect and forecast.

As winds swirl and circulate creating sudden changes in airflow, eddies are created that can shake an aircraft. Therefore, to better understand CAT, scientists model it using large-eddy simulation (LES), a computational fluid dynamics technique used to simulate these turbulent flows. However, despite its importance to research on air turbulence, one of the greatest challenges of LES is the computational cost. Simulating the complex interactions involved in LES requires high levels of computing power.

To elaborately simulate the process of turbulence generation using high-resolution LES, the research group from Nagoya University turned to an exascale computer called the Fugaku supercomputer. It is a high-performance computing system, currently ranked as the world's second fastest supercomputer.

Using Fugaku’s immense computational power, Dr. Ryoichi Yoshimura of Nagoya University in collaboration with Dr. Junshi Ito and others at Tohoku University, performed an ultra-high-resolution simulation of the CAT above Tokyo’s Haneda airport in winter caused by low pressure and a nearby mountain range.

They found that the wind speed disturbance was caused by the collapse of the Kelvin-Helmholtz instability wave, a specific type of instability that occurs the interface between two layers of air with different velocities. As one layer has higher velocity than the other, it creates a wave-like effect as it pulls at the lower velocity layer. As the atmospheric waves grow from the west and collapse in the east, this phenomenon creates several fine vortices, creating turbulence.

After making their computations, the group needed to confirm whether their simulated vortices were consistent with real-world data. “Around Tokyo, there is a lot of observational data available to validate our results,” said Yoshimura. “There are many airplanes flying over the airports, which results in many reports of turbulence and the intensity of shaking. Atmospheric observations by a balloon near Tokyo were also used. The shaking data recorded at that time was used to show that the calculations were valid.”

“The results of this research should lead to a deeper understanding of the principle and mechanism of turbulence generation by high-resolution simulation and allow us to investigate the effects of turbulence on airplanes in more detail,” said Yoshimura. “Since significant turbulence has been shown to occur in the limited 3D region, routing without flying in the region is possible by adjusting flight levels if the presence of active turbulence is known in advance. LES would provide a smart way of flying by providing more accurate turbulence forecasts and real-time prediction.”

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JOURNAL

Geophysical Research Letters

DOI

10.1029/2022GL101286 

METHOD OF RESEARCH

Computational simulation/modeling

ARTICLE TITLE

Clear Air Turbulence Resolved by Numerical Weather Prediction Model Validated by Onboard and Virtual Flight Data

SMART launches new research group M3S to advance AI, automation and the future of work

SMART launches a new research group, Mens, Manus and Machina (M3S) aimed at tackling key social and institutional challenges around the rise of AI and new technologies, advancing these fields to create impactful value for Singapore and the world

Business Announcement

SINGAPORE-MIT ALLIANCE FOR RESEARCH AND TECHNOLOGY (SMART)

 

IMAGE: SMART M3S LEAD PRINCIPAL INVESTIGATOR AND MIT PROFESSOR, PROFESSOR JINHUA ZHAO view more 

CREDIT: SMART M3S

• Five-year multi-million-dollar programme supported by NRF under its CREATE programme

• New interdisciplinary research group (IRG), SMART M3S, will bring together 17 MIT and Singapore professors to further Singapore’s Smart Nation initiative over five years

• The focus of the SMART M3S research will be to design the technology, training programmes and institutions for successful human-machine collaboration in the workplace and beyond

• The first of its kind, SMART M3S will integrate robotics and AI with human capital development, economic growth, and public acceptability

Singapore, 12 July 2023 - Singapore MIT-Alliance for Research and Technology (SMART), MIT’s research enterprise in Singapore, has launched a new interdisciplinary research group (IRG) aimed at tackling key social and institutional challenges around the rise of AI and new technologies, furthering advances in these fields to create impactful value for Singapore and the world beyond. In line with Singapore’s Smart Nation initiative and the National AI Strategy, and as part of SMART's commitment to foster collaborative research in Singapore that generates positive impact for society, Mens, Manus and Machina - How AI Empowers People, Institutions and the City in Singapore (M3S) will embark on an ambitious five year endeavour supported by a multi-million-dollar grant from the National Research Foundation (NRF) under its Campus for Research Excellence And Technological Enterprise (CREATE) programme. 

Bringing together a diverse team of 17 professors from the Massachusetts Institute of Technology (MIT) and Singapore, SMART M3S will also draw expertise from local researchers from Singapore Management University (SMU), Singapore University of Technology and Design (SUTD), the National University of Singapore (NUS), and the National Robotics Programme (NRP).

As Asia’s smartest city, Singapore’s integration of AI, automation, and robotics has been facilitated by strategic use of data analytics, IoT technologies, and smart infrastructure. Amid the rise of AI and machine learning, SMART M3S will contribute to Singapore's AI ecosystem by focusing on the human-machine relationship, enhancing existing AI initiatives in the city-state.

Mens, Manus and Machina (M3S) - inspired by MIT’s motto of mens et manus (mind and hand) - reflects the research group’s ideals to promote AI and machine use for practical application; technologies that are extensions of humans and augment their lives. SMART M3S, in a world first, integrates research into robotics and A.I. with human capital development, economic growth, and public acceptability - an intersectional approach to the ongoing transformation of how we work and live.

This interdisciplinary approach encompasses tackling key issues such as physical and digital interfaces between humans and machines, machine learning fundamentals, and understanding the implications of AI for human and social capital development. Other issues of focus include work on structuring human-machine teams within organisations and the developing dynamics between humans and machines in resource allocation and manpower (as well as machine-power) management.

The research conducted will significantly advance the fields of soft robotics, brain interfaces, learning algorithms, task allocation, team formation, model compression, sustainable technology, technology acceptability in the workplace, social acceptability of robotics and AI, and more. The impact of AI on human welfare and productivity and how AI technology can advance both areas will be central considerations for the work at SMART M3S, as society navigates the transition towards an AI- and machine-enhanced future.

Through interdisciplinary research, knowledge sharing, and impactful collaborations, SMART M3S aims to redefine the boundaries of AI, automation, and robotics to scientific, societal and commercial impact. The work at M3S will explore the intricate interplay between human capabilities, emerging technologies, and societal structures, paving the way for designing inclusive, resilient, and innovative solutions that empower individuals, institutions, and cities in Singapore. SMART M3S, by collaborating with Singaporean partners, will enhance Singapore’s ability to create forward-looking AI policies, invigorate Singapore’s economic standing within AI, and support local workforce training and mentorship on AI topics. 

Since its inception in Singapore in 2007, SMART has pioneered innovations that have transformed and are transforming a multitude of fields such as autonomous driving, agriculture, microelectronics, cell therapy, mechanics and microfluidics platforms for biology and medical diagnostics, and antimicrobial resistance.

“As a species, humans have spent eons learning how to work effectively with each other but, at the scale of human history, we are still neophytes to computation and automation,” said Professor Jinhua Zhao, Professor at MIT and Lead Principal Investigator at SMART M3S. “We focus on two questions at M3S: How will we design AI and Robotics technologies and train humans to build the skills and habits necessary for success in a robotics-heavy work environment? How will we adapt our social and business institutions to create the incentives and protections necessary to drive innovation and social welfare?”

SMART M3S is helmed by Lead Principal Investigator (PI) Professor Zhao and Co-lead PIs MIT Professor Daniela Rus and SMU Professor Archan Misra. 

Professor Rus shared, “The M3S collaboration between MIT and Singapore, through SMART, will break new ground in our understanding of AI's impact on the future of work. By harnessing our collective expertise and innovative spirit, we aim to advance the state of the art in AI and turn this technological advancement into an engine for human potential and societal progress.”

Professor Misra noted, “M3S is distinguished by its ambition to address the key challenges of human-AI synergy holistically, from both a scientific and societal perspective. It will focus not just on the technical breakthroughs that will allow human workers and AI-enabled machines and software to work interactively, but also on the training and governance mechanisms that ensure that individuals and organisations adapt to and thrive in this new future of work. I’m especially excited to partner MIT on this important national priority, which aligns perfectly with SMU’s strategic multi-disciplinary research priority area of Digital Transformation”.

Eugene A. Fitzgerald, CEO and Director of SMART, added, “Since 2007, SMART has pioneered impactful innovations across various fields, transforming industries such as autonomous driving, agriculture, cell therapy, microelectronics, and medical diagnostics by bringing together some of the finest from MIT and Singapore. With our latest interdisciplinary research group SMART M3S, we further our commitment to bringing scientific, social, and commercial impact to Singapore and beyond. The focus on a human-centric approach to AI advancement will contribute towards Singapore being at the forefront of the future of work.”

Seeking to redefine the boundaries of AI, automation, and robotics through interdisciplinary research, knowledge sharing, and impactful collaborations, SMART M3S aims to design inclusive, resilient, and innovative solutions that empower individuals, institutions, and cities. By exploring the intricate relationship between human capabilities, emerging technologies, and societal structures, it is envisioned that SMART M3S will drive scientific, societal, and commercial impact in Singapore and beyond.

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Aston University-based Supergen Bioenergy Hub to receive £5m to continue renewable energy research

Grant and Award Announcement

ASTON UNIVERSITY

 

IMAGE: PROFESSOR PATRICIA THORNLEY. view more 

CREDIT: ASTON UNIVERSITY

• 
  
• 
  
• Aston University-based Supergen Bioenergy Hub is to receive £5 million
• The hub contributes to the government’s engineering net zero priority
• The UK could have enough biomass and waste to supply over 40% of its primary energy demand.

Aston University-based Supergen Bioenergy Hub is to receive £5 million to continue its exploration of the use of renewable energy.

The hub is one of three across the UK which contribute to the government’s engineering net zero priority to ensure the country benefits from clean energy research and innovation.

The successful bid was led by director of the hub and of Aston University’s Energy and Bioproducts Research Institute (EBRI), Professor Patricia Thornley.

The new UK Research and Innovation funding builds on the hub’s bioenergy research which focused on accelerating current generation technologies.

Bioenergy is a significant and increasing UK renewable energy. The UK could have sufficient indigenous biomass and waste to supply over 40% of the UK's primary energy demand.

The vision of the new impact Supergen Bioenergy Hub is to increase sustainable biomass production in the UK to minimise greenhouse gas emissions.

Established in 2018 Supergen Bioenergy Hub works with academia, industry, government and other groups to develop sustainable bioenergy systems that support the UK’s transition to an affordable, resilient, low-carbon energy future.

The hub is funded by the Biotechnology and Biological Sciences Research Council (BBSRC) and the Engineering and Physical Sciences Research Council (EPSRC), part of UK Research and Innovation.

Professor Thornley said: "Getting the right enabling environment is absolute key to unleashing the massive potential of bioenergy in the UK

“We are delighted that UKRI - UK Research and Innovation - have recognised the ability of the world class team of investigators in this proposal to deliver a step change in the bioenergy sector.

“We look forward to working with colleagues in industry, policy and academia to incorporate new ideas and information into this exciting new programme of work.”

The grant is part of an overall investment of £55 million in six national research centres to drive forward change in the energy system and help to meet the UK’s net zero target by 2050.  

The centres will boost knowledge, create innovative green technologies and reduce demand for energy to achieve greener, cleaner domestic, industrial and transport energy systems.

Professor Dame Ottoline Leyser, chief executive of UK Research and Innovation, said:

“The government has set a target of reaching net zero emissions by 2050, requiring rapid decarbonisation of our energy systems. UKRI is leveraging its ability to work across disciplines to support this ambition through a major portfolio of investments that will catalyse innovation and new green energy systems. 

“The funding announced today will support researchers and innovators to develop game changing ideas to improve domestic, industrial and transport energy systems.”

Over the next four years Professor Thornley and her colleagues will be working with key industrial partners. These include Advisian, Alps Ecoscience, Compact Syngas Solutions, Croda, DAABON, Energy Systems Catapult, Engas UK, Future Biogas, Glass Futures, Kew Technology, Progressive Energy, Reheat, Renewable Energy Association, Rolls Royce, Straw Innovations, Wales & West Utilities, Straw Innovations, Terravesta, Uniper.

Academic partners Imperial College, London and the University of York will work with Aston University to support the growth and dissemination of the hub’s work. They will help to prove how sustainable bioenergy technology solutions developed in the UK can work.

The Universities of Surrey, Glasgow, Sheffield and Strathclyde will play key roles in developing innovative and disruptive bioenergy technologies.

Meanwhile Aston University, the University of York, University of Glasgow, Imperial College and the University of Southampton will focus on supplying independent academic perspectives to support development of the sector.

Scientists find evidence of world’s oldest glaciers

Reports and Proceedings

GOLDSCHMIDT CONFERENCE

Scientists have discovered the traces of the world’s oldest known glaciers, dating from 2.9 billion years ago, in rocks sitting under the world’s largest gold deposits in South Africa. This suggests the presence of continental ice caps at that time and that either the area was closer to the poles, or that parts of the Earth may have been frozen in a previously unknown “snowball Earth” period of extreme cold weather. This work is presented for the first time at the Goldschmidt geochemistry conference in Lyon, after recent peer-reviewed publication.

Scientists agree that there must have been large variations in the early Earth’s climate, but convincing evidence of the exact conditions in the early Earth have been difficult to find.

Now researchers Professor Axel Hofmann (University of Johannesburg, South Africa) and Professor  Ilya Bindeman (University of Oregon, USA) have found evidence from relative oxygen isotope concentrations in ancient rocks, as well as physical proof, showing firm evidence of glaciers, 2.9 billion years ago.

Ilya Bindeman said “We found extremely well-preserved glacial deposits close to the gold fields of South Africa. This is one of the few areas which remain fairly intact and unchanged from the early Earth. These deposits are fossilized glacial moraines, which are basically the debris left by a glacier as it gradually melts and contracts. These are the oldest moraine deposits ever found. In addition, we were able to correlate this with analysis of oxygen isotopes from these rocks, which showed that the climate must have been cold when the rocks were deposited”.

“We looked at relative amounts of 3 oxygen isotopes, 16O, 17O, and 18O. These are all types of oxygen but have very slightly different weights. We found that these rocks had very low amounts of 18O, and very high amounts of 17O, indicating that they were formed at icy temperatures. This means ice. Couple that geochemical evidence with the moraine evidence, and it means glaciers, the oldest glaciers yet found on Earth”.

The researchers put forward a couple of possible explanations: “It may be that this area was close to the poles. Another possibility is that the whole Earth was in a “snowball Earth” period, when low atmospheric concentrations of CO2 and CH4 led to a ‘reverse greenhouse effect’, causing much of the planet to freeze. Scientists believe that this may have happened on a couple of occasions in the more recent past. If so, this would be the earliest such global cooling period recorded. Either possibility is scientifically interesting”, said Axel Hofmann.

He added “The largest sedimentary gold deposits in the world are found in slightly younger rocks sitting above the rocks we studied. It’s possible that a change from icehouse to greenhouse conditions may have aided in the formation of those gold deposits, but this needs to be confirmed and requires further work”.

Commenting, Dr Andrey Bekker (Associate Professor at the Department of Earth & Planetary Sciences, University of California, Riverside) said:

“Evidence for glaciation of this age has been hotly discussed and debated for decades based on sedimentological evidence with suggestions ranging from high altitude to high latitude glaciation.  Triple oxygen isotope analysis add an entirely new line of evidence to this argument. The biogeochemical carbon cycle not only controls climate, but also atmospheric oxygen content and these data are likely to trigger follow-up studies on the transient oxygenation at that time”.

This work is based on the article “Earth’s first glaciation at 2.9 Ga revealed by triple oxygen isotopes”, A.Hofmann and I.M. Bindeman, Geochemical Perspectives Letters v26. https://doi.org/10.7185/geochemlet.2319 See https://www.geochemicalperspectivesletters.org/article2319/

This press release contains additional material and comments, not present in the above published paper.

This work will be presented in the talk number 17171 entitled “A model of unidirectional and accumulative fluxes from mantle to the lithosphere explaining crustal growth via triple oxygen isotope mass balance throughout Earth’s history”, scheduled for 10.00 CEST, Weds 12 July.

The Goldschmidt Conference is the world’s main geochemistry conference. It is a joint congress of the European Association of Geochemistry and the Geochemical Society (US). It takes place in Lyon, France, from 9-14 July. Almost 5000 delegates are expected to attend. https://conf.goldschmidt.info/goldschmidt/2023/goldschmidt/2023/meetingapp.cgi

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JOURNAL

Geochemical Perspectives Letters

DOI

10.7185/geochemlet.2319 

METHOD OF RESEARCH

Observational study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Earth’s first glaciation at 2.9 Ga revealed by triple oxygen isotopes

Solar hydrogen: Barriers for charge transport in metal oxides

Peer-Reviewed Publication

HELMHOLTZ-ZENTRUM BERLIN FÜR MATERIALIEN UND ENERGIE

 

IMAGE: IN THE FEMTOSECOND LABORATORY, ALL SAMPLES ARE INVESTIGATED WITH BOTH A TERAHERTZ METHOD (OPTP) AND MICROWAVE SPECTROSCOPY (TRMC), BOTH MEASUREMENT METHODS INITIALLY PROVIDE INFORMATION ON THE MOBILITY AND LIFETIME OF THE CHARGE CARRIERS - BUT ON DIFFERENT TIME SCALES. view more 

CREDIT: MARKUS SCHLEUNING/HZB

In the future, climate-neutral hydrogen will play an important role as a fuel and raw material. Hydrogen is produced by electrolysis of water, either using an indirect approach in which an external energy source (solar panel or wind turbine) supplies the electrolysis cell with voltage, or using a direct approach: a photoelectrochemical cell in which the photoelectrode itself supplies the electrical energy for electrolysis (PEC cell). This direct approach would have some advantages, but is not yet competitive.

So far, this is mainly due to a lack of good photoelectrodes. Metal oxides are considered suitable in principle; they are inexpensive, non-toxic, stable in aqueous solution and also often possess catalytic properties that can accelerate the desired chemical reaction. And sunlight releases charge carriers in metal oxides, thus generating an electrical voltage. But compared to doped semiconductors such as silicon, these charge carriers are not very mobile, they are rather slow, or immediately settle back into the lattice and localise. This is due to various mechanisms on different time and length scales which are still poorly understood.

In the femtosecond laser laboratory at HZB, the team led by Dr. Dennis Friedrich and Dr. Hannes Hempel has now investigated in detail for the first time what limits the conductivity of metal oxides: "We wanted to find out how strongly charge carriers are localised and how this reduces their mobility at different times," says Markus Schleuning, first author of the study, who did his doctorate on this topic.

"First, we developed a new method to determine the diffusion lengths. The simple equation can also be applied to other classes of materials such as halide perovskites or silicon," explains Hempel.

Then we found out that this does not work for certain materials, and precisely when the charge carriers are located", adds Friedrich: "In the femtosecond laboratory, all samples are investigated with both a terahertz method (OPTP) and microwave spectroscopy (TRMC), both measurement methods initially provide information on the mobility and lifetime of the charge carriers - but on different time scales. The results can be very different, indicating that the carriers have been localised in the meantime. From ultrafast processes in the range of 100 femtoseconds to slower processes lasting 100 microseconds, the team was able to determine the dynamics of charge carriers in the materials. By way of comparison, extrapolated to our human perception of time, this would correspond to changes in time spans of 1 second to 31 years.

The physicists used this combination of methods to analyse ten metal oxide compounds, including Fe2O3, CuFeO2, α-SnWO4, BaSnO3 and CuBi2O4. For all materials, the mobilities were very low compared to conventional semiconductors. A heat treatment, annealing, significantly improved the mobility in BaSnO3. The best performer was the well-known bismuth vanadate (BiVO4), which shows little carrier localisation on the length scales studied. The study shows how metal oxide compounds can be characterised to identify and develop the best materials for photoelectrodes.

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JOURNAL

Advanced Functional Materials

DOI

10.1002/adfm.202300065 

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Carrier Localization on the Nanometer-Scale limits Transport in Metal Oxide Photoabsorbers

Gulf War illness caused by mitochondrial dysfunction, not inflammation

UC San Diego scientists contest longstanding hypothesis about mysterious illness affecting Gulf War veterans, providing first direct evidence that symptoms are driven by impaired mitochondria

Peer-Reviewed Publication

UNIVERSITY OF CALIFORNIA - SAN DIEGO

 

IMAGE: VETERANS WITH GULF WAR ILLNESS HAVE LONG STRUGGLED TO GET A PROPER DIAGNOSIS AND TREATMENT, DESPITE EXPERIENCING SYMPTOMS FOR SEVERAL DECADES. view more 

CREDIT: PHOTO BY JAKOB OWENS ON UNSPLASH

Gulf War Illness (GWI) is a chronic multisymptom health condition affecting one-third of all veterans who served in the 1991 Gulf War, most of whom remain afflicted more than 30 years later. Common symptoms include fatigue, headaches, muscle aches, joint pain, diarrhea, insomnia and cognitive impairment. 

The condition is believed to have been triggered by veterans’ exposure to environmental toxins. However, its exact mechanism in the body continues to be debated, making it difficult to diagnose and treat. The prevailing notion is that inflammation is the driving force of the symptoms, as inflammatory markers are modestly higher in affected veterans than in healthy controls. However, a rival hypothesis suggests mitochondria — the energy-producing organelle found in most cells — may be the true source of the symptoms. 

In a new study, researchers at University of California San Diego School of Medicine put both ideas head-to-head, directly assessing mitochondrial impairment and inflammation in 36 individuals, 19 of whom were veterans with GWI. The findings, published July 12, 2023 in Scientific Reports, suggest that impaired mitochondrial function, and not inflammation, is the main driver of GWI symptoms and should be the primary target of future clinical interventions. 

“This is a radical rethinking of the pathology of GWI,” said corresponding author Beatrice Golomb, MD, PhD, professor of medicine at UC San Diego School of Medicine. “For veterans who have long struggled to get effective care, this discovery could be a real game changer.”

To evaluate the respective roles of mitochondrial function and inflammation in GWI, the researchers acquired muscle biopsies from the study participants and measured the levels of mitochondrial respiratory chain function (MRCF). Inflammation was assessed through participants' blood levels of high-sensitivity C-reactive protein (hsCRP), a common marker of peripheral inflammation.

The researchers then compared this data to the participants’ GWI symptoms and found that the severity of symptoms could be predicted by their degree of mitochondrial impairment, but not by their degree of inflammation. Further statistical analyses found that 17 of the 20 most common GWI symptoms were statistically related to mitochondrial function. In contrast, only one of the 20 symptoms met this criterion for inflammation. 

Another set of analyses revealed that the degree to which participants' mitochondria were compromised in converting fat to energy was strongly related to the degree of inflammation in GWI patients, but not in controls. Reduced activity of this process, called fatty acid oxidation, is known to trigger cell death, which then leads to inflammation. Thus the researchers say this suggests that mitochondrial dysfunction may be the reason inflammation is higher in GWI patients.

“Inflammation does appear to be linked to GWI, but our work suggests that it’s actually a side effect of the primary issue, which is impaired cell energy,” said Golomb. 

The researchers also note that many GWI symptoms are expected outcomes of mitochondrial dysfunction. For example, muscles rely heavily on fat to fuel them, so if mitochondrial dysfunction leads to impaired fatty acid oxidation in GWI patients, this could explain the muscle aches and physical fatigue they often experience. Indeed, muscle symptoms in GWI correlated most strongly with the degree of impairment in mitochondrial fatty acid oxidation. Conversely, the brain relies mostly on sugar for energy, and brain symptoms in GWI related most strongly to impairment in mitochondrial energy production using sugar as a fuel.

The findings also have possible implications for other health conditions, including different forms of toxin exposure, aging and even heart disease. Many of these conditions are marked by increased inflammation, yet often do not respond well to anti-inflammatory drugs. Golomb and colleagues argue that mitochondrial impairment may be an underlying cause for these conditions, creating opportunities for new therapeutic strategies.  

“This is the first time that direct evidence for the mitochondrial hypothesis of GWI has been reported,” said Golomb. “We hope that it will lead to improved treatment plans for the veterans who have long struggled with this mysterious illness.” 

Co-authors of the study include: Roel Sanchez Baez, Jan M. Schilling, Mehul Dhanani, McKenzie J. Fannon, Brinton K. Berg, Bruce J. Miller, Pam R. Taub and Hemal H. Patel, all at UC San Diego.

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JOURNAL

Scientific Reports

DOI

10.1038/s41598-023-35896-w 

AMP biosynthesis key to longevity and metabolic health in vertebrates

Peer-Reviewed Publication

THE HEBREW UNIVERSITY OF JERUSALEM

A recent study led by Dr. Itamar Harel from the Silberman Institute at the Hebrew University of Jerusalem has revealed new insights into the role of AMP biosynthesis in the lifespan and metabolic health of vertebrates. The findings of this study have far-reaching implications, significantly advancing our understanding of the intricate interplay between energy metabolism, aging, and lifespan regulation. Moreover, the study opens up exciting possibilities for developing interventions to combat age-related metabolic diseases and enhance healthy aging.

Aging is commonly associated with disruptions in metabolic homeostasis, which contribute to various health issues. The AMP-activated protein kinase (AMPK) plays a critical role in cellular energy regulation and organismal metabolism. However, previous attempts to genetically manipulate the AMPK complex in mice yielded unfavorable outcomes. In search of an alternative approach, the research team focused on manipulating the upstream nucleotide pool to modulate energy homeostasis.

Using the turquoise killifish as their model organism, the team targeted and mutated APRT, a key enzyme involved in AMP biosynthesis. Remarkably, this manipulation resulted in a significant extension of lifespan in heterozygous male killifish. The study further employed an integrated omics approach, revealing rejuvenation of metabolic functions in the aged mutant fish. These included the adoption of a fasting-like metabolic profile and enhanced resistance to a high-fat diet.

At the cellular level, the heterozygous fish exhibited remarkable traits such as enhanced nutrient sensitivity, reduced ATP levels, and activation of AMPK. These findings highlight the potential of perturbing AMP biosynthesis to modulate vertebrate lifespan and promote metabolic health.

Dr. Itamar Harel expressed his enthusiasm, stating, "This is the first long-lived genetic model in killifish, highlighting the potential is this emerging model for aging. Genetic manipulation of AMP biosynthesis in the turquoise killifish reveals remarkable effects on lifespan and metabolic health. Our study unravels the intricate interplay between energy metabolism, aging, and lifespan regulation, offering exciting possibilities for the development of interventions to combat age-related metabolic diseases and enhance healthy aging."

However, the study also unveiled an intriguing observation. The benefits of extended lifespan and rejuvenated metabolic functions were nullified when lifelong intermittent fasting was applied. Furthermore, the longevity phenotypes were sex-specific. This discovery underscores the complex underlying mechanisms and emphasizes the delicate balance required for optimizing health outcomes, which be different in males and females.

The research sheds new light on the potential of targeting APRT as a promising strategy for promoting metabolic health and extending lifespan in vertebrates. Further investigations in this field hold promise for the development of interventions that enhance healthy aging and combat age-related metabolic diseases.

Research Team: Dr. Itamar Harel, Tehila Atlan, Dr. Gwendoline Astre, Dr. Adi Oron-Gottesman, Uri Goshtchevsky, Ariel Velan and Tomer Levy – Silberman Institute, the Hebrew University of Jerusalem; Margarita Smirnov – Department of Fisheries and Aquaculture, Ministry of Agriculture and Rural Development; Kobi Shapira and Prof. Erez Y. Levanon – Faculty of Life Sciences, Bar-Ilan University; Dr. Joris Deelen – Max Planck Institute for Biology of Ageing.

Dr Harel is a Zuckerman Faculty Scholar, and was recently awarded the prestigious ERC starting grant by the EU.

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JOURNAL

Developmental Cell

DOI

10.1016/j.devcel.2023.05.015 

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Genetic perturbation of AMP biosynthesis extends lifespan and restores metabolic health in a naturally short-lived vertebrate

ARTICLE PUBLICATION DATE

12-JUL-2023