Wednesday, December 20, 2023

 PRE ATOMIC AGE

Mollusks from polar expeditions reveal new details about the ocean


The shells can reveal the oceans’ natural chemistry before they were so severely polluted by humans

Peer-Reviewed Publication

AARHUS UNIVERSITY

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GLASSES WITH NEARLY 100 YEAR OLD MUSSELS AND SEA SNAILS. THE SAMPLES CONTAIN INFORMATION ON HOW THE CHEMISTRY OF THE OCEAN WAS BEFORE NUCLEAR TESTS AND CO2 FROM INDUSTRIALISATION CHANGED IT.

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CREDIT: CHRISTOF PEARCE




In the early hours of 30 October 1961, a Russian bomber took off and flew north. The plane was headed for the Novaya Zemlya archipelago in the Russian part of the Arctic. When the pilot saw the islands far below, he released the cargo – a bomb the size of a double-decker bus.

While the pilot accelerated to get out of range, the bomb slowly descended to the ground under the canopy of a huge parachute. A minute passed, and then the sky was illuminated by the harshest light ever created by humans. 

The bomb, later named Tsar Bomba, is the most powerful nuclear weapon ever detonated. It was the culmination of the nuclear tests carried out by the USSR, the United States and a number of other countries in the years following World War 2.

Two years later, in 1963, the nuclear powers agreed to cease atmospheric nuclear tests, and the tests were moved underground.

However, after almost 20 years of detonations - from the first in 1945 until the treaty in 1963 - the chemistry of the oceans had changed. A change that will last for thousands of years. 

For example, American and French detonations in the Pacific Ocean killed thousands of fish and depleted biodiversity in the area. But the tests also had another consequence. They made it difficult to use carbon-14 dating.

Christof Pearce and a number of his colleagues have attempted to find a method to get around these problems.

“We can’t calibrate the carbon-14 age of fossilised animals or plants found in ocean sediments. The nuclear tests created massive amounts of carbon-14 in the atmosphere, which were slowly absorbed into the ocean. Whereas the atmosphere quickly regained some sort of equilibrium, it will take hundreds, or even thousands of years before the ocean can do the same,” says Christof Pearce, and continues:

"That's why we need material from before the nuclear tests – and that’s where the polar expeditions come in. We can use them to find out, how much carbon-14 there was before the detonations and adjust the dating.

What is carbon-14 dating?

The Earth's atmosphere consists of a number of gases such as oxygen, CO2 and nitrogen.

When nitrogen atoms move into the upper layers of the atmosphere, they’re hit by free neutrons released due to cosmic radiation. The nitrogen atoms absorb the neutrons and are converted to carbon-14 and emit a proton. The new carbon-14 atoms then bind with oxygen, creating CO2. 

Trees, shrubs and other plants absorb CO2 from the air during photosynthesis. Meaning they also absorb carbon-14.

However, the vast majority of CO2 in the atmosphere consists of carbon-12. Only a small proportion of CO2 contains carbon-14, which is radioactive. Therefore plants primarily absorb carbon-12.

When a plant dies, it stops absorbing new carbon, but because carbon-14 is radioactive, it decays and disappears slowly. Carbon-12, on the other hand, does not. Researchers can calculate how old a plant residue is by measuring how much carbon-14 is left compared with carbon-12. We know the half-life of carbon-14 is 5,700 years – and we know that the natural distribution between carbon-12 and carbon-14 is fairly stable.

Plants are eaten by herbivores, who thereby absorb the carbon. The herbivores in turn are eaten by carnivores, which then also absorb it. This is why the method can also be used to carbon date animals and humans.

Museums are a treasure trove

The nuclear tests are not the only reason why the age of carbon-14 in the oceans has changed. Human emissions of CO2 have also shifted the balance - but in the opposite direction. 

As the name suggests, fossil fuels consist of fossil plant material and they therefore have a high carbon-14 age. CO2 emissions have therefore had the opposite effect to the atomic bombs that created new carbon-14.

And this is a well-known problem, especially for geologists, archaeologists and other researchers interested in what the ocean looked like in the past.

For Christof Pearce, one of the most important sources of knowledge about the climate and marine environment of the past is sediment samples. Just like researchers who drill ice cores out of the ice sheet to study the climate of the past, Christof and his colleagues use cores from of the seabed.

The different layers in the cores are full of microfossils and organic material that can reveal what the oceans were like in the past.

But in order to use the knowledge stored in the cores pulled from the seabed, the researchers need to know when the layers were formed. And this is where carbon-14 enters the picture.

"The problem is that we don't know the natural level of carbon-14 everywhere in the ocean. We don’t have a zero point like we do in the atmosphere. When we try to date a layer of sediment, we’re often off by several hundred years. We need material of a known age from the time before the major human disturbances. I’ve spent a long time thinking about how we could solve the carbon problem for the ocean in parts of the Arctic,” says Christof Pearce and continues:

“When I was working in Stockholm, I walked past some display cases that line the hallways of the university. They’re all about the old polar expeditions. That’s when it hit me, samples from before the nuclear tests might still exist that I could examine.”

Samples from Danish and Swedish expeditions

Christof Pearce then set out to find out whether samples from the old expeditions had been preserved. If they were preserved, he looked into whether he could use them. He quickly discovered that both Denmark and Sweden had samples from their polar expeditions preserved in museum collections. 

One of the old expeditions he looked at set sail from Copenhagen almost 100 years ago. It was called the Godthaab expedition, and even though it is one of the lesser known expeditions, the researchers on it brought back plenty of valuable knowledge. This knowledge is now a goldmine for researchers like Christof Pearce.

“The expedition sailed between Greenland and Canada. It measured the salinity and temperature of the water, measured depth, took bottom samples and collected mussels. A huge endeavour.

“Fortunately, samples and records from that time are still in the storage rooms at the Zoological Museum in Copenhagen. And as luck would have it, we were allowed to take some of the samples back with us. This allowed us to test the carbon-14 levels in the ocean before the nuclear tests.”

The Swedish Museum of Natural History in Stockholm also allowed the research team to take samples from old polar expeditions.

A foul-smelling job

Christof Pearce and his colleagues brought back almost 100 samples to their laboratory. 

However, only mussels and snails with soft tissue left in them could be used. And preparing them for analysis wasn’t a job for people with a delicate sense of smell. 

"We fished half-rotten mussels and snails out of the old glass bottles. It smelled awful but we had to get them out and dry them before they could be used. Once the samples were ready they were carried to the Department of Physics and Astronomy, where the only laboratory in Denmark that can carry out carbon-14 dating is situated.”

Then the researchers waited in anticipation for the results, fingers crossed that the samples would be good enough.

A more precise C14-dating

Luckily, the samples were good, and once the results started ticking in, Christof Pearce could see that they would have enough data to date more accurately material from around Greenland.

“And not only that, we now know much more about local variations. The concentration of carbon-14 in the ocean is affected by ocean currents. The lowest values were found around Baffin Bay, between Canada and Greenland, where the influence of the Arctic Ocean is strongest. Low values were also found in areas with a lot of sea ice, which acts as a barrier between the atmosphere and ocean,” says Christof Pearce.

He explains that the new calculations will make researching the ocean climate of the past more accurate. This knowledge is crucial if we are to predict how climate change will affect oceans in the future.

"In order to calculate what will happen to Arctic waters in the future, we need to know how the ocean has evolved over the past several thousand years. And we now have a tool to help us to do this more accurately,” he says and continues:

“Furthermore, I think we’ve shown how important it is to preserve the samples in old museum collections. They may not be of great value today, but you never know, they might be important in the future, just like the 100-year-old mollusks suddenly became important to us.”

Two students help Christof Pearce go through the archives of the Zoological Museum in Copenhagen in search for samples from old polar expeditions. Luckily the archives hold almost everything that was collected on the expeditions. 

The shelves in the museum archive are filled with samples from previous expeditions. Finding the right ones takes time.

Here is some of the samples used for recalibrating the carbon14-levels in the ocean near Greenland. 

Christof Pearce is removing old mussels from the sealed glasses. Even though the liquid in the glasses kills the bacteria, some of the soft tissue was in the snails and mussels was rotten. Opening the glasses were therefore a smelly procedure.

CREDIT

Christof Pearce

 

Uncovering the 150-year history of Japanese beer barley breeding


Researchers use DNA technology to pinpoint traces of breeding efforts inscribed in the genomes of modern elite Japanese barley cultivars


Peer-Reviewed Publication

OKAYAMA UNIVERSITY

Symptoms of barley yellow mosaic virus disease in susceptible and resistant accessions 

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A: CLOSE-UP IMAGES OF A SINGLE BARLEY LEAF. A-1: YELLOW MOSAIC VIRUS-INFESTED LEAF SHOWING APPARENTLY YELLOWISH MOSAIC SYMPTOM, A-2: RESISTANT ACCESSION HAS A GREEN AND HEALTHY LEAF. B: WHOLE PLANT IMAGES. B-1: HEAVILY INFESTED ACCESSION SHOWS SEVERE YELLOWING AND WITHERING—THE CORRESPONDING YIELD AND QUALITY DETERIORATE. B-2: RESISTANT CULTIVAR WITH HEALTHY GREEN LEAVES.

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CREDIT: PROFESSOR SHIN TAKETA FROM OKAYAMA UNIVERSITY




Barley is a staple crop with several applications, acting as a source of food, livestock feed, and an ingredient for malt brewing. Originally disseminated from China and the Korean Peninsula about 2,000 years ago, all Japanese barley cultivars were six-row for human food until the 1880s. After the cultural enlightenment of the Meiji period, Japan needed to initiate its own domestic brewery. To supply raw materials for emerging beer industries, two-row beer barley cultivars were introduced from the West as genetic resources. Breeding of new beer barley cultivars was initiated to adapt to harsh climate and endemic diseases in Japan.
Lately, barley yellow mosaic virus (BaYMV) has devastated barley crops in Japan. Most Japanese six-row barley cultivars are either resistant or moderately resistant to BaYMV. Unfortunately, the newly introduced Western two-row cultivars are highly susceptible to this disease.
Genes that confer resistance to BaYMV, such as resistance to yellow mosaic 5 (rym5) and rym3, have been routinely used to breed BaYMV-resistant barley cultivars. Such cultivars are also economically suitable for farming and have acceptable malting qualities. However, concerns arose that intensive breeding of BaYMV-resistant two-row malting barley cultivars may have reduced their genetic diversity.
To assess the diversity of two closely related modern Japanese malting barley cultivars, ‘Sukai Golden’ and ‘Sachiho Golden,’ Professor Shin Taketa from the Institute of Plant Science and Resources, Okayama University, and Dr. Keiichi Mochida from RIKEN Center for Sustainable Resource Science, along with Professor Shunsuke Yajima from the NODAI Genome Research Center, Tokyo University of Agriculture, Dr. Hidekazu Takahashi from the Food and Agricultural Sciences, Fukushima University, and Dr. Toshinori Sotome from the Tochigi Prefectural Agricultural Experiment Station, analyzed gene expression and single-nucleotide polymorphisms (SNPs) by sequencing RNAs from 20-day-old immature seeds. The results of their study were published online in Breeding Science on October 28, 2023.
RNA sequencing is an effective method to quickly obtain complete gene expression profiles and genome-wide data on SNPs, which are single-base variants in DNA that can sometimes be the reason for differences in disease susceptibility between populations.
Their analyses showed that these two Japanese cultivars possessed unique and contrasting features related to malting quality and BaYMV resistance gene(s). Notably, the researchers detected 2,419 Sukai Golden-specific and 3,058 Sachiho Golden-specific SNPs—a high SNP number compared to the genome sequences of two reference cultivars.
Discussing their findings, Prof. Taketa adds, “This study detected key traces of Japanese barley improvement inscribed in the genomes of two high-quality modern cultivars. Japanese beer barley breeding began around 150 years ago by introducing Western high-quality beer barley. The hot and humid Japanese climate and soil-transmitting virus diseases hampered the development of beer barley suited for Japan. Western beer barley cultivars inevitably required crossed with virus-disease-resistant East Asian barley, despite the latter having undesirable brewing quality characteristics. Balancing virus disease resistance and malting quality was extremely difficult. ” 
Two SNP clusters were detected in ‘Sukai Golden’ showing the incorporation of the BaYMV resistance gene rym5 on the long arm of 3H and the anthocyanin-less ant2 gene on the long arm of 2H, respectively.
Similarly, the resistance gene rym3 from ‘Haganemugi’ was mapped to the proximal region of 5H. Haplotype analysis of progenitors of the two modern malting cultivars revealed that this particular rym3 gene received independent introduction into ‘Sukai Golden’ and ‘Sachiho Golden.’
This study of the immature seed transcriptomes of two elite Japanese malting barley cultivars could provide important insights into improving seed quality and resistance to BaYMV. Accordingly, Prof. Taketa concludes, “We know that repeated crossing and rigorous selection of the barley cultivars allowed for adaptation to the harsh Japanese agricultural environment. In this way, high-quality modern Japanese beer barley cultivars were developed over the past 150 years and are still evolving for the future, thanks to the strenuous efforts of both public and private breeders.”  
In summary, this study emphasizes the pivotal role of barley research in proposing long-term effective measures for preventing the barley resistance genes from becoming ineffective against variant virus strains. Plant geneticists should devise effective strategies for the durable use of limited virus resistance gene sources.

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 Professor Shin Taketa from Okayama University, Japan
Professor Shin Taketa, affiliated with the Institute of Plant Science and Resources at Okayama University, obtained his Ph.D. from Kyoto University in 1992. Prof. Taketa’s research interests include plant genetics and genomics, agriculture science, morphology, and seed quality. He is a member of the Japanese Society of Plant Physiology and the Japanese Society of Breeding. He has authored over 100 research articles in national and international publications of repute. 
 

 

Breakthrough in the development of a drug for sleeping sickness


A novel way to attack the trypanosome parasite through its ribosome prevents the parasite from producing essential proteins, thus impairing its ability to survive


Peer-Reviewed Publication

BAR-ILAN UNIVERSITY




Trypanosome is a single-celled parasite that takes an extensive human and economic toll due to its involvement in causing sleeping sickness in humans and a similar disease in cattle. The parasite, found mainly in rural areas of Africa, is transmitted to humans or cattle by the tsetse fly. There is no vaccine for the disease, and current treatments are difficult and ineffective due to the resistance of the parasites to existing drugs.

 

Advanced research by Prof. Shulamit Michaeli from the Goodman Faculty of Life Sciences at Bar-Ilan University, recently published in the journal Nature Communications, offers a new strategy for combating the disease. The research was conducted in collaboration with scientists from the group of Nobel Prize laureate Prof. Ada Yonath, of the Weizmann Institute of Science, a world-renowned expert on the spatial structure of the ribosome.

 

The new approach is based on damaging the ribosome of the trypanosome. The ribosome functions in all living cells as a factory for the production of proteins and it is comprised of very long chains of RNA and many diverse proteins. Damaging production of the proteins in the parasite causes a delay in its growth and thus its death.

 

In the RNA of the parasite's ribosome there are dozens of chemical changes (modifications) that are created by small RNA molecules found in the area of the cell nucleus where ribosomes are produced. One of these modifications, known as pseudouridine, stabilizes RNA molecules, including the ribosomal RNA. That is, in the absence of even a single specific pseudouridine, the parasite cannot multiply and cause the disease in a person or animal infected with it. Interestingly, pseudouridine plays a central role in the composition of the artificially coded RNA that the coronavirus vaccine contains.

 

The researchers in Prof. Michaeli's group showed that the deletion of just one pseudouridine from the ribosome of the parasite causes the loss of a structural protein in the ribosome, thereby impairing its ability to produce several specific proteins as well as inhibiting its growth. The findings of the study show that in the future it will be possible to design RNA-based drugs that will specifically damage the ribosome of the parasite (and not that of the human or cattle host) and thus stop its growth and the development of the disease. The future drug will be aimed at damaging the specific site on the ribosome where the essential pseudouridine is located.

 

Another innovation in the research is related to the role of pseudouridine in dealing with the very different growth temperature between the two hosts: the tsetse fly, whose body temperature is 260C, and the human host, whose body temperature is 370C. Chemical modifications stabilize the ribosome at elevated temperatures and give it the ability to function at a difference of 110C during the transmission from fly to human. The set of modifications changes during transmission, and this is what allows the parasite's ribosome to function in the two different hosts. Damage to these modifications negates the ability of the parasite's ribosome to survive the heat differences between the tsetse fly and the human body.

 

Deletion of the pseudouridine deprives the parasite of both its ability to develop and its ability to survive the transmission from the body of a fly to the body of a mammal. These findings form the basis for the development of a drug that can solve the difficult medical problems caused by the trypanosome parasite and parasites of the same family, such as the Leishmania parasite that causes the Rose of Jericho disease, which has also appeared in Israel.

 

"This development is exciting because it connects between the role of a single modification to the ribosome structure and its function in producing new proteins" says Prof. Michaeli.

 

The research was carried out by Dr. Rajan Shanmugha, a former doctoral student in Prof. Michaeli's laboratory, in collaboration with Dr. Anat Bashan, a senior staff scientist in Prof. Yonath's laboratory, together with several students and researchers in both laboratories. Prof. Toshiaki Isube from Tokyo Metropolitan University, Prof. Ron Unger and his group from the Goodman Faculty of Life Sciences at Bar-Ilan University, as well as Prof. Schraga Schwartz from the Weizmann Institute of Science.

 

The study of the biochemical aspects of this research was funded by a grant from the Israel National Science Foundation

SPAGYRIC HERBALISM

Medicinal plants, phytomedicines and traditional herbal remedies for drug discovery and development against COVID-19


Book Announcement

BENTHAM SCIENCE PUBLISHERS




Medicinal Plants, Phytomedicines and Traditional Herbal Remedies for Drug Discovery and Development against COVID-19, edited by Editor: Mithun Rudrapal & Chukwuebuka Egbuna

This extensive resource examines traditional herbal therapies, phytomedicines, and medicinal plants as possible sources for COVID-19 prevention and treatment. It includes nine chapters written and edited by well-known professionals. The book offers insights into treating SARS-CoV-2 infections and respiratory problems, and it notably highlights the prospective drug discovery opportunities based on bioactive components from medicinal plants and herbal remedies.

The work examines the enormous potential of phytomedicine, medicinal plants, and conventional treatments against COVID-19, providing insight into novel directions for drug discovery.  Each chapter current information on the application of herbal remedies, medicinal plants, and conventional pharmaceuticals in the fight against COVID-19.
 SARS-CoV-2 outbreaks. Novel approaches to drug repurposing for COVID-19 drug development by utilizing databases of phytochemicals and bioactive molecules produced from phytomedicine are discussed.

The book includes a list of references for advanced readers and a reader-friendly introduction to each topic. A wide spectrum of readers, including postgraduate researchers and pharmaceutical R&D specialists, who are interested in COVID-19 control techniques will find this timely reference to be a helpful resource. In addition, it functions as a guide for practitioners of clinical and herbal medicine.

Learn more about this book here: https://www.eurekaselect.com/ebook_volume/3607

For media inquiries, review copies, or interviews, please contact, Bentham Science Publishers.


DOI
10.2174/97898150495101230101

 

Chilean researchers pledge for transformative change to tackle climate action


Peer-Reviewed Publication

IOP PUBLISHING

Evening panorama of Santiago de Chile 

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EVENING PANORAMA OF SANTIAGO DE CHILE

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CREDIT: IOP PUBLISHING




Addressing climate change has become a central issue in Chile’s public policy. As part of that debate, Dr. Maisa Rojas, researcher in Atmospheric Physics, who currently serves as Chilean Minister for Environment and Marco Billi of the Centre for Climate and Resilience Research, Universidad de Chile, propose a new model of governance at the country level to facilitate the changes needed. The proposal – written before Dr. Rojas’ appointment to the Chilean government – is published in IOP Publishing’s journal Environmental Research Letters.  

The model proposed places climate action as the basis of a new social and ecological order coherent with carbon-neutral, resilient development and social justice. It looks though the lens of climate change at the relationship a society has to all the elements of nature, embedding it in all institutions in charge of economic development, social welfare, and environmental management. 

Billi says: “Chile is under increasing climate stress, with more frequent storms, heat waves, forest fires and human-caused water shortages. These are closely connected issues; changes in land use affect water availability, while climate change accelerates fires, releasing greenhouse gases and pollution. Tackling these problems requires the recognition that the climate change and biodiversity crises are unified and that the solutions to one must not worsen the other.” 

The effects of climate change are most profound in vulnerable and marginalised groups. Inequality is a key driver of environmental conflicts and social unrest, increased by the weakness of participation mechanisms, leaving local and indigenous communities unprotected against the power of large corporations. 

Billi adds: “In the face of current challenges, there is an urgent need for a new model of governance, which should favour a transformative change in the way in which our society relates to nature and manages climate change and its risks.” 

 

One small material, one giant leap for life on Mars: Sussex research takes us a step closer to sustaining human life on the red planet


Using ‘waste’ product from recent NASA research, scientists create transformative nanomaterials with potential for clean energy production


Peer-Reviewed Publication

UNIVERSITY OF SUSSEX

Processes involved in transforming gypsum to nano belts 

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TWO RAW ROCKS USED BY THE RESEARCHERS (LEFT). VIALS SHOW THE NANOBELTS IN WATER, WITH A CLOSE UP OF THE ACTUAL NANOBELTS (RIGHT).

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CREDIT: UNIVERSITY OF SUSSEX




  • A mineral found on the surface of Mars offers potential to create sustainable energy 
  • Uses ‘waste’ product from recent NASA research to create transformative nanomaterials
  • Findings could play role in shaping sustainable habitation on the red planet – and clean energy production back home

Researchers at the University of Sussex have discovered the transformative potential of Martian nanomaterials, potentially opening the door to sustainable habitation on the red planet. 

Using resources and techniques currently applied on the International Space Station and by NASA, Dr Conor Boland, a Lecturer in Materials Physics at the University of Sussex, led a research group that investigated the potential of nanomaterials – incredibly tiny components thousands of times smaller than a human hair – for clean energy production and building materials on Mars.

Taking what was considered a waste product by NASA and applying only sustainable production methods, including water-based chemistry and low-energy processes, the researchers have successfully identified electrical properties within gypsum nanomaterials - opening the door to potential clean energy and sustainable technology production on Mars.

Dr Conor Boland, said: 

“This study shows that the potential is quite literally out of this world for nanomaterials. Our study builds off recent research performed by NASA and takes what was considered waste, essentially lumps of rock, and turns it into transformative nanomaterials for a range of applications from creating clean hydrogen fuel to developing an electronic device similar to a transistor, to creating an additive to textiles to increase their robustness.

“This opens avenues for sustainable technology – and building – on Mars but also highlights the broader potential for eco-friendly breakthroughs here on Earth.”

To make the breakthrough the researchers used NASA's innovative method for extracting water from Martian gypsum, which is dehydrated by the agency to get water for human consumption. This produces a byproduct called anhydrite—considered waste material by NASA, but now shown to be hugely valuable.

The Sussex researchers processed anhydrite into nanobelts –  essentially tagliatelle-shaped materials – demonstrating their potential to provide clean energy and sustainable electronics. Furthermore, at every step of their process, water could be continuously collected and recycled.

Dr Boland added: 

“We are optimistic of the feasibility of this process on Mars, as it requires only naturally occurring materials – everything we used could, in theory, be replicated on the red planet. Arguably this is the most important goal in making the Martian colony sustainable from the outset.”

While full-scale electronics production may be impractical on Mars due to the lack of clean rooms and sterile conditions, the anhydrite nanobelts hold promise for clean energy production on Earth, and could, later down the line, still have a profound effect on sustainable energy production on Mars. 

 

Can we decode the language of our primate cousins?


A UNIGE team shows that the human brain is capable of identifying the vocalisations of certain primate species, if they are close to us and if the frequencies used are also close to our own.


Peer-Reviewed Publication

UNIVERSITÉ DE GENÈVE




Are we able to differentiate between the vocal emissions of certain primates? A team from the University of Geneva (UNIGE) asked volunteers to categorise the vocalisations of three species of great apes (Hominidae) and humans. During each exposure to these ‘‘onomatopoeia’’, brain activity was measured. Unlike previous studies, the scientists reveal that phylogenetic proximity - or kinship - is not the only factor influencing our ability to identify these sounds. Acoustic proximity - the type of frequencies emitted - is also a determining factor. These results show how the human brain has evolved to process the vocal emissions of some of our closest cousins more efficiently. Find out more in the journal Cerebral Cortex Communications.


Our ability to process verbal language is not based solely on semantics, i.e. the meaning and combination of linguistic units. Other parameters come into play, such as prosody, which includes pauses, accentuation and intonation. Affective bursts - ‘‘Aaaah!’’ or ‘‘Oh!’’ for example - are also part of this, and we share these with our primate cousins. They contribute to the meaning and understanding of our vocal communications.


When such a vocal message is emitted, these sounds are processed by the frontal and orbitofrontal regions of our brain. The function of these two areas is, among other things, to integrate sensory and contextual information leading to a decision. Are they activated in the same way when we are exposed to the emotional vocalisations of our close cousins the chimpanzees, macaques and bonobos? Are we able to differentiate between them?


MRI scans with headphones on

A UNIGE team sought to find out by exposing a group of 25 volunteers to various human and simian vocalisations. ‘‘The participants were placed in an MRI scanner and were given headphones. After a short period of familiarisation with the different types of vocalisations, each participant had to categorise them, i.e. identify to which species they belonged,’’ explains Leonardo Ceravolo, senior lecturer at the UNIGE’s Faculty of Psychology and Educational Sciences, and first author of the study.


These vocalisations were of the affiliative type, i.e. linked to a positive interaction, or of the agonistic type, i.e. linked to a threat or distress. The human vocalisations came from databases recorded by actors. The simian ones came from field recordings made as part of previous research. This study is the first of its kind to include bonobo vocalisations.


Bonobos, not so close cousins

The results show that for macaque and chimpanzee vocalisations, the frontal and orbitofrontal regions of the participants were activated in a similar way to human vocalisations. The participants were able to differentiate between them easily. On the other hand, when confronted with the ‘‘sounds’’ of bonobos, also close cousins of humans, the involved cerebral areas were much less activated, and categorisation was at chance level.


‘‘It was thought that kinship between species - the ‘phylogenetic distance’ - was the main parameter for having the ability, or not, to recognise these different vocalisations. We thought that the closer we were genetically, the more important this ability was,’’ explains Didier Grandjean, full professor at the Swiss Center for Affective Sciences and at the UNIGE’s Faculty of Psychology and Educational Sciences, who led the study. ‘‘Our results show that a second parameter comes into play: acoustic distance. The further the dynamics of the acoustic parameters, such as the frequencies used, are from those of humans, the less certain frontal regions are activated. We then lose the ability to recognise these sounds, even if they are emitted by a close cousin, in this case the bonobo.”


Bonobo calls are very high-pitched and can sound like those of certain birds. This acoustic distance in terms of frequencies, compared with human vocalisations, explains our inability to decode them, despite our close phylogenetic proximity. ‘‘Are we capable of identifying the different emotional aspects of affiliative or agonistic vocalisations emitted by a chimpanzee, a macaque or a bonobo? And if so, how? Thiese questions will be at the heart of our next research, which will involve analysing not our ability to categorise vocalisations by species but to identify their emotional content,’’ concludes Didier Grandjean.