Wednesday, May 21, 2025

How did plants evolve the ability to transport massive amounts of protein into seed vacuoles?

Tracing evolutionary steps through the gradual functional shift of a membrane trafficking protein

National Institutes of Natural Sciences

How VAMP72 evolved into VAMP727 through stepwise changes in plants — image:
This illustration shows how the membrane trafficking protein VAMP72 gradually changed during plant evolution to give rise to VAMP727, which functions in transporting storage proteins to vacuoles. The first step was the acquisition of a short insertion in its structure through alternative splicing. This insertion contained a non-canonical tyrosine-based motif, which enabled a partial shift in localization from the secretory to the vacuolar transport zone within the trans-Golgi network. Later, the insertion became more acidic and acquired a dileucine-like motif, enhancing its interaction with the AP-4 adaptor complex. These stepwise changes allowed VAMP72 to evolve into VAMP727, supporting the development of the efficient vacuolar transport system found in seed plants.
view more
Credit: Takashi Ueda and Masaru Fujimoto

Seed plants, such as soybeans, store large amounts of protein in specialized organelles called protein storage vacuoles. These proteins not only sustain seedling growth but also serve as a major source of dietary protein for humans and livestock. This protein storage function is unique to plant vacuoles and does not occur in other organisms. During evolution, plants developed a dedicated mechanism to transport large quantities of proteins into vacuoles — but how did this transport pathway, which is absent in animals or fungi, come into existence?

In a recent study published in Current Biology, a research team led by Professor Takashi Ueda of the National Institute for Basic Biology and Associate Professor Masaru Fujimoto of the University of Tokyo has revealed the molecular steps that led to the emergence of this plant-specific vacuolar transport system. Their work shows that the acquisition of this pathway was driven by the stepwise neofunctionalization of a membrane fusion protein called VAMP7.

The team discovered that the plant vacuolar transport system arose through a series of molecular innovations: the appearance of an amino acid insertion within the VAMP7 protein, its acidification over time, and the progressive acquisition and strengthening of binding capacity to the AP-4 adaptor protein complex, which is responsible for cargo selection. These modifications enabled the establishment of a vacuolar transport route unique to seed plants.

Plants contain two major types of VAMP7 proteins: VAMP71, which functions in vacuolar membrane fusion, and VAMP72, which is involved in trafficking to the plasma membrane — part of the secretory pathway.

Professor Ueda, who led the study, explains:
“In addition to these, we previously identified a unique VAMP72-like protein, called VAMP727, in seed plants such as Arabidopsis thaliana. Unlike typical VAMP72s, VAMP727 contains an acidic amino acid-rich insertion of about 20 residues in the N-terminal longin domain. This protein is known to function in vacuolar trafficking and is essential for transporting storage proteins into vacuoles during seed development. However, it was unclear when and how VAMP727 and its associated trafficking pathway emerged during evolution, or what molecular mechanisms underpinned this innovation.”

To address this, the team focused on the molecular evolution of VAMP7. By comparing the amino acid sequences and functions of VAMP72 proteins across a wide range of plant species, from green algae to seed plants, they reconstructed the evolutionary trajectory by which VAMP72, originally functioning in secretion, acquired a vacuolar trafficking role. Based on these insights, they investigated how specific changes in the VAMP72 sequence altered its localization, function, and protein-protein interactions within cells.

Associate Professor Fujimoto, first author of the study, explains:
“Our findings suggest that VAMP72 first gained a partially acidic insertion containing a tyrosine-based motif, enabling a partial functional shift. As this insertion became more acidic and formed an acidic dileucine motif, the protein's interaction with the AP-4 complex was strengthened, resulting in the emergence of VAMP727, a vacuole-targeted VAMP. We believe that this two-step functional transition led to the birth of a new vacuolar transport pathway in plants, allowing for the massive accumulation of storage proteins in seed protein storage vacuoles.”

A phylogenetic tree (left) illustrates the major green plant lineages, from chlorophyte algae to angiosperms. Aligned amino acid sequences (right) show the insertion regions in VAMP72 and VAMP727 homologs from representative species. The emergence of key sequence motifs—such as tyrosine-based and acidic dileucine motifs—occurred in a stepwise fashion during evolution, ultimately giving rise to VAMP727.

Credit

Takashi Ueda and Masaru Fujimoto

Super-resolution confocal live imaging microscopy (SCLIM) reveals the subcellular localization of VAMP727 in wild-type and ap4m mutant Arabidopsis root epidermal cells. In wild-type cells (A and B), VAMP727 predominantly localizes to late endosomes, the trans-Golgi network (TGN), and the interface between these compartments. In ap4m mutants lacking a functional AP-4 complex, VAMP727 exhibits a broadened distribution across the TGN and diminished presence in late endosomes (B). These observations indicate that the AP-4 complex plays a critical role in partitioning VAMP727 within the TGN to facilitate its selective incorporation into the vacuolar transport pathway. Scale bars: 1 µm.

Credit

Yutaro Shimizu and Masaru Fujimoto

Journal

Current Biology

DOI

10.1016/j.cub.2025.04.062

Method of Research

Experimental study

Subject of Research

Cells

Article Title

Neofunctionalization of VAMP7 opened up a plant-unique vacuolar transport pathway

Article Publication Date

19-May-2025

Phthalateas

Innovative metal-free method upcycles PET waste into valuable chemicals

The global plastic waste crisis, fueled by the ubiquity of polyethylene terephthalate (PET), has driven the search for more effective recycling solutions.

Nanjing Institute of Environmental Sciences, MEE

Metal-Free Catalytic Upcycling of Waste Plastics into Value-Added Chemicals. — image:
This diagram illustrates the process of upcycling waste plastics, including various polyesters (PET, PEF, PEA, PES, PLA) and polycarbonates (PC, PPC), using ionic liquid catalysts. The method involves the formation of hydrogen bonds between the ionic liquid and reactants, facilitating the transformation of PET into valuable chemicals such as dimethyl terephthalate (DMT) and ethylene carbonate (EC). The process efficiently depolymerizes PET and other plastics, offering a sustainable approach to plastic recycling and contributing to a circular economy.
view more
Credit: Eco-Environment & Health

A new metal-free catalytic method for upcycling polyethylene terephthalate (PET) waste into valuable products has been developed. By utilizing ionic liquids (ILs), researchers have achieved an impressive 99% yield of dimethyl terephthalate (DMT) and 91% yield of ethylene carbonate (EC) within 2.5 hours under mild conditions. This innovative process relies on the formation of hydrogen bonds to activate the reactants, enabling the complete conversion of PET. The method offers a sustainable, efficient alternative to traditional recycling techniques, with significant environmental and economic benefits and potential for large-scale industrial implementation.

The global plastic waste crisis, fueled by the ubiquity of polyethylene terephthalate (PET), has driven the search for more effective recycling solutions. Traditional mechanical recycling methods are often inefficient and degrade material quality over time. Chemical recycling via methanolysis has shown promise, but challenges such as incomplete depolymerization and reliance on metal-based catalysts have limited its potential. Ionic liquid-based catalysis has emerged as a promising alternative, providing a metal-free, efficient way to recycle PET. However, achieving complete depolymerization remains a hurdle. Given these challenges, further research into advanced catalytic systems is essential to unlock the full potential of PET upcycling.

In an exciting new study (DOI: 10.1016/j.eehl.2025.100139), researchers from Zhejiang University have introduced a metal-free catalytic approach for upcycling PET waste. Published in Eco-Environment & Health, the research highlights the use of ionic liquids, specifically [EMIm][OAc], to efficiently catalyze the methanolysis of PET. This novel method enables the complete conversion of PET into valuable chemicals, including dimethyl terephthalate (DMT) and ethylene carbonate (EC) within 2.5 hours. The study addresses significant environmental and economic challenges, marking a major step forward in sustainable recycling technologies.

The study presents an innovative metal-free catalytic system designed to upcycle PET waste into high-value products, such as dimethyl terephthalate (DMT) and ethylene carbonate (EC). The key to the method's success lies in the use of ionic liquids (ILs), particularly [EMIm][OAc], which facilitate the complete depolymerization of PET. Under mild conditions, the process achieves an impressive 99% yield of DMT and 91% of EC. The formation of hydrogen bonds between the ionic liquid and the reactants plays a crucial role in activating both the carbonyl groups of PET and the hydroxyl groups of methanol and ethylene glycol.. These interactions enhance the reaction’s efficiency, leading to the full conversion of PET into valuable chemicals.What sets this method apart is its versatility; it can be applied to various polyesters and polycarbonates, extending its potential beyond just PET. Unlike traditional recycling methods that often require metal catalysts, this approach eliminates the risk of metal contamination, offering a cleaner, more sustainable solution. The method’s ability to achieve high yields while reducing energy consumption and avoiding metal residues positions it as a promising solution in the quest for effective plastic recycling on an industrial scale.

Dr. Qingqing Mei, the lead researcher on the study, expressed, "Our research introduces a transformative solution to the plastic waste dilemma, particularly for PET, one of the most challenging plastics to recycle. By employing a metal-free ionic liquid catalyst, we not only improve the efficiency of PET upcycling but also create a sustainable pathway for managing plastic waste. This method holds immense potential for revolutionizing recycling technologies, contributing to a circular economy by turning plastic waste into valuable raw materials that can be reused in manufacturing."

The implications of this research are profound for the recycling industry. This new metal-free method for upcycling PET into high-value chemicals like DMT and EC represents a significant leap forward in sustainable recycling practices. By offering a cleaner, more efficient alternative to traditional methods, it could dramatically reduce the environmental footprint of PET waste, a major contributor to global pollution. Additionally, the method's applicability to various polyesters and polycarbonates broadens its impact, positioning it as a key player in the push for industrial-scale recycling. This development offers a promising route towards a more circular economy, where plastic waste is continuously recycled into valuable materials.

###

References

DOI

10.1016/j.eehl.2025.100139

Original Source URL

https://doi.org/10.1016/j.eehl.2025.100139

Funding information

This work was supported by National Natural Science Foundation of China (22376183, 22209146), Key Research and Development Program of Zhejiang Province (2024C03112), the Fundamental Research Funds for the Central Universities (226-2023-00077), and Postdoctoral Fellowship Program of CPSF (GZC20232274).

About Eco-Environment & Health

Eco-Environment & Health (EEH) is an international and multidisciplinary peer-reviewed journal designed for publications on the frontiers of the ecology, environment and health as well as their related disciplines. EEH focuses on the concept of "One Health" to promote green and sustainable development, dealing with the interactions among ecology, environment and health, and the underlying mechanisms and interventions. Our mission is to be one of the most important flagship journals in the field of environmental health.

Journal

Eco-Environment & Health

DOI

10.1016/j.eehl.2025.100139

Subject of Research

Not applicable

Article Title

Targeted conversion of waste PET into dimethyl terephthalate and ethylene carbonate under metal-free conditions

How to swim without a brain

Many microorganisms can move in a goal oriented way in liquids. How do they do this without a complex nervous system? Research conducted at TU Wien provides explanations

Vienna University of Technology

Cartoon — image:
Artist's impression of a tiny swimming creature: The body is modelled as a chain with several mass points in the computer simulation.
view more
Credit: TU Wien

Bacteria can do it, amoebas can do it, even blood cells can do it: they all have the ability to move in a goal oriented way in liquids. And they do so despite having extremely simple structures without a central control system (such as a brain). How can this be explained? A team from TU Wien, the University of Vienna and Tufts University (USA) simulated this type of movement on a computer and was able to show that swimming movements are possible even without a central control unit. This not only explains the behaviour of microorganisms, it could also enable nanobots to move in a targeted manner, for example to transport drugs to the right place in the body.

Success even without a central control system

“Simple microorganisms can be imagined as being composed of several parts, a bit like a string of pearls,” says Benedikt Hartl from the Institute of Theoretical Physics at TU Wien and the Allen Discovery Center at Tufts University, lead author of the current publication. "The individual parts can move relative to each other. We wanted to know: under what circumstances does this result in a movement that causes the entire organism to move in a desired direction?"

This is relatively simple if there is a central control system – something like a brain or at least a nerve centre. Such a centre can issue specific commands to the individual parts. It is easy to understand how this can result in coordinated movement.

But a single-celled organism naturally has no nerve cells, no central processing system that could issue commands. How is it possible in this case for a coordinated swimming movement to arise? If the individual parts of the microorganism all behave according to very simple rules, can this result in collective behaviour that leads to efficient swimming?

Microorganisms simulated on a computer

This question was investigated using computer simulations: the microorganisms were modelled as chains of interconnected beads . Each of these beads can exert a force to the left or right, but each bead only knows the position of its immediate neighbours. There is no knowledge of the overall state of the organism or of beads further away.

“The crucial question now is: Is there a control system, a set of simple rules, a behavioural strategy that each bead can follow individually so that a collective swimming motion emerges – without any central control unit?” says Benedikt Hartl.

On the computer, the individual beads – the simulated parts of the virtual microorganism – were equipped with a very simple form of artificial intelligence, a tiny neural network with only 20 to 50 parameters, explains Hartl: "The term neural network is perhaps somewhat misleading in this context; of course, a single-celled organism has no neurons. But such simple control systems can be implemented within a cell, for example, by means of very simple physical-chemical circuits that cause a specific area of the microorganism to perform a specific movement."

This simple decentralized control system has now been adapted to the computer in search of the most efficient ‘control code’ possible that produces the best swimming behaviour. With each version of this control system, the virtual microorganism was allowed to swim in a simulated viscous fluid.

“We were able to show that this extremely simple approach is sufficient to produce highly robust swimming behaviour,” says Benedikt Hartl. “Although our system has no central control and each segment of the virtual microorganism behaves according to very simple rules, the overall result is complex behaviour that is sufficient for efficient locomotion.”

Biology and technology

This result is not only interesting because it explains the complex behaviour of very simple biological systems, it could also be interesting for artificially produced nanobots: “This means that it would also be possible to create artificial structures that could perform complex tasks with very simple programming,” says Andreas Zöttl (University of Vienna). “It would be conceivable, for example, to build nanobots that actively search for oil pollution in water and help to remove it. Or even medical nanobots that move autonomously to specific locations in the body to release a drug in a targeted manner.”

Journal

Communications Physics

DOI

10.1038/s42005-025-02101-5

Method of Research

Computational simulation/modeling

Subject of Research

Not applicable

Article Title

Neuroevolution of decentralized decision-making in -bead swimmers leads to scalable and robust collective locomotion

Article Publication Date

18-May-2025

Study links dementia care gaps in Quebec to socio-economic status

McGill research informs policy-makers’ plan to make dementia care more equitable

McGill University

A new study has found stark differences in the dementia care received by people in richer and poorer neighbourhoods in Quebec, despite the universal health-care system.

The research was led by Dr. Claire Godard-Sebillotte, a Professor in McGill University’s Division of Geriatrics and a researcher at the Research Institute of the McGill University Health Centre. It is the first large-scale study in Quebec to track how social conditions relate to dementia care.

The study analyzed health records from about 200,000 people newly diagnosed with dementia between 2000 and 2017. Each patient was followed for a year or until their death or admission to a long-term care facility, whichever occurred first.  To measure socio-economic status, the researchers used a standard material deprivation index, which ranks neighbourhoods based on income, education and employment levels.

People in the most deprived areas were more likely than people in the least deprived areas to be hospitalized, visit the emergency room, receive potentially inappropriate medications and die within a year of diagnosis. Meanwhile, people in wealthier neighbourhoods had more visits to cognition specialists.

Health-care disparities in context

Due to lifelong disadvantages, people in poorer areas may be in worse health by the time they’re diagnosed with dementia, which could partly explain why they rely more on hospitals and die more within the year of diagnosis. However, this raises questions about equity within our universal healthcare system, said Godard-Sebillotte.

“The persistence of these patterns over nearly two decades of data is concerning," she said. "Access to care needs to be adapted to people’s needs. Equity isn’t about treating everyone the same, it’s about making sure each person gets the right care for their situation."

People in poorer neighborhoods were more likely to be prescribed medications such as antipsychotics or benzodiazepines, which can increase the risk of falls and confusion. They were also less likely to see cognition specialists.

“This result suggests inequity. Indeed, if people in poorer neighborhoods consistently had more complex health needs, requiring these potentially inappropriate medications, they should be referred more to cognition specialists. It’s possible that people in these areas are actually not more complex but have less access to home care or other supports for caregivers to help manage difficult behaviours or symptoms, so doctors may turn to medications more often,” she said.

Using data to drive change

As one of the directors of the Research on Organization of Healthcare Services for Alzheimer’s team, Godard-Sebillotte and her colleagues work closely with Quebec’s health minister to share their findings and support evidence-based decision-making.

The study’s insights informed the Quebec Policy on Alzheimer's Disease and Other Neurocognitive Disorders which, contrary to most policies internationally, includes a standalone objective to reduce inequities in dementia care.

Next, the research team plans to examine how racialization, language and living in rural areas intersect with poverty to shape people’s access to care.

About the study

“Examining equity in service use across socioeconomic status in people with dementia” by Claire Godard-Sebillotte and Isabelle Vedel et al., was published in Alzheimer’s & Dementia: Behavior & Socioeconomics of Aging.

This study was supported by the Canadian Consortium on Neurodegeneration in Aging.

Journal

Alzheimer s & Dementia Behavior & Socioeconomics of Aging

DOI

10.1002/bsa3.70006

Method of Research

Data/statistical analysis

Subject of Research

People

Article Title

Examining equity in service use across socioeconomic status in people with dementia

FORWARD TO THE PAST

Clay can help make for tomorrow’s environmentally friendly quantum technologies

A naturally occurring clay material with sought-after properties can be used in quantum technology,

Norwegian University of Science and Technology

image:
Barbara Pacáková and Jon Otto Fossum are part of an international research group that has come up with very interesting results which can help us on the path to new technology. This photo is from SNBL-ESRF Grenoble France.
view more
Credit: Photo: NTNU/SNBL-ESRF

In the future, quantum technology will become the standard for extremely fast computers. These kinds of machines will be important in everything from space technology to mineral exploration and the development of new medicines.

“Quantum technology is often associated with synthetic materials that have been developed in advanced, completely clean environments,” says Professor Jon Otto Fossum from the Norwegian University of Science and Technology (NTNU’s) Department of Physics.

But Fossum and colleagues have good news.

A promising material

“We have found a naturally occurring clay material with sought-after properties for use in quantum technology,” says Fossum.

The material is thus both cheap and easily available, straight from nature.

“What we found is essentially a quantum‑active component formed by nature. It is stable, non‑toxic, abundant, and appears in a structure that is already usable—especially exciting in the context of sustainable materials,” says Barbara Pacáková, a researcher at NTNU’s Department of Physics at NTNU.

Three good things at once. And the material is also environmentally friendly.

She is the first author of a paper that has now been published in the Nature journal npj 2D Materials and Applications.

Three things at once

So why is this so promising? Well, the clay material is practically two-dimensional, and in this case, is a semiconductor and is antiferromagnetic. And what does that mean?

Two-dimensional fabrics are fundamentally important when everything is at extremely small scale. Quantum technology is technology at the atomic level and below.
Semiconductors are substances that are good at conducting electricity under some conditions, but are not good at conducting electricity under others. They are widely used in electronics and photonics.
Antiferromagnetic substances are not magnetic in the traditional sense, but they are magnetic nonetheless. They are magnetic in two directions at the same time, and thus they cancel each other out. If you can influence this magnetism, it is useful, yes, really central, in quantum technology.

Three good things at once, in other words. And the material is also environmentally friendly.

A quantum leap in clay

The researchers have called it “a quantum leap in clay”. A quantum leap is technically a very small leap, even though it is used in everyday speech to mean great progress. In this context, it is both.

But even though the material is found in nature, it will still have to be made useful in high-tech environments. It is not just a matter of shovelling the clay directly out of the ground and then using it in quantum computers or in photonics.

“Advanced methods are still needed to extract the material, examine it and find out how it can be used in technology,” says Pacáková.

To study these thin clay layers, researchers have to use specialized equipment in laboratories that is accurate and reliable.

And if the material is going to be used in new products one day, it may still be necessary to have a very clean and controlled environment, such as in a laboratory cleanroom.

Not perfect at room temperature

“The material is also not antiferromagnetic at room temperature. But its characteristics suggest that the material may have an impact on the technology of the future, such as in spintronics, photonics, magnetic sensors and computers that mimic the human brain,” says Fossum.

We don’t just look for flawless materials created in laboratories, but look for natural materials that can also be used.

Fossum heads the Soft and Complex Matter Lab at NTNU, where much of the work on the new material has been carried out.

“Our laboratory has a special approach. We don’t just look for flawless materials created in laboratories, but look for natural materials that can also be used. This allowed us to identify this material,” says Fossum.

International cooperation

The findings are the result of an international partnership led by the Norwegian University of Science and Technology (NTNU), in close collaboration with physicists at the Universidade de São Paulo (USP) in Brazil, the European Synchrotron Radiation Facility (ESRF) in Grenoble, France, and Univerzita Karlova in Prague, Czech Republic. www.softcomlab.com

The NTNU team consists of six researchers. Four are women who are early in their careers. Fossum and Pacáková say these results show the importance of supporting up-and-coming researchers through mentor programmes such as NTNU offers

“Not only are these exciting, scientific results. It shows what talented researchers can achieve early on when they are only given the opportunity,” Fossum and Pacáková said.

Reference: Pacakova, B., Lahtinen-Dahl, B., Kirch, A. et al. Naturally occurring 2D semiconductor with antiferromagnetic ground state. npj 2D Mater Appl 9, 38 (2025). https://doi.org/10.1038/s41699-025-00561-5

Journal

npj 2D Materials and Applications

DOI

10.1038/s41699-025-00561-5

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Naturally occurring 2D semiconductor with antiferromagnetic ground state

Article Publication Date

19-May-2025