Wednesday, June 07, 2023

Remnants of ancient virus may fuel ALS in people

Study identifies promising new target for treating underlying cause of the fatal disease

UNIVERSITY OF COLORADO AT BOULDER

More than 5,000 people are diagnosed annually with ALS (amyotrophic lateral sclerosis), a fatal, neurodegenerative disease that attacks nerve cells in the brain and spinal cord, gradually robbing people of the ability to speak, move, eat and breathe.

To date, only a handful of drugs exist to moderately slow its progression. There is no cure.

But CU Boulder researchers have identified a surprising new player in the disease—an ancient, virus-like protein best known, paradoxically, for its essential role in enabling placental development.

The findings were recently published in the journal eLife.

“Our work suggests that when this strange protein known as PEG10 is present at high levels in nerve tissue, it changes cell behavior in ways that contribute to ALS,” said senior author Alexandra Whiteley, assistant professor in the Department of Biochemistry.

With funding from the ALS Association and the National Institutes of Health, and Venture Partners, her lab is now working to understand the molecular pathways involved and to find a way of inhibiting the rogue protein.

“It is early days still, but the hope is this could potentially lead to an entirely new class of potential therapeutics to get at the root cause of this disease.”

Ancient viruses with modern-day impact

Mounting research suggests about half the human genome is made up of bits of DNA left behind by viruses (known as retroviruses) and similar virus-like parasites, known as transposons, which infected our primate ancestors 30-50 million years ago. Some, like HIV, are well known for their ability to infect new cells and cause disease.

Others, like wolves who have lost their fangs, have become domesticated over time, losing their ability to replicate while continuing to pass from generation to generation, shaping human evolution and health.

PEG10, or Paternally Expressed Gene 10, is one such “domesticated retrotransposon.” Studies show it likely played a key role in enabling mammals to develop placentas—a critical step in human evolution.

But like a viral Jekyll and Hyde, when it’s overly abundant in the wrong places, it may also fuel disease, including certain cancers and another rare neurological disorder called Angelman’s syndrome, studies suggest.

Whiteley’s research is the first to link the virus-like protein to ALS, showing that PEG10 is present in high levels in the spinal cord tissue of ALS patients where it likely interferes with the machinery enabling brain and nerve cells to communicate.

“It appears that PEG10 accumulation is a hallmark of ALS,” said Whiteley, who has already secured a patent for PEG10 as a biomarker, or way of diagnosing, the disease.

Too much protein in the wrong places

Whiteley did not set out to study ALS, or ancient viruses.

Instead, she studies how cells get rid of extra protein, as too much of the typically good thing has been implicated in other neurodegenerative diseases, including Alzheimer’s and Parkinson’s.

Her lab is one of a half-dozen in the world to study a class of genes called ubiquilins, which serve to keep problem proteins from accumulating in cells.

In 2011, a study linked a mutation in the ubiquilin-2 gene (UBQLN2) to some cases of familial ALS, which makes up about 10% of ALS cases. The other 90% are sporadic, meaning they are not believed to be inherited.

But it has remained unclear how the faulty gene might fuel the deadly disease.

Using laboratory techniques and animal models, Whiteley and colleagues at Harvard Medical School first set out to determine which proteins pile up when the UBQLN2 misfires and fails to put the brakes on. Among thousands of possible proteins, PEG10 topped the list.

Then Whiteley and her colleagues collected the spinal tissue of deceased ALS patients (provided by the medical research foundation Target ALS) and used protein analysis, or proteomics, to see which if any seemed overexpressed.

Again, among more than 7,000 possible proteins, PEG10 was in the top five.

In a separate experiment, the team found that with the ubiquilin brakes essentially broken, the PEG10 protein piles up and disrupts the development of axons—the cords which carry electrical signals from the brain to the body.

PEG10 was overexpressed in the tissue of individuals with both sporadic and familial ALS, the study found, meaning the virus-like protein may be playing a key role in both.

“The fact that PEG10 is likely contributing to this disease means we may have a new target for treating ALS,” she said. “For a terrible disease in which there are no effective therapeutics that lengthen lifespan more than a couple of months, that could be huge.”

The research could also lead to a better understanding of other diseases, which result from protein accumulation as well as keener insight into how ancient viruses influence health.

In this case, Whiteley said, the so-called “domesticated” virus could a be rearing its fangs again.

“Domesticated is a relative term, as these virus-like activities may be a driver of neurodegenerative disease,” she said. “And in this case, what is good for the placenta may be bad for neural tissue.”

JOURNAL

eLife

DOI

10.7554/eLife.79452

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Cells

ARTICLE TITLE

UBQLN2 restrains the domesticated retrotransposon PEG10 to maintain neuronal health in ALS

Motor skills and physical activity practice supports preschoolers’ learning

A doctoral thesis has demonstrated that motor skills and physical activity practice can support the cognitive and early academic skills of preschoolers.

Reports and Proceedings

UNIVERSITY OF HELSINKI

A doctoral thesis has demonstrated that motor skills and physical activity practice can support the cognitive and early academic skills of preschoolers, particularly when the activities include motor skills practice, or when motor skills or physical activity practice is combined with the subject to be learnt.

In recent years, concerns have been raised about children and adolescents being less physically active and having weaker motor skills than previous generations. A further cause of concern is the decline of for instance mathematical and language skills, with an increasing number of children in schools and kindergartens needing support in their learning. Prior research has shown that physical inactivity is a new risk factor for skills development.

Doctoral Researcher Pinja Jylänki from the University of Helsinki investigated whether physical activity and motor skills practice can support the development of cognitive and early academic skills in children of preschool age.

Physical activity or motor skills practice should be combined with the subject taught

In systematic reviews included in her doctoral thesis, Jylänki examined a total of 57 previously completed studies on the topic. Roughly 70% of these studies had demonstrated that motor skill and physical activity interventions have positive effects on preschoolers’ cognitive and early academic skills.

Effects had been observed particularly in children’s memory and executive function as well as language and early numeracy skills. The most marked effects were seen as a result of motor skills practice, or when motor skills or physical activity practice was combined with the topic being taught.

“The findings support the idea that practising one skill, motor skills in this case, supports the learning of another skill, that is, early academic or cognitive skills, more than a quantitative increase of physical activity alone,” Jylänki says.

Based on the prior research, it is also advisable to combine the practice of different skills, as such combination was found to be more effective compared to practising motor skills or physical activity exclusively.

However, the field is relatively new, and further research of a high standard is needed to verify the results.

Intervention programme narrowed down learning differences in early numeracy skills

In her doctoral thesis, Jylänki and her colleagues developed an intervention programme called Movement with Early Numeracy. This programme for practising motor and early numeracy skills is designed for Finnish early childhood education. It supports children with challenges in early numeracy skills.

Movement with Early Numeracy combines the practice of numerical concepts with motor skills practice. Concepts describing numerical relational skills, such as ‘more’, ‘less’ or ‘half’ and ‘whole’, were first practised in a story read for children, after which the same concepts were incorporated into motor skills training. The effects of practice were observed in 36 children.

According to the study, the effects were positive, and a delayed measurement showed that the effects remained approximately eight weeks following the intervention. Moreover, differences in numerical relational skills decreased in the eight-week period between children whose performance was lower at the beginning of the intervention and the average performance control group. There were no significant differences between the groups at the end of the intervention.

“The novelty value of this finding is boosted by the fact that, in previous intervention programmes for early numeracy practice, long-term effects or the narrowing of differences between children with lower and average performance have not often been identified,” Jylänki says.

Jylänki’s doctoral thesis is part of the Active Early Numeracy research project led by Professor Pirjo Aunio (University of Helsinki) and Associate Professor Arja Sääkslahti (University of Jyväskylä).

Jylänki will continue, together with the Active Numeracy research group, to investigate the Movement with Early Numeracy intervention programme using a larger sample.

To gain more information on the effects of the intervention, its effects will also be compared with those of practising motor skills or early numeracy alone. Following the completion of these studies, the programme will be released for public use free of charge.

Pinja Jylänki, Master of Sport Science, defended her doctoral thesis entitled “Active Early Interventions - Supporting Preschoolers’ Cognitive and Academic Skills with Fundamental Motor Skill and Physical Activity Interventions” on 5 May 2023 at the Faculty of Educational Sciences, University of Helsinki.

Bombardier vs. assassin: Mimetic interactions via a shared enemy

Peer-Reviewed Publication

KOBE UNIVERSITY

A bombardier beetle and an assassin bug. — IMAGE: (A) AN ADULT BOMBARDIER BEETLE PHEROPSOPHUS OCCIPITALIS JESSOENSIS. (B) AN ADULT ASSASSIN BUG SIRTHENEA FLAVIPES. BOTH SPECIES ARE FOUND IN THE SAME GRASSLAND IN JAPAN. view more
CREDIT: SHINJI SUGIURA

Animals can defend themselves against their natural enemies in various ways. Well-defended species often share conspicuous body colors with other well-defended or undefended species, forming mimetic interactions. Bombardier beetles eject toxic chemicals at a temperature of 100°C to repel enemies such as frogs, and many have warning body colors that function to deter enemies. An assassin bug, Sirthenea flavipes, exhibits a conspicuous body color similar to the bombardier beetle Pheropsophus occipitalis jessoensis which coexist with the assassin bug in the same habitat in Japan (Fig. 1). The assassin bug can stab with its proboscis, causing severe pain in humans. Although both insects are well defended, the mimetic interaction between the bombardier beetle and the assassin bug remains unclear.

Japanese entomologists Shinji Sugiura (Kobe University) and Masakazu Hayashi (Hoshizaki Green Foundation) found that the bombardier beetle P. occipitalis jessoensis has a stronger defense against a shared predator compared to the assassin bug S. flavipes. They also showed that both the bombardier beetle and the assassin bug benefit from the mimetic interaction via the shared predator. Their research appears in the 6 June 2023 issue of PeerJ.

In central Japan, the pond frog Pelophylax nigromaculatus coexists with the bombardier beetle and the assassin bug in the same habitat. The pond frog, which is well known as a predator of various insects, could potentially attack the bombardier beetle and the assassin bug under field conditions. The researchers observed the behavioral response of pond frogs to bombardier beetles and assassin bugs under laboratory conditions (see video). Among the frogs, 100% rejected bombardier beetles and 75% rejected assassin bugs (Fig. 2), suggesting that the bombardier beetle is better defended against frogs than the assassin bug. The researchers also provided a bombardier beetle or an assassin bug to a frog that had encountered the other insect. Frogs that had previously encountered one insect species were less likely to attack the other species (Fig. 3). Specifically, a history of encounter with assassin bugs reduced the rate of attack on bombardier beetles by frogs from 75.0% to 21.7% (Fig. 3). A history of encounter with bombardier beetles reduced the rate of attack on assassin bugs by frogs from 91.3% to 40.0% (Fig. 3). Therefore, the mimetic interaction between the bombardier beetle and the assassin bug may be mutualistic.

Video:
https://youtu.be/BZ75K6rfvdE
Credit: Shinji Sugiura

Journal article:
Sugiura, S. & Hayashi, M. (2023) Bombardiers and assassins: mimetic interactions between unequally defended insects. PeerJ (https://doi.org/10.7717/peerj.15380)

Frogs that had not encountered the bombardier beetle or assassin bug were used in this study. Ignore: frogs did not attack beetles (or bugs). Stop attack: frogs stopped their attacks immediately after their tongues had contacted beetles (or bugs). Spit out: frogs spat out beetles (or bugs) immediately after taking the indicated insects into their mouths.

Rates of attack on the bombardier beetle Pheropsophus occipitalis jessoensis and the assassin bug Sirthenea flavipes by the frog Pelophylax nigromaculatus before and after encounters with the other insect species.
CREDIT
Shinji Sugiura