New technology reveals hidden DNA scaffolding built before life ‘switches on’
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An early Drosophila embryo captured during a wave of nuclear division. Dividing nuclei (blue) and non-dividing nuclei (pink) illustrate the rapid, highly organised nature of early development and the substantial regulation of genome organisation needed to enable proper gene activation despite repeated disruption as nuclei divide.
view moreCredit: Clemens Hug
For decades, scientists viewed the genome of a newly fertilised egg as a structural ‘blank slate’ – a disordered tangle of DNA waiting for the embryo to ‘wake up’ and start reading its own genetic instructions.
In research published today in Nature Genetics, Professor Juanma Vaquerizas and his team have found that a surprising level of structure is already in place. They’ve developed a breakthrough technology, called Pico-C, which enables scientists to see the 3D structure of the genome in unprecedented detail. Using this technique, they discovered that well before the genome fully awakens – a critical event known as Zygotic Genome Activation – a sophisticated 3D scaffold of DNA is already being built. Understanding how DNA folds in space matters because this controls which genes can be turned on during development, helping cells function properly and preventing developmental defects and disease.
“We used to think of the time before the genome awakens as a period of chaos,” explains Noura Maziak, lead author of the study. “But by zooming in closer than ever before, we can see that it’s actually a highly disciplined construction site. The scaffolding of the genome is being erected in a precise, modular way, long before the ‘on’ switch is fully flipped.”
Pico-C: Seeing More with Less
The team’s discovery was made in the fruit fly (Drosophila). In the first few hours after fertilisation, a fly embryo undergoes a rapid series of nuclear divisions, creating thousands of cells. It’s this high-speed environment that makes the fruit fly perfect for studying the fundamentals of genetics.
Using their ultra-sensitive Pico-C technology, they mapped the 3D structure of the fruit fly genome during these early developmental stages. They found that the 3D loops and folds of DNA follow a modular logic, allowing different inputs to regulate specific parts of the genome. It is a complex architectural programme that ensures the information encoded in the genome is ready for action the moment it is needed.
As well as providing high-resolution detail about the shape of DNA, Pico-C only requires tiny amounts of sample – ten times less than standard methods. This opens the door to opportunities for studying how DNA folding shapes gene regulation and its implication in many diseases in greater detail than previously possible.
From Fly Embryos to Human Health
While the ‘blueprint’ of this architecture was discovered in fruit flies, the importance of maintaining it applies directly to humans. In a companion study published today in Nature Cell Biology led by Professor Ulrike Kutay and collaborators at ETH Zürich in Switzerland, the team applied this high-resolution mapping to human cells.
They investigated what happens when the ‘anchors’ that hold this 3D structure in place are removed. The results were striking: when the architecture collapses, the human cell mistakes the structural failure for a viral attack. This triggers the cell’s innate immune system, sounding a false alarm that can lead to inflammation and disease.
“These two studies tell a complete story,” says Juanma. “The first shows us how the genome’s 3D structure is carefully built at the start of life. The second shows us the disastrous consequences for human health if that structure is allowed to collapse.”
This study was funded by the Medical Research Council and the Academy of Medical Sciences (AMS) through an AMS Professorship award.
Journal
Nature Genetics
Article Title
Three-dimensional genome reorganization foreshadows zygotic genome activation in Drosophila
Article Publication Date
24-Feb-2026
Enzymes work as Maxwell's demon by using memory stored as motion
Researchers show that enzymes with enhanced enzyme diffusion can function as Maxwell's demon by utilising information from past reactions to actively shift away from equilibrium and control the directionality of chemical reactions
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An artistic illustration depicting "Maxwell's demon" modulating the diffusion speed of an enzyme. The demon represents the physical mechanism by which the enzyme uses information to break chemical equilibrium.
view moreCredit: Tetsuhiro S. Hatakeyama, ELSI
Living cells are sustained by countless chemical reactions that must be carefully regulated to maintain internal order and function. Enzymes play a central role in this process, accelerating reactions that would otherwise proceed too slowly to support life. Traditionally, enzymes have been viewed as passive catalysts—speeding up chemical reactions without influencing their final balance. However, how enzymes might contribute to the regulation of chemical states beyond simple catalysis remains an open question in biology.
A study led by researchers from Earth-Life Science Institute (ELSI) at Institute of Science Tokyo, explain the biological consequences of enhanced enzyme diffusion or mobility that is observed during catalysis. Their new study proposes that enzymes behave similar to the theoretical "Maxwell's demon" and can utilise information from past reactions to actively shift subsequent reactions away from equilibrium. This is a fundamentally new role for enzymes with implications in fine metabolic regulation.
It all began with the observation of the phenomenon of enhanced enzyme diffusion (EED), in which enzymes transiently move faster after catalysis. Instead of treating enhanced diffusion as a secondary effect, the researchers asked whether it could play an active functional role in chemical reactions. Their work provides a fundamental explanation for how EED could influence reaction dynamics at the macroscopic level.
In the study, the researchers simulated the scenario where chemical energy generated during a catalytic reaction is utilised by the enzymes to transiently increase mobility. They tested whether this change in motion altered subsequent reactions; in particular, they studied the composition of substrates and products. In their simulation analysis, they observed that the ratio of substrate to product exhibited a clear deviation from the expected chemical equilibrium.
How do simple diffusion changes break the chemical equilibrium? "We struggled to understand the physical mechanism driving this shift," says Associate Professor Tetsuhiro S. Hatakeyama, co-author of the study. "The most challenging aspect was bridging the gap between the simulation results and the theoretical understanding."
The key insight came from recognising that the enzyme's behaviour resembled a famous thought experiment known as Maxwell's demon, which describes an imaginary being that uses information about molecular motion to create order without doing work, seemingly violating the second law of thermodynamics. In this study, the enzyme plays a comparable role through physical processes rather than intention. "Realising the analogy to 'Maxwell's demon' was the critical conceptual leap that allowed us to view the enzyme as an agent performing measurement and feedback. This allowed us to understand that the biological behaviour of increased diffusion is a form of 'memory' and connected to information thermodynamics," explains co-author Kunihiko Kaneko, Visiting Researcher of ELSI.
Based on this, the researchers constructed a theoretical model where the transient increase in motility served as a "memory" of the enzyme's immediate past reaction event. The enzyme used this information to leave the product molecules, thereby eliminating the probability of the reverse reaction. This behaviour disrupts the delicate balance between forward and reverse reactions and drives the system to a new steady state that deviates from the chemical equilibrium. Adding to the significance of this study is the finding that this phenomenon is not limited to the theoretical world but is biologically possible within the parameters of actual enzymes, such as urease.
One of the most significant implications of this finding is the possibility that EED may have existed in primitive "proto-enzymes" that may have utilised the heat or energy from chemical reactions to drive non-equilibrium reactions purely through physical motility changes. EED may be the potential "missing link" in prebiotic chemistry, serving as a simple, physical principle that paved the way for the emergence of life.
Overall, this study overturns the traditional passive role of enzymes by showing that enzymes can process information to actively control the directionality of chemical reactions. It also provides a concrete, biological realisation of the theoretical "Maxwell's demon" and suggests that nature may have been utilising information-to-energy conversion mechanisms in biomolecules all along. Most notably, this study clears the mystery surrounding the biological significance of EED.
Looking ahead, further investigation will be needed to understand how this mechanism operates within living cells. Sharing their vision for this study, Hatakeyama says, "Theoretically, we aim to explore how this 'demon-like' behaviour affects larger metabolic networks. Does the cell use this mechanism to regulate metabolic flux or create spatial organisation?"
Together, these findings add a new dimension to biochemical regulation and could reshape our understanding of how enzymes function within living systems.
Comparison of molecular concentrations with and without enhanced enzyme diffusion (EED). In the absence of EED, the concentrations of the product and substrate align with chemical equilibrium (set here to be equal). However, in the presence of EED, the balance between forward and reverse reactions is broken, resulting in a steady-state increase in product concentration.
A transition diagram illustrating how an enzyme functions as Maxwell's demon via Enhanced Enzyme Diffusion (EED). 'S' and 'P' represent the substrate and product, respectively. The black face indicates the enzyme in its normal state, while the yellow face represents the high-motility (EED) state. When the enzyme catalyses a substrate, this event is "recorded" as a transition to the EED state. This memory is used to suppress the probability of the reverse reaction, causing a deviation from chemical equilibrium (Red arrow). Conversely, the information is lost and no deviation occurs if the intrinsic diffusion is already too high (Grey arrow), if the EED state decays too quickly (Blue arrow), or if the reverse reaction occurs before the enzyme can diffuse away (Green arrow).
Credit
Hatakeyama et al. Adapted from Physical Review Letters
Reference
Shunsuke Ichii1, 2, Tetsuhiro S. Hatakeyama3*, and Kunihiko Kaneko3, 4, Enzyme as Maxwell's Demon: Steady-State Deviation from Chemical Equilibrium by Enhanced Enzyme Diffusion, Physical Review Letters, DOI: 10.1103/flv6-zw1v
1. Department of Physics, The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-0033, Japan
2. Center for Biosystem Dynamics Research, RIKEN, 6-2-3 Furuedai, Suita, Osaka 565-0874, Japan
3. Earth-Life Science Institute, Institute of Science Tokyo, 2-12-1 Ookayama, Meguro-ku, Tokyo 152-8550, Japan
4. Niels Bohr Institute, University of Copenhagen, Blegdamsvej 17, 2100 Copenhagen, Denmark
More information
Earth-Life Science Institute (ELSI) is one of Japan's ambitious World Premiere International research centers, whose aim is to achieve progress in broadly inter-disciplinary scientific areas by inspiring the world's greatest minds to come to Japan and collaborate on the most challenging scientific problems. ELSI's primary aim is to address the origin and co-evolution of the Earth and life.
Institute of Science Tokyo (Science Tokyo) was established on October 1, 2024, following the merger between Tokyo Medical and Dental University (TMDU) and Tokyo Institute of Technology (Tokyo Tech), with the mission of "Advancing science and human wellbeing to create value for and with society."
World Premier International Research Center Initiative (WPI) was launched in 2007 by Japan's Ministry of Education, Culture, Sports, Science and Technology (MEXT) to foster globally visible research centers boasting the highest standards and outstanding research environments. Numbering more than a dozen and operating at institutions throughout the country, these centers are given a high degree of autonomy, allowing them to engage in innovative modes of management and research. The program is administered by the Japan Society for the Promotion of Science (JSPS).
Journal
Physical Review Letters
Method of Research
Computational simulation/modeling
Subject of Research
Not applicable
Article Title
Enzyme as Maxwell's Demon: Steady-State Deviation from Chemical Equilibrium by Enhanced Enzyme Diffusion
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