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Researchers at Ohio State University have discovered over 230 previously unknown giant viruses, often referred to as “giruses,” in seawater samples from oceans around the world.

These viruses are far larger and more complex than typical viruses, sometimes rivaling bacteria in size and genetic content.

Their genomes can span more than a million base pairs and include genes commonly found in cellular organisms—such as those for metabolism, photosynthesis, and even DNA repair—challenging our traditional definition of what a virus is.

These giant viruses primarily infect marine protists, such as algae and amoebae, playing a crucial role in ocean ecosystems.

By hijacking their hosts’ metabolic and reproductive systems, these viruses can influence major biological processes like carbon cycling and oxygen production.

This interaction has significant implications for climate regulation and nutrient flow, as marine microbes are at the foundation of the food web and account for a large portion of the Earth's oxygen production.

The study also suggests that these viruses may be important in controlling harmful algal blooms, which can devastate marine biodiversity and fisheries.

By better understanding how these viruses operate and interact with microbial life, scientists could develop new tools for monitoring and managing the health of ocean ecosystems.

This groundbreaking discovery reveals just how much of Earth’s microbial and viral diversity remains unexplored and emphasizes the ocean’s role as a critical reservoir of biological innovation.

Physicists may have found a surprising new link between the universe’s biggest and smallest mysteries—hidden in the twist of light.

In a groundbreaking study, researchers discovered that when photons journey through the warped fabric of spacetime, their polarization—the direction in which they vibrate—can behave in a way that defies classical expectations. Instead of returning to its original state, the polarization can shift in a phenomenon known as non-reciprocity. This subtle effect suggests that light, in the presence of gravity, may not be as predictable as once thought.

At the heart of this discovery is a shift in perspective—literally. By carefully adjusting the quantization axis, or the angle at which polarization is observed, scientists detected amplified changes in the photon’s orientation, known as Wigner Rotation Angles (WRAs). Remarkably, near massive objects like black holes, these shifts could be ten times greater than previously anticipated.

To test this theory, researchers propose using advanced space-based interferometers and quantum optical systems. If confirmed, this non-reciprocal twist could offer a new way to explore how quantum mechanics and general relativity interact—and may even challenge Einstein’s cherished Equivalence Principle.

“This opens up a new experimental window into some of physics’ biggest mysteries,” said Dr. Warner Miller, co-author of the study.

Published in Scientific Reports, the findings could reshape how we probe the cosmos—from the vast gravitational wells of black holes to the subatomic quirks of quantum particles.