A new study led by researchers at the Earth-Life Science Institute (ELSI) at the Institute of Science, Tokyo, has uncovered a surprising role for calcium in shaping life’s earliest molecular structures. Their findings suggest that calcium ions can selectively influence how primitive polymers form, shedding light on a long-standing mystery: how life’s molecules came to prefer a single “handedness” (chirality).

The study is published in Proceedings of the National Academy of Sciences.

Like our left and right hands, many molecules exist in two mirror-image forms. Yet life on Earth has a striking preference: DNA’s sugars are right-handed, while proteins are built from left-handed amino acids. This phenomenon, called homochirality, is essential for life as we know it—but how it first emerged remains a major puzzle in origins of life research.

The team investigated tartaric acid (TA), a simple molecule with two chiral centers, to explore how early Earth’s environment might have influenced the formation of homochiral polymers. They discovered that calcium dramatically alters how TA molecules link together.

Without calcium, pure left- or right-handed TA readily polymerizes into polyesters, but mixtures containing equal amounts of both forms fail to form polymers readily. However, in the presence of calcium, this pattern reverses—calcium slows down the polymerization of pure TA while enabling mixed solutions to polymerize.

“This suggests that calcium availability could have created environments on early Earth where homochiral polymers were favored or disfavored,” says Chen Chen, Special Postdoctoral Researcher at RIKEN Center for Sustainable Resource Science (CSRS), who co-led the study.

The researchers propose that calcium drives this effect through two mechanisms: first, by binding with TA to form calcium tartrate crystals, which selectively remove equal amounts of both left- and right-handed molecules from the solution; and second, by altering the polymerization chemistry of the remaining TA molecules. This process could have amplified small imbalances in chirality, ultimately leading to the uniform handedness seen in modern biomolecules.

What makes this study especially intriguing is its suggestion that polyesters—simple polymers formed from molecules like tartaric acid—could have been among life’s earliest homochiral molecules, even before RNA, DNA, or proteins.

“The origin of life is often discussed in terms of biomolecules like nucleic acids and amino acids,” ELSI’s Specially Appointed Associate Professor Tony Z. Jia, who co-led the study, explains. “However, our work introduces an alternative perspective: that ‘non-biomolecules’ like polyesters may have played a critical role in the earliest steps toward life.”

The findings also highlight how different environments on early Earth could have influenced which types of polymers formed. Calcium-poor settings, such as some lakes or ponds, may have promoted homochiral polymers, while calcium-rich environments might have favored mixed-chirality polymers.

Beyond chemistry, this research bridges multiple scientific fields—biophysics, geology, and materials science—to explore how simple molecules interacted in dynamic prebiotic environments. The study is also the result of years of interdisciplinary collaboration, bringing together researchers from seven countries across Asia, Europe, Australia, and North America.

“We faced significant challenges in integrating all of the complex chemical, biophysical, and physical analyses in a clear and logical way,” says project co-leader Ruiqin Yi of the Guangzhou Institute of Geochemistry, Chinese Academy of Sciences.

“But thanks to the hard work and dedication of our team, we’ve uncovered a compelling new piece of the origins of life puzzle.”

This research not only deepens our understanding of life’s beginnings on Earth but also suggests that similar processes could be at play on other planets, helping scientists search for life beyond our world.