The mystery of the Greenland shark’s incredible longevity may finally be unraveling, as a team of international researchers has completed the first comprehensive genome map of the creature.
Native to the cold waters between Greenland, Iceland, and Canada, Greenland sharks boast one of the longest vertebrate lifespans on Earth, approaching 400 years. In a recent paper published in the Proceedings of the National Academy of Sciences, researchers led by Shigeharu Kinoshita of the University of Tokyo have identified some of the genetic basis of that extraordinary lifespan, which they say future researchers may exploit to treat cancer and age-related illnesses.
Greenland Sharks Longevity
As genetic sequencing technology has improved and costs have fallen, there has been a major increase in the number of sequences from long-lived species for comparative analysis. Discoveries have included identifying increases in genes related to the immune system and growth hormone receptors in rockfish and bat species noted for their longevity.
With an entire lifecycle in slow motion, Greenland sharks’ longevity can be traced to their prolonged development: they take 150 years to reach sexual maturity, growing only 1 centimeter per year. Despite being one of the slowest swimmers in the ocean, the species undertakes large-scale migrations spanning over 1,000 kilometers.
Genome Mapping
Large genome sizes, like those of the Greenland shark, pose enormous mapping challenges, full of many repetitive sequences. Despite their importance for management and conservation, few whale and shark species have been sequenced due to the difficulty involved. To fill data gaps in the genetic causes of longevity, aquatic species evolution, and the risks of biodiversity loss, the team chose the Greenland shark as their subject.
The University of Tokyo-led team mapped roughly 5.9 billion DNA base pairs, accounting for 96.7% of the shark’s genome. Among the discoveries were the identification of specific genetic features likely related to the Greenland shark’s longevity.
In their paper, they wrote of discovering “genetic traits associated with cancer, immune response function, genome stability, and cardiac function, deep-sea adaptations, and population size dynamics,” in the new research.
Longevity Results
One of the most crucial of these traits is how the shark appears to mitigate the genetic strain that contributes to aging by stabilizing the building blocks of chromosomes. Chromatin is a structure consisting of DNA, RNA, and proteins, which makes up chromosomes.
In the Greenland shark, the histone H1.0 protein, which binds DNA in chromatin, undergoes an amino acid substitution that may enhance stability and reduce the effects of aging.
Another genetic tool aiding the shark’s longevity is the presence of 59 copies of the FTH1b gene, which researchers discovered on pseudochromosome 33, far above the number seen in other shark or fish species. This helps regulate ferroptosis, a form of programmed cell death, thereby mitigating cell damage. Since the gene controls iron storage and ferroptosis is iron-dependent, the researchers say this multiplication of FTH1b could prevent oxidative cell damage.
Beyond those specific expressions, researchers also found expansion of entire gene families associated with DNA repair, immune functions, and cancer resistance.
Although limited to a single species, the research does advance general understanding of the genetic factors involved in extended lifespans. However, it will be up to future researchers to identify how this new information can be applied to human concerns.
The paper, “The Greenland Shark Genome: Insights into Lifespan Extremes and Population Dynamics,” appeared in Earth and Planetary Science Letters on May 19, 2026.
Ryan Whalen covers science and technology for The Debrief. He holds an MA in History and a Master of Library and Information Science with a certificate in Data Science. He can be contacted at ryan@thedebrief.org, and follow him on Twitter @mdntwvlf.