Great White Shark Teeth Morphological Changes with Age: New University Research Reveals Ontogenetic Shifts

Revolutionary Insights into Great White Shark Tooth Evolution from Australian Universities

Recent research from leading Australian higher education institutions has unveiled how great white sharks, or Carcharodon carcharias, dramatically alter their tooth morphology as they mature, adapting to shifting dietary needs and ecological roles. This discovery highlights the dynamic nature of shark dentition, where teeth evolve not just across species but within an individual's lifetime. 72 70

Great white sharks, apex predators of marine ecosystems, replace their teeth continuously through a conveyor-belt-like mechanism, generating thousands over a lifetime. This regeneration allows for precise adaptations to life stages, from juvenile piscivory to adult macropredation on marine mammals.

Understanding Shark Dentition: A Foundation in Evolutionary Biology

Shark teeth, or dentition, vary widely across species to match prey types—needle-like for squid, flat molars for shellfish, and serrated triangles for flesh. In great whites, this variability extends ontogenetically, meaning changes occur with growth and age. Unlike mammals with fixed teeth, elasmobranchs like sharks possess polyphyodont dentition, enabling endless replacement every few weeks. 72

Prior studies noted broader teeth in adults but lacked comprehensive analysis across full jaws and life stages. This gap has now been bridged by interdisciplinary teams from universities, combining morphometrics and advanced imaging.

The Groundbreaking Study: Form, Function, and Feeding

Published on January 26, 2026, in the peer-reviewed journal Ecology and Evolution, the paper "Form, Function and Feeding: Changes in Tooth Size and Shape Associated With Ontogenetic Changes in Prey Consumption by Australian White Sharks" details findings from 97 specimens. Lead author Emily Hunt, from the University of Sydney's School of Life and Environmental Sciences, collaborated with experts from the same university, University of Technology Sydney, and government bodies like New South Wales Department of Primary Industries. 72

• Specimens spanned 90.85–491.3 cm precaudal length (PCL), covering young-of-year to adults.
• Sources: Primarily NSW Shark Meshing Program (1999–2024), plus fisheries and museums.
• No significant sex differences, aligning with similar diets in eastern Australian populations.

This university-led effort exemplifies how higher education drives marine science breakthroughs.

Innovative Methods: From Morphometrics to Elliptic Fourier Analysis

Researchers employed classic morphometrics (e.g., tooth height, width, base thickness) and Elliptic Fourier Analysis (EFA) for outlines. Teeth were photographed in situ using standardized iPhone rigs, silhouettes processed in Adobe Photoshop, and analyzed via R's Momocs package (7 harmonics capturing 99.9% variation). Generalized linear mixed models (GLMMs) assessed effects of PCL, tooth position, and number, with shark ID as random effect. 72

Jaw metrics included circumference and width, revealing structural shifts. Paired t-tests confirmed bilateral symmetry, while ANOVAs tested life stage and sex effects on tooth counts.

Ontogenetic Shifts: The Pivotal Transition at 210-250 cm PCL

A critical shift occurs around 210 cm PCL (~3m total length): juvenile teeth—narrow, cuspidate with accessory cusplets—transform into broad, serrated triangles. Cusplets aid grasping slippery fish/squid; adults slice dense mammal tissue/bone. GLMM residuals pinpoint inflexions at ~210 cm (morphometrics) and ~250 cm (EFA). 72

Root surface area and jaw width expand at ~210 cm, boosting bite force.

Photo by Nicole Avagliano on Unsplash

Jaw Position Variation: Functional Heterodonty

Teeth differ anterior-to-posterior: first 6 per side symmetrical/triangular for piercing; post-6th compressed/recurved blades for tearing. Upper teeth cut/dismember; lower grip/hold. Central teeth (1st/2nd) have thicker bases as "impact" absorbers; 3rd/4th upper shorter/angled for retention. 72 71

• Inflexion at 6th tooth marks role shift.
• Classic metrics explained 19.8% deviance vs. 4.3% EFA.

Dietary and Ecological Transitions

Juveniles are piscivorous; post-3m, mammals enter diet (~194 cm PCL per prior studies). Tooth/jaw changes enable this niche shift, enhancing trophic roles. As apex predators, these adaptations influence community dynamics.Explore research jobs in shark ecology at universities worldwide.

Read the full study for detailed figures. 72

Implications for Conservation and Public Safety

Understanding these shifts aids population modeling, as juveniles avoid mammals, reducing human-shark conflicts initially. In Brazil, where shark conservation is vital amid fisheries pressures, similar studies could inform policies. Universities like Universidade Federal Rural de Pernambuco (UFRPE) have explored shark jaws, paving ways for collaborations. 28

The study underscores higher ed's role in bridging form-function gaps, with applications to evolutionary biology and biomechanics.

Brazilian Perspectives: Media Buzz and Local Research Potential

Brazilian outlets like Folha de S.Paulo highlighted the findings, sparking interest in national marine biology programs. Though focused on Australian populations, great whites occasionally appear off Brazil's coast, urging local unis to adapt methodologies. Programs at USP or UNESP could extend this to regional elasmobranchs.Brazil higher ed opportunities.

Folha coverage emphasizes global relevance. 70

Future Research Directions in Higher Education

Authors recommend serration analysis, jaw kinematics, and mineralization studies. Integrating genetics could reveal mechanisms. For aspiring marine biologists, this exemplifies quantitative ecology's power—craft a strong academic CV for such roles.

Photo by Will Turner on Unsplash

• Serration development timelines.
• Comparative studies across shark species.
• Biomechanical modeling of bites.

Conclusion: Teeth as Windows to Shark Life Histories

This University of Sydney-led publication redefines shark evolution, showing teeth as adaptive records. For higher ed professionals, it signals opportunities in interdisciplinary marine science. Explore professor ratings on Rate My Professor, browse higher ed jobs, or seek career advice. University jobs in research abound—find yours.