Herring Shift Poleward After Fishery Memory Loss

Marine ecosystems are undergoing profound transformations as global climate patterns shift, with marine ectotherms—organisms whose body temperatures fluctuate with their environment—often bearing the brunt of these changes more acutely than their terrestrial counterparts. Notably, many marine fish species respond to rising oceanic temperatures by migrating toward cooler, higher-latitude waters, progressively shifting their historic geographical distributions poleward. This phenomenon, while widely observed, encapsulates intricate ecological and evolutionary dynamics that scientists are still striving to untangle.

A recent comprehensive study spanning three decades of oceanographic and biological data sheds new light on the mechanisms driving an abrupt poleward movement in spawning behavior of the Norwegian spring-spawning (NSS) herring, a vital species in the Northeast Atlantic ecosystem and fisheries economy. By meticulously analyzing zooplankton samples and thermal profiles from key spawning and larval drift regions alongside generalized additive models, researchers sought to disentangle the complex interplay between environmental drivers and fish behavioral adaptations.

Contrary to simplistic assumptions that rising temperatures alone act as a direct trigger for poleward spawning shifts, the model results revealed a more nuanced reality. The abrupt transition after 2020, characterized by NSS herring moving their spawning grounds towards higher latitudes, was not aligned with the expected environmental cues, such as ocean warming or prey availability gradients. Instead, energetic trade-offs linked to migration were posited as a critical factor: while bypassing traditional spawning sites like Møre requires additional migration energy, this cost might be offset by increased larval survival in warmer waters that abound with higher prey concentrations.

Indeed, the persistence of NSS herring spawning in Møre over the preceding two decades, even amid steadily warming waters, suggests an adaptive resilience and a finely tuned reproductive ecology sustained by longstanding environmental patterns. Notably, the timing of the North Atlantic spring phytoplankton bloom, a foundational event governing zooplankton productivity, has shown remarkable stability over interannual scales despite climatic variation. Given that herring spawning phenology is closely tied to photoperiod—the daylight cues that remain consistent with latitude—this illustrates a deep evolutionary synchronization with the latitudinal timing of primary production and secondary consumer availability along the Norwegian continental shelf.

However, ocean warming exerts an indirect but profound influence on the herring life cycle by altering the mixing dynamics between established adult populations and newly recruited cohorts. Unlike the photoperiod-regulated spring blooms, the summer to autumn plankton blooms have experienced significant temporal delays during the climate change era. This shift in plankton phenology has likely facilitated the emergence of a second generation of the key copepod species, Calanus finmarchicus, a crucial prey item for NSS herring. The resultant extended feeding opportunities into late autumn enabled herring to stretch their migratory range southwestward post-2005, exploiting an expanded temporal and spatial food resource.

Such ecological adjustments coincide with a notable behavioral change: delayed return migrations. By overwintering closer to their extended feeding grounds, NSS herring displayed a marked split in distribution, segregating older, experienced generational groups from the newly recruited 2016 cohort. This separation likely disrupted the transmission of migratory ‘collective memory’—culturally inherited knowledge that guides traditional spawning routes. The erosion of this behavioral culture appears to be a pivotal mechanism underlying the sudden latitudinal shift in spawning locations.

While shifting spawning grounds northward may entail potential drawbacks in long-term reproductive output, large cohorts continue to arise under specific environmental and ecological conditions—an observation supported by synchronized peaks in zooplankton biomass and temperature congruence along the coastline. Cyclic fluctuations in these parameters correspond to the successful recruitment of sizable NSS herring cohorts, notably in birth years such as 2002, 2004, and 2016, underscoring the complex yet finely balanced ecological interactions shaping population dynamics.

These findings collectively challenge the dominant narrative attributing fish distributional changes solely to direct climate warming effects. Instead, they highlight the interplay of behavioral ecology, life-history traits, and subtle environmental shifts driving population restructuring. Such insights underscore the vulnerability of migratory fish species’ culturally transmitted behaviors to anthropogenic pressures, including overfishing, which may have contributed to the collective memory loss observed in NSS herring.

This research also emphasizes the importance of integrating multidisciplinary approaches—combining long-term biological datasets, ecological modeling, and behavioral studies—to unravel how climate change propagates through marine ecosystems. Understanding these mechanisms is paramount for predicting species’ responses to future ocean scenarios and informing sustainable fisheries management that preserves both the ecological integrity and the cultural heritage embedded in migratory behaviors.

Furthermore, the demonstrated indirect effects of warming on population mixing and migratory culture transmission open new avenues for conservation strategies that consider behavioral plasticity and intra-species social dynamics. Maintaining ecological connectivity and preventing disruptions in population structure may be as critical as mitigating direct environmental stressors in securing the resilience of marine fish stocks.

Ultimately, the NSS herring case exemplifies a broader paradigm where environmental change interacts intricately with social and biological factors to shape species distributions. It calls for heightened attention to the less visible, yet equally consequential, channels through which climate change influences marine biodiversity, extending beyond temperature metrics to encompass behavioral and cultural dimensions.

This study’s revelations serve as a timely reminder that marine species’ adaptation to climate shifts is multifaceted, mediated by genetic, ecological, and social processes. As oceanic conditions continue to evolve, monitoring and protecting the traditions and behaviors that underlie successful reproduction and migration may prove indispensable for conserving marine life in a rapidly changing world.

Subject of Research: Norwegian spring-spawning (NSS) herring behavior and migration shifts in response to environmental and cultural factors amid climate change.

Article Title: Herring spawned poleward following fishery-induced collective memory loss.

Article References:
Slotte, A., Salthaug, A., Vatnehol, S. et al. Herring spawned poleward following fishery-induced collective memory loss. Nature (2025). https://doi.org/10.1038/s41586-025-08983-3

Image Credits: AI Generated

Tags: climate change impact on marine speciesecological dynamics of fish populationseffects of global warming on marine ecosystemsevolutionary adaptations of fish speciesfisheries management in a warming oceanherring migration patternsmarine ectotherm responses to temperature changesNortheast Atlantic fishery economicsoceanographic data analysis for marine biologypoleward distribution shifts in fishspawning behavior of Norwegian spring-spawning herringzooplankton and fish interactions