Innate immune signaling is traditionally associated with the response to pathogenic infection. However, emerging evidence suggests that nuclear innate immune sensors and their downstream pathways may also serve as a critical mechanism for genome surveillance. This review explores a model in which DNA sensors such as mouse IFI204 and IFI205 (IFI16 in humans) localize to replication forks, where they detect endogenous aberrant DNA structures and initiate an interferon-stimulated gene (ISG) transcriptional program. A key output of this transcriptional program is ISG15, which we find conjugated to fork-associated proteins and facilitates recruitment of the replication fork protection complex, thereby stabilizing replication forks under physiological conditions. We discuss how nuclear innate immune sensors mediate replication stress sensing and examine the broad consequences of downstream ISG transcription across diverse contexts—including its impact on genome stability and its dual roles in modulating tumor cell behavior and the tumor microenvironment. These findings suggest that the innate immune system, through its nuclear DNA sensing arm, may be evolutionarily co-opted for genome surveillance and may influence tumor initiation and therapy resistance. Understanding how innate immune signaling intersects with replication stress could offer mechanistic insights into tumor development and reveal novel therapeutic targets.

Innate immune sensing

Interferon-stimulated gene

ISG15

Genome surveillance

Epigenetic plasticity

Tumorigenesis

© 2025 The Author(s). Published by Elsevier B.V.