The ribonuclease domain function is dispensable for SLFN11 to mediate cell fate decision during replication stress response.

The SLFN11 gene participates in cell fate decision following cancer chemotherapy and encodes the N-terminal ribonuclease (RNase) domain and the C-terminal helicase/ATPase domain. How these domains contribute to the chemotherapeutic response remains controversial. Here, we expressed SLFN11 containing mutations in two critical residues required for RNase activity in SLFN11-/- cells. We found that this mutant was still able to suppress DNA damage tolerance, destabilized the stalled replication forks, and perturbed recruitment of the fork protector RAD51. In contrast, we confirmed that the helicase domain was essential to accelerate fork degradation. The fork degradation by the RNase mutant was dependent on both DNA2 and MRE11 nuclease, but not on MRE11's novel interactor FXR1. Collectively, these results supported the view that the RNase domain function is dispensable for SLFN11 to mediate cell fate decision during replication stress response.

Evolution, inactivation and loss of short wavelength-sensitive opsin genes during the diversification of Neotropical cichlids.

Natural variation in the number, expression and function of sensory genes in an organism's genome is often tightly linked to different ecological and evolutionary forces. Opsin genes, which code for the first step in visual transduction, are ideal models for testing how ecological factors such as light environment may influence visual system adaptation. Neotropical cichlid fishes are a highly ecologically diverse group that evolved in a variety of aquatic habitats, including black (stained), white (opaque) and clear waters. We used cross-species exon capture to sequence Neotropical cichlid short wavelength-sensitive (SWS) opsins, which mediate ultraviolet (UV) to blue visual sensitivity. Neotropical cichlid SWS1 opsin (UV-sensitive) underwent a relaxation of selective constraint during the early phases of cichlid diversification in South America, leading to pseudogenization and loss. Conversely, SWS2a (blue-sensitive) experienced a burst of episodic positive selection at the base of the South American cichlid radiation. This burst coincides with SWS1 relaxation and loss, and is consistent with findings in ecomorphological studies characterizing a period of extensive ecological divergence in Neotropical cichlids. We use ancestral sequence reconstruction and protein modelling to investigate mutations along this ancestral branch that probably modified SWS2a function. Together, our results suggest that variable light environments played a prominent early role in shaping SWS opsin diversity during the Neotropical cichlid radiation. Our results also illustrate that long-term evolution under light-limited conditions in South America may have reduced visual system plasticity; specifically, early losses of UV sensitivity may have constrained the evolutionary trajectory of Neotropical cichlid vision.

Mouse Slfn8 and Slfn9 genes complement human cells lacking SLFN11 during the replication stress response.

The Schlafen (SLFN)11 gene has been implicated in various biological processes such as suppression of HIV replication, replication stress response, and sensitization of cancer cells to chemotherapy. Due to the rapid diversification of the SLFN family members, it remains uncertain whether a direct ortholog of human SLFN11 exists in mice. Here we show that mSLFN8/9 and hSLFN11 were rapidly recruited to microlaser-irradiated DNA damage tracks. Furthermore, Slfn8/9 expression could complement SLFN11 loss in human SLFN11-/- cells, and as a result, reduced the growth rate to wild-type levels and partially restored sensitivity to DNA-damaging agents. In addition, both Slfn8/9 and SLFN11 expression accelerated stalled fork degradation and decreased RPA and RAD51 foci numbers after DNA damage. Based on these results, we propose that mouse Slfn8 and Slfn9 genes may share an orthologous function with human SLFN11. This notion may facilitate understanding of SLFN11's biological role through in vivo studies via mouse modeling.