Abstract
Summary
Cells must adapt to environmental changes to maintain homeostasis. One of the most striking environmental adaptations is entry into hibernation during which core body temperature can decrease from 37°C to as low at 4°C. How mammalian cells, which evolved to optimally function within a narrow range of temperatures, adapt to this profound decrease in temperature remains poorly understood. In this study, we conducted the first genome-scale CRISPR-Cas9 screen in cells derived from Syrian hamster, a facultative hibernator, as well as human cells to investigate the genetic basis of cold tolerance in a hibernator and a non-hibernator in an unbiased manner. Both screens independently revealed glutathione peroxidase 4 (GPX4), a selenium-containing enzyme, and associated proteins as critical for cold tolerance. We utilized genetic and pharmacological approaches to demonstrate that GPX4 is active in the cold and its catalytic activity is required for cold tolerance. Furthermore, we show that the role of GPX4 as a suppressor of cold-induced cell death extends across hibernating species, including 13-lined ground squirrels and greater horseshoe bats, highlighting the evolutionary conservation of this mechanism of cold tolerance. This study identifies GPX4 as a central modulator of mammalian cold tolerance and advances our understanding of the evolved mechanisms by which cells mitigate cold-associated damage—one of the most common challenges faced by cells and organisms in nature.
Introduction
Rapid temperature changes pose a challenge to all clades of life, including endotherms. Homeotherms such as mammals routinely defend a core body temperature set-point, with profound thermal deviations leading to organ dysfunction and death1–4. Indeed, several studies have shown that while homeotherm-derived cells typically possess a capacity for mild cold tolerance in culture, primary cultured cells and cell lines derived from a number of mammalian species, including humans, exhibit high rates of cell death following prolonged severe cold exposure5–8. Although considerable work has focused on understanding the cellular responses and adaptations to an increased temperature (heat stress and heat-shock)9–11, little is known about how cell biological processes modulate cell sensitivity to decreased temperatures.
The mechanisms underlying cold-induced death remain poorly understood but have been hypothesized to involve phase transition of cellular membranes, with the resulting membrane damage leading to ion gradient disruption and irrecoverable cellular dysfunction12–15. However, many warm-blooded animals, including some primates, have evolved the ability to enter torpor and hibernation – states during which body temperature can decrease far below its homeostatic set-point16–18. In many animals, torpor is a state of profoundly reduced metabolic rate and body temperature lasting from hours to days, while hibernation is a seasonal behavior comprising multiple bouts of torpor interrupted by periodic arousals to normal body temperature. During torpor, the core body temperature of many small hibernators including the Syrian golden hamster (Mesocricetus auratus), the 13-lined ground squirrel (Ictidomys tridecemlineatus), and the greater horseshoe bat (Rhinolophus ferrumequinum), reaches 4-10°C19–21. Animals can remain at these low temperatures for extended periods of time (up to several weeks), indicating that their cells and tissues are either genetically predisposed to cold tolerance, or that they can adapt to tolerate long-term cold exposure19–22.
Although in principle the ability to tolerate cold temperatures could be conveyed by systemic factors present in torpid or hibernating animals, cell lines derived from hibernating rodents maintain high viability when exposed to 4°C for several days, indicating the presence of cell-intrinsic mechanisms of cold tolerance5–8. Several studies have reported distinctive responses of hibernator-derived cells in the cold. For example, Syrian hamster-derived epithelial-like hamster kidney (HaK) cells maintain mitochondrial membrane potential and ATP production during cold exposure7, and both HaK and epithelial-like smooth muscle cells derived from the Syrian golden hamster are able to prevent excess reactive oxygen species damage in response to cold exposure5. Similarly, unlike human induced pluripotent stem cell (iPSC)-derived neurons, cultures of iPSC-derived neurons from 13-lined ground squirrels retain microtubule stability in the cold6. Despite metabolic and cell biological differences between various hibernator and non-hibernator-derived cells in the context of cold exposure, the underlying genetic modulators of cold tolerance have yet to be systematically explored. Additionally, it is still unknown to what extent the pathways that regulate cold tolerance in one hibernating species are conserved across other evolutionarily distant hibernators and potentially even present in non-hibernators.
Here, we carry out the first unbiased genome-scale CRISPR-Cas9 screens in cells derived from a cold-tolerant hibernator (Syrian hamster) as well as human (non-hibernator) cells to identify genetic pathways required for long-term cold tolerance. Surprisingly, these screens independently identify a common mechanism dependent on the selenocysteine-containing enzyme Glutathione Peroxidase 4 (GPX4) as a key mediator of cellular cold tolerance. Employing genetic and pharmacological approaches, we confirm these findings and demonstrate that increased GPX4 activity is sufficient to improve cold tolerance in human cells. We further show that functional GPX4 is required for cold tolerance across several hibernating and non-hibernating mammals, including in distantly related hibernating horseshoe bats (Rhinolophus ferrumequinum), and propose that the GPX4 pathway may be a widespread, evolutionarily ancient metazoan mechanism of cold tolerance across endotherms.
Results
Assay for measuring viability of cold-exposed cells
Our initial evaluation of the ability of human K562 leukemia cells to tolerate prolonged exposure to extreme cold (4°C) temperatures led us to establish a new method for assessing viability of cold-exposed cells. To avoid confounding changes in media composition or pH, we transferred cultured cells into incubators cooled to 4°C with the CO2 concentration calibrated to maintain physiological pH (7.4). Cell survival was assessed based on exclusion of trypan blue, a membrane-impermeable dye, immediately upon removal from 4°C. We observed a 27 ± 3% survival rate for K562 cells following 24 hours at 4°C using this approach. However, recounting live cells after a 24-hour rewarming at 37°C revealed a ∼6-fold increase in live cells, inconsistent with the reported 16-24 hour doubling rate of this cell line (Figure 1b, Figure S1a). Reasoning that a substantial fraction of trypan blue-positive cells at 4°C remain alive and capable of cell division and recovery upon rewarming, we carried out a time course of trypan blue staining shortly after removal from 4°C (Figure 1a). We found that the fraction of trypan blue-positive cells dramatically reduced following a brief rewarming period (30 minutes to 1 hour, either at room temperature or at 37°C), consistent with the number of live cells observed after 24 hours of rewarming (Figure 1b,c, Figure S1a,b). To determine whether this effect was isolated to K562 cells, we measured trypan blue-positive cells at 4°C or following a brief period of rewarming in several human cell lines (HEK 293T, HeLa, and RPE1 cells), as well as Syrian hamster kidney fibroblasts (BHK-21 cells) (Figure S1c-f). We consistently observed that, absent a rewarming period, trypan blue staining significantly overestimates cold-induced cell death. We thus adopted this brief rewarming period (∼30-minutes) as a standard assay to measure cell viability of cold-exposed cells in our subsequent studies.
Hibernator-derived cells show enhanced cold tolerance compared to human cells
Using our modified assay for cell viability after cold challenge, we examined the relative cold tolerance of hibernator and non-hibernator cells. We tested four commonly used human cell lines (HT1080, HeLa, RPE1, and K562), as well as two cell lines (BHK-21 and HaK) derived from Syrian hamsters (Mesocricetus auratus), a hibernating mammal. Cells were placed at 4°C - the lower end of the temperature range which Syrian hamsters reach during hibernation - and we assessed cell survival after 1, 4, and 7 days of cold exposure. Consistent with prior reports5,7,8, hamster-derived cell lines maintained high levels of viability, whereas human cell lines showed varying degrees of death (Figures 1d-f), with several exhibiting less than 50% survival following 7 days in the cold. Notably, we observed generally higher cell survival rates than previously reported5, likely owing to our modified method of measuring cell viability. Similar survival trends were also observed using an orthogonal assay based on lactate dehydrogenase (LDH) release from dead cells into the media (Figure 1g).
Genome-scale CRISPR screen in a hibernator-derived cell line identifies suppressors of cold-induced cell death
To investigate the molecular pathways regulating cold resistance in hibernator-derived BHK-21 cells, we designed a genome-scale CRISPR-Cas9 screen. Taking advantage of a recent chromosome-level assembly of the Mesocricetus auratus genome23 and a modified CRISPOR-based guide selection algorithm (Methods), we generated a library of 218,143 single guide RNAs (sgRNAs) targeting all 21,473 annotated genes (∼10 guides per gene), including 2,299 intergenic-targeting and 250 non-targeting sgRNAs as negative controls. The pooled library was introduced into BHK-21 cells via a lentiviral vector expressing the sgRNA along with Cas9, achieving ∼1000-fold library representation with a multiplicity of infection (MOI) < 1.
Considering that many mammalian species, including Syrian hamsters, undergo prolonged periods of cold exposure (deep torpor) and rewarming (interbout arousals) during seasonal hibernation, we sought to recapitulate these temperature changes in our screen. We thus exposed BHK-21 cells to three cycles consisting of 4°C cold exposure (4 days) followed by rewarming at 37°C (2 days) (“4°C Cycling”, Figure 2a). To isolate genes selectively required upon cold exposure, we also analyzed BHK-21 cultures transduced in parallel that were maintained at 37°C for four passages/cycles (“37°C Control”, Figure 2a). For both paradigms, genomic DNA was isolated from cells during each cycle/passage to monitor selective sgRNA depletion. To assess our screen performance, we tested whether sgRNAs targeting previously identified human core essential genes24 were significantly depleted compared with nontargeting and intergenic sgRNAs and found that we can robustly distinguish between these functional categories at all three cycles and at both 37°C and 4°C (estimated p-value < 2.2e-16) (Figure S2).
To identify genes that selectively modify (suppress or potentiate) cold-induced cell loss, we compared the guides depleted during three cycles of cold exposure and rewarming to controls at 37°C with matched population doublings. Among the 21,473 targeted genes, only one gene, ribosomal protein S29 (Rps29)25, was selectively required in control 37°C conditions and only nine genes appeared selectively required during cold exposure (FDR < 0.1, log2 fold-change [Log2FC] >1, Figure 2b, Table S1, S2). Four selectively required genes - Dld, Lias, Lipt1, and Ybey – are involved in lipoylation and mitochondrial RNA processing26–29. Strikingly, five of the nine required genes - Gpx4, Eefsec, Pstk, Secisbp2, and Sepsecs - represent known components of the glutathione/Glutathione Peroxidase 4 (GPX4) antioxidant pathway, indicating that this pathway functions as a potent suppressor of cold-induced cell death in hibernator-derived BHK-21 cells (Figure 2c).
Gpx4 encodes a selenocysteine-containing lipid antioxidant enzyme that acts to suppress lipid peroxidation via the glutathione-mediated reduction of lipid hydroperoxides to non-toxic lipid alcohols30. GPX4 inhibition sensitizes cells to ferroptosis, a distinct form of programmed cell death characterized by iron-dependent accumulation of lipid peroxidation31. Notably, cold exposure has previously been associated with increased lipid peroxidation and ferroptosis in human cells5. Underscoring the requirement for Gpx4 activity, four of the eight remaining genes selectively required upon cold exposure (Eefsec, Secisbp2, Pstk, Sepsecs) are directly or indirectly involved in selenocysteine incorporation into cellular proteins and thus required for Gpx4 activity (Figures 2d-h)32,33.
Given that our initial screen design involved repeated rewarming cycles, we could not exclude the possibility that the Gpx4 pathway confers resistance to rewarming-associated stress rather than cold tolerance per se. To address this issue, we took advantage of the high cold tolerance of BHK-21 cells and included a second screen arm using similar methods in which cells were continuously exposed to 4°C for 15 days (Figure 2i). Sequencing prior to and following 15 days of cold exposure, followed by a brief rewarming to 37°C, confirmed significant depletion (FDR < 0.1, Log2FC < −0.5) of sgRNAs targeting Gpx4, Eefsec, and Secisbp2 (as well as a trend toward depletion for Sepsecs and Pstk), confirming a critical role for the Gpx4 pathway in BHK-21 cell prolonged cold tolerance (Figures 2j,k, Table S2, S3). Thus, two unbiased genome-scale screen arms identified Gpx4 as a major suppressor of cold-induced cell death in hibernator-derived BHK-21 cells in the context of both cyclical and continuous cold exposure.
Gpx4 catalytic activity is essential for hibernator cell survival during cold exposure
To further validate the role of GPX4 in cold-mediated cell death, we employed the top-ranked sgRNA from our screen to generate clonal Gpx4 knockout BHK-21 cells. We sorted individual cells to obtain clonal knockout cell lines and maintained them in the presence of liproxstatin-1 since they showed stunted growth at 37°C (Figure S4a). We confirmed the absence of Gpx4 via immunoblotting (Figure 3a). While wild-type (WT) BHK-21 cells maintained high cell viability at 4°C, all three Gpx4 knockout lines exhibited complete cell death within 4 days of cold exposure (****P < 0.0001) (Figure 3a). Moreover, these differences reflected Gpx4 loss, as opposed to off-target effects insofar as lentiviral re-expression of cytosolic hamster Gpx4 (****P < 0.0001), but not a GFP control gene or a catalytically dead mutant form of Gpx4 (mGPX4) that has a serine in the active site instead of a selenocysteine, restored cold tolerance of Gpx4 knockout lines (Figures 3b,c).
Together, these genetic experiments strongly implicate the catalytic activity of Gpx4 in BHK-21 cold tolerance. However, the constitutive nature of these interventions precluded a determination of whether Gpx4 functions to actively oppose cell death during cold-exposure or whether loss of its catalytic activity prior to cold exposure sensitizes cells to subsequent cold challenge. To address this issue, we used RSL3 and ML162, two competitive small-molecule Gpx4 inhibitors34–36. Acute treatment of cultured BHK-21 cells with these inhibitors during cold exposure yielded dose-dependent increases in cell death. Indeed, by four days of treatment, both RSL3- and ML162-treated BHK-21 cells display significantly increased cold-induced death compared to untreated controls (****P < 0.0001) (Figures 3d,e). Importantly, relative to WT cells, Gpx4 knockout cells exhibited no significant increase in cold-induced cell death upon RSL3 treatment following a short cold exposure (8 hours) (Figure S3), confirming the specificity of these inhibitors under the test conditions. We therefore conclude that Gpx4 catalytic activity is required in BHK-21 cells during the course of cold exposure to actively oppose cold-induced cell death.
Given that Gpx4 activity acts as a major endogenous suppressor of ferroptosis31, we tested whether the cold-induced cell death observed under Gpx4 inhibition occurred via the ferroptosis pathway. To this end, we made use of two small molecule inhibitors of ferroptosis, ferrostatin-1, a lipophilic antioxidant, and deferoxamine mesylate (DFO), a Fe2+ chelator. Both inhibitors effectively rescued cold-induced cell death in the presence of the Gpx4 inhibitor RSL3 (Figure 3f), indicating that acute inhibition of Gpx4 activity in the cold drives cell death via ferroptosis. Together, through a combination of genetic and pharmacological approaches, our studies demonstrate that Gpx4 activity confers substantial cold resistance in hibernator-derived cells, protecting cells from cold-induced ferroptosis.
Genome-scale CRISPR screen identifies determinants of cold sensitivity in human cells
In contrast to hibernator-derived cell lines, human cells display varying cold sensitivities in culture, with some exhibiting pronounced intolerance to the cold (Figure 1d-g). Consistent with prior reports5,8,37, pharmacological experiments in several human cell lines (K562, HT1080, RPE, and HeLa cells) confirmed that cold-induced cell-loss occurred primarily via ferroptosis, with both antioxidant ferroptosis inhibitors (ferrostatin-1 and liproxstatin-1) and iron chelators (DFO and 2’2’-pyridine) increasing the cold survival in all four cell lines in a dose-dependent manner. By contrast, neither the Caspase inhibitor Z-VAD-FMK nor the necroptosis inhibitor necrostatin-1 significantly affected cell viability (Figure S5, S6).
To gain further insight into the genetic modifiers of human cell cold sensitivity and resistance, we designed and performed an additional CRISPR-Cas9 screen in cold-sensitive human K562 cells exposed to cold temperatures. A pooled lentiviral CRISPR-Cas9 library targeting 19,381 genes (∼5 sgRNAs per gene) was delivered to K562 cells at an MOI of ∼0.5. Transduced cells were placed at 4°C for five days to allow for cold-induced cell death to occur in approximately 79 ± 1.76% of cells, followed by a three-day rewarming to 37°C to allow for amplification of remaining cells (Figure 4a). This cold-rewarming cycle was repeated three times, with cells collected after each cycle to monitor the relative enrichment and depletion of individual sgRNAs. As in our prior screens, separate cultures transduced in parallel were maintained at 37°C for comparative analysis. In addition, to discriminate between ferroptosis-dependent and - independent regulators of cold tolerance, we conducted a parallel screen in cold-exposed K562 cells under continuous ferrostatin-1 treatment. As before, the efficiency and specificity of the screens were assessed based on effective depletion of characterized core essential genes24 as well as the lack of depletion of negative control guides (250 nontargeting and 125 intergenic sgRNAs) (Figure S7).
To our surprise, this screen did not identify any genes whose disruption significantly enhanced K562 cold tolerance. By contrast, we identified 176 genes selectively required during cold cycling relative to constant 37°C control conditions (FDR < 0.1, LFC < −0.1, and requiring >2 sgRNAs, Figure 4b). It is notable that K562 cold survival was sensitive to the targeting of larger number of genes than the BHK-21 line, potentially indicating increased dependencies on genetic pathways which are not essential in BHK-21 cells (Figure S8, Table S6). Among the pathways identified, we honed in on the selenocysteine incorporation pathway and observed GPX4 and the selenocysteine incorporation genes PSTK, SEPSECS, and EEFSEC within the top-ranked K562 cold-protective genes, suggesting that the GPX4 pathway confers significant resistance to the cold not only in cold-tolerant hibernator cells, but also in cold-sensitive human cells (Figures 4c-g). Notably, we identified 11 genes that were no longer essential (Fold enrichment > 0.50, FDR < 0.10) in the presence of Ferrostatin-1, indicating that these genes act to suppress cold-induced ferroptosis (Figures 4h-n, Table S4, S5). Although multiple pathways have been described as suppressors of ferroptosis in other contexts38–42, it is notable that 5 of 11 identified genes represent known components of the GPX4 pathway.
To confirm these findings, we generated three clonal GPX4 knockout K562 cell lines and confirmed the loss of GPX4 via immunoblotting (Figure 5a). Similar to our findings in BHK-21 cells, K562 GPX4 knockout clones exhibited stunted growth and were expanded in the presence of liproxstatin-1 (Figure S4b). Importantly, GPX4 loss greatly increased cold-induced cell death (****P < 0.0001) (Figures 5a), thus confirming an essential role for GPX4 in human cell cold tolerance. Similar effects were also observed upon acute pharmacologically inhibition of GPX4 with RSL3 or ML162 at 4°C (****P < 0.0001) (Figures 5b, c). These effects were dependent on GPX4 inhibition insofar as the cold tolerance of K562 GPX4 knockout cells was unaffected by RSL3 treatment (Figure S9). In addition, RSL3-driven cold-induced cell death was rescued by either ferrostatin-1 or DFO treatment, indicating that RSL3-induced cell loss occurs via the ferroptosis pathway (Figure 5d). Increased cold-induced death in the GPX4 knockout K562 cell lines could be rescued upon lentiviral expression of either the cytosolic human (hs) or hamster (ma) GPX4, but not GFP or catalytically dead GPX4 variants (Figure 5e). Together, our genetic and pharmacological studies reveal that K562 cells, despite being significantly less cold-tolerant than hamster BHK-21 cells, also rely on the GPX4 pathway to suppress cold-induced ferroptosis.
GPX4 catalytic activity is limiting for K562 cell cold tolerance
Given that the GPX4 pathway is active during cold exposure and essential for cold survival in both hamster BHK-21 and human K562 cells, it is somewhat surprising that these cell lines exhibit markedly different cold tolerances. In this regard, it has previously been suggested5 that upon cold exposure human cells, in contrast to hibernator-derived cells, rapidly deplete intracellular glutathione, an essential co-factor for GPX4 function, which could thus account for their increased cold sensitivity. To test this idea, we supplemented K562 growth media with either cell-permeable Glutathione reduced ethyl ester (GSH-MEE), N-acetyl-cysteine (NAC), or L-Cystine, a glutathione precursor; however, these interventions failed to significantly increase K562 cells’ cold tolerance under our culture conditions (Figure S10). We therefore examined the possibility that GPX4 protein levels in K562 cells are limiting for their cold tolerance. To this end, we generated K562 lines overexpressing either human or hamster GPX4. Both of these overexpression lines exhibited strikingly improved cold tolerance compared to the wild-type K562 parental line and a GFP-overexpressing control cell line (****P < 0.0001) (Figure 5f. Indeed, GPX4-overexpressing K562 cells displayed comparable cold tolerance to that of hibernator-derived BHK-21 cells (Figure 1d, g). To confirm that increased GPX4 catalytic activity was responsible for the improved cell cold tolerance, we generated additional K562 lines overexpressing catalytically dead forms of hamster or human GPX4 in which the active site selenocysteine was mutated to serine and found that these GPX4 mutant lines exhibited no increase in cold tolerance (Figure 5f). Taken together, these results strongly suggest that GPX4 abundance serve as a key limiting determinant of K562 cell cold tolerance. Moreover, our finding that human and hamster GPX4 overexpression confer comparable increases in K562 cold tolerance may indicate that the intrinsic activity of the hamster and human GPX4 enzymes are similar.
GPX4 activity is broadly required for cold tolerance in primary cells across evolutionarily distant mammalian species
Given that our studies had largely employed a small number of transformed cell lines, we sought to extend our investigation to examine cold tolerance in primary cell types as well as cells derived from additional hibernating species. To this end, we obtained primary and immortalized fibroblasts from human, mouse, and rat as well as from Syrian hamster, 13-lined ground squirrel (Ictidomys tridecemlineatus), and horseshoe bat (Rhinolophus ferrumequinum), three distantly related mammalian hibernators, and characterized their cold tolerance. While hibernator-derived fibroblasts exhibited robust, roughly uniform cold tolerance, we observed a surprisingly variable degree of cold tolerance across non-hibernator primary cells (Figure 6a), with human dermal fibroblasts exhibiting a remarkable 79 ± 4.93% cell viability after seven days at 4°C, comparable to that observed with hamster-derived BHK-21 cells.
To examine the role of GPX4 in primary cell cold resistance, we transduced cells with Cas9 and sgRNAs targeting human GPX4 to create a population of GPX4 knockout human kidney fibroblasts (Figure 6b). Consistent with our prior findings in cell lines, GPX4 loss resulted in significantly decreased viability in the cold, which was largely rescued by ferrostatin-1 treatment in fibroblast cells (Figure 6b). Indeed, RSL3 treatment significantly decreased the viability of wild-type cold-exposed human kidney fibroblasts (Figures 6c, d), and these effects were dependent on GPX4 inhibition as the cold tolerance of human kidney fibroblast GPX4 knockout cells was largely unaffected by RSL3 treatment (Figure S4c).
To more widely examine the dependence of primary cell cold tolerance on GPX4 activity, we obtained and tested fibroblasts derived from six mammalian species. We found the GPX4 activity widely contributes to cold tolerance across hibernators and non-hibernators was dependent on GPX4, as RSL3-treated cells showed increased cold-induced cell death that was largely rescued by ferrostatin-1 treatment (Figures 6e, f). We also extended these findings to a non-fibroblast cell type, obtaining similar results with primary cortical neuronal cultures prepared from neonatal mice and hamsters (Figures 6g, h). Taken together, our data indicate that primary cell types are strongly sensitive to GPX4 loss in the cold and suggest that their differential cold sensitivities may reflect different levels of GPX4-mediated cold tolerance.
Discussion
Hibernators can lower their body temperature to ∼4°C for several days to weeks, indicating that their cells and tissues possess the ability to survive extended periods of cold. Previous studies have indicated that ferroptosis contributes to cold-induced cell death in cultured human cells5,8,37; however, the genetic modifiers of cold sensitivity in hibernators and non-hibernators have yet to be systematically explored. Here, we conducted a series of unbiased genome-wide CRISPR-Cas9 screens in both hibernator- and non-hibernator-derived cells to investigate the mechanisms controlling cellular cold tolerance. Our findings, further validated using stable genetic knockout lines and pharmacological inhibitors, identify the GPX4 pathway as a critical suppressor of cold-induced cell death. Indeed, overexpression studies in human K562 cells suggest that GPX4 abundance can serve as a key limiting determinant of cellular cold tolerance. Notably, Sone et al.43 recently also identified GPX4 as a strong regulator of cold tolerance through overexpression screening. These independent findings further support the current study identifying GPX4 as a conserved suppressor of cold-induced cell death. The consistency of our observations across diverse cell lines and primary cells, including cells derived from six different mammalian species, argues that GPX4 serves as an essential and evolutionarily conserved mechanism to protect cells from cold-induced ferroptotic cell death.
During the course of our studies, we made the surprising observation that cells stained with the commonly employed membrane-impermeable dye trypan blue exhibit increased dye retention immediately after cold exposure, an artifact not reflecting genuine cell death. Rather, cell counting following brief rewarming yields more accurate results, in some cases reflecting significantly higher cell viability than previously appreciated. Employing this modified approach to measure cold-induced cell death across sixteen cell lines and primary cell types points to more nuanced variations in cold survival across cell types. These differences are highlighted by the pronounced contrast between the poor cold viability of human HT1080 cells and the robust cold tolerance observed in human fibroblasts. The underlying basis of this transient cell permeability for trypan blue following cold exposure remains unclear; however, it is noteworthy that in S. cerevisiae heat and chemical insults have been found to induce a brief window of membrane permeability to PI prior to membrane repair44. Likewise, uptake of propidium ions across intact cell membranes has been previously observed in bacteria showing high membrane potentials45. Our observations suggest that further investigation into the mechanisms underlying transient membrane permeability in different cell types and stress conditions could lead to improved methods for accurately measuring cell viability, ultimately enhancing our understanding of cellular stress.
We report, to our knowledge, the first genome-scale hibernator CRISPR-Cas9 screen in cells derived from Syrian hamster. To create a genome-scale CRISPR-Cas9 library, we implemented a CRISPOR-based computational pipeline for sgRNA selection and benchmarked its success by carrying out the hamster and human screens described here. Our validated sgRNA libraries and associated algorithms should serve as a valuable resource to the hibernation community, as well as other scientific communities developing CRISPR-based tools for non-model organisms.
While our data point to GPX4 levels as a major determinant of cellular cold tolerance, whether endogenous levels of functional Gpx4 across various cell types correlates with their cold tolerance remains to be tested. It also remains possible that other factors such as GPX4 subcellular localization, the abundance of the cellular selenocysteine incorporation machinery, the abundance of glutathione, as well as GPX4-pathway independent factors all play important roles in limiting cold tolerance across various cell types. Although we did not see an increase in cold cell viability upon treatment of K562 cells with GSH-MEE, it is notable that in our screens, sgRNAs targeting genes involved in the glutathione biosynthesis (e.g. GCLC, GSS46,47) showed increased depletion in cold-exposed K562 versus BHK-21 cells (Figure S10, Figure S11). This suggest a reduced dependency on the conventional glutathione biosynthetic pathway in cold-exposed BHK-21 cells. In addition, while our data points to a key cellular need to reduce cold-associated lipid hydroperoxides, the mechanisms that drive peroxide accumulation in the cold remain unclear. Specifically, the roles of reactive oxygen species (ROS) production, polyunsaturated fatty acid (PUFA) levels, and free iron concentration should be further explored to understand the specific drivers of cold-induced ferroptotic cell death. Such insights have the potential to inform the development of more effective strategies for managing conditions exacerbated by cold exposure, such as ischemic injuries and organ transplantation.
We limited our current investigations to cell culture paradigms. However, future in vivo studies in hibernating organisms that naturally undergo profound drops in core body temperature could yield further insight into the adaptive mechanisms that govern cellular survival during periods of hibernation and torpor, while also allowing for the study of cold tolerance mechanisms in cell types that cannot presently be maintained in culture. Similarly, a Gpx4 conditional knockout mouse line has been generated and used to show that Gpx4 is essential for mitochondrial integrity and neuronal survival in adult animals48; however, these animals have not yet been used to evaluate the contribution of Gpx4 to in vivo cellular and tissue cold tolerance.
The ability to hibernate and survive long-term cold exposure is present in many mammalian species from rodents to bats to primates, raising the possibility that the ability to enter hibernation and tolerate cold was an ancestral trait present in protoendotherms. Our observation that a single pathway centered around GPX4 is required across diverse mammalian species to protect cells from cold-induced cell death, raises a question whether GPX4 has a role in protection from cold-induced ferroptosis in other cold-tolerant vertebrates including fish, amphibians, reptiles, and birds that also enter torpor. Such studies will advance our understanding of the evolved mechanisms by which cells mitigate cold-associated damage— one of the most common challenges faced by cells and organisms in nature.
Acknowledgements
We thank Wei Li for generously sharing 13-lined ground squirrel (Ictidomys tridecemlineatus) fibroblasts and Thomas P. Zwaka for sharing greater horseshoe bat (Rhinolophus ferrumequinum) fibroblasts. We thank Amanda Chilaka and Sumeet Gupta of the Whitehead Institute Genome Technology Core for high-throughput sequencing. We thank Aurora Lavin-Peter, Aleksandar Markovski, Tara Thakurta, William S. Owens, Sheamin Khyeam, Karina Smolyar, and Elena Assad for their technical support. We thank Whitney Henry, Matthew Vander Heiden, Alison Ringel, Morgan Sheng, Myriam Heiman, and members of the Hrvatin laboratory for providing feedback on the study. Schematics created with BioRender.com. This material is based upon work supported by the National Science Foundation Graduate Research Fellowship under Grant No. 2141064 and The Paul and Daisy Soros Fellowship for New Americans (PSM). Research reported in this publication was supported by The G. Harold and Leila Y. Mathers Charitable Foundation and the NIDDK/NIH under Award Number DP2DK136123. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.
Additional information
Author contributions
B.L., K.M.K., and S.H. conceived and designed the study. B.L. and K.M.K. designed, performed, and analyzed experiments. B.L., K.M.K., H.R.K. designed and performed genome wide CRISPR screens. A.K. assisted with the genome wide CRISPR screens. B.L. performed the genetic and pharmacological studies to validate the screens. K.M.K. performed the experiments with primary cells. E.M.F. and G.W.B. designed algorithms to select genome-wide Syrian hamster (Mesocricetus auratus) CRISPR library. M.E.B. and P.B. immortalized mouse embryonic fibroblasts and greater horseshoe bat (Rhinolophus ferrumequinum) fibroblasts. J.M.R., R.J., J.S.W., and E.C.G. advised on the study. B.L., S.H., and E.C.G led the writing of the manuscript with contributions from other authors. E.C.G. and S.H. obtained funding for the research. All authors approved and reviewed the manuscript.
Declaration of interests
The authors declare no competing interests.
Methods
Cell culture
Two hibernator-derived (BHK-21, HaK) and four non-hibernator-derived (HT1080, RPE1, HeLa, K562) cell lines were used. All cells were purchased from ATCC. K562 cells were cultured in Roswell Park Memorial Institute (RPMI) 1640 Medium (Gibco #11875093) supplemented with 10% fetal bovine serum (GeminiBio #100-106) and 1% penicillin/streptomycin. The remaining cells were cultured in Dulbecco’s modified Eagle’s medium (DMEM) (Thermo Fisher Scientific #12430054) supplemented with 10% fetal bovine serum (GeminiBio #100-106) and 1% penicillin/streptomycin (Thermo Fisher Scientific #15140122).
Cell viability assay
Cells were seeded on 24-well culture plates at 50,000 cells per well and allowed to adhere for 24 hours at 37°C. Cells were then placed at 4°C with 5% CO2 for varying time periods (1, 4, or 7 days), with a 30-minute rewarming at 37°C before assessing cell viability via trypan blue (TB) (Thermo Fisher Scientific #15250061) staining. To assess cell viability using the TB assay, cells were washed with PBS (Thermo Fisher Scientific #10010023), trypsinized and centrifuged at 300 x g for 3 minutes. The resulting pellet was resuspended in media, TB was added to a final concentration of 0.2%, and cells were manually counted using a hemocytometer.
Cell death assay (LDH)
The amount of LDH in the supernatant was measured using the LDH-Glo Cytotoxicity Assay (Promega J2380) following the manufacturer’s protocol. The samples were mixed with reagents on microplates, and luminescence was measured after a 30-minute incubation at room temperature. The maximum amount of LDH in each was measured by fully lysing replicate wells with 2% Triton X-100 (Thermo Fisher Scientific #A16046.AE). Background LDH signal was measured from media-only wells and subtracted from sample values before normalization to fully lysed wells in order to determine the amount of cytotoxicity per sample.
Compound sources
ML162 (SML0521), RSL3 (SML2234), erastin (E7781), 2’2’-Bipyridyl (D216305), and necrostatin-1 (N9037°C) were obtained from MilliporeSigma. Ferrostatin-1 (S7243), Liproxstatin-1 (S7699), and z-VAD-FMK (S7023) were purchased from Selleck Chemicals LLC. Deferoxamine mesylate (ab120727) was purchased from Abcam.
Genome-wide library design
sgRNAs targeting the hamster genome build GCF_017639785.1 (BCM_Maur_2.0) were designed based on NCBI Refseq gene annotations. Protein-coding regions of all gene exons were filtered to retain only the most constitutively expressed exons and extended 20 nt on each end. These regions were provided as input for CRISPOR49 to pick and score all potential guides. For each gene, guides were filtered by potential problem flags and then ranked by an overall score derived from its efficiency (the Doench16/Fusi score), a custom motif penalty, a fractional frameshift (from the Lindel score and the fractional distance to the beginning of the region), and its specificity (derived from the MIT specificity score). For each gene, after the guide with the best score was chosen, subsequent guides were also penalized by a location score, adding a penalty for presence in the same exon and proximity to previously selected guides for the same gene. If more than ten potential guides were identified for a gene, the ten with the highest scores were selected.
For the human genome-wide library, we obtained a list of protein-coding genes in human based on Ensembl release 98. The top five sgRNAs were picked for protein-coding genes and controls, for a total of 102223 sgRNAs. Human intergenic sgRNAs were chosen by first subsetting the list of all designed intergenic-region-targeted sgRNAs by Rank = 1, then requiring the sgRNAs to target only one genomic locus. This list of 465 sgRNAs was ranked by MIT specificity score in descending order, and the top 449 sgRNAs were chosen.
Library cloning
For the hamster library, 214,116 unique protospacer sequences targeting ∼21,000 unique gene symbols (> 99% with 10 sgRNAs/gene symbol), along with 2,299 intergenic-targeting and 250 nontargeting sequences were synthesized as an oligonucleotide pool (Agilent Technologies). Separately, for the human library, 98,077 unique protospacer sequences targeting ∼19,600 Ensembl transcript IDs (> 99.9% with 5 sgRNAs/gene), 449 intergenic-targeting sequences, 50 non-targeting sequences, and one sequence targeting the AAVS1 safe harbor locus were synthesized as an oligonucleotide pool (Agilent Technologies). A guanine nucleotide was prepended to each 20-nucleotide protospacer sequence that began with A, C, or T. For both hamster and human libraries, homology arms were prepended (5’-TATCTTGTGGAAAGGACGAAACACC-3’) and appended (5’-GTTTAAGAGCTATGCTGGAAACAGCATAGC-3’). Additional adapters were pre- and appended to the hamster library to enable subpool amplification if desired (subpool 1: 5’-TCGGTGTATTGCTAGTGCGAACCCA-3’ and 5’-ATCGTGTGAAAGGTGCCGCTATTGC-3’; subpool 2: 5’-GGTTCGTTCTACACATGGAAGCGGC-3’ and 5’-GAGGACTTCGAGTAGAACGCTGGCG-3’). Oligonucleotide pools were PCR amplified (forward primer: 5’-TTTCTTGGCTTTATATATCTTGTGGAAAGGACGAAACACC-3’; reverse primer: 5’-ATTTAAACTTGCTATGCTGTTTCCAGCATAGCTCTTAAAC-3’) and cloned into pLentiCRISPRv2-Opti (a gift from David Sabatini; Addgene plasmid # 163126; http://n2t.net/addgene:163126; RRID:Addgene_163126). Briefly, 0.25 µL of a 100 nM pool was PCR amplified in 50 µL reactions using Q5 HotStart DNA Polymerase (New England Biolabs) for 10 cycles under the following conditions:
All concentration steps were performed using a DNA Clean and Concentrator-5 kit (ZymoResearch). Amplification from 8 gradient annealing reactions (55-62 °C) was assessed, and successful reactions were pooled and concentrated. The vector was digested overnight at 37 °C with FastDigest Esp3I and FastAP (ThermoFisher Scientific), gel purified using a Zymoclean gel DNA recovery kit (ZymoResearch), and concentrated. NEBuilder HiFi DNA Assembly Master Mix (New England Biolabs) was used in 2 x 40-80 µL bulk assembly reactions, for a combined total reaction volume of 160 µL containing 4 µg of vector and 160 ng of PCR amplicon (hamster) or 120 µL total containing 3 µg of vector and 120 ng of PCR amplicon (human). Each bulk reaction was distributed in 5 µL aliquots and incubated for 10 minutes at 52.2 °C, pooled, concentrated, introduced into Endura Electrocompetent DUO cells (Lucigen) by electroporation, and plated on 8-16 LB agar with 75 µg/mL carbenicillin in 245 mm x 245 mm square bioassay dishes. A dilution series was also plated to assess electroporation efficiency. Cells were incubated overnight at 30 °C, collected, and DNA was isolated using a ZymoPURE II Plasmid DNA Maxiprep kit (ZymoResearch). Plasmid from separate electroporations was combined proportionally based on electroporation efficiency for a combined total library coverage of > 50-fold for each library. Sequence representation in the libraries was assessed as described below.
Lentivirus production for CRISPR-Cas9 screen
For large-scale virus production, HEK-293T (1.5×107) cells were seeded in T175 cm2 flasks in DMEM (Thermo Fisher Scientific #12430054) supplemented with 10% fetal bovine serum (GeminiBio #100-106). Media was changed 24 hours later to 20 mL viral production medium: IMDM (Thermo Fisher Scientific #1244053) supplemented with 20% heat-inactivated fetal bovine serum (GeminiBio #100-106). Cells were transfected 8 hours later with a mix containing 76.8 µL Xtremegene-9 transfection reagent (MilliporeSigma #06365779001), 3.62 µg pCMV-VSV-G (Addgene plasmid # 8454; http://n2t.net/addgene:8454; RRID:Addgene_8454)50, 8.28 µg psPAX2 (a gift from Didier Trono; Addgene plasmid # 12260; http://n2t.net/addgene:12260; RRID:Addgene_12260), and 20 µg sgRNA/Cas9 plasmid and Opti-MEM (Thermo Fisher Scientific #11058021) to a final volume of 1 mL. Media was changed 16 hours later to 55 mL fresh viral production medium. Viral supernatant was collected and filtered through a 0.45 µm filter and aliquoted 48 hours post-transfection, then stored at −80°C until use.
CRISPR screen in K562 cells
K562 cells (3.9×108) were transduced with a pooled genome-wide lentiviral sgRNA library in a Cas9-containing vector at MOI <1. The transduced cells were selected with 3 µg/mL puromycin (Thermo Fisher Scientific #A1113803), and 1×108 cells were passaged every 48-72 hours at a density of 6×105 cells/T175 cm2 flask in 45 mL RPMI 1640 (Gibco #11875093) medium supplemented with 10% fetal bovine serum (GeminiBio #100-106) and 1% penicillin/streptomycin for the duration of the screen. At 5 days post-puromycin selection, 1×108 cells were exposed to the cold with or without 1 µM ferrostatin-1 (Selleck Chemicals #S7243). K562 cells (1×108) were collected from the each of surviving populations after cold exposure and/or rewarming as well as a matched untreated population. Genomic DNA was isolated using the QIAmp DNA Blood Maxiprep kit (Qiagen # 51192), and high-throughput sequencing libraries were prepared.
CRISPR screen in BHK-21 cells
BHK-21 cells (8.55×108) were transduced with a pooled genome-wide lentiviral sgRNA library in a Cas9-containing vector at an MOI of 0.25. Transduced cells were selected with 2 µg/mL puromycin (Thermo Fisher Scientific #A1113803), and 2.56×108 cells were passaged every 48-72 hours at a density of 5×106 cells/15-cm dish in DMEM (Thermo Fisher Scientific #12430054) medium supplemented with 10% fetal bovine serum (GeminiBio #100-106) and 1% penicillin/streptomycin for the duration of the screen. At 6 days post-puromycin selection, 2.56×108 cells were exposed to the cold. Cells (2.4×108) were collected from each of the surviving populations after cold exposure and/or rewarming as well as from a matched untreated population. During the cycles, cells were placed at 4°C for 4 days, then rewarmed to 37°C for 24 hours, reseeded, and after a further 24 hours at 37°C were placed back at 4°C to begin a subsequent cycle. Genomic DNA was isolated using the QIAmp DNA Blood Maxiprep kit (Qiagen # 51192), and high-throughput sequencing libraries were prepared.
Sequencing library preparation
The QIAamp DNA Blood Maxiprep Kit (Qiagen # 51192) was used to extract genomic DNA (gDNA) from cell pellets of 2.5-5×107 cells according to manufacturer’s instructions with minor modifications: QIAGEN Protease was replaced with 500 µL of 10 mg/mL Proteinase K (MilliporeSigma # 3115879001) in water, and cells were lysed overnight; centrifugation was performed for 2 minutes and 5 minutes after the first and second wash, respectively; 1 mL of water preheated to 70 °C was used to elute gDNA, followed by centrifugation for 5 minutes. gDNA was quantified using the Qubit dsDNA HS Assay kit (Thermo Fisher Scientific #Q32851). PCR amplification of sgRNA sequences was performed in 50 µL reactions using ExTaq Polymerase (Takara Bio #RR001B) with the following program:
Using the following primers:
Forward: 5’- AATGATACGGCGACCACCGAGATCTACACCCCACTGACGGGCACCGGA - 3’ Reverse: 5’- CAAGCAGAAGACGGCATACGAGATCnnnnnnTTTCTTGGGTAGTTTGCAGTTTT - 3’
Where “nnnnnn” denotes the barcode used for demultiplexing.
Plasmid libraries were amplified for 16 cycles using 10 ng input per 50 µL reaction. gDNA was initially amplified for 24 (human) or 28 (hamster) cycles in 50 µL test PCR reactions with 1, 3, 4, 5, or 6 µg input. An additional 20-75 reactions were performed using 3-6 µg per reaction (sampling 150 µg or 300 µg gDNA total for human and hamster screens, respectively). Select-a-Size DNA Clean and Concentrator (Zymo Research #D4080) or HighPrep PCR (MagBio Genomics) was used to purify 95-100 µL of each pooled sample, which were eluted with 12-20 µL water and quantified using the Qubit dsDNA HS Assay kit prior to sequencing for 50 cycles on an Illumina Hiseq 2500 or NovaSeq using the following primers:
Read 1 sequencing primer: 5’-
GTTGATAACGGACTAGCCTTATTTAAACTTGCTATGCTGTTTCCAGCATAGCTCTTAAAC - 3’ Index sequencing primer: 5’-
TTTCAAGTTACGGTAAGCATATGATAGTCCATTTTAAAACATAATTTTAAAACTGCAAACTAC CCAAGAAA - 3’
CRISPR screen data analysis
Sequencing reads from the human screen were trimmed and mapped to the sgRNA library using Bowtie version 1.0.051, allowing no mismatches, and counted. Sequencing reads from the hamster screen were trimmed and mapped to the sgRNA library using a combination of command line prompts and a custom Python function which generated a dataframe of counts which perfectly (no permissibility for any base mismatches) matched sequenced reads to the full guide library (code supplied on Github). Data from both human and hamster screens was similarly analyzed using MAGeCK version 0.5.9.552 using a gene test false discovery rate (FDR) threshold of 0.05, the FDR method for p-value adjustment, and the median as the gene-level scoring metric.
PANTHER overrepresentation test was conducted on a set of 204 genes (FDR < 0.1) from the third cycle of the human K562 CRISPR-Cas9 screen [‘Analyzed List’]. A list of genes expressed in K562 cells at 37°C collected from bulk RNA sequencing was used as the [‘Reference List’]: https://pantherdb.org/tools/compareToRefList.jsp. Fisher’s Exact test type and false discovery rate correction were utilized. Bulk RNA sequencing of K562 cells at 37°C was conducted by generating a cDNA library prepared by depleting rRNA using the NEBNext rRNA Depletion Kit (Human/Mouse/Rat) (New England Biolabs) and then the NEBNext Ultra II Directional RNA Library Prep Kit (New England Biolabs). cDNA libraries were amplified using appropriate multiplexed index primers for PCR.
Data was visualized using R version 4.2.153 corrplot package version 0.9254 and base graphics, and GraphPad Prism version 10.
Generation of stable CRISPR/Cas9-targeted cell lines
Homology arms were prepended (5’-TATCTTGTGGAAAGGACGAAACACC-3’) and appended (5’-GTTTAAGAGCTATGCTGGAAACAGCATAGC-3’) to the top two ranked human or hamster GPX4-targeting guides from the genome-wide screens. These guides were PCR amplified and cloned into pLentiCRISPRv2-Opti (a gift from David Sabatini; Addgene plasmid # 163126; http://n2t.net/addgene:163126; RRID:Addgene_163126). K562 and BHK-21 cells were then infected with LentiCRISPRv2. Transduced cells were selected with 3 µg/mL puromycin (Thermo Fisher Scientific #A1113803) for K562 cells and 2 µg/mL for BHK-21 cells beginning two days after infection. After one passage, cells were sorted (BD FACSAria™ Fusion Flow Cytometer) into 96-well plates, at one cell per well to generate clonal knockout cell lines. Cells were cultured in media with 2.5 µM liproxstatin-1 (Selleck Chemicals #S7699) to prevent cell death. Western blotting was used to confirm GPX4 loss in individual knockout clones prior to further use.
Human sgRNA:
5’- CGTGTGCATCGTCACCAACG - 3’
5’- CTTGGCGGAAAACTCGTGCA - 3’
Hamster sgRNA:
5’- CGTGTGCATCGTCACCAACG - 3’
5’- CTTGGCTGAGAATTCGTGCA - 3’
Generation of CRISPR/Cas9-targeted human kidney fibroblast pooled cells
Primary human kidney fibroblasts were infected with LentiCRISPRv2 with sgRNAs targeting GPX4, using the top two ranked GPX4-targeting guides from the genome-wide human k562 screen. Transduced cells were selected with 1 µg/mL puromycin (Thermo Fisher Scientific #A1113803) beginning four days after infection. Cells were cultured in media with 2.5 µM liproxstatin-1 (Selleck Chemicals #S7699) to prevent cell death. Western blotting was used to confirm GPX4 loss in individual knockout clones prior to further use.
Immuoblotting
Cells were plated at 6×105 cells per well in a 6-well plate and maintained overnight at 37°C. Cells were then collected when wells were confluent. The media was aspirated, and cells were washed with ice-cold PBS (Thermo Fisher Scientific #10010023). Cells were scraped in 100 µL of RIPA buffer (150 mM NaCl, 1% Triton X-100, 0.5% Na-Dexycholate, 0.1% SDS, 50 mM Tris, pH 8) with protease inhibitors (MilliporeSigma #04693159001) and collected in microcentrifuge tubes. The contents were then vortexed for 30 minutes at 4°C and centrifuged at 16000 x g for 20 minutes at 4°C. Protein content of the samples was measured using the Pierce BCA Protein Assay kit (Thermo Fisher Scientific #23225) and resuspended in 100 µL of RIPA buffer with protein loading dye (10% SDS, 500 mM DTT, 50% Glycerol, 250 mM Tris-HCl and 0.5% bromophenol blue dye, pH 6.8). Protein samples were boiled for 5 minutes at 95°C, vortexed, and centrifuged at 16000 x g for 5 minutes before loading onto a gel. The gel was run at 120 V for 2 hours before being transferred to a Polyvinylidene difluoride (PVDF) membrane (Thermo Fisher Scientific #88518). The transfer cassette was run at 45 V for 2 hours. The membranes were then transferred to 5% milk TBST (1X Tris-Buffered Saline, 0.1% Tween® 20 Detergent) and shaken for 15 minutes before being washed in TBST. Primary antibodies recognizing GPX4 (Abcam #ab41787) or HA (Cell Signaling Technology #3724) were added at 1:1000 in 5% BSA (MilliporeSigma #A9418) and incubated overnight at 4°C. The membrane was then washed 3 times in 1x TBST and 1:3000 anti-rabbit secondary antibody (Cell Signaling Technology #7074) in 5% milk TBST was added. Membranes were incubated for 1 hour at room temperature and washed 3x in 1x TBST. Membranes were then incubated in Pierce™ ECL Western Blotting Substrate (Thermo Fisher Scientific #32106) for 5 minutes before imaging.
Generation of HA-GPX4 and HA-GFP overexpression constructs
To generate GPX4-overexpression lines, entire human GPX4 (cytosolic; NM_001367832.1) and hamster Gpx4 were amplified from the cDNA of K562 and BHK-21 cells, respectively. The cloned transcript fragments include the 3’ UTR that contains the SECIS element necessary for selenocysteine incorporation. The GPX4 genomic DNA fragments were cloned into pLJM1 (Addgene plasmid # 19319; http://n2t.net/addgene:19319; RRID:Addgene_19319) and confirmed via sequencing. To create GPX4 mutants, (U46S), non-overlapping primers were used to create mutations via inverse PCR, as previously described55, converting the UGA stop codon to UCA, encoding serine. GFP was amplified from pLJM1-EGFP (Addgene plasmid # 19319; http://n2t.net/addgene:19319; RRID:Addgene 19319) with Gibson overhangs to enable insertion into a lentivirus vector. HA-GPX4 and HA-GFP DNA fragments were then amplified by PCR and cloned into blasticidin lentiviral vectors [gift from Whitney Henry at the Whitehead Institute for Biomedical Research] using standard cloning methods, with point mutations in the PAM and guide sequences to prevent targeting of exogenously expressed GPX4.
HEK-293T cells (5×105) were seeded in 2 wells of a 6-well plate in DMEM (Thermo Fisher Scientific #12430054) supplemented with 10% fetal bovine serum (GeminiBio #100-106). Media was changed 16 hours later to 2 mL per well of viral production medium: IMDM (Thermo Fisher Scientific #1244053) supplemented with 20% heat-inactivated fetal bovine serum (GeminiBio #100-106). Cells were transfected 8 hours later with a mix containing 4.22 µL Xtremegene-9 transfection reagent (MilliporeSigma #06365779001), 181 ng pCMV-VSV-G (Addgene plasmid # 8454; http://n2t.net/addgene:8454; RRID:Addgene_8454)50, 414 ng psPAX2 (a gift from Didier Trono; Addgene plasmid # 12260; http://n2t.net/addgene:12260; RRID:Addgene_12260), and 1 µg HA-GPX4 or HA-GFP plasmid and Opti-MEM (Thermo Fisher Scientific #11058021) to a final volume of 50 µL per well. Media was changed 16 hours later to 2.5 mL per well of fresh viral production medium. Viral supernatant was collected and aliquoted 48 hours post-transfection, then stored at −80°C until use.
K562 or BHK-21 cells (6×105, wild-type and GPX4 knockout clones) were transduced with the lentiviral HA-tagged GPX4 or GFP in the presence of 10 µg/mL polybrene. After 8 hours of incubation at 37°C, media was changed to virus-free media. After 48 hours, the transduced cells were selected with blasticidin (Thermo Fisher Scientific #A1113903) at a concentration of 6 µg/mL for K562 cells and 4 µg/mL for BHK-21 cells. Overexpression of GPX4 and GFP was confirmed via immunoblotting.
Primary cell culture
Three hibernator (13-lined ground squirrel postnatal dermal fibroblasts [gift from Wei Li at Duke University], SV40-immortalized Greater horseshoe bat embryonic dermal fibroblasts [gift from Rudolf Jaenisch at the Whitehead Institute for Biomedical Research], and Syrian golden hamster embryonic primary dermal fibroblasts [isolated]) and five non-hibernator (mouse embryonic SV40-immortalized dermal fibroblasts [gift from Jonathan Weissman at the Whitehead Institute for Biomedical Research], adult human kidney fibroblasts [purchased from ATCC], adult human dermal fibroblasts [purchased from ATCC], adult rat dermal fibroblasts [purchased from ATCC], and adult mouse fibroblasts [purchased from ATCC]) primary cells were cultured in Dulbecco’s modified Eagle’s medium (Thermo Fisher Scientific #12430054) supplemented with 10% fetal bovine serum (GeminiBio #100-106) and 1% penicillin/streptomycin (Thermo Fisher Scientific #15140122). Cells were seeded on 24-well culture plates at ∼50,000 cells per well and allowed to adhere for 24 hours at 37°C. Cells were then placed at 4°C with 5% CO2 for varying time periods (1, 4, or 7 days), with a 30-minute rewarming at 37°C before assessing cell viability via trypan blue (TB) (Thermo Fisher Scientific #15250061) staining. To assess cell viability using the TB assay, cells were washed with PBS (Thermo Fisher Scientific #10010023), trypsinized and centrifuged at 300 x g for 3 minutes. The resulting pellet was resuspended in media, TB was added to a final concentration of 0.2%, and cells were manually counted using a hemocytometer.
Primary neuron isolation and culture
Primary Syrian golden hamster and C57BL/6 mouse cortical neurons were isolated at postnatal day 0. The day before isolation, standard tissue culture treated plates were coated with 3 µg/mL Poly-L-Ornithine (MilliporeSigma #P4957) and warmed at 37°C for 24 hours. The morning of isolation, wells were washed with 1X PBS (Thermo Fisher Scientific #10010023). To isolate neurons, pups were placed on ice for 2-5 minutes until movement ceased. Afterwards, they were washed with 10% ethanol, decapitated, and their heads placed in a 10x dissociation media bath (10.16 g MgCl2 hexahydrate and 11.915 g HEPES in 450 mL HBSS brought to a pH of 7 using NaOH with subsequent addition of 1.182 g of kynurenic acid heated to 65% while stirring until the solution was fully dissolved and cooled to room temperature and adjusted to a pH of 7.2. The dissociation media was then diluted from 10X to 1X in HBSS and filtered through a 0.22-µm vacuum filter). Dissected brains were placed in fresh dissociation media, where the cortices were dissected out and transferred to 50 mL Falcon tubes on ice containing 1X dissociation media. Afterwards, the dissociation media was removed from the cortices and replaced with papain solution (5 mL 1x dissociation media, 5-7 grains of L-Cyteine, and 172 µL Worthington papain [crystalline suspension in 50mM sodium acetate, pH 4.5 incubated in 1.1mM EDTA, 0.067mM mercaptoethanol and 5.5mM cysteine-HCl at 37°C. Activates to 20 units per 1 mg protein]) that was preheated to 37°C for 30 minutes. The cortices were incubated in the papain solution for 3-5 minutes at 37°C. Afterwards, the papain solution was replaced with trypsin inhibitor solution (10 mg of trypsin inhibitor dissolved in 10 mL of 1X dissociation media, preheated to 37°C) and incubated subsequently at 37°C for 3-5 minutes, repeated 3 times. Afterwards, the trypsin inhibitor solution was carefully removed and replaced with 6 mL of preheated complete neurobasal media (5 mL of GlutaMAX5, 10 mL of B-27, 5 mL of penicillin/streptomycin in neurobasal media filtered through a 0.22-µm vacuum filter). Using a 5 mL pipette tip, corticies were triturated until no tissue clumps were present. The cortices were then passed through a 100-µm cell strainer to remove large debris and centrifuged at 300 x g for 3 minutes before resuspension in 5 mL of complete neurobasal media before plating at a density of 50,000 mixed cortical neuron isolated cells per well of a 24 well plate. Subsequently, 50% of the media was replaced every second day with fresh 37°Ç pre-warmed media.
Statistical analyses and software information
Data are generally plotted as mean ± S.E.M. unless otherwise indicated. No statistical methods were used to predetermine sample sizes. Unless otherwise indicated, all replication numbers in the figure legends (n) indicate biological replicates. Statistical significance was determined using a two-tailed Student’s T-test, one-way ANOVA, or two-way ANOVA using Prism 10 software (GraphPad Software) unless otherwise indicated. Statistical significance was set at p<=0.05 unless otherwise indicated. Figures were finalized in Adobe Illustrator 2024.
Supplement
Tables
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