Abstract
Background
Genome-wide association studies and candidate gene association studies have identified more than 180 genetic variants statistically associated with anthracycline-induced cardiotoxicity (AIC). However, the lack of functional validation has hindered the clinical translation of these findings.
Objectives
The aim of this study was to functionally validate all genes associated with AIC using human induced pluripotent stem cell–derived cardiomyocytes (hiPSC-CMs).
Methods
Through a systemic literature search, 80 genes containing variants significantly associated with AIC were identified. Additionally, 3 more genes with potential roles in AIC (GSTM1, CBR1, and ERBB2) were included. Of these, 38 genes exhibited expression in human fetal heart, adult heart, and hiPSC-CMs. Using clustered regularly interspaced short palindromic repeats/Cas9–based genome editing, each of these 38 genes was systematically knocked out in control hiPSC-CMs, and the resulting doxorubicin-induced cardiotoxicity (DIC) phenotype was assessed using hiPSC-CMs. Subsequently, functional assays were conducted for each gene knockout on the basis of hypothesized mechanistic implications in DIC.
Results
Knockout of 26 genes increased the susceptibility of hiPSC-CMs to DIC. Notable genes included efflux transporters (ABCC10, ABCC2, ABCB4, ABCC5, and ABCC9), well-established DIC-associated genes (CBR1, CBR3, and RAC2), and genome-wide association study–discovered genes (RARG and CELF4). Conversely, knockout of ATP2B1, HNMT, POR, CYBA, WDR4, and COL1A2 had no significant effect on the in vitro DIC phenotype of hiPSC-CMs. Furthermore, knockout of the uptake transporters (SLC28A3, SLC22A17, and SLC28A1) demonstrated a protective effect against DIC.
Conclusions
The present findings establish a comprehensive platform for the functional validation of DIC-associated genes, providing insights for future studies in DIC variant associations and potential mechanistic targets for the development of cardioprotective drugs.
Key Words: cardiomyocytes, doxorubicin, genomics, GWAS, human induced pluripotent stem cells
Central Illustration
Anthracyclines, primarily doxorubicin, constitute a key component in about 60% of cancer treatment regimens,1 with approximately 35% administered to patients with breast cancer. Despite their efficacy, doxorubicin-induced cardiotoxicity (DIC) occurs in a dose-dependent manner in about 9% of patients, and 98% of these cases emerge within the first year of treatment.2 DIC encompasses 4 major interrelated molecular mechanisms: 1) generation of reactive oxygen species (ROS); 2) mitochondrial dysfunction; 3) DNA damage involving TOP2B; and 4) calcium overload leading to sarcomere damage. These mechanisms collectively lead to cardiomyocyte death, clinically determined by troponin detection in peripheral blood and reduced left ventricular ejection fraction.
To date, 5 genome-wide association studies (GWAS)3, 4, 5, 6, 7 and 20 candidate gene association studies8 have identified 80 genes with single-nucleotide polymorphisms (SNPs) significantly linked to anthracycline-induced cardiotoxicity (AIC).8 Despite this, only 1 AIC-associated variant locus (in SLC28A3) has been independently replicated.9,10 Thus, the functional validation of AIC-associated variants remains a critical prerequisite before incorporating this information into clinical practice.
The AIC-associated genes can be categorized into 6 major groups on the basis of their hypothesized mechanistic function. 1) Genes associated with ROS production and handling: doxorubicin induces ROS generation predominantly by reduction in the mitochondria, producing semiquinone-producing superoxide (O2+) free radicals. 2) Genes related to DNA damage: doxorubicin inflicts DNA damage on cardiomyocytes either by direct intercalation with DNA or by disruption of DNA repair after cleavage by TOP2B. 3) Genes associated with iron uptake: doxorubicin, with a high affinity for iron, can alter iron metabolism through interactions with iron regulatory proteins, stabilizing transferrin transcripts and inhibiting the expression of iron-sequestering proteins.11 4) Genes associated with transporters controlling doxorubicin uptake and efflux: generally, variants in uptake transporters (ie, members of the solute carrier [SLC] family) are protective against AIC by reducing doxorubicin transport into cardiomyocytes.9,10,12,13 Conversely, variants in efflux transporters (adenosine triphosphate–binding cassette [ABC]) are linked to increased intracellular doxorubicin concentration and AIC.14 5) Genes involved in calcium handling: doxorubicin directly binds to ryanodine receptors, inducing calcium release from sarcoplasmic reticulum.15 It also enhances L-type calcium channel activity,16 leading to an increased level of intracellular calcium. 6) Genes related to altered electric currents in the cardiomyocytes: after doxorubicin treatment, this can result in impaired contractile function.17
Previously, we demonstrated that human induced pluripotent stem cell–derived cardiomyocytes (hiPSC-CMs) accurately recapitulate patient-specific cardiotoxic responses to doxorubicin.13,18,19 In the present study, we functionally validate the role of 38 genes associated with anthracycline cardiotoxicity in patients with cancer using clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9–based knockout (KO) in hiPSC-CMs, followed by an array of in vitro characterization assays. Our work confirms that 31 genes, identified in GWAS and candidate gene association studies, play mechanistic roles in DIC at the cellular level. This approach provides insights into the impact of each gene KO on DIC development and their potential mechanistic pathways.
Methods
Variant and gene candidate identification
Following a comprehensive PubMed search involving both original and review papers investigating genetic risk factors associated with DIC, we compiled a list of potential candidates. These candidates underwent testing for their expression levels in hiPSC-CMs, adult human heart, and fetal human heart19 (Supplemental Table 1).
Human induced pluripotent stem cell culture, CRISPR/Cas9-mediated KO generation, and differentiation to cardiomyocytes
For detailed information, refer to the Supplemental Methods. We used a control male hiPSC line with an exogenous TNNT2 promoter–driven phleomycin D1 resistance cassette for cardiomyocyte purification, as previously described.13 All protocols received approval from the Northwestern University Institutional Review Board. Pairs of CRISPR/Cas9 guide RNAs were designed with a separation of >50 bp to induce a large deletion within the earliest common exon of each gene. Supplemental Tables 2 to 4 display all used primers for single guide RNA expression vector generation, a list of potential off-targets, and sequencing primers. We selected 1 KO hiPSC line with the lowest expression of each gene, which was then differentiated into cardiomyocytes and assessed on day 30.
Statistical methods
Data are expressed as mean ± SEM. Comparisons were conducted using 1- or 2-way analysis of variance or unpaired 2-tailed Student’s t-tests, with significant differences defined as P < 0.05, P < 0.01, P < 0.001, and P < 0.0001.
For more detailed methods, refer to the Supplemental Appendix.
Results
DIC-associated gene prioritization, KO generation, and in vitro doxorubicin toxicity measurement
We compiled a table of 429 SNPs associated with DIC, with 180 being unique (Supplemental Table 1). From this meta-analysis, we identified 80 SNP-harboring genes significantly linked to AIC. Our bioinformatic analysis did not predict any gain of function resulting from these SNPs. Additionally, we included 3 other potential candidates: GSTM1, associated with DIC through deletion rather than a SNP;20 CBR1, considered one of the prototypical DIC-associated genes;21 and ERBB2, implicated in the cardiotoxicity of trastuzumab plus doxorubicin regimens.22 We assessed the expression of 83 genes using RNA sequencing in the fetal heart, adult human heart, and hiPSC-CMs. Subsequently, 38 genes consistently expressed (>10 transcripts per million for hiPSC-CMs) were chosen for KO generation (Figure 1, Supplemental Table 1).
We generated KO hiPSC-CM lines for each of the 38 genes, with all guide RNA sequences listed in Supplemental Table 2. All KOs were validated using Sanger sequencing (Supplemental Figures 1 to 4, Supplemental Tables 4 and 5). The absence of the knocked-out protein was confirmed using western blot analysis (Supplemental Figures 5 and 6, Supplemental Tables 6 and 7). Additionally, attenuation of the KO gene in the KO lines was further confirmed using quantitative reverse transcriptase polymerase chain reaction (Figure 2A, Supplemental Table 8). Relevant SNPs contained in the control human induced pluripotent stem cells are detailed in Supplemental Table 9. Of the 38 KOs attempted, KO of 2 genes (ERCC2 and ABCC1) proved incompatible with hiPSC survival, and 1 gene (SP4) was incompatible with cardiac differentiation (Supplemental Table 1).
Next, the remaining 35 KO hiPSC lines were differentiated into cardiomyocytes and exposed to 5-log doses of doxorubicin (10−8 to 10−4 M) for 72 hours, followed by viability assessment to establish the dose required to kill 50% of the cells (median lethal dose [LD50]) (Figure 2B). KO of the uptake drug transporters SLC28A3, SCL22A17, and SLC28A1 increased viability after treatments with doxorubicin, with LD50 values between 6.35 and 11.2 μM compared with 3.78 μM in isogenic control hiPSC-CMs (Figure 2B, Supplemental Figure 7). KO of ATP2B1, HMNT, POR, CYBA, WDR4, and COL1A2 did not alter viability after doxorubicin treatments (Figure 2B, Supplemental Figure 8). KO of the rest of the genes (n = 26) increased the hiPSC-CMs’ sensitivity to doxorubicin (Figure 2B, Supplemental Figures 9 and 10). LD50 values for KOs with increased sensitivity to doxorubicin ranged between 0.32 μM (NOS3-KO and MYH7-KO cardiomyocytes; P < 0.0001) and 2 μM (GSTM1-KO cardiomyocytes; P = 0.0018) compared with 3.78 μM for isogenic control hiPSC-CMs.
Functional validation of DIC-associated genes
Next, for each gene KO, we performed a functional study to investigate their potential mechanistic implications for DIC. We categorized the genes into 6 functional groups (Table 1) and adopted a functional assay relevant to their mechanisms of action (Central Illustration).
Table 1.
Group | Gene | First Author (Year) Ref# | Mechanistic Implication |
---|---|---|---|
1 | CAT | Rajic et al (2009)31 | ROS generation/handling32 |
CBR1 | Armenian et al (2013)33 | ROS generation/handling34 | |
CBR3 | Visscher et al (2012),9 Armenian (2013)33 | ROS generation/handling34 | |
ERBB2 | Boekhout et al (2016)35 | ROS generation/handling36 | |
GPX3 | Visscher et al (2015)12 | ROS generation/handling37 | |
GSTM1 | Singh et al (2020)20 | ROS generation/handling | |
GSTP | Visscher et al (2012),9 Rossi et al (2009)38 | ROS generation/handling39 | |
HAS3 | Wang et al (2014)40 | ROS generation/handling41 | |
NOS3 | Krajinovic et al (2016)14 | ROS generation/handling42 | |
PLCE1 | Hildebrandt et al (2017)43 | ROS generation/handling44 | |
RAC2 | Armenian et al (2013),33 Rossi et al (2009)38 | ROS generation/handling45 | |
SPG7 | Visscher et al (2013)10 | ROS generation/handling46 | |
2 | PRDM2 | Wells et al (2017)5 | DNA damage47 |
MLH1 | Krajinovic et al (2016)14 | DNA damage48 | |
RARG | Aminkeng et al (2015)3 | DNA damage3 | |
3 | HFE | Armenian et al (2013)33 | Iron uptake and homeostasis49 |
4 | SLC22A17 | Visscher et al (2015)12 | DOX uptake13 |
SLC28A1 | Visscher et al (2012)9 | DOX uptake50 | |
SLC28A3 | Visscher et al (2012),9 Visscher et al (2013)10 | DOX uptake19 | |
ABCB4 | Visscher et al (2012)9 | DOX efflux51 | |
ABCC2 | Aminkeng et al (2015)3 | DOX efflux52 | |
ABCC5 | Krajinovic et al (2016)14 | DOX efflux14 | |
ABCC9 | Visscher et al (2015)12 | DOX efflux53 | |
ABCC10 | Visscher et al (2015)12 | DOX efflux53 | |
5 | CELF4 | Wang et al (2016)6 | Calcium handling54 |
MYH7 | Wasielewski et al (2014)55 | Calcium handling56 | |
6 | CYP2J2 | Visscher et al (2015)12 | Cardiac electrical activity57 |
RIN3 | Aminkeng et al (2015)3 | Cardiac electrical activity58 | |
ZFN521 | Aminkeng et al (2015)3 | Cardiac electrical activity59 |
DIC = doxorubicin-induced cardiotoxicity; DOX = doxorubicin; ROS = reactive oxygen species.
Genes involved in ROS production and handling
The largest group of genes in our list (12 of 35) is associated with ROS production and handling (Table 1). We assessed the H2O2 levels in hiPSC-CMs after 24 hours of doxorubicin treatment (Figures 3A to 3C). After doxorubicin treatment, our analysis indicated that ROS levels were lower in CBR1-KO (half maximal inhibitory concentration [IC50] = 20.6 mM; P = 0.0024) and CBR3-KO (IC50 = 31 mM; P = 0.0069) hiPSC-CMs compared with isogenic control hiPSC-CMs (IC50 = 4.1 mM) (Figure 3A). However, after doxorubicin treatment, ROS levels were increased in SPG7-KO (IC50 = 0.3 mM; P = 0.0006), HAS3-KO (IC50 = 0.1 mM; P = 0.0023), GSTM1-KO (IC50 = 0.26 mM; P = 0.039), and RAC2-KO (IC50 = 0.5 mM; P = 0.04) hiPSC-CMs (Figure 3B). No significant differences in ROS production were detected in PLCE1-KO, ERBB2-KO, CAT-KO, GSTP1-KO, NOS3-KO, and GPX3-KO hiPSC-CMs (Figure 3C).
Genes involved in DNA damage
RARG, PRDM2, and MLH1 were linked to DNA damage response3,19,47, 48, 60 (Table 1). Given our comprehensive study of the role of RARG in DIC,19 we directed our focus to PRDM2 and MLH1 to quantify double-stranded DNA breaks in hiPSC-CMs after doxorubicin treatment. Our immunofluorescence analysis suggests increased γH2AX staining in PRDM2-KO and MLH1-KO compared with isogenic hiPSC-CMs (Figure 3D). The elevated levels of γH2AX+ cells were further confirmed using flow cytometry after 1- and 3-μM doxorubicin treatments (Figure 3E). PRDM2 (22.1% ± 1.88% [P = 0.0283] and 32.16% ± 2.43% [P = 0.047]) and MLH1 (40.07% ± 5.79% [P < 0.0001] and 51.11% ± 3.2% [P < 0.0001]) KOs expressed higher levels of γH2AX after 1- and 3-μM doxorubicin treatments compared with isogenic control hiPSC-CMs (12.1% ± 2.37% and 23.52% ± 0.98%, respectively).
Genes involved in iron uptake and homeostasis
HFE encodes the homeostatic iron regulator protein, which controls iron transport and metabolism. The intracellular iron disposition in cardiomyocytes was examined by measuring iron-calcein quenching. No significant differences in iron uptake were observed in the presence of 0 and 10 μM Fe2+. However, HFE-KO hiPSC-CMs exposed to 100 μM of Fe2+ exhibited significantly reduced iron uptake (Figure 3F).
Genes involved in doxorubicin uptake and efflux
Doxorubicin uptake was assessed by measuring intracellular doxorubicin autofluorescence using flow cytometry after drug treatments.13 After the 1-μM doxorubicin treatment, SLC28A1-KO cardiomyocytes exhibited significantly reduced doxorubicin uptake (4.6% ± 2.5%; P = 0.0039) compared with isogenic control hiPSC-CMs (18.63% ± 3.24%) (Figure 4A). Conversely, doxorubicin uptake was significantly higher in ABCB4-KO (52.73% ± 3.2%; P < 0.0001), ABCC5-KO (48.45% ± 5.5%; P < 0.0001), ABCC9-KO (29.98% ± 2.7%; P = 0.0327), and ABCC10-KO hiPSC-CMs (60.18% ± 2.6%; P < 0.0001) (Figure 4A). After 1-μM treatments, no significant differences in doxorubicin uptake were observed in SLC22A17-KO, SLC28A3-KO, and ABCC2-KO hiPSC-CMs (Figure 4A).
Upon increasing the doxorubicin concentration to 3 μM, all the cells, except for ABCC10-KO, exhibited significant differences in doxorubicin uptake compared with control. Doxorubicin uptake was significantly lower in SLC22A17-KO (43.55% ± 3.04%; P = 0.0005), SLC28A1-KO (35.11% ± 2.63%; P < 0.0001), and SLC28A3-KO (35.24% ± 1.36%; P < 0.0001) hiPSC-CMs compared with isogenic control hiPSC-CMs (57.68% ± 3.11%) (Figure 4A). Conversely, 3-μM doxorubicin treatment led to significantly higher doxorubicin uptake in ABCB4-KO (71.77% ± 3.02%; P = 0.0001), ABCC2-KO (74.52% ± 1.57%; P = 0.0003), ABCC5-KO (79.52% ± 3.79%; P < 0.0001), and ABCC9-KO (68.57% ± 1.02%; P = 0.04) hiPSC-CMs (Figure 4A).
Genes involved in calcium handling
CELF4 and MYH7 play crucial roles in controlling cardiomyocyte function by affecting calcium transients. KO of CELF4 resulted in a significant shortening of full width at half maximum (99.89% ± 5.67%; P < 0.0001), calcium transient duration at 75% (158.04% ± 8.79%; P < 0.0001), and decay time (60.83% ± 3.5%; P < 0.0001) of calcium transients compared with isogenic control hiPSC-CMs (328.15% ± 17.27%, 449.41% ± 23.04%, and 172.73% ± 8.27%, respectively) (Figure 4B). On the contrary, KO of MYH7 resulted in a significant prolongation in full width at half maximum (441.44% ± 18.21%; P < 0.0001), calcium transient duration at 75% (543.82% ± 22.4%; P < 0.0023), and decay time (262.82% ± 11.56%; P < 0.0001) compared with isogenic control hiPSC-CMs (Figure 4B).
Gene involved in cardiac electric activity
We identified 3 genes, RIN3, ZFN521, and CYP2J2, associated with cardiac electric activity57, 58, 59 (Table 1). Impedance measurement revealed that KO of RIN3 increased the pulse width at 50% (1.41% ± 0.007% vs 0.89% ± 0.006%; P < 0.0001) and upstroke velocity (331% ± 3.37% vs 214% ± 7.02%; P < 0.0001) and reduced the relaxation velocity (−166% ± 2.94% vs −192% ± 6.74%; P < 0.0001), compared with isogenic control hiPSC-CMs (Figure 4B). KO of ZFN521 resulted in hiPSC-CMs with increased pulse width at 50% (1.17% ± 0.005%; P < 0.0001) and upstroke velocity (141% ± 1.55%; P < 0.0001) and reduced relaxation velocity (−43.2% ± 0.32%; P < 0.0001). KO of CYP2J2 resulted in increased beat rate (38.39% ± 3.82% vs 21.7% ± 0.26%; P < 0.0004) and pulse width at 50% (1.03% ± 0.01%; P < 0.0001) and decreased upstroke velocity (15.53% ± 0.5%; P < 0.0001) and relaxation velocity (−13.98% ± 0.58%; P < 0.0001), compared with isogenic control hiPSC-CMs (Figure 4B).
Discussion
Inter-individual cardiotoxic response to doxorubicin is variable, indicating that genetics plays an important role in DIC response. The functional validation of genes and variants associated with cardiotoxicity risk is essential to improve the outcome of anthracycline regimens and to develop cardioprotective treatments.
Knocking out DIC-related genes alters the hiPSC-CM response to doxorubicin treatment
Of the 35 genes studied, 3 gene KOs were protective of DIC (SLC28A3, SLC22A17, and SLC28A1), 6 gene KOs did not have a significant effect on DIC (ATP2B1, HNMT, POR, CYBA, WDR4, and COL1A2), and 26 KOs increased DIC (ABCC10, ABCC2, ABCB4, ABCC5, ABCC9, CAT, CBR1, CBR3, CYP2J2, ERBB2, GPX3, GSTM1, GSTP1, HAS3, HFE, MLH1, MYH7, NOS3, PLCE1, PRDM2, RAC2, RARG, RIN3, SPG7, CELF4, and ZFN521).
ROS production is the major mechanism causing DIC
The largest functional group studied comprised genes related to ROS production. H2O2 production analysis in cardiomyocytes exposed to doxorubicin revealed reduced production in CBR1-KO and CBR3-KO hiPSC-CMs, indicating a potential link to cardiotoxicity via reduced metabolism of doxorubicin to doxorubicinol by carbonyl reductases. In contrast, HAS3-KO, SPG7-KO, GSTM1-KO, and RAC2-KO exhibited higher ROS production and increased sensitivity to doxorubicin, indicating a role of these genes in H2O2 handling. Notably, no significant differences in H2O2 production were observed in CAT-KO, NOS3-KO, PLCE1-KO, GPX3-KO, ERBB2-KO, and GSTP1-KO. This might suggest that the DIC observed in the KO of these genes is due to the defects in the handling and detoxification of additional ROS products and/or participation in other mechanisms related to doxorubicin toxicity besides ROS generation. In fact, it has been shown that CAT, glutathione S-transferases, and glutathione peroxidases have played crucial roles in detoxifying metabolites generated during oxidative stress.61
DNA damage response is elevated in PRDM2-KO and MHL1-KO
RARG inhibits TOP2B, which binds to DNA and stabilizes the intermediate TOP2B-mediated double-stranded DNA breaks. KOs of the RARG gene activate this DNA damage pathway, leading to increased cardiac cell death. Similar mechanisms are thought to exist in PRDM2 and MLH1 gene KOs. We detected higher levels of DNA damage after doxorubicin treatments PRDM2-KO and MHL1-KO, suggesting a protective role for these genes against doxorubicin-induced DNA damage.
HFE-KO cardiomyocytes exhibit reduced iron uptake
Our results indicate reduced iron uptake in HFE-KO cardiomyocytes compared with isogenic control, particularly evident at high Fe2+ concentrations (100 μM). Considering the important role of iron in mitochondrial function and the energy-demanding nature of cardiomyocytes, this impaired iron uptake may contribute to the heightened DIC observed in HFE-KO cardiomyocytes, as evidenced by the exacerbated risk for heart failure in the context of iron deficiency.62
KOs of SLC transporters reduce and ABC transporters KOs increase the doxorubicin uptake
KOs of SLC family members in hiPSC-CMs showed reduced doxorubicin uptake compared with isogenic controls. In addition, KO of ABC family members in hiPSC-CMs resulted in an elevation of doxorubicin uptake. Our results indicate that SLC transporters play a crucial role in facilitating the influx of doxorubicin into the cardiomyocytes, thereby contributing to an increased risk for DIC. Conversely, ABC transporters are implicated in the efflux of doxorubicin out of the cells, reducing intracellular doxorubicin levels and establishing them as potential cardioprotective gene targets.
CELF4-KO and MYH7-KO hiPSC-CMs demonstrate altered calcium transients
CELF4 is involved in regulatory splicing events essential for the proper functioning of cardiac troponin T, which in turn plays an essential role in proper calcium signaling in cardiomyocytes.63 MYH7, a gene encoding myosin heavy chain beta isoform, is associated with increased intracellular calcium levels in patients with hypertrophic cardiomyopathy.64 Our analysis revealed alterations in multiple aspects of calcium transients in both CELF4-KO and MYH7-KO, suggesting impaired calcium handling as one of the mechanisms underlying DIC.
Contractile properties of ZFN521-KO, RIN3-KO, and CYP2J2-KO hiPSC-CMs are affected
ZFN521 regulates the ventricular conduction system in the heart,65 while RIN3 interacts with and regulates RAB5, facilitating membrane trafficking of the voltage-gated potassium channel KCNQ1 and thereby regulating potassium currents.66 CYP2J2 KO has been shown to result in QT-interval prolongation on echocardiography.67 Impedance analysis of ZFN521-KO, RIN3-KO, and CYP2J2-KO hiPSC-CMs revealed significant differences in contractile properties, including beat rate, pulse width at 50%, upstroke velocity, and relaxation velocity, compared with the isogenic control.
Study limitations
Although we investigated the KO of gene candidates from GWAS and candidate gene association studies, these studies identified SNPs linked to AIC. Because not all the SNPs cause loss of function, studying individual SNP corrections and/or patient-specific hiPSC-CMs can shed further light on this matter. Additionally, we generated KOs of selected candidate genes on the basis of their potential link to AIC and expression in hiPSC-CMs. Although not all the generated KOs showed significant differences in LD50 after doxorubicin treatment, repeating this process using KO of a gene with no proven function in AIC could further validate these findings. Additionally, the application of more mature cardiomyocytes could assist to harness the differences in a more physiologically relevant system. The present study was focused only on the effect of KOs on cardiomyocytes, but cardiotoxicity might stem from malfunction in other cell types, including endothelial cells and cardiac fibroblasts. Finally, for each KO, only 1 functional study was performed; additional functional studies can provide a more detailed understanding of each gene contribution to the formation of DIC.
Conclusions
This study demonstrates that genomic analysis, coupled with human induced pluripotent stem cell modeling, is an efficient platform for assessing the mechanisms of DIC. Through high-throughput assays, we validate the influence of DIC genes on cell viability, ROS production, DNA damage, doxorubicin uptake, iron uptake, calcium handling, and electric activity in response to doxorubicin. Our results confirm that more than 55% of the DIC genes identified to date in association studies are expressed in cardiac cells, reliably recapitulating alterations in DIC phenotype in the hiPSC-CM model. Furthermore, for each gene, we provide a functional assay to validate its role in DIC.
Perspectives.
COMPETENCY IN MEDICAL KNOWLEDGE: In this study, we have functionally validated all current DIC-associated genes that are expressed in cardiomyocytes. This comprehensive validation represents the first step in translating functionally validated genotype-phenotype correlations into clinical tests. Once the relevance of a gene in DIC is identified, and its mechanism of action is known, the next step involves validating the role of genetic variants in modulating the response to doxorubicin. This information will serve as a unique platform for designing polygenic risk scores that can benefit patients undergoing doxorubicin treatment. In addition, a precise understanding of the genetic basis of DIC is crucial for identifying druggable targets and discovering innovative cardioprotective therapies.
TRANSLATIONAL OUTLOOK: One major barrier in the clinical application of this study lies in determining the genetic contribution to DIC risk for each gene for all sexes and ancestries. Currently, there is a scarcity of studies exploring the effects of sex and diverse genetic backgrounds on the mechanisms of DIC. Establishing patient-specific risk factors is a crucial prerequisite before the clinical implementation of the findings from this study can be applied.
Funding Support and Author Disclosures
This work was supported by National Institutes of Health grants R01 CA220002 and R01 CA261898, American Heart Association Transformational Project Award 18TPA34230105, and the Leducq Foundation (to Dr Burridge). The authors have reported that they have no relationships relevant to the contents of this paper to disclose.
Footnotes
The authors attest they are in compliance with human studies committees and animal welfare regulations of the authors’ institutions and Food and Drug Administration guidelines, including patient consent where appropriate. For more information, visit the Author Center.
Appendix
For supplemental methods, tables, and figures, please see the online version of this paper.
Appendix
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