Abstract
Although opioids are necessary for the treatment of acute pain, cancer pain, and palliative care, opioid abuse is a serious threat to society. Heroin (Diacetylmorphine) is the most commonly abused opioid, and it can have a variety of effects on the body's tissues and organs, including the well-known gastrointestinal depression and respiratory depression; however, there is little known about the effects of diacetylmorphine on cardiac damage. Here, we demonstrate that diacetylmorphine induces abnormal electrocardiographic changes in rats and causes damage to cardiomyocytes in vitro by an underlying mechanism of increased autophosphorylation of CaMKII and concomitant regulation of myocardial contractile protein TPM1 and MYOM2 protein expression. The CaMKII inhibitor KN-93 was first tested to rescue the toxic effects of heroin on cardiomyocytes in vitro and the abnormal ECG changes caused by heroin in SD rats, followed by the TMT relative quantitative protein technique to analyze the proteome changes. Diacetylmorphine causes increased phosphorylation at the CaMKII Thr287 site in myocardium, resulting in increased autophosphorylation of CaMKII and subsequent alterations in myocardial contractile proteins, leading to myocardial rhythm abnormalities. These findings provide a theoretical basis for the treatment and prevention of patients with arrhythmias caused by diacetylmorphine inhalation and injection.
Similar content being viewed by others
Introduction
Poppy derivatives have been used for thousands of years, and the World Health Organization has proposed opioids as essential drugs for the treatment of acute pain, cancer pain, and palliative care1. Bayer resynthesized diacetylmorphine and marketed it as heroin in the nineteenth century for use in patients suffering from severe chronic pain or terminal illness2,3. However, due to diacetylmorphine's high biological toxicity and addictive nature, its abuse has caused significant social harm4,5,6,7. Diacetylmorphine has varying degrees of effect on various tissues and organs in the body, with the most serious side effects being respiratory depression and gastrointestinal depression8,9,10. It has also been demonstrated that diacetylmorphine can cause abnormal electrocardiographic parameters11; however, little is known about the mechanisms by which diacetylmorphine causes myocardial rhythm abnormalities.
Calcium (Ca2+)/calmodulin (CaM)-dependent kinase (CaMK)II is a serine/threonine (Ser/Thr)-specific phosphokinase that is predominantly the δ isoform in the heart. It can respond to changes in intracellular Ca2+ in cardiomyocytes12, and Ca2+ is an important second messenger in cardiomyocytes, involved in membrane excitation and myogenic fiber contraction13. CaMKII has a significant impact on excitation–contraction coupling in cardiac myocytes14, sustained activation of CaMKII plays a key role in arrhythmias, heart failure, cardiac ischemia–reperfusion and sudden cardiac death15,16,17. However, it is unknown whether CaMKII and its related downstream genes play a role in the process of diacetylmorphine-induced myocardial rhythm abnormalities. The goal of this study was to identify potential mechanisms of diacetylmorphine-induced myocardial rhythm abnormalities.
Materials and methods
Chemicals
Anti-CaMKIIδ (Item No. sc-100362) was purchased from Santa Cruz (USA), anti-CaMKII (phospho T287) (Item No. ab182647), anti-β Tubulin (Item No. ab6046), anti-cardiac troponin T (Item No. ab209813) were purchased from Abcam (Cambridge, UK), Tropomyosin-1/3 (Item No. D17B8) were purchased from Cell Signaling Technology (Beverly, MA, USA), Anti-MYOM2 (Item No. A20526) was purchased from ABclonal (Wuhan, China). KN-93 and KN-92 were obtained from Selleck (Houston, TX, United States).
Ethical statement
All rat studies were conducted in accordance with approved guidelines, and all study protocols were reviewed and approved by the Medical Ethics Committee for Animal Experiments of the First Affiliated Hospital of Xinjiang Medical University (K201907-06).
Animal studies
The animals used in this study were SD rat mammary rats as well as 40 SD rats. The SD rats were all male, 8 weeks old, with an initial weight of 210 ± 10 g. The experiment consisted of three groups of SD rats: Vehicle group, HE group, and HE + KN-93 group. The Vehicle group was injected subcutaneously with saline, the HE group was injected subcutaneously with diacetylmorphine, and the HE + KN-93 group was injected subcutaneously with diacetylmorphine and with KN-93 reagent in the tail vein, and the rats were subjected to a naloxone hydrochloride prodrome test on day 20, and each rat was observed for 30 min. Electrocardiograms were performed after administration of pentobarbital sodium anesthesia on day 50, followed by execution of the rats using the cervical dislocation method. All experimental rats were housed in individually ventilated cages with free access to food and free access to water. All animal experiments were performed in accordance with ARRIVE guidelines. All methods were performed in accordance with relevant guidelines and regulations.
Isolation and culture of primary SD rat cardiomyocytes
Three-day-old SD rat neonatal rats were anesthetized and their skin was disinfected with 75% ethanol under aseptic conditions before their hearts were curved and clipped into D-Hanks solution. The atrial portion was cut with ophthalmic scissors, and the apical portion was divided into 7–8 flaps before being placed in trypsin and shaken overnight at 4 °C. After the digestion was completed, the supernatant was discarded, type II collagenase was added, and the mixture was shaken for 10 min at 37 °C in a water bath. The supernatant was transferred into a centrifuge tube and centrifuged at 1000 rpm for 5 min before being discarded, plus complete medium containing 5-Brdu, mixed by slow blowing, and transferred into a cell culture dish. Following differential apposition, the cells were transferred to a 37 °C cell incubator for further experiments.
Cell processing
Diacetylmorphine was dissolved in PBS solution and used at a final concentration of 100 µmol/L. The CaMKII inhibitor KN-93 and KN-93 inactive analogue KN-92 were dissolved in dimethyl sulfoxide (DMSO) at a concentration of 1 mM/L, and both were used at a concentration of 1 μmol/L.
Measurement of spontaneous beating frequency of cardiac myocytes
Cardiomyocytes were seeded in polylysine-treated 6-well plates at a density of 1 × 105 cells/mL in a liquid volume of 2 mL per well. Following a incubation 5–7 days, four fields of view were randomly selected for each well after drug intervention, and two people were observed simultaneously under an inverted microscope, with the number of cell pulsations within 1 min being recorded and repeated eight times.
GOT and LDH activity assay
LDH and GOT activity in the supernatant was measured using commercially available LDH assay kits (Solarbio, Beijing, China) and GOT assay kits (Solarbio, Beijing, China) according to the manufacturer's instructions to assess cell damage.
5,5′,6,6′-Tetrachloro-1,1′,3,3′-tetraethylbenzimidazolocarbo-cyanine iodide (JC-1) staining
Following JC-1 staining (cat. no. C2006; Beyotime Institute of Biotechnology), incubate at 37 °C for 25 min, wash twice with JC-1 staining buffer, photograph and observe under laser confocal microscope, and analyze the data using ImageJ to respond to mitochondrial membrane potential changes by the red-green fluorescence ratio.
Western blotting
Cell precipitates and animal tissues were collected from each group. Total protein was extracted from RIPA lysates and protein concentration was measured using the BCA protein quantification method. The protein loading volume was 40 μg. Electrophoresis; transfer to PVDF membrane using the wet transfer method, close for 2 h, for a better antibody binding, western blotting images trimming of the corresponding target protein was trimmed according to the location of marker, add primary antibody, primary antibodies include CaMKIIδ (dilution ratio: 1:500), p-CaMKII (T287) (dilution ratio: 1:500), β Tubulin (dilution ratio: 1:1500), Tropomyosin-1/3 (dilution ratio: 1:1000), MYOM2 (dilution ratio: 1:1000), and shake overnight at 4 °C. Separately, goat anti-mouse IgG (1:2000) and goat anti-rabbit IgG (1:2000) were added and shaken at room temperature for 120 min. The film is washed with TBST before strip exposure. The grayscale values of each band were measured using the grayscale analysis tool included in the image Lab software, and the target protein's relative expression was compared to the grayscale value of the internal reference -tubulin to obtain the target protein's relative expression for statistical analysis.
Electrocardiogram testing
Rats were anesthetized with 2% pentobarbital sodium in the supine position. Using the BL-420 Biofunctional Experiment System, a silver needle was inserted into the rats' right forelimb, left hindlimb, and right hindlimb, and then the white alligator clip was connected to the silver needle of the right forelimb, the red alligator clip to the silver needle of the left hindlimb, and the black alligator clip to the silver needle of the right hindlimb. Recording of standard II-lead ECG.
Tandem mass spectrometry labeling for relative quantitative proteomics screening of differentially expressed proteins
Following cell extraction, quantification, TMT labeling, peptide grading, data acquisition using liquid chromatography-tandem mass spectrometry (LC–MS/MS), and finally screening for differentially expressed proteins, each group of cells was processed (this part of the experiment was done by Shanghai Zhongke New Life Biotechnology Co.).
Volcano map
To screen differentially expressed proteins, we calculated Fold change and P-value from t-test using the criteria of Fold change greater than 1.2-fold (up-regulation greater than 1.2-fold or down-regulation less than 0.83) and P-value less than 0.05. The horizontal coordinates represent the Fold change (log-transformed by 2), and the vertical coordinates represent the difference's P-value. The horizontal coordinate is the number of fold differences (log-transformed by 2), the vertical coordinate is the difference's P-value (log-transformed by 10), and the volcano plot is created in R with "ggplot."
Venn diagram
After excluding undefined proteins, common factors were screened between drug vs con up-regulation factors and KN-93 vs drug down-regulation factors, and between drug vs con down-regulation factors and KN-93 vs drug up-regulation factors, using the "VennDiagram" in R to generate Venn diagrams.
GO functional enrichment analysis
Gene Ontology (http://www.geneontology.org/) is a standardized functional classification system that provides a dynamically updated standardized vocabulary and describes the properties of genes and gene products in an organism in three aspects: Biological Process (BP), Molecular Function (MF), and Cellular Component (CC). We used Blast2Go (https://www.blast2go.com/) software for GO functional annotation of all identified proteins, followed by Fisher's exact test GO functional enrichment analysis of differentially expressed proteins.
KEGG pathway enrichment analysis
One of the most commonly used databases for pathway research is KEGG (Kyoto Encyclopedia of Genes and Genomes, http://www.kegg.jp/). The KEGG database contains information on metabolic pathways, genetic data processing, environmental data processing, cellular processes, organismal systems, human disease development, and other topics. Information. The KEGG pathway enrichment analysis analyzes and calculates the significance level of protein enrichment for each pathway using the KEGG pathway as the unit and the total proteins identified as the background, and the Fisher's Exact Test to identify the significantly affected metabolic and signal transduction pathways.
Hierarchical clustering, heatmap visualization
A hierarchical clustering heatmap is generated in R using the "ComplexHeatmap" package based on the factors sieved from the Wayne diagram.
Protein interaction network diagram
The STRING (http://string-db.org/) database was used to discover the interactions between the target proteins, and the CytoScape software was used to generate the interaction networks.
Statistical analysis
The results are presented as mean SD, and the data was evaluated using a t-test on two independent samples. ANOVA with LSD post hoc test for multiple comparisons, chi-square test for rate comparisons, SPSS 26 software for data analysis, and GraphPad 8.0.2 software for graphing were used to analyze multiple data sets. A statistically significant p-value of 0.05 was used.
Results
CaMKII inhibitors attenuate the toxic effects of diacetylmorphine on cardiomyocytes in vitro
We cultured primary SD rat neonatal rat cardiomyocytes in vitro and identified cardiomyocytes using Anti-cardiac troponin T (Supplemental Instrument Supplementary Fig. 1), which showed a purity of > 95% and could be used for subsequent experiments. Except for the cell control group(con), they were divided into the drug group (treated with 100 µmol/L heroin for 24 h), KN-93 group (treated with 100 µmol/L heroin + 1 μmol/L KN-93 for 24 h) and KN-92 group (100 µmol/L heroin + 1 μmol/L KN-92 for 24 h). Cardiomyocytes cultured for about 5–7 days resumed beating with a beating frequency averaging 120 beats/min. The beating frequency decreased significantly after diacetylmorphine treatment, averaging at 81 beats/min, whereas with KN-93, the beating frequency increased compared to the drug group, and there was no statistical difference between the KN-92 and drug groups (Fig. 1C). To observe the toxic effects of CaMKII inhibitor to attenuate KN-93 diacetylmorphine on cardiomyocytes in vitro in a multifaceted manner, we used JC-1 fluorescent probe and observed the mitochondrial membrane potential changes in each group using laser confocal microscope, and the results showed that the mitochondrial membrane potential was decreased in the drug group compared with the con group, while it was increased in the KN-93 group compared with the drug group, and there was no significant change in the KN-92 group (Fig. 1A,B). Subsequently, we measured the LDH and GOT levels in the cell culture supernatant and the results showed that the LDH and GOT levels in the drug group were higher than those in the con group, while the LDH and GOT levels in the KN-93 group were lower than those in the drug group, and there was no significant change in the LDH and GOT levels in the KN-92 and drug groups (Fig. 1DE). These findings suggest that KN-93 reduces the toxic effects of diacetylmorphine on cardiomyocytes in vitro. It also suggests that CaMKII is involved in the toxic effects of diacetylmorphine on cardiomyocytes in vitro.
Diacetylmorphine regulates cardiomyocyte protein expression patterns
To ascertain the effect of diacetylmorphine on cardiomyocytes as well as the mechanism of action of the CaMKII protein in it. We exposed cardiomyocytes to diacetylmorphine at a concentration of 100 μmol/L and either KN-93 at a concentration of 1 μmol/L or KN-92 at a concentration of 1 μmol/L. We first used protein blotting to detect the phosphorylation level of CaMKIIδ protein and its T287 site, and the results showed that the phosphorylation level was significantly higher in the drug group compared to the control group, while it was lower in the KN-93 group (Fig. 2A,B). We used an unbiased screening method and performed proteomic analysis with samples from the con group, drug group, and KN-93 group, with three biological replicates in each group, to further determine the mechanism of action of heroin on cardiomyocytes and the molecular mechanism of CaMKII protein in it. The mass deviation of all identified peptides was mostly within 10 ppm (Fig. 2C), and the distribution of peptide ion scores: approximately 72.37% of the peptides scored above 20, and the median score of peptides was 28.55 (Fig. 2D), indicating that the identification results were accurate and reliable, and the distribution of the identified protein characteristics was shown in Fig. 2E,F.
A total of 784 differentially expressed proteins were screened in the drug vs con group using the criteria of ploidy change greater than 1.2-fold (up-regulation greater than 1.2-fold or down-regulation less than 0.83) and P value less than 0.05. These differentially expressed proteins were defined as DEGs-1, of which 442 were up-regulated differentially expressed proteins and 342 were down-regulated proteins (Fig. 3A). As shown in Table 1: DEGs-1 was mainly involved in cardiac muscle tissue development, actin binding and other processes, while sarcomere, I band and other sites of protein were significantly altered. As shown in Fig. 3B, KEGG pathways such as Cardiac muscle contraction and Retrograde endocannabinoid signaling were changed more significantly (Fig. 3B).
To further determine the specific molecular mechanism of CaMKII protein in the action of diacetylmorphine on cardiomyocytes. A total of 346 differentially expressed proteins were screened in the KN-93 vs drug group using the criteria of ploidy change greater than 1.2-fold (up-regulation greater than 1.2-fold or down-regulation less than 0.83) and P value less than 0.05, and these 346 differentially expressed proteins were defined as DEGs-2, of which 169 were up-regulated and 177 were down-regulated (Fig. 3C). The common proteins of up-regulated proteins in DEGs-1 and down-regulated proteins in DEGs-2 were searched for a total of 20 proteins (Fig. 3D), then look for proteins that are down-regulated in DEGs-1 in common with the up-regulated proteins in DEGs-2, a total of 19 proteins (Fig. 3E), and these 39 proteins were defined as DE-CaMKIIs. Figure 3F depicts the expression of DE-CaMKIIs in each group (Fig. 3F). The DE-CaMKIIs protein interaction network prediction with CaMKII revealed that DE-CaMKIIs interacted with CaMKIID (Fig. 3G).
Abnormal cardiomyocyte rhythm caused by diacetylmorphine is associated with CaMKII regulation of TPM1 and MYOM2 proteins
To further confirm the mechanism of CaMKII in myocardial rhythm abnormalities caused by diacetylmorphine, we selected the myocardial contraction-related proteins MYOM2 and TPM1 after combining the results of previous proteomic analyses, and examined the changes in their expression levels in each group using protein blotting. We cultured primary SD rat suckling rats cardiomyocytes in vitro and exposed the cultured cells to diacetylmorphine at a concentration of 100 μmol/L as well as KN-93 at a concentration of 1 μmol/L or KN-92 at a concentration of 1 μmol/L for 24 h. Western Blot results showed that the relative expression levels of TPM1 and MYOM2 protein were significantly higher in the drug group compared with the con group, and the difference was statistically significant, while the relative expression levels of TPM1 and MYOM2 protein were lower in the KN-93 group compared with the drug group, and the difference was statistically significant, while there was no significant difference in the relative expression levels of TPM1 and MYOM2 protein in the KN-92 group compared with the drug group (Fig. 4A,B). This result is consistent with the proteomic results. To further determine the relationship between CaMKII and cardiac contractile proteins TPM1 and MYOM2, we used CaMKIIδ overexpression lentivirus to infect primary SD rat neonatal rat cardiomyocytes and verified the transfection efficiency using Western Blot, and the results showed that the relative expression level of CaMKIIδ protein in the CaMKIIδ overexpression group (LV-CaMKIIδ group) was significantly higher than that in the cell control group (con group) and the null-stained group (LV-NC group) (Fig. 4C,D). Subsequently, We treated LV-CaMKIIδ group cardiomyocytes with diacetylmorphine and detected the changes of p-CaMKII(T287), TPM1, MYOM2 protein relative expression levels using Western Blot, and the results showed that compared with the con group, the p-CaMKII(T287), TPM1, and MYOM2 protein relative expression levels were increased in the drug + LV-CaMKIIδ group, and p-CaMKII(T287), TPM1, MYOM2 protein relative expression levels were significantly increased in the drug + LV-CaMKIIδ group compared with the drug group, and the differences were statistically significant (Fig. 4E–H). The above Western Blot results all suggest that diacetylmorphine-induced rhythm abnormalities in cardiomyocytes are associated with CaMKII regulation of TPM1 and MYOM2 proteins.
KN-93 reduces the frequency of electrocardiographic abnormalities in diacetylmorphine-addicted rats
In order to explore the effect of heroin on ECG, we established a heroin addiction model in SD rats by dose-escalation method, and scored according to withdrawal symptoms (Supplemental Instrument Supplementary Table 1) to determine whether addiction was present, and the results showed that the HE group scored significantly higher than the Vehicle group (Fig. 5A), indicating that the model was established successfully. Subsequent injection of KN-93 and observation of II-lead ECG using BL-420 showed no abnormal ECG in the Vehicle group (Fig. 5C), in contrast, various types of ECG abnormalities, such as sinus arrest, complete right bundle branch block, premature ventricular beats, and ventricular tachycardia, were observed in the SD rats of the HE group (Fig. 5D–G), and ECG abnormalities were also observed in rats in the HE + KN-93 group (Fig. 5H), but were rare compared with the HE group (Fig. 5B and Supplemental Instrument Supplementary Table 2). The changes in the relative expression levels of p-CaMKII (T287), TPM1, and MYOM2 proteins were detected using Western Blot, and the results showed that the relative expression levels of p-CaMKII (T287), TPM1, and MYOM2 proteins were increased in the HE group compared with the Vehicle group, and the relative expression levels of p-CaMKII (T287), TPM1, and MYOM2 proteins were decreased in the HE + KN-93 group compared with the HE group, and the differences were statistically significant (Fig. 5I,J). These results suggest that KN-93 reduces the frequency of ECG abnormalities in diacetylmorphine-addicted rats and also suggest that CaMKII plays an important role in diacetylmorphine-induced ECG abnormalities in rats.
Discussion
In recent years, the mechanism of diacetylmorphine abuse on cardiovascular damage has become a hot research topic. Some studies have shown that diacetylmorphine can cause abnormal ECG parameters, and some scholars have found that diacetylmorphine addiction and abuse can cause different degrees of changes in the ECG of rats, showing various types of arrhythmias, and also diacetylmorphine can cause changes in the frequency of spontaneous beats of cardiac myocytes, but the specific mechanism is still unclear and The exact mechanism is unknown and needs to be further investigated.
Diacetylmorphine can cause different degrees of damage to various systems and organs, such as adrenal insufficiency, multi-organ function syndrome, cardiac arrest, etc.18,19,20. Here, we found that diacetylmorphine had an injurious effect on cardiomyocytes cultured in vitro, causing a decrease in spontaneous beat frequency, a decrease in mitochondrial membrane potential, and LDH and GOT release increase whereas KN-93, an inhibitor of CaMKII, had a protective effect on cardiomyocytes after diacetylmorphine intervention. KN-93 is a CaMKII-specific inhibitor that inhibits CaMKII activity21. In contrast, CaMKII belongs to the serine/threonine protein kinase family and is regulated by the Ca2+/CaM complex, with four isoforms, α, β, γ and δ. The δ isoform is mainly expressed in the myocardium. Meanwhile, CaMKII is considered to be an important factor in the excitation–contraction coupling process, which can affect the change of Ca2+ content in cardiac myocytes. Moderate activation is beneficial for the normal functioning of the heart, while continuous activation may lead to cardiac dysfunction. Many studies have now shown that CaMKII is closely associated with the development of cardiovascular diseases such as arrhythmia, cardiac hypertrophy and heart failure17,22,23,24.
In this study, the differentially expressed proteins and enriched pathways of diacetylmorphine intervention in cardiac myocytes were analyzed using proteomics, and it was found that differentially expressed proteins are mainly involved in muscle cell development, striated muscle cell development, muscle structure development, cardiac muscle tissue development, and other important biological processes, while cardiac muscle contraction is in the first 20 of the KEGG-enriched pathway. Marcin Kunecki et al. also demonstrated experimentally that morphine affects the systolic and diastolic functions of human heart muscle25. Further analysis by proteomics revealed that two contractile proteins, TPM1 and MYOM2, are likely to be involved in diacetylmorphine-induced myocardial rhythm abnormalities as CaMKII downstream proteins.
Proto-myosin (Tm) is a large family of highly conserved alpha-helix coiled-coil proteins, and TPM1 is a member of this large family26. Prothymosin, troponin, and myosin work together to move between blocked, closed, and open sites on thin filaments, thereby masking and exposing the actin binding sites necessary for myosin to interact across bridgeheads27. MYOM2, a member of the myomesin protein family, is a major component of the myofibrillar myogenic fiber M-band and a central gene in myofibrillar gene interactions28. In contrast, CaMKII is a signaling molecule whose activity is triggered by an increase in intracellular Ca2+ levels, an activity that can be sustained by enzymatic autophosphorylation, generating molecular memory concentrations after a decrease in Ca2+; it regulates a variety of proteins that are involved not only in ECC and relaxation but also in cell death, transcriptional activation of hypertrophy, inflammation, and arrhythmias29,30. We verified by Western Bloting assay and found that diacetylmorphine increased the phosphorylation level of CaMKII T287 site in cardiomyocytes and increased the relative expression of TPM1 and MYOM2 proteins compared with the con group, while after using CaMKII inhibitor KN-93, compared with the drug group, the phosphorylation level of CaMKII T287 site The relative expression of TPM1 and MYOM2 proteins was decreased. It is further suggested that myocardial rhythm abnormalities caused by diacetylmorphine are associated with CaMKII regulation of TPM1 and MYOM2 proteins.
Subsequent pharmacological interventions at the animal level revealed that heroin caused abnormal electrocardiographic changes in SD rats, whereas KN-93 reduced the occurrence of electrocardiographic abnormalities, and heroin increased the phosphorylation level of CaMKII T287 site and the relative expression of TPM1 and MYOM2 proteins in SD rat myocardial tissue, whereas KN-93 decreased the phosphorylation level of CaMKII T287 site and the relative expression of TPM1 and MYOM2 proteins in SD rat myocardial tissue.
The contraction and diastole of the myocardium is a complex process. Cardiac muscle is a transverse muscle that coordinates contraction in response to neuronal stimulation through a voltage- and calcium-dependent process of excitation–contraction coupling31. Myocardial contraction is mainly determined by contractile proteins (actin and troponin), regulatory proteins (troponin and prothymosin, etc.), and Ca2+32. Thus, it is not only the dysregulation of intracellular Ca2+ homeostasis in cardiac myocytes that affects myocardial rhythm, but also myocardial contraction-related proteins.
In conclusion, diacetylmorphine induces increased levels of phosphorylation at the myocardial CaMKII Thr287 site, which increases CaMKII autophosphorylation. which in turn causes alterations in the myocardial contractile proteins TPM1 and MYOM2, leading to abnormal myocardial rhythms. These findings provide a theoretical basis for the treatment and prevention of patients with arrhythmias caused by diacetylmorphine inhalation and injection.
Data availability
The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
Abbreviations
- CaMKII:
-
Ca2+/calmodulin-dependent protein kinaseII
- TPM1:
-
Tropomyosin1
- MYOM2:
-
Myomesin2
- Ca2+ :
-
Calcium
- ECG:
-
Electrocardiograph
References
Degenhardt, L. et al. Global patterns of opioid use and dependence: harms to populations, interventions, and future action. Lancet 394(10208), 1560–1579 (2019).
Tyers, G. F. O. Heroin history. CMAJ 190(5), E144 (2018).
Richert, L. Heroin in the hospice: Opioids and end-of-life discussions in the 1980s. CMAJ 189(39), E1231–E1232 (2017).
Mark, T. L., Woody, G. E., Juday, T. & Kleber, H. D. The economic costs of heroin addiction in the United States. Drug Alcohol Depend. 61(2), 195–206 (2001).
Singh, D., Chawarski, M. C., Schottenfeld, R. & Vicknasingam, B. Substance abuse and the HIV situation in Malaysia. J. Food Drug Anal. 21(4), S46–S51 (2013).
Jessell, L. et al. Sexual violence in the context of drug use among young adult opioid users in New York City. J. Interpers. Violence. 32(19), 2929–2954 (2017).
Ahmed, T., Long, T. N., Huong, P. T. & Stewart, D. E. Drug injecting and HIV risk among injecting drug users in Hai Phong, Vietnam: A qualitative analysis. BMC Public Health 15, 32 (2015).
Demaret, I., Lemaître, A. & Ansseau, M. L’héroïne [Heroin]. Rev. Med. Liege. 68(5–6), 287–293 (2013).
Kiyatkin, E. A. Respiratory depression and brain hypoxia induced by opioid drugs: Morphine, oxycodone, heroin, and fentanyl. Neuropharmacology 151, 219–226 (2019).
Sethi, S. The changing spectrum of heroin-associated kidney disease. Clin. J. Am. Soc. Nephrol. 13(7), 975–976 (2018).
Yildirim, E., Selcuk, M., Saylik, F., Mutluer, F. O. & Deniz, O. Effect of heroin on electrocardiographic parameters. Arq. Bras. Cardiol. 115(6), 1135–1141 (2020).
Carlson, C. R. et al. AKAP18δ anchors and regulates CaMKII activity at phospholamban-SERCA2 and RYR. Circ. Res. 130(1), 27–44 (2022).
Hund, T. J. & Mohler, P. J. Role of CaMKII in cardiac arrhythmias. Trends Cardiovasc. Med. 25(5), 392–397 (2015).
Beckendorf, J., van den Hoogenhof, M. M. G. & Backs, J. Physiological and unappreciated roles of CaMKII in the heart. Basic Res. Cardiol. 113(4), 29 (2018).
Feng, N. & Anderson, M. E. CaMKII is a nodal signal for multiple programmed cell death pathways in heart. J. Mol. Cell Cardiol. 103, 102–109 (2017).
Zhang, J. et al. Novel CaMKII-δ inhibitor hesperadin exerts dual functions to ameliorate cardiac ischemia/reperfusion injury and inhibit tumor growth. Circulation 145(15), 1154–1168 (2022).
Zhang, M. et al. CaMKII-δ9 induces cardiomyocyte death to promote cardiomyopathy and heart failure. Front. Cardiovasc. Med. 8, 820416 (2022).
Das, G. Chronic heroin dependence leading to adrenal insufficiency. Case Rep. Endocrinol. 2014, 461816 (2014).
Feng, G. et al. Multiple organ dysfunction syndrome, an unusual complication of heroin intoxication: A case report and review of literature. Int. J. Clin. Exp. Pathol. 8(9), 11826–11830 (2015).
Dezfulian, C. et al. American heart association council on cardiopulmonary, critical care, perioperative and resuscitation; council on arteriosclerosis, thrombosis and vascular biology; council on cardiovascular and stroke nursing; council on quality of care and outcomes research; and council on clinical cardiology. opioid-associated out-of-hospital cardiac arrest: Distinctive clinical features and implications for health care and public responses: A scientific statement from the American heart association. Circulation 143(16), e836–e870 (2021).
Zhao, H. et al. Endoplasmic reticulum stress/Ca2+-calmodulin-dependent protein kinase/signal transducer and activator of transcription 3 pathway plays a role in the regulation of cellular zinc deficiency in myocardial ischemia/reperfusion injury. Front Physiol. 12, 736920 (2022).
Hegyi, B. et al. CaMKII serine 280 O-glcnacylation links diabetic hyperglycemia to proarrhythmia. Circ. Res. 129(1), 98–113 (2021).
Hegyi, B. et al. Cardiomyocyte Na+ and Ca2+ mishandling drives vicious cycle involving CaMKII, ROS, and ryanodine receptors. Basic Res. Cardiol. 116(1), 58 (2021).
Ni, Y. et al. CaMKII inhibitor KN-93 impaired angiogenesis and aggravated cardiac remodelling and heart failure via inhibiting NOX2/mtROS/p-VEGFR2 and STAT3 pathways. J. Cell. Mol. Med. 26(2), 312–325 (2022).
Kunecki, M. et al. Opioidergic postconditioning’ of heart muscle during ischemia/reperfusion injury. Cardiol. J. 24(4), 419–426 (2017).
Janco, M. et al. Polymorphism in tropomyosin structure and function. J. Muscle Res. Cell Motil. 34(3–4), 177–187 (2013).
Lehman, W., Rynkiewicz, M. J. & Moore, J. R. A new twist on tropomyosin binding to actin filaments: Perspectives on thin filament function, assembly and biomechanics. J. Muscle Res. Cell Motil. 41(1), 23–38 (2020).
Auxerre-Plantié E, Nielsen T, Grunert M, Olejniczak O, Perrot A, Özcelik C, et al. (2020) Identification of MYOM2 as a candidate gene in hypertrophic cardiomyopathy and Tetralogy of Fallot, and its functional evaluation in the Drosophila heart. Dis Model Mech. 13(12): 045377.
Mattiazzi, A. et al. Chasing cardiac physiology and pathology down the CaMKII cascade. Am. J. Physiol. Heart Circ. Physiol. 308(10), H1177–H1191 (2015).
Gömöri, K. et al. Ca2+/calmodulin-dependent protein kinase II and protein kinase G oxidation contributes to impaired sarcomeric proteins in hypertrophy model. ESC Heart Fail. 9(4), 2585–2600 (2022).
Kuo, I. Y. & Ehrlich, B. E. Signaling in muscle contraction. Cold Spring. Harb. Perspect. Biol. 7(2), a006023 (2015).
Pelouch, V. Molecular aspects of regulation of cardiac contraction. Physiol. Res. 44(1), 53–60 (1995).
Acknowledgements
This study was supported by the National Natural Science Foundation of China (Grant No. 81860049 to HWP; No. 82160055 to HWP)
Author information
Authors and Affiliations
Contributions
H.W.P., L.P.S., and L.J.M. were responsible for study concept and design. L.L., M.J., J.L.X., and H.W.P. contributed to part of the animal experiment. M.J., L.P.S., Y.L.G. and H.W.P. contributed to cell experiment section. M.J.Z., S.S.Z., L.J.M. and H.W.P. contributed to data analysis and interpretation. M.J., L.P.S., L.L. and H.W.P. produced a draft of the manuscript, which was reviewed and approved by all authors.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Ji, M., Su, L., Liu, L. et al. CaMKII regulates the proteins TPM1 and MYOM2 and promotes diacetylmorphine-induced abnormal cardiac rhythms. Sci Rep 13, 5827 (2023). https://doi.org/10.1038/s41598-023-32941-6
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-023-32941-6
- Springer Nature Limited
This article is cited by
-
Glucose fluctuations aggravate myocardial fibrosis via activating the CaMKII/Stat3 signaling in type 2 diabtetes
Diabetology & Metabolic Syndrome (2023)