Mitochondrial Drug Delivery Research Articles

Mitochondrial signaling pathways and their role in cancer drug resistance

Mitochondria, traditionally known as cellular powerhouses, now emerge as critical signaling centers influencing cancer progression and drug resistance. The review highlights the role that apoptotic signaling, DNA mutations, mitochondrial dynamics and metabolism play in the development of resistance mechanisms and the advancement of cancer. Targeted approaches are discussed, with an emphasis on managing mitophagy, fusion, and fission of the mitochondria to make resistant cancer cells more susceptible to traditional treatments. Additionally, metabolic reprogramming can be used to effectively target metabolic enzymes such GLUT1, HKII, PDK, and PKM2 in order to avoid resistance mechanisms. Although there are potential possibilities for therapy, the complex structure of mitochondria and their subtle role in tumor development hamper clinical translation. Novel targeted medicines are put forth, providing fresh insights on combating drug resistance in cancer. The study also emphasizes the significance of glutamine metabolism, mitochondrial respiratory complexes, and apoptotic pathways as potential targets to improve treatment effectiveness against drug-resistant cancers. Combining complementary and nanoparticle-based techniques to target mitochondria has demonstrated encouraging results in the treatment of cancer, opening doors to reduce resistance and enable individualized treatment plans catered to the unique characteristics of each patient. Suggesting innovative approaches such as drug repositioning and mitochondrial drug delivery to enhance the efficacy of mitochondria-targeting therapies, presenting a pathway for advancements in cancer treatment. This thorough investigation is a major step forward in the treatment of cancer and has the potential to influence clinical practice and enhance patient outcomes.

Activation of Mitochondrial Oxygen Consumption Rate by Delivering Coenzyme Q10 to Mitochondria of Rat Skeletal Muscle Cell (L6)

Numerous mitochondria are present in skeletal muscle cells. Muscle disease and aging impair mitochondrial functioning in the skeletal muscle. However, there have been few reports of therapeutic intervention via drug delivery to mitochondria owing to methodological difficulties. We surmised that mitochondrial activation is associated with improved skeletal muscle function. In this study, we attempted to activate the mitochondrial respiratory capacity in rat skeletal muscle cells (L6 cells) by delivering Coenzyme Q10 (CoQ10), a mitochondrial functional activator, to mitochondria using MITO-Porter, a nanoparticle that facilitates mitochondria-targeted drug delivery. Cellular uptake was confirmed by measuring the amount of fluorescence-modified MITO-Porter taken up by cells using flow cytometry. Intracellular dynamics of MITO-Porter was observed using confocal laser scanning microscopy. Mitochondrial function was assessed by measuring the mitochondrial oxygen consumption rate using an extracellular flux analyzer. The results indicated MITO-Porter-assisted delivery of CoQ10 to the mitochondria activated mitochondrial respiratory capacity in L6 cells. We believe that our results indicate the possibility of skeletal muscle therapy using mitochondrial drug delivery.

Functionalized and Nonfunctionalized Nanosystems for Mitochondrial Drug Delivery with Metallic Nanoparticles.

Background: The application of metallic nanoparticles as a novel therapeutic tool has significant potential to facilitate the treatment and diagnosis of mitochondria-based disorders. Recently, subcellular mitochondria have been trialed to cure pathologies that depend on their dysfunction. Nanoparticles made from metals and their oxides (including gold, iron, silver, platinum, zinc oxide, and titanium dioxide) have unique modi operandi that can competently rectify mitochondrial disorders. Materials: This review presents insight into the recent research reports on exposure to a myriad of metallic nanoparticles that can alter the dynamic ultrastructure of mitochondria (via altering metabolic homeostasis), as well as pause ATP production, and trigger oxidative stress. The facts and figures have been compiled from more than a hundred PubMed, Web of Science, and Scopus indexed articles that describe the essential functions of mitochondria for the management of human diseases. Result: Nanoengineered metals and their oxide nanoparticles are targeted at the mitochondrial architecture that partakes in the management of a myriad of health issues, including different cancers. These nanosystems not only act as antioxidants but are also fabricated for the delivery of chemotherapeutic agents. However, the biocompatibility, safety, and efficacy of using metal nanoparticles is contested among researchers, which will be discussed further in this review.

Mitochondrial temperature-responsive drug delivery reverses drug resistance in lung cancer

Reversal of cancer drug resistance remains a critical challenge in chemotherapy. Mitochondria-targeted drug delivery has been suggested to mitigate drug resistance in cancer. To overcome the intrinsic limitations in conventional mitochondrial targeting strategies, we develop mitochondrial temperature-responsive drug delivery to reverse doxorubicin (DOX) resistance in lung cancer. Results demonstrate that the thermoresponsive nanocarrier can prevent DOX efflux and facilitate DOX accumulation and mitochondrial targeting in DOX-resistant tumors. As a consequence, thermoresponsive nanocarrier enhances the cytotoxicity of DOX and reverses the drug resistance in tumor-bearing mice. This work represents the first example of mitochondrial temperature-responsive drug delivery for reversing cancer drug resistance.

Mitochondrial nanomedicine: Subcellular organelle-specific delivery of molecular medicines

As mitochondria network together to act as the master sensors and effectors of apoptosis, ATP production, reactive oxygen species management, mitophagy/autophagy, and homeostasis; this organelle is an ideal target for pharmaceutical manipulation. Mitochondrial dysfunction contributes to many diseases, for example, β-amyloid has been shown to interfere with mitochondrial protein import and induce apoptosis in Alzheimer's Disease while some forms of Parkinson's Disease are associated with dysfunctional mitochondrial PINK1 and Parkin proteins. Mitochondrial medicine has applications in the treatment of an array of pathologies from cancer to cardiovascular disease. A challenge of mitochondrial medicine is directing therapies to a subcellular target. Nanotechnology based approaches combined with mitochondrial targeting strategies can greatly improve the clinical translation and effectiveness of mitochondrial medicine. This review discusses mitochondrial drug delivery approaches and applications of mitochondrial nanomedicines. Nanomedicine approaches have the potential to drive the success of mitochondrial therapies into the clinic.

Reversing Chemotherapy Resistance by a Synergy between Lysosomal pH-Activated Mitochondrial Drug Delivery and Erlotinib-Mediated Drug Efflux Inhibition.

Mitochondrial drug delivery has attracted increasing attention in various mitochondrial dysfunction-associated disorders such as cancer owing to the important role of energy production. Herein, we report a lysosomal pH-activated mitochondrial-targeting polymer nanoparticle to overcome drug resistance by a synergy between mitochondrial delivery of doxorubicin (DOX, an anticancer drug) and erlotinib-mediated inhibition of drug efflux. The obtained nanoparticles, DE-NPs could maintain negative charge and have long blood circulation while undergoing charge reversal at lysosomal pH after internalization by cancer cells. Thereafter, the acidity-activated polycationic and hydrophobic polypeptide domains boost lysosomal escape and mitochondrial-targeting drug delivery, leading to mitochondrial dysfunction, ATP suppression, and cell apoptosis. Moreover, the suppressed ATP supply and erlotinib enabled dual inhibition of drug efflux by DOX-resistant MCF-7/ADR cells, leading to significantly augmented intracellular DOX accumulation and a synergistic anticancer effect with a 17-fold decrease of IC50 relative to DOX. In vivo antitumor study demonstrates that DE-NPs efficiently suppressed the tumor burden in MCF-7/ADR tumor-bearing mice and led to negligible toxicity. This work establishes that a combination of mitochondrial drug delivery and drug efflux inhibition could be a promising strategy for combating multidrug resistance.

Therapeutic Strategies for Regulating Mitochondrial Oxidative Stress.

There have been many reports on the relationship between mitochondrial oxidative stress and various types of diseases. This review covers mitochondrial targeting photodynamic therapy and photothermal therapy as a therapeutic strategy for inducing mitochondrial oxidative stress. We also discuss other mitochondrial targeting phototherapeutic methods. In addition, we discuss anti-oxidant therapy by a mitochondrial drug delivery system (DDS) as a therapeutic strategy for suppressing oxidative stress. We also describe cell therapy for reducing oxidative stress in mitochondria. Finally, we discuss the possibilities and problems associated with clinical applications of mitochondrial DDS to regulate mitochondrial oxidative stress.

Power of mitochondrial drug delivery systems to produce innovative nanomedicines

Mitochondria carry out various essential functions including ATP production, the regulation of apoptosis and possess their own genome (mtDNA). Delivering target molecules to this organelle, it would make it possible to control the functions of cells and living organisms and would allow us to develop a better understanding of life. Given the fact that mitochondrial dysfunction has been implicated in a variety of human disorders, delivering therapeutic molecules to mitochondria for the treatment of these diseases is an important issue. To date, several mitochondrial drug delivery system (DDS) developments have been reported, but a generalized DDS leading to therapy that exclusively targets mitochondria has not been established. This review focuses on mitochondria-targeted therapeutic strategies including antioxidant therapy, cancer therapy, mitochondrial gene therapy and cell transplantation therapy based on mitochondrial DDS. A particular focus is on nanocarriers for mitochondrial delivery with the goal of achieving mitochondria-targeting therapy. We hope that this review will stimulate the accelerated development of mitochondrial DDS.

Cationic Oligopeptide-Functionalized Mitochondria Targeting Sequence Show Mitochondria Targeting and Anticancer Activity

Mitochondrial drug delivery systems require development of highly selective mitochondria-targeting carriers. In this study, we report that mitochondria targeting sequence (MTS)-hybrid cationic oligopeptide, MTS-H3R9, shows the dual role of a mitochondria targeting vector along with anticancer effect for cancer therapy. In cytotoxicity assays, MTS-H3R9 was shown to be more effective than MTS. MTS-H3R9 showed significant cell penetration and internalization activity compared to that of MTS along with more efficient escape from lysosome to the cytosol. We showed efficient targeting of MTS-H3R9 to mitochondria in HeLa cell line. Furthermore, we exhibited anticancer agent properties that mitochondrial-accumulated MTS-H3R9 caused cell death by reactive oxygen species generation and loss of mitochondrial membrane potential. MTS-H3R9 exhibited dramatically increased anticancer activity in 3D spheroids as well as in a 2D culture model. We demonstrated that MTS-H3R9 provides dual potentials both as a vehicle for targeted delivery and as a cancer treatment agent for therapeutic applications.

Nanotherapeutics with suitable properties for advanced anticancer therapy based on HPMA copolymer-bound ritonavir via pH-sensitive spacers

Ritonavir (RIT) is a widely used antiviral drug that acts as an HIV protease inhibitor with emerging potential in anticancer therapies. RIT causes inhibition of P-glycoprotein, which plays an important role in multidrug resistance (MDR) in cancer cells when overexpressed. Moreover, RIT causes mitochondrial dysfunction, leading to decreased ATP production and reduction of caveolin I expression, which can affect cell migration and tumor progression. To increase its direct antitumor activity, decrease severe side effects induced by the use of free RIT and improve its pharmacokinetics, ritonavir 5-methyl-4-oxohexanoate (RTV) was synthesized and conjugated to a tumor-targeted polymer carrier based on a N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer. Here we demonstrated that polymer-bound RTV enhanced the internalization of polymer-RTV conjugates, differing in RTV content from 4 to 15 wt%, in HeLa cancer cells compared with polymer without RTV. The most efficient influx and internalization properties were determined for the polymer conjugate bearing 11 wt% of RTV. This conjugate was internalized by cells using both caveolin- and clathrin-dependent endocytic pathways in contrast to the RTV-free polymer, which was preferentially internalized only by clathrin-mediated endocytosis. Moreover, we found the co-localization of the RTV-conjugate with mitochondria and a significant decrease of ATP production in treated cells. Thus, the impact on mitochondrial mechanism can influence the function of ATP-dependent P-glycoprotein and also the cell viability of MDR cancer cells. Overall, this study demonstrated that the polymer-RTV conjugate is a promising polymer-based nanotherapeutic, suitable for antitumor combination therapy with other anticancer drugs and a potential mitochondrial drug delivery system.

Cardiac progenitor cells activated by mitochondrial delivery of resveratrol enhance the survival of a doxorubicin-induced cardiomyopathy mouse model via the mitochondrial activation of a damaged myocardium

It has been reported that transplanting native cells would lack efficiency without producing artificial cell-tissue, due to the exaggerated oxidative stress in doxorubicin-induced cardiomyopathy. We attempted to activate cardiac progenitor cells (CPCs) by delivering resveratrol to mitochondria using a mitochondrial drug delivery system (MITO-Porter system). We first evaluated the viability of H9c2 cells (a cardio myoblast cell line) after doxorubicin treatment, where H9c2 cells were co-cultured with or without the mitochondria activated CPCs (referred to herein as MITO cell). We next evaluated the survival rate of doxorubicin treated mice, with or without the injection of MITO cells into the myocardium. Finally, we examined the molecular mechanism of the cell therapy by detecting oxidative stress and the induction of apoptosis in addition to quantification of the mRNA and protein levels about oxidative phosphorylation (OXPHOS). The MITO cell transplanted mice lived significantly longer than the conventional CPC transplanted ones. Oxidative stress and massive cell death were both significantly reduced in the MITO cell transplanted hearts, in which the expression levels of OXPHOS protein and gene were also higher than the control group. In doxorubicin-induced cardiomyopathy, the transplantation of MITO cells, which possess activated mitochondria, is more efficient compared to conventional CPC transplantation.

Bridging Pharmaceutical Chemistry with Drug and Nanoparticle Targeting to Investigate the Role of the 18-kDa Translocator Protein TSPO.

An interesting mitochondrial biomarker is the 18-kDa mitochondrial translocator protein (TSPO). Decades of study have shown that this protein plays an important role in a wide range of cellular functions, including opening of the mitochondrial permeability transition pore as well as programmed cell death and proliferation. Variations in TSPO expression have been correlated to different diseases, from tumors to endocrine and neurological disorders. TSPO has therefore become an appealing target for both early diagnosis and selective mitochondrial drug delivery. The number of structurally different TSPO ligands examined has increased over time, highlighting the scientific community's growing understanding of the roles of TSPO in normal and pathological conditions. However, only few TSPO ligands are characterized by the presence of groups that are potentially derivatizable; therefore only few such ligands are well suited for the preparation of targeted prodrugs or nanocarriers able to deliver therapeutics and/or diagnostic agents to mitochondria. This review provides an overview of the very few examples of drug delivery systems characterized by moieties that target TSPO.

Mitochondrial Delivery of Doxorubicin Using MITO-Porter Kills Drug-Resistant Renal Cancer Cells via Mitochondrial Toxicity

Most anticancer drugs are intended to function in the nuclei of cancer cells. If an anticancer drug could be delivered to mitochondria, the source of cellular energy, this organelle would be destroyed, resulting in the arrest of the energy supply and the killing of the cancer cells. To achieve such an innovative strategy, a mitochondrial drug delivery system targeted to cancer cells will be required. We recently reported on the development of a MITO-Porter, a liposome for mitochondrial delivery. In this study, we validated the utility of such a cancer therapeutic strategy by delivering anticancer drugs directly to mitochondria. We succeeded in packaging doxorubicin (DOX) as a model cargo in MITO-Porter to produce a DOX-MITO-Porter. We evaluated cellular toxicity of OS-RC-2 cell, a type of DOX-resistant cancer cell, after delivering DOX to mitochondria using the MITO-Porter system. Cell viability was decreased by the DOX-MITO-Porter treatment, while cell viability was not decreased in the case of naked DOX and a conventional DOX liposomal formulation. We also found a relationship between cellular toxicity and mitochondrial toxicity. The use of a MITO-Porter system for mitochondrial delivery of a toxic agent represents a possible therapeutic strategy for treating drug-resistant cancers.

Bioreducible Poly(ethylene glycol)-Triphenylphosphonium Conjugate as a Bioactivable Mitochondria-Targeting Nanocarrier.

Bioactivable nanocarrier systems have favorable characteristics such as high cellular uptake, target specificity, and an efficient intracellular release mechanism. In this study, we developed a bioreducible methoxy polyethylene glycol (mPEG)-triphenylphosphonium (TPP) conjugate (i.e., mPEG-(ss-TPP)2 conjugate) as a vehicle for mitochondrial drug delivery. A bioreducible linkage with two disulfide bond-containing end groups was used at one end of the hydrophilic mPEG for conjugation with lipophilic TPP molecules. The amphiphilic mPEG-(ss-TPP)2 self-assembled in aqueous media, which thereby formed core-shell structured nanoparticles (NPs) with good colloidal stability, and efficiently encapsulated the lipophilic anticancer drug doxorubicin (DOX). The DOX-loaded mPEG-(ss-TPP)2 NPs were characterized in terms of their physicochemical and morphological properties, drug-loading and release behaviors, in vitro anticancer effects, and mitochondria-targeting capacity. Our results suggest that bioreducible DOX-loaded mPEG-(ss-TPP)2 NPs can induce fast drug release with enhanced mitochondrial uptake and have a better therapeutic effect than nonbioreducible NPs.

ミトコンドリアを標的とする多機能性エンベロープ型ナノ構造体の創製とナノ医療への展開

A single cell contains a variety of organelles, including a nucleus, mitochondria, the golgi apparatus and others. If it were possible to prepare a nano craft that could specifically target a specific organelle, it would open a new field of research directed toward therapeutic treatments for a variety of diseases. We recently developed a new concept that we refer to as “Programmed Packaging”, by which we succeeded in creating a multifunctional envelope-type nano device (MEND) as a non-viral vector. Our attempts to target mitochondria are discussed here, mainly focusing on a MITO-Porter, a MEND for delivering cargoes to mitochondria. A variety of human diseases, including various neurodegenerative disorders, ischemic heart disease, diabetes and cancer have been reported to be associated with mitochondrial dysfunction. Because of this, mitochondrial therapy would be expected to be useful and productive in the treatment of such diseases. Our findings regarding mitochondrial drug delivery systems that are directed toward mitochondrial nano medicine development are summrized herein.

Mitochondrial DDS Opens Innovative Pharmaceutics

A variety of human diseases, including neurodegenerative disorders, ischemic heart disease, diabetes, and cancer have been reported to be associated with mitochondrial dysfunction. Because of this, mitochondrial therapy is expected to be useful and productive in the treatment of such diseases. We previously reported on the development of a MITO-Porter, a liposome-based nanocarrier that permits macromolecular cargos to be delivered into mitochondria via membrane fusion. Intracellular observations using the green fluorescence protein as a model macromolecule provided confirmation that a macromolecule could be delivered to mitochondria in living cells by the MITO-Porter. Here, we present our current findings on the development of mitochondrial medicine and mitochondrial gene therapy based on our mitochondrial drug delivery system (DDS). In this review, we propose "mitochondrial DDS" as a theme for "DDS research for innovative drug development" and discuss the contribution of mitochondrial DDS to innovative drug development.

MITO-Porter for Mitochondrial Delivery and Mitochondrial Functional Analysis.

Mitochondria are attractive organelles that have the potential to contribute greatly to medical therapy, the maintenance of beauty and health, and the development of the life sciences. Therefore, it would be expected that the further development of mitochondrial drug delivery systems (DDSs) would exert a significant impact on the medical and life sciences. To achieve such an innovative objective, it will be necessary to deliver various cargoes to mitochondria in living cells. However, only a limited number of approaches are available for accomplishing this. We recently proposed a new concept for mitochondrial delivery, a MITO-Porter, a liposome-based carrier that introduces macromolecular cargoes into mitochondria via membrane fusion. To date, we have demonstrated the utility of mitochondrial therapeutic strategy by MITO-Porter using animal models of diseases. We also showed that the mitochondrial delivery of antisense oligo-RNA by the MITO-Porter results in mitochondrial RNA knockdown and has a functional impact on mitochondria. Here, we summarize the current state of mitochondrial DDS focusing on our research and show some examples of mitochondrial functional regulations using mitochondrial DDS.

Abstract 2447: Development of Hsp90 paralog specific inhibitors with mitochondrial drug delivery system

Abstract The mitochondrial pool of Hsp90 and its mitochondrial paralog, TRAP1, suppresses cell death and reprograms energy metabolism in cancer cells; therefore, Hsp90 and TRAP1 have been suggested as target proteins for anticancer drug development. Here, we report that the actual target protein in cancer cell mitochondria is TRAP1, not Hsp90, and current Hsp90 inhibitors cannot effectively inactivate TRAP1 due to insufficient accumulation in the mitochondria. To develop mitochondrial TRAP1 inhibitors, we determined the crystal structures of human TRAP1 complexed with Hsp90 inhibitors. The isopropyl amine of the Hsp90 inhibitor PU-H71 was replaced with the mitochondria-targeting moiety triphenylphosphonium to produce SMTIN-P01. SMTIN-P01 showed a different mode of action from the non-targeted PU-H71, as well as much improved cytotoxicity to cancer cells. In addition, we determined the structure of a TRAP1-adenylyl-imidodiphosphate (AMP-PNP) complex. Based on comparative analysis of TRAP1 structures, we propose a molecular mechanism of ATP hydrolysis that is crucial for chaperone function. Citation Format: Byoung Heon Kang. Development of Hsp90 paralog specific inhibitors with mitochondrial drug delivery system. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2447. doi:10.1158/1538-7445.AM2015-2447

Development of the MITO-porter, a nano device for mitochondrial drug delivery via membrane fusion

Many human diseases have been reported to be associated with mitochondrial dysfunction. Therefore, mitochondrial therapy would be expected to be useful and productive in the treatment of various diseases. To achieve such an innovative therapy, it will be necessary to deliver therapeutic agents into mitochondria. However, only a limited number of methods are available for accomplishing this. We previously developed the MITO-Porter, a liposome-based carrier that permits macromolecular cargos to be transported into mitochondria via membrane fusion. Intracellular observations using the green fluorescence protein as a model macromolecule confirmed the mitochondrial delivery of a macromolecule by the MITO-Porter. Moreover, when we attempted the mitochondrial delivery of bongkrekic acid (BKA), an antiapoptosis agent, the MITO-Porter enhanced the antiapoptosis effect compared with naked BKA. To construct a device with enhanced performance, the MITO-Porter was coated with cell membrane-fusogenic outer envelopes to produce the dual function (DF)-MITO-Porter. Intracellular observations indicated that the DF-MITO-Porter was more effective in delivering exogenous macromolecules into mitochondria than the conventional MITO-Porter. Furthermore, when biomacromolecules were delivered using the DF-MITO-Porter to estimate the mitochondrial gene targeting of the carrier, the results confirmed that the MITO-Porter system has the potential for use in therapies aimed at mitochondrial DNA. This paper sumarizes our findings on mitochondrial drug delivery systems that are directed toward mitochondrial medicine development and mitochondrial gene therapy. It is expected that the MITO-Porter system will open new research areas in mitochondrial drug delivery systems and have a significant impact on the medical and life sciences.

Mitochondrial routing of glucose and sucrose polymers after pinocytotic uptake: avenues for drug delivery.

Mitochondria are key organelles organizing cellular metabolic flux. Therefore, a targeted drug delivery to mitochondria promises the advancement of medicine in fields that are associated with mitochondrial dysfunction. However, successful mitochondrial drug delivery is limited by complex transport steps across organelle membranes and fast drug efflux in cases of multidrug resistance. Strategies to deliver small-molecular-weight drugs to mitochondria are very limited, while the use of complex polymeric carriers is limited by a lack of clinical feasibility. We show here that clinically established macromolecules such as a sucrose copolymer (Ficoll 70/400 kDa) and polyglucose (dextran 70/500 kDa) are micropinocytosed swiftly by mesenchymal stem cells and subsequently routed to mitochondria. The intracellular level of Ficoll appears to decrease over time, suggesting that it does not persist within cells. After coupling to polysucrose, the low-molecular-weight photodynamic drug Rose Bengal reached mitochondria and thus exhibited an increased destructive potential after laser excitation. These findings support new opportunities to deliver already clinically approved drugs to mitochondria.