Selective targeting of c-Abl via a cryptic mitochondrial targeting signal activated by cellular redox status in leukemic and breast cancer cells

Endogenous ROS production in early differentiation state suppresses endoderm differentiation via transient FOXC1 expression

Oxidative stress plays a pivotal role in the differentiation and proliferation of cells and programmed cell death. However, studies on the role of oxidative stress in differentiation have mainly employed the detection of reactive oxygen species (ROS) during differentiation or generated by ROS inducers. Therefore, it is difficult to clarify the significance of endogenous ROS production in the differentiation of human cells. We developed a system to control the intracellular level of ROS in the initial stage of differentiation in human iPS cells. By introducing a specific substitution (I69E) into the SDHC protein, a component of the mitochondrial respiratory chain complex, the endogenous ROS level increased. This caused impaired endoderm differentiation of iPS cells, and this impairment was reversed by overproduction of mitochondrial-targeted catalase, an anti-oxidant enzyme. Expression of tumor-related FOXC1 transcription factor increased transiently as early as 4 h after ROS-overproduction in the initial stage of differentiation. Knockdown of FOXC1 markedly improved impaired endoderm differentiation, suggesting that endogenous ROS production in the early differentiation state suppresses endoderm differentiation via transient FOXC1 expression.

Delivery of drugs and macromolecules to the mitochondria for cancer therapy

Mitochondria are organelles that have pivotal functions in producing the energy necessary for life and executing the cell death pathway. Targeting drugs and macromolecules to the mitochondria may provide an effective means of inducing cell death for cancer therapy, and has been actively pursued in the last decade. This review will provide a brief overview of mitochondrial structure and function, how it relates to cancer, and importantly, will discuss different strategies of mitochondrial delivery including delivery using small molecules, peptides, genes encoding proteins and MTSs, and targeting polymers/nanoparticles with payloads to the mitochondria. The advantages and disadvantages for each strategy will be discussed. Specific examples using the latest strategies for mitochondrial targeting will be evaluated, as well as potential opportunities for specific mitochondrial compartment localization, which may lead to improvements in mitochondrial therapeutics. Future perspectives in mitochondrial targeting of drugs and macromolecules will be discussed. Currently this is an under-explored area that is prime for new discoveries in cancer therapeutics.

The DNA binding domain of p53 is sufficient to trigger a potent apoptotic response at the mitochondria

The tumor suppressor p53 is one of the most studied proteins in human cancer.1-3 While nuclear p53 has been utilized for cancer gene therapy, mitochondrial targeting of p53 has not been fully exploited to date.4,5 In response to cellular stress, p53 translocates to the mitochondria and directly interacts with Bcl-2 family proteins including antiapoptotic Bcl-XL and Bcl-2 and proapoptotic Bak and Bax.6 Antiapoptotic Bcl-XL forms inhibitory complexes with proapoptotic Bak and Bax preventing their homo-oligomerization.7 Upon translocation to the mitochondria, p53 binds to Bcl-XL, releases Bak and Bax from the inhibitory complex and enhances their homo-oligomerization.8 Bak and Bax homotetramer formation disrupts the mitochondrial outer membrane, releases antiapoptotic factors such as cytochrome c and triggers a rapid apoptotic response mediated by caspase induction.9 It is still unclear if the MDM2 binding domain (MBD), the proline-rich domain (PRD) and/or DNA binding domain (DBD) of p53 are the domains responsible for interaction with Bcl-XL.10-17 The purpose of this work is to determine if a smaller functional domain of p53 is capable of inducing apoptosis similarly to full length p53. To explore this question, different domains of p53 (MBD, PRD, DBD) were fused to the mitochondrial targeting signal (MTS) from Bcl-XL to ensure Bcl-XL specific targeting.18 The designed constructs were tested for apoptotic activity (TUNEL, Annexin-V, and 7-AAD) in 3 different breast cancer cell lines (T47D, MCF-7, MDA-MB-231), in a cervical cancer cell line (HeLa) and in non-small cell lung adenocarcinoma cells H1373. Our results indicate that DBD-XL (p53 DBD fused to the Bcl-XL MTS) reproduces (in T47D cells) or demonstrates increased apoptotic activity (in MCF-7, MDA-MB-231, and HeLa cells) compared to p53-XL (full length p53 fused to Bcl-XL MTS). Additionally, mitochondrial dependent apoptosis assays (TMRE, caspase-9), co-IP and overexpression of Bcl-XL in T47D cells suggest that DBD fused to XL MTS may bind to and inhibit Bcl-XL. Taken together, our data demonstrates for the first time that the DBD of p53 may be the minimally necessary domain for achieving apoptosis at the mitochondria in multiple cell lines. This work highlights the role of small functional domains of p53 as a novel cancer biologic therapy.

Enhanced and selective killing of chronic myelogenous leukemia cells with an engineered BCR-ABL binding protein and imatinib

The oncoprotein Bcr-Abl stimulates prosurvival pathways and suppresses apoptosis from its exclusively cytoplasmic locale, but when targeted to the mitochondrial compartment of leukemia cells, Bcr-Abl was potently cytotoxic. Therefore, we designed a protein construct to act as a mitochondrial chaperone to move Bcr-Abl to the mitochondria. The chaperone (i.e., the 43.6 kDa intracellular cryptic escort (iCE)) contains an EGFP tag and two previously characterized motifs: (1) an optimized Bcr-Abl binding motif that interacts with the coiled-coil domain of Bcr (ccmut3; 72 residues), and (2) a cryptic mitochondrial targeting signal (cMTS; 51 residues) that selectively targets the mitochondria in oxidatively stressed cells (i.e., Bcr-Abl positive leukemic cells) via phosphorylation at a key residue (T193) by protein kinase C. While the iCE colocalized with Bcr-Abl, it did not relocalize to the mitochondria. However, the iCE was selectively toxic to Bcr-Abl positive K562 cells as compared to Bcr-Abl negative Cos-7 fibroblasts and 1471.1 murine breast cancer cells. The toxicity of the iCE to leukemic cells was equivalent to 10 μM imatinib at 48 h and the iCE combined with imatinib potentiated cell death beyond imatinib or the iCE alone. Substitution of either the ccmut3 or the cMTS with another Bcr-Abl binding domain (derived from Ras/Rab interaction protein 1 (RIN1; 295 residues)) or MTS (i.e., the canonical IMS derived from Smac/Diablo; 49 residues) did not match the cytotoxicity of the iCE. Additionally, a phosphorylation null mutant of the iCE also abolished the killing effect. The mitochondrial toxicity of Bcr-Abl and the iCE in Bcr-Abl positive K562 leukemia cells was confirmed by flow cytometric analysis of 7-AAD, TUNEL, and annexin-V staining. DNA segmentation and cell viability were assessed by microscopy. Subcellular localization of constructs was determined using confocal microscopy (including statistical colocalization analysis). Overall, the iCE was highly active against K562 leukemia cells and the killing effect was dependent upon both the ccmut3 and functional cMTS domains.

Utilizing the estrogen receptor ligand-binding domain for controlled protein translocation to the insoluble fraction

PURPOSE

The estrogen receptor forms insoluble aggregates in the insoluble cytoskeletal subcellular fraction when bound to the antagonist fulvestrant. The ligand-binding domain was isolated and fused to signal sequences to target subcellular compartments. Sequestering a pro-apoptotic peptide tested the utility of a protein targeted to the insoluble fraction.

METHODS

The ligand-binding domain of the estrogen receptor was isolated and fused with signal sequences, either a nuclear localization signal or nuclear export signal. The subcellular localization when bound to drug fulvestrant was examined, specifically its interaction with cytokeratins 8 and 18. The ability to target a therapeutic peptide to the insoluble fraction was tested by fusing a therapeutic coiled-coil from Bcr-Abl in K562 cells.

RESULTS

The estrogen receptor ligand-binding domain responds to fulvestrant by translocating to the insoluble fraction. Adding a signal sequence significantly limited the translocation to either the nucleus or cytoplasm. The cytokeratin 8/18 status of the cell did not alter this response. The therapeutic coiled-coil fused to ERLBD was inactivated upon ligand induction.

CONCLUSIONS

Isolating the ligand-binding domain of the estrogen receptor creates a ligand-controllable protein capable of translocation to the insoluble fraction. This can be used to sequester an active peptide to alter its function.

Targeting malignant mitochondria with therapeutic peptides

The current status of peptides that target the mitochondria in the context of cancer is the focus of this review. Chemotherapy and radiotherapy used to kill tumor cells are principally mediated by the process of apoptosis that is governed by the mitochondria. The failure of anticancer therapy often resides at the level of the mitochondria. Therefore, the mitochondrion is a key pharmacological target in cancer due to many of the differences that arise between malignant and healthy cells at the level of this ubiquitous organelle. Additionally, targeting the characteristics of malignant mitochondira often rely on disruption of protein--protein interactions that are not generally amenable to small molecules. We discuss anticancer peptides that intersect with pathological changes in the mitochondrion.