Binary Proton Therapy of Ehrlich Carcinoma Using Targeted Gold Nanoparticles.

Proton therapy can treat tumors located in radiation-sensitive tissues. This article demonstrates the possibility of enhancing the proton therapy with targeted gold nanoparticles that selectively recognize tumor cells. Au-PEG nanoparticles at concentrations above 25 mg/L and 4 Gy proton dose caused complete death of EMT6/P cells in vitro. Binary proton therapy using targeted Au-PEG-FA nanoparticles caused an 80% tumor growth inhibition effect in vivo. The use of targeted gold nanoparticles is promising for enhancing the proton irradiation effect on tumor cells and requires further research to increase the therapeutic index of the approach.

Polymer/magnetite carriers functionalized by HER2-DARPin: Avoiding lysosomes during internalization and controlled toxicity of doxorubicin by focused ultrasound induced release.

Nanomedicine has revolutionized the available treatment options during the last decade, but poor selectivity of targeted drug delivery and release is still poses a challenge. In this study, doxorubicin (DOX) and magnetite nanoparticles were encapsulated by freezing-induced loading, coated with polymeric shell bearing two bi-layers of polyarginine/dextran sulphate and finally modified with HER2-specific DARPin proteins. We demonstrated that the enhanced cellular uptake of these nanocarriers predominantly occurs by SKOV-3 (HER2+) cells, in comparison to CHO (HER2-) cells, together with the controlled DOX release using low intensity focused ultrasound (LIFU). In addition, a good ability of DARPin+ capsules to accumulate in the tumor and the possibility of combination therapy with LIFU were demonstrated. A relatively high sensitivity of the obtained nanocarriers to LIFU and their preferential interactions with mitochondria in cancer cells make these carriers promising candidates for cancer treatment, including novel approaches to overcome drug resistance.

Barnase-barstar Specific Interaction Regulates Car-T Cells Cytotoxic Activity toward Malignancy.

The development of CAR-T specific therapy made a revolution in modern oncology. Despite the pronounced therapeutic effects, this novel approach displayed several crucial limitations caused by the complications in pharmacokinetics and pharmacodynamics controls. The presence of the several severe medical complications of CAR-T therapy initiated a set of attempts aimed to regulate their activity in vivo. We propose to apply the barnase-barstar system to control the cytotoxic antitumor activity of CAR-T cells. To menage the regulation targeting effect of the system we propose to use barstar-modified CAR-T cells together with barnase-based molecules. Barnase was fused with designed ankyrin repeat proteins (DARPins) specific to tumor antigens HER2 (human epidermal growth factor receptor 2) The application of the system demonstrates the pronounced regulatory effects of CAR-T targeting.

Synergistic Effect of the Combined Action of Targeted and Photodynamic Therapy on HER2-Positive Breast Cancer.

Development of combined schemes for the treatment of oncological diseases is a promising strategy to improve the effectiveness of antitumor therapy. This paper shows the fundamental possibility of multiplying the antitumor effect by combining targeted and photodynamic therapy. It was demonstrated that sequential treatment of HER-2 positive breast cancer cells with the targeted toxin DARPin-LoPE and the photoactive compound photodithazine leads to a synergistic enhancement of their effect. In the future, this approach is intended to achieve the maximum therapeutic effect while minimizing the risks of negative side effects.

[Doxycycline Sensitive Two-Promoter Integrator Based on the TET-ON 3G Transactivator].

A synthetic genetic chain was created-a two-promoter integrator, the activity of the output signal of which is high only with the high activity of two promoters at the input of the chain. The integrator is shown to work by the example of cancer-specific promoters of the human survivin and telomerase genes that can be used for specific transcription of target genes in tumor cells. To create the integrator, we used the well-known TET-ON 3G transactivator, regulated by doxycycline.

Multifunctional Complexes Based on Photoluminescent Upconversion Nanoparticles for Theranostics of the HER2-Positive Tumors.

Combining diagnostic and therapeutic functions in one agent is a promising strategy in the development of personalized approaches to the treatment of cancer. The opportunity to combine diagnostics and therapy appeared with the development of nanobiotechnologies and was realized in the concept of theranostics. To date, a number of promising agents based on nanomaterials capable of diagnosing, targeted therapeutic effects, and monitoring the response of tumor cells were obtained within the approach of theranostics. In this work, a new type of theranostic complexes based on upconversion nanoparticles coated with polyethylene glycol and functionalized with the DARPin-LoPE recombinant targeted toxin was developed. Selective binding of complexes to human breast adenocarcinoma cells overexpressing the HER2 receptor and specific toxicity to them were shown.

Magnetometry based method for investigation of nanoparticle clearance from circulation in a liver perfusion model.

Nanoparticles (NPs) are among the most promising agents for advanced theranostics. However, their functioning in vivo is severely inhibited by the mononuclear phagocyte system (MPS), which rapidly removes all foreign entities from blood circulation. Little is known about the sequestration mechanisms and the ways to counteract them. New methods are highly demanded for investigation with high scrutiny of each aspect of NP clearance from blood. For example, while liver macrophages capture the majority of the administered particles, reliable investigation of this process in absence of other MPS components is hard to implement in vivo. Here, we demonstrate a novel method for real-time investigation hepatic uptake of NPs in an isolated perfused liver based on an extremely accurate magnetometric registration technique. The signal is obtained solely from the magnetic NPs without any 'background' from blood or tissues, which is a significant advantage over other techniques, e.g. optical ones. We illustrate the method capacity by investigation of behavior of different particles and show good correlation with in vivo studies. We also demonstrate notable suitability of the method for studying the NP clearance from the flow in the user-defined mediums, e.g. those containing specific serum components. Finally, the method was applied to reveal an interesting effect of short-term decrease of liver macrophage activity after the first interaction with small amounts of NPs. The developed perfusion model based on the high-performance magnetometry can be used for finding new mechanisms of NP sequestration and for development of novel 'stealth' nanoagents.

Removal of the Translocation Domain and the Furin Cleavage Site Decreases the Relative Hepatotoxicity of the Targeted Antitumor Toxins.

Targeted toxins are promising anticancer agents that allow selectively destroying cancer cells due to the increased content of onco-specific markers on their surface. The use of such anti-cancer toxins in medicine is mainly hampered by their high non-specific toxicity, in particular, hepatotoxicity. In our work on human cell line, we have shown that the removal of the DARPin-PE40 translocation toxin domain leads to a decrease in hepatotoxicity. The same effect is also observed when inactivation of the furin cleavage site in the DARPin-PE40 molecule was done. Simultaneous removal of both the translocation domain and the furin cleavage site showed the best results. This toxin modification can be used to create more selective anti-cancer toxins.

The Application of Recombinant Phototoxins 4D5scFv-miniSOG and DARPin-miniSOG to Study the HER2 Receptor Internalization.

It was found that the fluorescent properties of the phototoxic domain of miniSOG allow to assess the ability of toxins to bind to human breast adenocarcinoma cells SK-BR-3 and study the dynamics of their internalization. We established that the main cause of the decrease of the fluorescence intensity of the recombinant proteins 4D5scFv-miniSOG and DARPin-miniSOG during their internalization in the complex with the HER2 receptor is their shielding and absorption of the fluorescence of miniSOG by the cells fluorophores.

Death Mechanism of Breast Adenocarcinoma Cells Caused by BRET-Induced Cytotoxicity of miniSOG Depends on the Intracellular Localization of the NanoLuc-miniSOG Fusion Protein.

Photodynamic therapy (PDT) is widely used in clinical practice to influence neoplasms in the presence of a photosensitizer, oxygen, and light source. The main problem of PDT of deep tumors is the problem of delivering excitation light (without lost of its intensity) inside the body. An alternative to the external light sources can be the internal light sources based on luciferase-substrate bioluminescent systems. In our work, we used the NanoLuc-furimazine system as an internal light source. This system can be successfully used to excite the protein photosensitizer miniSOG and to induce the phototoxicity of this flavoprotein in cancer cells during bioluminescent resonance energy transfer (BRET). It was shown that the mechanism of cell death caused by BRET-induced phototoxicity of mimiSOG in the presence of furimazine depends on the intracellular localization of the NanoLuc-miniSOG fusion protein: BRET-mediated activation of miniSOG in mitochondrial localization causes apoptosis, while the membrane localization of PS causes necrosis of cancer cells.

Synthesis of Magnetic Nanoparticles Stabilized by Magnetite-Binding Protein for Targeted Delivery to Cancer Cells.

A new method for obtaining biomodified magnetite nanoparticles for targeted delivery to cells was developed. The method is based on the use of the C-terminal fragment of the Mms6 protein, which is involved in the magnetite biomineralization during the synthesis of magnetosomes in magnetotactic bacteria Magnetospirillum magneticum AMB-1, and the barnase*barstar high-affinity protein pair. The Mms6 protein fragment is required for stabilizing magnetite, and the barnase*barstar pair mediates the interaction between nanoparticles and the component for modification. The efficiency of this method was confirmed in the synthesis of magnetite nanoparticles recognizing the HER2/neu tumor marker and in the selective labeling of HER2/neu with these nanoparticles on the surface of cancer cells.

[Targeted Bifunctional Proteins and Hybrid Nanoconstructs for Cancer Diagnostics and Therapies].

In this review, the authors' works published within the past 5 years devoted to the development of bifunctional hybrid nanostructures based on the targeting polypeptides and nanoparticles of various origin (quantum dots, nanogold, nanodiamonds, upconversion nanoparticles, magnetic and polymer nanoparticles) as modules that ensure visualization and various damaging effects on cancer cells are surveyed and the prospects of their application in theranostics and precision medicine have been contemplated.

[Bifunctional Toxin DARP-LoPE Based on the HER2-Specific Innovative Module of a Non-Immunoglobulin Scaffold as a Promising Agent for Theranostics].

We have generated and characterized HER2-specific targeted toxin based on the low-immunogenic variant of Pseudomonas exotoxin A (LoPE), in which most of the human immunodominant B-cell epitopes have been inactivated. Nonimmunoglobulin DARPin-based HER2-specific protein was used as a targeting module for toxin delivery to the cellular target. Using confocal microscopy, it has been found that both domains in this hybrid toxin retained their functionality, i.e., the specific interaction with HER2 receptor, as well as the internalization and effective transport to ER typical of the wild-type Pseudomonas exotoxin A. The HER2-dependent cytotoxic effect correlated with receptor expression level at the cell surface, as shown in vitro using cell lines with different levels of HER2 expression. Due to the very high selective cytotoxicity against HER2-positive human tumor cells, as well as expected low immunogenicity, we believe that this new targeted toxin may be promising for future in vivo studies as a therapeutic agent for HER2-positive tumors.

Flavoprotein miniSOG BRET-induced cytotoxicity depends on its intracellular localization.

It is proposed to use the bioluminescent resonance energy transfer to solve the problem of creating the internal light sources in photodynamic therapy of cancer. Energy donor in the developed system is the oxidized form of the luciferase NanoLuc substrate furimamide, and acceptor is the phototoxic fluorescent protein miniSOG. It is shown that, in the proposed system, the photoinduced cytotoxicity of flavoprotein miniSOG in vitro depends on the intracellular localization, and the cytotoxic effect is 48% for the cytoplasmic localization of the fusion protein, 65% for the mitochondrial localization, and 69% for the membrane localization. The obtained data indicate that, for maximization of the photodynamic effect in vivo, it is appropriate to use the NanoLuc-miniSOG fusion protein in the membrane localization.

Cytotoxicity of targeted HER2-specific phototoxins based on flavoprotein miniSOG is determined by the rate of their internalization.

The concept of targeted therapy implies the development of bifunctional agents complementing the therapeutic module with a targeting one. A promising target for the delivery of imaging and/or toxic modules is the HER2 (ErbB2) receptor. Earlier, we have functionally characterized the targeted photosensitizers 4D5scFv-miniSOG and DARPin-miniSOG, causing the death of HER2-overexpressing cells when irradiated with blue light. However, the cytotoxicity of targeted toxins 4D5scFv-miniSOG and DARPin-miniSOG (both having functionally active targeted and cytotoxic modules in recombinant proteins) against human breast adenocarcinoma cells differs 5 times. The study of the dynamics of internalization of 4D5scFv-miniSOG and DARPin-miniSOG proteins in the complex with HER2 in this work showed that the rate of internalization contributes most significantly to the toxicity of these photosensitizers, because it determines the duration of the presence of the phototoxin in the lipid bilayer of the cell membrane, where its damaging effect is maximum.

Synthesis of magnetic silica nanomarkers with controlled physicochemical properties.

Magnetic markers which can be detected with an extremely high sensitivity with the method of magnetic particle quantification (MPQ) were synthesized. Using a controlled Stober reaction, a set of magnetic silica markers of different sizes and zeta potentials was obtained. The use of a carboxymethyl dextran polymer to stabilize the magnetite particles during the synthesis made it possible to substantially reduce the detection limit of the obtained construct, which opens up new opportunities for creating effective diagnostic nanoagents.

Development and investigation of recombinant immunotoxin protein 4D5scFv-mCherry-PE(40).

Development of agents for theranostics implies combining the targeting module, the effector module, and the detection module within the same complex or recombinant protein. We have constructed, isolated, and characterized the 4D5scFv-mCherry-PE(40) protein, which exhibits fluorescent properties and specifically binds to cancer cells expressing the HER2 receptor and reduces their viability. The ability of the obtained targeted antitumor agent 4D5scFv-mCherry-PE(40) to selectively stain the HER2-positive cells and its highly selective cytotoxicity against these cells make the obtained targeted recombinant protein 4D5scFv-mCherry-PE(40) a promising theranostic agent for the diagnostics and therapy of HER2-positive human tumors.

[Supramolecular Agents for Theranostics].

This mini-review summarizes recent data obtained in the process of creation of a versatile module platform suitable for construction of supramolecular theranostic agents. As an example, we consider multifunctional hybrid agents for imaging and elimination of cancer cells. The use of an adapter protein system barnase:barstar for producing targeted multifunctional hybrid structures on the basis of highly specific peptides and mini-antibodies as addressing modules and recombinant proteins and/or nanoparticles of different nature (quantum dots, nanogold, magnetic nanoparticles, nanodiamonds, upconverting nanophosphores, polymer nanoparticles) as agents visualizing and damaging cancer cells is described. New perspectives for creation of selective and highly effective compounds for theranostics and personified medicine are contemplated.

[Targeted Delivery of Quantum Dots to HER2-Expressing Tumor Using Recombinant Antibodies].

Targeted delivery of semiconductor quantum dots (Q Ds) to tumors overexpressing HER2 cancer marker has been. demonstrated on immunocompromised mice bearing human breast cancer xenografts. To obtain targeted QDs complexes we applied the approach based on the use of protein adaptor system, RNAase barnase and its inhibitor barstar. Specific binding to target cancer marker was achieved through bivalent fusion protein containing two fragments of4D5scFv recombinant antibody and a fragment of barnase. QDs were conjugated to barstar, and final assembly of targeted complexes was obtained through non-covalent specific interaction of barstar, attached to QD, and barnase, that is part of the recombinant targeting protein. The efficient delivery of QDs to HER2-expressing tumor demonstrates the possibilities and prospects of the approach for targeted delivery of nanoparticles to cancer cells in vivo as the way to improve the efficiency of diagnosis and promote development of therapies based on the use of nanoparticles.

A comprehensive study of interactions between lectins and glycoproteins for the development of effective theranostic nanoagents.

A comprehensive study of the interactions between lectins and glycoproteins possessing different glycosylation profiles in the composition of nanoparticles was carried out in order to find specifically interacting protein pairs for the creation of novel classes of multifunctional nanoagets that based on protein-assisted selfassembly. We obtained information about specific interactions of certain lectins with selected glycoproteins as well as about the ability of certain monosaccharides to competitively inhibit binding of glycoproteins with lectins. These protein-mediated interactions may be involved in the formulation of self-assembled nanoparticles for therapy and diagnostics of various diseases.