Myxococcus xanthus Encapsulin as a Promising Platform for Intracellular Protein Delivery

Introducing a new genetically encoded material containing a photoactivatable label as a model cargo protein, based on Myxococcus xanthus (Mx) encapsulin system stably expressed in human 293T cells. Encapsulin from Mx is known to be a protein-based container for a ferritin-like cargo in its shell which could be replaced with an exogenous cargo protein, resulting in a modified encapsulin system. We replaced Mx natural cargo with a foreign photoactivatable mCherry (PAmCherry) fluorescent protein and isolated encapsulins, containing PAmCherry, from 293T cells. Isolated Mx encapsulin shells containing photoactivatable label can be internalized by macrophages, wherein the PAmCherry fluorescent signal remains clearly visible. We believe that a genetically encoded nanocarrier system obtained in this study, can be used as a platform for controllable delivery of protein/peptide therapeutics in vitro.


Introduction
To date, therapies using various types of peptides are demonstrating their great potential in the treatment of diseases due to higher specificity, higher bioactivity and lower toxicity. Such proteins/peptides as insulin, growth factors, monoclonal antibodies and many others have been developed and applied in the clinical treatment of cancer, endocrinological diseases and other pathologies [1]. However, there are several difficulties associated with the use of such protein-based drugs due to their short lifetime and in vivo instability. Encapsulation of therapeutic peptides can prevent degradation and prolong circulation time.
There are a number of systems which can be used for encapsulation of therapeutic peptides/proteins such as: inorganic nanoparticles, liposomes, vesicles, etc [2]. For example, pluronics (in particular, PF127) have already been approved by FDA for insulin, interleukin-2 and various hormone delivery systems [3]. Polysaccharides such as chitosan and dextran were successfully applied for loading various protein/peptide therapeutics of IgG, VEGF (vascular endothelial growth factor) [4] and EGF (epidermal growth factor) [5]. Hydrogel-based systems for protein/peptide therapeutics delivery were also used. For example, collagen/hyaluronan, albumin/hyaluronan and gelatin incorporated hydrogels were designed to load EGF [6], Cx43MP (Connexin43 mimetic peptide) [7] and BMP-2 (bone morphogenetic protein) [8], respectively. Liposomes are the most studied nanocarrier 2 of 11 systems [9] and they can be used for encapsulation of therapeutic proteins. The liposomes allowed containing granzyme B in a combination with mRNA [10]. There are other delivery systems for therapeutic proteins/enzymes; however, the goal of nanocarrier systems is to preserve the activity of loaded protein.
Despite the plethora of tools available, the development of new protein/peptide delivery systems is an extremely urgent task. In this work, we present a genetically encoded nanocarrier based on Myxococcus xanthus (Mx) encapsulin system, containing photoactivatable mCherry (PAmCherry) fluorescent cargo protein label as a model cargo protein, expressed in 293T cells. Encapsulins are bacterial/archaeal high molecular weight capsidlike nanocompartments involved in various aspects of bacterial/archaeal metabolism [11], for example, wild-type Mx encapsulins are able to play a role in iron sequestration. Mx encapsulin consists of a protein shell (~32 nm diameter) which is self-assembled from 180 protomer proteins with a molecular weight equal to 32.5 kDa each, and ferritin-like cargo proteins (MxBCD). The protein shell of Mx encapsulin is encoded by the EncA gene [12]. The biological purpose of the cargo proteins encapsulation in bacteria and archaea is still unknown; however, some data support the hypothesis that encapsulation can increase the stability or lifetime of cargo proteins. It is also well known that encapsulin protein shells are extremely stable against pH and temperature changes [13][14][15] which is important for the preservation of cargo protein.
Previously, the possibility of transient expression of encapsulins loaded with PAm-Cherry protein was shown in HEK293T cell line and it was shown that encapsulated PAmCherry protein retains its fluorescent properties [16]. In our work, a cell line stably expressing encapsulin system with PAmCherry protein as a model cargo was obtained by lentiviral transduction, which allows to produce encapsulins in 293T cells for a long period of time. Moreover, we have shown that isolated encapsulins from a stable cell line can be internalized by macrophages retaining PAmCherry fluorescent activity up to 2 h. Therefore, in this paper we present an extremely robust, genetically encoded nanocontainer system based on bacterial Mx encapsulins stably expressed in human 293T cells. Genes encoding Mx encapsulin shell protomer proteins (EncA-FLAG), and genes encoding photoactivatable mCherry protein were inserted into 293T cells genome via lentiviral transduction. This technique allows to obtain a stable cell line expressing encapsulated photoactivatable mCherry label (293T EncA_PAmCherry cells). Encapsulated PAmCherry label can be isolated from 293T EncA_PAmCherry cells by immunoprecipitation. Isolated encapsulin shells containing photoactivatable cargo protein can be successfully internalized by RAW 264.7 cells (mouse macrophage-like cell line) wherein the PAmCherry fluorescent signal remains clearly distinguishable, proving that the loaded PamCherry protein remains intact and functionally active. In light of the aforementioned, we can assume that the genetically encoded nanocarrier obtained in this study can be used in the future as a possible platform for nanoshell-based protein delivery tools.

Expression of Encapsulated PAmCherry in 293T Cells
To achieve stable expression of PAmCherry fluorescent protein encapsulated into Mx encapsulin shell in 293T cells, we performed lentiviral transduction. We used two viral vectors: the first one carried Mx encapsulin protomer protein encoding genes (EncA, tagged with a FLAG sequence), and the second one carried genes encoding fluorescent PAmCherry cargo. As previously mentioned, the PAmCherry encoding gene is coupled to a destabilization domain, which leads to degradation of the PAmCherry protein if not encapsulated into Mx shell. Blue Native PAGE (BN-PAGE) analysis of 293T EncA_PAmCherry cells is presented in Figure 1a which shows one band corresponding to assembled Mx encapsulin shells and it is clearly seen that such a band is absent in the control (non-transduced) 293T cells.
assembled Mx encapsulin shells and it is clearly seen that such a band is absent in the control (non-transduced) 293T cells. To detect the FLAG sequence co-expressed with EncA on encapsulin protomer proteins in 293T EncA_PAmCherry cells, we also performed direct immunostaining using monoclonal anti-DYKDDDDK Tag monoclonal antibodies labeled with Alexa Fluor 488 label (Ex-Max 495 nm/Em-Max 519 nm) and 293T cells were used as a control. The high intensity green fluorescent signal from Alexa Fluor 488 label in 293T En-cA_PAmCherry cells (Figure 1b) is visible in the micrograph. Fluorescent signal wasn't detected in non-transduced 293T cells stained with anti-DYKDDDDK Tag antibodies (Figure 1c).
To quantitatively evaluate whether the presence of a genetically encoded label affects 293T EncA_PAmCherry cells viability and proliferation rates, we compared the To detect the FLAG sequence co-expressed with EncA on encapsulin protomer proteins in 293T EncA_PAmCherry cells, we also performed direct immunostaining using monoclonal anti-DYKDDDDK Tag monoclonal antibodies labeled with Alexa Fluor 488 label (Ex-Max 495 nm/Em-Max 519 nm) and 293T cells were used as a control. The high intensity green fluorescent signal from Alexa Fluor 488 label in 293T EncA_PAmCherry cells (Figure 1b) is visible in the micrograph. Fluorescent signal wasn't detected in nontransduced 293T cells stained with anti-DYKDDDDK Tag antibodies (Figure 1c).
To quantitatively evaluate whether the presence of a genetically encoded label affects 293T EncA_PAmCherry cells viability and proliferation rates, we compared the dynamics of growth of intact 293T and 293T EncA_PAmCherry cells on different days (1, 3, 5) of culture using MTS assay in which the absorbance at 490 nm is proportional to the number of living cells. The proliferation rates of 293T EncA_PAmCherry and intact 293T cells (Figure 1d) are not statistically different. Therefore, we can conclude that there are no negative effects on cell viability and proliferation associated with the presence of a genetically encoded label in 293T EncA_PAmCherry cells.

Encapsulated PAmCherry Photoactivation in Cells
We performed confocal microscopy photoactivation experiments in 293T EncA_PAmCherry cells using intact 293T cell as a control. Initially (before photoactivation) no fluorescence signal in the red channel was detected; however, after irradiation with blue light followed by 561 nm excitation, the intensity of red fluorescence signal in 293T EncA_PAmCherry cells increased dramatically (Supplementary Video S3). Following photoactivation of EncA_PAmCherry with 405 nm laser light over various periods of time, fluorescence signal in the cytoplasm was detected, which progressively increased over the course of 30 s (Figure 2, lower panel). Supplementary Video S1 demonstrates life imaging of the photoactivation process in 293T EncA_PAmCherry cells during simultaneous irradiation with 405 nm and 561 nm lasers.
dynamics of growth of intact 293T and 293T EncA_PAmCherry cells on different days (1, 3, 5) of culture using MTS assay in which the absorbance at 490 nm is proportional to the number of living cells. The proliferation rates of 293T EncA_PAmCherry and intact 293T cells ( Figure 1d) are not statistically different. Therefore, we can conclude that there are no negative effects on cell viability and proliferation associated with the presence of a genetically encoded label in 293T EncA_PAmCherry cells.

Encapsulated PAmCherry Photoactivation in Cells
We performed confocal microscopy photoactivation experiments in 293T En-cA_PAmCherry cells using intact 293T cell as a control. Initially (before photoactivation) no fluorescence signal in the red channel was detected; however, after irradiation with blue light followed by 561 nm excitation, the intensity of red fluorescence signal in 293T EncA_PAmCherry cells increased dramatically (Supplementary Video S3). Following photoactivation of EncA_PAmCherry with 405 nm laser light over various periods of time, fluorescence signal in the cytoplasm was detected, which progressively increased over the course of 30 s ( Figure 2, lower panel). Supplementary Video S1 demonstrates life imaging of the photoactivation process in 293T EncA_PAmCherry cells during simultaneous irradiation with 405 nm and 561 nm lasers.

Uptake of Encapsulated Fluorescent Cargo Protein by RAW 264.7 Cells
To further study the fate of encapsulated PAmCherry cargo in cells, we isolated encapsulins from 293T EncA_PAmCherry cells using the immunoprecipitation method. Hydrodynamic size (Figure 3a) of isolated encapsulins (EncA_PAmCherry) in TBS buffer measured by dynamic light scattering method amounted to 34 ± 4 nm with 0,22 PDI (polydispersity index). We also performed TEM imaging of isolated EncA_PAmCherry (Figure 3b).  In contrast, fluorescence signal wasn't detected in 293T cells neither before nor after photoactivation ( Figure 2, upper panel; Supplementary Video S2).

Uptake of Encapsulated Fluorescent Cargo Protein by RAW 264.7 Cells
To further study the fate of encapsulated PAmCherry cargo in cells, we isolated encapsulins from 293T EncA_PAmCherry cells using the immunoprecipitation method. Hydrodynamic size (Figure 3a) of isolated encapsulins (EncA_PAmCherry) in TBS buffer measured by dynamic light scattering method amounted to 34 ± 4 nm with 0,22 PDI (polydispersity index). We also performed TEM imaging of isolated EncA_PAmCherry (Figure 3b).
Isolated encapsulins containing PAmCherry label were added to RAW 264.7 cells. After the addition of EncA_PAmCherry to the macrophage cells and subsequent incubation for 15 min, 1 h, 2 h and 24 h, lysosomes were additionally stained with LysoTracker Deep Red (Ex-Max 647 nm/Em-Max 668 nm) and confocal microscopy imaging of the cells was performed as described above. It was found (Figure 4a) that after 15 min of incubation, PAmCherry fluorescence signal in the red channel was already quite low but clearly visible. Then, the intensity of the signal gradually increased with an increase in incubation time to 1 h (Figure 4b). The signal was still clearly distinguishable after 2 h of incubation of RAW 264.7 cells with EncA_PAmCherry ( Figure 4c). Finally, after 24 h of incubation only minor fluorescence signal in the red channel was detected (Figure 4d). We assume that Mx protein shells and PAmCherry label were digested by the cells.  Isolated encapsulins containing PAmCherry label were added to RAW 264.7 cells. After the addition of EncA_PAmCherry to the macrophage cells and subsequent incubation for 15 min, 1 h, 2 h and 24 h, lysosomes were additionally stained with LysoTracker Deep Red (Ex-Max 647 nm/Em-Max 668 nm) and confocal microscopy imaging of the cells was performed as described above. It was found (Figure 4a) that after 15 min of incubation, PAmCherry fluorescence signal in the red channel was already quite low but clearly visible. Then, the intensity of the signal gradually increased with an increase in incubation time to 1 h (Figure 4b). The signal was still clearly distinguishable after 2 h of incubation of RAW 264.7 cells with EncA_PAmCherry ( Figure 4c). Finally, after 24 h of incubation only minor fluorescence signal in the red channel was detected (Figure 4d). We assume that Mx protein shells and PAmCherry label were digested by the cells.   Isolated encapsulins containing PAmCherry label were added to RAW 264.7 cells. After the addition of EncA_PAmCherry to the macrophage cells and subsequent incubation for 15 min, 1 h, 2 h and 24 h, lysosomes were additionally stained with LysoTracker Deep Red (Ex-Max 647 nm/Em-Max 668 nm) and confocal microscopy imaging of the cells was performed as described above. It was found (Figure 4a) that after 15 min of incubation, PAmCherry fluorescence signal in the red channel was already quite low but clearly visible. Then, the intensity of the signal gradually increased with an increase in incubation time to 1 h (Figure 4b). The signal was still clearly distinguishable after 2 h of incubation of RAW 264.7 cells with EncA_PAmCherry ( Figure 4c). Finally, after 24 h of incubation only minor fluorescence signal in the red channel was detected (Figure 4d). We assume that Mx protein shells and PAmCherry label were digested by the cells.  Notably, the part of the PAmCherry signal was colocalized with LysoTracker far-red fluorescence signal. Further experiments are needed to determine the mechanisms of Mx encapsulin nanoshell endocytosis.

Discussion
In a number of previously published articles, we have shown that stable heterologous expression of bacterial encapsulin shell encoding genes can be successfully achieved in mammalian cell lines, wherein the presence of heterogenous sequences in cells did not affect the rate of cell proliferation. One of our previous studies has shown that stable heterologous expression of Mx encapsulin genes can be achieved in human mesenchymal stem cells (MSCs). In that study, a lentiviral construct encoding the MxEncA-FLAG subsequence was used in conjunction with a lentiviral vector encoding the natural Mx BCD cargo protein and showed its high efficiency in MSCs transduction. [17]. We have also already obtained a mouse carcinoma cell line stably expressing Quasibacillus thermotolerans (Qt) encapsulin genes which allows the tracking of carcinoma cells via MRI [18]. Thus, our previous research has focused on the study of stable expressed Mx and Qt encapsulins in mammalian cells as genetically encoded reporters that enable non-invasive cell tracking. In the present study, the obtained cell line performs an auxiliary function allowing the production and isolation of Mx encapsulins.
Current observations confirmed that encapsulins are able to encapsulate various types of engineered cargo proteins, for example TFP (teal fluorescent protein) [19], EGFP (enhanced green fluorescent protein), luc (firefly luciferase) [20], peroxidase [14] and many others. This feature allows for the use of encapsulin-based systems in a variety of applications such as reporter systems, nanoreactors, targeted drug delivery platforms and nanocarriers for biomaterials synthesis.
There is existing research describing the use of encapsulins as a nanocontainer system to deliver various types of cargo to cells. For example, in one study [21] Thermotoga maritima encapsulins were used as a system for targeted delivery of a therapeutic drug into HepG2 (hepatocellular carcinoma) cells. The shells of nanocompartments were modified by SP94 peptide which specifically binds to the GRP78 protein (Glucose-regulated protein 78 kDa), which is overexpressed in various tumor cells including HepG2 cell line. In another study there was found that TFP loaded encapsulins from Brevibacterium linens were successfully internalized by J774 mouse macrophages in vitro. The authors of this work noted that it is possible to replace TFP cargo protein with a therapeutic drug and use encapsulinbased technology for its delivery. Interestingly, in the above article, the internalization time of encapsulins into macrophages and, especially, the intracellular distribution of the fluorescent cargo signal differ significantly from what we describe.
One of the latest works also describes Thermotoga maritima, Mx and Qt encapsulins as novel platforms for simultaneous RNA and protein packaging for their future use as targeted co-delivery systems. This allows for the targeting of multiple intracellular target classes (for example mRNA and protein, at the same time) [22].
Previously [16], PAmCherry protein has already shown itself as an optical label that can be encapsulated into Mx encapsulin shells. It was shown that photoactivation of PAmCherry protein inside the encapsulins could be detected by confocal microscopyfluorescence signal was detected throughout the cytoplasm of HEK293T cells, which is in good agreement with our data. Additionally, in this study a non-integrative adenoassociated viral vector was used to deliver MxA-FLAG together with ferritin-like B M7 cargo into murine brains, allowing only transient gene expression to be achieved. Such an approach does not allow to obtain a cell line, stably expressing an encapsulin system.
In the case when a cell line is used to produce encapsulins, the use of lentiviral vectors seems to be a more appropriate technique, since it allows to obtain a stable cell line once and then using it for a long period of time. Two lentiviral vectors were used to obtain a cell line stably expressing MxEncA encapsulin genes and PAmCherry encoding genes, which makes it possible to produce Mx encapsulins containing PAmCherry label in mammalian cells without the use of any bacterial strains. In our opinion, this is an important alternative strategy for the synthesis of encapsulins since the isolation of encapsulins from bacteria may be associated with bacterial endotoxin contamination.
Confocal microscopy was performed to study the process of photoactivation of the fluorescent cargo protein in cells. After irradiation with 405 nm light followed by 561 nm excitation, the intensity of red fluorescence signal in 293T EncA_PAmCherry cells significantly increased. This observation is in agreement with the data obtained by Verkhusha and coauthors [15]. We can conclude, therefore, that encapsulation does not affect the process of PAmCherry photoactivation.
To further demonstrate the functionality of PAmCherry containing Mx encapsulins for in vitro application, we isolated Mx encapsulins containing PAmCherry label from 293T EncA_PAmCherry cells by immunoprecipitation method. It was found that EncA_PAmCherry hydrodynamic size measured by DLS method was 34 ± 4 nm (0,22 PDI), which also agrees well with the TEM analysis data.
Laser scanning confocal microscopy was used to evaluate the uptake and intracellular distribution of EncA_PAmCherry by RAW 264.7 cells (macrophage-like, Abelson leukemia virus transformed cells). This cell line is often used to study the processes of internalization of various nanoparticles, including liposomes [23], gold nanoparticles [24], micelles [25] and many others. There was found that after 15 min of incubation, EncA_PAmCherry were already efficiently internalized by macrophages: fluorescent PAmCherry signal in the red channel which became demonstrable in the RAW 264.7 cells cytoplasm. The signal was still distinguishable after 2 h of incubation and the most of the PAmCherry fluorescence was colocalized with LysoTracker Deep Red fluorescence signal. After 24 h of incubation, only minor fluorescent signal in the red channel was detected, probably due to Mx protein shells and PAmCherry label digestion by the cells. Therefore, in this study we describe the possibility of intracellular delivery of functionally active protein inside of encapsulin shells into macrophage lysosomes.
Further experiments are needed to determine the mechanism of Mx encapsulin endocytosis; however, we believe that our research opens an opportunity to use an encapsulin based system for intracellular protein delivery For example, encapsulin shells can be functionalized with specific ligands or monoclonal antibodies and the model PAmCherry cargo protein can be replaced with therapeutic protein/peptide to be applied as a targeted drug delivery system.

Construction of Lentiviral Particles and Lentiviral Transduction
pRSV-Rev (19% by mass of total DNA), pMDLg/pRRE (37% by mass of total DNA), pCMV-VSV-G (7% by mass of total DNA) lentiviral packaging plasmids were used (all from Addgene (Watertown, MA, USA)). We also used one plasmid carrying encapsulin genes pCMV MxEncA-FLAG (37% by mass of total DNA) and another plasmid carrying genes of fluorescent cargo with the Mx encapsulation signal pLCMV DD-N_PAmCherry1_MxSig (37% by mass of total DNA) also used. Plasmids and P3000 reagent were mixed in Opti-MEM medium, then lipofectamine in Opti-MEM was added to the solution (1:1). The mixture was stirred and incubated for 20 min (room temperature) and then added dropwise to 293T cells. After 24 h of incubation, the initial growth medium was replaced with DMEM supplemented with 2 mM L-glutamine and 2% FBS. The supernatant containing viral particles was collected 48 h and 72 h post-transfection, loaded onto a 20 mL syringe and filtered through a 0.45 µm syringe filter (Merck, Rahway, NJ, USA). Transduction of the cells with the lentiviral vectors was performed according to standard protocol in DMEM growth medium supplemented with 10% heat-inactivated FBS and 8 µg/mL polybrene (Sigma-Aldrich, Burlington, MA, USA). Lentiviruses were added to give a multiplicity of infection of four for each virus, 48 h after transduction, the selection was started using puromycin (Thermo Fisher Scientific, Waltham, MA, USA) at a concentration of 2.5 µg/mL.

Blue Native Gel Electrophoresis
For detection of Mx encapsulin shell proteins, NativePAGE Novex 3-12% Bis-Tris gels (Life Technologies, Carlsbad, CA, USA) were used according to the manufacturer's recommendations. Gels were loaded with whole cell lysates mixed with NativePAGE Novex sample buffer and run for 120 min at 150 V. Protein standard (Life Technologies, Carlsbad, CA, USA) covering a size range between 20 and 1200 kDa was used as a marker. Gels were then stained using Coomassie stain according to the manufacturer's protocol (Bio-Rad Laboratories, Hercules, CA, USA).

MTS Cell Proliferation Assay
For comparative assessment of the proliferation rate, 293T and 293T EncA_PAmCherry cells were seeded into 96-well plates in 100 uL of growth medium (5 × 10 4 cells/well). After 1, 3 and 5 days of culturing 20 µL of MTS solution (Promega, Madison, WI, USA) was added to 100 µL of cell culture medium into each well. Then the cells were incubated with MTS reagent for 4 h and the optical density was measured using a Multiscan GO plate reader (Thermo Scientific, Waltham, MA, USA), λ = 490 nm.

Immunoprecipitation
293T EncA_PAmCherry cells were seeded into 6-well plates in 2 mL of growth medium (1.2 × 10 6 cells/well). After 24 h cultivation FLAG-tagged encapsulins were isolated from 293T EncA_PAmCherry cells using Anti-DYKDDDDK Tag (L5) Affinity Gel (Sigma-Aldrich, Burlington, MA, USA) according to the manufacturer instructions. The cells were washed with DPBS and incubated with MPER cell lysis buffer (460 uL of buffer were added into each well) for 15 min on a shaker at 4 • C. Cell lysates were centrifugated at 10,000× g for 20 min at 4 • C, and the supernatant was incubated with pre-equilibrated gel for 1.5 h on a shaker at 4 • C. For elution, the gel was incubated with 100 µg/mL 3X FLAG Peptide (Sigma-Aldrich, Burlington, MA, USA) for 30 min at 4 • C and centrifugated at 5000× g for 1 min. The eluate was kept at 4 • C for further analysis.

Cellular Uptake of Isolated Encapsulins
RAW264.7 cells were seeded on 3.5 cm 2 µ-Dish with a polymer coverslip bottom for confocal microscopy, in the amount of 1 × 10 5 cells/dish and cultured for 24 h in standard conditions. Following cultivation, 60 µL of eluated Mx encapsulins was added to the cells. The cells were incubated at 37 • C and 5% CO 2 for 15 min, 30 min, 1 h and 2 h to allow the cells to uptake the protein shells. Additionally, LysoTracker Deep Red (Thermo Fisher Scientific, Waltham, MA, USA) dye was added to a final concentration of 20 nM. Then, the medium was removed, and the cells were rinsed twice with DPBS. The cells were imaged using a Nikon Eclipse Ti2 confocal microscope (Nikon, Tokyo, Japan).

Dynamic Light Scattering
Eluate was diluted in TBS 1:3 rate and added in a glass cuvette. Hydrodynamic size obtained encapsulins were measured by ZetaSizer Nano ZS (Malvern Panalytical, UK), Zetasizer software. Measurements were performed at 25 • C using standard rectangular glass cuvettes containing 1000 µL of protein solution.

Transmission Electron Microscopy (TEM)
A suspension of encapsulins in TBS was dropped onto the surface of a formvar-coated copper grid (300 mesh), and the solvent was subsequently evaporated. Then encapsulins were incubated with UranyLess (Electron Microscopy Sciences, Hatfield, PA, USA) for 20 s, and after that the copper grid with encapsulins was rinsed twice in DI water. TEM analysis was performed on a JEM-1400 microscope (JEOL, Tokyo, Japan).

Conclusions
In summary, in this study we describe a new genetically encoded nanocarrier system based on bacterial Mx encapsulins stably expressed in human 293T cells. The container confines PAmCherry fluorescent cargo protein label which is used in this study as a model cargo protein. The presence of EncA-FLAG and PAmCherry sequences do not alter the proliferation of 293T EncA_PAmCherry cells. Genetically encoded nanocontainers obtained in this study can be easily isolated from 293T EncA_PAmCherry cells by immunoprecipitation, avoiding the use of any bacterial strains for the production of encapsulins. Isolated encapsulins containing PAmCherry cargo are able to internalize by RAW 264.7 cells while maintaining the fluorescent signal for at least 2 h, which allows us to assert that the protein shell protects the cargo protein. In the future, nanoshell-based genetically encoded nanomaterials obtained in this study can be vectorized with specific ligands such as transferrin whose receptor is overexpressed in tumor cells. The model cargo protein can be replaced with a therapeutic protein; therefore, an encapsulin-based vehicle can be applied as a targeted delivery system for cancer therapy.