Submitted Successfully!
To reward your contribution, here is a gift for you: A free trial for our video production service.
Thank you for your contribution! You can also upload a video entry or images related to this topic.
Version Summary Created by Modification Content Size Created at Operation
1 + 4877 word(s) 4877 2021-05-25 10:31:47 |
2 format correct Meta information modification 4877 2021-06-03 09:57:05 |

Video Upload Options

Do you have a full video?

Confirm

Are you sure to Delete?
Cite
If you have any further questions, please contact Encyclopedia Editorial Office.
Foglizzo, V. Bacteriophages in Cancer. Encyclopedia. Available online: https://encyclopedia.pub/entry/10459 (accessed on 29 March 2024).
Foglizzo V. Bacteriophages in Cancer. Encyclopedia. Available at: https://encyclopedia.pub/entry/10459. Accessed March 29, 2024.
Foglizzo, Valentina. "Bacteriophages in Cancer" Encyclopedia, https://encyclopedia.pub/entry/10459 (accessed March 29, 2024).
Foglizzo, V. (2021, June 03). Bacteriophages in Cancer. In Encyclopedia. https://encyclopedia.pub/entry/10459
Foglizzo, Valentina. "Bacteriophages in Cancer." Encyclopedia. Web. 03 June, 2021.
Bacteriophages in Cancer
Edit

Bacteriophages are a class of prokaryotic viruses with different sizes and shapes (icosahedral, such as T4, T7, or λ; filamentous, such as M13), which infect the host bacterial cell initiating either a lytic or a lysogenic cycle.

biopanning drug delivery gene therapy phage display targeting

1. Introduction

Cancer is a plague worldwide, affecting around 9.6 million people annually and accounting for 1 in every 6 deaths, globally. Adopting a healthy lifestyle lowers the risk of cancer development by 30–50%. Additionally, people suffering from cancer can more reliably count on preventive screenings, early detection, and access to affordable medicines (font: https://www.who.int/health-topics/cancer (accessed on 15 January 2021)). We live in the era of personalized medicine, where therapeutic interventions are built around the individual and are based on genetic screenings as well as on novel imaging techniques. The use of radiolabeled antibodies in Her2-positive breast carcinomas, for example, improved the detection of previously unidentified lesions, while genetic information rendered staging the disease more precise and led to the development of specific therapies [1][2].

Since the concept of targeted therapeutics came in vogue, efforts were made to gain a better understanding of tumor biology and to identify tumor-specific therapeutic targets. In fact, most of these targets are also predictive biomarkers that give us information on whether a certain therapy would be beneficial to one patient but not to another [3]. Furthermore, acquiring a deep understanding of the signaling pathways in which critical targets are involved is fundamental to dig out molecular mechanisms that will likely inform us on response—or resistance—to therapy [4]. Whether a tumor would respond or not is also a matter of selective drug accumulation [5]. Therefore, there is a necessity for a more careful drug design following the principles of low toxicity, targeting capacity, and high payload at the disease site [6]. The same is true for diagnostic agents that should necessarily biodistribute rapidly, accumulate specifically, and cause no harm to the individual [1]. Therefore, more drugs are being designed on the defined features of cancerous tissue to avoid unwanted side effects. It is in fact unconceivable to solely screen new compounds for their activity on specific cellular processes, as their effectiveness is often impaired by unbearable off-target toxicities.

To fulfill the need of more precise diagnostic and therapeutic medicines, a multitude of new strategies were implemented. Among those, the advent of nanotechnology opened up new roads in precision medicine with nanocarriers or nanoparticles (NPs) made up of different materials (namely, magnetic, iron oxide, gold, mesoporous silica, polymeric NPs, carbon nanostructures, and liposomes) showing good biocompatibility, relatively low toxicity, and simple customization to reach the defined parameters, such as good circulation lifespan and solubility [6]. With formulations already approved for the treatment of metastatic breast cancer (pegylated liposomal doxorubicin Doxil®; non-pegylated liposomal doxorubicin Myocet®) and others in late stages of clinical trial for different solid tumors, liposomes obtained the greatest success, especially for their low immunogenicity and toxicity [7]. All these nanocarriers, however, lack intrinsic target specificity and accumulate at the tumor site because of its leaky vasculature and the so-called enhanced permeability and retention (EPR) effect that causes greater fluid retention than in normal tissues [8][9]. In addition, they have to bypass a number of physiological barriers, namely the endothelium, the extracellular matrix (ECM) and different stromal cells, including phagocytic immune cells, before releasing their cargo at the target site [10][11].

2. Bacteriophages: An Overview

Bacteriophages are a class of prokaryotic viruses with different sizes and shapes (icosahedral, such as T4, T7, or λ; filamentous, such as M13), which infect the host bacterial cell initiating either a lytic or a lysogenic cycle. Lytic phages (e.g., T4) replicate inside the bacterial cell and produce endolysins to destroy the cell membrane and release the viral particles. Lysogenic phages (e.g., λ and T7), instead, integrate their genes into the bacterial genome (prophage) and are transmitted to the next generations. Under conditions such as stress or cellular damage, the prophage can be reactivated, viral particles can be produced, and a lytic cycle can be initiated [12]. Filamentous phages always behave as lysogenic viruses and never kill the host cell. Their genome can either be replicated as episomal DNA or integrated into the bacterial chromosome by recombination. In the latter case, reactivation of viral replication is achieved under certain stimuli (modification of pH or temperature) that also promote reassembly of new viral particles [13][14]. In the infection process, bacteriophages and host cells establish irreversible interactions that take place between the viral capsid proteins and specific receptors on the bacterial surface. In filamentous phages, contact with the host cell is mediated by the minor capsid protein that binds the bacterial F-Pilus. Pili retract towards the bacterial cell and promote the interaction of the phage with a secondary receptor located in the periplasm. With mechanisms that are still not fully understood, the major coat protein is inserted into the inner membrane and the phage ssDNA is released inside the cell [13][14]. In tailed icosahedral bacteriophages, upon binding through the tail fibers, a conformational change is induced in the capsid baseplate, which ultimately leads to capsid contraction and injection of phage’s genetic material (ds or ssDNA/RNA) into the bacterial cytoplasm [15].

Bacteriophages were discovered in 1915 and 1917 by Frederick Twort and Felix d’Herelle, respectively, for their use against human and animal infections, but research on the theme was abandoned with the advent of common antibiotics. They are applied as food preservatives, as surface biofilm degradants, and in many other applications that are extensively reviewed elsewhere [15][16]. It was only in 1985 that bacteriophage research for human therapy started to get off the ground. With the phage display technique, in fact, bacteriophages transformed into a platform to study protein, antibody, and peptide interactions. Bacteriophages can be genetically modified so that a polypeptide is produced and exposed as fusion with one of their capsid proteins. The different capsid proteins within a single phage particle are present in numbers that might vary from a handful to several hundreds. Thus, the surface of a phage can be variably decorated with multiple copies of the polypeptide of interest and within a phage population, a multiplicity of moieties are rapidly and easily displayed to create a library [17][18]. Libraries are propagated in bacteria and phage populations can be selected either in vitro or in vivo by biopanning—an affinity procedure that makes interacting phages to be retained while non-interacting phages are washed away. Biopanning on cell cultures, for example, is a straightforward method to identify cell surface-interacting peptides and to uncover novel tumor-associated antigens for the design of targeted delivery systems [11]. In recent years, bacteriophage research entered its second youth, with phages being exploited either in cancer therapy and diagnosis as targeted nanocarriers or employed in gene therapy as vehicles for curative DNAs/RNAs. Furthermore, phages as immunogenic particles are described in vaccine research for their capability to elicit both cell-mediated and antibody-mediated (humoral) immune responses [19].

3. Discovery of Cancer Biomarkers and Targeting Moieties by Phage Display

Smith and Winter paved the way for bacteriophage engineering and received the Nobel Prize in chemistry in 2018 for their contribution in establishing phage display [20]. This technique is based on the possibility of creating fusion proteins with antibodies or peptides, by cloning the sequence of interest at the N- or C-terminus of a capsid protein. The filamentous phage M13 is the most widely and successfully exploited. In this phage, exogenous peptides are expressed as a fusion with either the major coat protein gp8 or the minor coat protein gp3. The difference relies on the number of peptides with which the capsid surface is decorated, where the gp3 is positioned at one end of the bacteriophage and is expressed in 5 copies, while the gp8 protein covers the entire length of the phage and is expressed in ~2700 copies [21]. As a result, engineered phages have the ability to recognize and bind, by affinity and avidity, receptor molecules on the surface of a cell and interfere with their function [22]. Other bacteriophages used in phage display include the icosahedral phages λ [23], MS2 [24], T4 [25], and T7 [26]. All these platforms share the same biotechnological strategy, i.e., variable copies of exogenous peptides/antibodies are displayed in different copy numbers as fusion with one or more capsid proteins (Table 1).

Table 1. Platforms for phage display.

Bacteriophage Family Genome Coat Protein Copies Ref.
M13 Inoviridae circular ssDNA gp3
gp8
5
~2700
[21]
λ Siphovirudae linear dsDNA gpD, gpE
gpV
405
192
[27]
MS2 Lseviviridae linear ssDNA CP 178 [28]
T4 Myoviridae linear dsDNA Hoc
Soc
160
960
[29]
T7 Podoviridae linear dsDNA gp10B 415 [30]

Phage display is a high-throughput technology to select protein moieties (namely, peptides, proteins, antibodies, or single-chain variable fragments (scFvs)) starting from complex libraries, with a multiplicity that can reach 106–109 individual clones. The affinity selection is carried out in vitro or in vivo, based on the interaction of the library with a target of interest—a protein, a cell, a tissue, an organ, or even a whole organism. Sequential rounds of selection and amplification, followed by recovery of specifically enriched phage clones, enable the identification of previously uncharacterized moieties and their molecular targets. In the last 30 years, several studies sought to identify cancer-specific biomarkers and cognate targeting peptides/antibodies, through the use of phage platforms for various downstream purposes. There is a vast literature on the subject, whose full discussion goes beyond the scope of the present review; here, we propose an overview of different possible approaches, to introduce the reader to the multifaceted applications of phage display in oncology.

Poul et al. [31] generated an scFv phage library to select internalizing antibodies as a prerequisite to design targeted therapeutics (e.g., immunotoxins, immunoliposomes, antibody–drug conjugates) and gene delivery systems. They built a library of 7.0 × 109 human scFvs in an M13-derived phagemid, to be selected on the breast cancer cell line SKBR3. Depletion of unspecific binders was obtained on normal cells (fibroblasts) and recovery of SKBR3-internalizing scFvs was achieved after three rounds of panning. Out of 135 clones tested, they found two scFvs (clones F5 and C1) that uniquely bound to Her2, a receptor frequently overexpressed in breast cancer. For further characterization, they showed that in between the non-Her2 binders, 10 other scFvs were able to specifically interact with the cancer cell lines of different origin (breast, SKBR3 and MCF-7, ovary, SKOV3, and prostate, LNCaP). They retrieved one clone to selectively bind transferrin (Tf) receptor—another cell surface molecule often upregulated in cancer—and to induce, upon internalization, a strong growth inhibitory effect. Similarly, Tordsson et al. [32] employed phage display to uncover novel target molecules for immunotherapy and diagnosis of colon cancer. In this case, an M13 gp3-fused library of 2.7 × 107 scFv clones was derived from antibodies induced in Cynomolgus monkeys, upon immunization with human colon carcinoma cells. The library was panned on the human colorectal cancer cell line Colo205 and the selected clones were used to stain tissue sections of normal and cancerous tissues. This procedure allowed the identification of an scFv clone (A3), specific to both primary and metastatic colorectal cancer and also to pancreatic cancer, with restricted cross-reactivity to normal epithelia.

Using a different setting, Pavoni et al. [33] implemented an immunological screening protocol called SEREX, where a λ phage library was constructed by expression of cDNA-encoded protein fragments (200–300 amino acids in length) from the breast cancer cell lines MCF-7 and MDA-MB-468. This library was panned on sera from breast carcinoma patients, where circulating antibodies against cancer antigens are expected to be present in high titers. Twenty-one clones that specifically interacted with the sera were retrieved and their sequence were determined. Eighteen different gene products were found and their expression pattern was validated by semi-quantitative RT–PCR in 10 independent breast carcinoma samples, leading to the identification of five antigens (T6-2, T6-7, T7-1, T9-21, and T9-27) associated with cancer diagnosis.

An example of phage display performed on whole tissues is the work by Larsen et al. [34]. They screened an M13-displayed synthetic single domain antibody library [35] with a diversity of 6.2 × 107 on consecutive tissue sections for binding to CD271+ cells, considered as potential cancer stem cells (namely, cells that fuel tumor growth and are often drug-resistant). Of the 315 screened, they validated one clone (LH8) through immunohistochemical staining on cryo-preserved breast cancer tissue sections. This antibody showed confined reactivity to cancer cells with variable intensities within the tissue, confirming an intratumor heterogeneity of different cell populations and indicating a possible application in the precise identification of cancer stem cells.

Other studies used recombinant proteins as targets. Mueller et al. [36] searched for peptides that could bind to collagen type IV, specifically cleaved by the matrix metalloprotease 2 (MMP-2), an event that occurs during angiogenesis—the abnormal formation of new blood vessels that feed tumor growth. They found one M13 phage clone exposing the peptide motif TLTYTWS to bind immobilized MMP-2 processed collagen IV. The TLTYTWS peptide inhibited endothelial cell differentiation in a tube formation assay in vitro, blocked angiogenesis in Matrigel plug assays in vivo, and accumulated at tumor sites in Lewis Lung carcinoma-bearing mice. A work by Zhang et al. [37] focuses on CD44, a member of the family of integral membrane glycoproteins and the receptor for hyaluronic acid. CD44 is often aberrantly expressed in cancer and it is also associated with epithelial-to-mesenchymal transition, a crucial event in cancer progression. Consequently, generating new diagnostic tools for CD44 can lead to more efficacious treatments and predict response to therapy. Based on these premises, the authors searched for novel peptide ligands of CD44v—a splice variant often deregulated in gastric cancer—starting from a commercial M13 phage library of 1 × 109 independent 7-mers. They identified CV-1, the phage clone with the highest frequency and selectivity, to specifically bind the gastric cancer cell line SGC-7901, and stain both gastric cancer tissue and metastatic lymph nodes. Recently, Zuo et al. [38] sought to inhibit neovascularization mediated by vascular endothelial growth factor (VEGF) and its receptor VEGFR2. They generated a mini-library of T4 phages expressing different fragments of the extracellular domain of VEGFR2 fused with the Soc capsid protein, showing that all these fragments interacted equally well with plate-immobilized VEGF. Adding T4-VEGFR2 phages to cultured endothelial cells, significantly impaired their proliferation and migration through inhibition of VEGFR2 phosphorylation and downstream signaling. Intravenous administration of T4-VEGFR2 phages in mouse xenografts of Lewis lung cancer and colon cancer, greatly inhibited tumor growth, micro-vessel density, and tumor vascularization, in general.

4. Bacteriophages and Their Derivatives for Drug Delivery and Targeted Imaging

Phage display-identified peptides are extensively used in tumor-targeting approaches. Peptides penetrate easily within a given cell or tissue due to their relative small size. Furthermore, they can be rapidly conjugated to any drug or carrier with a simple and cheap chemistry. Thus, peptides, within protein-based nanocarriers, represent the driving force to identify target molecules and transform new generation drugs into self-navigating formulations [39]. So far evidence shows that conjugation with tumor-homing peptides ameliorates the therapeutic index of conventional chemotherapeutics, by lowering the side effects and allowing higher drug accumulation at the disease site. Applications are multiple and were extensively reviewed elsewhere [6]. Here, we report a few examples of peculiar studies on this subject.

Shadidi and Sioud [40] employed M13-based 7- and 12-mer commercial phage libraries to screen for breast cancer-specific internalizing peptides. Internalization is a feature of some peptides that upon recognition with surface receptors penetrate within the cell via bona fide endocytosis/macropinocytosis [41], thus, shuttling a conjugated active agent into the cytoplasm. After 5–6 rounds of panning on the Her2-positive SKBR3 breast cancer cell line, the authors found two peptide motifs, LTVSPWY, and WNLPWYYSVSPT, specific for breast cancer cells, the latter was also capable of binding to glioma, prostate, colon, and lung cancer cells. Both peptides were shown to internalize and deliver fluorescein-conjugated anti-Her2 antisense oligonucleotides into SKBR3 cells. Du et al. [42] employed a 12-mer commercial M13-displayed library for in vivo biopanning of xenograft models of BEL-7402 hepatocarcinoma (HCC). In these experiments, phages were injected intravenously, followed by animal killing after a short circulation time (15 min), and recovery of specific clones from explanted tumor masses. After testing the 130 tumor-enriched phage clones, they selected the clone A54 displaying the motif AGKGTPSLETTP for further validation. Doxorubicin (Dox) conjugated to the A54 peptide exerted a strong antitumor activity in HCC tumor-bearing mice, improving the overall survival and causing no severe side effects, as compared to the unconjugated drug. A strategy to target tumor angiogenesis was developed by Fukuta et al. [43]. They employed sequential in vitro and in vivo biopanning of random pentapeptides fused with the minor coat protein gp3 of M13 filamentous phage. The library was first panned on cultured human endothelial progenitor cells (hEPCs), followed by in vivo panning of the recovered phages in the dorsal air sac (DAS) model, in which a chamber ring loaded with B16 melanoma cells is dorsally implanted in mice. Among the phages recovered from the newly formed vessels around the ring, a clone displaying the ASSHN motif was found to be the most frequent and was validated in vitro and in vivo for binding to both hEPCs and the neo-vessels, respectively. The authors showed that this peptide homes to the vessels and leaks through them into the tumor. Upon conjugation with Dox-loaded liposomes, ASSHN distributed into the tumor and drove Dox-dependent growth inhibition to a much greater extent, as compared to untargeted liposomes. An interesting evolution of these applications combines liposomes and phage-derived proteins to target Dox in a model of human breast cancer. In a series of studies by Torchilin’s group, a tumor-targeting 8-mer was first selected by panning an M13-based library displayed on the major coat protein gp8 [44]. The whole 55-amino acid fusion protein, including both gp8 and the cancer-targeting 8-mer, was purified and incorporated into the lipid bilayer of Doxil. This formulation, named MCF-7-targeted phage-Doxil, showed cytotoxic effect in vitro and induced a significant reduction in tumor growth, without affecting the body weight, when administered to MCF-7 xenograft-bearing mice [45].

Bacteriophages themselves are particles with therapeutic potential. They can be vehicles for curative nucleic acids, and decoration of their capsids with drugs and imaging dyes transforms phages into theranostic platforms. Original work by Cai et al. [46] showed that a plasmid coding for a siRNA against focal adhesion kinase (FAK) could be easily packed into M13 particles displaying epithelial growth factor (EGF) as a fusion with the gp3 protein. The deriving siRNA-carrying phages were efficiently targeted to the EGF receptor (EGFR)-overexpressing H1299 lung carcinoma cells, with consequent inhibition of cell growth and invasiveness in vitro. In another work, Huang et al. produced derivatives of HK97 phage by chemically crosslinking a labeling dye (fluorescein), a targeting moiety (Tf), or both, to the capsid protein [47]. The dual-functionalized viral nanoparticles (VNPs) incubated with Tf receptor-overexpressing tumor cells were internalized and targeted to the endolysosomes, suggesting that they might be amenable for imaging and delivery of therapeutic molecules in vivo. Similarly, M13 phages targeted to prostate cancer cells via an anti-prostate-specific membrane antigen (PSMA) antibody were successfully employed as imaging agents. In this system, the antibody was fused with the gp3 protein, while near infrared (NIR)-fluorescent single-walled carbon nanotubes (SWNTs) were assembled through a peptide ligand fused with the gp8 protein. The deriving anti PSMA-M13-SWNT, when injected in tumor-bearing mice showed targeted uptake, thus, holding great promise for in vivo fluorescence imaging [48].

New therapeutic applications in oncology include photodynamic therapy in which light and a photosensitizer react together to form reactive oxygen species that kill cancer cells. Usually, the major side effects come from accumulation of the photosensitizer in off-target tissues and its uneven spreading caused by the EPR effect. To overcome this issue, Cohen et al. [49] employed MS2 bacteriophages decorated with nucleolin-targeting DNA aptamers to deliver the photosensitizer meso-tetra-(4-N,N,N,-trimethylani-linium)-porphine (TMAP) to breast cancer cells in vitro. In this experimental setting, the photosensitizer was incorporated into the phage capsid during the assembly process, while the aptamer was chemically crosslinked to the phage surface. This study showed that an equivalent of 2–3 μM TMAP administration was able to reduce cancer cell viability by 50%. Similarly, M13 bacteriophages targeted to SKBR3 breast cancer cells via a gp8-fused peptide (of sequence VSSTQDFP) and carrying the photosensitizer pyropheophorbid-a induced specific cancer cell death, as compared to untargeted phages [50].

In another line of research, enzyme replacement therapy or VNP-mediated enzyme prodrug therapy was envisaged as a new treatment modality against cancer. Sánchez–Sánchez et al. [51] expressed CYPBM3, a variant of Cytochrome P450 from Bacillus magaterium, as a fusion with the capsid protein of bacteriophage P22. The deriving P22-CYP VNPs load a higher amount of enzyme compared to other nanocarriers and deliver it to the cells that are almost completely active. Although a functionalization of the VNPs with a targeting ligand for mammalian uptake was not made in this work, the authors comment on its feasibility as a way of delivering an enzyme that efficiently converts a prodrug in the tissue of choice.

Among the different approaches described in this paragraph, prototype applications based on the M13 bacteriophage are summarized in Figure 1.

Figure 1. M13-based applications. Examples of therapeutic and diagnostic approaches exploiting M13 phage display-derived peptides [40][42], capsid proteins [44][45], and whole phages [46][48][50] as carriers for tumor-targeted delivery of drugs (e.g., Dox, antisense oligonucleotides, photosensitizers) or imaging dyes (e.g., fluorescein, NIR-SWNTs). Figure created with BioRender.com.

5. Bacteriophages and Their Derivatives for Gene Therapy

Gene therapy requires safe and efficient delivery systems that can target a specific cell or tissue. Bacteriophage-mediated gene therapy is now possible, due to their adaptability. Transgene delivery typically employs eukaryotic viruses, as they transduce cells with high efficiency. However, their native tropism for mammalian cells severely limits their use, as it leads to unwanted side effects. Bacteriophages represent a safer option as they can be re-engineered to transduce specific eukaryotic cells or tissues.

The double cyclic RGD peptide (CDCRGDCFC, RGD4C) that targets αvβ3 integrin, a marker of cancer vasculature and tumor tissue, was successfully exploited as a targeting moiety (by the research group of Pasqualini and Arap) to build up a hybrid adeno-associated virus (AAV)/M13 phage (P) system termed AAVP. This vector carries an eukaryotic AAV cassette in the intergenomic region of the RGD4C phage, which is packaged within the viral capsid, together with phage DNA [52]. An AAVP vector engineered to include the GFP gene under the CMV promoter was shown to be efficiently internalized by cancer cells. When systemically administered to human Kaposi sarcoma xenografted mice, RGD4C-AAVP accumulated in tumor vasculature by a ligand-directed mechanism. Similarly, an AAVP modified with a luciferase reporter gene for bioluminescence imaging showed specific accumulation in tumors and no accumulation in normal organs. To potentially translate this system into the clinic, a Herpes simplex virus-1/thymidine kinase (HSVtk) expression cassette was introduced to be exploited (i) as a suicide gene upon administration of ganciclovir (GCV) and (ii) as a positron emission tomography (PET) imaging platform, in the presence of the radiolabeled nucleoside analog 20-[18F]-fluoro-20-deoxy-1-β-D-arabino-furanosyl-5-ethyluracil ([18F]FEAU). With this system, tumor response to GCV treatment was monitored across cohorts of human-cancer-cell-xenotransplanted mice showing reduction of tumor volume and destruction of tumor vasculature at histopathological analysis. In another work by the same group, a similar approach was used to treat and image nude rats bearing human sarcoma tumors with the purpose of creating a preclinical model to predict drug response, when the overall tumor-size change does not represent a good read-out of therapy outcome [53]. An implementation of these AAVPs was designed by including an alternative promoter and a different targeting moiety. Glucose-regulated protein 78 (GRP78) is an endoplasmic reticulum protein chaperone, whose expression is induced in a variety of tumors, in conditions of glucose deprivation and hypoxia. Therefore, the GRP78 promoter, besides being specifically activated in cancer cells, is expected to improve gene expression compared to the CMV promoter, also because it is not silenced in eukaryotic cells [54]. Of note, upon a single systemic administration of either AAVP-RGD4C/GRP78-HSVtk or AAVP-RGD4C/CMV-HSVtk in L9 gliosarcoma-xenotransplanted nude mice, followed by GCV treatment, tumors showed similar responses. However, repeated administration of GCV in large tumors showed efficacy only in AAVP-RGD4C/GRP78-HSVtk treated mice, further confirming transcriptional delivery of the transgene in a stress-permeated setting [54]. A number of other promoters were assessed in vitro and in vivo to optimize the delivery efficiency of suicide genes, suggesting that some of them—namely, carcinoembryonic antigen (CEA) [55][56], epithelial cell adhesion molecule (EpCAM) [57], human telomerase reverse transcriptase (hTERT) [58]—might as well be suitably included in AAVP for cancer targeting. In several cancer settings, the GRP78 protein is not only overexpressed, but is also relocated from the cytoplasm to the cell surface, becoming suitable for ligand-targeted approaches. For example, moderate to strong levels of GRP78 are seen in inflammatory breast cancer (IBC), an aggressive disease characterized by difficult-to-detect micrometastasis at presentation. AAVPs displaying the GRP78-targeting peptide motif WIFPWIQL were employed to image IBC tumors in vivo with NIR-conjugated dyes. The positive outcome of these preliminary studies was translated into a theranostic platform to deliver the HSVtk suicide gene via a GRP78-targeted AAVP carrying the GRP78 promoter. Results demonstrated improved imaging and decreased tumor size upon GCV administration, as a result of ligand-directed accumulation of the processed drug within the tumor [59]. A schematic representation of these theranostic AAVP vectors is provided in Figure 2.

Figure 2. Theranostic applications of the hybrid AAVP vector. AAPVs can be ligand-targeted to a tumor-specific cell surface molecule such as αvβ3 integrin [53] or GRP78 [59], followed by internalization of DNA and production of AAVP-coded proteins. The HSVtk transgene codes for TK, an enzyme that adds phosphate groups to thymidine analogues and converts (i) the prodrug GCV in the cytotoxic drug GCV triphosphate and (ii) [18F]FEAU in [18F]FEAU phosphate, which is retained intracellularly, allowing detection by PET imaging. Figure created with BioRender.com.

Well-known, biologically active peptides are also a source of targeting ligands that do not require a priori screening. For example, octreotide (OCT), a synthetic analog of somatostatin, was exposed on AAVP for the delivery of tumor necrosis factor (TNF) to somatostatin receptor type-2 (SSTR-2) expressing pancreatic neuroendocrine tumors. Mid- and long-term systemic injection of OCT-AAVP-TNF in transgenic mice with pancreatic insulinomas induced tumor response, as determined by the decreased insulin secretion, total choline levels, and tumor sizes [60]. Transduction in AAVP systems remains a challenge due to physiological limitations in viral delivery and processing. In particular, both the ECM and the proteasome system pose a barrier to AAVP efficacy. Hence, ECM depletion by specific enzymes (collagenase and hyaluronidase) and proteasome inhibition by peptide aldehyde inhibitors (N-benzyloxycarbonyl-L-leucyl-L-leucyl-L-leucinal (MG132) and N-acetyl-L-leucyl-L-leucyl-leucyl-L-norleucinal (LLnL)) were shown to improve both viral uptake and transgene expression [61][62].

Bacteriophage-based VNPs are, at present, the only reliable alternative to liposome-mediated noncoding RNA delivery. Their stability at physiological and supraphysiological conditions proved them to be resistant even at acidic pH and high temperatures, and encapsulation within the viral capsid protects RNA molecules from degradation. Long-noncoding RNAs (lncRNAs) are cell regulatory RNAs, typically more than 200 nucleotides in length, whose expression is often lost in cancer. LncRNA MEG3 re-expression in HCC models is the only rescue attempt that was published so far. Within this publication, the EGFR-targeting peptide YHWYGYTPQNVI (named GE11) was crosslinked to the capsid of MS2 bacteriophage-derived VNPs, in order to achieve MEG3 endocytosis. MEG3 reintroduction was shown to cause growth arrest and apoptosis via p53 stabilization in vitro and to impair tumor growth in vivo [63] (Figure 3a).

Figure 3. Bacteriophage-based platforms to deliver therapeutic and diagnostic agents via RNA technology. (a) Reintroduction of MEG3 lncRNA in cancer cells via an EGFR-targeted MS2 phage—upon binding to EGFR, the phage is internalized by endocytosis and releases MEG3, thus inducing apoptosis and inhibiting proliferation of cancer cells [63]. (b) VNPs derived from Φ29 bacteriophage pRNA are suitable nanocarriers for the delivery of RNAs (aptamer, ribozyme, siRNA), small molecules (drug, dye), or proteins (targeting moiety) to cancer cells [64][65]. Figure created with BioRender.com.

As a peculiar yet promising application in phage-derived therapeutics, RNA nanotechnology offers the possibility of manipulating the DNA packaging unit of bacteriophage Φ29, to make chimeric RNAs that form dimers via the right and left-hand loop interactions. Within the bacteriophage, packaging RNA (pRNA) dimers serve as building blocks for bottom-up assembly of pRNA hexamers that compact its DNA in the procapsid. pRNA dimers are 25 nm in size and sequence replacement of their helical domain does not alter dimer formations. Thus, redesign of monomers to carry siRNAs for gene downregulation and aptamers/ribozymes for cell targeting is possible and is shown to produce dimers that mediate gene silencing in different cell types [66]. As an example, specific dimers of pRNA-folate and pRNA-siRNA survivin or metallothionein II were shown to degrade the corresponding mRNAs in ovarian cancer cells much more efficiently than siRNAs alone [67]. Furthermore, changing these assemblies to build modules of up to 12 monomers with different geometries was demonstrated to lead to stable RNA nanoparticles that can also be systemically administered [64]. Recently it was also shown that the 3-way core junction of Φ29 pRNA could be functionalized to carry two siRNAs and a targeting RNA aptamer. Specifically, Her2+ breast cancer cells were targeted with an RNA nanoparticle carrying two siRNAs for MED1 (a well-known transcriptional co-activator of Her2) and an RNA aptamer targeting Her2. pRNA-Her2apt-siMED1 effectively silenced MED1 in breast cancer cells, blocked tumor growth, and completely eradicated lung metastases [65] (Figure 3b). These results clearly point towards future application of these RNA-based nanoparticles in the clinic.

References

  1. Lammers, T.; Rizzo, L.Y.; Storm, G.; Kiessling, F. Personalized nanomedicine. Clin. Cancer Res. 2012, 18, 4889–4894.
  2. Perik, P.J.; Lub-De Hooge, M.N.; Gietema, J.A.; van der Graaf, W.T.; de Korte, M.A.; Jonkman, S.; Kosterink, J.G.; van Veldhuisen, D.J.; Sleijfer, D.T.; Jager, P.L.; et al. Indium-111-labeled trastuzumab scintigraphy in patients with human epidermal growth factor receptor 2-positive metastatic breast cancer. J. Clin. Oncol. 2006, 24, 2276–2282.
  3. Amin, S.; Bathe, O.F. Response biomarkers: Re-envisioning the approach to tailoring drug therapy for cancer. BMC Cancer 2016, 16, 850.
  4. Hait, W.N.; Hambley, T.W. Targeted cancer therapeutics. Cancer Res. 2009, 69, 1263–1267.
  5. Ju, Z.; Sun, W. Drug delivery vectors based on filamentous bacteriophages and phage-mimetic nanoparticles. Drug Deliv. 2017, 24, 1898–1908.
  6. Yao, V.J.; D’Angelo, S.; Butler, K.S.; Theron, C.; Smith, T.L.; Marchio, S.; Gelovani, J.G.; Sidman, R.L.; Dobroff, A.S.; Brinker, C.J.; et al. Ligand-targeted theranostic nanomedicines against cancer. J. Control Release 2016, 240, 267–286.
  7. Awasthi, R.; Roseblade, A.; Hansbro, P.M.; Rathbone, M.J.; Dua, K.; Bebawy, M. Nanoparticles in cancer treatment: Opportunities and obstacles. Curr. Drug Targets 2018, 19, 1696–1709.
  8. Maeda, H.; Wu, J.; Sawa, T.; Matsumura, Y.; Hori, K. Tumor vascular permeability and the EPR effect in macromolecular therapeutics: A review. J. Control Release 2000, 65, 271–284.
  9. Thomas, O.S.; Weber, W. Overcoming physiological barriers to nanoparticle delivery-are we there yet? Front. Bioeng. Biotechnol. 2019, 7, 415.
  10. Boraschi, D.; Italiani, P.; Palomba, R.; Decuzzi, P.; Duschl, A.; Fadeel, B.; Moghimi, S.M. Nanoparticles and innate immunity: New perspectives on host defence. Semin. Immunol. 2017, 34, 33–51.
  11. Durymanov, M.O.; Rosenkranz, A.A.; Sobolev, A.S. Current approaches for improving intratumoral accumulation and distribution of nanomedicines. Theranostics 2015, 5, 1007–1020.
  12. Karimi, M.; Mirshekari, H.; Moosavi Basri, S.M.; Bahrami, S.; Moghoofei, M.; Hamblin, M.R. Bacteriophages and phage-inspired nanocarriers for targeted delivery of therapeutic cargos. Adv. Drug Deliv. Rev. 2016, 106, 45–62.
  13. Loh, B.; Kuhn, A.; Leptihn, S. The fascinating biology behind phage display: Filamentous phage assembly. Mol. Microbiol. 2019, 111, 1132–1138.
  14. Rakonjac, J.; Bennett, N.J.; Spagnuolo, J.; Gagic, D.; Russel, M. Filamentous bacteriophage: Biology, phage display and nanotechnology applications. Curr. Issues Mol. Biol. 2011, 13, 51–76.
  15. Harada, L.K.; Silva, E.C.; Campos, W.F.; Del Fiol, F.S.; Vila, M.; Dabrowska, K.; Krylov, V.N.; Balcao, V.M. Biotechnological applications of bacteriophages: State of the art. Microbiol. Res. 2018, 212, 38–58.
  16. Adhya, S.; Merril, C.R.; Biswas, B. Therapeutic and prophylactic applications of bacteriophage components in modern medicine. Cold Spring Harb. Perspect. Med. 2014, 4, a012518.
  17. Gamkrelidze, M.; Dabrowska, K. T4 bacteriophage as a phage display platform. Arch. Microbiol. 2014, 196, 473–479.
  18. Lindner, T.; Kolmar, H.; Haberkorn, U.; Mier, W. DNA libraries for the construction of phage libraries: Statistical and structural requirements and synthetic methods. Molecules 2011, 16, 1625–1641.
  19. Yacoby, I.; Benhar, I. Targeted filamentous bacteriophages as therapeutic agents. Expert. Opin. Drug Deliv. 2008, 5, 321–329.
  20. Mimmi, S.; Maisano, D.; Quinto, I.; Iaccino, E. Phage Display: An Overview in Context to Drug Discovery. Trends Pharmacol. Sci. 2019, 40, 87–91.
  21. Saw, P.E.; Song, E.W. Phage display screening of therapeutic peptide for cancer targeting and therapy. Protein Cell 2019, 10, 787–807.
  22. Fagbohun, O.A.; Kazmierczak, R.A.; Petrenko, V.A.; Eisenstark, A. Metastatic prostate cancer cell-specific phage-like particles as a targeted gene-delivery system. J. Nanobiotechnol. 2013, 11, 31.
  23. Davies, J.; Riechmann, L. Antibody VH domains as small recognition units. Biotechnology 1995, 13, 475–479.
  24. Peabody, D.S. Subunit fusion confers tolerance to peptide insertions in a virus coat protein. Arch. Biochem. Biophys. 1997, 347, 85–92.
  25. Ren, Z.; Black, L.W. Phage T4 SOC and HOC display of biologically active, full-length proteins on the viral capsid. Gene 1998, 215, 439–444.
  26. Houshmand, H.; Froman, G.; Magnusson, G. Use of bacteriophage T7 displayed peptides for determination of monoclonal antibody specificity and biosensor analysis of the binding reaction. Anal. Biochem. 1999, 268, 363–370.
  27. Casjens, S.R.; Hendrix, R.W. Locations and amounts of major structural proteins in bacteriophage lambda. J. Mol. Biol. 1974, 88, 535–545.
  28. Koning, R.I.; Gomez-Blanco, J.; Akopjana, I.; Vargas, J.; Kazaks, A.; Tars, K.; Carazo, J.M.; Koster, A.J. Asymmetric cryo-EM reconstruction of phage MS2 reveals genome structure in situ. Nat. Commun. 2016, 7, 12524.
  29. Jiang, J.; Abu-Shilbayeh, L.; Rao, V.B. Display of a PorA peptide from Neisseria meningitidis on the bacteriophage T4 capsid surface. Infect. Immun. 1997, 65, 4770–4777.
  30. Ionel, A.; Velazquez-Muriel, J.A.; Luque, D.; Cuervo, A.; Caston, J.R.; Valpuesta, J.M.; Martin-Benito, J.; Carrascosa, J.L. Molecular rearrangements involved in the capsid shell maturation of bacteriophage T7. J. Biol. Chem. 2011, 286, 234–242.
  31. Poul, M.A.; Becerril, B.; Nielsen, U.B.; Morisson, P.; Marks, J.D. Selection of tumor-specific internalizing human antibodies from phage libraries. J. Mol. Biol. 2000, 301, 1149–1161.
  32. Tordsson, J.; Lavasani, S.; Ohlsson, L.; Karlstrom, P.; Svedberg, H.; Abrahmsen, L.; Brodin, T. A3—A novel colon and pancreatic cancer reactive antibody from a primate phage library selected using intact tumour cells. Int. J. Cancer 2000, 87, 559–568.
  33. Pavoni, E.; Vaccaro, P.; Pucci, A.; Monteriu, G.; Beghetto, E.; Barca, S.; Dupuis, M.L.; De Pasquale Ceratti, A.; Lugini, A.; Cianfriglia, M.; et al. Identification of a panel of tumor-associated antigens from breast carcinoma cell lines, solid tumors and testis cDNA libraries displayed on lambda phage. BMC Cancer 2004, 4, 78.
  34. Larsen, S.A.; Meldgaard, T.; Fridriksdottir, A.J.; Lykkemark, S.; Poulsen, P.C.; Overgaard, L.F.; Petersen, H.B.; Petersen, O.W.; Kristensen, P. Raising an antibody specific to breast cancer subpopulations using phage display on tissue sections. Cancer Genom. Proteom. 2016, 13, 21–30.
  35. Mandrup, O.A.; Friis, N.A.; Lykkemark, S.; Just, J.; Kristensen, P. A novel heavy domain antibody library with functionally optimized complementarity determining regions. PLoS ONE 2013, 8, e76834.
  36. Mueller, J.; Gaertner, F.C.; Blechert, B.; Janssen, K.P.; Essler, M. Targeting of tumor blood vessels: A phage-displayed tumor-homing peptide specifically binds to matrix metalloproteinase-2-processed collagen IV and blocks angiogenesis in vivo. Mol. Cancer Res. 2009, 7, 1078–1085.
  37. Zhang, D.; Jia, H.; Li, W.; Hou, Y.; Lu, S.; He, S. Screening and identification of a phage display derived peptide that specifically binds to the CD44 protein region encoded by variable exons. J. Biomol. Screen. 2016, 21, 44–53.
  38. Zuo, S.; Dai, G.; Wang, L.; Wen, Y.; Huang, Z.; Yang, W.; Ma, W.; Ren, X. Suppression of angiogenesis and tumor growth by recombinant T4 phages displaying extracellular domain of vascular endothelial growth factor receptor 2. Arch. Virol. 2019, 164, 69–82.
  39. Ghosh, D.; Peng, X.; Leal, J.; Mohanty, R. Peptides as drug delivery vehicles across biological barriers. J. Pharm. Investig. 2018, 48, 89–111.
  40. Shadidi, M.; Sioud, M. Identification of novel carrier peptides for the specific delivery of therapeutics into cancer cells. FASEB J. 2003, 17, 256–258.
  41. Bolhassani, A. Potential efficacy of cell-penetrating peptides for nucleic acid and drug delivery in cancer. Biochim. Biophys. Acta 2011, 1816, 232–246.
  42. Du, B.; Han, H.; Wang, Z.; Kuang, L.; Wang, L.; Yu, L.; Wu, M.; Zhou, Z.; Qian, M. Targeted drug delivery to hepatocarcinoma in vivo by phage-displayed specific binding peptide. Mol. Cancer Res. 2010, 8, 135–144.
  43. Fukuta, T.; Asai, T.; Kiyokawa, Y.; Nakada, T.; Bessyo-Hirashima, K.; Fukaya, N.; Hyodo, K.; Takase, K.; Kikuchi, H.; Oku, N. Targeted delivery of anticancer drugs to tumor vessels by use of liposomes modified with a peptide identified by phage biopanning with human endothelial progenitor cells. Int. J. Pharm. 2017, 524, 364–372.
  44. Wang, T.; D’Souza, G.G.; Bedi, D.; Fagbohun, O.A.; Potturi, L.P.; Papahadjopoulos-Sternberg, B.; Petrenko, V.A.; Torchilin, V.P. Enhanced binding and killing of target tumor cells by drug-loaded liposomes modified with tumor-specific phage fusion coat protein. Nanomedicine 2010, 5, 563–574.
  45. Wang, T.; Hartner, W.C.; Gillespie, J.W.; Praveen, K.P.; Yang, S.; Mei, L.A.; Petrenko, V.A.; Torchilin, V.P. Enhanced tumor delivery and antitumor activity in vivo of liposomal doxorubicin modified with MCF-7-specific phage fusion protein. Nanomedicine 2014, 10, 421–430.
  46. Cai, X.M.; Xie, H.L.; Liu, M.Z.; Zha, X.L. Inhibition of cell growth and invasion by epidermal growth factor-targeted phagemid particles carrying siRNA against focal adhesion kinase in the presence of hydroxycamptothecin. BMC Biotechnol. 2008, 8, 74.
  47. Huang, R.K.; Steinmetz, N.F.; Fu, C.Y.; Manchester, M.; Johnson, J.E. Transferrin-mediated targeting of bacteriophage HK97 nanoparticles into tumor cells. Nanomedicine 2011, 6, 55–68.
  48. Yi, H.; Ghosh, D.; Ham, M.H.; Qi, J.; Barone, P.W.; Strano, M.S.; Belcher, A.M. M13 phage-functionalized single-walled carbon nanotubes as nanoprobes for second near-infrared window fluorescence imaging of targeted tumors. Nano Lett. 2012, 12, 1176–1183.
  49. Cohen, B.A.; Bergkvist, M. Targeted in vitro photodynamic therapy via aptamer-labeled, porphyrin-loaded virus capsids. J. Photochem. Photobiol. B 2013, 121, 67–74.
  50. Gandra, N.; Abbineni, G.; Qu, X.; Huai, Y.; Wang, L.; Mao, C. Bacteriophage bionanowire as a carrier for both cancer-targeting peptides and photosensitizers and its use in selective cancer cell killing by photodynamic therapy. Small 2013, 9, 215–221.
  51. Sánchez-Sánchez, L.; Tapia-Moreno, A.; Juarez-Moreno, K.; Patterson, D.P.; Cadena-Nava, R.D.; Douglas, T.; Vazquez-Duhalt, R. Design of a VLP-nanovehicle for CYP450 enzymatic activity delivery. J. Nanobiotechnol. 2015, 13, 66.
  52. Hajitou, A.; Trepel, M.; Lilley, C.E.; Soghomonyan, S.; Alauddin, M.M.; Marini, F.C., III; Restel, B.H.; Ozawa, M.G.; Moya, C.A.; Rangel, R.; et al. A hybrid vector for ligand-directed tumor targeting and molecular imaging. Cell 2006, 125, 385–398.
  53. Hajitou, A.; Lev, D.C.; Hannay, J.A.; Korchin, B.; Staquicini, F.I.; Soghomonyan, S.; Alauddin, M.M.; Benjamin, R.S.; Pollock, R.E.; Gelovani, J.G.; et al. A preclinical model for predicting drug response in soft-tissue sarcoma with targeted AAVP molecular imaging. Proc. Natl. Acad. Sci. USA 2008, 105, 4471–4476.
  54. Kia, A.; Przystal, J.M.; Nianiaris, N.; Mazarakis, N.D.; Mintz, P.J.; Hajitou, A. Dual systemic tumor targeting with ligand-directed phage and Grp78 promoter induces tumor regression. Mol. Cancer Ther. 2012, 11, 2566–2577.
  55. Qiu, Y.; Peng, G.L.; Liu, Q.C.; Li, F.L.; Zou, X.S.; He, J.X. Selective killing of lung cancer cells using carcinoembryonic antigen promoter and double suicide genes, thymidine kinase and cytosine deaminase (pCEA-TK/CD). Cancer Lett. 2012, 316, 31–38.
  56. Rama, A.R.; Hernandez, R.; Perazzoli, G.; Burgos, M.; Melguizo, C.; Velez, C.; Prados, J. Specific colon cancer cell cytotoxicity induced by bacteriophage E gene expression under transcriptional control of carcinoembryonic antigen promoter. Int. J. Mol. Sci. 2015, 16, 12601–12615.
  57. Danda, R.; Krishnan, G.; Ganapathy, K.; Krishnan, U.M.; Vikas, K.; Elchuri, S.; Chatterjee, N.; Krishnakumar, S. Targeted expression of suicide gene by tissue-specific promoter and microRNA regulation for cancer gene therapy. PLoS ONE 2013, 8, e83398.
  58. Higashi, K.; Hazama, S.; Araki, A.; Yoshimura, K.; Iizuka, N.; Yoshino, S.; Noma, T.; Oka, M. A novel cancer vaccine strategy with combined IL-18 and HSV-TK gene therapy driven by the hTERT promoter in a murine colorectal cancer model. Int. J. Oncol. 2014, 45, 1412–1420.
  59. Dobroff, A.S.; D’Angelo, S.; Eckhardt, B.L.; Ferrara, F.; Staquicini, D.I.; Cardo-Vila, M.; Staquicini, F.I.; Nunes, D.N.; Kim, K.; Driessen, W.H.P.; et al. Towards a transcriptome-based theranostic platform for unfavorable breast cancer phenotypes. Proc. Natl. Acad. Sci. USA 2016, 113, 12780–12785.
  60. Smith, T.L.; Yuan, Z.; Cardo-Vila, M.; Sanchez Claros, C.; Adem, A.; Cui, M.H.; Branch, C.A.; Gelovani, J.G.; Libutti, S.K.; Sidman, R.L.; et al. AAVP displaying octreotide for ligand-directed therapeutic transgene delivery in neuroendocrine tumors of the pancreas. Proc. Natl. Acad. Sci. USA 2016, 113, 2466–2471.
  61. Przystal, J.M.; Umukoro, E.; Stoneham, C.A.; Yata, T.; O’Neill, K.; Syed, N.; Hajitou, A. Proteasome inhibition in cancer is associated with enhanced tumor targeting by the adeno-associated virus/phage. Mol. Oncol. 2013, 7, 55–66.
  62. Yata, T.; Lee, E.L.; Suwan, K.; Syed, N.; Asavarut, P.; Hajitou, A. Modulation of extracellular matrix in cancer is associated with enhanced tumor cell targeting by bacteriophage vectors. Mol. Cancer 2015, 14, 110.
  63. Chang, L.; Wang, G.; Jia, T.; Zhang, L.; Li, Y.; Han, Y.; Zhang, K.; Lin, G.; Zhang, R.; Li, J.; et al. Armored long non-coding RNA MEG3 targeting EGFR based on recombinant MS2 bacteriophage virus-like particles against hepatocellular carcinoma. Oncotarget 2016, 7, 23988–24004.
  64. Shu, Y.; Haque, F.; Shu, D.; Li, W.; Zhu, Z.; Kotb, M.; Lyubchenko, Y.; Guo, P. Fabrication of 14 different RNA nanoparticles for specific tumor targeting without accumulation in normal organs. RNA 2013, 19, 767–777.
  65. Zhang, Y.; Leonard, M.; Shu, Y.; Yang, Y.; Shu, D.; Guo, P.; Zhang, X. Overcoming tamoxifen resistance of human breast cancer by targeted gene silencing using multifunctional pRNA nanoparticles. ACS Nano 2017, 11, 335–346.
  66. Guo, S.; Tschammer, N.; Mohammed, S.; Guo, P. Specific delivery of therapeutic RNAs to cancer cells via the dimerization mechanism of phi29 motor pRNA. Hum. Gene Ther. 2005, 16, 1097–1109.
  67. Tarapore, P.; Shu, Y.; Guo, P.; Ho, S.M. Application of phi29 motor pRNA for targeted therapeutic delivery of siRNA silencing metallothionein-IIA and survivin in ovarian cancers. Mol. Ther. 2011, 19, 386–394.
More
Information
Subjects: Pathology
Contributor MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register :
View Times: 806
Revisions: 2 times (View History)
Update Date: 03 Jun 2021
1000/1000