Paclitaxel/IR1061-Co-Loaded Protein Nanoparticle for Tumor-Targeted and pH/NIR-II-Triggered Synergistic Photothermal-Chemotherapy.

PURPOSE: The aim of this study was to develop an "all-in-one" nanoplatform that integrates at the second near-infrared (NIR-II) region dye IR1061 and anticancer drug paclitaxel (PTX) into an apoferritin (AFN) nanocage (IR-AFN@PTX). Simultaneously, folic acid (FA), tumor target molecule,  was conjugated onto IR-AFN@PTX to be IR-AFN@PTX-FA for tumor-targeted and pH/NIR-II-triggered synergistic photothermal-chemotherapy. METHODS: IR1061 was firstly reacted with PEG and then conjugated with AFN to be IR-AFN. Then, FA was conjugated onto the surface of IR-AFN to be IR-AFN-FA. At last, PTX was incorporated into IR-AFN-FA to fabricate a nanoplatform IR-AFN@PTX-FA. The NIR-II photothermal properties and pH/NIR-II triggered drug release were evaluated. The ability of IR-AFN@PTX-FA to target tumors was estimated using optical bioluminescence. In vitro and in vivo synergistic therapeutic effects of pH/NIR-II-triggered and tumor-targeted photothermal-chemotherapy were investigated in 4T1 tumor model. RESULTS: IR-AFN@PTX-FA showed excellent water solubility and physiological stability, which significantly enhanced the solubility of both IR1061 and PTX. After 5 min of laser irradiation at 1064 nm, IR-AFN@PTX-FA exhibited an effective photothermal effect compared with laser irradiation at 808 nm, even when blocked with 0.6 cm thick chicken breast. Cellular uptake experiments showed IR-AFN@PTX-FA utilized clathrin-mediated and caveolae-mediated endocytosis pathways to enter 4T1 cells, and was then delivered by the endosome to the lysosome. NIR-II laser irradiation and pH could synergistically trigger PTX release, inducing significant tumor inhibition in vitro and in vivo. CONCLUSION: As a novel "all-in-one" nanoplatform, IR-AFN@PTX-FA was found to selectively target tumors and showed very efficient NIR-II photothermal effects and pH/NIR-II triggered drug release effects, showing a remarkable, synergistic photothermal-chemotherapy effect.

Mild Acid-Responsive "Nanoenzyme Capsule" Remodeling of the Tumor Microenvironment to Increase Tumor Penetration.

Dense extracellular matrix (ECM) severely impedes the spread of drugs in solid tumors and induces hypoxia, reducing chemotherapy efficiency. Different proteolytic enzymes, such as collagenase (Col) or bromelain, can directly attach to the surface of nanoparticles and improve their diffusion, but the method of ligation may also impair the enzymatic activity due to conformational changes or blockage of the active site. Herein, a "nanoenzyme capsule" was constructed by combining collagenase nanocapsules (Col-nc) with heavy-chain ferritin (HFn) nanocages encapsulating the chemotherapy drug doxorubicin (DOX) to enhance tumor penetration of the nanoparticles by hydrolyzing collagen from the ECM. Col-nc could protect the activity of the enzyme before reaching the site of action while being degraded under mildly acidic conditions in tumors, and the released proteolytic enzyme could digest collagen. In addition, HFn as a carrier could effectively load DOX and had a self-targeting ability, enabling the nanoparticles to internalize into cancer cells more effectively. From in vivo and in vitro studies, we found that collagen was effectively degraded by Col-nc/HFn(DOX) to increase the accumulation and penetration of nanoparticles in the solid tumor site and could alleviate hypoxia inside the tumor to enhance the antitumor effects of DOX. Therefore, the strategy of increasing nanoparticle penetration in this system is expected to provide a potential approach for the clinical treatment of solid tumors.

Chitosan binding onto the epigallocatechin-loaded ferritin nanocage enhances its transport across Caco-2 cells.

The effect of chitosan decoration on the transport of epigallocatechin (EGC)-encapsulated ferritin cage across the Caco-2 cells was investigated. After the encapsulation of EGC in apo-red bean (adzuki) ferritin (apoRBF), the EGC-loaded apoRBF nanoparticle (ER) was fabricated with an encapsulation ratio of 11.6% (w/w). The results indicated that different chitosan molecules (with molecular weights of 980, 4600, 46 000, and 210 000 Da) could attach onto the apoRBF via electrostatic interactions to form ER-chitosan complexes (ERCs) (ERCs980, ERCs4600, ERCs46000, and ERCs210000). ERCs980 and ERCs4600 retained the typical shell-like morphology of ferritin with a size distribution of 12 nm and showed weak negative zeta-potentials at pH 6.7, while ERCs46000 and ERCs210000 significantly aggregated. Furthermore, the transport of EGC in ERCs980 and ERCs4600 across the Caco-2 cells was enhanced by the transferrin receptor 1 (TfR-1)-mediated absorption pathway, demonstrating that chitosan molecules with low molecular weights of 980 and 4600 Da were beneficial to the absorption of EGC based on the ferritin cage. This study will facilitate the application of ferritin-chitosan materials for fabricating the core-shell platform for encapsulation and bioavailability enhancement of bioactive molecules.

A Hollow NaGdF4 /AFn Nanosystem Based on "Relay Race" Release for Therapy.

To develop a multifunctional nanomaterial for dual-mode imaging and synergetic chemotherapy, curcumin (CUR) was physically entrapped into hollow upconversion NaGdF4 nanomaterial, then apoferritin (AFn) loaded with doxorubicin (DOX) was attached to the NaGdF4 surface. Subsequent modification with the targeting reagent folic acid (FA) led to generation of the CUR/NaGdF4 -DOX/AFn-FA conjugate for cancer treatment. X-ray diffraction, scanning (SEM) and transmission electron microscopy (TEM), and Fourier transform infrared (FTIR) spectroscopy demonstrated the successful preparation of hexagonal-phase NaGdF4 and NaGdF4 -AFn-FA. Moreover, no toxicity was observed for NaGdF4 -AFn-FA. In vitro and in vivo experiments demonstrated that the two drugs are sequentially released from the nanocomposites. This two-drug system showed strong growth inhibitory effects on MCF-7 cells. Upconversion luminescence imaging and magnetic resonance (MR) imaging of NaGdF4 -AFn-FA were carried out. The results of this study show that NaGdF4 -AFn-FA can be used for targeted anticancer drug delivery as well as imaging, a novel multi-pronged theranostic system for tumor treatment.

Comparative analysis of two ferritin subunits from blunt snout bream (Megalobrama amblycephala): Characterization, expression, iron depriving and bacteriostatic activity.

Iron is an essential microelement for almost all living organisms, while an excess of iron is toxic, thus maintenance of iron homeostasis is vital. As iron storage protein, ferritin plays an important role in iron metabolism. In the present study, we cloned and characterized the ferritin H subunit from Megalobrama amblycephala, termed as MamFerH. An iron-responsive element (IRE) was predicted in the 5' untranslated region (UTR) of MamFerH, while its bulge structural was different from that of the reported ferritin M subunit (MamFerM). The MamFerH and MamFerM genes exhibited similar expression patterns during early development with specifically high expression post hatching, whereas their tissue expression patterns were different. Specifically, MamFerM was highly expressed in the spleen, liver and kidney, while MamFerH was predominantly expressed in the blood and brain, indicating their different functions. In addition, the expression of the two genes was induced upon Aeromonas hydrophila infection at both transcriptional and translational levels, and MamFerH was more efficient. Immunohistochemistry and immunofluorescence analysis confirmed their significant changes at protein level and distribution in the liver post infection, indicating their participation in host immune response. Furthermore, bacteriostatic experiment revealed that recombinant MamFerH displayed more significant inhibitory effect on the growth of A. hydrophila.

Protein Nanocage Mediated Fibroblast-Activation Protein Targeted Photoimmunotherapy To Enhance Cytotoxic T Cell Infiltration and Tumor Control.

Carcinoma-associated fibroblasts (CAFs) are found in many types of cancer and play an important role in tumor growth and metastasis. Fibroblast-activation protein (FAP), which is overexpressed on the surface of CAFs, has been proposed as a universal tumor targeting antigen. However, recent studies show that FAP is also expressed on multipotent bone marrow stem cells. A systematic anti-FAP therapy may lead to severe side effects and even death. Hence, there is an urgent need of a therapy that can selectively kill CAFs without causing systemic toxicity. Herein we report a nanoparticle-based photoimmunotherapy (nano-PIT) approach that addresses the need. Specifically, we exploit ferritin, a compact nanoparticle protein cage, as a photosensitizer carrier, and we conjugate to the surface of ferritin a FAP-specific single chain variable fragment (scFv). With photoirradiation, the enabled nano-PIT efficiently eliminates CAFs in tumors but causes little damage to healthy tissues due to the localized nature of the treatment. Interestingly, while not directly killing cancer cells, the nano-PIT caused efficient tumor suppression in tumor-bearing immunocompetent mice. Further investigations found that the nano-PIT led to suppressed C-X-C motif chemokine ligand 12 (CXCL12) secretion and extracellular matrix (ECM) deposition, both of which are regulated by CAFs in untreated tumors and mediate T cell exclusion that prevents physical contact between T cells and cancer cells. By selective killing of CAFs, the nano-PIT reversed the effect, leading to significantly enhanced T cell infiltration, followed by efficient tumor suppression. Our study suggests a new and safe CAF-targeted therapy and a novel strategy to modulate tumor microenvironment (TME) for enhanced immunity against cancer.

Bioengineered Magnetoferritin Nanoprobes for Single-Dose Nuclear-Magnetic Resonance Tumor Imaging.

Despite all the advances in multimodal imaging, it remains a significant challenge to acquire both magnetic resonance and nuclear imaging in a single dose because of the enormous difference in sensitivity. Indeed, nuclear imaging is almost 10(6)-fold more sensitive than magnetic resonance imaging (MRI); thus, repeated injections are generally required to obtain sufficient MR signals after nuclear imaging. Here, we show that strategically engineered magnetoferritin nanoprobes can image tumors with high sensitivity and specificity using SPECT and MRI in living mice after a single intravenous injection. The magnetoferritin nanoprobes composed of (125)I radionuclide-conjugated human H-ferritin iron nanocages ((125)I-M-HFn) internalize robustly into cancer cells via a novel tumor-specific HFn-TfR1 pathway. In particular, the endocytic recycling characteristic of TfR1 transporters solves the nuclear signal blocking issue caused by the high dose nanoprobes injected for MRI, thus enabling simultaneous functional and morphological tumor imaging without reliance on multi-injections.

Targeting ferritin receptors for the selective delivery of imaging and therapeutic agents to breast cancer cells.

In this work the selective uptake of native horse spleen ferritin and apoferritin loaded with MRI contrast agents has been assessed in human breast cancer cells (MCF-7 and MDA-MB-231). The higher expression of L-ferritin receptors (SCARA5) led to an enhanced uptake in MCF-7 as shown in T2 and T1 weighted MR images, respectively. The high efficiency of ferritin internalization in MCF-7 has been exploited for the simultaneous delivery of curcumin, a natural therapeutic molecule endowed with antineoplastic and anti-inflammatory action, and the MRI contrast agent Gd-HPDO3A. This theranostic system is able to treat selectively breast cancer cells over-expressing ferritin receptors. By entrapping in apoferritin both Gd-HPDO3A and curcumin, it was possible to deliver a therapeutic dose of 167 µg ml(-1) (as calculated by MRI) of this natural drug to MCF-7 cells, thus obtaining a significant reduction of cell proliferation.

Semi-artificial and bioactive ferroxidase with nanoparticles as the active sites.

Light-chain apoferritin lacks ferroxidase activity, which can be supplemented with Pt-nanoparticles. The hybrid bioinorganic nanoparticle outperforms its heavy-chain pendant in terms of ferroxidase activity, mineralization ability and inhibition resistance. Being active in a cellular environment it regulates the iron homeostasis.

The interaction of DNA with phytoferritin during iron oxidation.

Phytoferritin from legume seeds is considered an iron supplement with great potential. Phytoferritin co-exists with plastid DNA in amyloplasts of legume seed cells where Fe(2+) is oxidized into Fe(3+), followed by storage within the inner cavity of the protein. In this study, the interaction of plasmid DNA with black bean (Phaseolus vulgaris L.) seed ferritin (BSF) during iron oxidation was studied. Results indicated that iron ions facilitated formation of apoBSF aggregates at a high iron loading (>48 Fe(2+)/shell). Interestingly, the co-existence of DNA and ferritin has a pronounced effect on iron uptake by ferritin. This view is confirmed by a pronounced increase in the rate of iron oxidation catalysed by apoBSF in the presence of DNA. On the other hand, the apoBSF exhibited a marked DNA-protective function against oxidative damage at a low loading of Fe(2+) (⩽ 48 Fe(2+)/shell). However, outside this ratio, such an effect gradually decreased, because the added iron exceeded the iron binding capacity of ferritin. The current study advances the understanding of the interaction among multi-components in foodstuffs.

Iron bioavailability in larvae yellow snapper (Lutjanus argentiventris): cloning and expression analysis of ferritin-H.

Ferritin is a major intracellular iron storage protein in higher vertebrates and plays an important role in iron metabolism. In this study, ferritin H subunit was cloned from the larvae of yellow snapper, Lutjanus argentiventris, by rapid amplification of cDNA ends (RACE) following in silico transcriptome analysis. The full-length cDNAs of the LaFeH was 1231 bp in length encoding 177 amino acids with a predicted molecular mass (MW) about 20.82 kDa and theoretical isoelectric point (pI) of 5.79. Amino acid alignment revealed that LaFeH shared high similarity with other known ferritins. It shared high degree identity to the ferritin H subunits of Lates calcarifer (99%), Takifugu rubripes (97%) and Dicentrarchus labrax (97%), and low identity to that of human (82%) and mouse (84%). By real-time PCR assays, the mRNA transcripts of LaFeH was found to be higher expressed in head-kidney, eye, heart and brain. Moreover, mRNA expression levels of LaFeH was measured by real-time PCR in larvae exposed with graded levels of iron (6.8 µg/ml and 13.6 µg/ml (Fe2x and Fe4x, respectively) and an iron chelation assay. Results showed that the expression of the LaFeH mRNA increased gradually with Fe2x in water. The LaFeH gene expression declined with increasing iron exposure levels at Fe4x. Finally, we can observe a high expression of LaFeH gene in larvae exposed to iron chelation therapy at 2 h; however this increase was gradually decreasing over time. In summary, the LaFeH gene expression for larvae yellow snapper showed a dose-depend increase following the iron treatment. These data indicated that iron bioavailability regulates LaFeH at transcriptional level in larvae yellow snapper. Further studies are necessary to ascertain their role in the immune response in teleost fish.

Electrochemical detection of individual single nucleotide polymorphisms using monobase-modified apoferritin-encapsulated nanoparticles.

An electrochemical approach for detection of individual single nucleotide polymorphisms (SNPs) based on nucleobase-conjugated apoferritin probe loaded with metal phosphate nanoparticles is reported. Coupling of the nucleotide-modified nanoparticle probe to the mutant sites of duplex DNA was induced by DNA polymerase I (Klenow fragment) to preserve Watson-Crick base-pairing rules. After sequential liquid hybridization of biotinylated DNA probes with mutant DNA and complementary DNA, the resulting duplex DNA helixes were captured to the surface of magnetic beads through a well known and specific biotin-streptavidin affinity binding. For signaling each of eight possible Single-nucleotide polymorphisms (SNPs), Pb, Cu, Cd and Zn phosphate-loaded apoferritin nanoparticle probes were linked to adenosine (A), cytidine (C), guanosine (G), and thymidine (T) mononucleotides, respectively. Monobase-conjugated apoferritin probes were coupled to the mutant sites of the formed duplex DNA in the presence of DNA polymerase. Electrochemical stripping analyses of the metals loaded in apoferritin nanoparticle probes provide a means for detection and quantification of mutant DNA. Each mutation captures different nucleotide-conjugated apoferritin probe and provide a distinct four-potential voltammogram, whose peak potentials reflect the identity of the mismatch. The method is sensitive enough to accurately determine AG mutation, as the most thermodynamically stable mismatch to detect, in the range of 50-600 pM. The proposed protocol provides a simple, fast, cost-effective, accurate and sensitive method for detection of SNPs.

Molecular cloning and copy number variation of a ferritin subunit (Fth1) and its association with growth in freshwater pearl mussel Hyriopsis cumingii.

Iron is one of the most important minor elements in the shells of bivalves. This study was designed to investigate the involvement of ferritin, the principal protein for iron storage, in shell growth. A novel ferritin subunit (Fth1) cDNA from the freshwater pearl mussel (Hyriopsis cumingii) was isolated and characterized. The complete cDNA contained 822 bp, with an open reading frame (ORF) of 525 bp, a 153 bp 5' untranslated region (UTR) and a 144 bp 3' UTR. The complete genomic DNA was 4125 bp, containing four exons and three introns. The ORF encoded a protein of 174 amino acids without a signal sequence. The deduced ferritin contained a highly conserved motif for the ferroxidase center comprising seven residues of a typical vertebrate heavy-chain ferritin. It contained one conserved iron associated residue (Try27) and iron-binding region signature 1 residues. The mRNA contained a 27 bp iron-responsive element with a typical stem-loop structure in the 5'-UTR position. Copy number variants (CNVs) of Fth1 in two populations (PY and JH) were detected using quantitative real-time PCR. Associations between CNVs and growth were also analyzed. The results showed that the copy number of the ferritin gene of in the diploid genome ranged from two to 12 in PY, and from two to six in JH. The copy number variation in PY was higher than that in JH. In terms of shell length, mussels with four copies of the ferritin gene grew faster than those with three copies (P<0.05), suggesting that CNVs in the ferritin gene are associated with growth in shell length and might be a useful molecular marker in selective breeding of H. cumingii.

H-ferritin is the major source of iron for oligodendrocytes.

There is a critical relationship between oligodendrocyte development, myelin production, and iron bioavailability. Iron deficiency leads to hypomyelination both in humans and animal models, and the neurological sequelae of hypomyelination are significant. Therefore, understanding molecular mechanisms of iron import into oligodendrocytes is necessary for devising effective strategies for iron supplementation. Although transferrin has been considered as an essential component of oligodendrocyte media in culture, oligodendrocytes in vivo lack transferrin receptors. We have established that receptors for H-ferritin (HF) exist on cells of oligodendroglial lineage and that uptake of extracellular HF by oligodendrocyte progenitors is via receptor mediated endocytosis. These data strongly argue that ferritin is a major source of iron for oligodendrocytes. In this study, we demonstrate that media deficient in transferrin results in loss of viability of oligodendrocyte progenitors in culture. Cell loss could be prevented by supplementing the media with HF. Moreover, the addition of extracellular HF stimulates development of oligodendrocyte progenitor cells (OPCs) by increasing expression of myelin basic protein (MBP) and olig2 proteins without increasing their proliferation. The effect of HF on the OPCs could be mimicked by addition of membrane permeable 3,5,5-trimethylhexanoyl ferrocene (TMH-Fe) as an iron source to the media, but not membrane-impermeable ferric ammonium citrate. Overall, therefore, our results demonstrate the importance of iron for OPCs viability and differentiation and identify extracellular HF as a critical source of iron for oligodendrocytes. Given that ferritin receptors, but not transferrin receptors can be demonstrated on oligodendrocytes in vivo, the delivery of iron to oligodendrocytes via ferritin may be the more biological relevant delivery system.

A high-throughput approach for identification of novel general anesthetics.

Anesthetic development has been a largely empirical process. Recently, we described a GABAergic mimetic model system for anesthetic binding, based on apoferritin and an environment-sensitive fluorescent probe. Here, a competition assay based on 1-aminoanthracene and apoferritin has been taken to a high throughput screening level, and validated using the LOPAC(1280) library of drug-like compounds. A raw hit rate of approximately 15% was reduced through the use of computational filters to yield an overall hit rate of approximately 1%. These hits were validated using isothermal titration calorimetry. The success of this initial screen and computational triage provides feasibility to undergo a large scale campaign to discover novel general anesthetics.

Hypergravity as a crystallization tool.

The centrifugal increase of concentration is nondestructive, rapid, and simple technology. Therefore it is used to create a higher supersaturation that is required for crystal nucleation, as the one that is appropriate for the subsequent growth. Crystal nucleation is evoked in glass capillary tubes filled with protein solutions. The couple ferritin/ apoferritin is used as model proteins in the present article. Although differing in their masses the two (quasi) spherical molecules have exactly the same size and surface properties. Together with the temperature-independent solubility this makes them very convenient for our investigations. Decoupling nucleation and growth, for example, by means of hypergravity makes it possible to grow quasi-equidimensional crystals. The use of monodisperse crystalline forms of therapeutic agents can ensure constant time-release of protein-based medications.

Novel properties of L-type polypeptide subunits in mouse ferritin molecules.

Properties of the L- and H-type polypeptide subunits forming ferritin 24-mer molecules in mice were investigated, using the products of in vitro transcription and translation from the two cloned genes, and recombinant ferritin molecules (H24L0 or H0L24) produced by transformation in Escherichia coli. Several different conditions for analytical electrophoresis reproducibly show that the relative migration position of the two mouse ferritin subunits is reversed from that reported for ferritin H- and L-subunits in all other mammals; since mouse and human H-polypeptides almost co-migrate, this unusual relative mobility is due largely to novel properties of the murine L-subunit. This unusual electrophoretic property of the mouse L-subunit has led to conflicting reports about the subunit composition of natural mouse ferritin. Here, we show that the single major electrophoretic band given by liver ferritin purified from mice having a short-term iron overload matches that produced by the genetically defined L-polypeptide and that some bona fide H-subunits are also detected. In conclusion, it is reasonable to assume that, when mouse ferritin samples will be analyzed under the same conditions as those described here, the slower species will correspond to the L-type subunit. However, when dealing with ferritin from species other than human or mouse, it should be kept in mind that upon electrophoretic analysis of ferritin polypeptide, the designation of an electrophoretic band as being H- or L-type subunits will be very uncertain without corroboration from genetic, immunological, or amino acid sequencing data.

Synergism and substitution in the lactoferrins.

The anion binding properties of human lactoferrin (Lf), with Fe3+ or Cu2+ as the associated metal ion, highlight differences between the two sites, and in the anion binding behaviour when different metals are bound. Carbonate, oxalate and hybrid carbonate-oxalate complexes have been prepared and their characteristic electronic and EPR spectra recorded. Oxalate can displace carbonate from either one or both anion sites of Cu2(CO3)2Lf, depending on the oxalate concentration, but no such displacement occurs for Fe2(CO3)2Lf although it does for the bovine analogue. Addition of oxalate and the appropriate metal ion to apoLf under carbonate-free conditions gives dioxalate complexes with both Fe3+ and Cu2+. The anion sites as determined from the crystal structures of Fe2(CO3)2Lf, Fe2(C2O4)2Lf, Cu2(CO3)2Lf, and Cu2(CO3)(C2O4)Lf have been compared. Both the carbonate and oxalate ions bind in bidentate fashion to the metal, except that the carbonate ion in the N-lobe site of dicupric lactoferrin is monodentate. The hybrid copper lactoferrin complex shows that the oxalate ion binds preferentially in the C-lobe site in a bidentate mode. A series of complexes containing the synergistic anion O,N-chelates with increasing substitution on the N atom (glycinate, iminodiacetate and nitrilotriacetate) have been prepared with iron bovine lactoferrin for comparison with the O,O-chelate oxalate. Overall these observations lead to a generalised model for synergistic anion binding by transferrins and allow comparisons to be made with nonsynergistic anions such as citrate and succinate.