Fluorescent Nanoparticles Coated with a Somatostatin Analogue Target Blood Monocyte for Efficient Leukaemia Treatment.

BACKGROUND: Leukaemia is the most prevalent form of cancer-causing death in a large number of populations and needs prompt and effective treatment. Chemotherapeutics can be used to treat leukaemia, but their pronounced killing effects to other living cells is still an issue. Active targeting to certain specific receptors in leukaemic cells is the best way to avoid damage to other living cells. Leukaemic cells can be targeted using novel nanoparticles (NPs) coated with a specific ligand, such as octreotide (OCD), to target somatostatin receptor type 2 (SSTR2), which is expressed in leukaemic cells. METHODS: Amino-PEGylated quantum dots (QDs) were chosen as model NPs. The QDs were first succinylated using succinic anhydride and then coated with OCD. The reactivity and selectivity of the formulated QDs-OCD were studied in cell lines with well-expressed SSTR2, while fluorescence was detected using confocal laser scanning microscopy (CLSM) and flow cytometry (FACS). Conclusively, QD-OCD targeting to blood cells was studied in vivo in mice and detected using inductively coupled plasma mass spectrometry and CLSM in tissues. RESULTS: Highly stable QDs coated with OCD were prepared. FACS and CLSM showed highly definite interactions with overexpressed SSTR2 in the investigated cell lines. Moreover, the in vivo results revealed a higher concentration of QDs-OCD in blood cells. The fluorescence intensity of the QDs-OCD was highly accumulated in blood cells, while the unmodified QDs did not accumulate significantly in blood cells. CONCLUSION: The formulated novel QDs-OCD can target SSTR2 overexpressed in blood cells with great potential for treating blood cancer.

Ligand-functionalized nanoparticles target endothelial cells in retinal capillaries after systemic application.

To date, diseases affecting vascular structures in the posterior eye are mostly treated by laser photocoagulation and multiple intraocular injections, procedures that destroy healthy tissue and can cause vision-threatening complications. To overcome these drawbacks, we investigate the feasibility of receptor-mediated nanoparticle targeting to capillary endothelial cells in the retina after i.v. application. Cell-binding studies using microvascular endothelial cells showed receptor-specific binding and cellular uptake of cyclo(RGDfC)-modified quantum dots via the αvß3 integrin receptor. Conversely, Mueller cells and astrocytes, representing off-target cells located in the retina, revealed only negligible interaction with nanoparticles. In vivo experiments, using nude mice as the model organism, demonstrated a strong binding of the ligand-modified quantum dots in the choriocapillaris and intraretinal capillaries upon i.v. injection and 1-h circulation time. Nontargeted nanoparticles, in contrast, did not accumulate to a significant amount in the target tissue. The presented strategy of targeting integrin receptors in the retina could be of utmost value for future intervention in pathologies of the posterior eye, which are to date only accessible with difficulty.

G protein-coupled receptors function as logic gates for nanoparticle binding and cell uptake.

More selective interactions of nanoparticles with cells would substantially increase their potential for diagnostic and therapeutic applications. Thus, it would not only be highly desirable that nanoparticles can be addressed to any cell with high target specificity and affinity, but that we could unequivocally define whether they rest immobilized on the cell surface as a diagnostic tag, or if they are internalized to serve as a delivery vehicle for drugs. To date no class of targets is known that would allow direction of nanoparticle interactions with cells alternatively into one of these mutually exclusive events. Using MCF-7 breast cancer cells expressing the human Y(1)-receptor, we demonstrate that G protein-coupled receptors provide us with this option. We show that quantum dots carrying a surface-immobilized antagonist remain with nanomolar affinity on the cell surface, and particles carrying an agonist are internalized upon receptor binding. The receptor functions like a logic "and-gate" that grants cell access only to those particles that carry a receptor ligand "and" where the ligand is an agonist. We found that agonist- and antagonist-modified nanoparticles bind to several receptor molecules at a time. This multiligand binding leads to five orders of magnitude increased-receptor affinities, compared with free ligand, in displacement studies. More than 800 G protein-coupled receptors in humans provide us with the paramount advantage that targeting of a plethora of cells is possible, and that switching from cell recognition to cell uptake is simply a matter of nanoparticle surface modification with the appropriate choice of ligand type.

Kidney podocytes as specific targets for cyclo(RGDfC)-modified nanoparticles.

Renal nanoparticle passage opens the door for targeting new cells like podocytes, which constitute the exterior part of the renal filter. When cyclo(RGDfC)-modified Qdots are tested on isolated primary podocytes for selective binding to the αvß3 integrin receptor a highly cell- and receptor-specific binding can be observed. In displacement experiments with free cyclo(RGDfC) IC(50) values of 150 nM for αvß3 integrin over-expressing U87-MG cells and 60 nM for podocytes are measured. Confocal microscopy shows a cellular Qdot uptake into vesicle-like structures. Our ex vivo study gives clear evidence that, after renal filtration, nanoparticles can be targeted to podocyte integrin receptors in the future. This could be a highly promising approach for future therapy and diagnostics of podocyte-associated diseases.

Multivalent targeting of AT1 receptors with angiotensin II-functionalized nanoparticles.

The angiotensin II receptor type 1 (AT1R) is a G protein-coupled receptor of paramount significance since it is overexpressed in a number of diseased tissues that are highly attractive for nanoparticle targeting. However, it is also expressed at physiological levels in healthy tissue. Multivalent interactions mediated by multiple AT1R-binding moieties per nanoparticle could promote a high binding avidity to AT1R overexpressing cells and concomitantly spare off-target tissue. To investigate the feasibility of this approach, angiotensin II was thiolated and conjugated to PEGylated quantum dots. Nanoparticle binding, uptake and affinity to several cell lines was investigated in detail. The colloids were rapidly taken up by clathrin-mediated endocytosis into AT1R-expressing cells and showed no interaction with receptor negative cells. The EC50 of the thiolated angiotensin II was determined to be 261 nM, whereas the ligand-conjugated Qdots activated the receptor with an EC50 of 8.9 nM. This 30-fold higher affinity of the nanoparticles compared to the unconjugated peptide clearly demonstrated the presence of multivalent effects when using agonist-targeted nanoparticles. Our study provides compelling evidence that, despite being immediately endocytosed, Ang II-coupled nanoparticles exert potent multivalent ligand-receptor interactions that can be used to establish high affinities to an AT1R overexpressing cell and tissue.

Multivalent nanoparticles bind the retinal and choroidal vasculature.

The angiotensin II receptor type 1 (AT1R), which is expressed in blood vessels of the posterior eye, is of paramount significance in the pathogenesis of severe ocular diseases such as diabetic retinopathy and age-related macular degeneration. However, small molecule angiotensin receptor blockers (ARBs) have not proven to be a significant therapeutic success. We report here on a nanoparticle system consisting of ARB molecules presented in a multivalent fashion on the surface of quantum dots (Qdots). As a result of the multivalent receptor binding, nanoparticles targeted cells with high AT1R expression and inhibited their angiotensin receptor signaling with an IC50 of 3.8 nM while showing only minor association to cells with low AT1R expression. After intravenous injection into the tail vein of mice, multivalent nanoparticles accumulated in retinal and choroidal blood vessels of the posterior eye. At the same time, multivalent ligand display doubled the Qdot concentration in the blood vessels compared to non-targeted Qdots. Remarkably, ARB-targeted Qdots showed no pronounced accumulation in AT1R-expressing off-target tissues such as the kidney. Following systemic application, this multivalent targeting approach has the potential to amplify AT1R blockade in the eye and concomitantly deliver a therapeutic payload into ocular lesions.

Nanoparticle multivalency counterbalances the ligand affinity loss upon PEGylation.

The conjugation of receptor ligands to shielded nanoparticles is a widely used strategy to precisely control nanoparticle-cell interactions. However, it is often overlooked that a ligand's affinity can be severely impaired by its attachment to the polyethylene glycol (PEG) chains that are frequently used to protect colloids from serum protein adsorption. Using the model ligand EXP3174, a small-molecule antagonist for the angiotensin II receptor type 1 (AT1R), we investigated the ligand's affinity before and after its PEGylation and when attached to PEGylated nanoparticles. The PEGylated ligand displayed a 580-fold decreased receptor affinity compared to the native ligand. Due to their multivalency, the nanoparticles regained a low nanomolar receptor affinity, which is in the range of the affinity of the native ligand. Moreover, a four orders of magnitude higher concentration of free ligand was required to displace PEGylated nanoparticles carrying EXP3174 from the receptor. On average, one nanoparticle was decorated with 11.2 ligand molecules, which led to a multivalent enhancement factor of 22.5 compared to the monovalent PEGylated ligand. The targeted nanoparticles specifically bound the AT1R and showed no interaction to receptor negative cells. Our study shows that the attachment of a small-molecule ligand to a PEG chain can severely affect its receptor affinity. Concomitantly, when the ligand is tethered to nanoparticles, the immense avidity greatly increases the ligand-receptor interaction. Based on our results, we highly recommend the affinity testing of receptor ligands before and after PEGylation to identify potent molecules for active nanoparticle targeting.

Hyalocyte proliferation and ECM accumulation modulated by bFGF and TGF-beta1.

PURPOSE: In cases of severe retinal diseases, the vitreous body has to be removed and replaced by a suitable biomaterial. Currently, however, no satisfying long-term vitreous substitute is in clinical use. A novel therapeutic concept represents the combination of hyalocytes with suitable biomaterials. The goal of the present study was to evaluate the potential of bFGF and TGF-beta1 as tools to control hyalocyte proliferation and the accumulation of extracellular matrix (ECM). METHODS: In vitro investigation on the influence of different concentrations of bFGF and TGF-beta1 on hyalocyte morphology, proliferation and ECM production. RESULTS: Both growth factors affected hyalocyte morphology; small, round cells could be observed after bFGF supplementation, whereas the cells appeared more completely spread when cultured with TGF-beta1. Hyalocyte proliferation was increased 3-fold by 10 ng/ml bFGF; 1 ng/ml TGF-beta1 in contrast reduced cell proliferation to about 40% of the control. Converse effects of the growth factors could also be observed on the ECM accumulation of hyalocytes; whereas bFGF halved ECM accumulation, TGF-beta1 enhanced the ECM production up to 3-fold. Precultivation of hyalocytes with bFGF for two passages had no influence on their subsequent accumulation of glycosaminoglycans (GAG). However, cells precultivated with bFGF exhibited a doubled accumulation of collagen compared to controls. CONCLUSIONS: The observed opposite effects of bFGF and TGF-beta1 on hyalocyte proliferation and ECM accumulation may allow for the control of hyaloycte properties. Therefore, these two growth factors seem to be valuable tools towards the development of a cell-based vitreous substitute.