Macrocyclic chelators with paramagnetic cations are internalized into mammalian cells via a HIV-tat derived membrane translocation peptide

Combination of transfection agents and magnetic resonance contrast agents for cellular imaging: relationship between relaxivities, electrostatic forces, and chemical composition

The purpose of this study was to investigate the changes in electrostatic and magnetic resonance (MR) properties observed when MR contrast agents (CAs) (Feridex, MION-46L, or G5-dendrimer-DOTA-Gd) are combined with transfection agents (TAs) under various conditions for use as a CA-TA complex basis for cellular labeling and MRI. CAs were incubated with various classes of TAs for 0-48 hr in solutions of varying concentrations and pH values. NMR relaxation rates (1/T(1), 1/T(2)), MRI and zeta potential (ZP) of CA-TA solutions were measured. TAs decreased the 1/T(1) and 1/T(2) of G5-DOTA-Gd, Feridex, and MION-46L by 0-95%. Altering the pH of G5-DOTA-Gd-TA decreased the T(1)-weighted signal intensity (SI) on MRI from 0 to 78%. Measured ZP values for G5-DOTA-Gd, Feridex, and MION-46L were -51, -41, and -2.0 mV, respectively. The TA LV had a negative ZP, while the other TAs had ZPs ranging from +20 to +65 mV. The alteration of the ZP and NMR relaxivities of the MR CAs, Feridex, MION-46L, and G5-DOTA-Gd by TAs has been demonstrated. These results enhance our understanding of the relationship between electrostatic and MR properties.

Synthesis and visualization of a membrane-permeable MRI contrast agent

The study of in vivo developmental events has undergone significant advances with the advent of biological molecular imaging techniques such as computer enhanced light microscopy imaging, positron emission tomography (PET), micro-CT, and magnetic resonance imaging (MRI). MRI has proven to be a particularly powerful tool in clinical and biological settings. Images can be acquired of opaque living animals, with the benefit of tracking events of extended periods of time on the same specimen. Contrast agents are routinely used to enhance regions, tissues, and cells that are magnetically similar but histologically distinct. A principal barrier to the development of MR contrast agents for investigating developmental biological questions is the ability to deliver the agent across cellular membranes. As part of our research, we are investigating a number of small molecules that facilitate transport of charged and uncharged species across cell membranes. Here we describe the synthesis and testing of a Gd(III)-based MR contrast agent conjugated to polyarginine that is able to permeate cell membranes. We confirmed cellular uptake of the agent using two-photon laser microscopy to visualize a Eu(III) derivative of the contrast agent in cell culture, and verified this uptake by T(1) analysis of the Gd(III) agent in cells.

Innovative magnetic resonance imaging diagnostic agents based on paramagnetic Gd(III) complexes

Gd(III) complexes are under intense scrutiny as contrast agents for magnetic resonance imaging (MRI). They act by enhancing tissutal proton relaxation rates. Much has already been done in order to get an in-depth understanding of the relationships between structure, dynamics, and contrastographic ability of these paramagnetic complexes. Their potential in the assessment of flow, perfusion, and capillary permeability has already been established. The next challenges are in the field of molecular imaging applications, which would allow the attainment of early diagnosis based on the recognition of specific reporters of the onset of the pathological state. To this end, Gd(III) complexes have to be endowed with improved targeting capabilities by conjugating suitable recognition synthons on their surfaces. Small peptides are candidates of choice for the attainment of this goal. Moreover, the intrinsic low sensitivity of the NMR techniques implies the need to deliver large amounts of contrast agents to the target in order to get its visualization in the resulting images. Highly efficient delivery systems have been identified, which bring a great promise for the development of innovative diagnostic agents based on Gd(III) complexes.

Peptide and protein drug delivery to and into tumors: challenges and solutions

The potential of peptide and protein anticancer agents has yet to be realized owing to the many unresolved problems concerning their delivery to the site of a tumor and into tumor cells. However, our understanding of the mechanisms underlying the biological fate and biodistribution of protein and peptide drugs has advanced to the stage where methods that use or influence these mechanisms are now available. There are different approaches that can improve the stability, longevity and targeting of peptides and proteins in the body, such as their modification with various soluble polymers, incorporation into microparticular drug carriers, enhanced permeability and retention effect-based tumor targeting and the use of targeting moieties. Furthermore, new approaches to intracellular drug delivery, including the use of transduction proteins and peptides, are being developed. These advances promise the delivery of a new generation of anticancer drugs.

Arginine containing peptides as delivery vectors

Recently several membrane translocalizational signals (MTS) have been identified and applied to various applications. These peptide signals, ranging between nine and 30 amino acid residues in length, have the capability of crossing plasma membrane, in addition to delivering other biological molecules into cells. To date, small molecules, peptides, proteins, oligonucleotides, plasmids and even nanometer-sized particles have been delivered. These MTS sequences vary from hydrophobic to purely hydrophilic, and, surprisingly, all of them are able to penetrate cellular membrane in an energy-independent pathway. Potentially, MTS could be used as delivery vectors for a number of therapeutic agents. In this review, we specifically focus on arginine-containing MTS, and their properties, characteristics, in vitro and in vivo applications are discussed in detail.

Nanostructured materials designed for cell binding and transduction

The surface-functionalization of shell cross-linked (SCK) nanoparticles with the oligomeric peptide sequence YGRKKRRQRRR, the protein transduction domain (PTD) from the human immunodeficiency virus TAT protein, is described, and the cell binding interactions these nanobioconjugates exhibit are demonstrated. A convergent synthetic strategy was employed, whereby the SCK nanoparticles and the PTD were prepared independently and then coupled together during immobilization of the PTD component on a solid support. The SCK nanoparticles were prepared by the micellization of amphiphilic block copolymers of poly(epsilon-caprolactone-b-acrylic acid), followed by amidation-based cross-linking of the acrylic acid residues located within the micellar corona. The PTD sequence was constructed upon a solid support, from C-terminus to N-terminus, followed by extension with four glycine residues, leaving the amino chain end for subsequent coupling with remaining acrylic acid functionalities present on the surface of the SCK. Finally, cleavage from the solid support was performed, which also facilitated deprotection of the peptide side chain functionalities as well as hydrolysis of the poly(epsilon-caprolactone) segments composing the SCK core domain, to yield PTD-derivatized nanocage structures (PTD-nanocage). Covalent labeling of the SCK precursor with fluorescein-5-thiosemicarbazide provided fluorescently tagged PTD-nanocage nanobioconjugates to allow for their detection by fluorescence microscopy. The fluorescent PTD-nanocage bioconjugates were found to interact with CHO cells and HeLa cells, whereas the analogous structure lacking the PTD component did not. CHO cells bound with fluorescent PTD-nanocage bioconjugates were analyzed using flow cytometry and fluorescence activated cell sorting (FACS). Fluorescence confocal microscopy of isolated bioconjugate-bound CHO cells indicated that the bioconjugated nanoparticles were primarily located near the cell periphery; however, transduction of the nanoparticle into the cells also occurred.

Intracellular cargo delivery using tat peptide and derivatives

Efficient delivery of therapeutic and diagnostic agents across the plasma membrane is crucial in developing novel therapies. Membrane permeating peptides, in particular HIV-1 tat peptide and its derivatives, have enabled the intracellular delivery of cargos of various sizes and physicochemical properties. This review summarizes the current knowledge of tat-derived cell permeating peptides in the transduction of exogenous molecules/complexes.

Design, synthesis, and evaluation of gadolinium cationic lipids as tools for biodistribution studies of gene delivery complexes

Gadolinium-chelating cationic lipids have been synthesized to obtain lipoplexes with MRI contrast properties. These compounds were designed to follow the biodistribution of synthetic DNA for gene delivery by nuclear magnetic resonance imaging. The lipid MCO-I-68 was synthesized, and chelate complexes with gadolinium were formed and characterized in terms of physicochemical and DNA binding properties. The transfection activity of MCO-I-68-Gd/DNA complexes was assayed in vitro on NIH 3T3. Different formulations of the product were tested. When up to 5% of the gadolinium lipid complexes were co-formulated with the cationic lipid RPR120535 used as a reference, the transfection levels were maintained as compared to RPR120535 alone. To date, only a liposomal formulation of a gadolinium-cationic lipid chelate without DNA had been observed using magnetic resonance imaging. In vivo intratumoral administration of MCO-I-68-Gd/DNA lipoplexes to tumor model led to an important increase of the NMR signal. It was demonstrated that the new complexes also acted as transfection carriers when they were formulated from liposomes.

Novel branching membrane translocational peptide as gene delivery vector

A fragment of HIV-tat protein, RKKRRQRRR, has been shown to have membrane penetration and nuclear localization properties, which are critical attributes of gene therapy agents. In this study, we designed a series of arborizing tat peptides, containing 1-8 tat moieties, and evaluated them as transfection enhancers in a variety of cell lines. We found that all compounds complexed with plasmid DNA, but only the molecule containing 8 tat-peptide chains shows significant transfection capabilities. Using rhodamine labeled plasmid and eight tat-peptide complex, we were also able to demonstrate intracellular delivery of the complex by fluorescence microscopy.

Insights into the use of paramagnetic Gd(III) complexes in MR-molecular imaging investigations

Can gadolinium III [Gd(III)] complexes be considered good candidates for magnetic resonance (MR)-molecular imaging studies? In this review article, we examine the principal issues that are the basis of successful use of Gd-based protocols in molecular imaging applications. High relaxivity is the primary requisite. Therefore, the design of such paramagnetic probes has to be pursued keeping in mind the relationships between structure, dynamics, and the relevant parameters involved in paramagnetic relaxation processes. Moreover, the limited number of target molecules on cellular membranes makes it necessary to define strategies aimed at delivering many Gd-containing moieties to the sites of interest. Examples are reported for the attainment of very high relaxivities for the design of new routes for pursuing the accumulation of small sized Gd(III) complexes at the targeting sites. An efficient cellular uptake of Gd-containing probes is the key step for attaining the visualization of targeted cells by MR imaging, and selected examples are reported. In this context, the problem of the assessment of the minimum amount of Gd(III) complexes necessary for the MR imaging-visualization of cells has been addressed by reporting the authors' observations on the cell-internalization of Gd(III) complexes. A particularly efficient delivery system is represented by Gd-loaded apoferritin, which allows the MR visualization of hepatocytes when the number of Gd-complexes per cell is 4 +/- 1 x 10(7). Finally, the potential of responsive systems is considered by outlining the exploitation of the amplification effect brought about by the action of a specific enzymatic activity on the relaxivity of a suitably functionalized Gd(III) complex.

Formation kinetics and stability studies on the lanthanide complexes of 1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid by capillary electrophoresis

In this study, the kinetic behaviors of four lanthanide ions, Sm(3+), Dy(3+), Yb(3+) and Lu(3+), when mixed with a polyazamacrocyclic chelating agent 1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid (DOTA), were investigated by capillary electrophoresis (CE) in the pH range of 2.0-6.0. At pH 2.0, the formation rate of DOTA-metal complex is extremely low as very little complex was detected after 5 days reaction, whereas almost no free DOTA was found in the mixture of metal ion and DOTA after 4 min at pH 6.0. The second-order kinetic association rate constants of the four lanthanide ions chelates at pH 4.2 were calculated as 1.44 x 10(-2) mM(-1)min(-1), 5.20 x 10(-2) mM(-1)min(-1), 4.56 x 10(-2) mM(-1)min(-1) and 4.54 x 10(-2) mM(-1)min(-1) at 25 degrees C with CE, respectively. In addition, the stability constants of the four lanthanide ions with DOTA were determined by CE at pH 3.0 where approximately 80-90% of the metal ions were associated with DOTA at 25 degrees C. The measured stability constants (log K(f)) of the four DOTA-metal complexes were 23.36, 23.93, 23.39 and 23.06, respectively, and correlated well with published data obtained by different methods. The percentage of metal ion bound with DOTA was evaluated as a function of reactant concentration in pH 6.0 buffer. After adding excess strong acid (0.1 M HCl) to each solution of DOTA-metal was formed at pH 6.0, no released DOTA was detected after 24 h; thus, dissociation of these lanthanide complexes did not occur under strongly acidic conditions. The Ln(DOTA)(-) species for the four DOTA-metal complexes were characterized by electrospray ionization-mass spectroscopy (ESI-MS), and the results correlated with proposed structures.

Magnetodendrimers allow endosomal magnetic labeling and in vivo tracking of stem cells

Magnetic resonance (MR) tracking of magnetically labeled stem and progenitor cells is an emerging technology, leading to an urgent need for magnetic probes that can make cells highly magnetic during their normal expansion in culture. We have developed magnetodendrimers as a versatile class of magnetic tags that can efficiently label mammalian cells, including human neural stem cells (NSCs) and mesenchymal stem cells (MSCs), through a nonspecific membrane adsorption process with subsequent intracellular (non-nuclear) localization in endosomes. The superparamagnetic iron oxide nanocomposites have been optimized to exhibit superior magnetic properties and to induce sufficient MR cell contrast at incubated doses as low as 1 microg iron/ml culture medium. When containing between 9 and 14 pg iron/cell, labeled cells exhibit an ex vivo nuclear magnetic resonance (NMR) relaxation rate (1/T2) as high as 24-39 s-1/mM iron. Labeled cells are unaffected in their viability and proliferating capacity, and labeled human NSCs differentiate normally into neurons. Furthermore, we show here that NSC-derived (and LacZ-transfected), magnetically labeled oligodendroglial progenitors can be readily detected in vivo at least as long as six weeks after transplantation, with an excellent correlation between the obtained MR contrast and staining for beta-galactosidase expression. The availability of magnetodendrimers opens up the possibility of MR tracking of a wide variety of (stem) cell transplants.

TAT peptide on the surface of liposomes affords their efficient intracellular delivery even at low temperature and in the presence of metabolic inhibitors

To achieve an efficient intracellular drug and DNA delivery, attempts were made to target microparticulate drug carriers into cytoplasm bypassing the endocytotic pathway. TAT peptides derived from the HIV-1 TAT protein facilitate intracellular delivery of proteins and small colloidal particles. We demonstrated that relatively large drug carriers, such as 200-nm liposomes, can also be delivered into cells by TAT peptide attached to the liposome surface. Liposomes were fluorescently labeled with membranotropic rhodamine-phosphatidylethanolamine or by entrapping FITC-dextran. Incubation of fluorescent TAT liposomes with mouse Lewis lung carcinoma cells, human breast tumor BT20 cells, and rat cardiac myocyte H9C2 results in intracellular localization of certain liposomes. Steric hindrances for TAT peptide x cell interaction (attachment of TAT directly to the liposome surface without spacer or the presence of a high MW polyethylene glycol on the liposome surface) abolish liposome internalization, evidencing the importance of direct contact of TAT peptide with the cell surface. Low temperature or metabolic inhibitors, sodium azide or iodoacetamide, have little influence on the translocation of TAT liposomes into cells, confirming the energy-independent character of this process. The approach may have important implications for drug delivery directly into cell cytoplasm.

Gd3+ complexes with slowly exchanging bound-water molecules may offer advantages in the design of responsive MR agents

RATIONALE AND OBJECTIVES

Slow water exchange in Gd3+ complexes is generally considered detrimental to their use as MR contrast agents. The objective of this work was to demonstrate how this feature may serve as a useful template for the design of responsive MR agents.

METHODS

Lanthanide (Ln) complexes of two 1,4,7,10-tetraazacyclododecane-N,N',N",N'"-tetraacetic acid (DOTA)-tetraamide phosphonate (1) and phosphonate ester (2) ligands were studied by multinuclear (1H, 13C, 31P, and 17O) nuclear MR spectroscopy.

RESULTS

The inner-sphere water lifetime in the Ln(2) complexes was much longer (tauM298 = 0.8-1.3 ms) than in the corresponding Ln(1) complexes. This allowed direct detection of the bound-water molecule in europium(2) in water at 40 degrees C by 1H nuclear MR. The water relaxivity of gadolinium(2) was independent of pH between 8.5 and 6.0, whereas the relaxivity of gadolinium(1) increased more than twofold in this pH range.

CONCLUSIONS

T1-weighted images of phantoms containing gadolinium(1) at different pH values demonstrate the efficacy of this complex as a pH-sensitive MR contrast agent.