Analogs of Eu3+ DOTAM-Gly-Phe-OH and Tm3+ DOTAM-Gly-Lys-OH: synthesis and magnetic properties of potential PARACEST MRI contrast agents

Chelated lanthanide ions, especially gadolinium, have found wide use as contrast agents in magnetic resonance imaging. A new paradigm for generating contrast, termed PARACEST, was recently described that requires the slow exchange of water or other exchangeable protons present in the ligand framework. In previous work, we have described a synthetic method for the preparation of dipeptide conjugates of DOTAM for use as PARACEST agents. Two compounds possessed interesting magnetic properties: the Eu(3+) complex of DOTAM-Gly-Phe-OH and the Tm(3+) complex of DOTAM-Gly-Lys-OH. To understand the relationship between the structure of these complexes and their magnetic properties, we have expanded our synthetic methodology and prepared several new complexes. Ligands have been prepared in which the terminal phenylalanine moieties have been replaced with tryptophan or tyrosine, the distance to the amino acid residue possessing an alpha-substituent has been changed, or phenylalanine and lysine have been combined in the peptide sequence. The preparation of lanthanide(III) complexes of these ligands has been achieved and their PARACEST properties have been determined.     

Labeling of proteins and oligopeptides with luminescent lanthanide(III) chelates.

Synthesis of a building block that allows introduction of photoluminescent europium(III) and samarium(III) chelates to synthetic oligopeptides on solid phase using standard Fmoc chemistry is described. Upon completion of the oligopeptide synthesis, these conjugates were converted to the corresponding lanthanide(III) chelates by treatment with appropriate lanthanide(III) salt. Also synthesis of a new terpyridine-based europium(III) chelate designed for solution phase protein labeling is demonstrated.     

Near-infrared Yb(3+) vibronic sideband spectroscopy: application to Ca(2+)-binding proteins.

We have used near-infrared (NIR) vibronic fluorescence spectroscopy to study the vibrational structure of ligands associated with model complexes of the lanthanide Yb(3+). This technique exploits the similar binding properties of the lanthanide Yb(3+) to probe Ca(2+)-binding sites in proteins. The (NIR) fluorescence of complexed Yb(3+) exhibits, in addition to main 0-0 (2F5/2----2F7/2) electronic transition of Yb(3+), weak vibronic sidebands which provide infrared-like, local vibrational spectra of the chelates (inner sphere ligands) of Yb(3+). A similar approach has been used for the lanthanide Gd(3+) (MacGregor, R.B., Jr (1989) Arch. Biochem. Biophys. 274, 312-316) which fluoresces in the UV and which is usually complicated by amino-acid residues fluorescing in the same spectral region. In this same spectral region, other complications in studying photosynthetic membranes occur in the form of the excitation wavelength being actinic, promoting photodegradation of the membranes, as well as the reabsorption of Gd(3+) fluorescence. NIR excitation and fluorescence detection of Yb(3+) avoid these problems when studying photosynthetic membranes. A preliminary study has been conducted here on rat muscle parvalbumin.     

Force constants and fundamental frequencies of the fare earth trihalide molecules

The effective nuclear charge model has been applied to the rare earth trihalides. A set of the effective nuclear charge values of the rare earth atoms has been evaluated from the bond stretch force constants obtained by normal coordinate analysis of the infrared spectra of the lanthanide trifluorides.The force constants and the fundamental frequencies of all the lanthanide trihalides have been calculated by means of the effective nuclear charge model. The calculated results are in agreement with the experimental data. The results show that the most probable configuration of the lanthanide trihalides is pyramidal with C_3ν symmetry, although the geometry of the lanthanide trifluoride molecules is very close to planar. It is also found that the frequency ν₂ (symmetric deformation) and the frequency ν₄ (antisymmetric deformation) will vary with the bond angle (XLnX).     

Scanning the prime-site substrate specificity of proteolytic enzymes: a novel assay based on ligand-enhanced lanthanide ion fluorescence

A novel method for assaying the substrate specificity of proteolytic enzymes has been developed utilizing ligand-enhanced lanthanide ion fluorescence. This approach was used to develop peptide libraries to probe substrate specificity in the prime sites of proteolytic enzymes. A positional scanning synthetic combinatorial library of fluorogenic peptides was synthesized and used to determine the extended prime site specificity of bovine -chymotrypsin. The enzyme showed a preference for Lys and Arg in the P1′ position, rather broad specificity in the P2′ position, and a slight Arg specificity in the P3′ position. The specificity profile of bovine -chymotrypsin agrees well with previously reported data, and the substrate library reported herein should provide valuable information about the prime site substrate specificities of other proteolytic enzymes as well. Furthermore, the continuous fluorogenic assay described may prove useful in analyzing the activity of other hydrolytic enzymes.     

Targeted molecular imaging agents for cellular-scale bimodal imaging

Molecular imaging is a powerful tool that has the ability to elucidate biochemical mechanisms and signal the early onset of disease. Overexpression of the peripheral benzodiazepine receptor (PBR) has been observed in a variety disease states, including glioblastoma, breast cancer, and Alzheimer's disease. Thus, the PBR could be an attractive target for molecular imaging. In this paper, the authors report cellular uptake and multimodal (MRI and fluorescence) imaging of PBR-overexpressing C6 glioblastoma (brain cancer) cells using a cocktail administration approach and a new PBR targeted lanthanide chelate molecular imaging agent.     

Action cross sections of two-photon excited luminescence of some Eu(III) and Tb(III) complexes.

Four different luminescent lanthanide complexes have been studied with respect to multiphoton excitation using near-infrared femtosecond pulses. The method for measuring action cross sections of two-photon excited fluorescence in solution relative to a known standard is reviewed. Two refractive index-related corrections are necessary in this method: one for the multiphoton excitation process, the other for the collection of the emitted light. It has been found that (2,4,6-trimethoxyphenyl)dipicolinic acid and Michler's ketone are reasonable sensitisers of two-photon excited lanthanide luminescence in solution, whereas dipicolinic acid and carbostyril-124 do not give rise to any detectable two-photon excited lanthanide luminescence using modest excitation powers (<20 mW focused at the sample) in the 700-1000 nm range.     

Using lanthanide ions to align troponin complexes in solution: order of lanthanide occupancy in cardiac troponin C

The potential for using paramagnetic lanthanide ions to partially align troponin C in solution as a tool for the structure determination of bound troponin I peptides has been investigated. A prerequisite for these studies is an understanding of the order of lanthanide ion occupancy in the metal binding sites of the protein. Two-dimensional [(1)H, (15)N] HSQC NMR spectroscopy has been used to examine the binding order of Ce(3+), Tb(3+), and Yb(3+) to both apo- and holo-forms of human cardiac troponin C (cTnC) and of Ce(3+) to holo-chicken skeletal troponin C (sTnC). The disappearance of cross-peak resonances in the HSQC spectrum was used to determine the order of occupation of the binding sites in both cTnC and sTnC by each lanthanide. For the lanthanides tested, the binding order follows that of the net charge of the binding site residues from most to least negative; the N-domain calcium binding sites are the first to be filled followed by the C-domain sites. Given this binding order for lanthanide ions, it was demonstrated that it is possible to create a cTnC species with one lanthanide in the N-domain site and two Ca(2+) ions in the C-domain binding sites. By using the species cTnC.Yb(3+).2 Ca(2+) it was possible to confer partial alignment on a bound human cardiac troponin I (cTnI) peptide. Residual dipolar couplings (RDCs) were measured for the resonances in the bound (15)N-labeled cTnI(129-148) by using two-dimensional [(1)H, (15)N] inphase antiphase (IPAP) NMR spectroscopy.     

Synthesis of nonluminescent lanthanide(III) chelates tethered to an aminooxy group and their applicability to biomolecule derivatization

Synthesis of nonluminescent lanthanide(III) chelates tethered to an aminooxy group (i.e., 1-[4-(6-aminooxyhexamido)benzyl]diethylenetriaminetetraacetic acid lanthanides(III), 6a-d, where Ln(3+) is Eu, Dy, Sm, and Tb) is described. Their applicability to biomolecule derivatization is demonstrated by allowing them to react with a synthetic oligopeptide, a protein, two synthetic drugs, and a steroid. The oligopeptide and protein were linked to 6 after preoxidation of their N-terminal serine residues, while the drugs and the steroid reacted via their ketone functionality. Also some application data is included.     

Interaction of La (III) and Tb (III) ions with purine nucleotides: evidence for metal chelation (N-7-M-PO3) and the effect of macrochelate formation on the nucleotide sugar conformation.

The interaction of the La (III) and Tb (III) ions with adenosine-5'-monophosphate (5'-AMP), guanosine-5'-monophosphate (5'-GMP), and 2'-deoxyguanosine-5'-monophosphate (5'-dGMP) anions with metal/nucleotide ratios of 1 and 2 has been studied in aqueous solution in acidic and neutral pHs. The solid complexes were isolated and characterized by Fourier transform ir and 1H-nmr spectroscopy. The lanthanide (III)-nucleotide complexes are polymeric in nature both in the solid and aqueous solutions. In the metal-nucleotide complexes isolated from acidic solution, the nucleotide binding is via the phosphate group (inner sphere) and an indirect metal-N-7 interaction (outer-sphere) with the adenine N-1 site protonated. In the complexes obtained from neutral solution, metal chelation through the N-7 and the PO3(2-) group is prevailing. In aqueous solution, an equilibrium between the inner and outer sphere metal-nucleotide interaction has been observed. The ribose moiety shows C2'-endo/anti pucker in the free AMP anion and in the lanthanide (III)-AMP complexes, whereas the GMP anion with C2'-endo/anti sugar conformation exhibits a mixture of the C2'-endo/anti and C3'-endo/anti sugar puckers in the lanthanide (III)-GMP salts. The deoxyribose has O4'-endo/anti sugar pucker in the free dGMP anion and a C3'-endo/anti, in the lanthanide (III)-dGMP complexes.     

Structure and NIR luminescence of lanthanide(III) complexes with an organic tridentate ligand

Some lanthanide (Ln) complexes (Ln = Er, Nd, Yb) with an organic ligand, 6-diphenylamine carbonyl 2-pyridine carboxylic acid (HDPAP), have been synthesized. The crystal structure and near infrared luminescence of these complexes (Er-DPAP, Nd-DPAP and Yb-DPAP) have been investigated. The results showed that the lanthanide complexes have electroneutral structures and the near infrared (NIR) emission exhibits characteristic narrow emission of the lanthanide ions. The energy transfer mechanisms in the lanthanide complexes were discussed.     

Lanthanide octaethylprophyrins: preparation, association, and interaction with axial ligands

The synthesis of virtually all the lanthanide octaethylporphyrin complexes have been achieved by heating appropriate anhydrous lanthanide halide and octaethylporphyrin in imidazole melt at 210 degrees C for two hours. The lighter lanthanide porphyrin complexes are very susceptible to hydrolysis, the middle lanthanide porphyrin complexes are moderately stable, and the heavier lanthanide porphyrin complexes are relatively more stable to hydrolysis. Two out of four lanthanide porphyrin complexes studied in detail, namely ytterbium and lutetium octaethylporphyrins, aggregate in benzene and the Soret bands in their absorption spectra are about 6 nm shifted to higher energies upon a hundred-fold increase in their concentrations. The aggregations of these lanthanide porphyrin complexes in non-coordinating solvents have been further verified by 1H NMR spectral studies. This spectral behavior can be interpreted qualitatively in terms of the model of the molecular exciton interactions with stacking of at least two prophyrins. A dimeric structure of these lanthanide porphyrin complexes has been proposed on the basis of geometrical considerations. On the contrary, the europium and gadolinium octaethylporphyrins associate very weakly in benzene in the concentration range studied. All four lanthanide porphyrin complexes interact with pyridine and piperidine, and the Soret bands in their absorption spectra are about 8 nm shifted to low energies as compared with their values in pure benzene.     

Lanthanide porphyrin probes of heme proteins. Insertion of ytterbium (III) mesoporphyrin IX into apomyoglobin.

Apomyoglobin has been reconstituted with the lanthanide porphyrin complex, ytterbium(III)mesoporphyrin IX. The reconstituted material exhibits absorption and magnetic circular dichroic spectra significantly different from those of the ytterbium porphyrin itself. The sizeable, positive extrinsic Cotton effect in the Soret band of Yb-mesoporphyrin IX induced by the interactions with the globin indicates that the lanthanide porphyrin complex occupies the heme crevice.     

An investigation into lanthanide–lanthanide magnetic interactions in a series of [Ln2(mdeaH2)2(piv)6] dimers

A series of six isostructural lanthanide dimers of general formula [Ln₂(mdeaH₂)₂(piv)₆], where mdeaH₂ is N-methyldiethanolamine, piv is pivalate, and Ln = La, Ce, Pr, Nd, Sm, and Gd, has been surveyed to gauge the nature of the magnetic interactions between the lanthanide centres. Single-crystal X-ray structure analyses indicate that the lanthanides are connected by syn,syn-carboxylate bridges. It was found from an analysis of their bulk magnetic susceptibilities as a function of temperature that this type of bridge mediates vanishingly small magnetic interactions. This finding is important in the context of developing synthetic strategies for the preparation of new molecular based magnetic materials.     

A possible calcium binding site in D1 protein: A fluorescence and FTIR study of the interaction between lanthanides and a synthetic peptide

A peptide ranging from residue 229 to 240 of the D₁ protein of Photosystem (PS) II was synthesized and lanthanides were used as candidates of calcium. Fluorescence and FTIR spectroscopy were used to test the conformational adaptation after lanthanide additions. Fluorescence spectroscopy showed that the synthetic peptide provides lanthanide binding site, and that glutamic acids are involved in lanthanide binding. Resolution enhancement techniques were combined with band curve-fitting procedures to quantitate the FTIR spectral information from the amide 1 bands. The relative areas of these component bands indicate that lanthanide induced a substantial decrease in the amount of unordered structure and turns, while a corresponding increase in the amount of -helix and open loop was also observed. This indicates that a relatively compact structure of the synthetic peptide is formed if lanthanides are applied. The results may reflect on the physiological and biochemical function of calcium in PS II, including preventing D₁ from trypsin digestion.Abbreviations DCMU 3-(3,4-Dichlorophenyl)-1,1-dimethylurea - FTIR Fourier transform infrared - FSD Fourier self-deconvolution - PS Photosystem - Q_B Secondary plastoquinone electron acceptor of PS II     

Survey of factors determining the circularly polarised luminescence of macrocyclic lanthanide complexes in solution

The development of emissive lanthanide complexes as structural or reactive probes to signal changes in their local chiral or ionic environment has been inhibited by the lack of understanding of correlating structural and electronic spectral information. The definition of relatively rigid enantiopure macrocyclic lanthanide complexes, whose inter- and intramolecular exchange dynamics have been defined, offers scope for remedying this situation. Chiral axially symmetric lanthanide complexes in solution give rise to large emission dissymmetry values (g(em)) in CPL spectra. The sign and magnitude of g(em) are determined by the degree of twist about the principal axis, which is predicted to be a maximum at +/-22.5 degrees, and by the site symmetry and local ligand field. In particular, the polarisability of the ligand donor atoms, especially for any axial donor, is very important. Examples of each case are discussed for structurally related cationic Eu(III) complexes.     

Enzyme-amplified lanthanide luminescence for enzyme detection in bioanalytical assays

Enzyme-amplified lanthanide luminescence (EALL) is a new method which has been developed for enzymatically amplified signal detection in ultrasensitive bioanalytical assays where an enzyme is used as label or is itself the analyte of interest. Signal generation is performed by enzymatically transforming a substrate into a product which forms a luminescent lanthanide chelate; the product chelate can then be detected using time-resolved or normal fluorescence methods. Alkaline phosphatase substrates have been developed and demonstrated in a model immunoassay in microwell format. The method has also been demonstrated for detection of a variety of other hydrolytic and oxidative enzymes. Thus the EALL method shows promise for use in a wide variety of bioanalytical applications.     

From synthetic antigens to synthetic vaccines

The availability of synthetic antigens permitted a systematic elucidation of the molecular basis of antigenicity, as well as of other phenomena, and to establish the genetic control of immune response and its link to the major histocompatibility region of the species. Moreover, it allowed a conceptual approach to production of vaccines made up of synthetic fragments of relevant virus antigens. This was first demonstrated with a bacteriophage, MS-2, that can be efficiently inactivated with antibodies obtained with an immunogen in which a synthetic peptide corresponding to a sequence of 20 amino acid residues within its coat protein was covalently linked to a polymeric synthetic carrier. When the synthetic adjuvant N-acetyl-muramyl-L-alanyl-D-isoglutamine (MDP) was chemically linked to the same molecule, the resulting immunogen was effective in aqueous solution. This approach has now been used for diphtheria: a synthetic peptide from the A-chain of the toxin, covalently attached together with MDP to the synthetic carrier multichain poly(DL-alanine) induced antibodies cross-reactive with the diphtheria toxin as well as protection against the dermonecrotic activity of the toxin. A similar approach has been described also by R. Arnon and her colleagues in our laboratory for influenza virus, making use of a peptide with sequence 91–108 of the hemagglutinin of type A H₃N₂ strains attached to tetanus toxoid. The results indicated that the conjugate led to partial protection against A/Texas mouse-adapted influenza virus.     

Synthesis of affinity-label chelates: a novel synthetic method of coupling ethylenediaminetetraacetic acid to amine functional groups

An affinity-label chelate for the enzyme trypsin was synthesized by a novel synthetic technique which takes advantage of the presence of a dangling carboxylate arm in the [Co(EDTA)Cl]2- complex anion. The dangling carboxylate group was coupled to the amino group of p-aminobenzamidine, an effective inhibitor of trypsin activity, via the carbodiimmide reaction to produce a trypsin affinity label at one end and a strong EDTA-like chelating agent at the other, coupled through an amide bond. The cobalt ion can be removed if desired by reduction with Fe2+ + ascorbate, and alternate metal ions inserted in its place. The reaction is general, and affinity labels which contain amino groups can be easily coupled via this procedure, allowing the introduction of a paramagnetic or fluorescent probe into a protein or nucleotide system. The same method has been used to prepare a highly effective chelating gel which is capable of removing calcium and lanthanide ions from the binding protein parvalbumin.     

Affinity chromatography using enzymatically synthesized nucleotide-containing DNA binding polymers

A series of nucleotide-containing polyphenols has been synthesized by a simple, two-step enzymatic method. The binding properties of these synthetic polymers to complementary oligonucleotides have been evaluated using a commercially available oligo(dT)cellulose column. Complementary synthetic nucleosides were retained on this column to a greater extent than non-complementary synthetic nucleosides. These results suggest that the synthetic nucleosides prepared via this two-step enzymatic approach may have application as affinity matrices.