Triple-helical polynucleotides. Mixed triplexes of the poly(uridylic acid)-poly(adenylic acid)-poly(uridylic acid) class

By the techniques of interferon induction in primary rabbit kidney cells "superinduced" with metabolic inhibitors, ultraviolet absorbance-temperature profiles, sensitivity to pancreatic ribonuclease A, and sucrose velocity gradient ultracentrifugation, a number of reactions between double-helical RNA and single-stranded RNA or DNA homopolymers were investigated. The polymers involved in these studies were poly(adenylic acid), poly(uridylic acid), poly(ribothymidylic acid), poly(5-bromouridylic acid), poly(deoxythymidylic acid), poly(deoxyuridylic acid), poly(3-methyluridylic acid), poly(2'-O-methyluridylic acid), and poly(2'-azido-2'-deoxyuridylic acid). Two different reaction courses, both leading to the formation of triple helices, were noted: (1) poly(Ux)-poly(A) + poly(Uy) leads to poly(Ux)-poly(A)-poly(Uy) if the Tm of poly(Ux)-poly(A) was higher than the Tm of poly(Uy)-poly(A); (2) poly(Ux)-poly(A) + poly(Uy) leads to poly(Uy)-poly(A)-poly(Ux) if the Tm of poly(Ux)-poly(A) was lower than the Tm of poly(Uy)-poly(A). In these equations, the homopolymer written to the left of poly(A) implies Watson-Crick hydrogen bonding whereas the polymer to the right of poly(A) is involved in Hoogsteen hydrogen bonding.     

Polynucleotide displacement reactions: detection by interferon induction

A large variety of displacement reactions between homopolynucleotides and complexes thereof has been demonstrated by interferon induction data obtained in primary rabbit kidney cell cultures superinduced with metabolic inhibitors. The polymers involved in these helix-coil displacement studies were: poly(adenylic acid), poly(inosinic acid), poly(cytidylic acid), poly(uridylic acid), poly(ribothymidylic acid), polylaurusin, poly(7-deazaadenylic acid), poly(7-deazainosinic acid), poly(5-bromocytidylic acid), and poly(5-bromouridylic acid). As monitored by ultraviolet absorbance-temperature profiles, all displacement reactions were directed toward the formation of the helix with the higher thermal stability. Concomitantly, the resulting helix was invariably more active as interferon inducer than the reactant helix, except for some reactions in which poly(7-deazaadenylic acid) was involved. For the latter reactions both the reactant and resultant helices were inactive as interferon inducer. The interferon induction data revealed that all displacement reactions proceeded to completion within 1 h even at temperatures well below the Tm of the reactant helix. The helix-coil displacement reaction could also be monitored by sucrose velocity gradient analysis, and, as evidenced for poly(A)-2poly(I) + 2poly(C) leads to 2poly(I)-poly(C) + poly(A), readily occurred at the cellular level, presumably at the cell surface.     

Varied effects of polyadenylic-polyuridylic acid on immune responses

The effect of the double-stranded synthetic polynucleotide, poly(A).poly(U), on the immune response of inbred mouse strains to multichain synthetic polypeptides was studied. Poly(A).poly(U) did not affect immune responses controlled by H-2 linked genes. Thus, when either (T,G)-A- -L or (Phe,G)-A--L were injected into high or low responder mice followed by administration of poly(A).poly(U) 24 h after immunization, no increase in the antibody titers was observed. In contrast, poly(A).poly(U) increased significantly the response to polyproline, which is controlled by a non H-2 linked gene, in low responder mice. However, the polyribonucleotide had no effect on the antibody titers of the SJL mice, the high responders to multichain polyproline. When poly(A).poly(U) was injected into DBA/1 mice following immunization with (Phe,G)-Pro- -L, the polynucleotide enhanced the low response to the Pro- -l region at the expense of the anti (Phe,G) response which is normally high in this mouse strain. In this case poly(A).poly(U) caused an intramolecular antigenic competition. The general conclusion of this study is that the chemical nature of the antigenic determinant plays an important role in determining the type of influence exerted by poly(A).poly(U).     

Polynucleotides. XLV Synthesis and properties of poly(2'-azido-2'-deoxyinosinic acid)

Poly (2'-azido-2'-deoxyinosinic acid), [poly (Iz)], was synthesized from 2'-azido-2'-deoxyinosine diphosphate by the action of polynucleotide phosphorylase. Poly (Iz) has UV absorption properties similar to poly (I) and hypochromicity of 11% at 0.15M Na+ and neutrality. In solutions of high Na+ ion concentration, poly (Iz) forms a multi-stranded complex and its Tm at 1.0M Na+ ion concentration was 43 degrees. Upon mixing with poly (C), poly (Iz) forms a 1:1 complex having a Tm lower than that of poly (I)-poly (C) complex in the same conditions. The effect of substitution at the 2'-position of the poly (I) strand was discussed in relation to the interferon-inducing activity.     

1H-15N NMR signal assignment and secondary structure of bacteriorhodopsin (1-231) in solution

15N-Labeled de-(232-248)-bacteriorhodopsin [BR(1-231)] was solubilized in 1:1 chloroform-methanol solvent mixture that contained 1.0 M 2HCO2N2H4 and mimic membrane medium. Resonances in the 1H-15N heteronuclear multiple-quantum coherence (HMQC) spectrum of BR (1-231) were assigned using the data of two- and three-dimensional NMR experiments. Of 117 cross-peaks present in the 1H-15N HMQC spectrum, 98 were assigned to residues in 1-75 and 193-231 segments of the protein. Almost all cross-peaks that correspond to the 76-192 segment were absent in the HMQC spectrum (except for six cross-peaks from the side chains and 14 cross-peaks from the backbone). Deuterium exchange rates of amide protons and cross-peaks of nuclear Overhauser effect helped to localize helices A (residues 8-30), B (residues 40-65), and G (residues 198-226). The periodicity in the rates of deuterium exchange of NH protons of helices A, B, and G was explained by the compact arrangement of these helices in the protein globule. The broadening of signals from six residues in helix G, which, according to the electron cryomicroscopy model of bacteriorhodopsin, is in contact with the NMR-unobservable bundle of helices CDEF, indicates specific interactions of the helices in BR(1-231). These data suggest that BR(1-231) solubilized in an organic medium has a spatial structure similar to that in the electron cryomicroscopy model of BR.     

Neomycin, spermine and hexaamminecobalt (III) share common structural motifs in converting B- to A-DNA

The (dG)n.(dC)n-containing 34mer DNA duplex [d(A2G15C15T2)]2 can be effectively converted from the B-DNA to the A-DNA conformation by neomycin, spermine and Co(NH3)6(3+). Conversion is demonstrated by a characteristic red shift in the circular dichroism spectra and dramatic NMR spectral changes in chemical shifts. Additional support comes from the substantially stronger CH6/GH8-H3'NOE intensities of the ligand-DNA complexes than those from the native DNA duplex. Such changes are consistent with a deoxyribose pucker transition from the predominate C2'-endo (S-type) to the C3'-endo (N-type). The changes for all three ligand-DNA complexes are identical, suggesting that those three complex cations share common structural motifs for the B- to A-DNA conversion. The A-DNA structure of the 4:1 complex of Co(NH3)6(3+)/d(ACCCGCGGGT) has been analyzed by NOE-restrained refinement. The structural basis of the transition may be related to the closeness of the two negatively charged sugar-phosphate backbones along the major groove in A-DNA, which can be effectively neutralized by the multivalent positively charged amine functions of these ligands. In addition, ligands like spermine or Co(NH3)6(3+) can adhere to guanine bases in the deep major groove of the double helix, as is evident from the significant direct NOE cross-peaks from the protons of Co(NH3)6(3+) to GH8, GH1 (imino) and CH4 (amino) protons. Our results point to future directions in preparing more potent derivatives of Co(NH3)6(3+) for RNA binding or the induction of A-DNA.     

Temperature effects on the structure of poly(dA).poly(dT): an X-ray fiber diffraction study

X-ray fiber diffraction of poly(dA).poly(dT) subjected to variation in the relative humidity, has allowed us to demonstrate the effects of temperature on the conformation of the polynucleotide. When the temperature of the poly(dA).poly(dT) is greater than 30 degrees C and the relative humidity near 80%, a new diffraction pattern is obtained. We observe a transition between the classical alpha B' form of poly(dA).poly(dT) and a double helical structure, B*, which remains stable at a temperature up to 70 degrees C. This new conformation of poly(dA).poly(dT) is a right-handed double helix with 11.4 nucleotide pairs per turn and a pitch of 36.7 A.     

Structure of poly d(AI).poly d(CT) in two different packing arrangements

X-ray diffraction analysis of poly d(AI).poly d(CT) in oriented and polycrystalline fibers has revealed the DNA structure to be a 10-fold, right-handed, antiparallel, Watson-Crick base paired double helix in two distinct packing arrangements corresponding to one and two helices, respectively, in the unit cell. The helix pitch is 32.1 A and 32.4 A in the two cases, almost 1.5 A shorter than in classical B-DNA. The resulting B'-DNA geometry, described in terms of a tetranucleotide repeat which is conformationally similar to B-DNA, has its minor groove closely shut and major groove correspondingly widened, thus striking a sharp morphological contrast to B-DNA. According to difference electron density maps, a spine of hydration along the minor groove connects both strands and provides structural stability; ordered sodium ions and water molecules are actively involved in bridging the phosphate groups of neighboring helices. The crystallographic R-values for these two allomorphs are 0.26 and 0.20, respectively, for data up to 3.0 A resolution.     

DNA structural features responsible for sequence-dependent binding geometries of Hoechst 33258

The complexes of Hoechst 33258 with poly[d(A-T)2], poly[d(I-C)2], and poly[d(G-C)2], and poly[d(G-m5C)2] were studied using linear dichroism, CD, and fluorescence spectroscopies. The Hoechst-poly[d(I-C)2] complex, in which there is no guanine amino group protruding in the minor groove, exhibits spectroscopic properties that are very similar to those of the Hoechst-poly[d(A-T)2] complex. When bound to both of these polynucleotides, Hoechst exhibits an average orientation angle of near 45 degrees relative to the DNA helix axis for the long-axis polarized low-energy transition, a relatively strong positive induced CD, and a strong increase in fluorescence intensity--leading us to conclude that this molecule also binds in the minor groove of poly[d(I-C)2]. By contrast, when bound to poly[d(G-C)2] and poly[d(G-m5C)2], Hoechst shows a distinctively different behavior. The strongly negative reduced linear dichroism in the ligand absorption region is consistent with a model in which part of the Hoechst chromophore is intercalculated between DNA bases. From the low drug:base ratio onset of excitonic effects in the CD and fluorescence emission spectra, it is inferred that another part of the Hoechst molecule may sit in the major groove of poly[d(G-C)2] and poly[d(G-m5C)2] and preferentially stacks into dimers, though this tendency is strongly reduced for the latter polynucleotide. Based on these results, the importance of the interactions of Hoechst with the exocyclic amino group of guanine and the methyl group of cytosine in determining the binding modes are discussed.     

Synthesis, Characterization and Fluorescence of Terbium(Ⅲ) Complexes with Phenylglyoxylic Acid and 2,2-Dipyridine, 1,10-Phenanthroline, Triphenyl Phosphine Oxide

Three new complexes TbL3dipy(H2O)2, TbL3phen(H2O)2 and TbL2(TPPO)2NO3 were synthesized (L=phenylglyoxylate ion, dipy=2,2-dipyridine, phen=1,10-phenanthroline, TPPO=Triphenyl phosphine oxide).Elemental analysis, conductivity, IR spectra, and 1HNMR spectra studies were performed.IR spectra indicate that the carboxylate ion of phenylglyoxylate is coordinated to the Tb(Ⅲ) ion as an unidentate ligand.In 1HNMR, the signals of different hydrogens in phenylglyoxylate ion shift upfield.The excitation and emission spectra of the three solid complexes were recorded at room temperature, in which the optimum excitation wavelengths are 361.0, 359.0 and 367.0 nm for these three complexes, respectively.Four emission bands due to the 5D4-7Fj(j=6, 5, 4, 3) transitions were observed for TbL3dipy(H2O)2 (489.0, 545.0, 584.0, 620.0 nm) and TbL3phen(H2O)2 (490.0, 544.0, 583.0, 620.0 nm).Under the same conditions, only one emission band due to the 5D4-7F5 transition was observed for the complex TbL2(TPPO)2NO3.The emission intensity of TbL3dipy(H2O)2 is the strongest among the three complexes.     

Triple helix formation by (G,A)-containing oligonucleotides: asymmetric sequence effect

Sequence effects on the stability of purine-motif (also called (G, A)-motif) triple helix have been investigated through two symmetry-related systems: one of them had a 5'(GGA)43' core sequence of triplex-forming oligonucleotides (TFOs), whereas the other one had a reversed 5'(AGG)43' core sequence. These (G,A)-containing TFOs were prone to self-associate into intermolecular complexes at room temperature. The competition of TFOs' self-association with triple helix formation was assessed, and minimized. By varying the lengths and the terminal base sequences of TFOs, the following were found that (1) The stability of two triple helices with identical length and base composition but reverse strand orientation may be significantly different (up to a factor of 6). (2) When the 5'(GGA)43' core sequence was extended at the 3'-end by a G, the 13-nt TFO exhibited 3- and 5-fold higher affinity toward the target double-stranded DNA (dsDNA) than the longer 14-nt and 15-nt TFOs in which one and two A(s) were added at the 3'-end of the 13-nt TFO, respectively. In contrast, when the similar extensions occurred at the 5'-end of the 5'(AGG)43' core sequence, the length increase provided a higher binding affinity of TFOs toward the target duplex. (3) The nature of the base triplets involved at the ends of triple helices may have great influence on triplex stability. The observed asymmetric sequence effect of the (G,A)-motif triple helix formation is discussed in terms of the binding strength of the first base triplet(s) at the 3' end which seems to be deeply involved in the nucleation step of triple helix formation and therefore to be a determining factor for triplex stability.     

Design, synthesis and conformational analysis of hGM-CSF(13-31)-Gly-Pro-Gly-(103-116)

On the basis of the X-ray structure and results from structure-activity relationship studies, the following GM-CSF analogue was designed and synthesized by solid-phase methodology: hGM-CSF[13-31]-Gly-Pro-Gly-[103-116]-NH2. This analogue was constructed to comprise helices A and D of the native hGM-CSF, covalently linked in an antiparallel orientation by the tripeptide spacer Gly-Pro-Gly, which is known as a turn-inducing sequence. The conformational analysis of the analogue by CD spectroscopy revealed an essentially random structure in water, while alpha-helix formation was observed upon addition of TFE. In 40% TFE the helix content was approximately 45%. By two-dimensional NMR experiments in 1:1 water/trifluoroethanol mixture two helical sequences were identified comprising the segments corresponding to helix A and helix D. In addition to medium-range NOESY connectivities, a long-range cross-peak was found involving the leucine residues at positions 13 and 35. Based on the experimentally derived data (54 NOEs), the structure was refined by restrained molecular dynamics simulations over 120 ps at various temperatures. A representative conformation derived from the computer simulation is mainly characterized by two helical segments connected by a loop region. The overall three-dimensional structure of the analogue is comparable to the X-ray structure of hGM-CSF in that helices A and D are oriented in an antiparallel fashion, forming a two alpha-helix bundle. Nevertheless, there are small differences in the topology of the helices between the solution structure of the designed analogue and the X-ray structure of hGM-CSF. The possible implications of these conformational features at the effects of biological activity are discussed.     

Poly-2'-deoxy-2'-fluoro-cytidylic acid: enzymatic synthesis, spectroscopic characterization and interaction with poly-inosinic acid

The polymerization of 2'deoxy-2'-fluoro-cytidine-diphosphate (dCflDP) by polynucleotide phosphorylase is barely detectable in the presence of Mg++ under usual experimental conditions for polymerization of nucleoside diphosphates. High concentrations of enzyme have to be used to accomplish the synthesis. Mn++ is a better activator than Mg++ for the reaction. cCflDP inhibits the polymerization of CDP and has a Km=8.8X10-3M, six times higher than CDP.- The polymer, poly (dCfl), ressembles in many respects poly(C), but not poly(dC): the acid selfstructure forms at similar pK's; interaction with poly(I) yields a 1:1 complex the CD spectrum of which is similar to that of poly(I).poly(C). Finally, the Tm's of poly(I).poly(dCfl) are comparable to those of poly(I).poly(C).     

Mode of action of the anti-AIDS compound poly(I).poly(C12U) (Ampligen): activator of 2',5'-oligoadenylate synthetase and double-stranded RNA-dependent kinase

The mismatched double-stranded RNA (dsRNA), poly(I).poly(C12U), also termed Ampligen, exhibits a strong antiviral and cytoprotective effect on cells (human T-lymphoblastoid CEM cells and human T-cell line H9) infected with the human immunodeficiency virus type 1 (HIV-1). Untreated H9 cells infected with HIV-1 start to release the virus 3 days post-infection, while in the presence of 40 micrograms/ml (80 micrograms/ml) of poly(I).poly(C12U) the onset of virus production and release is retarded and does not occur before day 5 (day 6). We demonstrate that poly(I).poly(C12U) markedly extends the duration of the transient increase of 2',5'-oligoadenylate (2-5A) synthetase mRNA level and activity preceding virus production after infection of cells with HIV-1. Treatment of HeLa cells with poly(I).poly(C12U) was found to cause a significant increase in total (activated plus latent) 2-5A synthetase activity; no evidence was obtained that the level of latent (nonactivated) 2-5A synthetase is changed in cells treated with dsRNA plus interferon (IFN). Poly(I).poly(C12U) is able to bind and to activate 2-5A synthetase(s) from HeLa cell extracts. Addition of poly(I).poly(C12U) to HeLa cell extracts results in production of longer 2-5A oligomers (> or = 3 adenylate residues), which are better activators of RNase L. Both free and immobilized poly(I).poly(C12U) also bind to the dsRNA-dependent protein kinase (p68 kinase), resulting in autophosphorylation of the enzyme. Activation of the kinase by the free RNA occurs within a limited concentration range (10(-7) to 10(-6) grams/ml). Addition of HIV-1 Tat protein does not affect binding and activation of p68 kinase to poly(I).poly(C12U)-cellulose but strongly reduces the binding of the kinase to immobilized TAR RNA of HIV-1. We conclude that poly(I).poly(C12U) may antagonize Tat-mediated down-regulation of dsRNA-dependent enzymes.     

Capping interactions in isolated alpha helices: position-dependent substitution effects and structure of a serine-capped peptide helix

The influence of an amino acid on the stability of alpha-helical structure depends on the position of the residue in the helix with respect to the ends. Short alpha helices in proteins are stabilized both by H-bonding of the main-chain NH and CO groups and by capping interactions between side chains and unfulfilled peptide groups at the N and C termini. Peptide models based on consensus position-dependent helix sequences allow one to model capping effects in isolated helices and to establish a base line for these interactions in proteins. We report here an extended series of substitutions in the cap positions of our peptide models and the solution structure of peptide S3, with serine at the N-cap position defined as the N-terminal residue with partly helix and partly coil conformation. The resulting model, determined by 2D 1H NMR, is consistent with a structure at the N-cap involving H-bonding between the serine gamma oxygen and the peptide NH of the glutamic acid residue three amino acids toward the C terminus. A bifurcated H-bond of Ser O gamma with the NH of Asp5 is possible also, since this group is within interacting distance. This provides direct evidence that specific side-chain interactions with the main chain stabilize isolated alpha-helical structure.     

Synthesis and conformational study of peptides possessing helically arranged delta ZPhe side chains

Z-Dehydrophenylalanine (delta ZPhe) possessing four oligopeptides, Boc-(L-Ala-delta ZPhe-Aib)n-OCH3 (n = 1-4: Boc, t-butoxycarbonyl; Aib, alpha-aminoisobutyric acid), were synthesized, and their solution conformations were investigated by 1H-nmr, ir, uv, and CD spectroscopy and theoretical CD calculation. 1H-nmr (the solvent accessibility of NH groups) and ir studies indicated that all the NH groups except for those belonging to the N-terminal L-Ala-delta ZPhe moiety participate in intramolecular hydrogen bonding in chloroform. This suggests that the peptides n = 2-4 have a 4-->1 hydrogen-bonding pattern characteristic of 3(10)-helical structures. The uv spectra of all these peptides recorded in chloroform and in trimethyl phosphate showed an intense maximum around 276 nm assigned to the delta ZPhe chromophores. The corresponding CD spectra of the peptides n = 2-4 showed exciton couplets with a negative peak at longer wavelengths, whereas that of the peptide n = 1 showed only weak signals. Theoretical CD spectra were calculated for the peptides n = 2-4 of several helical conformations, on the basis of exciton chirality method. This calculation indicated that the three peptides form a helical conformation deviating from the perfect 3(10)-helix that contains three residues per turn, and that their side chains of delta ZPhe residues are arranged regularly along the helix. The center-to-center distance between the nearest phenyl pair(s) was estimated to be approximately 5.5 A. The chemical shifts of the delta ZPhe side-chain protons (H beta and aromatic H) for the peptides n = 2-4 indicated anisotropic shielding effect of neighboring phenyl group (s); the effect also supports a regular arrangement of the delta ZPhe side chains along the helical axis.     

Accommodation of insertions in helices: the mutation in hemoglobin Catonsville (Pro 37 alpha-Glu-Thr 38 alpha) generates a 3(10)-->alpha bulge

Hemoglobin Catonsville is a mutation of human hemoglobin (an alpha 2 beta 2 tetramer) in which a glutamate residue is inserted into the first turn of a highly conserved 3(10) helix (the C helix) of each alpha subunit. In theory, amino acid insertions (or deletions) in protein helices can be accommodated via two distinct mechanisms. One, termed the register shift mechanism, preserves the geometry of the helix while requiring all of the residues on one flank of the insertion site to rotate by 100 degrees in the case of an alpha helix or by 120 degrees in the case of a 3(10) helix. The other, termed the bulge (or indentation) mechanism, distorts the local geometry of the helix but does not alter the helix register. High-resolution X-ray diffraction analysis of deoxyhemoglobin Catonsville shows that the inserted residue is accommodated as a bulge, demonstrating that this is a viable mechanism. (In contrast, no such evidence is yet available for the register shift mechanism.) More specifically, the insertion converts one turn of the C helix from 3(10) geometry to alpha helix-like geometry, raising the possibility that a common mechanism for accommodating insertions and deletions within helices may involve localized interconversions between 3(10), alpha, and pi helical structures.     

Conformation and ion-channeling activity of a 27-residue peptide modeled on the single-transmembrane segment of the IsK (minK) protein

IsK (minK) protein, in concert with another channel protein KVLQT1, mediates a distinct, slowly activating, voltage-gated potassium current across certain mammalian cell membranes. Site-directed mutational studies have led to the proposal that the single transmembrane segment of IsK participates in the pore of the potassium channel [Takumi, T. (1993) News Physiol. Sci. 8, 175-178]. We present functional and structural studies of a short peptide (K27) with primary structure NH2-1KLEALYILMVLGFFGFFTLGIMLSYI27R-COOH, corresponding to the transmembrane segment of IsK (residues 42-68). When K27 was incorporated, at low concentrations, into phosphatidylethanolamine, black-lipid membranes, single-channel activity was observed, with no strong ion selectivity. IR measurements reveal the peptide has a predominantly helical conformation in the membrane. The atomic resolution structure of the helix has been established by high-resolution 1H NMR spectroscopy studies. These studies were carried out in a solvent comprising 86% v/v 1,1,1,3,3,3-hexafluoro-isopropanol-14% v/v water, in which the IR spectrum of the peptide was found to be very similar to that observed in the bilayer. The NMR studies have established that residues 1-3 are disordered, while residues 4-27 have an alpha-helical conformation, the helix being looser near the termini and more stable in the central region of the molecule. The length (2. 6 nm) of the hydrophobic segment of the helix, residues 7-23, matches the span of the hydrocarbon chains (2.3 +/- 0.25 nm) of fully hydrated bilayers of phosphatidylcholine lipid mixture from egg yolk. The side chains on the helix surface are predominantly hydrophobic, consistent with a transmembrane location of the helix. The ion-channeling activity is believed to stem from long-lived aggregates of these helices. The aggregation is mediated by the pi-pi stacking of phenylalanine aromatic rings of adjacent helices and favorable interactions of the opposing aliphatic-like side chains, such as leucine and methionine, with the lipid chains of the bilayer. This mechanism is in keeping with site-directed mutational studies which suggest that the transmembrane segment of IsK is an integral part of the pore of the potassium channel and has a similar disposition to that in the peptide model system.     

Syntheses and Characterization of Binuclear Complexes Tb（1-x）Eux（TTA）3 Phen

Rare earth ternary complexes Tb1-xEux（TTA）3Phen（x=0,0.25,0.5,0.75,1.0）were synthesized and characterized by DTA-TG,XRD and infrared（IR）.The photophysical properties of these complexes were studied in detail using ultraviolet absorption spectra and fluorescent spectra.Ultraviolet absorption showed that the energy absorption of the complexes mostly came from ligands.Infrared spectra of Tb1-xEux（TTA）3Phen complexes were similar to the pure complexes.TG curves proved that the complexes were stable.Tb3＋ emission was almost quenched and the Eu3＋ emission was enhanced by codoping the complexes.The Tb3＋ ion acted as an energy transfer bridge that helped energy transfer from poly（N-vinylcar-bazole（PVK）to Eu3＋.In addition,their PL and EL properties were systematically studied.