Conformations of model compounds of proteins. II. Infrared spectra of N-acetyl-amino acid methylamides

N-Acetyl-amino acid methylamides CH₃CONHCHRCONHCH₃ were prepared from L - and DL -alanine, L and DL -α-amino-n-butyric acid, L - and DL -norvaline, DL -norleucine, L - and DL -methionine, L - and DL -leucine, L -aspartic acid and DL -phenylalanine. The deuterium homologs of the type CH₃CONDCHRCONDCH₃, CD₃CONHCHRCONHCH₃, and CH₃CONHCHRCONHCD₃ were also prepared. The infrared spectra of these compounds were measured down to 300 cm^?1 in the crystalline state. The infrared spectra of N-isopropylacetamide CH₃CONHCH(CH₃)₂, N-methylisobutyramide (CH₃)₂CHCONHCH₃ and their deuterium homologs were also measured. The C?O in-plane and out-of-plane bending vibration bands of the CH₃CONHC^α group (amide IVa and VIa) and those of the –C^αCONHCH₃ group (amide IVb and VIb) were assigned from these data. Two crystalline modifications, form I and form II, were found for the compounds prepared from L -alanine, DL -leucine, L -aspartic acid and DL -phenylalanine. The two forms show quite different skeletal vibrations, which suggest, rotational isomerism. Two distinct patterns were found as to the positions of the amide IVa and VIa bands for the above compounds. The two amide bands were found near 630 and 600 cm^?1 in form I, whereas they were found near 600 cm^?1 in form II. The crystals of the remaining compounds were also classified into form I or form II on the basis of the arrangement of the amide bands. The X-ray structure analyses suggest that these two forms have different hydrogen-bond structures.     

Heterobifunctionalized tetraethylene glycol: A spacer for surface attachment of viral peptide epitopes for ELISA and derivatization of membrane modifying peptides

Summary New hydrophilic linkers of the formula Fmoc-NHCH₂CH₂COO(CH₂CH₂O)₄X (X=COCH₂CH₂COOH Fmoc-Ats (2), X=CONHCH₂COOH Fmoc-Atg (4) and X=CONHCH₂CH₂COOH Fmoc-Ata (5) have been prepared by heterobifunctional modification of tetraethylene glycol as starting material. These linkers represent a useful tool for solid phase peptide synthesis according to Fmoc/tBu strategy. Two examples are presented to illustrate the applicability of these building blocks: (i) spacing between biotin and a peptide epitope of the hepatitis C virus and evaluation in a biotin-streptavidin ELISA, and (ii) coupling of the new linker to the N- and C-terminus of the peptide antibiotic alamethicin to show eventual influences on the peptide's α-helical conformation.     

Beta-turns in serine-containing linear and cyclic models

Tetrapeptides, Cbz-Gly-X-Y-Gly-OSt ( 1 – 4 )—as well as cyclic systems, cyclo[NH-(CH₂)_n-CO-Gly-Ser(OX)-Ser(OX)-Gly] ( 5 and 6 ; n = 4 and 2, X = Bu^t or H), have been synthesized in order to compare the CD spectrum of linear and cyclic β-turn models containing either a protected or a free hydroxyl of the serine residue. In extremely dilute cyclohexane solution the linear models Cbz-Gly-Ser-Y-Gly-OSt ( 1 – 3a ) show class B spectra with very strong positive bands, contrary to other members of the series. Based on 200-MHz ¹H nuclear overhauser enhancement and Fourier transform ir studies, Cbz-Gly-Ser-Ser(OBu^t)-Gly-OSt ( 3a ) in dilute chloroform solution assumes a distorted type II β-turn conformation fixed by an extended system of intramolecular H bonds. As evidenced by ¹H-nmr and FT-IR experiments, the cyclic model cyclo[NH-(CH₂)₄-CO-Gly-Ser(OBu^t)- Ser(OBu^t)-Gly] ( 5a ) in a 1 : 1 mixture of (CD₃)₂SO-CDCl₃ is also characterized by a type II β-turn encompassing the Ser³(OBu^t)-Gly⁴ sequence. In water, a class B pattern was measured for this model, in good agreement with theoretical and experimental studies that show that type II β-turns are generally characterized by class B spectra. In the protected and free OH cyclic models, cyclo[NH-(CH₂)₂-CO-Gly-Ser(OX)-Ser(OX)-Gly] ( 5b and 6b , X = Bu^t or H) distortions of the peptide backbone due to the loss of two CH₂ groups result in the appearance of CD spectra characterized by a strong negative band near 200 nm, interpreted as a sign of the lack of β-turn structures in these models. This observation, together with other CD data discussed in this paper, clearly show that the CD of serine-containing β-turn sequences strongly depends on long-range backbone and local side-chain interactions.     

Vibrational analysis of nucleic acids. IV. normal modes of the DNA phosphodiester structure modeled by diethyl phosphate

Raman and ir spectra are reported for diethyl phosphate [(CH₃CH₂O)₂PO^-₂] and diethyl phosphate isotopomers incorporating carbon-13 at methylene group sites [(CH¹³₃CH₂O)₂PO^-₂] and deuterium substituents on methyl and methylene carbons [(CH₃CD₂O)₂PO^-₂, (CD₃CH₂O)₂PO^-₂ (CD₃CD₂O)₂PO^-₂]. The vibrational spectra are analyzed to develop a consistent set of assignments for the C-C-O-P(O^-₂)-O-C-C network, which serves as a model for the nucleic acid phosphodiester backbone. The present study resolves previously conflicting vibrational assignments for the phosphodiester skeleton and provides a firm empirical basis for interpreting conformationally sensitive modes of DNA and RNA. Ab initio vibrational analyses have also been conducted on the above isotopomers of diethyl phosphate in the trans-gauche-gauche-trans conformation, optimized using the 3-21+G^* basis set at the restricted Hartree-Fock level. The ab initio calculations are in good agreement with the empirical results, thus strengthening the proposed assignment scheme for Raman and infrared spectra. The present study provides a basis for improvement of empirical force fields utilized in previous normal coordinate analyses of the nucleic acid phosphodiester group. © 1996 John Wiley & Sons, Inc.     

Beta-turns in bridged proline-containing cyclic peptide models

The synthesis, CD, ir spectroscopic, and conformational studies of a series of bridged cyclic peptides of the general formula, cyclo[NH-(CH₂)_n-CO-Gly-Pro-Y-Gly] (2a–d, Y = Gly or Ser(OBu^t), n = 4 or 2) is reported. As indicated by difference nuclear Overhauser enhancement and Fourier transform ir experiments, the tetrapeptide sequence of cyclo[NH-(CH₂)₄-CO-Gly-Pro-Gly-Gly] (2a) and cyclo[NH-(CH₂)₂-CO-Gly-Pro-Gly-Gly] (2b) adopts a 1 ← 4 hydrogenbonded type II β-turn conformation in solution, while cyclo[NH-(CH₂)₄-CO-Gly-Pro-Ser(OBu^t) -Gly] (2c) features a type I β-turn, fixed by 1 ← 4 and O^γ … NH intramolecular H bonds. In aqueous solution 2a and 2c show class B and class C CD spectra, respectively. This is the first case reported of a typical class C CD pattern in aqueous solution for a conformationally mobile system having a type I β-turn. Based on the comparison of the band intensities of the bridged models with those of linear and cyclic model systems reported earlier, a set of subspectra with reduced band intensities is suggested for use in the CD analysis of the conformation of polypeptides in solution.     

Resonance Raman spectroscopy of chemically modified retinals: Assigning the carbon-methyl vibrations in the resonance Raman spectrum of rhodopsin

To assign the observed vibrationsl modes in the resonance Raman spectrum of the retinylidene chromophore of rhodopsin, we have studied chemically modified retinals. The series of analogs investigated are the n-butyl retinals substituted at C₉ and C₁₃. The results obtained for the 11-cis isomer have clearly assigned the CCH₃ vibrational frequencies observed in the spectrum of the retinylidene chromophore. The data show that the C₍₉₎CH₃ stretching vibration can be assigned to the vibrational mode observed in the 1017 cm^?1 region, and the vibration detected at 997 cm^?1 can be assigned to the C₍₁₃CH₃ vibration. The C₍₅₎CH₃ stretching mode does not contribute to the vibrations observed in this region. The splitting in the C_(n)CH₃ (n = 9, 13) vibration is characteristic of the 11-cis conformation. The results on the modified retinals do not support the hypothesis that the splitting arises from equilibrium mixtures of 11-cis, 12-s-cis and 11-cis, 12-s-trans in solution. Thus, this splitting cannot be used to determine whether the chromophore in rhodopsin is in a 12-s-cis or 12-s-trans conformation. However, our results demonstrate that there are other vibrational modes in the spectra which are sensitive to this conformational equilibrium and we use the presence of a strong ~ 1271 cm^?1 mode in bovine and squid rhodopsin spectra as an indication that the chromophore in these pigments is 11-cis, 12-s-trans.     

Circular dichroism spectra of bradykinin analogs containing β-homoamino acids

The CD spectra of β-homoprolyl⁷-bradykinin (βHProB) and β-homophenylalanyl⁸-bradykinin (βHPheB) were compared to those of bradykinin. The spectra were analyzed in terms of models that have been proposed for the solution conformation of bradykinin. Cann $\text{et al}$. (1) proposed 3 → 1 hydrogen-bonding across Pro³, Pro⁷ and Phe⁸ in bradykinin, as shown by a 234 nm trough in the CD. The extra CH₂ groups in the chains of the two bradykinin analogs would be expected to facilitate the proposed hydrogen-bonding, but in the case of βHProB the 234 nm trough is eliminated, and is reduced in magnitude for βHPheB. Ivanov $\text{et al}$. (2) proposed a cyclic conformation for bradykinin, stabilized by ionic attraction between the side-chain of Arg¹ and the carboxylate terminal. The extra CH₂ groups of these two analogs would be expected to increase the stability of such a conformation, and there was some evidence that the ionic effects on the CD spectra of the two analogs were different from those on the bradykinin spectra. Alternatively, the effects could be attributed to cis-trans isomerizations around the prolyl peptide bonds.     

Nonactin,monactin, dinactin,trinactin, and tetranactin. A Raman spectroscopic study

Raman spectra are reported for crystalline nonactin, monactin, dinactin, trinactin, and tetranactin and their solutions in CCl₄, CHCl₃, CH₃OH, and 4:1 (v/v) CH₃OH:CHCl₃. The macrotetrolide nactins selectively bind a wide variety of cations, and are important model compounds for the study of ion complexation. The conformations of nonactin, monactin, and dinactin in solution are similar. Their conformations are found to be sufficiently open to permit the ester carbonyl groups to form hydrogen bonds with CH₃OH; this gives rise to characteristic changes in the vibration frequencies associated with the ester groups. Nonactin, which is the least soluble of the nactins in CH₃OH, is also the least effective at forming hydrogen bonds with CH₃OH. The greater ability of the higher nactins to form hydrogen bonds with CH₃OH may be due to the increased inductive effect of ethyl over methyl side chains, which may increase the dipole moment of the ester carbonyl groups. Spectra of crystalline nonactin, monactin, and tetranactin are fairly similar, while the spectra of dinactin and trinactin comprise a second, distinct family. This is consistent with X-ray crystallographic studies, which show that nonactin and tetranactin form monoclinic crystals, while trinactin is triclinic.     

Optical anisotropies of amides and peptides in dioxane

The molar Kerr constants _mK, molar refractions _mR, and dipole moments μ are reported for the N-methylacetamides CX₃CONHCH₃ (X = H, CH₃, F. CI, Br) and acetamides CX₃CONH₂ (X = H, F, Cl, Br). The components of the polarizability tensor α are deduced for N-methylacetamide and acetamide on the basis of the bond additivity approximation. This α is found to be considerably more anisotropic than was indicated in previous determinations by other methods. The data for N-methylacetamide were used to calculate _mK, μ, and γ² (anisotropy squared) of N-acetyl-N′-methylglycine amide and N-acetyl-N′-methyl-alanine amide as functions of the torsional angles (?,Ψ). The statistical mechanical averages of _mK, μ, and γ² were calculated from conformational energies obtained by the methods of Scheraga.     

Basic polypeptides as histone models. Synthesis, conformation, and interaction with DNA of statistical copolymers (Lys x,Ala y)n.

Statistical copolymers (Lys^x,Ala^y)_n were synthesized by copolymerization of N-carboxyanhydrides of L -amino acids. The conformation of copolymers in aqueous solutions was investigated using circular dichroism (CD). Calculations based on the CD data showed that polymers (Lys^x,Ala^y)_n can exhibit a random conformation, an α-helix, and a β-structure in various ratios. CD spectra of complexes of copolymers with DNA prepared by gradual dialysis from a high ionic strength to 0.15 M NaCl can be correlated with the copolymer conformation in medium and high ionic strength. For copolymers forming an α-helix and β-structure, these spectra show resemblance with similar spectra of complexes of those histones that are able to exhibit ordered conformations.     

Synthesis,conformation and biological activity of centrally modified pseudopeptidic analogues of For-Met-Leu-Phe-OMe

Summary. For-Met-βAlaψ[CSNH]-Phe-OMe (3), For-Met-βAlaψ[CH₂NH]-Phe-OMe (5), For-Met-NH-pC₆H₄-SO₂-Phe-OMe (8a), For-Met-NH-mC₆H₄-SO₂-Phe-OMe (8b) and the corresponding N-Boc precursors (2, 4, 7a, b) have been synthesized and their activity towards human neutrophils has been evaluated in comparison with that shown by the reference tripeptide For-Met-Leu-Phe-OMe (fMLF-OMe). Chemotaxis, lysozyme release and superoxide anion production have been measured. ¹H NMR titration experiments and IR spectra have been discussed in order to ascertain the preferred solution conformation adopted by the tripeptide 3 with particular reference to the presence of a folded conformation centred at the centrally positioned thionated β-residue.     

Crystal structure and a twisted β-sheet conformation of the tripeptide L-leucyl-L-leucyl-L-leucine monohydrate trimethanol solvate: Conformation analysis of tripeptides

In order to test the helical preference of short oligo-L -leucines, we crystallized the tripeptide L -leucyl-L .-leucyl-L -leucine (LLL) and carried out x-ray diffraction studies of it (L -leucyl-L -leucyl-L leucine)₂. 3CH₃OH. H₂O, (C₃₉H₈₄N₆O₁₂). Crystallized in the monoclinic system, space group P2₁, cell parameters: a = 12.031(2), b = 15.578(3), c = 14.087(2) Å, α = 90°, β = 97.29(1)°, γ = 90°, V = 2618.6 ų. MW = 829.1, D_c = 1.051 gcm^?3. R index of 0.057 for 4213 reflections (λ_cukα = 1.5418 Å) > 2σ. LLL takes tip the β-sheet rather than a helical conformation in the crystalline stale. The three methanol molecules and the water molecule that constitute the solvent of crystallization form a network of hydrogen bonds to the LLL molecules and to one another. It is rather remarkable that though A and L have stronger helical preferences than G, neither AAA nor LLL form the crystalline helix but GAL does, indicating that the helical preferences depend on the sequence context. The residue L2 in molecule A and the residues L1 and L3 of molecule B do not show the preferred conformation for forming helices. Further, very remarkably. LLL exhibits a unique super secondary feature of the protein folding topology, namely the twisted β-sheet. Where as most short peptides show only the classical p-sheet conformation. Thai even the tripeptide LLL is able to exhibit the twisted β-sheet conformation, and with the correct left-handed twist this suggests that even very short peptide segments possess the ability to assume several of the characteristic topological features exhibited by proteins. An extensive review of tripeptide conformations has been carried out and some results of this study have been included here. © 1995 John Wiley & Sons, Inc.     

Metal ion size selectivity in ligands with groups containing the neutral oxygen donor atom. A crystallographic and thermodynamic study

The coordinating properties of open-chain ligands containing alcoholic or ethereal oxygen donors are examined. Addition of oxygen donors usually leads to complex stabilisation for large metal ions (Pb²⁺, Cd²⁺) and to less favourable effects on complex stability for small metal ions (Cu²⁺, Ni²⁺). The formation constants of these metal ions with the set of ligands RN(CH₂CHOH·CH₃)₂ where R is ---H, ---CH₂CHOH·CH₃, ---CH₂CH₂OCH₃, ---CH₂CH₂OCH₂CH₂OH, and ---CH₂---CHOCH₂CH₂CH₂ are reported. The largest stabilisation for each case where R is an O-donor group relative to R = H occurs for Pb²⁺, the largest metal ion, while Cu²⁺, the smallest metal ion, shows the smallest stabilisation. The crystal structure of [Ni(HOCH₂CH₂NHCH₂CH₂NH₂)₂] (NO₃)₂ is reported. The space group is P , with cell constants a = 13.098(3), b = 8.737(4), and c = 7.746(3) Å, β = 112.66(3), β = 90.65(3), and γ = 85.03(2), and Z = 2. Disorder of the nitrate anions hindered refinement, with the result that a final conventional R factor of 0.0903 was achieved. The Ni---N bond lengths average 2.06(1) (secondary nitrogen) and 2.10(2) (primary nitrogen). The Ni---O bond lengths are rather long, averaging 2.15(1) Å, which is used to support the idea that the steric effects are responsible for destabilising the complexes of small metal ions such as Ni(11) when neutral oxygen donors are present.     

Conformational geometry and vibrational frequencies of nucleic acid chains.

Normal coordinate analysis of diethyl phosphate has been made, which predicts all observed Raman frequencies in the range 170–1300 cm^?1. The force constants from this calculation have been transferred to a vibrational calculation for a simplified model of the backbone of nucleic acids, which also involves the ? O? PO₂^?? O phosphate group and the ? C₅′? C₄′? C₃′? linkage of the ribose. The coordinates of these atoms are those recently given by Arnott and Hukins, which place the ribose ring of B-DNA in a C₃′-exo conformation. This simple polymer model appears to be able to describe adequately the frequency-dependent changes observed in the Raman spectra arising from the backbone vibrations of nucleic acid in going from the B- to A-form. The symmetric ? O? P? O? diester stretch increases in frequency from about 787 cm^?1 in the B-form to 807 cm^?1 in the A-form. The increased frequency characteristic of the A-form is due to the combining of the diester stretch with vibrations involving the C₅′, C₄′, and C₃′ nuclei. The frequency of the symmetric ? O? P? O? diester stretch is shown to be very dependent on the conformation of the ribose ring, indicating that in polynucleotides the ribose ring takes on one of two rigid conformations: C₃′-endo for A-form or C₃′-exo for B-form and “disordered” polynucleotides. The calculation lends confirmation to the atomic coordinates of Arnott and Hukins since the use of other geometries with the same force constants failed to give results in agreement with experimental evidence. The calculations also demonstrate the lowering effect of hydration on the anionic PO stretching frequencies. Experimental results show that the 814-cm^?1 band observed in the spectra of 5′GMP gel arises from a different vibrational mode than that of the 814-cm^?1 band of A-DNA.     

Crystal structures of two cyclic pseudopentapeptides containing ψ[CH2S] and ψ[CH2SO] backbone surrogates

The solid state conformations of cyclo[Gly–Proψ[CH₂S]Gly–D –Phe–Pro] and cyclo[Gly–Proψ[CH₂–(S)–SO]Gly–D –Phe–Pro] have been characterized by X-ray diffraction analysis. Crystals of the sulfide trihydrate are orthorhombic, P2₁2₁2₁, with a = 10.156(3) Å, b = 11.704(3) Å, c = 21.913(4) Å, and Z = 4. Crystals of the sulfoxide are monoclinic, P2₁, with a = 10.662(1) Å, b = 8.552(3) Å, c = 12.947(2) Å, β = 94.28(2), and Z = 2. Unlike their all-amide parent, which adopts an all-trans backbone conformation and a type II β-turn encompassing Gly-Pro-Gly-D -Phe, both of these peptides contain a cis Gly¹-Pro² bond and form a novel turn structure, i.e., a type II′ β-turn consisting of Gly–D –Phe–Pro–Gly. The turn structure in each of these peptides is stabilized by an intramolecular H bond between the carbonyl oxygen of Gly¹ and the amide proton of D -Phe⁴. In the cyclic sulfoxide, the sulfinyl group is not involved in H bonding despite its strong potential as a hydrogen-bond acceptor. The crystal structure made it possible to establish the absolute configuration of the sulfinyl group in this peptide. The two crystal structures also helped identify a type II′ β-turn in the DMSO-d₆ solution conformers of these peptides. © 1993 John Wiley & Sons, Inc.     

Complexes of binucleating ligands. XVII. Some 3-atom N,C bridged palladium(II) complexes

The acetate-bridged complex, LPd₂(CH₃CO₂), in which L^3? is a binucleating ligand, reacts with 2-vinylpyridine in the presence of methanol or ethanol to generate the 3 atom N,C bridged complexes LPd₂(2-C₅H₄N·CH·CH₂OR) (R = Me or Et) whose ¹H and ¹³C nmr spectra indicate the presence in solution of two slowly interconverting forms at room temperature. The ¹H and ¹³C nmr spectra of two closely related pairs of 3 atom N,C bridged complexes of the form LPd₂(2-C₅H₄N·CH·X) and LPd₂ (HN = C(CH₃)·CH·X) (where X = COCH₃ or COOCH₃) show that the complexes with pyridine-containing bridges exist in solution at room temperature in two distinguishable forms whilst the corresponding imine-bridged complexes behave as single species. The existence of two forms of the complexes with pyridine-containing 3 atom N,C bridges, the natures of which are discussed in this paper, appears to be a consequence of steric interaction between the pyridine α hydrogen atom and the closely adjacent oxygen donor of L.     

Flexibility of DNA and RNA upon Binding to Different Metal Cations. An Investigation of the B to A to Z Conformational Transition by Fourier Transform Infrared Spectroscopy

Abstract

The interaction of DNA and RNA with Cu(II), Mg(II), [Co(NH₃)₆]³⁺ [Co(NH₃)₅Cl]²⁺ chlorides and, cis- and trans-Pt(NH₃)₂Cl₂ (CIS-DDP, trans-DDP) has been studied by Fourier Transform Infrared (FT-IR) spectroscopy and a correlation between metal-base binding and conformational transitions in the sugar pucker has been established. It has been found that RNA did not change from A-form on complexation with metals, whereas DNA exhibited a B to Z transition. The marker bands for the A-form (C′₃-endo-anti conformation) were found to be near 810–816 cm^?1, while the bands at 825 and 690 cm^?1 are marker bands for the B- conformation (C′₂-endo, anti), The B to Z (C₃′-endo, syn conformation) transition is characterized by the shift of the band at 825 cm^?1 to 810–816 cm^?1 and the shift of the guanine band at 690 cm^?1 to about 600–624 cm^?1.     

Use of chemical ionization for GC–MS metabolite profiling

Metabolite profiling is commonly performed by GC–MS of methoximated trimethylsilyl derivatives. The popularity of this technique owes much to the robust, library searchable spectra produced by electron ionization (EI). However, due to extensive fragmentation, EI spectra of trimethylsilyl derivatives are commonly dominated by trimethylsilyl fragments (e.g. m/z 73 and 147) and higher m/z fragment ions with structural information are at low abundance. Consequently different metabolites can have similar EI spectra, and this presents problems for identification of “unknowns” and the detection and deconvolution of overlapping peaks. The aim of this work is to explore use of positive chemical ionization (CI) as an adjunct to EI for GC–MS metabolite profiling. Two reagent gases differing in proton affinity (CH₄ and NH₃) were used to analyse 111 metabolite standards and extracts from plant samples. NH₃-CI mass spectra were simple and generally dominated by [MH]⁺ and/or the adduct [M+NH₄]⁺. For the 111 metabolite standards, m/z 73 and 147 were less than 3% of basepeak in NH₃-CI and less than 30% of basepeak in CH₄-CI. With CH₄-CI, [MH]⁺ was generally present but at lower relative abundance than for NH₃-CI. CH₄-CI spectra were commonly dominated by losses of CH₄ [M+1-16]⁺, 1–3 TMSOH [M+1-nx90]⁺, and combinations of CH₄ and TMSOH losses [M+1-nx90-16]⁺. CH₄-CI and NH₃-CI mass spectra are presented for 111 common metabolites, and CI is used with real samples to help identify overlapping peaks and aid identification via determination of the pseudomolecular ion with NH₃-CI and structural information with CH₄-CI.

     

Luminescent α-diimine complexes of ruthenium(II) containing scorpionate ligands

We describe the synthesis, characterization, and reactivity of several Ru(II) complexes of the type cis-L₂Ru(Z)ⁿ⁺, where L is an α-diimine [e.g. 2,2′-bipyridine (bpy) or 1,10-phenanthroline (phen)] ligand and Z is a bis-coordinated scorpionate ligand such as tris-(1-pyrazolyl)methane (HC(pz)₃, PZ=1-pyrazolyl; n=2) or tetrakis-(1-pyrazolyl)borate anion (B(pz)₄ ⁻; n=1). The complexes each exhibit strong visible absorption assigned as a π*(L)←dπ(Ru) metal-to-ligand charge-transfer (MLCT) transition characteristic of the cis-L₂Ru²⁺ kernel. A corresponding MLCT excited state emission is observed in room temperature CH₃CN solution, although emission energies, lifetimes, and quantum yields are reduced relative to Ru(bpy)₃ ²⁺. Electronic spectra and cyclic voltammetry measurements indicate that the relative π-acceptor abilities of the coordinated Z are: Z=(1H-pyrazolyl)₂(pz)₂B(pz)₂<(pyridine)₂<(pz)₂CH(pz). Uncoordinated pz groups of cis-(bpy)₂Ru(pz)₂B(pz)₂ ⁺ can be reacted to form a sterically hindered, localized-valence (K_com33 l mol⁻¹) cis,cis-(bpy)₂Ru^II(pz)₂B(pz)₂Ru^II(bpy)₂ ³⁺ dimer. The dimer properties are interpreted by comparison to the known cis-(bpy)₂Ru^II(pz)₂Ru^II(bpy)₂ ²⁺ analog. The dimer is photoreactive and undergoes an asymmetrical photocleavage in CH₃CN (yielding cis-(bpy)₂Ru^III(pz)₂B(pz)₂ ²⁺ and cis-(bpy)₂Ru^II(CH₃CN)₂ ²⁺), similar to the corresponding thermal reaction observed for the mixed-valence cis-(bpy)₂Ru^II(pz)₂Ru^III(bpy)₂ ³⁺ system.