Nuclear magnetic resonance studies of the binding of trimethoprim to dihydrofolate reductase.

The resonances of the aromatic protons of trimethoprim [2,4-diamino-5-(3',4',5'-trimethoxybenzyl)pyrimidine] in its complexes with dihydrofolate reductases from Lactobacillus casei and Escherichia coli cannot be directly observed. Their chemical shifts have been determined by transfer of saturation experiments and by difference spectroscopy using [2',6'-2H2]trimethoprim. The complex of 2,4-diamino-5-(3',4'-dimethoxy-5'-bromobenzyl)pyrimidine with the L. casei enzyme has also been examined. At room temperature, the 2',6'-proton resonance of bound trimethoprim is very broad (line width great than 30 Hz); with the E. coli enzyme, the resonance sharpens with increasing temperature so as to be clearly visible by difference spectroscopy at 45 degrees C. This line broadening is attributed to an exchange contribution, arising from the slow rate of "flipping" about the C7-C1' bond of bound trimethoprim. The transfer of saturation measurements were also used to determine the dissociation rate constants of the complexes. In the course of these experiments, a decrease in intensity of the resonance of the 2',6'-proton resonance of free trimethoprim on irradiation at the resonance of the 6 proton of free trimethoprim was observed, which only occurred in the presence of the enzyme. This is interpreted as a nuclear Overhauser effect between two protons of the bound ligand transferred to those of the free ligand by the exchange of the ligand between the two states. The chemical shift changes observed on the binding of trimethoprim to dihydrofolate reductase are interpreted in terms of the ring-current shift contributions from the two aromatic rings of trimethoprim and from that of phenylalanine-30. On the basis of this analysis of the chemical shifts, a model for the structure of the enzyme-trimethoprim complex is proposed. This model is consistent with the (indirect) observation of a nuclear Overhauser effect between the 2',6' and 6 protons of bound trimethoprim.     

Trimethoprim binding to bacterial and mammalian dihydrofolate reductase: a comparison by proton and carbon-13 nuclear magnetic resonance

The binding of trimethoprim to dihydrofolate reductase from L1210 mouse lymphoma cells has been studied by measuring the changes in chemical shift of nuclei of the ligand that accompanying binding. The 6- and 2',6'-proton chemical shifts of bound trimethoprim have been determined by transfer of saturation experiments, and the 2-carbon chemical shift has been determined by using [2-13C]trimethoprim. The changes in proton chemical shift are substantially smaller than those accompanying binding to bacterial dihydrofolate reductase [Cayley, P. J., Albrand, J. P., Feeney, J., Robert, G. C. K., Piper, E. A., & Burgen, A. S. V. (1979) Biochemistry 18, 3886]. It is shown that this difference arises largely from the fact that trimethoprim adopts different conformations when bound to mammalian and to bacterial dihydrofolate reductase. The proton chemical shifts are interpreted in terms of ring-current contributions from the two aromatic rings of trimethoprim itself and the nearby aromatic amino acid residues of the enzyme. The latter have been located by using the refined crystallographic coordinates of the Lactobacillus casei and Escherichia coli reductases in their complexes with methotrexate [Bolin, J. T., Filman, D. J., Matthews, D. A. & Kraut, J. (1982) J. Biol. Chem. 257, 13650], under the assumption that, as indicated by the 13C chemical shifts, the diaminopyrimidine ring of trimethoprim binds in the same way as does the corresponding part of methotrexate. With use of these assumptions, the conformation of trimethoprim bound to the dihydrofolate reductases from L. casei, E. coli, and L1210 cells has been calculated.(ABSTRACT TRUNCATED AT 250 WORDS)     

Partial 1H NMR assignments of the Escherichia coli dihydrofolate reductase complex with folate: evidence for a unique conformation of bound folate

Sequence-specific 1H assignments have been made for over 25% of the amino acid side chains of Escherichia coli dihydrofolate reductase complexed with folate by using a variety of two-dimensional techniques. Proton resonances were assigned by using a combination of site-directed mutagenesis and a knowledge of the X-ray crystal structure. Unique sets of NOE connectivities present in hydrophobic pockets were matched with the X-ray structure and used to assign many of the residues. Other residues, particularly those near or in the active site, were assigned by site-directed mutagenesis. The ability to assign unambiguously the proton resonances of these catalytically important residues allowed for extensive networks of NOE connectivities to follow from these assignments. As a consequence of these assignments, the orientation of the pterin ring of folate could be determined, and its conformation is similar to that of the productive dihydrofolate complex. Under these experimental conditions, only one bound form of the pterin ring could be detected.     

Structural studies of cytochrome b5: complete sequence-specific resonance assignments for the trypsin-solubilized microsomal ferrocytochrome b5 obtained from pig and calf

We report complete sequence-specific proton resonance assignments for the trypsin-solubilized microsomal ferrocytochrome b5 obtained from calf liver. In addition, sequence-specific resonance assignments for the main-chain amino acid protons (i.e., C alpha, C beta, and amide protons) are also reported for the porcine cytochrome b5. Assignment of the majority of the main-chain resonances was rapidly accomplished by automated procedures that used COSY and HOHAHA peak coordinates as input. Long side chain amino acid spin system identification was facilitated by long-range coherence-transfer experiments (HOHAHA). Problems with resonance overlap were resolved by examining differences between the two-dimensional 500-MHz NMR spectra of rabbit, pig, and calf proteins and by examining the temperature-dependent variation of amide proton resonances. Calculations of the aromatic ring-current shifts for protons that the X-ray crystal structure indicated were proximal to aromatic residues were found to be useful in corroborating assignments, especially those due to the large shifts induced by the heme. Assignment of NOESY cross peaks was greatly facilitated by a prediction of intensities using a complete relaxation matrix analysis based on the crystal structure. These results suggest that the single-crystal X-ray structure closely resembles that of the solution structure although there is evidence that the solution structure has a more dynamic character.     

1H NMR (500 MHz) of gene 32 protein--oligonucleotide complexes

In concentrated solutions, gene 32 single-stranded DNA binding protein from bacteriophage T4 (gene 32P) forms oligomers with long rotational correlation times, rendering 1H NMR signals from most of the protons too broad to be detected. Small flexible N- and C-terminal domains are present, however, the protons of which give rise to sharp resonances. If the C-terminal A domain (48 residues) and the N-terminal B domain (21 residues) are removed, the resultant core protein of 232 residues (gene 32P) retains high affinity for ssDNA and remains a monomer in concentrated solution, and most of the proton resonances of the core protein can now be observed. Proton NMR spectra (500 MHz) of gene 32P and its complexes with ApA, d(pA)n (n = 2, 4, 6, 8, and 10), and d(pT)8 show that the resonances of a group of aromatic protons shift upfield upon oligonucleotide binding. Proton difference spectra show that the 1H resonances of at least one Phe, one Trp, and five Tyr residues are involved in the chemical shift changes observed with nucleotide binding. The number of aromatic protons involved and the magnitude of the shifts change with the length of the oligonucleotide until the shifts are only slightly different between the complexes with d(pA)8 and d(pA)10, suggesting that the binding groove accommodates approximately eight nucleotide bases. Many of the aromatic proton NMR shifts observed on oligonucleotide complex formation are similar to those observed for oligonucleotide complex formation with gene 5P of bacteriophage fd, although more aromatic residues are involved in the case of gene 32P.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tyrosyl-base-phenylalanyl intercalation in gene 5 protein-DNA complexes: proton nuclear magnetic resonance of selectively deuterated gene 5 protein.

The interactions of oligodeoxynucleotides with the aromatic residues of gene 5 protein in complexes with d(pA)8 and d(pT)8 have been determined by 1H NMR of the protein in which the five tyrosyl residues have been selectively deuterated either in the 2,6 or the 3,5 positions. Only the 3,5 protons of the three surface tyrosyls (26, 41, and 56) interact with the bases. The remainder of the aromatic protons undergoing base-dependent upfield ring-current shifts on complex formation are phenylalanyl protons, assigned to Phe(13) on the basis of model building. 19F NMR of the complexes of the m-fluorotyrosyl-labeled protein with d(pT)4 and d(pA)8 confirms the presence of ring-current perturbations of nuclei at the 3,5-tyrosyl positions of the three surface tyrosyls. Differential expression of the 19F(1H) nuclear Overhauser effect confirms the presence of two buried and three surface tyrosyl residues. A new model of the DNA binding groove is presented involving Tyr(26)-base-Phe(13) intercalation.     

Assignment of resonances in the 1H NMR spectrum of human lysozyme

Assignments in the 1H NMR spectrum for more than 120 resonances arising from 38 of the 130 amino acid residues of human lysozyme are presented. Assignments have been achieved using a combination of one and two-dimensional NMR techniques. Two-dimensional double-quantum correlated spectroscopy and relayed coherence transfer spectroscopy were found to be particularly useful for the identification of spin systems in the aromatic and methyl regions of the spectrum. These spin systems were assigned to specific residues in human lysozyme with reference to the X-ray crystal structure using one-dimensional nuclear Overhauser enhancement (NOE) data and a computer-based search procedure. Unique assignments were found for resonances of 27 amino acid residues even when a distance constraint on NOE effects of 0.7 nm was used in the search procedure; for the remaining residues closer constraints or additional information were required. The assignments include all but one of the resonances in the aromatic region of the spectrum and all the methyl group resonances in the region upfield of 0.6 ppm. The assignments presented here provide a basis for a comparison of the NMR spectra of human lysozyme and the more widely studied hen lysozyme.     

Production of an aromatic amino acid auxotroph of a trimethoprim-resistant Escherichia coli and deuteration of the aromatic amino acids in its dihydrofolate

Interpretation of the ¹H-NMR spectra of Escherichia coli dihydrofolate reductase is complicated by the large number of overlapping resonances due to protonated aromatic amino acids. Deuteration of the aromatic protons of aromatic amino acid residues is one technique useful for simplifying the ¹H-NMR spectra. Previous attempts to label the dihydrofolate reductase from over-producing strains of Escherichia coli were not completely successful. This labeling problem was solved by transducing via P1 phage a genetic block into the de novo biosynthetic pathway of aromatic amino acids in a trimethoprim resistant strain of E. coli, MB 3746. A new strain, MB 4065, is a very high level producer of dihydrofolate reductase and requires exogenous aromatic amino acids for growth, therefore allowing efficient labeling of its dihydrofolate reductase with exogenous deuterated aromatic amino acid.     

The combined use of selective deuteration and double resonance experiments in assigning the 1H resonances of valine and tyrosine residues of dihydrofolate reductase

Selective deuteration is a general solution to the resolution problem which limits the application of double resonance experiments to the assignment of the ¹H NMR spectra of proteins. Spin-decoupling and NOE experiments have been carried out on Lactobacillus casei dihydrofolate reductase and on selectively deuterated derivatives of the enzyme containing either [γ-²H₆]Val or (α,δ₂,?₁-²H₃]His, [α,δ₁,δ₂,?₁,?₂,ζ-²H₆]Phe, [α,δ₁,?₃,ζ₂,ζ₃,η₂-²H₆]Trp and [α,?₁,?₂-²H₃]Tyr. When combined with ring-current shift calculations based on the crystal structure of the enzyme, these experiments allow us to assign ¹H resonances of Val 61, Val 115, Tyr 46 and Tyr 68.     

Studies of individual carbon sites of proteins in solution by natural abundance carbon 13 nuclear magnetic resonance spectroscopy. Relaxation behavior.

The aromatic regions in proton-decoupled natural abundance 13C Fourier transform nuclear magnetic resonance spectra (at 14.2 kG) of small native proteins contain broad methine carbon bands and narrow nonprotonated carbon resonances. Some factors that affect the use of natural abundance 13C Fourier transform NMR spectroscopy for monitoring individual nonprotonated aromatic carbon sites of native proteins in solution are discussed. The effect of protein size is evaluated by comparing the 13C NMR spectra of horse heart ferrocytochrome c, hen egg white lysozyme, horse carbon monoxide myoglobin, and human adult carbon monoxide hemoglobin. Numerous single carbon resonances are observed in the aromatic regions of 13C NMR spectra of cytochrome c, lysozyme, and myoglobin. The much larger hemoglobin yields few resolved individual carbon resonances. Theoretical and some experimental values are presented for the natural linewidths (W), spin-lattice relaxation times (T1), and nuclear Overhauser enhancements (NOE) of nonprotonated aromatic carbons and Czeta of arginine residues. In general, the 13C-1H dipolar mechanism dominates the relaxation of these carbons. 13C-14N dipolar relaxation contributes significantly to 1/T1 of C epsilon2 of tryptophan residues and Czeta of arginine residues of proteins in D2O. The NOE of each nonprotonated aromatic carbon is within experimental error of the calculated value of about 1.2. As a result, integrated intensities can be used for making a carbon count. Theoretical results are presented for the effect of internal rotation on W, T1, and the NOE. A comparison with the experimental T1 and NOE values indicates that if there is internal rotation of aromatic amino acid side chains, it is not fast relative to the over-all rotational motion of the protein.     

Sequential assignment of the proton NMR spectrum of isolated alpha(CO) chains from human adult hemoglobin.

In this paper we report proton two-dimensional NMR experiments on isolated alpha chains from human hemoglobin A (HbA) in the monocarboxylated state. Several J-correlated and NOE spectra in water or deuterium water and phosphate buffer (100 mM) at 310 K and pH 5.6 were acquired and analysed for the sequential assignment of the proton resonances. In addition, we used the topological data obtained from the crystal structure of alpha subunits in the monocarboxylated HbA tetramer. The assigned resonances correspond to 70% of the amino acid residues. The present results provide information on the tertiary structure of isolated alpha chains in solution, particularly in the heme region. This structure may be compared with that of the a subunits in the tetrameric HbA(CO) in crystal by comparison of observed chemical shifts and those calculated from the X-ray atomic coordinates. Overall, the global folding of the two forms are highly similar. However, this analysis points out several local conformational differences in the heme pocket and the neighboring of the unique Trp residue. Possible explanations of these differences are discussed.     

Helix-coil transition of the self-complementary dG-dG-dA-dA-dT-dT-dC-dC duplex.

The helix-coil transition of the octanucleotide self-complementary duplex dG-dG-dA-dA-dT-dT-dC-dC has been monitored at the Watson-Crick protons, the base and sugar nonexchangeable protons and the backbone phosphates by high-resolution nuclear magnetic resonance (NMR) spectroscopy. The melting transition of the octanucleotide monitored by ultraviolet absorbance spectroscopy is characterized by the thermodynamic parameters delta H degree = -216.7 kJ/mol and delta S degree (25 degrees C) = -0.632 KJ mol-1 K-1 in 0.1 M NaCl, 10 mM phosphate solution. Correlation of the transition midpoint values monitored by the ultraviolet absorbance studies at strand concentrations below 0.2 mM and by NMR studies at 5.3 mM suggest that both methods are monitoring the octanucleotide duplex-to-strand transition. The NMR spectra of the Watson-Crick ring NH protons of the octanucleotide duplex have been followed as a function of temperature. The resonance from the terminal dG.dC base pairs broadens out at room temperature while the resonances from the other base pairs broaden simultaneously with the onset of the melting transition. The nonexchangeable base and sugar H-1' protons are resolved in the duplex and strand states and shift as average peaks through the melting transition. The experimental shifts on duplex formation have been compared with calculated values based on ring-current and atomic diamagnetic anisotropy contributions for a B-DNA base-pair-overlap geometry in solution. Several nonexchangeable proton resonances broaden in the fast-exchange region during the duplex-to-strand transition and the excess widths yield a duplex dissociation rate constant for the octanucleotide of 1.9 x 10(3) s-1 at 32 degrees C (fraction of duplex = 0.86) in 0.1 M NaCl, 10 mM phosphate buffer. The 31P resonances of the seven internucleotide phosphates are distributed over 0.6 ppm in the duplex state, shift downfield during the duplex-to-strand transition and undergo additional downfield shifts during the stacked-to-unstacked strand transition with increasing temperature.     

Assignment of the backbone 1H and 15N NMR resonances of bacteriophage T4 lysozyme

The proton and nitrogen (15NH-H alpha-H beta) resonances of bacteriophage T4 lysozyme were assigned by 15N-aided 1H NMR. The assignments were directed from the backbone amide 1H-15N nuclei, with the heteronuclear single-multiple-quantum coherence (HSMQC) spectrum of uniformly 15N enriched protein serving as the master template for this work. The main-chain amide 1H-15N resonances and H alpha resonances were resolved and classified into 18 amino acid types by using HMQC and 15N-edited COSY measurements, respectively, of T4 lysozymes selectively enriched with one or more of alpha-15N-labeled Ala, Arg, Asn, Asp, Gly, Gln, Glu, Ile, Leu, Lys, Met, Phe, Ser, Thr, Trp, Tyr, or Val. The heteronuclear spectra were complemented by proton DQF-COSY and TOCSY spectra of unlabeled protein in H2O and D2O buffers, from which the H beta resonances of many residues were identified. The NOE cross peaks to almost every amide proton were resolved in 15N-edited NOESY spectra of the selectively 15N enriched protein samples. Residue specific assignments were determined by using NOE connectivities between protons in the 15NH-H alpha-H beta spin systems of known amino acid type. Additional assignments of the aromatic proton resonances were obtained from 1H NMR spectra of unlabeled and selectively deuterated protein samples. The secondary structure of T4 lysozyme indicated from a qualitative analysis of the NOESY data is consistent with the crystallographic model of the protein.     

31P-NMR assignment and conformational study of NADPH bound to Lactobacillus casei dihydrofolate reductase based on two-dimensional 1H-31P-heteronuclear and 1H-detected 1H-31P-shift-correlation experiments.

For any detailed NMR conformational study of a protein-ligand complex it is essential to have specific resonance assignments. We have now assigned the pyrophosphate 31P resonances in spectra of NADPH bound to Lactobacillus casei dihydrofolate reductase (DHFR) by using a combination of 1H-31P-heteronuclear shift-correlation (HETCOR), 1H-31P-heteronuclear multiple-quantum-coherence correlation spectroscopy (HMQC-COSY), 1H-1H COSY, homonuclear Hartmann-Hahn (HOHAHA) and NOE spectroscopy (NOESY) experiments. The nicotinamide pyrophosphate phosphorus, P(n), has been unequivocally assigned to a signal (-14.07 ppm) which shows a large 3JP-O-C-H coupling constant. Such a coupling constant when combined with the appropriate Karplus relationship provides conformational information about the P-O-C-H torsion angle. The torsion angle changes by 65 degrees +/- 10 degrees for the binary complex compared with the value in free NADPH. The observed coupling constants for the binary (DHFR--NADPH) and ternary (DHFR--NADPH--methotrexate) complexes (12.3 and 10.5 +/- 0.6 Hz, respectively) indicate that the pyrophosphate group has a similar conformation in the two complexes.     

Proton nuclear magnetic resonance studies of the effects of ligand binding on tryptophan residues of selectively deuterated dihydrofolate reductase from Lactobacillus casei

We have prepared a selectively deuterated dihydrofolate reductase in which all the aromatic protons except the C(2) protons of tryptophan have been replaced by deuterium and have examined the 1H NMR spectra of its complexes with folate, trimethoprim, methotrexate, NADP+, and NADPH. One of the four Trp C(2)-proton resonance signals (signal P at 3.66 ppm from dioxane) has been assigned to Trp-21 by examining the NMR spectrum of a selectively deuterated N-bromosuccinimide-modified dihydrofolate reductase. This signal is not perturbed by NADPH, indicating that the coenzyme is not binding close to the 2 position of Trp-21. This contrasts markedly with the 19F shift (2.7 ppm) observed for the 19F signal of Trp-21 in the NADPH complex with the 6-fluorotryptophan-labeled enzyme. In fact the crystal structure of the enzyme . methotrexate . NADPH shows that the carboxamide group of the reduced nicotinamide ring is near to the 6 position of Trp-21 but remote from its 2 position. The nonadditivity of the 1H chemical-shift contributions for signals tentatively assigned to Trp-5 and -133 indicates that these residues are influenced by ligand-induced conformational changes.     

Interpretation of nuclear magnetic resonance spectra for Lactobacillus casei dihydrofolate reductase based on the X-ray structure of the enzyme-methotrexate-NADPH complex.

The three-dimensional molecular structure of Lactobacillus casei dihydrofolate reductase complexed with NADPH and methotrexate has been used to interpret published magnetic resonance spectra for this enzyme. Proton resonances from histidine residues and 19F resonances from fluorine-labeled fluorotyrosine and fluorotryptophan dihydrofolate reductase have been assigned in several cases to specific amino acids in the primary sequence. Furthermore, the 31P signals from the pyrophosphate moiety of bound NADPH have been assigned and the large upfield shift for 13C-labeled (at the carboxamide carbon) NADP+ upon binding to the reductase has been explained in terms of desolvation effects.     

Proton NMR studies of transforming and nontransforming H-ras p21 mutants

One- and two-dimensional nuclear magnetic resonance spectroscopy (1D and 2D NMR) and site-directed mutagenesis were used to study the influence of mutations on the conformation of the H-ras oncogene product p21. No severe structural differences between the different mutants, whether they were transforming or nontransforming, could be detected. Initially, selective incorporation of 3,5-deuterated tyrosyl residues into p21 and 2D NMR were used to identify the resonances representing the spin systems of the imidazole rings of the three histidyl residues in the protein, of six of the nine tyrosyl rings, and of four of the five phenylalanyl rings. The spin systems of the phenyl rings of Phe28, Phe78, and Phe82 could be assigned by using mutant proteins, since no severe structure-induced spectral changes in the aromatic part of the spectra of the mutant proteins were detected. Sequence-specific assignments of the histidine imidazole resonances could be obtained by comparison of the distance information obtained by nuclear Overhauser enhancement spectroscopy (NOESY) experiments with the crystal structure. The change in the chemical shift values of the Hl' proton and the alpha-phosphate of the bound GDP in the NMR spectra of the p21(F28L) mutant and the 28-fold increase in the GDP dissociation rate constants of this mutant suggest a strong interaction between Phe28 and the p21-bound nucleotide. In solution, the p21-bound GDP.Mg2+ has an anti conformation, and the phenyl ring of Phe28 is close to the ribose of the bound GDP.Mg2+.     

Proton nuclear magnetic resonance saturation transfer studies of coenzyme binding to Lactobacillus casei dihydrofolate reductase

The chemical shifts of all the aromatic proton and anomeric proton resonances of NADP+, NADPH, and several structural analogues have been determined in their complexes with Lactobacillus casei dihydrofolate reductase by double-resonance (saturation transfer) experiments. The binding of NADP+ to the enzyme leads to large (0.9-1.6 ppm) downfield shifts of all the nicotinamide proton resonances and somewhat smaller upfield shifts of the adenine proton resonance. The latter signals show very similar chemical shifts in the binary and ternary complexes of NADP+ and the binary complexes of several other coenzymes, suggesting that the environment of the adenine ring is similar in all cases. In contrast, the nicotinamide proton resonances show much greater variability in position from one complex to another. The data show that the environments of the nicotinamide rings of NADP+, NADPH, and the thionicotinamide and acetylpyridine analogues of NADP+ in their binary complexes with the enzyme are quite markedly different from one another. Addition of folate or methotrexate to the binary complex has only modest effects on the nicotinamide ring of NADP+, but trimethoprim produces a substantial change in its environment. The dissociation rate constant of NADP+ from a number of complexes was also determined by saturation transfer.     

Identification of the 1H resonances of valine and leucine residues in dihydrofolate reductase by using a combination of selective deuteration and two-dimensional correlation spectroscopy

Lactobacillus casei dihydrofolate reductase (Mr 18 500) contains 16 valine and 14 leucine residues. By comparing the 2D COSY NMR spectra of normal and [gamma-2H6]valine enzyme we have been able to identify all 60 methyl resonances from these residues, and to connect the pairs arising from the same residue. This pairing of the methyl resonances was aided by the examination of the 2D RELAY spectrum which also allowed the C alpha H resonances (and hence the complete spin systems) of 14 of the valine residues to be identified. The combination of selective deuteration with 2D NMR techniques is shown to be a powerful general method for resolving 1H resonances in the complex spectra of proteins and for assigning them to amino-acid type.     

Use of 13C conformation-dependent chemical shifts to elucidate the local structure of a large protein with homologous domains in solution and solid state

In order to clarify the difference between solution NMR and X-ray diffraction analyses concerning the presence of alpha-helical structure in protein A, the 13C conformation-dependent chemical shifts of the 13C-labeled carbonyl carbons for selectively labeled protein A were used. In the 13C CP/MAS NMR spectra, the higher-field shifts of the carbonyl carbons of 13C-labeled Thr and Val residues compared with the random coil chemical shifts both in solution and solid state imply the presence of the third helix in the polypeptide chain, in contrast to the crystal structure of Fc-bound B-domain. Thus, a combination of selective isotope labeling and conformation-dependent chemical shifts will be a good Indicator to monitor the local structure of homologous protein in solution and solid state.