Tài liệu Báo cáo khoa học: Local stability identification and the role of a key aromatic amino acid residue in staphylococcal nuclease refolding pdf

amino acid residue in staphylococcal nuclease refolding Zhengding Su3, Jiun-Ming Wu1, Huey-Jen Fang1, Tian-Yow Tsong2,3and Hueih-Min Chen1 1 Institute of BioAgricultural Sciences, Academ

amino acid residue in staphylococcal nuclease refolding Zhengding Su3, Jiun-Ming Wu1, Huey-Jen Fang1, Tian-Yow Tsong2,3and Hueih-Min Chen1

1 Institute of BioAgricultural Sciences, Academia Sinica, Taipei, Taiwan, ROC

2 Institute of Physics, Academia Sinica, Taipei, Taiwan, ROC

3 Department of Biochemistry, University of Minnesota College of Biological Sciences, St Paul, MN, USA

Staphylococcal nuclease (SNase) is a single-domain

protein of 149 amino acids Its 3D structure has been

examined by NMR [1–3] and X-ray crystallography

[4,5] However, only part of the structure (positions 1–

141) can be confirmed The segment 142–149 has not

been defined with certainty because of its apparent

flexibility Structural observations made with NMR or

X-ray have led to the prediction that certain amino

acid(s) in the flexible segment stabilize the rest of the

structure, in particular the key amino acid(s) located

close to this flexible segment The tryptophan at

posi-tion 140, for example, may play an important role in

maintaining the protein structure formed by amino

acids 1–141 In this study, we used site-directed

muta-genesis to generate point mutations and truncations

around this position to explore the above prediction

As shown by Chen and colleagues [6], SNase protein

can be unfolded by lowering its pH (for example, from

pH 7 to pH 2) About 2.5 protons are associated with

the key glutamic amino acid residues at positions 75 and

129 This association between protons and key amino

acids leads the protein to unfold However, the refolding process may be different and more complex because the transition of refolding is from many unfolded states to

a single native state Based on previous kinetic experi-ments using single-jump and double-jump stopped-flow for refolding [7,8], SNase protein can be refolded in vitro

to its active 3D conformation in milliseconds The sequence of equilibrium reactions between the three denatured states and one native state can be shown as [9] N« D1« D2« D3, where N is the protein in its native state and Di(i¼ 1–3) indicates the protein in its unfolded state This scheme has been used to solve puz-zles such as accumulated intermediates and to conduct random searches among ‘microscopic states’ [8] The early stages of refolding (Difi N) occur via key amino acid(s) which act as nucleation centres before proton dissociation Subsequently, these centres trigger the condensation of random polypeptide chains into the compact form of the native state

In this study, the effects of mutating W140 [10]

on SNase protein conformation and stability were

Keywords

aromatic amino acid; refolding; stability;

staphylococcal nuclease

Correspondence

H-M Chen, Institute of BioAgricultural

Sciences, Academia Sinica, Taipei,

Taiwan 115, R.O.C.

Fax: +886 2 2788 8401

Tel: +886 2 2785 5696 ext 8030

E-mail: robell@gate.sinica.edu.tw

(Received 3 May 2005, revised 3 June

2005, accepted 13 June 2005)

doi:10.1111/j.1742-4658.2005.04814.x

Staphylococcal nuclease (SNase) is a model protein that contains one domain and no disulfide bonds Its stability in the native state may be maintained mainly by key amino acids In this study, two point-mutated proteins each with a single base substitution [alanine for tryptophan (W140A) and alanine for lysine (K133A)] and two truncated fragment proteins {positions 1–139 [SNase(1–139) or W140O] and positions 1–141 [SNase(1–141) or E142O]} were generated Differential scanning micro-calorimetry in thermal denaturation experiments showed that K133A and E142O have nearly unchanged DHcal relative to the wild-type, whereas W140A and W140O display zero enthalpy change (DHcal
0) Far-UV CD measurements indicate secondary structure in W140A but not W140O, and near-UV CD measurements indicate no tertiary structure in either W140 mutant These observations indicate an unusually large contribution of W140 to the stability and structural integrity of SNase

Abbreviations

DSC, differential scanning calorimetry; SNase, staphylococcal nuclease.

investigated Two point-mutated proteins, with a single

base substitution of alanine for tryptophan (W140A)

and alanine for lysine (K133A), and two truncated

fragment proteins, with fragments 1–139 [SNase(1–

139) or W140O] and 1–141 [SNase(1–141) or E142O],

were generated The effect of these C-terminal

trunca-tions and point mutatrunca-tions to C-terminal residues on

SNase stability and conformation integrity was

exam-ined by subjecting these mutants and wild-type

pro-teins to CD [11,12] and differential scanning

calorimetry (DSC) [13,14] The preliminary refolding

process in terms of assembly of fragments is discussed

Results

CD spectra

Secondary structure of SNase and its mutants was

deter-mined by CD with spectrapolorimetry measurements

The approximate fraction of secondary structure type

that is present in any protein can be determined by its

far-UV CD spectrum as the sum of fractional multiples

of the reference spectra for each structural type

Figure 1A shows the CD spectra of W140A, E142O

and K133A There are no significant differences from

that of the wild-type protein In contrast, W140O has a

completely different CD spectrum There are no peak

minima at 222 nm and 208 nm, but instead a peak

mini-mum at 200 nm, indicating that it has no secondary

structure only random coil We can therefore postulate

that, when the segment beyond W140 was removed, the

secondary structure of the protein disintegrated Using

the peak at 222 nm of the wild-type protein as an index

of helical conformational stability, this CD spectrum of

W140O suggests a decrease in helicity on removal of all

amino acids beyond position 140

In CD spectra in the near-UV region (Fig 1B), the

wild-type protein and mutants E142O and K133A show

strong intensity at
277 nm (h
)77 degreesÆcm)2Æ

dmol)1), revealing an intact tertiary conformation In

contrast, W140A and W140O both lacked tertiary

struc-ture, as their intensities at 277 nm were only h
)22

and )13 degreesÆcm)2Ædmol)1 (Fig 1B) However,

W140A at 295 nm had a similar spectrum to that of the

wild-type protein, but W140O did not (h
0) This may

indicate that the aromatic F or Y in the W140A mutant

are more ordered and compact than in the W140O

protein

Tryptophan fluorescence spectra

W140 is located near the flexible C-terminus of SNase

Changes in the fluorescence intensity of W140 reflect

a change in the hydrophobic environment surrounding W140 and thus indicate a change in the overall (ter-tiary) structure of the protein Figure 2 shows the fluorescence spectra of wild-type SNase and the four mutants E142O, K133A, W140A and W140O The fluorescence spectra of E142O and K133A are similar

to that of the wild-type protein However, the fluores-cence in the mutants without tryptophan at 140 (W140A and W140O) was much lower than both the wild-type protein and mutants E142O and K133A

Thermal analysis of protein unfolding The DSC curves of the wild-type protein and the mutants K133A, E142O, W140A and W140O are shown in Fig 3, with their thermodynamic parameters summarized in Table 1 The calorimetric DHcal values

Fig 1 CD spectra of wild- type and SNase mutants (A) CD spectra (far-UV) of five proteins [wild-type (WT), W140A, E140O, W140O and K133A] All spectra are similar except the W140O spectrum (bold line) (B) CD spectra (near-UV) of the same proteins Protein concentration was 0.5 mgÆmL)1.

of the wild-type protein and K133A and E142O were

88.45, 84.70, and 83.60 kcalÆmol)1, respectively The

melting point and DSC profile of E142O (52.8
C) was

almost identical with that of the wild-type protein (52.32
C) K133A had a similar DHcal but a slightly different melting point (47.70
C) compared with the wild-type protein These results suggest that lysine at position 133 and the residues that follow glutamic acid

at position 142 play negligible roles in maintaining the native structure of SNase

In contrast, W140A and W140O revealed no distinct maxima in their DSC profiles This is very different from the wild-type protein and K133A and E142O, which showed a significant enthalpy change This implies that either the protein has poor stability or no secondary⁄ tertiary structure results from either repla-cing the tryptophan at position 140 with alanine or the removal of a fragment from positions 140–149 This

is supported by the melting points of the proteins (52.32
C for the wild-type and ‘not detectable’ for W140A and W140O) Flanagan et al [15] reported that multiple mutations can cause large changes in the average conformation of denatured proteins Here we show that a specific single mutation or removal of a specific fragment can cause large changes in the native state of SNase

Discussion

In addition to its local electrostatic interactions, which contribute largely to SNase stability via specific charged amino acids (Results shown in the preceding paper), other nonelectrostatic interactions at even more specific positions play a significant role in maintaining SNase tertiary structure

Our CD and DSC data show that the W140 in SNase is the amino acid responsible for the stability of the whole protein However, in comparison with the wild-type protein, the mutant W140A retains signifi-cant secondary structure (Fig 1A) Yin & Jing [16] reported that W140 plays an important role in the native-like SNase conformation and the enrichment

of an ordered secondary structure If tryptophan is relocated from position 140 to 34, the mutant (F34W⁄ W140F) [17] retains its secondary structure, but its tertiary structure is lost This implies that tryp-tophan plays a significant role in maintaining the 3D structure only at 140 (wild-type SNase has only one W) Without W140, the secondary structure may be maintained by other interactions such as local stable segments interacting around E75 and E129, areas with oppositely charged amino acids The truncated protein W140O in this study (deletion of residues 1–140) shows zero enthalpy on thermal unfolding (Table 1) and has

no secondary structure (Fig 1A) This indicates that, without tryptophan and residues 140–149, the protein

Fig 2 Steady-state fluorescent spectra of wild-type and mutant

SNase Spectra of five proteins [wild-type (WT), W140A, E140O,

W140O and K133A] Protein concentration was 0.4 mgÆmL)1.

Fig 3 Calometric melting curves of wild-type and mutants of

SNase DSC curves of five proteins [wild-type (WT), W140A,

E140O, W140O and K133A] The curves of W140A and W140O

are nearly linear in terms of intensity All protein concentrations

were 2 mgÆmL)1.

cannot maintain its tertiary conformation or even the

secondary motif However, if residues 142–149 are

removed, the protein largely retains its 3D structure

(Table 1 and Fig 2) Related experiments have been

performed previously Parker et al [18] showed that

the apparent association constant of SNase(1–126)

bound to pdTp in the presence of Ca2+ is

approxi-mately threefold lower than that of the wild-type

pro-tein Therefore, some or all of the residues in the 127–

149 segment are critical for maintenance of the native

conformation of the protein In addition, Griko and

coworkers [19], studying SNase(1–136), showed that

this fragment (residues 1–136) has no secondary

struc-ture but retains the tertiary conformation They thus

proved that SNase(1–136) is not a ‘molten globule’

protein, although its unfolding process was a

first-order phase transition This situation contrasts with

our W140O [SNase(1–139)] mutant, which maintains

its secondary structure to a certain extent but has no

tertirary conformation (Fig 1A)

As to the point of fragment assembly during protein

folding, Anfinsen and coworkers [20,21] originally

studied the enzymic effect using overlapping

structure-less fragments [for instance, SNase(99–149) interacting

with SNase(1–126)] and found that the reconstructed

complex was active and exhibited much of the ordered

structure Anfinsen consequently predicted that this

protein was organized from its polypeptide chain into

N-terminal and C-terminal centers during refolding

[21] Since then, many scientists have been interested in

demonstrating this concept by using N-terminal and

C-terminal fragments of SNase as models for the study

of folding and unfolding pathways For example, Choy

& Kay [22] using NMR 15N and 2H spin relaxation

techniques illustrated that the fragment D131D

(dele-tion of wild-type residues 3–12 and 141–149) of SNase

was completely unfolded under nondenaturing

condi-tions (pH
5 and low salt concentration) This is

because they observed much more vibrational motion

in the unfolded protein than in folded ones on the

picosecond time scale Taniuchi et al [23] used both

SNase(1–126) and SNase(50–149) as typical fragments

to form type I and type II (in equilibrium) complex proteins They reported that these two overlapping fragments could form enzymically active complement-ary structures, and their folding rates were not related

to any decrease in energy from the unfolded to the folded state Feng et al [24] created the SNase frag-ments SNase(1–110), SNase(1–121) and SNase(1–135) and used them in NMR spectroscopy experiments to study the folding process They concluded that the conformation of these fragments could be considered

as native-like partially folded and unfolded states Recently, they further used the short N-terminal frag-ments SNase(1–20), SNase(1–28) and SNase(1–36) to show that the folding nucleation sites of SNase may start from the N-terminus [25] However, we used the C-terminal fragments SNase(1–140) and SNase(1–142)

to show that SNase(1–140) plays a role in the assembly

of the protein during refolding Our results also show that SNase(1–140), without Trp at position 140, does not have any structure, whereas the fragment including Trp at position 140, i.e SNase(1–142), has a similar structure to the wild-type enzyme

Our experiments show that tryptophan at position

140 plays an important role in maintaining protein ter-tiary integrity Figure 4A shows how tryptophan (loop 1) may interact with loop 2 and loop 3 These inter-actions seem to form a ‘lower neck’ in the protein as compared with the ‘upper neck’ which is formed by E75 with H121 and K915 The forces responsible for the interactions between these loops are not yet clear One possibility is that the loops together with W140 constitute a nucleation center The indole ring [26]

of W140 may be the main target for the interaction with both loop 2 and loop 3 Furthermore, from the protein folding scheme discussed previously [9],

N« D1« D2« D3, the energy needed for transfor-mation among the Di states of protein unfolding⁄ refolding is negligible (4.57 kcalÆmol)1 for D1 « D2 and 4.32 kcalÆmol)1 for D2« D3) and a possible intermediate state such as SNase(1–139) exists

Table 1 DSC results of SNase and its mutants Phosphate buffer (25 m M Na2HPO4⁄ 50 m M NaH2PO4⁄ 200 m M NaCl, pH adjusted to 7.0) was used in the experiments All proteins were used at a concentration of 2 mgÆmL)1 Difference from DH of WT (%) calculated by [(DH mutant ) DH WT ) ⁄ DH WT ] · 100 Difference from DC p of WT (%) calculated by [(DC p mutant ) DC p WT ) ⁄ DC p WT ] · 100 WT, Wild-type; ND, not detectable.

Average Tm(
C) DH (kcalÆmol)1)

Difference of

DH from WT (%)

DC p

(kcalÆmol)1ÆK)1)

DDC p

(kcalÆmol)1ÆK)1)

Difference of

DC p from WT (%)

(Fig 4B, State 2) When tryptophan occupies position

140, the whole protein is folded into its native

confor-mation (Fig 4B, State 3)

Summary

Trp140 located in the C-terminal loop of SNase plays

an important role in protein stability and

conforma-tional integrity During protein unfolding⁄ refolding,

the addition of 2.5 protons (both E75 and E129 are

the targets of protonation) results in SNase unfolding,

with refolding at an early stage through the formation

of a SNase(1–139) fragment in which the tryptophan

at position 140 is needed for formation of the native structure

Experimental procedures

Materials

Luria–Bertani broth and isopropyl thio-b-d-galactoside were purchased from USB (Cleveland, OH) Salmon testes DNA and some analytical grade chemicals such as EDTA, Tris⁄ HCl, CaCl2, NaCl and mineral oil were obtained from Sigma (St Louis, MO, USA) Salmon testes DNA for the enzyme activity test was used without further purification Guanidine hydrochloride and dNTPs were purchased from Boehringer (Mannheim, Germany) Ethanol (> 99%) was obtained from Panreac (Barcelona, Spain) Urea was a product of Acros (Pittsburgh, PA, USA) The Quick-changeTM kit containing Pfu DNA polymerase, 10· reac-tion buffer and DpnI restricreac-tion enzyme was purchased from Stratagene (La Jolla, CA, USA) Water used for these experiments was deionized and distilled

PCR site-directed mutagenesis

The wild-type SNase nuc gene (originally obtained from

D Shortle, the Johns Hopkins University, Baltimore, MD, USA) was cloned into pTrc-99A, which was used to trans-form Escherichia coli strain JM105 Plasmid DNA was purified by the alkaline lysis method (Gibco-BRL, Gaithers-burg, MD, USA; GFXTMkit), and stored at)20
C before being subjected to mutagenesis Two complementary 33-mer primers that included the alanine codon at positions 140 or

133 were designed and synthesized (Life Technologies, Rockville, MD, USA) Single-point mutations were made

by site-directed mutagenesis to generate W140A and K133A Truncated proteins W140O (the segment between positions 140 and 149 of the wild-type protein was removed) and E142O (the segment between positions 142 and 149 of the wild-type protein was removed) were generated by using suitable complementary primers For site-directed mutagen-esis, a 10· reaction buffer (Stratagene; QuickChangeTMkit) was mixed with 1.5 lL dsDNA template, 1.2 lL of a pair of complementary oligonucleotides, 1 lL 10 mm each dNTP and double-distilled water to a final volume of 50 lL Then

1 lL Pfu DNA polymerase was added to the solution, and the mixture was overlaid with 30 lL mineral oil A PCR consisting of 16 cycles of 50
C (1.5 min), 68
C (14 min), and 94
C (1 min) was performed using a PerkinElmer 480 thermal cycler (Wellesley, MA, USA) The wild-type DNA template was then digested by adding 1 lL DpnI restriction enzyme to the PCR mixture and incubating at 37
C for

1 h Then 10 lL of the reaction mixture (containing undi-gested mutant plasmid) was used to transform 100 lL

B

A

Fig 4 Global segment interactions and the folding profiles in

wild-type SNase (A) W140, in loop 1 interacts with loop 2 and loop 3

which forms a ‘lower neck’ network area in maintaining protein

ter-tiary structure State 1 denotes the nascent polypeptide fragment.

(B) The fragment folding pathway induced via the SNase(1–139)

fragment and formed to its minimum energy native state via the

addition of either tryptophan at position 140 or fragment 140–149.

competent JM105 cells The mixture was incubated on ice

for 1 h, and at 42
C for 2 min, followed by 2 min

incuba-tion on ice After transformaincuba-tion, 800 lL Luria–Bertani

medium was added, and the mixture incubated at 37
C for

1 h Transformed cells were selected on ampicillin plates,

and mutant DNA was isolated from the resulting colonies

Mutant plasmids were then identified by BamHI and NcoI

restriction digestion, and their sequences confirmed by

DNA sequencing

DNA sequencing

Plasmid DNA was isolated with the GFXTM Micro

Plas-mid Prep Kit (Amersham Pharmacia Biotech, Piscataway,

NJ, USA), and the resulting dsDNA was mixed with 8 lL

BigDyeTMmaster mix (BigDyeTMTerminator Ready

Reac-tion Kit; Applied Biosystems, Foster City, CA, USA) and

3.2 pmol sequencing primer The final solution was mixed

with deionized water to a final volume of 20 lL in a

0.5-mL thin-walled PCR tube and overlaid with 40 lL light

mineral oil DNA sequencing was performed by cycle

sequencing using 25 cycles of 96
C for 30 s, 50
C for

15 s, and 60
C for 4 min in a PerkinElmer 480 thermal

cycler The extension products were purified by a

Centri-SepTM spin column chromatography (Princeton

Separa-tions, Adelphia, NJ, USA) to remove unincorporated dye

terminators Template suppression reagent (5 lL; PE

Applied Biosystems, Foster City, CA, USA) was mixed

with purified extension products The samples were heated

at 95
C for 2 min and then chilled on ice Capillary

elec-trophoresis was performed using an ABI PRISM 310

Gen-etic Analyzer (PE Applied Biosystems) fitted with a 47-cm

capillary containing POP-6 polymer The mutant sequences

(positions 1–149 for mutant proteins or 1–139 and 1–141

for truncated proteins) were compared with that of the

wild-type and confirmed to have the correct mutant

sequences

Protein purification

Escherichia coliJM105 carrying recombinant plasmids were

grown in Luria–Bertani broth containing 100 lgÆmL)1

ampicillin at 37
C Protein expression was induced by

adding isopropyl thio-b-d-galactoside The cells were

har-vested after 4 h of incubation and suspended in chilled

buffer A (6 m urea, 0.05 m Tris, 0.2 m NaCl, pH 9.2,

fil-tered through a 0.45 lm membrane) Proteins were

collec-ted after two alcohol precipitations and stored in buffer B

(6 m urea, 0.05 m Tris, pH 9.2, filtered through a 0.45 lm

membrane) The recombinant proteins were purified by

cation-exchange chromatography (washed CM-25

ion-exchange gel column) The proteins were dialysed after

purification for 2 days at 4
C against phosphate buffer

(25 mm NaH2PO4⁄ 50 mm NaHPO4⁄ 200 mm NaCl, pH

adjusted to 7.0) and were then lyophilized The average

yield of recombinant proteins was
25 mgÆL)1 SNase purity was investigated by SDS⁄ PAGE The gel was stained with Coomassie blue and analyzed by densitome-try, revealing protein purity of greater than 85% Protein concentration was determined by measuring the absorption coefficient of each mutant by the method of Gill & von Hippel [27]

CD measurements

CD was performed on wild-type protein and mutants using a Jasco model J-720 spectropolarimeter The spectra were measured between 200 and 320 nm Wild-type and mutant proteins were dissolved in phosphate buffer (25 mm NaH2PO4⁄ 50 mm NaHPO4⁄ 200 mm NaCl, pH adjusted to 7.0) at a concentration of 0.5 mgÆmL)1 Spec-tra were obtained as the average of five successive scans with a bandwidth of 1.0 nm and a scan speed of

20 nmÆmin)1

Steady-state tryptophan fluorescence measurements

Measurements were made with a LS-50B spectrometer (PerkinElmer) Samples were dissolved in phosphate buffer

at a concentration of 0.4 mgÆmL)1 Excitation was set at

298 nm, and emissions were observed at 350 nm The fluor-escence spectra were measured between 300 and 550 nm with a scanning speed of 150 nmÆs)1 and an excitation slit

of 5.0 nm

Calorimetric measurements

Thermal analysis of protein denaturation was performed with DSC (a model 6100 Nano II; Calorimetry Sciences Corp., Provo, UT, USA) Lyophilized wild-type and mutant SNase were dissolved in phosphate buffer at a concentration of 2 mgÆmL)1 Samples were first sonicated for 15 min Then 1 mL buffer or sample was loaded into

a clean reference or sample cell, respectively, ensuring that the samples were free of air bubbles Samples were heated from 20
C to 75
C under 3 atm at a heating rate of

1
CÆmin)1 The melting point (Tm) of protein tested was directly obtained from the DSC curve The enthalpy change (DHcal) of each protein was calculated by integra-tion of the curve covering area (Tm was taken as the curve peak point) using origin software

Acknowledgements

This work is partially supported by a grant (NSC-92-2311-B-001) from the National Science Council, Taiwan, R.O.C and the theme project of Academia Sinica, Taipei, Taiwan, R.O.C

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