Báo cáo khóa học: Some properties of human small heat shock protein Hsp20 (HspB6) potx

Gusev1 1 Department of Biochemistry, School of Biology, Moscow State University, Moscow, Russia; 2 Imperial College School of Medicine at National Heart and Lung Institute, London, UK Hu

Some properties of human small heat shock protein Hsp20 (HspB6)

Olesya V Bukach1, Alim S Seit-Nebi1, Steven B Marston2and Nikolai B Gusev1

1 Department of Biochemistry, School of Biology, Moscow State University, Moscow, Russia; 2 Imperial College School of Medicine

at National Heart and Lung Institute, London, UK

Human heat shock protein of apparent molecular mass

20 kDa (Hsp20) and its mutant, S16D, mimicking

phos-phorylation by cyclic nucleotide-dependent protein kinases,

were cloned and expressed in Escherichia coli The proteins

were obtained in a homogeneous state without utilization

of urea or detergents On size exclusion chromatography at

neutral pH, Hsp20 and its S16D mutant were eluted as

symmetrical peaks with an apparent molecular mass of

55–60 kDa Chemical crosslinking resulted in the

forma-tion of dimers with an apparent molecular mass of 42 kDa

At pH 6.0, Hsp20 and its S16D mutant dissociated, and

were eluted in the form of two peaks with apparent

molecular mass values of 45–50 and 28–30 kDa At

pH 7.0–7.5, the chaperone activity of Hsp20 (measured by

its ability to prevent the reduction-induced aggregation of

insulin or heat-induced aggregation of yeast alcohol

dehydrogenase) was similar to or higher than that of

commercial a-crystallin Under these conditions, the S16D

mutant of Hsp20 possessed lower chaperone activity than

the wild-type protein At pH 6.0, both a-crystallin and Hsp20 interacted with denatured alcohol dehydrogenase; however, a-crystallin prevented, whereas Hsp20 either did not affect or promoted, the heat-induced aggregation of alcohol dehydrogenase The mixing of wild-type human Hsp27 and Hsp20 resulted in a slow, temperature-dependent formation of hetero-oligomeric complexes, with apparent molecular mass values of 100 and 300 kDa, which contained approximately equal amounts of Hsp27 and Hsp20 subunits Phosphorylation of Hsp27 by mito-gen activated protein kinase-activated protein kinase 2 was mimicked by replacing Ser15, 78 and 82 with Asp A 3D mutant of Hsp27 mixed with Hsp20 rapidly formed a hetero-oligomeric complex with an apparent molecular mass of 100 kDa, containing approximately equal quanti-ties of two small heat shock proteins

Keywords: small heat shock proteins; phosphorylation; chaperone activity

Human small heat shock proteins (sHsp) form a large

group of proteins, consisting of 10 members with a

molecular mass in the range of 17–23 kDa [1] These

proteins are grouped together because all contain an

a-crystallin domain, of 80–100 amino acid residues, which

is located in the C-terminal part of the protein [2,3] Some

sHsp, such as aB-crystallin and Hsp27, are ubiquitous

and expressed in practically all tissues [1,2,4,5], whereas

other sHsp (such as HspB7 and HspB9) are expressed

only in specific tissues [1,4,5] sHsp tend to form large

oligomers that vary in structure and number of monomers

[6,7] These complexes can be formed by identical or

nonidentical subunits Subunits of a-crystallin, Hsp20,

Hsp22, and Hsp27 seem to be involved in the formation

of different heterooligomeric complexes [8–12] Hsp27 and

aB-crystallin have been analyzed in detail [2–5,13,14],

whereas other members of the large superfamily of sHsp are less well characterized

Hsp20 was described by Kato et al [8] as a byproduct of purification of human aB-crystallin and Hsp27 Hsp20 is expressed in practically all tissues, reaching a maximal level

of 1.3% of total proteins in skeletal, heart and smooth muscles [2,9,15] Since 1997, the laboratory of Colleen Brophy has performed detailed investigations of the role of Hsp20 in the regulation of smooth muscle contraction It has been shown that cAMP- and cGMP-dependent protein kinases phosphorylate Ser16 of Hsp20 and that phosphory-lation of Hsp20 is associated with smooth muscle relaxation that is independent of the level of phosphorylation of the myosin light chain [16–20] These findings have been confirmed and extended [21–23] Insulin induces phos-phorylation of rat Hsp20 at Ser157 [24] and Hsp20 phosphorylated at two different sites (Ser16 and Ser157) differently affects glucose transport [25,26] Recently, Hsp20 was detected in blood and it has been shown that Hsp20 binds to and inhibits platelet aggregation [27] Thus, significant progress has been achieved in revealing a possible physiological role of Hsp20 However, investigation of the biochemical properties of isolated Hsp20 lag behind Indeed, the biochemical properties of rat Hsp20 were only briefly characterized in the reports of Kato et al [8,9] and van de Klundert et al [15], whereas the corresponding properties of human Hsp20 remain practically uncharac-terized Therefore, the present work was devoted to the cloning and purification of wild-type human Hsp20 and its

Correspondence to N B Gusev, Department of Biochemistry,

School of Biology, MoscowState University, Moscow119992, Russia.

Fax:/Tel.: + 7 095 9392747, E-mail: NBGusev@mail.ru

Abbreviations: ADH, yeast alcohol dehydrogenase; DMS,

dimethyl-suberimidate; EDC, 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide

hydrochloride; Hsp, heat shock protein; 3D mutant, human Hsp27

with replacement of Ser15, 78 and 82 by Asp; NHS,

N-hydroxy-succinimide; S16D, mutant of human Hsp20 with replacement of

Ser16 by Asp; sHsp, small heat shock proteins.

(Received 21 October 2003, accepted 17 November 2003)

mutant mimicking phosphorylation of Ser16, analysis of

their oligomeric state, chaperone activity and their ability to

interact with human Hsp27

Materials and methods

Proteins

Hsp27 The full-length cDNA encoding human Hsp20

(GenBank accession no.: AK056951) was amplified from

Marathon-Ready cDNA, Heart (Clontech) using the

fol-lowing forward 5¢-GAGATATACATATGGAGATCC

CTGTGC-3¢ (NdeI restriction site underlined) and reverse

5¢-GTGCTCGAGTTACTTGGCTGCGGCTGGCGG-3¢

(XhoI restriction site underlined) primers, and Pwo DNA

polymerase (Roche) The 480 bp PCR product was purified

after electrophoresis in an agarose gel, then digested with the

restriction endonucleases NdeI and XhoI and inserted into

the plasmid vector pET23b (which had been predigested with

the same endonucleases) The resulting construct was verified

by DNA sequencing and used for expression and

mutagen-esis A two step PCR-based
megaprimer method [28,29] was

used for the replacement of Ser16 of Hsp20 with Asp In this

case, the primer S16D (5¢-GCCGCGCCGACGCCCCG

TTGC-3¢) was used for site-directed mutagenesis

The human Hsp27 full-length cDNA (GenBank

acces-sion no.: NM001540) was amplified from Marathon-Ready

cDNA, Lung (Clontech) using the following forward

5¢-GAGATATACATATGGCCGAGCGC-3 and reverse

5¢-CCGGATCCCTACTTCTTGGCTGG-3¢ primers

con-taining, respectively, NdeI and BamHI restriction sites

(underlined) The PCR product was purified and inserted

into the plasmid vector, pET11c (Novagen) The resulting

construct was verified by DNA sequencing and used for

expression and site-directed mutagenesis

Three serine residues of Hsp27 (Ser15, Ser78 and

Ser82) were replaced with Asp This was achieved by

using the following primers: 5¢-CGGGGCCCCGACTG

GGACCCC-3¢ for S15D and 5¢-GACCCCGCTGTC

GAGTTGCCGGTCGAGCGCGC-3¢ for the S78D and

S82D mutants The two step PCR-based
megaprimer

method [28,29] permits creation of the so-called 3D

mutant of Hsp27 with replacements of Ser15, Ser78 and

Ser82 by Asp This type of mutation mimics

phosphory-lation of Hsp27 by mitogen activated protein

kinase-activated protein kinase 2 [30,31]

Expression and purification of human Hsp20 and

Hsp27 Expression was performed in Escherichia coli

BL21(DE3) pUBS520 E coli was cultured with aeration,

on Luria–Bertani (LB) media containing ampicillin

(150 lgÆmL)1) and kanamycin (40 lgÆmL)1), to an

attenu-ance (D600) of 0.5 Isopropyl thio-b-D-thiogalactoside

(IPTG) was added to a final concentration of 0.5 mMand

culture was continued for a further 4 h at 30C The cells

were harvested, frozen and used for isolation of

recombin-ant human wild-type Hsp20, its S16D mutrecombin-ant, recombinrecombin-ant

human wild-type Hsp27 and its 3D mutant

The initial stages of purification of Hsp20 and its S16D

mutant were performed as described previously [32] Briefly,

the crude extract of Hsp20 in lysis buffer (50 m Tris/HCl,

pH 8.0, 100 mM NaCl, 1 mM EDTA, 0.5 mM phenyl-methanesulfonyl fluoride, 14 mM b-mercaptoethanol) was fractionated with (NH4)2SO4 (0–30% saturation) and subjected to ion-exchange chromatography on a High-Trap

Q column (Amersham-Pharmacia) equilibrated with buffer B (20 mM Tris/acetate, pH 7.6, 10 mM NaCl, 0.1 mM EDTA, 0.1 mM phenylmethanesulfonyl fluoride,

14 mM b-mercaptoethanol) and developed by a linear (10–410 mM) gradient of NaCl Further purification was achieved by hydrophobic chromatography on a phenyl-superose column (Amersham-Pharmacia) equilibrated with

20 mM phosphate buffer (pH 7.0), containing 0.3M (NH4)2SO4, and developed by a decreasing (0.3–0.005M) gradient of (NH4)2SO4 The final preparations of Hsp20, or its S16D mutant, were concentrated by ultrafiltration and stored frozen in buffer B

The initial steps of purification of Hsp27 or its 3D mutant were similar to those described for Hsp20 Hsp27 and its 3D mutant were fractionated by (NH4)2SO4 (0–50% satura-tion) and subjected to ion-exchange chromatography on a High-Trap Q column (Amersham-Pharmacia), followed by gel filtration on a Sephacryl S300 High-Prep 16/60 column (Amersham-Pharmacia) If necessary, further purification was achieved by hydrophobic chromatography on phenyl-superose (Amersham-Pharmacia) Preparations of Hsp27 and its 3D mutant were concentrated by ultrafiltration and stored frozen in buffer B containing 10% glycerol Denaturation and renaturation of sHsp Denaturation and renaturation of Hsp20 and commercial a-crystallin (Sigma) was performed according to van de Klundert et al [15] Recombinant wild-type Hsp20 in buffer B was freeze-dried The samples of freeze-dried Hsp20 or commercial a-crystallin were dissolved in 50 mM phosphate (pH 7.5), containing 100 mMNa2SO4, 0.02% b-mercaptoethanol and

6Murea, up to a final protein concentration of 6 mgÆmL)1, and then stored on ice for 2 h After incubation, the samples were diluted sixfold in the same buffer, minus urea and b-mercaptoethanol, and dialyzed against two changes of the same buffer overnight

IEF and electrophoresis Isoelectrofocusing (IEF) was performed, as described pre-viously [29], in a 5.4% polyacrylamide gel containing 8.5M urea, 2% Triton-X-100, 0.4% ampholine (pH 3–10) and 1.6% ampholine (pH 5–7) Phosphoric acid (10 mM) and sodium hydroxide (20 mM) were used as electrode buffers After fixation and removal of ampholine, the proteins were stained with Coomassie R-250

SDS gel electrophoresis was performed according to Laemmli [33] For quantitative measurements the gels were stained with Coomassie R-250 and evaluated using the programONEDSCAN

Size exclusion chromatography The oligomeric state of sHsp was determined by size exclusion chromatography on Superdex 200 HR 10/30 using the ACTA-FPLC system The column was usually equilibrated with buffer C (20 mM Tris/HCl, pH 7.5, containing 150 m NaCl and 15 m b-mercaptoethanol)

In the case of renaturation experiments, the same column

was equilibrated and developed with 50 mM phosphate

(pH 7.5) containing 100 mM Na2SO4 The column w as

calibrated using the following molecular mass markers:

thyroglobulin (669 kDa), ferritin (440 kDa), catalase

(240 kDa), aldolase (158 kDa), BSA (66 kDa) and

chymo-trypsinogen (25 kDa)

For investigating the exchange of subunits between

Hsp20 and Hsp27, equimolar quantities (0.4 mgÆmL)1

Hsp20 and 0.54 mgÆmL)1Hsp27) of sHsp were mixed in

buffer B The mixture obtained was either immediately

loaded onto the column or incubated for 3 h at 30 or 37C,

or for 15 h at 18C, before chromatography at room

temperature In control experiments, isolated Hsp20 or

Hsp27 were incubated under exactly the same conditions

and subjected to size exclusion chromatography The

protein composition of the fractions obtained in the course

of size exclusion chromatography was analyzed by means of

SDS gel electrophoresis [33]

The effect of pH on the oligomeric state of Hsp20 was

also analyzed by size exclusion chromatography To achieve

this, the Superdex 200 HR 10/30 column was equilibrated

with buffer D (50 mM phosphate, 150 mM NaCl, 1 mM

EDTA, 15 mM b-mercaptoethanol), pH-adjusted to 5.5,

6.0, 6.5, 7.0 or 7.5 The protein sample (150 lL,

0.6 mgÆmL)1) was mixed with an equal volume of 2· buffer

D at the test pH and incubated for 1 h at 20C before

chromatography at room temperature

Chemical crosslinking

Three different methods were used for crosslinking Hsp20

In the first, Hsp20 (0.2 mgÆmL)1) was dialyzed overnight

against 50 mM phosphate buffer (pH 7.5), containing

100 mM Na2SO4 Before SDS gel electrophoresis, the

samples were either treated with an excess of

b-mercapto-ethanol or loaded onto the gel in the absence of

b-mercaptoethanol

In the second method, Hsp20 (0.75 mgÆmL)1) in 0.2M

triethanolamine (pH 7.5) was incubated with

dimethylsube-rimidate (20 mM) for 1 h at 20C The reaction was

stopped by the addition of SDS sample buffer The protein

composition of the samples thus obtained was analyzed by

SDS gel electrophoresis

In the third method, Hsp20 (1 mgÆmL)1), in 20 mM

imidazole/HCl (pH 7.0) containing 150 mM NaCl, was

incubated for 1 h at 30C in the presence of

1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride

(EDC) (5 mM) and N-hydroxysuccinimide (NHS) (5 mM)

The reaction was stopped by the addition of SDS sample

buffer and subjected to SDS/PAGE (15% gel) [33]

CD spectroscopy

sHsp ( 1 mgÆmL)1) were dialyzed overnight, against

50 mMphosphate buffer containing 150 mMNaCl, at three

different pH values (6.0, 6.8 or 7.5) The samples thus

obtained were subjected to centrifugation (12 000 g,

20 min) and the pellet was discarded Far UV CD spectra

were recorded in 0.05 cm cells at room temperature on a

Mark V Jobin Yvon autodichrograph All spectra

presen-ted represent the average of three accumulations

Determination of chaperone activity The chaperone activity of Hsp20 and of bovine lens a-crystallin (Sigma) was determined by their ability to retard or to decrease aggregation of the insulin B-chain (Sigma) [15] All experiments were performed in buffer E (50 mMphosphate, pH 7.5, 100 mMNa2SO4) Insulin (6.5 mgÆmL)1), dissolved in 2.5% acetic acid, was added to the incubation mixture (270 lL) to a final concentration of 0.25 mgÆmL)1 The mixture was incubated at 40C and the reaction started by addition of a water solution of dithio-threitol up to a final concentration of 20 mM Reduction of the disulfide bonds of insulin was accompanied by aggre-gation of the B-chain and an increase of turbidity that was measured at 360 nm on an Ultraspec 3100 Pro spectro-photometer

The chaperone activity of Hsp20 and of commercial a-crystallin was also determined by their ability to retard or

to prevent the heat-induced aggregation and precipitation of yeast alcohol dehydrogenase (ADH) [29,34] The incubation mixture (280 lL) comprised equal volumes of buffer B and buffer F (100 mMphosphate, 300 mMNaCl) at pH 6.0 or 7.0 Yeast ADH (Sigma) was added to the incubation mixture to a final concentration of 0.15–0.26 mgÆmL)1and the sample w as incubated at 42C The reaction was started

by the addition of dithiothreitol and EDTA up to final concentrations of 30 mMand 2 mM, respectively Heating and removal of divalent cations induces the aggregation of ADH; this process was followed at 360 nm on an Ultraspec

3100 Pro spectrophotometer The optical measurement of aggregation was complemented by a centrifugation assay where the samples were withdrawn at different time-points

of incubation and subjected to centrifugation (12 000 g,

10 min) The protein composition of the pellet and super-natant was determined by quantitative SDS gel electro-phoresis [33]

Results

Isolation of human Hsp20 and its S16D mutant

As described in the Materials and methods, we developed procedure for purification of recombinant wild-type human Hsp20 All steps of extraction and purification were performed in the absence of urea or detergents The method provided 5–7 mg of recombinant wild-type Hsp20 from 1 L

of the E coli culture

When the S16D mutant of Hsp20 was expressed in

E coli, most of the protein was insoluble in the lysis buffer and this buffer extracted less than 20% of the protein The S16D mutant that was extracted with lysis buffer was subjected to the same steps of purification as the wild-type protein and, according to the SDS gel electrophoresis, had the same apparent molecular mass as the wild-type protein (Fig 1A) Most of the S16D mutant that was not soluble in the lysis buffer could be dissolved in the same buffer containing 6M urea and was subjected to ion-exchange chromatography on a High-Trap Q column in buffer B, containing 6M urea, at pH 8.5 According to SDS gel electrophoresis, the apparent molecular mass of the protein thus obtained was 2–3 kDa less than the corresponding molecular mass of the wild-type Hsp20 or water-soluble

S16D mutant of Hsp20 (Fig 1A) Tandem MS analysis

performed by Dr R Wait (Kennedy Institute of

Rheuma-tology Division, Faculty of Medicine, Imperial College,

London) was unable to detect peptides beyond residue 102

in the urea-soluble S16D mutant (Fig 1C), whereas both

N- and C-terminal peptides were clearly detected in the

wild-type Hsp20 and water soluble S16D preparations

(Fig 1C) IEF, under denaturing conditions, indicated that

the pI value of the urea-soluble S16D mutant was higher

than that of the intact wild-type Hsp20 (Fig 1B) By

analyzing the distribution of the charge residues in the

C-terminal region of Hsp20, and by calculating the

theor-etical pI values of differently truncated species of Hsp20, we

found that cleavage of the polypeptide chain only between

residues 122 and 127 resulted in the formation of a protein

species with a theoretical pI higher than that of intact

Hsp20 Thus, we propose that during expression or

purification, the S16D mutant tends to undergo proteolysis

of the C-terminal region All experiments described in this

report were performed with an S16D mutant that was

soluble in the absence of urea The pI value of this soluble

S16D mutant was 0.2 units lower than that of the wild-type

Hsp20 A similar shift of pI was observed previously for the

point mutants of Hsp25 with replacement of Ser with

Asp [29]

The method developed for purification of recombinant

human Hsp27 and its 3D mutant was similar to that

described previously [32,36] and yields 5–7 mg of

homo-geneous protein from 1 L of E coli culture As in the case

with Hsp20, all stages of Hsp27 purification were performed

in the absence of urea or detergents

Oligomeric state of recombinant human Hsp20 Recombinant human wild-type Hsp20 was subjected to size exclusion chromatography, at neutral pH, on a Superdex

200 column under three different experimental conditions

In the first we loaded the column with 240 lL of a 2.6 mgÆmL)1concentration of protein (curve 1 on Fig 2A)

In the second, the column was loaded with the same volume

of 0.3 mgÆmL)1protein (curve 2 on Fig 2A) In the third, the column was loaded with 30 lL of protein at a concentration of 2.6 mg mL)1(curve 3 on Fig 2A) Under these experimental conditions, the apparent molecular mass

of recombinant human wild-type Hsp20 was 58, 54 and

56 kDa for the first, second and third experimental condi-tions, respectively We also analyzed the effect of urea induced denaturation, followed by renaturation, on the oligomeric state of Hsp20 As shown in Fig 2B (curves 3 and 4) denaturation–renaturation showed practically no effect on the oligomeric state of Hsp20, and both intact and

Fig 1 Characterization of recombinant human wild-type Hsp20 and its

S16D mutant SDS gel electrophoresis (A) and IEF (B) of wild-type

Hsp20 (1), and of its S16D mutant that is soluble in the absence (2) and

in the presence (3) of urea Arrows indicate the position of molecular

mass markers (14 and 25 kDa) and direction of pH gradient (C)

Primary structure of wild-type Hsp20, and of its S16D mutant soluble

in the absence and in the presence of urea, as determined by HPLC/

tandem MS The experimentally determined sequence is shown in

bold; shadowed residues were not detected in the experiment.

Fig 2 Size-exclusion chromatography of recombinant human wild-type Hsp20 (A) Lack of effect of dilution or sample volume on the apparent molecular mass of Hsp20 Equal volumes (240 lL) containing 624 lg (1) or 72 lg (2) of Hsp20, or equal quantities (72 lg) of Hsp20 dissolved in 240 lL (2) or 30 lL (3) volumes, were subjected to chromatography on a Superdex 200 HR 10/30 column (B) Effect of urea-induced denaturation followed by renaturation on the chroma-tographic behavior of small heat shock proteins a-Crystallin (1 and 2) and wild-type Hsp20 (3 and 4) were subjected to size-exclusion chromatography before (1 and 3) or after (2 and 4) urea-induced denaturation, followed by renaturation.

renatured proteins had an apparent molecular mass of

54–56 kDa However, denaturation–renaturation of

com-mercial a-crystallin was accompanied by a significant

decrease of molecular mass The molecular mass of

a-crystallin that was not subjected to urea treatment was

> 900 kDa, whereas after urea treatment and renaturation

its molecular mass w as 570 kDa (Fig 2B)

As size-exclusion chromatography was insufficient for the

exact estimation of oligomeric forms of Hsp20, and the

apparent molecular mass of 54–56 kDa determined by this

method may correspond to dimers or trimers of Hsp20, we

performed additional crosslinking experiments The

removal of b-mercaptoethanol was accompanied by the

appearance of an additional band of molecular mass

40 kDa, as shown by SDS/PAGE (Fig 3A) This band

disappeared if, prior to electrophoresis, the sample was

treated w ith an excess of b-mercaptoethanol Therefore, we

suggest that the 40 kDa band corresponds to Hsp20 dimer

crosslinked via single Cys46 Crosslinking of Hsp20 with

dimethylsuberimidate was also accompanied by the

forma-tion of an addiforma-tional band with molecular mass 40 kDa

(Fig 3B), that probably also corresponds to Hsp20 dimer

Similar results were obtained if Hsp20 was subjected to

zero-length crosslinking by EDC and NHS (Fig 3C) In

this case we observed two or three closely separated bands

with apparent molecular mass 38–40 kDa that probably

correspond to isomers of Hsp20 dimers Thus, under the

experimental conditions used, Hsp20 predominantly forms

dimers of 40 kDa molecular mass, as judged by SDS gel

electrophoresis, and 54–58 kDa by size-exclusion

chroma-tography

We considered that changes in pH might somehowaffect

the quaternary structure of Hsp20 At pH 7.5–7.0 Hsp20

was eluted as a more or less symmetrical peak with apparent

molecular mass 54–58 kDa (Fig 4) At pH 6.5, both

wild-type protein and its S16D mutant were eluted as broader

peaks with a slightly smaller apparent molecular mass (46–47 kDa) (Fig 4) When the pH was decreased to 6.0, two peaks with apparent molecular masses of 47–50 and 28–30 kDa were observed on the chromatogram (Fig 4)

At pH 5.5, the high molecular mass peak completely disappeared and the small molecular mass peak became broader and more asymmetric (Fig 4) A decrease in pH from 7.5 to 5.5 was accompanied not only by a decrease of the apparent molecular mass of Hsp20, but also by a decrease in the area under the protein peaks on the chromatogram Acidification probably results in the disso-ciation of small oligomers of Hsp20 and its S16D mutant to monomers that tend to unfold and aggregate These aggregates are retarded on the top of the column and therefore not detected on the chromatogram

The data presented indicates that acidic pH induced unfolding of Hsp20 In order to confirm this, we analyzed far UV CD spectra of Hsp20 and a-crystallin at different

pH values At a high concentration of wild-type Hsp20 ( 1.0 mgÆmL)1), dialysis against pH 6.0 buffer was accom-panied by partial protein precipitation The molar ellipticity

of Hsp20 remaining in the supernatant ( 0.5 mgÆmL)1) had a negative maximum at 220 nm (Fig 5A) After dialysis at pH 6.8, wild-type Hsp20 ( 1.0 mgÆmL)1) w as predominant in the supernatant and the maximum peak of molar ellipticity was shifted to 218 nm (Fig 5A) Dialysis of wild-type Hsp20 ( 1.0 mgÆmL)1) at pH 7.5 w as not accompanied by any precipitation and the molar ellipticity

at pH 7.5 was lower than that at acidic pH values with a shift in the maximum to 216 nm The data presented confirm that acidification leads to partial unfolding and precipitation of Hsp20 and indicate that the secondary (or tertiary) structure of Hsp20 remaining in the supernatant at acidic pH is different from that at neutral pH values Similar results were obtained with the S16D mutant of Hsp20 (data

Fig 3 Crosslinking of Hsp20 (A) Formation of disulfide crosslinked

Hsp20 dimers A sample of oxidized Hsp20 treated with an excess of

b-mercaptoethanol (2), or loaded onto the gel without the addition of

reducing agents (3) (B) Crosslinking of Hsp20 with

dimethylsube-rimidate Hsp20 before (2) or after (3) incubation with 20 m M

dimethylsuberimidate (C) Zero-length crosslinking of Hsp20 Hsp20

before (2) and after (3) incubation with

1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride (5 m M ) and N-hydroxysuccinimide

(5 m M ) In all cases the mixture of standards containing proteins with

molecular masses 94, 67, 43, 30, 20 and 14 kDa was loaded on the first

track.

Fig 4 Effect of pH on the oligomeric state of recombinant human wild-type Hsp20 and its S16D mutant Three-hundred microliter samples containing 90 lg of wild-type Hsp20 (solid lines) or its S16D mutant (dotted lines) were loaded onto the column of Superdex 200 HR 10/30 equilibrated with buffer D (50 m M phosphate, 150 m M NaCl, 1 m M

EDTA, 15 m M b-mercaptoethanol) with a pH of 7.5, 7.0, 6.5, 6.0 or 5.5 For clarity, the pairs of elution profiles obtained at different pH values are shifted from each other by 10 mAu.

not shown) Analogous experiments were performed with

commercial a-crystallin In this case, independently of pH,

a-crystallin was not precipitated and remained in the

supernatant The changes of pH in the range of 6.0–7.5

weakly affect both amplitude and the position of maximum

on the far UV CD spectra of a-crystallin (Fig 5B) Thus,

acidification induced small changes in the secondary (or

tertiary) structure of a-crystallin and these changes were not

accompanied by protein aggregation As already

men-tioned, acidification induces substantial changes in the

secondary structure of Hsp20 These structural changes

probably result in the dissociation of Hsp20 dimers and

aggregation of partially unfolded monomers

Chaperone activity of human Hsp20

The reduction of disulfide bonds induces dissociation and

aggregation of the insulin B-chain that is accompanied by a

substantial increase in the optical density (Fig 6, curve 1)

At pH 7.5, the addition of increasing quantities of intact

wild-type Hsp20 results in an increase of the lag period and

a decrease in the amplitude of light scattering Significant

retardation of the insulin B-chain aggregation was observed

at an insulin/Hsp20 ratio of 2 : 1 At a mass ratio of 1 : 1,

the sHsp almost completely prevented the aggregation of

reduced insulin (Fig 6A) Denaturation by 6M urea followed by renaturation had no effect on the chaperone activity of the wild-type Hsp20, and complete prevention of insulin aggregation was achieved at the same Hsp20/insulin ratio as for intact protein (Fig 6B) The S16D mutant of Hsp20 also decreased the aggregation of insulin (Fig 6C); however, it was less effective than the wild-type protein Denaturation–renaturation of the S16D mutant only weakly affected its chaperone properties (Fig 6D) Com-mercial a-crystallin that was not subjected to urea treatment was very ineffective in preventing reduction-induced aggre-gation of insulin Even at a ratio of 1 : 1, a-crystallin only slightly decreased the aggregation of insulin (Fig 6E) Urea-induced denaturation followed by renaturation significantly improved the chaperone activity of a-crystallin (Fig 6F) This was probably caused by a change in the aggregation state of a-crystallin that was induced by urea treatment and identified by size-exclusion chromatography (see Fig 2B) However, even after treatment with urea, the chaperone activity of a-crystallin was similar to that of the wild-type Hsp20 Thus, at pH 7.5 and with reduced insulin as a model substrate, the chaperone activity of the wild-type Hsp20 was comparable to or greater than that of commercial a-crystallin

At pH 7.0, the heating of isolated ADH in the absence of divalent cations was accompanied by aggregation and a large increase in the light scattering (Fig 7, curve 1) Addition of increasing quantities of the wild-type Hsp20 resulted in retardation of the onset of aggregation and a decrease in the amplitude of light scattering (Fig 7A, curves 2–5) At the ADH/Hsp20 ratio of 1 : 1 (wt/wt), aggregation

of ADH was completely prevented Similar results were obtained with the S16D mutant of Hsp20 (Fig 7B) and a-crystallin (Fig 7C) However, at a lower concentration, when the ratio of ADH/sHsp was 2 : 1 (wt/wt), the efficiency of three sHsp decreased in the following order: wild-type Hsp20 > S16D mutant > a-crystallin (Fig 7D) Thus, phosphorylation (or a mutation mimicking phos-phorylation) decreased the chaperone activity of Hsp20 measured both with insulin and ADH (Figs 6 and 7) It is worthwhile to note that at the same time, phosphorylation

of Ser16 of Hsp20 significantly enhanced the relaxation effect of Hsp20 on the smooth muscle contraction [16–23] The optical method used for measuring the chaperone activity of Hsp20 was complemented by the centrifugation assay Upon heating, isolated ADH formed aggregates that were easily precipitated and, after only 20 min of incubation, more than 75% of the ADH was detected in the pellet (Fig 7E, curve 1) After 60 min of incubation, isolated ADH was completely aggregated and precipitated a-Crystallin was rather ineffective in preventing the aggregation of ADH (Fig 7E, curve 2) This fact seems to contradict with the results obtained by light scattering where a-crystallin at least partially inhibited the aggregation of ADH (Fig 7C) However, this apparent contradiction can be explained by the suggestion that small complexes are effectively precipi-tated during centrifugation but contribute only slightly to light scattering These complexes can be formed either by denatured ADH or by denatured ADH being bound to sHsp Indeed, we found that at the end of incubation more than 30% of a-crystallin was coprecipitated with denatured ADH (Fig 7F) Hsp20 was more effective in preventing

Fig 5 Far UV CD spectra of the wild-type Hsp20 (A) and commercial

a-crystallin (B) The spectra were recorded at pH 6.0 (1), 6.8 (2) or 7.5

(3).

precipitation of denatured ADH (Fig 7E, curve 3) Much

smaller quantities of Hsp20 were coprecipitated with

dena-tured ADH (Fig 7F, curve 2) It is worthwhile mentioning

that isolated sHsp were not precipitated in the absence of

ADH, even after 60 min of incubation (Fig 7F, curve 3)

Similar results were obtained with the S16D mutant of Hsp20

(data not shown) Thus, at pH 7.0, Hsp20 is a more potent

chaperone than a-crystallin, probably because complexes

formed by Hsp20 with denatured ADH are smaller or more

soluble than the corresponding complexes formed by

dena-tured ADH and a-crystallin

As discussed above, a decrease in the pH to pH 6.0 may

induce partial unfolding and dissociation of small oligomers

formed by Hsp20 or its S16D mutant (Figs 4 and 5) As

unfolding and dissociation may affect the chaperone activity

of Hsp20, we analyzed the effect of different sHsps on the

aggregation of ADH at pH 6.0 Under these conditions,

heating also induced the aggregation of ADH (Fig 8, curve

1) Addition of increasing quantities of wild-type Hsp20

increased the rate and amplitude of light scattering (Fig 8A,

curves 2–5) Thus, the wild-type Hsp20, instead of

prevent-ing, promotes the aggregation of ADH This is probably a

result of the formation of insoluble complexes of Hsp20 and

denatured ADH Indeed, as shown in Figs 8E,F, incubation

of ADH with the wild-type Hsp20 resulted in the formation

of a pellet containing both proteins At pH 6.0 and at the low

concentrations used in the experiment, isolated Hsp20 itself is

completely soluble and does not precipitate (Fig 8A, curve

6, Fig 8F, curve 3) However, complexes formed by partially

unfolded Hsp20 and denatured ADH tend to aggregate and

precipitate

Qualitatively similar results were obtained with the S16D mutant of Hsp20 (Fig 8B) However, in this case addition

of increasing quantities of the S16D mutant resulted in a small retardation of the onset of ADH aggregation and either did not affect the amplitude of light scattering or slightly increased it Using the centrifugation assay we found that after a short incubation, the S16D mutant predominantly remained in the supernatant, whereas after a long incubation a large proportion of the S16D mutant coprecipitated with ADH (data not shown)

At pH 6.0, a lowconcentration of a-crystallin either did not affect or slightly increased the thermal aggregation of ADH (Fig 8C) At an ADH/crystallin ratio of 1 : 1, a significant decrease in the extent of ADH aggregation was observed (Fig 8C, curve 5) a-Crystallin was more effective than Hsp20 in preventing the precipitation of ADH (Fig 8E) and smaller quantities of a-crystallin were copre-cipitated with denatured protein (Fig 8F) Therefore, at

pH 6.0, a-crystallin possessed higher chaperone activity than Hsp20 or its S16D mutant

Formation of mixed oligomer complexes between recombinant human Hsp20 and Hsp27

In tissue extracts, Hsp20 forms high molecular weight complexes [9,19] and is copurified with aB-crystallin and Hsp27 [8,9] Indirect data also indicate that Hsp20 may interact with Hsp27 and aB-crystallin [10] However, to our knowledge, the hetero-oligomeric complexes formed by Hsp20 with other sHsp have not been characterized and reported in the literature Therefore, we investigated the

Fig 6 Influence of recombinant human Hsp20

(A and B), the S16D mutant of Hsp20 (C and

D) or commercial a-crystallin (E and F) before

(A, C and E) or after (B, D and F) urea

treat-ment followed by renaturation on the reduction

induced aggregation of insulin The chaperone

activity was measured by the prevention of

dithiothreitol-induced aggregation of insulin

(0.25 mgÆmL)1) at 40 C under conditions

described in the Materials and methods.

Insulin alone (1), or insulin in the presence of

0.06 mgÆmL)1(2), 0.12 mgÆmL)1(3) or

0.25 mgÆmL)1(4) small heat shock proteins.

interaction of Hsp20 and its mutant mimicking

phosphory-lation with Hsp27

Interaction of the wild-type Hsp20 with the wild-type

Hsp27 was analyzed by means of size-exclusion

chroma-tography Hsp20 and Hsp27 were eluted from the Superdex

200 column as single peaks with molecular masses of 56

and 560 kDa, respectively The chromatographic behavior

of isolated Hsp20 and Hsp27 was not altered if, prior to

loading on the column, these proteins were preincubated for

3 h at 30 or 37C or for 15 h at 18 C If equimolar

quantities of these two proteins were mixed and immediately

subjected to size-exclusion chromatography, two well

sep-arated peaks with apparent molecular masses 560 and

56 kDa, corresponding to isolated Hsp27 and Hsp20, were

detected on the chromatogram (Fig 9A, curve 1)

Accord-ing to SDS/PAGE, the high molecular mass peak contained

exclusively Hsp27, whereas the small molecular mass peak

contained only Hsp20 The elution profile was not changed

upon preincubation of this mixture of proteins for 15 h at

18C (data not shown) If, prior to loading on the column,

the mixture of the wild-type Hsp27 and Hsp20 was

incubated for 3 h at 30C, the elution profile was

signifi-cantly changed The amplitude of the high molecular mass

peak decreased and its apparent molecular mass was

470 kDa This peak was asymmetric with a prominent

trailing edge In addition, a newpeak, with an apparent

molecular mass of 91 kDa, appeared on the chromatogram

and the peak corresponding to isolated Hsp20 (56 kDa)

decreased in size (Fig 9A, curve 2) Even more prominent

changes were observed if the mixture of two wild-type proteins was incubated for 3 h at 37C (Fig 9A, curve 3)

In this case we observed two protein peaks with apparent molecular masses of 300 and 100 kDa, and each of these peaks, according to SDS/PAGE, contained almost identical quantities of Hsp27 and Hsp20 (insert on Fig 9A) Similar results were obtained if the wild-type Hsp27 was mixed with the S16D mutant of Hsp20 Thus, after mixing at 30–37C, homo-oligomers of wild-type Hsp27 and Hsp20 (or the S16D mutant of Hsp20) may rearrange, forming mixed hetero-oligomers that contain similar quantities of these two sHsp

The isolated 3D mutant of Hsp27 produces a broad peak with apparent molecular mass 96–106 kDa A significant decrease in molecular mass compared with the wild-type Hsp27 is a result of the fact that mutations mimicking phosphorylation induce dissociation of large oligomers of Hsp27 [29–31] As already mentioned, the wild-type Hsp20 and its S16D mutant are eluted as a single peak with an apparent molecular mass of 56 kDa A mathematical summation of elution profiles obtained for the 3D mutant

of Hsp27 and the wild-type Hsp20 is presented on curve 1 of Fig 9B Only one broad asymmetric peak, with an apparent molecular mass of 100 kDa, was observed if, immediately after mixing, the two proteins were loaded onto the column (Fig 9B, curve 2) The position and shape of this peak were different from the sum of the two elution profiles obtained for the isolated 3D mutant of Hsp27 and wild-type Hsp20 (compare curves 1 and 2 on Fig 9B) If the mixture of the

Fig 7 Effect of Hsp20, its S16D mutant and a-crystallin on the heat-induced aggregation of yeast alcohol dehydrogenase (ADH) at pH 7.0 Aggregation of ADH (0.26 mgÆmL)1) w as induced by the addition of EDTA and dithiothreitol and incubation at 42 C, and was measured either by light scattering (A–D)

or by centrifugation (E–F) Panels A–C, ADH alone (1), or ADH in the presence of 0.026 mgÆmL)1(2), 0.052 mgÆmL)1(3), 0.13 mgÆmL)1(4) or 0.26 mgÆmL)1(5) of the wild-type Hsp20 (A), the S16D mutant of Hsp20 (B), or a-crystallin (C) (D) Compar-ison of the effect of different small heat shock proteins (0.13 mgÆmL)1) on the aggregation of ADH (0.26 mgÆmL)1) ADH alone (1), or ADH in the presence of the wild-type Hsp20 (2), the S16D mutant of Hsp20 (3) or a-crys-tallin (4) (E) Heat-induced precipitation of isolated ADH (0.26 mgÆmL)1) (1), or ADH

in the presence of either a-crystallin (0.13 mgÆmL)1) (2) or wild-type Hsp20 (0.13 mgÆmL)1) (3) The percentage of ADH

in the pellet is plotted against the time of incubation (F) Co-precipitation of a-crystal-lin (1) or wild-type Hsp20 (2) with heat denatured ADH The percentage of small heat shock protein in the pellet is plotted against the time of incubation Lack of precipitation

of isolated small heat shock proteins is shown

on curve 3.

3D mutant of Hsp27 and wild-type Hsp20 (or S16D mutant

of Hsp20) were incubated for 3 h at 30C, only one peak

with an apparent molecular mass 95 kDa was detected on

the chromatogram Thus, homo-oligomers formed by the

3D mutant of Hsp27 and wild-type Hsp20 (or its S16D

mutant) rapidly rearrange, forming hetero-oligomeric

complexes

Discussion

To our knowledge there are only two publications that

report a detailed investigation of the biochemical properties

of isolated Hsp20 Kato et al [9] reported that Hsp20 is

presented in so-called aggregated and dissociated forms

with apparent molecular masses of 200–300 and 67 kDa,

respectively Using size-exclusion chromatography, van de

Klundert et al [15] also detected two forms of Hsp20, with

apparent molecular masses of 470 and 43 kDa, that,

depending on the protein concentration may convert to

each other In our case, size-exclusion chromatography

revealed only an oligomer of Hsp20 with an apparent

molecular mass of 54–58 kDa (Fig 2) According to our

crosslinking experiments, Hsp20 predominantly forms

dimers with an apparent molecular mass of 40 kDa, as

judged by SDS/PAGE (Fig 3) Therefore, the question

arises as to why we did not observe the high molecular mass

oligomers of Hsp20 detected previously by Kato et al [9]

and van de Klundert et al [15]

We presumed that the exposure of Hsp20 to a high

concentration of urea [9,15], or to urea and detergents [35],

as used in the previously published reports, might affect the quaternary structure of Hsp20 In order to verify this, we denatured Hsp20 (purified by our method) by 6Murea and renatured it under the conditions described by van de Klundert et al [15] This treatment had no effect either on the apparent molecular mass, as determined by size-exclusion chromatography, or on the chaperone activity measured by the prevention of insulin aggregation Thus, treatment with urea cannot explain the difference in molecular mass identified in our experiments and in data published previously [9,15] Another explanation was based

on the fact that practically all previously published results were obtained using rat Hsp20 [9,15,35], whereas in the present study human Hsp20 was used Although rat and human Hsp20 are highly homologous ( 90% identity of the primary structure), the rat Hsp20 consists of 162 residues, whereas the human protein consists of 160 residues and the dipeptide deletion is located at the very C-terminal end (residues 154–155 of rat Hsp20) It is known that the C-terminal extension affects the oligomerization and chap-erone action of Hsp27 [37] Therefore, we propose that the difference in the C-terminal extension of human and rat Hsp20 results in a different oligomeric state of these two proteins However, this suggestion is speculative and needs experimental verification Finally, as previously mentioned, when expressing the S16D mutant we found that truncation

of 30–50 C-terminal amino acid residues results in the formation of protein aggregates that were soluble only in the presence of a high concentration of urea Previously it has been shown that the truncation of a short C-terminal

Fig 8 Influence of Hsp20, its S16D mutant

and a-crystallin on the heat-induced

aggrega-tion of yeast alcohol dehydrogenase (ADH) at

pH 6.0 Aggregation of ADH (0.15 mgÆmL)1)

was measured either by light scattering (A–D)

or by centrifugation (E–F) A–C, ADH alone

(1), or ADH in the presence of 0.015 mgÆmL)1

(2), 0.03 mgÆmL)1(3), 0.075 mgÆmL)1(4) or

0.15 mgÆmL)1(5) of the wild-type Hsp20 (A),

the S16D mutant of Hsp20 (B) or a-crystallin

(C) Lack of aggregation of isolated small heat

shock proteins (0.15 mgÆmL)1) is show n

on curve 6 (D) Comparison of the effect

of different small heat shock proteins

(0.15 mgÆmL)1) on the aggregation of ADH

(0.15 mgÆmL)1) ADH alone (1), or ADH in

the presence of wild-type Hsp20 (2), the S16D

mutant of Hsp20 (3) or a-crystallin (4) (E)

Heat-induced precipitation of isolated ADH

(0.15 mgÆmL)1) (1), or ADH in the presence of

either wild-type Hsp20 (0.15 mgÆmL)1) (2) or

a-crystallin (0.15 mgÆmL)1) (3) The

percent-age of ADH in the pellet is plotted against the

time of incubation (F) Co-precipitation of

wild-type Hsp20 (1) or a-crystallin (2) with

heat denatured ADH The percentage of small

heat shock proteins in the pellet is plotted

against the time of incubation Lack of

preci-pitation of isolated small heat shock proteins

is show n on curve 3.

peptide increases the hydrophobicity of Hsp27 and

decrea-ses its chaperone effect [37] There were no signs of

proteolytic degradation in the samples of Hsp20 purified

by Kato et al [9] and van de Klundert et al [15]; however,

truncation of a short (2–4 kDa) fragment can be easily

overlooked Therefore, we suggest that during expression

and/or purification, Hsp20 can undergo limited proteolysis,

and deletion of a short C-terminal fragment may result in

the formation of a mixture of small and large aggregates

that were reported in the previous publications

Van de Klundert et al [15] claimed that Hsp20 is a poor chaperone In our investigation we found that at neutral or slightly alkaline pH, Hsp20 has comparable or even higher chaperone activity than commercial a-crystallin (Figs 6 and 7) sHsp protect the cell against unfavorable conditions, among them acidosis For instance, the data of Wang [38] indicate that a-crystallin prevents acidification-induced aggregation of creatine kinase and luciferase In our study,

at pH 6.0, a-crystallin partially prevented the aggregation of yeast ADH, whereas the wild-type Hsp20 retained its ability

to interact with denatured substrates, but, instead of preventing, promoted the aggregation of denatured ADH (Fig 8) This was caused by the fact that at low pH Hsp20 tends to unfold, and dimers of Hsp20 dissociate to monomers Under these conditions, partially unfolded monomers of Hsp20 interact with denatured ADH and form poorly soluble complexes Similar effects have been observed for the truncated form of Hsp27 [37] and for the alternative splicing product of aA-crystallin [39] Thus, although Hsp20 and a-crystallin are closely related, they have different properties Acidification induced a small decrease of the chaperone activity of a-crystallin, but significantly decreased the chaperone activity of Hsp20 Similar conclusions were reached by van de Klundert et al [40], who postulated that Hsp20 and a-crystallin might be involved in distinct protective activities in living cells It is worthwhile of note that the measurement of chaperone activity and analysis of the quaternary structure of Hsp20 was performed in buffers with compositions that are not completely physiological This was implemented in order to compare our results with data in the published literature However, limitations of biochemical experiments should be taken into account when interpreting our results at a physiological level

The data obtained with the help of a yeast two-hybrid system indicate that different sHsps may interact with each other [10] Moreover, Bova et al [11], using the method of fluorescence energy transfer, have directly shown that Hsp27 and a-crystallin may form mixed oligomers If crude extracts of skeletal muscle or heart were subjected to size exclusion chromatography, Hsp20 was eluted in one or two high molecular mass peaks Kato et al [9] detected two peaks with apparent molecular masses 200–300 and

68 kDa, whereas Pipkin et al [19] detected only one peak with an apparent molecular mass of 230 kDa Brophy et al [17] postulated that cAMP-dependent phosphorylation results in the change of macromolecular associations of Hsp20 Finally, Hsp20 is usually copurified with Hsp27 and a-crystallin [9,19] Thus, all these data indirectly indicate the formation of mixed oligomer complexes between Hsp20 and a-crystallin or Hsp27 To verify this, we analyzed the chromatographic behavior of the mixture of Hsp20 and Hsp27 In good agreement with Bova et al [41], we found that at lowtemperature the rate of subunit exchange between the wild-type Hsp20 and Hsp27 was very slow However, at 30 or 37C the rate of exchange was significantly increased and we detected two hetero-oligo-meric complexes with apparent molecular masses 100 and

300 kDa that contained similar quantities of Hsp20 and Hsp27 subunits (Fig 9A) Mutation S16D, imitating phos-phorylation of the Ser16 of Hsp20, had no significant effect

on the rate of subunits exchange or on the composition or

Fig 9 Formation of hetero-oligomeric complexes between Hsp27 and

Hsp20 (A) Rearrangement of the complexes formed by the wild-type

Hsp27 and Hsp20 The wild-type Hsp27 and Hsp20 were loaded onto

the column immediately after mixing (1) or were incubated at 30 C (2)

or at 37 C (3) for 3 h For clarity the profiles are shifted from each

other by 40 mAu The protein composition of profile 3 fractions 25–33

is shown on the insert The positions of Hsp27 and Hsp20 are marked

by arrows (B) Rearrangement of the complexes formed by the 3D

mutant of Hsp27 and the wild-type Hsp20 A mathematical

summa-tion of the elusumma-tion profiles of the isolated 3D mutant of Hsp27 and

isolated wild-type Hsp20 is presented on curve 1 Experimental elution

profiles of the mixture of the 3D mutant of Hsp27 and Hsp20 loaded

onto the column immediately after mixing (2), or after incubation for

3 h at 30 C (3) For clarity the profiles are shifted from each other by

40 mAu.