Báo cáo khóa học: Chaperone activity of cytosolic small heat shock proteins from wheat pptx

We studied the chaperone activity of dodecameric wheat TaHsp16.9C-I, a class I cytosolic sHsp from plants and the only eukaryotic sHsp for which a high resolution structure is available,

Chaperone activity of cytosolic small heat shock proteins

from wheat

Eman Basha1,*, Garrett J Lee1,†, Borries Demeler2and Elizabeth Vierling1

1

Department of Biochemistry & Molecular Biophysics, University of Arizona, Tucson, AZ, USA;2Department of Biochemistry, University of Texas, San Antonio, TX, USA

Small Hsps (sHsps) and the structurally related eye lens

a-crystallins are ubiquitous stress proteins that exhibit

ATP-independent molecular chaperone activity We studied the

chaperone activity of dodecameric wheat TaHsp16.9C-I, a

class I cytosolic sHsp from plants and the only eukaryotic

sHsp for which a high resolution structure is available,

along with the related wheat protein TaHsp17.8C-II, which

represents the evolutionarily distinct class II plant cytosolic

sHsps Despite the available structural information on

TaHsp16.9C-I, there is minimal data on its chaperone

activity, and likewise, data on activity of the class II

pro-teins is very limited We prepared purified, recombinant

TaHsp16.9C-I and TaHsp17.8C-II and find that the class II

protein comprises a smaller oligomer than the dodecameric

TaHsp16.9C-I, suggesting class II proteins have a distinct

mode of oligomer assembly as compared to the class I proteins Using malate dehydrogenase as a substrate, TaHsp16.9C-I was shown to be a more effective chaperone than TaHsp17.8C-II in preventing heat-induced malate dehydrogenase aggregation As observed by EM, mor-phology of sHsp/substrate complexes depended on the sHsp used and on the ratio of sHsp to substrate Surprisingly, heat-denaturing firefly luciferase did not interact signifi-cantly with TaHsp16.9C-I, although it was fully protected

by TaHsp17.8C-II In total the data indicate sHsps show substrate specificity and suggest that N-terminal residues contribute to substrate interactions

Keywords: sHsps; a-crystallins; protein folding; protein aggregation; luciferase

Small Hsps (sHsps) and the structurally related eye lens

a-crystallins are ubiquitous stress proteins that exhibit

ATP-independent molecular chaperone activity [1] sHsps are

defined by a conserved C-terminal domain of 90 amino

acids, called the a-crystallin domain, which is flanked by a

short C-terminal extension and a variable length,

noncon-served N-terminal arm [2] sHsps range in size between 15

and 40 kDa and form high molecular mass oligomers of

9–32 subunits, depending on the sHsp sHsps are very

efficient at binding denatured proteins, and current models

propose that they function to prevent irreversible protein

aggregation and insolubilization, thereby increasing the

stress resistance of cells [1]

Plants are unusual among eukaryotes in that they express

multiple sHsp gene families that appear to have evolved

after the divergence of plants and animals [3–5] While in

other organisms sHsps are found in the cytosol, plants

express both cytosolic sHsps and specific isoforms targeted

to intracellular organelles There are at least two types of sHsps in the cytosol, referred to as class I and class II proteins, which share only 50% identity in the a-crystallin domain and are estimated to have diverged over 400 million years ago [6] Five separate gene families encode mitochon-drion, plastid, peroxisomal, nuclear and endoplasmic reticulum-localized sHsps, each with appropriate organelle targeting signals [3,4] The evolutionary expansion of the plant sHsp family may be the result of selection pressure for tolerance to the many types of stresses encountered

by plants when they made the transition to growth on land

In what way these sHsp families may serve specialized functions is unknown

High resolution structures of two sHsp oligomers are now available: the class I plant sHsp, Triticum aestivum (wheat) TaHsp16.9 C-I, and an sHsp from a prokaryotic archeaon, Methanococcus jannaschii MjHsp16.5 Although TaHsp16.9C-I is a dodecameric disk [7], and MjHsp16.5 forms a sphere composed of 24 subunits [8], both sHsp oligomers are built from a conserved dimer structure, and similar contacts between dimers stabilize the oligomer Although the oligomer is the dominant species at optimal temperature for the organism, sHsp oligomers are in rapid equilibrium with dissociated species as revealed by subunit exchange [7,9–12], and some sHsps dissociate to a stable suboligomeric species at the heat stress temperatures at which they are predicted to be most active [7,13] These dynamic properties are likely to be important for sHsp function

The mechanism of sHsp chaperone action is an area of active research In vitro studies have shown that sHsps

Correspondence to E Vierling, Department of Biochemistry,

University of Arizona, Tucson, AZ 85721–0106, USA.

Fax: +1 520 621 3709, Tel.: + 1 520 621 1601,

E-mail: vierling@u.arizona.edu

Abbreviations: Hsp(s), heat shock protein(s); sHsp(s), small heat shock

protein(s); MDH, porcine mitochondrial malate dehydrogenase;

Luc, firefly luciferase; SEC, size exclusion chromatography.

Present addresses: *Department of Botany, Tanta University, Tanta,

Egypt;
Monsanto, Co., 800 N Lindbergh Blvd., St Louis, MO

63167, USA.

(Received 16 December 2003, revised 29 January 2004,

accepted 6 February 2004)

bind partially unfolded substrate proteins in an

ATP-independent fashion [1] Current models suggest that

it is an sHsp dimer or other suboligomeric species that is

the active substrate-binding unit [7,14] However, sHsp/

substrate complexes are typically significantly larger than

sHsp oligomers, consistent with some kind of

reassocia-tion of sHsp subunits after substrate binding A few

studies have identified regions of sHsps that potentially

interact with substrate [15–17], and sHsp/substrate

inter-actions are proposed to involve hydrophobic contacts [1]

The inactive, non-native substrate that is associated with

the sHsp can be refolded by ATP-dependent chaperones,

primarily the Hsp70/DnaK system, although under some

conditions, Hsp100/ClpB or GroEL may also be required

[14,15,18–20]

To better define sHsp chaperone function and the

potential differences in function between the divergent

cytosolic class I and II plant sHsps, we initiated in vitro

studies of the chaperone activity of class I wheat

TaHsp16.9C-I in comparison to a wheat class II protein,

TaHsp17.8C-II As mentioned above, TaHsp16.9C-I is the

only eukaryotic sHsp for which a high resolution structure is

available, but no significant characterization of its

chaper-one activity has been performed Wheat TaHsp17.8C-II is

 33% identical overall to TaHsp16.9C-I Only two

previ-ous studies have examined the chaperone activity of this

class of sHsp, and no plant class II sHsp has been tested

for the ability to support substrate refolding [21,22] Both

TaHsp16.9C-I and TaHsp17.8C-II are undetectable in

vegetative plant tissues, but accumulate dramatically during

heat stress and are also expressed during seed development

(E Basha & E Vierling, unpublished observation) In vivo

studies indicate that plant class I and II sHsps, although

both present in the cytosol, do not coassemble into mixed

oligomers, suggesting they have distinct functions in the

cell [23]

We prepared purified, recombinant TaHsp16.9C-I and

TaHsp17.8C-II and found that the class II protein

compri-ses a smaller oligomer than the dodecameric TaHsp16.9C-I,

suggesting class II proteins have a distinct mode of oligomer

assembly as compared to the class I proteins Using malate

dehydrogenase (MDH) as a substrate, TaHsp16.9C-I was

shown to be a much more effective chaperone than

TaHsp17.8C-II in preventing heat-induced MDH

aggrega-tion Surprisingly, heat-denaturing firefly luciferase (Luc), a

commonly used sHsp substrate, did not interact significantly

with TaHsp16.9C-I, although it was fully protected by

TaHsp17.8C-II In total, the data indicate these sHsps show

substrate specificity and suggest that the divergent sHsp

N-terminal arm contributes significantly to substrate

inter-actions

Materials and methods

Bacterial expression and purification ofTaHsp16.9C-I

andTaHsp17.8C-II

Triticum aestivum TaHsp16.9C-I (AZ 369) and

Ta-Hsp17.8C-II (Accession number: AF350423) [24], were

produced as recombinant proteins in Escherichia coli BL21

cells using the pJC20 expression plasmid [25] Cells were

grown in Luria–Bertani broth with 200 lgÆmL)1

carbeni-cillin at 37C (for TaHsp16.9C-I) or 32 C (for TaHsp17.8C-II), induced by the addition of isopropyl thio-b-D-galactoside to 1 mMand then grown for a further

6 h Purification of the recombinant sHsp from the soluble cell fraction was performed essentially as described in Lee and Vierling [25] with the following modifications TaHsp16.9C-I was enriched in the 55–90% (w/v) ammo-nium sulfate fraction, while TaHsp17.8C-II was more concentrated in the 40–70% (w/v) fraction For TaHsp17.8C-II, DEAE chromatography (diethylamino-ethyl-Sepharose Fast Flow resin; Sigma) was performed in 3.2M urea (2.8M urea for TaHsp16.9C-I) After DEAE chromatography, fractions containing sHsps were dialyzed into 25 mMTris/HCl, 1 mMEDTA, pH 7.5 (T25E1 buffer) and applied to an hydroxyapatite column equilibrated in

10 mMNa/Pibuffer, pH 7.5 The columns were eluted using 10–400 mM Na/Pi buffer, pH 7.5 Fractions containing sHsps were pooled and dialyzed against T25E1 and concentrated, if necessary, to 1–2 mgÆmL)1with an Amicon filter (YM10 membrane) Protein concentration was deter-mined using the Bio-Rad protein assay with BSA as a standard Concentrations for the sHsp are expressed in terms of subunit molecular mass, which is 16721.96 Da for TaHsp16.9C-I and 17649.40 Da for TaHsp17.8C-II, as calculated without the start Met residue, which is removed

in vivoin E coli Yields were 30 mgÆL)1bacterial culture Protein was stored at)80 C

Gel electrophoresis SDS/PAGE was performed on 14.5% (w/v) acrylamide gels using standard procedures Non-denaturing pore exclusion PAGE was performed on 4–18% (w/v) acrylamide gradient gels as described by Helm et al [23,26] Gels were stained with Coomassie Blue

Electron microscopy Proteins were applied to carbon-coated 200 mesh copper grids (Ted Pella, Inc., Redding, CA, USA) in 50 mM phosphate buffer, pH 7.5 at 6.0 lM subunits and negat-ively stained with 2% (w/v) uranyl acetate The sHsp/ substrate complexes were obtained by incubating either TaHsp16.9C-I or TaHsp17.8C-II with MDH under condi-tions described for sHsp/substrate complex formation assays (below) Grids were viewed in a Philips 420 transmission electron microscope (Philips Electronics, Ein-dhoven, the Netherlands) and micrographs were taken at

82 000· magnification

Sedimentation velocity experiments Analytical ultracentrifugation was performed with a Beck-man Optima XL-A ultracentrifuge Samples (450 lL) were centrifuged for 3.5 h at 4C and 40 000 r.p.m in an AN 60

TI rotor using double sector epon centerpieces Measure-ments were taken at 230 and 280 nm using a 0.001 cm radial step size in continuous measurement mode Data were analyzed with ULTRA SCAN II version 6.2 for Unix (http://www.ultrascan.uthscsa.edu/), using the van Holde– Weischet method [27] and finite element analysis as described previously [28]

Thermal aggregation protection assays

Thermal aggregation protection assays were performed with

MDH essentially as described by Lee et al [15] using 0.6 lM

MDH and purified sHsps from 0.18 to 3.0 lM(monomer)

in 50 mMNA/Pibuffer, pH 7.5 Samples were incubated in

1 mL quartz cuvettes in a thermostated water bath at 45C

To quantify changes in light scattering, absorbance at

320 nm was taken before heating began and monitored

throughout heating every 5 min Bovine IgG (reagent grade,

Sigma) at a final concentration equivalent to the weight

of 1.8 lMmonomer TaHsp16.9C-I or 3.0 lMmonomer in

the case of TaHsp17.8C-II was added to 0.3 lMMDH as a

negative control

Aggregation protection of firefly luciferase (Luc)

(Pro-mega) was assessed as follows Luc at 1 lMwas heated with

12 lMTaHsp16.9C-I or TaHsp17.8C-II subunits in 50 mM

Na phosphate, pH 7.5 (denaturation buffer) for 15 min at

42C in siliconized 0.65 mL microcentrifuge tubes After

heating, samples were centrifuged for 15 min at 16 250 g

and the supernatant fractions removed The supernatant

and pellet fractions were treated with SDS sample buffer

and the entire amount analyzed by SDS/PAGE and

Coomassie blue staining

sHsp/substrate complex formation and size exclusion

chromatography

Purified TaHsp16.9C-I and TaHsp17.8C-II were analyzed

by size exclusion chromatography (SEC) on a Rainen

HPLC using a Toso-Haas TSK G4000 SWXL column, in a

mobile phase containing 250 mM Na/Pi, pH 7.3 and

200 mM NaCl For analysis of sHsp/MDH complexes,

6.0 lMof TaHsp16.9 C-I or TaHsp17.8C-II subunits were

incubated with different MDH concentrations in 50 mM

Na/Pi buffer, pH 7.5 for 30 or 90 min at 45C After

incubation, samples were cooled on ice for 2 min and

centrifuged at 16 000 g for 15 min NaCl was added to the

supernatant to a final concentration of 200 mM Samples

were size-fractionated on the SEC column in a mobile phase

containing 250 mM Na/Pi, pH 7.3 and 200 mM NaCl

Analysis of sHsp/Luc complexes was performed similarly, except the concentration of Luc was 1 lM and the concentration of sHsps was 12 lMsubunits Samples were heated for 15 min at 42C as described by Lee et al [15] SEC was performed as above except the mobile phase was

200 mMNa/Pi, 100 mMNaCl, pH 7.3

Firefly luciferase reactivation assays Luc was heat-inactivated at 42C in the presence of sHsp

as described for formation of sHsp/Luc complexes above Luc reactivation in reticulocyte lysate was assayed as described previously [18] The sHsp/Luc mixture was diluted to 25 nM Luc in 50% rabbit reticulocyte lysate (Green Hectares, Oregon, WI, USA) in refolding buffer and incubated at 30C and assayed as described previ-ously Luc activity was determined over time by adding 2.5 lL of the reticulocyte lysate reaction to 50 lL of Luciferase Assay Mix (Promega) and monitoring light emission in a Turner 20/20 luminominer Activity is plotted as a percentage relative to that of an equivalent amount of native Luc measured prior to the heating step

As a negative control, 0.11 lgÆlL)1 bovine IgG was substituted for sHsp (equivalent weight) in the initial heat-inactivation step Data points and error bars reflect the mean and standard deviation of three replicates

Results

Comparison of TaHsp16.9 C-I and TaHsp17.8 C-II

To produce recombinant wheat class I and II sHSPs for these studies, we utilized the wheat class I cDNA, TaHsp16.9C-I (Accession number, S21600), corresponding

to the sHsp for which the high resolution structure (2.65 A˚) has been described [7], and a new wheat class II cDNA, TaHsp17.8 C-II (Accession number, AAK51797) [24] Amino acid sequence alignment illustrates the conserved and divergent regions of these two sHsps (Fig 1) TaHsp16.9C-I and TaHsp17.8C-II have an overall identity

of only  33%, but regions corresponding to secondary

Fig 1 Amino acid sequence alignment of TaHsp16.9C-I (Accession number S21600) and TaHsp17.8C-II (Accession number AAK51797) Identical residues are indicated with * and highly conservative replacements indicated with colons or periods under the alignment Regions of secondary structure in TaHsp16.9C-I [7] are indicated above the alignment The a-helices are displayed as open bars; b-strands as lines The conserved a-crystallin domain extends from b-strand 2 to b-strand 9 Regions in gray shaded boxes correspond to consensus regions within the a-crystallin domain that show particularly high conservation between plant sHsps Residues in the N-terminal region shown in bold correspond to sequences conserved in all class I or class II proteins, respectively Residues in the C-terminus in bold correspond to the conserved Basic-X-I/V-Q-I/V motif identified by de Jong et al [29] Underlined residues in the C-terminus of TaHsp17.8C-II correspond to a conserved motif of class II proteins [6] The alignment was performed using the - program (European Bioinformatics Institute; http://www.ebi.ac.uk/clustalw/index.html).

structure in the TaHsp16.9C-I a-crystallin domain along

with the conserved C-terminal basic-X-I/V-Q-I/V motif

identified by de Jong et al [29] show very high similarity In

contrast, the N-terminal arms show very little similarity, as

is typical for sHsps [2,29], and each protein contains an

N-terminal consensus unique to the class I or class II plant

sHsps [6] TaHsp17.8C-II also has a C-terminal motif

containing ProProPro that is typical of class II plant sHsps

Thus, although these proteins would be predicted to have a

similar fold in the a-crystallin domain and to utilize the

hydrophobic residues of the basic-X-I/V-Q-I/V motif for

oligomer assembly, differences in the N-terminal arms and

flexibility of the C-terminal extension suggest that their

overall oligomeric structure may differ

TaHsp16.9C-I, as reported previously [7], and

TaHsp17.8C-II were purified to greater than 98%

homo-geneity from E coli cells, and the purified recombinant

proteins migrated as a single species at the expected monomer

mass on SDS/PAGE (Fig 2A) Non-denaturing pore

exclusion PAGE and size exclusion chromatography (SEC)

were then utilized to compare the native structure of the two sHsps By both methods, although TaHsp16.9C-I has a smaller monomeric size than TaHsp17.8C-II, TaHsp16.9 C-I appears to exist as a larger oligomeric structure than the class

II sHsp On nondenaturing PAGE TaHsp16.9C-I has an estimated mass of 284 kDa, while TaHsp17.8C-II migrates

at 242 kDa Similarly, on SEC the TaHsp16.9C-I peak eluted at 10.32 min while TaHSP17.8C-II eluted later

at 10.65 min (Fig 2C) Compared to TaHsp16.9C-I, TaHsp17.8C-II always exhibited a fairly broad elution profile, which could result from a variety of factors, including oligomeric instability, nonuniformity of oligomer size or interaction with the column matrix As TaHsp16.9C-I

is a 12-subunit oligomer [7], these results suggest the TaHsp17.8C-II oligomer is composed of fewer than 12 subunits

Size of the recombinant sHsp oligomers Although nondenaturing PAGE and SEC indicated the class I and II sHsps have different oligomeric structures, neither of these techniques are primary methods for size determination Therefore, to better understand the differ-ence in subunit organization of these sHsps, we compared them by EM using negative staining and by sedimentation velocity centrifugation analysis

As shown in Fig 3, purified preparations of either sHsp appear as mostly uniform, roughly spherical particles The TaHsp16.9C-I particles have a diameter of approximately

11 nm, consistent with the crystal structure [7] They are clearly larger than the TaHsp17.8C-II particles, which have an estimated diameter of only 9 nm Therefore, the relative sizes of the two oligomers are consistent with their behavior on nondenaturing PAGE and SEC Their appearance is also similar to what has been observed for class I and II sHsps from Pisum sativum (pea) [21], suggesting conservation of the subunit stoichiometry of class I and II oligomers

In sedimentation velocity experiments, the sedimen-tation distribution profile of both TaHsp16.9C-I and TaHsp17.8C-II indicate that both proteins are associated

in a higher order structure (Fig 4) The fact that these sHsps exhibit nearly identical sedimentation coefficient distribu-tions, but have different monomer molecular masses, is consistent with the interpretation that TaHsp17.8C-II contains either fewer subunits than TaHsp16.9C-I, or has

a more nonglobular shape Finite element analysis of the data [28] estimates a molecular mass of 201 kDa for TaHsp16.9C-I and 173 kDa for TaHsp17.8C-II These data are consistent with a more extended shape for TaHsp16.9C-I than for TaHsp17.8C-II and with a dodecameric organiza-tion for TaHsp16.9C-I and an oligomer of TaHsp17.8C-II containing 9–10 monomer units These data are in good agreement with the results from the other methods In total, the data indicate these two plant cytosolic sHsps have a different oligomeric organization

The wheat sHsps prevent heat-induced aggregation

of MDH Although the TaHsp16.9C-I structure is known, there is only one published experiment concerning its chaperone

Fig 2 Purified TaHsp16.9C-I and TaHsp17.8C-II form high molecular

mass homo-oligomers Purified TaHsp16.9C-I and TaHsp17.8C-II

(5 lg) were separated by SDS/PAGE (A), nondenaturing pore

exclu-sion PAGE (9 lg) (B), or size-excluexclu-sion HPLC (10 lg) (C) Gels were

stained with Coomassie blue (C) Elution time in min is shown relative

to protein absorbance at 220 nm Approximate elution positions of

molecular mass standards are indicated Asterisk indicates a peak

arising from buffer absorbance.

activity, in which it was shown to form complexes with the

model substrate MDH when the two proteins are heated

together [7] We undertook a more detailed examination of

the activity of TaHsp16.9C-I and, in comparison,

TaHsp17.8C-II A well-established assay for sHsp

chaper-one activity is the ability to prevent heat-induced protein

aggregation as measured by light scattering [25] In this

assay, the ratio of sHsp to substrate that is required to

suppress light scattering can be used as a measure of

effectiveness of the chaperone Using this assay we tested the

relative activity of the two wheat proteins in suppressing

aggregation of MDH As shown in Fig 5, both wheat

sHsps were effective in preventing MDH aggregation as assessed by suppression of an increase in light scattering over time at 45C TaHsp16.9C-I achieved maximum protection of MDH at a ratio of two to three subunits of

Fig 3 Visualization of negatively stained TaHsp16.9C-I (left) and TaHsp17.8C-II (right)

by electron microscopy Both proteins appear

as homogenous, roughly spherical particles, but TaHsp17.8C-II is smaller Bar indicates

50 nm for both.

Fig 4 Sedimentation velocity analysis of TaHsp16.9C-I and

TaHsp17.8C-II Shown is the integral distribution plot from the van

Holde–Weischet analysis of the data obtained for TaHsp16.9C-I (s)

and TaHsp17.8C-II (d) For both proteins, the majority of the sample

sedimented between 8.6 s and 9.2 s, with a small amount of smaller

association states (less than 6% of the total concentration) sedimenting

at S-values between 1 s and 8 s Both samples also display some

amount of slightly higher order association states (< 10%)

sedi-menting between 9 s and 10 s.

Fig 5 Wheat sHsps suppress heat-induced aggregation of MDH Relative light scattering (320 nm) is plotted vs time at 45 C for 0.6 l M MDH (monomer) incubated with the indicated concentration (in monomers) of either TaHsp16.9C-I (top) or TaHsp17.8C-II (bot-tom) Numbers in parentheses indicate the ratio of sHsp monomer to MDH monomer For the IgG control, IgG was added at a weight equivalent to 1.8 l M TaHsp16.9C-I or 3.0 l M TaHsp17.8C-II Points represent average and standard deviation of three replicates.

sHsp to one subunit of MDH In contrast, TaHsp17.8C-II

required four to five subunits of the sHsp per MDH subunit

to achieve the same level of protection Note that no

aggregation protection is seen with the control protein IgG,

even when used at the same concentration as the highest

sHsp concentration (on a weight basis) Thus, while

both sHsps are effective chaperones, with this substrate

TaHsp16.9C-I is approximately twice as active on a subunit

(or weight) basis

At the lowest concentrations of sHsp used (0.18 lM

TaHsp16.9C-I and 0.60 lM TaHsp17.8C-II) the extent of

light scattering was actually higher than in the absence of

the sHsp This may reflect the formation of very large

aggregates of MDH that also include the sHsp At low sHsp

concentrations the sHsp could be bound to the MDH, but

not be abundant enough to prevent interaction of unfolded

MDH with itself

Analysis of sHsp/MDH complexes

The differences in effectiveness of aggregation protection

between the two wheat sHsps suggests that the way in which

the sHsp and denatured substrate interact may be different

To characterize sHsp/MDH complexes, SEC analysis

was performed after heating either TaHsp16.9C-I or

TaHsp17.8C-II (6.0 lM) with 1–4 lM MDH, yielding

sHsp/MDH ratios comparable to those used in the

light-scattering assays MDH does not interact with either sHsp

when the proteins are incubated together at 22C (Fig 6A);

the proteins elute at the predicted position based on their

individual native molecular masses We have noted that

TaHsp17.8C-II consistently yields a lower absorbance

(A220) than TaHsp16.9C-I on column chromatography

We attribute this to either irreversible interaction of the

protein with the column, or presence of aggregates too large

to enter the column, but too small to be removed by brief

centrifugation prior to loading MDH incubated alone at

45C becomes insoluble and does not enter the column

(Fig 6B) However, a higher molecular mass species

becomes visible after heating sHsps and MDH together at

45C for 30 or 90 min (Fig 6C)

At the ratio of sHsp:substrate of 6 : 1, TaHsp16.9C-I

gives full substrate protection; the size of the complex peak

increases between 30 and 90 min, and after 90 min the

MDH peak is completely depleted (Fig 6C, upper panels;

compare to MDH peak in A) A majority of the MDH is in

complexes after the first 30 min, consistent with the rate of

aggregation protection measured by light scattering The

same phenomenon occurs at a ratio of TaHsp16.9C-I to

MDH of 3 : 1, where full protection from aggregation is

also observed However, as the ratio of TaHsp16.9C-I to

MDH is further decreased, the complex peak, while higher

at 30 min, actually decreases over time, and aggregated

MDH is now found in the sample pellet prior to column

loading (not shown) All of the 30 min samples show a

detectable complex peak that elutes earlier (7 min), which

may represent some kind of intermediate in complex

assembly As the vast majority of complexes elute in the

column void volume, differences in complex size at the

different ratios cannot be estimated

Complex formation with TaHsp17.8C-II reveals the

reduced capacity of this sHsp to protect MDH compared

to TaHsp16.9C-I (Fig 6C, lower panels) Although com-plete protection is observed at the sHsp:MDH ratio of

6 : 1, already at a 3 : 1 ratio the TaHsp17.8C-II/MDH complex peak does not increase after 30 min This result is consistent with the light-scattering data, which showed the sHsp was unable to fully protect MDH at this ratio As the amount of sHsp to substrate is further decreased, most

of the MDH is no longer found in complexes, but rather

is aggregated and removed by centrifugation prior to sample loading on the column (not shown) Interestingly, the sHsp itself does not appear to be complexed with the insoluble MDH at the 2 : 1, sHsp/MDH ratio; after

90 min the free sHsp is still all accounted for in the peak

at 10.65 min However, some sHsp is clearly lost to the insoluble fraction, which is not loaded on the column, when the ratio is only 1.5 : 1 This is consistent with the maximum light-scattering values observed for TaHsp17.8C-II/MDH at a 1 : 1 ratio, which were higher than those for MDH alone A potential intermediate-sized species of complex is also evident at 6.5 min in most of the samples In total, as observed by light scattering, substrate denaturation and aggregation are time-depend-ent, the sHsps can be saturated with substrate, and TaHsp17.8C-II is less effective in protecting MDH compared to TaHsp16.9C-I

To visualize the sHsp substrate complexes directly, samples incubated as for the SEC analysis at 45C for

30 min were observed by EM and negative staining (Fig 7) Note that because samples were centrifuged prior

to application to the grid, only soluble material was observed Two consistent observations arose from this analysis First, complexes formed at an sHsp to substrate ratio that was sufficient, or higher, than that required for full protection (as determined in the light-scattering experiments) were the most uniform At the ratio required for full protection, complexes formed with TaHsp16.9C-I (3 : 1 ratio) had an average diameter of

 54 nm, while complexes formed with TaHsp17.8C-II (6 : 1 ratio) were somewhat larger (60 nm) Second, complex regularity decreased as the amount of sHsp to substrate decreased below the level of full protection for either sHsp, with the irregular complexes looking more like aggregates composed of smaller particles ( 40–

46 nm), as seen in the 2 : 1 and lower ratio mixtures MDH heated alone and applied to the grid before centrifugation was a large amorphous mass, while after centrifugation no proteinaceous material could be observed (not shown)

TaHsp17.8 C-II, but not TaHsp16.9 C-I, suppresses aggregation of Luc

The above data indicate that TaHsp16.9C-I is more effective in preventing aggregation of MDH than is TaHsp17.8C-II To test if this difference in chaperone activity is the same with another heat sensitive substrate, aggregation protection of firefly luciferase (Luc) was examined A simple differential centrifugation assay was employed to determine if either wheat sHsp could prevent insolubilization of Luc during heating This assay was employed in place of the spectrophotometric assay used for MDH because of difficulties with adhesion of Luc to

the cuvette walls As shown in Fig 8A, Luc incubated

with TaHsp17.8C-II at 42C for 15 min was recovered

almost exclusively in the soluble fraction, indicating that

TaHsp17.8C-II was able to protect Luc from heat-induced

insolubilization A similar weight of IgG gave no

protec-tion (not shown) Surprisingly, when Luc was incubated

with TaHsp16.9C-I, virtually all of the Luc was found in

the pellet fraction, while the sHsp remained soluble Thus,

in contrast to results with MDH, TaHsp16.9C-I is a less

effective chaperone with Luc than is TaHsp17.8C-II Note

that a higher ratio of sHsp to substrate is required to

protect Luc as compared to MDH In parallel to these

observations, TaHsp17.8C-II formed a complex when heated with Luc, which could be observed by SEC (Fig 8B) No such complex formed with TaHsp16.9C-I (not shown) Thus, these two sHsps do not behave equivalently with all substrates

Denatured Luc bound toTaHsp17.8C-II can be reactivated in a cell free lysate

The effectiveness of sHsp chaperone activity can also be assessed by the ability of an sHsp to maintain substrate in

a state from which it can be refolded by ATP-dependent

Fig 6 TaHsp16.9C-I is more effective in forming complexes with MDH than is TaHsp17.8C-II All samples were separated by SEC, and absorbance (220 nm) monitored over elution time Samples were centrifuged to remove insoluble material prior to loading on the column (A) sHsps (6 l M ) and MDH (2 l M ) incubated together at room tempera-ture (B) MDH heated alone (C) High molecular mass complexes formed between sHsps and MDH after heating at 45 C for

30 or 90 min Concentrations were 6 l M sHsp subunits for all samples, with from 1 to 4 l M

MDH as indicated by the sHsp/MDH ratio Asterisk indicates a buffer peak.

chaperones [18] To test if the Luc protected by

TaHsp17.8C-II was in a conformation capable of

reacti-vation, the TaHsp17.8C-II/Luc complexes, or Luc

heat-denatured in the presence of TaHsp16.9C-I or an

equivalent weight of IgG, were incubated with reticulocyte

lysate plus or minus ATP (Fig 8C) Reactivation of Luc

bound to TaHsp17.8C-II was highly efficient, achieving up

to 70% reactivation in less than 1 h in the presence of

ATP As expected, TaHsp16.9C-I supported less than

15% reactivation of Luc because most of the Luc was

insoluble and not associated with the sHsp Controls using

IgG, or in the absence of ATP, showed 5% or less

reactivation Thus, formation of TaHsp17.8C-II/Luc

com-plexes is correlated with ability to support substrate

reactivation

Discussion

Our data provide the first detailed analysis of the in vitro chaperone activity of TaHsp16.9C-I, the only eukaryotic sHsp for which a high resolution structure is available Surprisingly, although this sHsp effectively protects MDH from insolubilization, it did not interact with a second substrate, Luc, under the conditions tested In parallel, we analyzed a related wheat sHsp, TaHsp17.8C-II, which proved to be less effective in protecting MDH, but interacted well with Luc, both preventing aggregation and supporting refolding Thus, these results document the first clear example of apparent substrate specificity for sHsps TaHsp16.9C-I and TaHsp17.8C-II represent two distinct classes of cytosolic sHsps from plants (class I and class II),

Fig 7 MDH/sHsp complexes visualized by

electron microscopy and negative staining.

TaHsp16.9C-I or TaHsp17.8C-II (6 l M

sub-units) heated with different concentrations of

MDH ranging from 6 to 1 subunit sHsp: 1

subunit substrate Complexes were formed at

45 C for 30 min then centrifuged and loaded

on the EM grids for visualization at

magni-fication of 820 000 Bar indicates 110 nm

for all.

estimated to have diverged at least 400 million years ago [6].

Comparing these two wheat proteins, amino acid sequence

identity is 33% overall, and 46% for the a-crystallin

domain In addition to sequence differences, our analysis

of the purified recombinant proteins indicates that they

assemble into different quaternary structures Solution

methods, from this work and previous studies, and a crystal

structure [7] demonstrate that native TaHsp16.9C-I is

dodecameric In contrast, by EM, SEC and sedimentation

velocity experiments, the class II TaHsp17.8C-II was found

to form regular, but smaller oligomers, with an estimated

nine to ten subunits Members of these same two sHsp

classes have also been characterized from Pisum sativum

(pea), PsHsp18.1C-I and PsHsp17.7C-II [21] EM pictures

of the purified pea oligomers are remarkably similar to those

of the wheat proteins, with the class I sHsp having a

diameter of 10–11 nm and the class II protein a slightly

smaller diameter, despite the larger subunit size

PsHsp18.1C-I was also found to be dodecameric by

sedimentation equilibrium analysis, like the homologous

wheat TaHsp16.9C-I (amino acid sequence

identity/simi-larity 68/75% throughout, and 80/86% in the a-crystallin

domain) However, sedimentation equilibrium analysis of

PsHsp17.7C-II estimated an oligomer of 11.3 ± 0.5

sub-units [21], larger than our estimate for the wheat class II

protein Therefore, it is unclear whether the stoichiometry of

oligomeric assembly is the same for all plant class II

proteins However, we would predict that the assembly

should comprise an even number of subunits, based on the

dimeric building block of TaHsp16.9C-I, which involves

features conserved in the class II proteins as well [1,6]

Regardless of absolute subunit numbers, class I and II sHsp

oligomers clearly have distinct modes of assembly, as also

reflected in the fact that these two classes of sHsps do not

coassemble into mixed oligomers in vivo or in vitro, although

class I or II sHsps will coassemble into normal oligomers

when mixed with class I or II sHsps, respectively, from

different plant species ([7,23], and E Basha & E Vierling,

unpublished observation) Distinct assemblies of different sHsps in the same cell have also been observed in humans and bacteria [30,31], suggesting there are different, conserved roles for specific sHsps

Both TaHsp16.9C-I and TaHsp17.8C-II were able to suppress the heat-dependent aggregation of MDH How-ever, TaHsp16.9C-I suppresses MDH aggregation com-pletely at a stoichiometry of 2–3 subunits sHsp to 1 subunit MDH In contrast, complete suppression of MDH aggregation by TaHsp17.8C-II required the higher ratio of 4–5 sHsp subunits:1 MDH subunit From previous work, PsHsp18.1C-I was found to be somewhat more effective in the aggregation protection of MDH than either of the wheat sHsps, suppressing MDH aggregation

at a ratio of 2 : 1, sHsp subunit:MDH [15] The pea class

II protein was not tested with MDH, but when tested with citrate synthase, it was more than sixfold less effective than the PsHsp18.1C-I [21] Thus, using these in vitro assays with two different substrates, class II proteins have proven to be less effective as chaperones than class I proteins, consistent with some type of substrate specificity for these two classes of proteins

At the lowest concentrations of sHsp used (0.18 lM TaHsp16.9C-I and 0.6 lMTaHsp17.8C-II to 1 lMMDH) the extent of light scattering was actually higher than in the absence of the sHsp This may reflect the formation of very large aggregates of MDH that also include the sHsp, as evidenced by the loss of sHsp from the SEC profile under these conditions At this low sHsp concentration, the sHsp might be bound to the MDH but not be abundant enough

to prevent extensive interaction of unfolded MDH with itself Bova et al [32] noticed such an effect using aB-crystallin containing the R120G mutation linked to desmin-related myopathy One of the authors’ interpreta-tions for the effect was a possible change in the availability

of substrate binding sites resulting in a less efficient chaperone When we used a low concentration of wheat sHsps, therefore providing fewer binding sites, we may have

Fig 8 TaHsp17.8C-II, but not TaHsp16.9C-I, maintains Luc in a soluble form during heating and facilitates Luc reactivation (A) Coomassie blue stained SDS/PAGE of soluble (S) and pellet (P) fractions prepared after heating 12 l M TaHsp16.9 or 17.8 with 1.0 l M Luc at 42 C for 15 min (B) SEC analysis of 12 l M TaHsp17.8C-II plus 1.0 l M Luc either before (22 C) or after heating at 42 C for 15min (42 C) Approximate elution times of molecular mass markers are indicated (C) Time course of Luc reactivation in reticulocyte lysate (d) TaHsp17.8C-II + ATP; (j) TaHsp17.8 C-II – ATP; (m) TaHsp16.9C-I + ATP; (h) Hsp16.9 C-I – ATP; (s) IgG + ATP.

imitated the same effect of the R120G mutation in

aB-crystallin

SEC analysis showed that the complexes formed between

the two wheat sHsps and MDH are quite large Working

with PsHsp18.1C-I, Lee et al [15] found complexes with

MDH were much smaller than those formed with the wheat

sHsps, although the size observed by SEC was dependent

on the substrate concentration as well as the denaturation

temperature The less efficient aggregation protection

obtained with the wheat sHsps (on a molar basis of sHsp:

substrate) compared to PsHsp18.1C-I suggests that the

MDH aggregates more rapidly than it can form stabilizing

interactions with the wheat sHsps It is interesting that there

is always a free peak of sHsp on SEC, even when some

of the substrate has precipitated The free sHsps could

still have a role in protection, by cycling on and off the

aggregates, as suggested by both Lindner et al [33] and

Friedrich et al [12]

The decrease in SEC complex peak height and the

eventual loss of sHsp at the highest substrate concentrations

is due to the insolubility of the sHsps bound to excess

substrate (as indicated by SDS PAGE; not shown)

Transition of sHsps to an insoluble fraction is observed

in vivoin many organisms [15,34,35], and may also result

from overloading of the sHsp with substrates Experiments

in E coli suggest that the chaperone ClpB is necessary

to resolubilize sHsp/substrate complexes in vivo [36], and

in vitro, protein aggregates containing sHsps are more

effective ClpB substrates than aggregates without sHsps

[19] Therefore, even when complexed in an insoluble

fraction, the sHsps may confer an advantage for recovery of

protein activity in the cell

We also observed by EM that at sHsp:substrate ratios

sufficient for complete substrate protection, sHsp/substrate

complexes had dimensions of  56 and 60 nm for

TaHsp16.9C-I and TaHsp17.8C-II, respectively As

repor-ted previously, and consistent with the SEC comparisons,

PsHsp18.1C-I complexes with MDH were smaller on

average, being frequently 16 to 20 nm [15] Complex

morphology also changed with decreasing sHsp to substrate

ratio, with much more heterogeneous particles and

aggre-gates of particles observed These results are at odds with a

report by Stromer et al [37] in which complex morphology

was reported to be dictated by substrate identity and

independent of the identity of the sHsp, although different

sHsp:substrate ratios were not observed by EM It is

interesting that  40 nm particles, termed heat shock

granules, are found after heat stress in plants in vivo

[34,38] To what extent the in vitro-formed complexes

resemble in vivo heat shock granules remains to be

determined

Surprisingly, while TaHsp16.9C-I was more effective

than TaHsp17.8C-II in protecting MDH, TaHsp16.9C-I

showed no ability to protect Luc under the conditions

tested In contrast, TaHsp17.8C-II protected Luc from

aggregation and formed high molecular mass complexes

with Luc We also showed that TaHsp17.8C-II supported

Luc refolding using rabbit reticulocyte lysate as a source

of ATP-dependent eukaryotic chaperones However, the

inability of TaHsp16.9C-I to protect Luc is not true for all

class I sHsps PsHsp18.1C-I has been shown to protect

Luc with the same effectiveness as TaHsp17.8C-II and to

support Luc refolding [12,15,18] This fact indicates that the differences in sHsp–substrate interactions must be more subtle than the differences between class I and II sHsps in primary sequence or quaternary structure TaHsp16.9C-I and PsHsp18.1C-I show 80% identity and 86% similarity in the conserved C-terminal a-crystallin domain In contrast they show only 41% identity and 50% similarity in the N-terminal arm, suggesting substrate specificity is deter-mined by the N-terminal arm The N-terminus of PsHsp18.1.C-I was also implicated in substrate interactions

in bis-ANS binding experiments [15] As it is proposed that substrate binding and protection involves oligomer dissoci-ation and some type of reassocidissoci-ation to form the large sHsp/ substrate complexes [7,13], it must also be considered that overall differences in oligomer stability and/or the kinetics

of oligomer dissociation, rather than specific sequence differences, dramatically affect sHsp interactions with different substrates

Although to date sHsps have been ascribed little substrate specificity, it is clear from this study and previous work [21,37] that the effectiveness of substrate protection, on a molar basis, by different sHsps can vary significantly under the same conditions A difference in effectiveness is obvious

to the extreme with TaHsp16.9C-I, which fails to interact with Luc It should be considered that minor differences

in the ratio of sHsp/substrate required for maximal substrate protection are potentially functionally important differences in the cellular environment and are essentially an indication of substrate specificity Full understanding of sHsp substrate interactions will require not only considera-tion of substrate binding sites and binding interacconsidera-tions, but also the dynamics of the sHsp oligomer and the kinetics of substrate aggregation

Acknowledgements

This work was supported by National Institutes of Health grant RO1-GM42762, USDA-NRICGP and University of Arizona Experiment Station Funds, and American Cancer Society Faculty Research Award

#FRA-420 to E V G J L was a recipient of a National Institutes of Health Postdoctoral Fellowship B D was supported by NSF

BB1-9974819 We thank Drs Kim Giese and Kenneth Friedrich for critical reading of the manuscript.

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