Báo cáo khoa học: Binding of the viral immunogenic octapeptide VSV8 to native glucose-regulated protein Grp94 (gp96) and its inhibition by the physiological ligands ATP and Ca2+ Ming Ying and Torgeir Flatmark pot

native glucose-regulated protein Grp94 gp96 and itsMing Ying and Torgeir Flatmark Section of Biochemistry and Molecular Biology, Department of Biomedicine, University of Bergen, Norway G

native glucose-regulated protein Grp94 (gp96) and its

Ming Ying and Torgeir Flatmark

Section of Biochemistry and Molecular Biology, Department of Biomedicine, University of Bergen, Norway

Grp94 (gp96), a major chaperone of the ER lumen

and a paralogue of the cytoplasmic chaperone Hsp90,

plays an essential role in the structural maturation

and⁄ or secretion of a subset of client (cargo) proteins

destined for transport to the cell surface [1] Related

studies have indicated that Grp94 also associates with

a wide array of immunogenic peptides generated in the

cytosol or in the early secretory pathway Such Grp–

peptide complexes have been proposed to interact with

antigen-presenting cells (APC) in a specific manner

that eventually leads to the presentation of peptides by

the major histocompatability complex (MHC) class I

molecules of the APCs [2] The immunodominant viral

octapeptide RGYVYQGL (VSV8), derived from

vesicu-lar stomatitis virus nucleoprotein (residues 52–59), has

been identified as a MHC class I H2-Kb⁄ H2-Kd

epi-tope (http://immunax.dfci.harvard.edu/bioinformatics/

epimhc/) and a Grp94 ligand in VSV-infected cells [3],

and has been shown to bind to Grp94 in vitro [4–7] The generally reported low affinity and low stoichio-metry of peptide binding to Grp94 in vitro, and the finding that this binding seems to be almost irrevers-ible, have questioned the proposed in vivo peptide acceptor–donor function of the chaperone [8,9] Thus,

in previous in vitro studies peptide binding to Grp94 was artificially enhanced by experimental conditions that elicit a more open conformational state of the chaperone, i.e by heat shock denaturation (50–60
C) [5–7,10], by a chemically induced conformational change [6] or by high salt concentrations [5] More-over, the binding assays were based on incubations of Grp94 and radiolabelled ligand for 1–20 h [7] Finally,

no physiological ligands favouring such

conformation-al states of Grp94 have been defined, and a better understanding of the interaction of the native chaper-one with ‘client’ peptides and the possible regulation

Keywords

ATP; cations; Grp94; SPR; VSV8

Correspondence

T Flatmark, Section of Biochemistry and

Molecular Biology, Department of

Biomedicine, University of Bergen, Jonas

Lies vei 91, N-5009 Bergen, Norway

Fax: +47 55 586360

Tel: +47 55 586428

E-mail: torgeir.flatmark@biomed.uib.no

(Received 30 September 2005, revised

1 December 2005, accepted 2 December

2005)

doi:10.1111/j.1742-4658.2005.05084.x

The molecular chaperone Grp94 (gp96) of the endoplasmic reticulum (ER) lumen plays an essential role in the structural maturation and⁄ or secretion of proteins destined for transport to the cell surface Its proposed role in binding and transferring peptides for immune recognition is, however, controversial Using SPR spectroscopy, we studied the interaction of native glycosylated Grp94 at neutral pH and 25 and 37
C with the viral immunogenic octa-peptide RGYVYQGL (VSV8), derived from vesicular stomatitis virus nucleoprotein (52–59) The peptide binds reversibly with low affinity ([A]0.5
640 lm) and a hyperbolic binding isotherm, and the binding is par-tially inhibited by ATP and Ca2+at concentrations that are present in the

ER lumen, and the effects are explained by conformational changes in the native chaperone induced by these ligands Our data present experimental support for the recent proposal that, under native conditions, VSV8 binds

to Grp94 by an adsorptive, rather than a bioselective, mechanism, and thus further challenge the proposed in vivo peptide acceptor–donor function

of the chaperone in the context of antigen-presenting cell activation

Abbreviations

APC, antigen-presenting cell; dn ⁄ dc, refractive index increment; ERGIC, ER ⁄ Golgi intermediate compartment; Grp78 (BiP), ER glucose-regulated protein of 78 kDa; Grp94 (gp96), ER glucose-glucose-regulated protein of 94 kDa; MHC, major histocompatability complex; NECA, 5¢-N-ethylcarboxamidoadenosine; RU, resonance unit; TAP, transporter associated with antigen presentation.

of this function by ligand interactions is considered

imperative [9] In this study, SPR spectroscopy was

used to study multiple ligand-binding events in real

time to the immobilized native glycosylated Grp94

(rGrp94) and nonglycosylated recombinant Grp94 at

25 or 37
C Special attention was paid to the

reversi-ble binding of the viral immunogenic octpeptide

RGY-VYQGL (VSV8) and physiological low-molecular mass

ligands of the ER lumenal compartment (Ca2+ and

ATP), known to regulate the function of Grp94 as a

protein chaperone [4,11,12] Thus, the SPR binding

studies provide new insights into native Grp94–ligand

interactions related to its proposed in vivo peptide

binding and antigen presentation activity

Results

Previous in vitro studies on the peptide-binding activity

of Grp94 [6,7] have not given any equilibrium-binding

parameters for peptide binding to the native chaperone

or identified any physiological factors in the ER

lumenal environment which may have a regulatory

effect on the Grp94–peptide interactions In this study

we addressed both questions by choosing SPR as the

experimental approach to study the interactions

ofGrp94 in real time with the viral immunogenic

octapeptide VSV8 and some known physiological

low-molecular mass ligands of the chaperone in the ER

lumenal compartment which may perturb this

inter-action

Binding of the viral immunogenic octapeptide

VSV8 to native rGrp94

Native glycosylated rat Grp94 (rGrp94) and

recombin-ant nonglycosylated Grp94 were immobilized using

carbodiimide-activated amine coupling so that the chip

surface might present random orientations of Grp94

molecules Figure 1A shows a series of sensorgrams

for the binding of VSV8 to rGrp94 at 25
C and

pH 7.4, corrected for the change in refractive index

observed on the adjacent mock-immobilized surface of

the same chip The kinetics of both association and

dissociation are near the limit of being too fast to be

analysed quantitatively with confidence Thus, the

response values at the steady-state plateau were taken

as a measure of the amount of ligand bound to the

sensor surface The sensorgrams show increasing

response to concentrations of VSV8 in the range

10 lm to 1 mm, and from the hyperbolic equilibrium

binding isotherm (Fig 1B) a [A]0.5 of
640 lm and a

global Rmax(obs) of 27 RUÆ(ng proteinÆmm)2) was

estimated The binding affinity was decreased at 37
C,

Fig 1 Binding of VSV8 to immobilized native glycosylated rGrp94

as measured by SPR rGrp94 was immobilized on the sensor chip

at 15 856 RU, and the binding of VSV8 was studied at 25
C and

pH 7.4 in HBS-P buffer (A) Representative sensorgrams at 0, 100,

500 and 1000 l M VSV8 (B) The equilibrium-binding isotherm with a half-maximal response ([A] 0.5 ) at
640 l M of VSV8 and a global

Rmax(obs) of 27 RUÆ(ng proteinÆmm)2) (C) Double-reciprocal plot of the equilibrium-binding isotherms obtained in the absence of ATP ⁄ Ca 2+

(d), in the presence of 500 l M ATP (.) and in the pres-ence of 500 l M Ca 2+ (s) in the flow buffer.

but slightly increased by lowering the pH from 7.4 to

6.5 [approximate pH of the ER⁄ Golgi intermediate

(ERGIC) compartment] [13] (not shown) Essentially

identical results and binding parameters were obtained

for recombinant nonglycosylated Grp94 (not shown)

Moreover, the low-molecular mass analytes ATP and

Ca2+at concentrations near the physiological levels in

the ER were both found to inhibit rGrp94 binding of

VSV8 (Fig 1C), most pronounced for ATP at low

concentrations of the peptide (see below) However, at

this ATP concentration we observed no significant

effect on the binding of VSV8 to the recombinant ER

chaperone Grp78⁄ BiP (not shown)

Although SPR typically offers no direct information

about stoichiometry, an estimate was obtained from

Eqn 2 (Experimental Procedures) by assuming a single

binding site (n¼ 1) per rGrp94 monomer (96 kDa) for

VSV8 and the same refractive index increment [dn⁄ dc

(cm3Æg)1)] as for the immobilized protein [14] Thus, an

Rmax(theoretical) of 4.9 RUÆ(ng proteinÆmm-2) was

cal-culated for the rGrp94 monomer, which represents

18% of the Rmax(obs) of 27 RUÆ(ng proteinÆmm-2) as

calculated from the binding isotherm (Fig 1B) VSV8

is a water soluble peptide and is shown structurally to

be in an extended and flexible monomeric state [15],

and it was most likely a monomer at the experimental

conditions used This indicates that rGrp94 contains

multiple low-affinity binding sites for VSV8

Binding of ATP, MgATP and NECA to rGrp94

The function of Grp94 as a protein chaperone is

repor-ted to be sensitive to ER lumenal ATP levels [11] The

chaperone has been reported to bind ATP and ADP

with estimated Kd-values in the millimolar concentration

range [16], and the recently obtained three-dimensional

structure of its N-terminal domain in complex with ATP

and ADP has revealed a nucleotide-induced

conforma-tional switch in the chaperone [17] SPR analyses of the

full-length glycosylated protein are in agreement with

both observations ATP binds to the full-length rGrp94

and the binding results in a negative SPR signal

(Fig 2A) This unusual response can only be explained

by a ligand-induced conformational change, because a

positive signal was expected due to the increased surface

mass contribution of bound ATP (507 Da) as observed

in a control experiment with the ER chaperone

Grp78⁄ BiP (Fig 2C) From the negative response

iso-therm obtained within the concentration range of

0–500 lm ATP an apparent [A]0.5of
90 lm was

esti-mated (Fig 2B) Owing to the mixed contribution of ATP

binding to the overall SPR signal response, i.e a positive

DRU due to an increased surface mass concentration,

Fig 2 Binding of ATP to immobilized native glycosylated rGrp94 and recombinant Grp78 ⁄ BiP as measured by SPR rGrp94 and Grp78 ⁄ BiP were immobilized on the sensor chip at 15 945 and

2323 RU, respectively, and the binding of ATP was studied at

25
C and pH 7.4 in HBS-P buffer (A) Representative sensorgrams for rGrp94 at 10, 75, 150 and 300 l M of ATP (B) The equilibrium-response isotherm for rGrp94 within the range 0–500 l M ATP with

a half-maximal response ([A]0.5) at
90 l M ATP (C) The equilib-rium-response isotherm for Grp78 ⁄ BiP with a half-maximal response ([A] 0.5 ) at
170 l M ATP.

and a negative DRU due to the ligand-induced

conform-ational change, no exact value for the binding affinity

and the stoichiometry of ATP binding could be

deter-mined By contrast, in the same concentration range

MgATP (at a molar ratio of Mg2+: ATP¼ 2 : 1) gave

a positive SPR signal with an apparent [A]0.5of 5.8 mm

(Fig 4B) Almost the same response isotherm was

obtained for nonglycosylated recombinant Grp94 (not

shown), and from Fig 2C it is seen that in a control

experiment with Grp78⁄ BiP ATP binds with a

posit-ive SPR response isotherm, and [A]0.5 was
170 lm

DRUmax [1.75 RUÆ(ng proteinÆmm)2)] calculated from

the response isotherm by nonlinear regression analysis is

similar to the Rmax(theoretical) ¼ 1.63 calculated from

Eqn 2 using the estimated dn⁄ dc value for ATP (i.e

63% of that for VSV8), indicating an apparent 1 : 1

stoichiometry of ATP binding to Grp78⁄ BiP monomer

(78 kDa)

Grp94 was found to bind the substituted adenosine

analogue 5¢-(N-ethylcarboxamido) adenosine (NECA)

with submicromolar affinity [16] The crystal structure

of a monomeric double-truncated form of canine

Grp94 (residues 69–337D40) has more recently revealed

that NECA binds to a conserved adenine-binding

cav-ity and a second partially hydrophobic pocket, and the

presence of an adenosine nucleotide-induced

conforma-tional switch was predicted [18] and recently confirmed

[17] Our SPR analyses (Fig 3) also support the

con-clusion that NECA (308 Da) binds to native rGrp94

with high affinity, relative to ATP In contrast to ATP

the SPR response to NECA was positive, and the

equilibrium binding isotherm was hyperbolic with a well-defined saturating SPR response and an apparent [A]0.5of
550 nm

Binding of divalent cations to rGrp94 The function of Grp94 as a protein chaperone is also sensitive to ER lumenal calcium levels [12,19] Like the other abundant lumenal proteins of the ER, Grp94 is

a low-affinity, high-capacity calcium-binding protein, making it one of the important calcium-storage and -buffer proteins of the ER [20] Our SPR binding stud-ies (Fig 4A) revealed that Ca2+ (40 Da) binds to rGrp94 at pH 7.4 with a positive SPR signal and the

Fig 3 Binding of NECA to immobilized native glycosylated rGrp94

as measured by SPR rGrp94 was immobilized on the sensor chip

at 16 239 RU, and the binding of NECA was measured within the

concentration range of 0–90 l M at 25
C and pH 7.4 in HBS-P

buf-fer containing 1% (v ⁄ v) dimethylsulfoxide The hyperbolic

equilib-rium binding isotherm revealed a well-defined saturating SPR

response with a half-maximal response ([A]0.5) at
550 n M

Fig 4 Binding of divalent cations to immobilized native

glycosylat-ed rGrp94 as measurglycosylat-ed by SPR rGrp94 was immobilizglycosylat-ed on the sensor chip at 18 230 RU, and the binding was studied at 25
C and pH 7.4 in HBS-P buffer (A) Representative sensorgrams obtained at 100, 400, 1000 and 3000 l M Ca 2+ (B) The equilibrium-binding isotherms for Ca 2+ (d), Mg 2+ (s), MgATP (.) and Na + (n) with a half-maximal response ([A] 0.5 ) at 2.8 m M for Ca2+ and 9.6 m M for Mg 2+

‘square-wave’ sensorgram is typical for a low-affinity

binding analyte [21,22] From the slightly sigmoidal

equilibrium response isotherm (nH¼ 1.2) an apparent

[A]0.5 of 2.8 mm and an Rmax of 39 RUÆ(ng

pro-teinÆmm)2) was estimated by nonlinear regression

ana-lysis (Fig 4B) By contrast, at pH 6.5 a hyperbolic

response isotherm (nH¼ 1.0) was obtained with an

apparent [A]0.5 of 8.6 mm, demonstrating a reduced

affinity and noncooperative binding at this acidic pH

(not shown) From Fig 4B it is seen that rGrp94 also

binds Mg2+ (24 Da) at pH 7.4 in the same

concentra-tion range as Ca2+, but with a lower apparent affinity

([A]0.5¼ 9.6 mm), indicating that at least some of the

cation-binding sites are of a mixed Ca2+⁄ Mg2+ type

By contrast, Na+ (NaCl) gave only a very small SPR

response indicating very little contribution of an ionic

strength effect to the responses observed for Ca2+

(CaCl2) and Mg2+ (MgCl2) Interestingly, the SPR

response to Mg2+was higher than for MgATP at equal

concentrations (Fig 4B) which may be explained by

the negative SPR signal resulting from the binding

of ATP alone (Fig 2) By assuming the same

dn⁄ dc (cm3Æg)1) for Ca2+as for rGrp94 (which is likely

an overestimation), an approximate theoretical Rmax

-value due to the contribution of the surface

concentra-tion (ngÆmm)2) of the analyte alone was estimated from

Eqn 2 to Rmax(theoretical)¼ 43 RU at 17 000 RU

immobilized, i.e  2.5 RUÆ(ng proteinÆmm)2), for the

n¼ 15 binding sites previously estimated [20] From

the response isotherm (Fig 4B) a Rmax of 39 RUÆ

(ng proteinÆmm)2) was obtained by nonlinear

regres-sion analysis indicating that the SPR response to Ca2+

largely may reflect a concentration dependent global

conformational change of the protein in addition to the

increased surface mass concentration

Interaction between Grp94 and other molecular

chaperones of the ER

Several ER resident proteins are calcium-binding with

low affinity and high capacity [20], and they have been

proposed to weakly interact through a ‘calcium matrix’

[19] In order to test whether Grp94 interacts with two

of these proteins, the molecular chaperones Grp78⁄ BiP

and calreticulin, rGrp94 and recombinant Grp78⁄ BiP

were immobilized on CM5 sensor chips by the

stand-ard procedure at a surface concentration of 3.4–5.6 ng

proteinÆmm)2, respectively In the experiments with

immobilized rGrp94 the injection of the recombinant

forms of Grp78⁄ BiP and calreticulin, dissolved at

vari-able concentrations in the flow buffer (HBS-P at

pH 7.4 or 6.5), revealed no binding in the absence

or presence of up to 3 mm Ca2+ or 500 lm ATP (not

shown) Similar negative binding results were obtained when Grp78⁄ BiP was immobilized on the sensor chip and rGrp94 was injected over the surface (not shown)

Discussion

The ER provides a tightly regulated environment for the folding and maturation of proteins destined to enter the secretory pathway [23], and the most abundant resident proteins (Grp94, Grp78⁄ BiP, protein disulfide isomerase and calreticulin) all function in protein fold-ing A characteristic feature of these molecular chaper-ones is the wide diversity of ligand-binding properties, including specificity and affinity [23] In this study

we addressed the proposal that Grp94 also has a peptide acceptor–donor function related to antigen pres-entation [2], using SPR spectroscopy as a biophysical method to study in vitro its multiple binding properties

ATP- and Ca2+-induced conformational changes

of native rGrp94 Although there is general agreement that Grp94 binds ATP and has a low ATPase activity, their functional significance has been controversial [4,16,17,24] In this study, ATP was found to bind to native glycosylated and nonglycosylated recombinant Grp94 with relat-ively low apparent affinity, and with a complex SPR response isotherm In contrast to the titration of the

ER chaperone Grp78⁄ BiP with ATP (Fig 2C), the SPR signal obtained with Grp94 was net negative at all concentrations of the nucleotide (Fig 2B), showing that the response is dominated by an ATP-induced conformational change This conclusion is in agree-ment with the change in conformation observed as a loss of an epitope-specific antibody binding in the pres-ence of ATP [7] and more recently crystallographically

as a large conformational change in the N-terminal nucleotide binding domain of a C-terminal truncated form of Grp94 upon ATP binding [17] These struc-tural studies also revealed a different binding mode for the adenosine analog NECA which in this study binds

to rGrp94 with relatively high affinity and with a net positive SPR response Interestingly, a similar negative conformation-dependent SPR response as observed for ATP binding to rGrp94 has been reported for the binding of maltose to the maltose-binding protein of Escherichia coli [25] In that case it was shown crystal-lographically that the ligand binding induced a con-formational change which caused a net decrease in the hydrodynamic radius of the protein [26], and the observed negative SPR response was considered to be

a function of the net change in hydrodynamic radius

that occurs upon maltose binding [25] By contrast, in

our control experiment with Grp78⁄ BiP ATP was

found to bind with a positive SPR signal (Fig 2C),

and the response isotherm gave a [A]0.5 of 168 lm

Although Grp78⁄ BiP and Grp94 are the two major

recipients of the pool of ATP translocated into the

lumen of ER [24] the effects of ATP binding are quite

different for the two chaperones Thus, Grp78⁄ BiP has

a weak ATPase activity which is stimulated by its

binding of exogenous polypeptides [27] and is further

regulated by ER cochaperones [28] Grp94, by

con-trast, has an unusually weak ATPase activity [4,16]

which is inhibited or not stimulated by exogenous

pep-tides [4], and the precise role of ATP binding⁄

hydro-lysis in the in vivo chaperoning function of Grp94

remains unclear [1,29]

Four ER lumenal calcium-binding glycoproteins were

originally reported in isolated rat liver microsomes [20]

A major component was Grp94, suggesting that one of

its roles might be in the calcium-storage and -buffer

function of the ER Moreover, calcium has been shown

to be required for the retention of Grp94 in the ER [12],

as well as to be involved in the transport of secretory

proteins out of the ER [19], and Grp94 may thus also be

considered as a Ca2+sensor protein In this study, it is

confirmed that native rGrp94 possess multiple

low-affin-ity binding sites for Ca2+[20] As reported above (see

Results) the theoretical maximum SPR signal [Rmax

(the-oretical)¼ 2.5 RUÆ(ng proteinÆmm)2)] assuming 15

binding sites for Ca2+[20] was markedly lower than the

observed SPR value [Rmax¼ 39 RUÆ(ng proteinÆ

mm)2)], indicating a major contribution of a Ca2+

-induced conformational transition to the overall SPR

response This finding is in agreement with a previous

far-UV CD spectroscopic study that calcium causes a

conformational change in Grp94 with a decrease in the

a-helical content from 40 to 34% [20] Interestingly, the

large conformation-dependent enhancement of the SPR

response observed in our study is similar to that

previ-ously observed for Ca2+binding to tissue

transglutami-nase [25], an allosteric enzyme which undergo significant

conformational changes, including an increase in its

hydrodynamic radius, upon binding of Ca2+[30]

Peptide-binding properties of native rGrp94 and

its inhibition by physiological ER ligands

Since the original studies by Srivastava et al [31] it

has been considered that Grp94 has the ability to bind

a subset of immunogenic peptides and is actively

involved in loading transporter associated with antigen

presentation (TAP)-translocated peptides onto MHC

class I molecules [2] However, a direct role of Grp94

in antigen presentation is highly controversial and has still to be formally proven [8,9] In particular, the reported low affinity and low stoichiometry of peptide binding to Grp94 in vitro, and the finding that the pep-tide binding seems to be almost irreversible at the selected experimental in vitro conditions (usually invol-ving heat shock denaturation and aggregation of the chaperone), are observations which have questioned its proposed peptide acceptor–donor function in vivo [8]

In this study, a low affinity was observed for the fully reversible binding of VSV8 to native glycosylated and nonglycosylated recombinant Grp94 (pH 7.4 or 6.5 and 25 or 37
C), with a hyperbolic equilibrium bind-ing isotherm and half-maximal bindbind-ing at
640 lm (pH 7.4 and 25
C) A similar low affinity was observed for the binding of VSV8 to Grp78⁄ BiP, i.e [A]0.5
560 lm (not shown), in agreement with the previously published low-affinity binding of a library

of 7-mer peptides to this chaperone [27] Moreover, at saturation (extrapolated value) an apparent maximal stoichiometry
6 mol peptide per mol of rGrp94 monomer was estimated (see Results) which presents experimental support for the recent hypothetical pro-posal [9] of a binding of peptides to this chaperone by

an adsorptive, rather than a bioselective, mechanism

A further argument [9] against the function of Grp94

in binding and transferring peptides for antigen presen-tation has been that peptide binding in vitro is consid-ered to be very stable, almost irreversible [5,7,8,10] Thus, previous in vitro studies on Grp94 binding of radiolabelled synthetic peptides were performed under nonequilibrium binding conditions using a chaperone exposed to either heat shock denaturation and aggre-gation (50–60
C) or to a chemically induced conform-ational change in connection with long incubation times (1–20 h) [5–7,10] In this study, the SPR analyses revealed an equilibrium binding of VSV8 to native rGrp94 at pH 7.4 and 25 or 37
C which was com-pletely reversible Moreover, the rate of dissociation was very rapid (t½¼ 7.2 ± 1.2 s; n ¼ 10) and incom-patible with the proposed peptide acceptor–donor function of the chaperone [31] Thus, the VSV8-bind-ing sites⁄ interactions in native Grp94 (this study) appear to be different from that observed for non-native forms of the protein [7,10] A further argument

is our finding that the binding of VSV8 was partly inhibited by ATP at concentrations (500 lm) consid-ered to be physiological in the ER and ERGIC lume-nal compartments [24], and most pronounced at the low concentrations of VSV8 The inhibitory effect of ATP is most likely related to the ATP-induced formational change discussed above, and a certain con-formation-related inhibition was also observed at the

reported high (mm) total concentration of Ca2+ in the

ER lumen [32] This may explain a previous

observa-tion that Grp94 and six other ER proteins were

selec-tively bound to an affinity column of denatured

histone and specifically eluted by ATP, and that the

release of Grp94 was further stimulated by

Ca2+⁄ Mg2+[33]

Additional, as yet unidentified, cofactors present in

the lumenal ER compartment in vivo may also affect

the peptide-binding properties of native Grp94,

inclu-ding its bininclu-ding parameters However, interactions of

Grp94 with its two related ER lumenal chaperones

Grp78⁄ BiP and calreticulin were excluded from this

study By analogy to Grp78⁄ BiP [28] and the

cytoplas-mic Hsp90, it is possible that the function of Grp94

may be regulated by physical interactions with

cochap-erones, but to date there is no direct evidence for the

existence of ER homologues of Hsp90-associated

pro-teins [1] Moreover, it should be noted that a low

affin-ity of peptide binding to native Grp94 has been

observed also in experiments at the cellular level Thus,

Lammert et al [34], in their studies on

streptolysine-permeabilized cells, found that radiolabelled peptides

are translocated into the ER lumen by the TAP

trans-porter and thus bind to Grp94 The fact that the

affinity-purified Grp94 could only be labelled with

TAP-translocated peptides containing a

photo-cross-linker (a photoreactive phenylalanine label) was

inter-preted as reflecting a weak interaction of the peptides

with the chaperone Finally, recent quantitative and

structural analyses of peptides extracted from a

Grp94-enriched glycoprotein fraction, isolated by

con-cavalin A affinity chromatography from a T-cell

lym-phoma tumour cell line, revealed a peptide occupancy

of only 0.1–0.4% compared with
100% occupancy

for MHC class I molecules [35] The specific nature of

Grp94-associated peptides, compared with those

pre-sented by MHC class I molecules, together with the

far substoichiometric occupancy of Grp94, strongly

suggested that Grp94 is not a peptide chaperone

involved in antigen processing [35]

Concluding remarks

Our data present experimental support for the recent

proposal by Nicchitta et al [9] that VSV8 under native

conditions binds to Grp94 by an adsorptive, rather

than a bioselective, mechanism, and thus further

chal-lenge the proposed in vivo peptide acceptor–donor

function of the chaperone in the context of APC

acti-vation [2,31] Moreover, Nicchitta et al [8,9] also

pro-posed an alternative mechanism, in which Grp94 may

function by inducing an activation of the immune

system independent of bound peptides Such a mech-anism is supported by a recent study [36] demonstra-ting that Grp94 and its N-terminal fragment induce an enhancement of the humoral immune responses to a protein antigen (HbsAg), related to the chaperone as

an adjuvant

Experimental procedures

The octapeptide VSV8 (RGYVYQGL), derived from VSV nucleoprotein (residues 52–59), was synthesized by Euro-gentec (Seraing, Belgium) NECA and ATP were purchased from Sigma (St Louis, MO) All solutions used in the SPR analyses were purchased from Biacore AB (Uppsala,

obtained from Stressgen Bioreagents (Victoria, Canada), and recombinant calreticulin from Abcam (Cambridge, UK) Polyclonal anti-Grp94 sera were obtained from StressGen Biotechnologies Corp (Victoria, Canada)

Purification of rGrp94

rGrp94 was purified from rough microsomes of rat pan-creas using a published procedure [37] with the following modifications The lumenal protein fraction was applied to

a concanavalin A–Sepharose column equilibrated with

50 mm phosphate buffer, pH 6.5 containing 0.2 m KCl at a slow flow rate at 4
C for 12 h, and washed with the same buffer until A280nm returned to
0 Glycoproteins were eluted using 0.5 m of methyl-a-d-mannopyranoride, and the eluate was concentrated and excess methyl-a-d-mannopyra-onoside removed by ultrafiltration (Centricon 30 from Amicon) before size-exclusion chromatography on a Super-dex 26⁄ 60 column (Pharmacia, Uppsala, Sweden) Purified rGrp94 was concentrated by ultrafiltration to a final concentration of 0.24 mgÆmL)1 Small aliquots were flash-frozen in liquid N2and stored at)80
C The purity of the rGrp94 preparations was ‡ 95% as judged by SDS ⁄ PAGE and staining with Comassie Brilliant Blue and stains-all [38], and immunoblotting revealed only a single band of the expected subunit molecular mass (
96 kDa) (not shown) The yield was about 32 lg rGrp94 per g of rat pancreas

SPR measurements

SPR analyses were performed using the Biacore 3000 bio-sensor system (Biacore AB) Dimeric Grp94 (0.24 lgÆmL)1) was desalted, diluted in 10 mm sodium acetate, pH 4.0 to

a final concentration of 0.03 lgÆmL)1 (exposure time

10 min), and immobilized covalently to the hydrophilic carboxymethylated dextran matrix of a CM5 sensor chip

by the standard primary amine coupling reaction as described by the manufacturer The amount of immobilized

correspond to
1 ng of immobilized proteinÆmm)2 [39],

and a surface concentration of 10–19 ngÆmm)2was used in

the analyses The responses to the different analytes were

found to be proportional to the amount of immobilized

proteins (range 10–19 ngÆmm)2) A reference surface was

subjected to the same procedure, but with no protein A

stable baseline was obtained in the cell with immobilized

protein by a continuous flow (50 lLÆmin)1) of HBS-P

run-ning buffer (10 mm Hepes, 150 mm NaCl, pH 7.4) for

1 h This equilibration also removed any low-affinity

lig-ands bound to the protein as isolated All measurements

were normally performed at 25 or 37
C with running

buffer (pH 7.4 or 6.5) at a constant flow of 5–30 lLÆmin)1

Each compound was dissolved in the running buffer and

ana-lysed (in triplicate) using a two-to-five-fold dilution series

All sensorgrams were processed by first subtracting the

SPR response observed for the reference surface Because all

the analytes, except NECA, were found to bind with low

affinity we were as expected [21,22] unable to measure

kin-etic rate constants for association and dissociation

More-over, for at least three of the analytes (ATP, Ca2+and

Mg2+) a conformational change of Grp94 represented a

major contribution to the overall SPR response The

sensor-grams were therefore analysed by simple Langmuir

bind-ing⁄ response isotherms, and the equilibrium responses

(Req¼ DRU at t ¼ 3 min) as a function of the free analyte

(A) concentration was used to determine the concentration

at half-maximal response ([A]0.5) and the global Rmax(obs)

by nonlinear regression analysis using the Jandel scientific

Sigma Plot technical graphing software The experimental

error for the SPR response in replicate injections of the

ana-lyte was found to be < 4% The theoretical maximum Req,

Rmax(theoretical), was estimated using the equation [40],

RmaxðtheoreticalÞ ¼ ðMr;analyte=Mr;ligandÞnðAÞRimmobilized ð1Þ

where Mr,analyteand Mr,ligandare the relative molecular mass

of the analyte and ligand, respectively; n is the number of

analyte-binding sites on the protein; (A) is the fraction

of active sites on the immobilized protein; and Rimmobilizedis

the RU of protein on the surface The activity (A) of the

immobilized ligands was assumed to be
40% at the high

immobilization levels used (10–19 ngÆmm)2) [40] Because

the refractive index increment [dn⁄ dc (cm3Æg)1)] of the

analytes may be different from that of the protein [14] this

parameter was also considered in the calculations, giving the

modified equation,

RmaxðtheoreticalÞ ¼ ðMr;analyte=Mr;ligandÞnð0:4ÞRimmobilized

ððdn=dcanalyteÞ=ðdn=dcligandÞÞ ð2Þ

where (dn⁄ dcanalyte) and (dn⁄ dcligand) are the refractive index

increment for the analyte and ligand, respectively Similar

(dn⁄ dc) values have been determined for bovine serum

albu-min (0.190 cm3Æg)1) and alanine (0.192 cm3Æg)1) [14], and

the same value was therefore used for Grp94 and VSV8

Note that Eqns 1 and 2 do not include any parameter for the global conformational changes which are often observed on low-molecular-mass ligand binding to immobi-lized proteins [25,41–43]

To account for different immobilization levels of protein, the SPR responses to analyte binding in each sensorgram were divided by the calculated amount of immobilized pro-tein and expressed as DRUÆ(ng propro-teinÆmm)2)

Acknowledgements

This work was supported by the Novo Nordic Foun-dation, Rebergs Legat, the Blix Family Fund and the University of Bergen

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