Tài liệu Báo cáo khoa học: Exposure of IgG to an acidic environment results in molecular modifications and in enhanced protective activity in sepsis doc

The present study shows that low-pH buffer treat-ment of a commercial IVIg results in its enhanced binding to bacterial antigens as well as to self-antigens, owing to structural changes

molecular modifications and in enhanced protective

activity in sepsis

Iglika K Djoumerska-Alexieva1,*, Jordan D Dimitrov1,2,3,4,*, Elisaveta N Voynova1,

Sebastien Lacroix-Desmazes2,3,4, Srinivas V Kaveri2,3,4and Tchavdar L Vassilev1

1 Department of Immunology, Stefan Angelov Institute of Microbiology, Bulgarian Academy of Sciences, Sofia, Bulgaria

2 Centre de Recherche des Cordeliers, Universite´ Pierre et Marie Curie Paris 6, France

3 Universite´ Paris Descartes, France

4 INSERM U 872, Eq 16, Paris, France

Introduction

The ability of antibodies to interact with one single or

with multiple structurally unrelated antigens

(monore-activity versus polyre(monore-activity) is believed to be an

inherent property of each individual immunoglobulin

molecule However, it has been previously shown by

us, as well as by others, that the in vitro exposure of

monoclonal and of polyclonal IgG to various protein-destabilizing factors may result in dramatic enhance-ment of their binding polyreactivity These treatenhance-ments include high-salt solutions, low-pH or high-pH buffers, chaotropic agents, ferrous ions, reactive oxygen species, and heme [1–7]

Keywords

antibodies; antibody polyreactivity; antigen–

antibody interaction; IgG; immunoglobulins

Correspondence

T Vassilev, Stefan Angelov Institute of

Microbiology, Bulgarian Academy of

Sciences, Acad G Bonchev St., Block 26,

1113 Sofia, Bulgaria

Fax: +359 2 870 0109

Tel: +359 2 979 6348

E-mail: vassilev@microbio.bas.bg

*These authors contributed equally to this

work

(Received 22 February 2010, revised 22

April 2010, accepted 18 May 2010)

doi:10.1111/j.1742-4658.2010.07714.x

IgG molecules are exposed on a regular basis to acidic conditions during immunoaffinity purification procedures, as well as during the production of some therapeutic immunoglobulin preparations This exposure is known to induce in them an antigen-binding polyreactivity The molecular mecha-nisms and the possible biological significance of this phenomenon remain, however, poorly understood In addition to the previously reported ability

of these modified IgG antibodies to interact with a large panel of self-anti-gens, enhanced binding to non-self-antigens (bacterial), an increased ability

to engage in F(ab¢)2⁄ F(ab¢)2 (idiotype⁄ anti-idiotype) interactions and an increased functional antigen-binding affinity are reported here The newly acquired ‘induced polyreactivity’ of low-pH buffer-exposed IgG is related

to structural changes in the immunoglobulin molecules, and is at least partly attributable to the enhanced role of the hydrophobic effect in their interactions with antigen Our results suggest that data from many previous studies on monoclonal and polyclonal IgG antibodies purified by low-pH buffer elution from protein A or protein G immunoaffinity columns should

be reconsidered, as the procedure itself may have dramatically affected their antigen-binding behavior and biological activity Low-pH buffer-trea-ted pooled therapeutic immunoglobulins acquire novel beneficial properties,

as passive immunotherapy with the pH 4.0 buffer-exposed, but not with the native therapeutic intravenous immunoglobulin preparation, improves the survival of mice with bacterial lipopolysaccharide-induced septic shock

Abbreviations

ANS, 8-anilinonaphthalene-1-sulfonate; CRP, C-reactive protein; IFN-c, interferon-c; IVIg, intravenous immunoglobulin;

LPS, lipopolysaccharide; RU, relative units.

A comparative study of seven licensed commercially

available pooled therapeutic intravenous

immunoglob-ulins (IVIgs) revealed that those produced using a

frac-tionation step at low pH were significantly more

polyreactive when tested on a complex mix of

self-anti-gens [8] The molecular mechanisms responsible for the

effect of low-pH buffer exposure on IgG molecule

have remained, however, poorly understood IVIg

preparations with lower and with higher

antigen-bind-ing polyreactivity have quantitatively different effects

on cells in vitro Low-pH buffer-exposed IVIg causes

significantly stronger suppression of Phaseolus vulgaris

agglutinin-induced proliferation of human peripheral

blood mononuclear cells than the native preparation

[8] Polyreactive natural antibodies form part of the

innate immunity mechanism, and are known to play a

major role in preventing pathogen dissemination in the

preimmune host [9–11] Natural polyreactive

antibod-ies are detected in the sera of all healthy individuals,

and their immunoreactivity increases dramatically in

the pure IgG fractions, purified from the same sera

using low-pH buffer elution from immunoaffinity

col-umns [12] However, the physicochemical

characteris-tics and the biological activities of IgG antibodies

transiently exposed to low-pH conditions remain

unknown We hypothesized that low-pH (£ 4) buffer

exposure could endow a commercially available IVIg

preparation with novel beneficial therapeutic proper-ties The present study shows that low-pH buffer treat-ment of a commercial IVIg results in its enhanced binding to bacterial antigens as well as to self-antigens, owing to structural changes in the immunoglobulin molecules The modified preparation is shown to have

a protective effect in experimental sepsis

Results

Exposure to a low-pH buffer increases the binding polyreactivity of IgG to foreign antigens Previous studies showed that low-pH buffer-exposed IVIg acquired enhanced autoreactivity [8] The first aim of the study was to find out whether the same broadening of IgG polyreactivity occurred when for-eign antigens were used The exposure of pooled human IgG to a pH 4 buffer resulted in an increase

in its pre-existing binding to antigens present in an Escherichia coli lysate, and in the appearance of some new bands showing the acquisition of new antibody reactivities (Fig 1A) Interestingly, the same treatment did not significantly change the reactivity to Bacillus anthracis antigens In contrast, the transient exposure

of IVIg to pH 2.8 buffer resulted in a significant (P < 0.05) enhancement of immunoreactivity, and in

E D

Fig 1 Exposure of IgG to a pH 4 buffer results in increased antigen-binding polyreactivity (A) Densitometric profiles of the reactivity of the native (solid line) and low-pH buffer-exposed (dashed line) IVIg to Escherichia coli antigens Migration distances (x-axis) expressed in pixels were plotted against the intensity of binding (y-axis) expressed in relative units (RU) for each IVIg preparation (B) Reactivity of native (lines 1 and 4), pH 4 buffer-exposed (lines 2 and 5) and pH 2.8 buffer-exposed (lines 3 and 6) IVIg with Bacillus anthracis antigens The membranes were incubated with two concentrations of IVIg: 100 lgÆmL)1(lines 1–3) and 50 lgÆmL)1(lines 4–6) (C) Increased binding of pH 4 buffer-exposed IVIg to recombinant human IFN-c (D) Increased binding of low-pH buffer-buffer-exposed IVIg to human factor H In both panels, binding

of the native IVIg is indicated by a solid line, and that of the low-pH buffer-exposed IVIg is indicated by a dashed line (E) Binding of two commercially available IVIg preparations [Endobulin (solid line); Octagam (dashed line)] to human factor H Data represent mean absorbance values ± standard deviation of quadruplicate wells in one of three ELISA experiments.

the appearance of a number of novel antigen-binding

specificities (Fig 1B)

Enhanced binding of low-pH buffer-exposed IVIg

to recombinant human interferon-c (IFN-c) and

other self-antigens

Interactions of IVIg with cytokines and other

mole-cules of the immune system have been shown to play a

role in the immunomodulatory effect of the

prepara-tion [13] To determine whether the IgG treatment

described affected binding to a typical

proinflammato-ry cytokine, the interactions of the native and the

low-pH buffer-exposed IVIg preparations with

recom-binant human IFN-c were compared by ELISA The

pH 4 buffer-exposed IVIg showed significantly

(P < 0.05) stronger binding to this human

proinflam-matory cytokine (Fig 1C) Next, the reactivity of

native and of low-pH buffer (pH 2.8)-exposed IVIg

towards a panel of structurally unrelated pure plasma

proteins or intracellular self-proteins was analyzed

This transient exposure resulted in increases in their

binding to all tested target antigens [see Fig 1D for

reactivity to factor H; data not shown for all other

antigens (see Experimental procedures)] We also

com-pared the antigen-binding potentials of two

commer-cially available IVIg preparations that differ in the

absence or presence of exposure to low-pH conditions

during the production process (Endobulin versus

Octa-gam) As expected, the binding of the second to

fac-tor H was significantly (P < 0.05) higher (Fig 1E)

The same was true for all other antigens in the panel

(not shown)

Low-pH buffer exposure increases the anti-idiotypic reactivity of IgG

After a pH 4 buffer exposure, the studied IVIg prepa-ration showed enhanced binding to IVIg F(ab¢)2 frag-ments (Fig 2A) as well as to autologous pooled IgM molecules (Fig 2B) In contrast, no increase in reactiv-ity of the modified IVIg to Fc-c (Fig 2C) or Fc-l fragments (Fig 2D) was observed

Antigen-binding kinetics of low-pH buffer-exposed IVIg

In order to obtain quantitative information on the effect of low-pH buffer exposure on the reactivity of IgG, we used real-time kinetic measurements of the interaction of IVIg with C-reactive protein (CRP) The binding profiles obtained after single injections of native and of low-pH buffer-exposed IVIg were com-pared As shown in Fig 3A, transient (5 min) exposure

of IVIg to pH 2.8 buffer resulted in an increase in the reactivity towards human CRP, as detected by this nonequilibrium binding assay The reactivity of the

pH 4 buffer-exposed preparation was also elevated, but to a much lower extent (approximately nine-fold) The native IVIg preparation showed no detectable binding to CRP at the concentration and during the period of observation used in the experiment

Interaction analyses using increasing concentrations

of the native and of the low-pH buffer-treated IVIg were also performed (Fig 3B) The data obtained were used to evaluate the kinetic constants of these inter-actions The bimolecular association rate constant of

Fig 2 Low-pH buffer exposure of pooled

human IgG enhances its binding to F(ab¢) 2

immunoglobulin fragments Dialysis of IVIg

against a pH 4 buffer results in increased

binding to F(ab¢) 2 fragments of IVIg (A) and

to pooled human IgM (B), but not to Fc-c

(C) or Fc-l fragments (D), as assessed by

ELISA Data represent mean absorbance

values ± standard deviation of quadruplicate

wells (solid lines, native IVIg; dashed lines,

low-pH buffer-exposed IVIg).

binding of the pH 2.8 buffer-exposed IVIg to CRP

was very low, at 33.5 ± 1.3 mol)1Æs)1 The estimated

dissociation rate constant had a value of (2.32 ·

10)3) ± (2.0· 10)5s)1) The equilibrium dissociation

constant for CRP and low-pH buffer-exposed IVIg

was 69.1 lm The absence of detectable binding or

negligible responses precluded the estimation of

reli-able values of kinetic parameters for the native and

the pH 4 buffer-exposed IVIg preparations

Enhanced role of hydrophobicity in the binding

of a pH 4.0 buffer-treated monoclonal IgG

antibody to its target antigen

To evaluate the types of intermolecular interactions in

antigen binding, pH and salt concentration screening

assays were performed This study was carried out

using the mouse monoclonal Z2 antibody, which

behaves in its native form as a typical monoreactive

antibody, as it interacts only with mouse IgG2a[14]

The interaction of the native Z2 antibody with its

immobilized target antigen was highly pH-dependent,

and characterized by a bell-shaped curve with a

bind-ing optimum at neutral pH (Fig 4A) On the other

hand, the interaction of low-pH buffer-exposed Z2

antibody was much less dependent on the pH of the buffer From pH 4.5 upwards, the binding reached a plateau and became almost independent of further increases in pH

The salt concentration dependence of the same inter-action (within the range 0–4 m sodium chloride) was also studied The binding of the native Z2 antibody to IgG2a was shown to be highly dependent on the salt concentration in the buffer In contrast, this interac-tion was mostly independent of the salt concentrainterac-tion

in the case when the low-pH buffer-exposed Z2 was left to bind with its target antigen (Fig 4B) Both observations could be explained by an increased role for the hydrophobic effect in the interaction of the modified monoclonal antibody with its immobilized antigen

Increase in the IgG hydrophobicity as evaluated

by 8-anilinonaphthalene-1-sulfonate (ANS) fluorescence

In order to confirm the increased role of the hydro-phobic effect upon low-pH buffer exposure of IgG, fluorescence spectroscopy using a molecular probe for protein hydrophobicity was applied ANS changes its

A

B

Fig 3 Real-time interaction analysis of the binding of IVIg to human CRP (A) Comparison of interaction profiles of 5 l M native IVIg (black line), pH 4 buffer-exposed IVIg (gray line) and pH 2.8 buffer-exposed IVIg (light gray line) with human CRP (B) Profiles characterizing the interactions of increasing concentrations (0.039–1.25 l M ) of native IVIg (left panel), pH 4 buffer-exposed IVIg (middle panel) and pH 2.8 buf-fer-exposed IVIg (right panel) with the same human molecule The sensorogram depicting the interaction of pH 2.8 bufbuf-fer-exposed IVIg was used for evaluation of the binding affinity by global analyses All measurements were performed at 25 C The results obtained in one of two independent experiments are shown.

fluorescence properties with the polarity of the

envi-ronment Thus, the transition from a polar to a

non-polar (hydrophobic) environment results in a dramatic

increase in its fluorescence signal This property and

the ability of ANS to bind to proteins make it a widely

used molecular probe for the evaluation of

hydropho-bicity of proteins, as well as for exploring structural

alternations in protein molecules [15–18]

Incubation of native IVIg in the presence of ANS

resulted in a modest change in the fluorescence signal

(Fig 4C) Similar spectral characteristics were

mea-sured in the case of IVIg exposed to a pH 4 buffer,

implying the absence of a significant increase in the

total hydrophobicity of the immunoglobulins The lack

of correlation between these findings and the data

shown in Fig 4A,B could well be explained by the

dif-ferent IgG preparations studied (pooled, polyclonal

versus monoclonal) and the different sensitivities of the

methods used Dramatic changes in the fluorescence

characteristics of ANS were seen in the presence of

pH 2.8 buffer-exposed IVIg Thus, a considerable

increase in the fluorescence intensity and a blue shift in

the fluorescence maxima were observed These effects

were observed at different concentrations of ANS

(Fig 4D) These findings further confirmed the results

from the pH and ionic strength dependencies of the interactions, demonstrating the increased hydrophobic-ity of low-pH buffer-exposed IgG molecules

Fluorescence studies on low-pH buffer-exposed immunoglobulins

Here, the physicochemical mechanisms responsible for the increased IgG antigen recognition potential after low-pH buffer exposure were studied Aromatic amino acids in proteins possess intrinsic fluorescence proper-ties when excited at an appropriate wavelength The fluorescence characteristics (intensity and wavelength

of the fluorescence maxima) depend on the polarity of the local protein environment Thus, changes in the positions of the fluorescent amino acids, caused by structural modifications of the molecule, result in changes in the microenvironment of the aromatic amino acids that affect the fluorescence characteristics, especially the position of the emission maxima [15,19] For these reasons, fluorescence spectroscopy is widely used for the analysis of structural changes and of the stability of proteins

We used tryptophan fluorescence in order to deter-mine whether the exposure of immunoglobulin

Fig 4 Low-pH buffer exposure of IgG antibodies results in an enhanced role of the hydrophobic effect in their antigen binding (A) A pH-scanning ELISA analysis of the interaction of the mouse monoclonal Z2 IgG antibody with its target antigen (B) The same antigen– antibody interaction in the presence of increasing concentrations of NaCl In both experiments, binding intensities are represented in RU, and each data point shows the mean value ± standard deviation of quadruplicate wells Solid lines, native Z2; dotted lines, low-pH buffer-exposed Z2 (C) Emission spectra of 32 l M ANS in the absence or presence of 2 l M native, pH 4 buffer-exposed or pH 2.8 buffer-exposed IVIg (D) Comparison of the fluorescence characteristics of increasing concentrations of ANS (1–32 l M ) in the presence of 2 l M native IVIg (solid lines) or pH 2.8 buffer-exposed IVIg (dashed lines) The emission spectra of ANS were recorded after excitation at 388 nm.

molecules to an acidic milieu would result in structural

modifications Indeed, an increase in the fluorescence

intensity of the pooled IgG preparation and a slight

red shift in the emission maxima following its exposure

to a pH 2.8 buffer were detected by fluorescence

spec-troscopy (Fig 5) This effect is consistent with a

change in the positions of tryptophan(s) in the

immu-noglobulins The red shift in the emission maxima is

indicative of the relocation of tryptophan(s) to a more

polar environment In contrast, treatment of the same

preparation with a pH 4 buffer did not change the

tryptophan fluorescence of the same molecules

Increase in the relative functional antigen-binding

affinity of a monoclonal antibody after its

exposure to a pH 4 buffer

The relative functional affinities of the native and the

low-pH buffer-exposed monoclonal Z2 antibody were

analyzed by thiocyanate elution ELISA [20] In the

elution assay, 0–3.0 m potassium thiocyanate was used

to disrupt the binding of the Z2 antibody to its target,

mouse IgG2a The functional affinity was defined by

the molar concentration of potassium thiocyanate

required for a 50% reduction in binding as detected in

ELISA at A405 nm The modified mouse monoclonal

IgG antibody bound more strongly to the immobilized

antigen (Fig 6)

Passive immunotherapy with low-pH

buffer-exposed, but not with native IVIg has

protective activity in mouse sepsis

The effect of treatment with low-pH buffer-exposed

IVIg on the survival of lipopolysaccharide

(LPS)-injected animals was studied The decision to test the modified immunoglobulin preparation in experimental sepsis was based on its enhanced binding to IFN-c, on the known role of polyreactive antibodies in infections [10], and on the hypothesis of Antonio Coutinho and Stratis Avrameas suggesting that polyreactive antibod-ies may represent a buffering system that prevents brisk changes in the levels of components of inflamma-tion, coagulainflamma-tion, and other pathways [21] The admini-stration of a single dose of 500 mgÆkg)1 of the modified IVIg had significant (P < 0.05) protective activity in this experimental sepsis model The native IVIg was not protective, regardless of the dose used (Fig 7A–D) Two sets of data strongly argue that the therapeutic effect of the modified IVIg was not due to better neutralization of the injected LPS: first, the binding of the preparation to LPS in its two forms was identical (tested by ELISA, data not shown); and second, the pH 4.0 buffer-exposed IVIg significantly (P < 0.05) decreased mortality, even if injected after the administration of LPS (Fig 7E)

Discussion

The brief exposure of polyclonal and at least some monoclonal IgG preparations to a low-pH buffer results in an alteration of the immunoglobulin struc-ture, and in the acquisition of enhanced antigen recog-nition behavior and new biological activities Our data show that the changes fall short of denaturation of the immunoglobulin molecules The main argument in support of this claim that low-pH-modified IgG molecules fully retain their F(ab¢)2-dependent and

Fig 5 Increase in the fluorescence intensity of pooled IgG after

low-pH buffer exposure Spectrofluorometric analyses of native

(solid line), pH 4 exposed (dotted line) and pH 2.8

buffer-exposed (dashed line) IVIg The ordinate represents fluorescence

intensity in RU.

Fig 6 Increased functional affinity of a mouse monoclonal Z2 anti-body after its exposure to a pH 4 buffer Thiocyanate elution ELISA was performed as described in Experimental procedures The func-tional affinity is represented by the molar concentration of potas-sium thiocyanate required for a 50% reduction in binding as detected at A 405 nm The results represent the average of at least three independent measurements, with the standard deviation indi-cated by error bars (gray bar, native Z2 antibody; black bar, pH 4 buffer-exposed Z2 antibody).

Fc-dependent antibody functions is based on clinical

experience over many years with IVIg preparations

produced using a low-pH buffer fractionation step

This study supports a previous suggestion [8] that

com-mercially available immunoglobulin preparations are

not equal, and shows that the differences between

them might be large enough to be clinically relevant

The possibility that nonspecific aggregation of IgG

on surface-adsorbed antigens is responsible for the

observed enhanced immunoreactivity can be ruled out

by the results presented above Spectroscopic data

(tryptophan fluorescence and ANS fluorescence) did

not imply the presence of aggregation of the IgG

mole-cules in solution after low-pH buffer treatment In

contrast, we observed an increase in the fluorescence

signal after exposure of IVIg to pH 2.8 buffer In the

case of IgG aggregation, a decrease in fluorescence

intensity would be expected Nonspecific aggregation

on the surface of the adsorbed antigens is also ruled

out by the fact that the increased antigen recognition

is not observed in the case of all studied antigens Our real-time kinetic measurements imply that the complex

of low-pH buffer-treated IgG with CRP dissociates, although at a slow rate

Wymann et al [22] have recently suggested that the increased antigen-binding polyreactivity of pH 4 buf-fer-exposed immunoglobulin preparations was mainly caused by the dissociation of IgG dimers in them Our data strongly suggest, however, that the effect of this exposure goes beyond IgG–IgG dimer dissociation, and affects the IgG molecules themselves

A possible explanation for the finding of new anti-gen-binding specificities after exposure to low-pH con-ditions is the induction of structural rearrangements in the variable region of the antibody Indeed, we observed changes in the tryptophan fluorescence char-acteristics of IVIg after its exposure to a low-pH (2.8) buffer The increase in the fluorescence intensity and the red shift in the emission maximum are signs of a change in the position of tryptophan(s) in the IgG molecules – a mark of the existence of a structural modification in the polypeptide chains of the immuno-globulins In addition, our results revealed that the interactions of low-pH buffer-exposed IgG are less dependent on changes in the ionic strength or the pH

of the medium Such binding behavior is typical of protein–protein bonds that rely on nonpolar types of interaction (hydrophobic effect and van der Waals contacts) Indeed, the increase in the hydrophobicity may well be explained by exposure of previously bur-ied hydrophobic amino acids to the solvent, as shown previously for IgG treated with chaotropic agents [23]

By using the fluorescence molecular probe for hydro-phobicity of proteins (ANS), we confirmed that the exposure of IgG to a low-pH buffer results in molecu-lar modifications characterized by a considerable increase in their surface-exposed hydrophobicity The antigen-binding behavior of low-pH buffer-exposed IgG preparations was enhanced for some, but not all, antigens tested (e.g IgG Fc fragments) We are cur-rently investigating whether the proteins that are pref-erentially recognized by the modified antibodies share any common features

It has been observed that the increased polyreacti-vity of a monoclonal IgG after transient exposure to urea correlates well with the elevated flexibility of the antigen-binding site and the involvement of hydropho-bic interactions as a driving force for the recognition

of the target antigen All of these findings allow us to hypothesize that elevated binding to various molecular patterns of monoclonal and polyclonal IgG after their transient exposure to low pH (pH 4 or less) may well be caused by an augmentation of the structural

A

E

B

Fig 7 Treatment with pH 4 buffer-exposed IVIg reduces mortality

in bacterial LPS-induced septic shock Survival curves of mice (15

per group) injected with 0.5 mg of LPS and treated with 4 mgÆkg)1

(A), 20 mgÆkg)1(B), 100 mgÆkg)1(C) or 500 mgÆkg)1(D) native IVIg

(solid lines), or pH 4 buffer-exposed IVIg (dashed lines), or NaCl ⁄ P i

(pH 7.4) alone (gray lines) The protective activity of the modified

IVIg is retained, even when its administration has been postponed

for 1 h (E) *P < 0.05, Mann–Whitney test.

plasticity of their paratopes Urea and low-pH buffer

exposure are both known to induce some degree of

melting of the protein conformation The increased

poly-reactivity observed could well be explained by limited

melting of immunoglobulin molecules by either of

these agents

Our previous data have indicated that treatment of

some IgG antibodies with different redox-active agents

is also able to enhance antigen-binding polyreactivity

by modulating the properties of the antigen-combining

sites of some, but not all, studied IgG antibodies The

binding behavior of some, generated in response to

repeated immunizations and expected to have rigid,

high-affinity binding sites, is not modified by exposure

to these conditions [5] The precise mechanisms that

make an individual IgG molecule resistant to

polyreac-tivity-inducing treatment remain to be determined

Redox-active agents (heme, iron ions, reactive oxygen

species) are released in vivo in inflammation sites as

well as after trauma, hemorrhages, etc Exposure to

low pH is part of the production process for some

commercial IVIg preparations, and is used on a daily

basis for IgG immunoaffinity purification

The dramatically increased antigen-binding

polyreac-tivity of polyclonal and of some monoclonal IgG

anti-bodies that have been briefly exposed to a pH 4.0 or

pH 2.8 buffer suggests that conclusions from many

previous studies on IgG, purified by low-pH buffer

elution from Protein A, Protein G or other

immuno-affinity columns, have to be carefully re-examined We

[24,25] and others [26] have previously used a similar

approach to immunopurify anti-self-antigen-binding

IgGs from IVIg by recirculating the pooled

immuno-globulin preparation through immunoaffinity columns,

containing pure immobilized self-antigens, and then

eluting the bound fractions by washing the columns

with a pH 2.8 buffer The latter were found to be

enriched in natural autoantibodies with the expected

specificities These antibodies were further tested in

various in vitro assays, and shown to engage in

biologi-cally relevant interactions Spalter et al claimed that

all individuals, regardless of their ABO histo-blood

antigen groups, possessed both A and B

anti-gen IgG in their sera Their main argument was based

on the ability of pure IgG, isolated from the sera of

donors with an A, B, AB or a O blood group, to bind

to the A as well as to the B antigens The pure IgG

fraction was obtained, however, by pH 3 buffer elution

from a Protein G Sepharose affinity column We

pro-pose an alternative explanation for the same

observa-tions Even a brief exposure to a low-pH milieu (pH 4

or lower) modifies some of the circulating IgG

molecules, resulting in their enhanced antigen-binding

polyreactivity and possibly in the acquisition of the ability to bind to a polysaccharide self-antigen (A or B) The low-pH buffer elution of the same fraction may also enhance its capacity to engage in F(ab¢)2⁄ F(ab¢)2 (idiotype⁄ anti-idiotype) interactions with other immunoglobulin molecules (see Fig 2) IVIg preparations are used in patients with primary and secondary immunodeficiencies, as well as in an increasing number of autoimmune and inflammatory diseases To the best of our knowledge, no compara-tive clinical studies on the immunomodulatory effects

of IVIg preparations produced by different protein fractionation technologies have been performed so far Data from this and from an earlier study [8] strongly suggest that licensed therapeutic IVIgs exposed to pro-duction steps at low pH do acquire new, clinically rele-vant, properties Their use could be beneficial in the early stages of sepsis, which are characterized by uncontrolled production of proinflammatory mediators (‘cytokine storm’) Previous studies have shown that binding to bacterial LPS is not affected in IgG mole-cules modified by protein-destabilizing agents [5], strongly suggesting that the prevention of LPS-induced sepsis death is due to the ability of this preparation

to attenuate the hyperreactivity of body defense mechanisms

In addition to sepsis, there is an increasing number

of emerging infectious diseases in which the severe gen-eralized inflammatory reaction of the infected host is a major factor in the poor outcome Recent additions to the list are H5N1 influenza (avian flu), dengue, Marburg and Lassa hemorrhagic fevers, and West Nile virus infection [27–31] One could speculate that pas-sive immunotherapy with ‘modified’ IVIg preparations would be beneficial in patients with these diseases An important argument in favor of low-pH buffer-exposed IVIg is that it has already been in clinical use for a long time, whereas the ferrous ion and heme-exposed IVIg preparations are at an early preclinical evaluation stage

Experimental procedures

Monoclonal antibody immunoglobulin preparations, and immunoglobulin fragments The Z2 hybridoma producing a mouse monoclonal IgG2b

antibody against mouse IgG2a was kindly provided by

E Rajnavolgyi (Department of Immunology, Lorand Eotvos University, Budapest, Hungary) The commercial intrave-nous immunoglobulins Endobulin S⁄ D (Baxter, Deerfield,

IL, USA), and Octagam (Octapharma, Lachen, Switzerland) were used in the experiments F(ab¢)2and Fc fragments of

IVIg, as well as an experimental pooled human IgM

preparation, were prepared as described previously [32,33]

Pure human Fc-l fragments, obtained from a patient with

l-heavy chain disease, were a gift from L Mouthon (Cochin

Hospital, Paris)

The Z2 antibody and IVIg samples were diluted in 0.1 m

sodium acetate buffer (pH 4.0 or 2.8) and incubated for

5 min The pH was then brought to 7.0, and the samples

were dialyzed against NaCl⁄ Pi (pH 7.2) [8] The pH 4.0

buffer was chosen because several commercial IVIg

prepa-rations are produced using a fractionation step with this

pH value Buffers of pH 2.8 are widely used for the

isola-tion of pure IgG by affinity chromatography

Immunoblot analysis

The total lysate from a nonpathogenic strain of B

anthra-ciswas kindly provided by S Mesnage (Centre de

Recher-che des Cordeliers, Paris, France) A lysate of E coli was

prepared as described elsewhere [5] Both bacterial antigen

extracts were subjected to 10% SDS⁄ PAGE and

trans-ferred to nitrocellulose membranes (Scheicher & Schuell,

Dassel, Germany) with a Mini Transfer Blot system

(Bio-Rad, Richmond, CA, USA) in a buffer containing 48 mm

Tris, 110 mm glycine, and 20% (v⁄ v) methanol Then, they

were incubated for 1 h at room temperature in NaCl⁄ Tris

containing 0.3% Tween-20 Membranes were further cut

into strips or fixed in a miniblot system, and incubated

for 1 h at room temperature with the native, the pH 4.0

buffer-exposed or the pH 2.8 buffer-exposed IVIg

prepara-tions (at 0.1 mgÆmL)1) After extensive washing, they were

incubated with goat anti-human IgG (Fc-specific),

conju-gated to alkaline phosphatase (Southern Biotech,

Birming-ham, AL, USA), and finally developed using the Nitro

Blue tetrazolium and bromo-chloro-indolyl-phosphate

substrates (both from Sigma-Aldrich, Taufkirchen,

Germany) The quantitation of bound antibodies in

immu-noblots was performed by densitometry in reflective mode,

using a UMAX 1220p scanner linked to a PC The data

were analyzed using imagetoolv2.0 for Windows

(UTHSCSA, San Antonio, TX, USA) Migration distance

(x-axis) was expressed in pixels, and intensity of binding

level (y-axis) was expressed in relative units (RU)

ELISA

Ninety-six-well polystyrene plates (Brand GMBH,

Wert-heim, Germany, or Nunc, Denmark) were coated with

5 lgÆmL)1 recombinant human IFN-c (a gift from I

Iva-nov, Institute of Molecular Biology, Bulgarian Academy of

Sciences, Sofia, Bulgaria), with 2 lgÆmL)1 human

fac-tor VIII, 10 lgÆmL)1 human factor IX (LFB, France),

10 lgÆmL)1 human CRP, 10 lgÆmL)1 human C3 (both

from Calbiochem), 10 lgÆmL)1 human factor H,

10 lgÆmL)1 human factor B (both from Complement

Technology, TX, USA), 20 lgÆmL)1 porcine thyroglobulin,

20 lgÆmL)1 rabbit tubulin, and 10 lgÆmL)1 bovine myelin basic protein (all three from Sigma-Aldrich), for 2 h at room temperature Plates were blocked with 0.25– 0.4% (v⁄ v) Tween-20 in NaCl ⁄ Pi for 2 h After washing with NaCl⁄ Pi containing 0.05% Tween-20, the plates were incubated overnight at 4C (in the case of IFN-c) or for

2 h at 25C (in the case of other proteins) with increasing concentrations of the immunoglobulin preparations under study The plates were then extensively washed, and goat anti-(human IgG) (c-chain-specific) coupled to alkaline phosphatase was added and incubated for 1 h at room tem-perature Immunoreactivities were revealed by adding p-ni-trophenyl phosphate (Sigma-Aldrich) diluted in appropriate buffers

The pH and salt concentration dependence of the binding

of the native or low-pH buffer-exposed mouse monoclonal Z2 antibody to its cognate antigen were analyzed by ELISA Polystyrene plates were coated with 20 lgÆmL)1of

a mouse IgG2amonoclonal antibody (clone IP2-11-1) The free binding sites were blocked with NaCl⁄ Pi containing 0.5% (v⁄ v) Tween-20 for 2 h at room temperature After washing, the plates were incubated overnight at 4C with dilutions of the native or the low-pH buffer-exposed Z2 For the pH-scanning analysis, the Z2 antibody was diluted

to 15 lgÆmL)1 in buffers with different pH values, as fol-lows: in citrate⁄ phosphate-buffered saline [0.05 m sodium citrate, 0.05 m Na2HPO4, 0.14 m NaCl, 0.05% (v⁄ v) Tween-20] with a pH in the range 3–7.5, or in carbonate-buffered saline [0.05 m NaHCO3, 0.05 m Na2CO3, 0.14 m NaCl, 0.05% (v⁄ v) Tween-20] with a pH in the range 8.5–12 In the ELISA with increasing salt concentrations, the Z2 antibody was diluted to 15 lgÆmL)1in buffers with 0–4 m sodium chloride After a 2 h incubation step under the described conditions, the plates were washed and further incubated with an alkaline phosphatase-conjugated goat anti-mouse IgG2b (PharMingen, San Diego, CA, USA) for 1 h at room temperature The following steps of the assay were performed as described above The results were represented in RU The binding at pH 7.0 or in the presence of 0 m NaCl buffers, respectively, was referred to

as 1 RU

The abilities of both IVIg variants to engage in idio-type⁄ anti-idiotype interactions were compared by ELISA Polystyrene plates were coated with F(ab¢)2 or Fc IVIg fragments, with pooled IgM, or with pure Fc-l fragments (all at 10 lgÆmL)1 in coating buffer) The blocking and washing steps were performed as described above The plates were incubated with increasing concentrations of the IVIg preparations under study, and after extensive washing, goat anti-human IgG (Fc-specific; Sigma-Aldrich) coupled

to alkaline phosphatase was added for an additional 1 h at room temperature In the case when Fc-c fragments were used as coating antigen, goat anti-human IgG [F(ab)2 -spe-cific] (PharMingen, San Diego, CA, USA) was used to

reveal antibody binding The final steps were performed as

described above

Real-time kinetic measurements

The kinetic constants of the interactions between IVIg and

human CRP were determined by surface plasmon resonance

(BIAcore 2000; GE Biacore, Uppsala, Sweden) CRP was

immobilized on research-grade CM5 chips, using an

amino-coupling kit (Biacore) as described by the manufacturer In

brief, CRP was diluted in 5 mm maleic acid (pH 5) to a

final concentration of 100 lgÆmL)1, and coated on the

pre-activated sensor surface Experiments were performed using

HBS-EP (0.01 m Hepes, pH 7.4, containing 0.15 m NaCl,

3 mm EDTA, and 0.005% Tween-20) as running and

sam-ple dilution buffer IVIg (native or low-pH buffer-exposed

Endobulin) was injected at concentrations in the range

5–0.039 lm at a flow rate of 10 lLÆmin)1 The association

and dissociation phases of the interaction were monitored

for 5 min The regeneration of the chip surface was

performed using a 5 m solution of guanidine-HCl

(Sigma-Aldrich) The binding to the surface of the uncoupled

control flow cell was always subtracted from the binding to

the protein-coated flow cells biaevaluation software

(ver-sion 4.1; Biacore) was used for the calculation of the kinetic

rate constants Calculations were performed by global

analysis of the experimental data using the kinetic models

included in the software, fitting the data with lowest value

of v2

Fluorescence spectroscopy

Intrinsic emission spectra measurements of the native and

of the low-pH buffer-exposed IVIg were performed on a

Hitachi F-2500 spectrofluorometer Samples of the IVIg

were exposed at 4C to pH 4 or pH 2.8 acetate buffers

After incubation, the samples were dialyzed against

NaCl⁄ Pi All analyses were carried out at 25C, using 1 cm

quartz cuvette The samples were diluted in NaCl⁄ Pito a

final concentration of 2 lm A wavelength of 295 nm,

which excites tryptophans, was used for the fluorescence

spectra measurements The fluorescence emission spectra

were recorded between 300 and 450 nm The excitation and

emission slits were both 10 nm, and the scan speed was

1500 nmÆmin)1

ANS fluorescence

ANS was obtained from Sigma-Aldrich IVIg

prepara-tions (at 2 lm, native as well as low-pH buffer-exposed)

were mixed with increasing concentrations of ANS

(1–32 lm) After excitation at 388 nm, the fluorescence

emission spectra of ANS were recorded between 425 and

600 nm in a 1 cm quartz curette The excitation and

emission slits were set to 10 nm, and the scan speed was

1500 nmÆmin)1

Thiocyanate elution ELISA The thiocyanate elution ELISA was performed as described previously [20] Briefly, ELISA plates were coated with a mouse IgG2amonoclonal antibody and, after washing, were further incubated overnight at 4C with 15 lgÆmL)1of the native or low-pH buffer-exposed mouse monoclonal Z2 antibody in the presence of increasing concentrations of potassium thiocyanate (ranging from 0 to 2.0 m) After incubation and washing, the antibody binding was mea-sured using a goat anti-mouse IgG2bas described above

Experimental septic shock Outbred ICR mice were purchased from the Breeding Farm

of the Bulgarian Academy of Sciences The experimental protocols were approved by the Animal Care Commission

of the Institute of Microbiology, in accordance with National and European Regulations The number of ani-mals used was kept at the minimum that still ensured statis-tical significance of survival differences between the experimental groups Septic shock was induced in 16–18-week-old animals by the intraperitoneal administration of

400 lg of bacterial LPS (from E coli B 055:B5, Sigma-Aldrich, #L2880) Minutes later, groups of mice (15 per group) were injected intravenously with increasing doses of the native IVIg or of the low-pH buffer-exposed IVIg prep-aration, or with NaCl⁄ Pialone Survival was observed for

5 days In a separate experiment, the native and the modi-fied IVIg (500 mgÆkg)1, 10 animals per group) were infused

1 h after the administration of LPS Any effect of a treat-ment started at this time-point should be the result of its influence on the pathophysiological mechanisms of the sep-sis syndrome [34]

Statistical analysis Statistical analyses were performed using graphpad prism, version 4.00 (GraphPad Software, San Diego, CA, USA) Statistical analyses of the ELISA data and the areas under the curve of the immunoblot densitometric profiles were performed using the paired Student t-test For survival analyses, differences between groups were analyzed by the Mann-Whitney U-test In all cases, P-values < 0.05 were considered to indicate statistical significance

Acknowledgements

This study was supported by the Bulgarian National Science Fund (grants VU-L-314⁄ 07 and

TK-X-1710⁄ 07), by the NATO Science for Peace Program