Immunoglobulins (Igs) protect against disease to a considerable extent by activating
complement and stimulatory IgFc receptors (FcRs) and aggregating microbial pathogens
1, 2
; yet IgG1, the predominant murine serum Ig isotype, cannot activate complement by
the classical pathway, binds more avidly to an inhibitory than to stimulatory FcRs
and has limited ability to aggregate pathogens.
1-3
In these regards, it resembles human IgG4.
4
We hypothesized that limited ability to activate effector mechanisms might protect
against immune complex (IC) immunopathology. Here we show that IgG1-deficient (γ1-)
mice,
5
immunized with a potent antigen (Ag), develop lethal renal disease soon after they
begin to produce Ag-specific antibody (Ab), while similarly immunized wild-type (WT)
mice remain healthy. Surprisingly, renal disease in this model is complement- and
FcR-independent and results from IC precipitation in glomerular capillaries, as in
some cryoglobulinemic humans.
6
IgG3, which self-associates to form large ICs
7,8,, accounts for >97% of the mouse Ig in this cryoglobulin; furthermore, glomerular
disease develops when mice are injected with IgG3 anti-trinitrophenyl (TNP) monoclonal
antibody (mAb) followed by a TNP-labeled protein. Renal disease is prevented in both
active and passive immunization models by Ag-specific IgG1; other isotypes are less
potent at preventing disease. These observations demonstrate the adaptive significance
of Ig isotypes that poorly activate effector mechanisms, reveal an IC-dependent, complement-
and FcR-independent nephrotoxic mechanism, and suggest that isotypes that poorly activate
effector mechanisms may be useful for inhibiting IC immunopathology.
Immunization of WT BALB/c or C57BL/6 mice with a potent immunogen, goat anti-mouse
IgD antiserum (GaMD), leads to a large, rapid, predominantly IgG1 Ab response to goat
IgG (GIgG) and the generation of mouse IgG1/GIgG ICs
9
, but no noticeable disease. In contrast, GaMD-immunized γ1- BALB/c and C57BL/6 mice
develop renal disease characterized by increased urinary protein, leukocyte esterase
(LE) and erythrocytes (blood), starting 6-7 days post-immunization, as well as increased
blood concentration of urea (BUN), and decreased serum albumin, with anasarca (subcutaneous
edema) and peritoneal effusion (Fig. 1a-e and Extended Data Fig. 1a). Kidney color
in these mice changes from red-brown to yellow, reflecting dramatically decreased
perfusion (Fig. 1f). Microscopically, glomerular capillaries contain IgG and complement
deposits, but few inflammatory cells (Figs. 1g and Extended Data Fig. 1b and c). The
microscopic damage is initially observed 6-7 days after GaMD immunization and is followed
by disruption of glomerular structure and development of fibrosis (Fig. 1g and Extended
Data Fig. 1c). Because no other organ damage was observed (not shown), it is likely
that renal insufficiency caused the death of 60-80% of γ1- mice by day 16-22 post-immunization
(Fig. 1h).
Lack of the normally dominant IgG1 response in GaMD-immunized γ1- mice was accompanied
by increased production of IgG3, IgM, and in some experiments, IgG2a (Fig. 2a and
Extended Data Fig. 2a). Because these isotypes, unlike IgG1, strongly activate complement
and IgG2a potently activates all stimulatory IgGFcRs,
1-3
we expected renal disease in γ1- mice to be complement- and possibly FcR-dependent.
However, severe renal disease still developed in GaMD-immunized γ1- mice that lacked
both C3, the complement component that is generally required for all complement activation
pathways,
2
and FcRγ–chain (FcRγ), a required component of all stimulatory FcRs in mice
10
(Figs. 2b and c and Extended Data Fig. 2b). This was true even when these mice were
also treated with C5a antagonists (Extended Data Fig. 3). Inhibition of IgG2a production
with anti-IFN-γ mAb
11
also failed to suppress kidney disease (Extended Data Fig. 2c and d). Additional studies
eliminated the possibilities that renal disease in γ1- mice results from persistence
of circulating Ag or a decreased ratio of Ig to Ag that might form more inflammatory
ICs (Extended Data Fig. 4).
These observations suggested that GaMD-induced kidney disease might be caused by a
qualitative change in the ICs in immunized γ1- mice. Consistent with this, IgG3, the
dominant isotype produced in these mice, generates large ICs by self-associating through
Fc– Fc interactions
7,8
; these large ICs tend to reversibly precipitate at reduced temperature (i.e.; they
are cryoglobulins) and at increased concentration (which occurs as plasma is ultra-filtered
in glomeruli). Indeed, large cryoglobulin concentrations were found in plasma from
GaMD-immunized γ1-, but not WT mice (Fig. 2d); cryoglobulin analysis demonstrated
that IgG3 was the dominant mouse Ig constituent, although they also contained IgM
(Fig. 2e). In keeping with this, deposits within glomerular capillaries were rich
in IgG3 (Fig. 2f). A dominant role for IgM in this kidney disease model is unlikely
because glomerular IgM, unlike glomerular IgG3, does not persist (Extended Data Fig.
5); severe disease still develops in immunized mice deficient in both IgG1 and J chain
(Extended Data Fig. 6), which produce little pentameric IgM;
12
and mice that lack activation-induced cytidine deaminase (AID) and consequently secrete
only IgM do not develop kidney disease following GaMD immunization (data not shown).
A passive immunization model was used to further test the hypothesis that renal disease
can be caused by IgG3/Ag IC precipitation in glomerular capillaries. WT BALB/c mice
were injected simultaneously with IgG3 anti-TNP mAb i.v.and TNP-goat serum (TNP-GIgG)
s.c.on days 0 and 1. These mice developed increased BUN, urine protein, LE, and blood,
and large deposits of amorphous material in glomerular capillaries on day 2 (Fig.
3a-c and Extended Data Fig. 7a). Similar lesions developed in similarly treated C3-deficient
mice, (Fig. 3d and Extended Data Fig. 7b) and FcRγ-deficient mice, as well as in C57BL/6
mice and in BALB/c WT mice when TNP-BSA was substituted for TNP-GIgG (not shown).
WT mice injected with TNP-GIgG plus IgG1, IgG2a, or IgG2b anti-TNP mAb failed to develop
renal disease (Fig. 3a and Extended Data Fig. 7a). None of the mAbs induced disease
when injected without TNP (Fig. 3b and data not shown).
The unique pathogenicity of IgG3 raised the possibility that the other IgG isotypes
might be able to inhibit IgG3-mediated disease. Consistent with this, GaMD induced
only transient renal disease in γ1+/- mice, which produced ∼50% as much IgG1 as WT
(γ1+/+) mice, but similar IgG3 as γ1-/- mice (Extended Data Fig. 8). Similarly, development
of proteinuria, hypoalbuminemia and azotemia in GaMD-immunized γ1-/- mice was suppressed
by administration of the IgG1 anti-GIgG-rich serum from GaMD-immunized WT mice (GaMD
immune WT serum). This suppression was Ag-specific, because it was not observed with
serum from rabbit anti-mouse IgD-immunized WT mice (RaMD immune WT serum) (Figs. 4a
and b). Disease suppression by GaMD immune WT serum required initiation of treatment
by day 5 after GaMD immunization (Extended Data Fig. 9a), when immunized mice first
secrete IgG anti-GIgG. Importantly, injection of GaMD immune WT serum starting 4-5
days after GaMD immunization suppressed renal disease in γ1- mice without decreasing
serum IgM, IgG2a or IgG3 levels and only modestly decreased production of any isotype
by cultured spleen cells (Fig. 4c and Extended Data Fig. 9b). Thus, IgG1 primarily
suppresses renal disease in our model by competing with IgG3 for Ag epitopes and/or
changing the solubility of ICs rather than by decreasing IgG3 secretion; and the increased
IgG3 secretion by GaMD-immunized γ1- mice results from blocked isotype switching rather
than from a lack of IgG1.
Consistent with our conclusion that IgG1 suppresses IgG3-induced renal disease by
competing with IgG3 for Ag binding and/or changing IC solubility, IgG1 anti-TNP mAb
suppressed glomerular IgG3 deposition and disordered renal function when mice were
injected with IgG3 anti-TNP mAb plus TNP-BSA or TNP-goat serum (Fig. 4d, e and Extended
Data Fig. 10). Very little IgG1 was found in the glomeruli of mice injected with both
isotypes (Extended Data Fig. 10b), suggesting that the presence of IgG1 in an IC with
IgG3 prevents glomerular IC deposition and/or increases its clearance. IgG1 suppression
of IgG3-associated renal disease did not depend on C3 or Fc γRIIB (Fig. 4d and e and
Extended Data Fig. 7b, c) and isotype control mouse IgG1 mAb had no effect on IgG3-mediated
disease (data not shown). IgG1 anti-TNP was more potent than IgG2a anti-TNP, and IgG2a
anti-TNP more potent than IgG2b anti-TNP, at preventing IgG3-mediated disease (Fig.
4f and Extended Data Fig. 7d), even though isotype switch variants of IgG1, IgG2a
and IgG2b were used that had identical Ag binding V regions,
13
avidity for TNP (Extended Data Fig. 7e), non-specific binding to IgG3 (Extended Data
Fig. 7f) and similar non-specific binding to themselves (Extended Data Fig. 7g). Preferential
inhibition by IgG1 over IgG2a and IgG2b was also seen in studies with a second set
of mAbs that were not switch variants (not shown).
The increased ability of IgG1 to inhibit IgG3-mediated renal disease may be a consequence
of its short hinge region length and consequent low segmental flexibility. This may
limit IC formation by decreasing IgG1's ability to bind bivalently to a ligand and
increasing the likelihood that it will sterically block binding of IgG3,
14, 15
which could separate IgG3 molecules sufficiently to inhibit their self-association.
Consistent with this possibility, IgG2a, which has hinge region length and segmental
flexibility intermediate between IgG1 and IgG2b
14
, had an intermediate ability to suppress IgG3-mediated renal disease (Fig. 4f and
Extended Data Fig. 7d). Thus, IgG1 may limit Ab-mediated disease in our model by suppressing
the formation of ICs that become insoluble when they are concentrated by glomerular
filtration. We cannot, however, eliminate the possibility that the addition of IgG1
to IgG3/Ag ICs facilitates their elimination by the reticulo-endothelial system, which
could limit nephrotoxicity.
Our observations make two important points: First, we show that ICs can destroy kidney
function by precipitating in glomerular capillaries, even in the absence of complement
and FcR activation. The rapidity of capillary obstruction and the lack of an anaphylatoxin
gradient in our model, as well as the ability of complement to increase IC solubility
and elimination
16
, may explain the failure of complement to exacerbate disease despite its deposition
in glomeruli. Secondly, we show that Ig isotypes that activate effector mechanisms
poorly protect against disease caused by more proinflammatory isotypes. In this regard,
isotypes such as mouse IgG1 and human IgG4 appear to act like partial agonists, which
can cause immunopathology under some conditions, but prevent it by blocking the effects
of other, more proinflammatory isotypes, in other circumstances. Indeed, functional
similarities between mouse IgG1 and human IgG4 suggest that our observations in mice
are human-applicable. Mouse IgG1-mediated protection against IC deposition in our
model is probably facilitated by its short hinge region, which limits Ag crosslinking
by decreasing segmental flexibility
14
. Human IgG4 is likely to have even greater ability to suppress IC development because,
in addition to its short hinge region
14
, its labile inter-heavy chain disulfide bond allows it to dissociate into univalent
half molecules
17
.
Similar abilities of mouse IgG1 and human IgG4 to suppress disease caused by other
isotypes may extend further. While not shown in this paper, our preliminary observations,
with additional collaborators, demonstrate that the absence of IgG1 promotes the development
and severity of complement- and FcγR-mediated diseases in mice, including collagen-induced
arthritis and experimental myasthenia gravis. Thus, mouse IgG1 likely suppresses disease
mediated by complement and FcγRs, as well as disease mediated by excessive intravascular
formation of insoluble ICs. The inability of human IgG4 to activate complement
2, 3
and its poor binding to FcγRs
4
suggest that it can similarly limits organ damage in complement- and FcγR-mediated
diseases. These considerations raise the possibility of using human IgG4 Abs to suppress
autoimmune and IC disorders that are mediated by other isotypes, an approach that
might be amplified by making IgG4 Abs even more immunosuppressive by increasing their
sialylation
18
, galactosylation
19
, and/or affinity for FcγRIIB
20
.
Methods
Mice
All mice were bred and maintained in the SPF facility at the Cincinnati Children's
Research Foundation and all experiments were done with the approval of and in accordance
with regulatory guidelines and standards set by the Institutional Animal Care and
Use Committee of Cincinnati Children's Hospital Medical Center. Male and female mice
were used between the ages of 8 and 20 weeks. BALB/c and/or C57BL/6 background γ1-deficient
mice
5
, FcRγ-deficient (Taconic, Hudson, NY), C3-deficient mice (a gift from Dr. Marsha
Wills-Karp, Cincinnati Children's Hospital, Cincinnati, OH), J-chain deficient mice
(a gift of Dr. Dennis Metzger, Albany Medical College, USA), FcγRIIB-deficient, AID-deficient
(a gift of Dr. M. Muramatsu, Kyoto University, Kyoto, Japan)
21
and WT control mice were bred in our colony. Double and triple gene-deficient mice,
made by crossbreeding the single gene-deficient mice, were typed by PCR. Typing for
γ1 and C3 deficiency was confirmed by gel double diffusion assay of serum. WT littermates
of the double and triple gene-deficient mice were used as controls. Mice of the appropriate
genotype were randomly assigned to groups, but a specific randomization program was
not used. Studies were not blinded.
Active model for induction of IC renal disease
Mice were injected s.c. with 0.2 ml (BALB/c) or 0.4 ml (C57BL/6) of GaMD on day 0.
In some experiments mice were also injected i.p. daily with pooled day 12 serum from
GaMD or RaMD immunized WT mice (GaMD immune WT serum and RaMD immune WT serum, respectively).
Spontaneously micturated urine was collected from mice on specific days and assayed
for protein, LE and blood content by urine dipstick. Serum was collected by tail vein
puncture and kidneys were preserved in formalin or gluteraldehyde or frozen in OCT
for histologic evaluation.
Passive model for IC induction of renal disease
Mice were simultaneously injected with mouse IgG3 anti-TNP mAb i.v.and TNP-goat serum
or TNP-BSA s.c. on days 0 and 1. Some mice also received mouse IgG1, IgG2a or IgG2b
anti-TNP mAb isotype switch variants or in some cases non-switch variant mAbs i.v.on
days 0 and 1.
Reagents
Hybridomas were obtained from the following sources: 9A6 (mouse IgG3 anti-TNP mAb),
a gift from Shozo Izui
22
; 1B7.11 (mouse IgG1 anti-TNP mAb), from the American Type Culture Collection (Rockville,
MD); HY1.2 and C1040 (mouse IgG2a anti-TNP mAbs) and GORK (mouse IgG2b anti-TNP mAb),
a gift from Brigitta Heyman; switch variant mouse IgG1, IgG2a and IgG2b anti-TNP mAbs,
a gift from Mike Robson
23
and XMG-6 (rat IgG1 anti-mouse IFN-γ)
24
from DNAX, Palo Alto, CA. A hybridoma that secretes mouse IgG1 anti-FITC mAb was produced
in house. Hybridomas were grown as ascites in Pristane-primed athymic nude mice and
mAbs were purified from ascites by ammonium sulfate precipitation (25%-50% for all
IgGs except 20%-30% for IgG3), followed by DE-52 cation exchange chromatography for
the IgG isotypes. IgG2a anti-TNP mAb was also purchased from Bio X Cell (Lebanon,
NH). GaMD and RaMD antisera were made as described
25
. Mouse hyperimmune antisera to goat (GaMD immune WT serum) and rabbit (RaMD immune
WT serum) were made by injecting WT mice s.c.every 14 days for several injections
with GaMD or RaMD, respectively and pooling serum collected 10-12 d after each immunization.
Non-immune mouse serum was collected by tail vein bleeding from untreated BALB/c or
C57BL/6 WT mice and pooled. The C5aR antagonists, JPE 1275
26
(a gift from John Lambris, U of Penn, Philadelphia, PA) and A8δ71-73
27
, were injected as 20 μg or 10 μM doses, respectively, i.p. every 12 hrs starting
on d4 and ending on d8 after GaMD immunization.
Urine and serum measurements
Urine protein, LE and blood levels were measured on fresh, freely excreted urine using
Multistik 10 (Becton-Dickson). Measurements were on a colorimetric scale, ranging
from 0 to 4 for protein and 0 to 3 for LE and blood, as per manufacturers’ instructions.
Serum albumin and BUN were measured using a Beckman DXC (Brea, CA) courtesy of Mr.
Robert Louderbeck, Veterans Administration Medical Center, Cincinnati, Ohio. Serum,
splenic supernatants and re-suspended cryoglobulin pellets were analyzed for total
and GIgG-specific IgG1, IgG2a/c, IgG2b, IgG3, IgE, IgA and IgM content, using standard
sandwich ELISA with paired anti-Ig isotype mAbs for each Ig isotype (BD-Pharmingen
and eBioscience). Sera, splenic supernatants and re-suspended cryoglobulin solutions
were titered for GIgG-specific Ab levels by ELISA, as previously described
25
, using wells coated with 5 μg/ml of goat IgG. Gel double diffusion was used to identify
mouse IgG1, mouse C3 and GIgG in mouse serum with Abs purchased from Bethyl.
TNP-goat serum and TNP-BSA
Goat serum or BSA were conjugated to TNP as previously described
28
.
Immunofluorescence microscopy
Kidneys were harvested from mice and immediately placed in OCT and snap frozen in
liquid nitrogen. OCT-embedded kidneys were stored at -80°C. Frozen tissue sections
were cut, mounted on glass slides, fixed in acetone and air-dried. After rehydration
and blocking, immunofluorescence microscopy was performed with FITC-labeled anti-C3
and anti-mouse IgG antibodies (ICN biomedicals Inc./Cappel, Aurora, Ohio). After washing,
coverslips were applied to slides after addition of anti-fade medium that contained
DAPI (Prolong Gold; Invitrogen Corp., Carlsbad CA). Slides were assessed microscopically
and photographed at an original magnification of 400X using an RT Slider digital camera
(Diagnostic Instruments Inc., Sterling Heights, MI) mounted on an E600 fluorescent
microscope (Nikon Instruments, Melville, NY).
Immunostaining microscopy
Kidneys were harvested from mice and immediately placed in formalin for a minimum
of 3 days before embedding in paraffin. For IgG3 staining, de-paraffinised sections
were incubated with goat anti-mouse IgG3 antibody (Jackson ImmunoResearch Laboratories,
West Grove, PA) for 1 hr, then incubated for 12 min with biotin-donkey anti-goat IgG
antibody (Jackson ImmunoResearch Laboratories) and visualized with an iVIEW Plus Detection
Kit (Ventana Medical Systems, Tucson, AZ). Staining for IgG1 was performed with a
rabbit anti-mouse IgG1 antibody (Novus Biologicals, Littleton, CO), followed by biotin-donkey
anti-rabbit antibody (Jackson ImmunoResearch Laboratories). All antibodies were used
at 1:100 dilutions and all staining was performed with a Discovery XT (Ventana Medical
Systems).
Quantitation of splenic Ig production
Spleens were diced into 1-2 mm cubes, washed in ice cold PBS, then transferred to
a Petri dish with 5 ml of RPMI medium 1640 supplemented with fetal bovine serum, penicillin,
gentamicin, HEPES, sodium pyruvate, essential amino acids and 2-mercaptoethanol and
cultured at 37°C, 5% CO2 for 24 hrs. Supernatants were collected, separated into aliquots,
frozen and stored at -80°C until analyzed.
Cryoprecipitant collection
Blood was collected in a polystyrene centrifuge tube and immediately incubated for
4 hrs at 37°C. The tube was centrifuged and solid material was removed. Sera were
incubated at 4°C for 7 days. Precipitates were obtained by centrifugation, washed
3 times in ice-cold saline, then re-suspended in a volume of saline equal to that
of the initial serum sample and heated to 37°C for 2 hrs to dissolve cryoprecipitates.
Samples were then re-centrifuged at room temperature and supernatants were collected.
Anti-TNP mAb ELISA
For avidity measurement ELISA plates were coated with 10 μg TNP-OVA/ml overnight followed
by varying concentrations of the mAbs. This was followed by HRP- or biotin-labeled
anti-mouse Ig isotype-specific mAb purchased from BD bioscience, streptavidin-HRP
if needed and SuperSignal ELISA substrate from Pierce (Cheshire, United Kingdom).
For IgG3 binding or self-association measurement, ELISA plates were coated with 10
μg mouse IgG1, IgG2a, IgG2b or IgG3 anti-TNP mAb/ml overnight followed by varying
concentrations of biotin-labeled mouse IgG1, IgG2a, IgG2b or IgG3 anti-TNP mAbs. This
was followed by streptavidin-HRP and SuperSignal substrate from Pierce.
Statistics
The non-parametric Mann-Whitney 2-tailed t test (GraphPad Prism 5.0; GraphPad Software,
La Jolla, CA) was used to compare Ig levels, BUN and albumin concentrations between
different groups of mice. A P value <0.05 was considered significant. A more complex
test was used to compare the multiple samples in Fig. 4f and Extended Data Fig. 7d
(see figure legend for details).
Sample size was calculated with a tool for comparing 2 independent samples on the
website <http://www.stat.ubc.ca/∼rollin/stats/ssize/n2.html>. Sample size calculations
for initial studies were based on the assumptions that a one sided test would be used
to test the hypothesis that the mean for the normal (usually wild-type) group would
be 3 times as large (or one third as large) as the mean for the abnormal (usually
γ1-deficient) group, that the common standard deviation would be the same size as
the smaller mean, that the type I error rate would be 0.05 and that the desired power
would be 0.80. These assumptions suggested a sample size of 4 for each sample. In
practice, we often used the results of our initial studies to determine whether this
sample size was sufficient to yield the desired power or indicate the larger sample
size that would yield a significant result if the trend observed in the initial study
predicted the results obtained with the larger sample size.
Extended Data
Extended Data Figure 1
GaMD immunization of γ1- mice induces renal dysfunction and glomerular deposition
of PAS+ material that includes IgG and complement
a, WT and γ1- mice (4/gp) were immunized with GaMD. Urine LE and blood were obtained.
b, Representative photomicrographs of glomeruli stained for C3 (top panels) or total
mouse IgG (bottom panels) from WT (right panels) and γ1-/- mice (left panels) 12 d
post-GaMD immunization 3 mice/group. c, Deposition of amorphous PAS+ material in glomeruli
of γ1-, but not WT begins ∼7 days post GaMD-immunization and leads to glomerular destruction
by day 9. Note the scarcity of inflammatory cells in glomeruli. Representative data
of 6 mice/group.
Extended Data Figure 2
The development of kidney disease in GaMD-immunized γ1- mice is independent of IFN-γ,
IgG2a, C3 and FcRγ
BALB/c WT and γ1- mice (5/gp) were immunized with GaMD on d0 and injected with 1 mg
of either anti-IFN-γ or control mAb on days 0 and 5. a, Total levels of all Ig isotypes
were determined in 24 hr culture supernatants of spleen cells harvested on days shown.
b, GaMD-immunized γ1-, γ1-/FcRγ-, γ1-/C3-, C3-/ FcRγ- and γ1-/C3-/FcγR- mice (5/gp)
had their urine tested for LE and blood on days shown. c, d, BALB/c WT and γ1- mice
(5/gp) were immunized with GaMD on d0 and injected with 1 mg of either anti-IFN-γ
or control mAb on days 0 and 5. c, Urine obtained on days indicated was assayed for
protein, LE and blood. d, BUN levels were determined prior to and 10 days after GaMD
immunization. * p<0.05
Extended Data Figure 3
Neither complement nor stimulatory FcRs is required for renal disease development
in GaMD-immunized γ1- mice
Mixed background γ1- and γ1-/C3-/FcRγ- mice (4/gp) were immunized with GaMD ± C5aR
antagonist. Urinalyses were obtained at baseline and daily starting on day 6.
Extended Data Figure 4
Delayed antigen elimination does not account for renal disease in GaMD-immunized γ1-
mice
a. BALB/c WT and γ1- mice (10/gp) were immunized s.c. withGaMD. Sera obtained 5, 6,
7 and 9 days later were evaluated by gel double diffusion for the presence of goat
IgG. b-e. BALB/c WT mice (4 or 5/gp) were injected s.c. with a total of 0.2 ml of
different mixtures of GaMD and goat anti-KLH antisera. b, c, Mouse sera collected
9d later were assayed for BUN (b) and IgG1 anti-goat IgG Ab (c). d, Sera obtained
6-13d post-immunization were evaluated by gel double diffusion for the presence of
goat IgG. e, Urine samples collected 4-12 days post-immunization were analyzed for
protein. * p<0.05, **p<0.005
Extended Data Figure 5
IgG3 IC persist and accumulate in the glomeruli of GaMD-immunized γ1-
BALB/c WT and γ1- mice were left untreated or were immunized with GaMD. Kidney sections
were stained for mouse IgG1, IgG2a, IgG2b, IgG3 and IgM 8 and 12d later. Representative
photomicrographs from 3 GaMD-immunized mice are shown. Insets show magnified views.
No staining was observed with sections from unimmunized mice (not shown).
Extended Data Figure 6
Severe renal disease develops in GaMD-immunized γ-/J chain- mice
BALB/c γ1- (12 mice), J-chain- (9 mice) and γ1-/J-chain- (12 mice) were injected s.c.
with GaMD. a, Urinalysis was performed on indicated days. b, BUN levels on d 0 and
11. The difference between γ1- and γ1- x J-chain- mice was not consistently observed.
c, Survival of GaMD-immunized mice. * p<0.05
Extended Data Figure 7
IgG1 inhibits IgG3-induced cryoglobulin kidney disease independent of complement and
FcγRIIB and better than IgG2a and IgG2b
a, WT mice (4/gp) were injected i.v. with 4 mg of mouse IgG1, IgG2a, IgG2b, or IgG3
anti-TNP mAb and s.c. with 100 μl of TNP-goat serum on days 0 and 1. Urine LE and
blood measured prior to injections and on d1 and d2. b, Urine LE and blood for BALB/c
WT and C3- mice (4/gp) injected i.v. with 4 mg of IgG3 anti-TNP mAb and s.c. with
400 μl of TNP-goat serum on d0 and 1. c, WT and FcγRIIB-deficient (FcγRIIB-) mice
(4/gp) were injected s.c. with 100 μl of TNP-goat serum and i.v. with 4 mg of IgG3
anti-TNP ± 5 mg of IgG1 anti-TNP on d0 and 1. Urinalysis on d0, 1 and 2. d, BALB/c
mice were injected i.v. with 4 mg of IgG3 anti-TNP and s.c. with 1.4 mg of TNP-BSA
on days 0 and 1. Some mice were also injected with 0.625, 1.25, 2.5, or 5 mg of switch
variants of IgG1, IgG2a or IgG2b anti-TNP mAbs on d0 and 1. Urine protein was determined
on d0 (not shown), d1 (upper panel) and d2 (lower panel). Results are pooled from
a total of 7 experiments. Group size: IgG3 alone: 19 mice; 0.625 mg of IgG1, IgG2a,
or IgG2b: 4 mice; 1.25 mg of IgG1, IgG2a or IgG2b: 8 mice; 2.5 mg of IgG1, IgG2a or
IgG2b: 6 mice; 5 mg of IgG1, IgG2a or IgG2b: 8 or 9 mice. The significance of differences
between treatment groups was determined as described in the legend to Fig. 4f. # p<0.05
as compared to IgG2a plus IgG3. +p<0.05 as compared to IgG2b plus IgG3. *p<0.05 as
compared to IgG3 alone. e, Binding of the Ig isotype switch variants to ELISA wells
coated with TNP-BSA, reported as percentage of maximal binding. f, Binding of the
Ig isotype switch variants to ELISA wells coated with IgG3 anti-TNP mAb. g, Binding
of IgG3 and the Ig isotype switch variants to ELISA wells coated with themselves.
Extended Data Figure 8
GaMD-immunized γ1+/- mice generate large IgG3 responses but develop mild renal disease
BALB/c mice homozygous (γ1+/+), heterozygous (γ1+/-) and null (γ1-/-) for a functional
γ1 allele (6/gp) were injected s.c. with GaMD. a, Sera were titered for goat IgG-specific
IgG1, IgG2a and IgG3 0, 8 and 12 days later. Day 0 titers were zero for all Ig isotypes
(data not shown). b, Urine samples from the same mice were assayed for protein and
leukocyte esterase. ND = none detected.
Extended Data Figure 9
GaMD immune serum from WT mice inhibits GaMD-induced renal disease without decreasing
other isotypes if injected into GaMD-immunized γ1- mice by 5d after immunization
a. BALB/c γ1- mice (4 or 8/gp) were injected s.c. with GaMD on day 0 and i.p. with
0.5 ml of pooled serum from GaMD-immunized WT mice (GaMD immune WT serum) or unimmunized
WT mice (non-immune serum), starting 4, 5, or 6d after GaMD immunization. Day 7 urine
samples were analyzed. ND = none detected. b. BALB/c γ1- mice (4 or 8/gp) were injected
s.c. with GaMD on day 0 and i.p. with 0.5 ml of pooled serum from GaMD-immunized WT
mice (GaMD immune WT serum) or unimmunized WT mice (non-immune serum), 5, 6 and 7
d after GaMD immunization. Sera were assayed for total IgG1, IgG2a, IgM and IgG3 on
d0 (unimmunized) and 8d after GaMD immunization. ND = none detected.For both a and
b, * indicates p < 0.05; ** indicates p < 0.005 (both as compared to d6 only in a
and unimmunized in b.
Extended Data Figure 10
Antigen-specific IgG1 can prevent IgG3 immune complex glomerular deposition
BALB/c WT mice were injected i.v.with mouse IgG1 and/or IgG3 anti-TNP mAb with or
without s.c.injection of TNP-BSA on days 0 and 1. a. Kidneys were stained with PAS
on day 2. Representative micrographs from 3 mice/group are shown. b. Kidney serial
sections were stained with PAS or for IgG3 or IgG1 (brown pigment). Representative
micrographs from 4 mice/group are shown.