Science - USA (2019-02-15)

(Antfer) #1

result was further confirmed by a transcriptome-
wide analysis, where the Spearman correlations
between B2→B1 and B1 control samples were as
high as those between biological replicates and
significantly higher than those between B2→B1
and B2 control samples, closely clustering B1 and
B2→B1 samples together (Fig. 4B). Thus, the
B2→B1 conversion entails profound genetic alter-
ations, leading to a B1-typical transcriptome profile
in B2→B1 cells.
Taken together, mature B2 cells of the various
subsets exhibit plasticity toward B1 cell differen-
tiation. The cells undergo B1 differentiation upon
substitution of their BCR by an autoreactive BCR
that is known to drive B1 cell development in
early postnatal life. In both instances, differenti-
ation is initially linked toextensive cell prolifer-
ation, likely reflecting a special mode of B cell
activation by autoantigen ( 4 , 20 ). The present
experimental system offers a unique opportunity
to study this process, which is key to the un-
derstanding of BCR repertoire selection in the B1
compartment. In contrast, only low numbers of
B1 cells switching to the expression of the B2-
typical BCR were recovered from the animals,
with a surface phenotype intermediate between
B1 and B2. This is likely a consequence of the fact
that B1 cells represent B cells that have under-
gone antigen-driven activation, proliferation, and
differentiation. The profound genetic and mor-
phological changes that the cells undergo during
these processes may well be irreversible.
Jerne’s notion that autoreactive receptors ini-
tially drive lymphocyte development, with the
subsequent selection of escape somatic mutants,
was accommodated in the classical model of
B cell development through ordered V(D)J gene
rearrangements, in first the IgH and then the IgL


loci of progenitor B cells ( 1 , 31 , 32 ). In this model,
IgH chain–containing pre-BCRs constitutively
drive clonal expansion sustained by the surrogate
light chain, followed by sequential IgL chain gene
rearrangements and IgL chain editing. Although
these ordered gene rearrangements clearly dom-
inate postnatal B cell development, recent evi-
dence indicates that during fetal development,
very much in agreement with Jerne, IgH and IgL
chains are often initially coexpressed ( 33 ). In this
situation, autoreactive BCRs instead of pre-BCRs
drive the expansion and selection of B cells,
which at that developmental stage predominantly
develop into the B1 variety ( 11 , 34 ).
Although the control of these different path-
ways of differentiation remains to be fully eluci-
dated, the present results establish that mature
B2 cells are not irreversibly committed to a B2
“lineage”but maintain the potential to develop
into B1 cells. That these cells do so upon engraft-
ment of an autoreactive, B1 cell–typical BCR
demonstrates the instructive role of BCR speci-
ficity and mode of signaling in driving B1 cell
differentiation, in the absence of B1-lineage
precommitment.

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ACKNOWLEDGMENTS
We thank S. Clarke for reagents and the Vk4mice;J.diSanto
for providing the Rag2−/−Cg−/−mice; J. Wang, K. Jenssen,
V. Blinder, E. Derudder, T. Chakraborty, J. Xia, D. Ghitza,
C.Aristoff,A.Monti,A.Tetreault,J.Grundy,andA.Pellerin
for technical help in Boston; K. Petsch, C. Grosse, J. Pempe,
S. Mackowiak, and the MDC animal caretakers for their help;
and H. P. Rahn for excellent FACS-related support. We apologize

Grafet al.,Science 363 , 748–753 (2019) 15 February 2019 5of6


A

Neurl3
Dennd3Sox4

Csrp2
Emid1
Lrrk2
1300014i06rik
Gdf11
IcoslFcer2a

Fam101b
Zfp608
Ccr6
Cpm
Pstpip2
Myo1dPlscr1

Cd300lf
Gpr55
Csf2rb
Folr4
AhrTbc1d9

Bhlhe41
Zbtb32
Cyp11a1
Fam160a1
Lysmd2

−2 −1 0 1 2
Row Z−Score

02040

Color Key
and Histogram

Count
0.8 0.9 1
Correlation

024

6

8

Color Key
and Histogram

Count

B

B1-up signature
B2-up signature

B1 Ctrl B2→B1 B2 Ctrl B2 Ctrl B2→B1 B1 Ctrl

B1 Ctrl

B2


B1

B2 Ctrl

Fig. 4. B2→B1 cells acquire the transcriptome profile of B1 cells.
(A) Heat map with sample clustering of gene expression levels of 14 genes
specifically expressed in B1 cells (red) and 14 genes specifically expressed
in B2 cells (blue) previously defined as B1 signature ( 30 ). RNA was isolated
from splenic control B2 cells from B2 mice (B2 Ctrl), peritoneal 5C5+cells


from B1 mice (B1 Ctrl), and B2→B1 cells isolated from the peritoneal
cavity of recipients 30 days after transfer (B2→B1). (B) Heat map
of Spearman correlations between each sample, based on the expression
levels of 7629 expressed genes. Each B2→B1 sample is based on one
donor animal and was pooled from three or four recipients.

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