Supplementary figures, supplementary tables

Description of Supplementary Files File Name: Supplementary Information Description: Supplementary figures, supplementary tables

 

Supplementary Figure 1 a

Stomach

Liver

Lungs

Cre– Cre–

80 60 40 Cre 5

10

15

Cre

→

+

→ →

0

+

20

→

20

→

Survival (%)

100

b

Age (weeks)

CD8+ T cells Cre– Cre+

CD69

d

**

6100 4100

*

2100

** **

100 50

**

25 0 Il

1b

Il6

Events (% of max)

CD62L

mRNA (relative expression)

f CD44

e

Stomach 8100

mRNA (relative expression)

CD4+ T cells

mRNA (relative expression)

c

g Ifn

fa Tn

fb Tg

Liver 500

***

400

***

200 150 100

**

50 0 Il

1b

Il6

** fa Tn

If

ng

g

Lungs

600

*

500

bp 500

400 240

Cre–

Cre+

Cre+

Cre+

fb Tg

Transferred T cells (Cre+)

400 300

Tgfbr1 Deleted ‘Floxed’

120

0 Il1

b

Il6

fa Tn

g

Ifn

fb

Tg

Fig. S1: CD11c-Cre.Tgfbr1fl/fl Mice Develop a Lethal Systemic Inflammatory Disease (a) Survival of lymphocyte-sufficient CD11c-Cre.Tgfbr1fl/fl (Cre+) or Tgfbr1fl/fl (Cre–) mice with 5 (Cre+) or 6 (Cre–) mice/group and data are representative of 2 experiments. (b) H&E staining of stomach, liver and lungs from Cre– (upper panels) or Cre+ (lower panels) mice. Images are representative of at least 4 mice/group. Scale bars 500µm. (c) Expression of CD69, CD44 and CD62L by splenic CD4+ and CD8+ T cells from Cre– (dashed line) or Cre+ mice (solid line). Shaded histograms represent staining with appropriate isotype controls. (d-f) qRT-PCR analysis of IL1β, IL6, TNFα, IFNγ and TGFβ mRNA in stomach (d), liver (e) and lungs (f) of Cre– or Cre+ mice. (g) Genomic PCR for Tgfbr1 expression by splenic CD3+ T cells from intact lymphocyte-sufficient Cre– or Cre+ mice, or by donor CD3+ T cells purified from the recipients of Cre+ splenic T cells (‘Transferred T cells’). Flow cytometric analysis from one of two independent experiments with n=4-8/group.

Supplementary Figure 2 a

Gating strategy for identification of DC in small intestinal and colonic LP 25.1

FSC-H

FSC-A

b

7-AAD

20.1

CD11c

Assessment of CD103/CD11bdefined DC subsets and CD64+ Mφ (Figure 3a-d)

CD11c

55.4

SSC-A

94.1

SSC-A

79.8

FSC-A

SSC-A

60.4

CD45

CD64

MHCII

SI LP Live CD45+ CD11c+ MHCII+ CD64– Cre+

CD103

Tgfbr1+/fl Rag+/– 27.5 34.2

Tgfbr1fl/fl Rag+/– 33.5 16.7

25.8

31.7

CD11b Gating strategy for identification of DC in spleen (Figure 3e)

d

FSC-H

7-AAD/Ly6G

Assessment of CD11b-defined subsets (Figure 3e)

CD11c

SSC-A

93.8

SSC-A

FSC-A

SSC-A

45.1 FSC-A

8.04

96.7

70.2

MHCII

CD45

Gating strategy for identification of DC in small intestinal LP of mixed BM chimeric mice (Figure 4b & c) 24.9

FSC-A

FSC-H

7-AAD

48.3

‘NOT’ gate

Assessment of contribution of CD45.2 (Tgfbr1fl/fl) BM to each subset (Figure 4b)

CD11c

CD45.1+ (WT)

94.4

SSC-A

78

FSC-A

SSC-A

49.4

CD103

c

MHCII

CD45.2+ (Tgfbr1fl/fl)

CD11b

CD45.1 (WT) +

CD11c

CD64

e

Assessment of CD103/CD11bdefined subsets (Figure 4c)

CD45.2+ (Tgfbr1fl/fl) Gating strategy for identification of migratory DC in mesenteric lymph node (MLN) of mixed BM chimeric mice

2.5

FSC-A

MHCII

CD45.1+ (WT)

45.4 15.1

CD11c

93.8

FSC-H

CD3/CD19/7AAD

56.4

FSC-A

FSC-A

SSC-A

3.43

Assessment of CD103/CD11bdefined subsets (Figure 4d) 50.1

CD45.2+ (Tgfbr1fl/fl)

Fig. S2: Gating strategies used throughout study (a) Gating strategy to identify DC and macrophages in the small intestine and colonic lamina propria in Figure 3 and Figure 6. (b) Representative expression of CD103 and CD11b by DC subsets from the small intestine of CD11c-Cre.Tgfbr1+/fl Rag1+/– or CD11c-Cre.Tgfbr1fl/fl Rag1+/– mice. Plots are from one experiment of two independent experiments performed with 3 mice per group. (c) Gating strategy to identify DC in the spleen in Figure 3. (d) Gating strategy to identify DC subsets in the small intestinal lamina propria of mixed BM chimeric mice in Figure 4. (e) Gating strategy to identify DC subsets in the mesenteric lymph node (MLN) of mixed BM chimeric mice in Figure 4.

Supplementary Figure 3 b

Small Intestinal mononuclear phagocytes - CD11c-Cre.Rosa26-LSL-eYFP mice

40 20

80

20

60 40 20

D

II +

CD19+ MHCII + B cells CD3+ MHCII – T cells Total CD45+ leukocytes

80 60 40 20 0102 103 104 105 CD11c

C

C

D

C

10

100

0 II –

010 10 10 10 CD11c

0

5

C

4

H

3

H

2

19

3+ C D D 11 10 b– 3+ C C D D 11 10 b+ 3– F4 C D /8 11 0+ b+ M H C II + M φ

0

C

20

0

Events (% of max)

40

eYFP+ (%)

60

80

3+ M

20

100

CD103+ CD11b – CD103+ CD11b + DC CD103 – CD11b+ Subset F4/80+ MHCII+ Mφ Total CD45+ leukocytes

80

0102 103 104 105 eYFP

M

40

100

13.2

40

+

60

35.3

60

0

Events (% of max)

80

eYFP+ (%)

100

0102 103 104 105 YFP eYFP

100

CD3+ MHCII –

CD19+ MHCII +

82.5

60

0

Small Intestinal lymphocytes - CD11c-Cre.Rosa26-LSL-eYFP mice

F4/80+ MHCII+ Mφ

83.2

95.3

95.9

80

CD103 – CD11b+

D

Events (% of max)

100

CD103+ CD11b +

Events (% ( of max))

CD103+ CD11b –

C

a

DC Subset

Blood leukocytes - CD11c-Cre.Rosa26-LSL-eYFP mice Ly6Clo monocytes

CD19+ MHCII + B cells

CD3+ MHCII – T cells

100

80 0.55

60

0.39

66.4

5.62

6.67

40

60 40 20

20 0

80

0102 103 104 105

Ly6Cint CD11b+ neutrophils Ly6Chi monocytes Ly6Clo monocytes CD19+ MHCII + B cells CD3+ MHCII – T cells

100 80 60 40 20 0

0102 103 104 105 CD11c

Ly 6

eYFP

0

Events e ts (% of o max) a )

Ly6Chi monocytes

eYFP+ (%)

Events (% ( of max))

CD11b+ Ly6Cint SSChi neutrophils 100

C in St S Ch i Ly neu 6C tro hi p Ly mo hils 6 C no cy lo C D 1 9 mo tes + no M H cyte C C D II + s 3+ B M ce H C II – lls T ce lls

c

Fig. S3: Efficiency of CD11c-Driven Cre Recombinase Activity (a) Representative expression of eYFP by DC subsets and F4/80+MHCII+ macrophages from the small intestine of CD11c-Cre.Rosa26-LSL-eYFP mice or CD11c-Cre mice (shaded histograms). Scatter plots show the frequency of eYFP+ cells in each subset. Each symbol represents an individual animal and the horizontal bar represents the mean of n=7 mice from a single experiment. The lower histogram shows CD11c expression by DC subsets, F4/80+MHCII+ macrophages and total CD45+ leukocytes from the small intestine of 6 week old CD11c-Cre.Rosa26-LSL-eYFP mice. (b) Representative expression of eYFP by CD19+ MHCII+ B cells and CD3+ MHCII– T cells from the small intestine of CD11cCre.Rosa26-LSL-eYFP mice or CD11c-Cre mice (shaded histograms). Scatter plots show the frequency of eYFP+ cells in each lymphocyte subset. Each symbol represents an individual animal and the horizontal bar represents the mean n=7 mice from a single experiment. The lower histogram shows CD11c expression by CD19+ MHCII+ B cells, CD3+ MHCII– T cells and total CD45+ leukocytes from the small intestine of CD11c-Cre.Rosa26-LSL-eYFP mice. (c) Representative expression of eYFP by neutrophils, classical Ly6Chi monocytes, non-classical Ly6Clo monocytes, CD19+ MHCII+ B cells and CD3+ MHCII– T cells from the blood of CD11c-Cre.Rosa26-LSL-eYFP mice or CD11c-Cre mice (shaded histograms). Scatter plots show the frequency of eYFP+ cells in each leukocyte subset. Each symbol represents an individual animal and the horizontal bar represents the mean n=7 mice from a single experiment. The histogram (right) shows CD11c expression by each blood leukocyte subset from blood of CD11c-Cre.Rosa26-LSL-eYFP mice.

Supplementary Figure 4 Events (% of max)

a

b

100

c

F4/80+ MHCII+ M CD103+ CD11b– CD103+ CD11b+ CD103– CD11b+

80 60 40 20 0

0102 103 104 105 SiglecF

EpCAM

Gp2

Fig. S4: Assessment of markers identified by microarray analysis at protein level Representative expression of SiglecF (a), EpCAM (b) and GP2 (c) by CD103/CD11b-defined DC subsets and by F4/80+MHCII+ macrophages from the small intestinal LP of unmanipulated WT mice. Data are from a single experiment.

c

r

ey

ve

ng

dn Ki

Li

on

Lu

ol C

e

en le

tin nt lI al Sm

TREM1+ of CD103+ CD11b– DC (%)

r

ey

ve

dn

Li

Ki

ng Lu

on ol

lI

C

le

e tin es nt

en

0 Sp

r

20

al Sm

60 40 20

r

ey dn

Ki

ng

ve Li

Lu

ol C

es

CD101

on

0

2.43

en

97.5

0.0293

e

3.47 7

40

80 CD103– CD11b– 0.0293

tin

1.7 7 96.2

0.201 1

le

0 0.101

60

Sm

al

lI

CD11b

98.3

3.73

CD103– CD11b+

nt

CD103

TREM1

0

96.1

80

ey

Sm 0.319 9

CD103+ CD11b–

CD101+ TREM1+ of CD11b+ DC (%)

99.7

0

dn

al

‘Resident’ DC CD11c+ MHCIIhi

20

Ki

ng

ve Li

Lu

on ol C

le

lI

nt

en

0

0

e

CD103– CD11b+

0.182

20

tin

0

40

es

CD103+ CD11b–

60

Sp

0

‘Migratory’ DC CD11c+ MHCIIhi

r

lI al

Inguinal LN

80

Sp

b

40

ey

35.4

60

dn

54.7

CD101

80

Ki

21

Sm CD11b

TREM1+ of CD11b+ DC (%)

TREM1

CD103

‘Migratory’ DC CD11c+ MHCIIhi

ng

3.58

4.72

ve

1.89 9

5.51

Li

96.6

74.7 7

on

0.767

ol

1.13 3

nt

0.567

0

CD103– CD11b+

Lu

CD103+ CD11b+

20

C

18.5

e

CD103+ CD11b–

81.7

40

en

0.926

60

tin

99.1

CD101+ of CD103+ CD11b– DC (%)

80

‘Resident’ DC CD11c+ MHCIIhi

Sp

0

es

CD103– CD11b+ 0.381

le

0

es

CD103+ CD11b–

Sp

0

CD101+ of CD11b+ DC (%)

Supplementary Figure 5 a Mesenteric LN

Fig. S5: Expression of CD101 and TREM1 by lymphoid and non-lymphoid DC subsets (a-b) Representative expression of CD103 and CD11b by ‘resident’ (CD11c+ MHCII+) and ‘migratory’ (CD11c+MHCIIhi) DC in the mesenteric (a) or inguinal (b) lymph nodes (left panels), and representative expression of CD101 and TREM1 by CD103- and CD11b-defined DC subsets (right panels). (c) Scatter plots show the frequency of CD101+, TREM1+ or CD101+TREM1+ DC in the tissues indicated. Each symbol represents an individual animal and the horizontal bar represents the mean of 4 mice from one of two representative experiments performed.

Table S1: Genes unique to SILP CD103+CD11b– DC Subset Clec9a Xcr1 A530099J19Rik Gpr33 5430435G22Rik Ctla2b Ffar4 Irf8 Tlr12 Ifi205 Cadm1 Tlr3 Ppap2a Cxcr3 Cd8a Snx22 P2ry14 Cd36 Agpat3 F630111L10Rik Cd81 Lif Btla Dapk2 Ttc39a Leprel1 Fnip2 Slc7a8 Met Ppt1 Naaa Cpq Mospd1 Plce1 Pi4k2a Il12b E330020D12Rik Cyp26b1 Zdhhc2

Tmem27 Slc8b1 Alms1 Casp6 Fgd6 Gnb4 Tlr11 Fndc7 Pbx1 Dbn1 Clec12a Trpm2 Pdia5 Arhgap42 Cxcl9 Arhgef9 Stk39 Itm2a Ppef2 Itga1 Ptger2 Ccr9 Mras Dusp10 Enpp4 Fam149a Mpeg1 Phyh Rab32 Itga8 Acvrl1 Cd200 Erc1 Gkap1 BC028528 Igf2r B3gnt5 Mycl Slc25a24

Clec1a Pdlim7 Ptgis Fbxo4 Itga3 Sdc3 Arrb1 Pttg1ip Nek6 Gcsam Dnase1l3 Gprc5c Cyfip2 Gatm Lrrc1 Pstpip2 Serpinb8 Adam8 Ubash3b Fzd1 Cldn1 Cpne3 Klf2 Cdc14a Hmgn3 Arap1 4930486L24Rik Mpzl2 Cpd Fbxw17 Cxx1c Oasl1 Camk1d Fmnl2 Enpp5 Clnk Ly75 Slc25a26 Plcb4

Sgcb Myo9a Gng12 Bcl2l14 Txndc15 Mllt3 Esyt3 Extl3 Sgk1 A630072M18Rik Cttnbp2nl Procr Naga Cdk14 Laptm4b Il15 Pfkfb1 Tap1 Tspan33 Hps4 2610034B18Rik Dhrs9 Slc9a9 Pde1b Tubb2b Adrb2 Stt3b Chst11 Slc33a1 Gna15 2410016O06Rik Tcf7l2 Gusb Gm1965 Galc Tubb2a Impa2 Tmem86a Cyb5a

Slco3a1 Nab2 Glce Rab39 Olfr433 Arsb Nup93 Trim35 Galnt7 Hk3 Sept3 Ndrg1 Gm6226 Rcn2 Osbpl3 Rala Sdad1 Acadl Slc31a2 Rhobtb1 Crim1 Psen2 Dpy19l3 Pqlc2 Plin2 Ubfd1 Nck2 Asap2 Fndc9 Mctp1 Aagab Agpat5 6820445E23Rik Ccndbp1 Ppp1r11 Zfp366 Sipa1l1 Trim30a Coro7

Lima1

Sgms1

Ldoc1l

Ankrd12

St3gal5

Map2k6 Lap3 Ece1 Arhgap21 Pdlim4 Rab43 Rab13 Cdon Bcl9 Lrrcc1 Nampt Pygo2 Pus3 Rab11a Klra5 Tmtc3 Mgat4b Gdpd5 Ptplb Ipcef1 Adam19 Gpr157 Apol7c Dnmbp Fam168a Ptpn18 Gabbr1 Myo6 Fmo5 Mospd2 Slc9a3r2 Rasgrp3 Zc3h12c Sult1a1 Id2 Gm11545 Zfp57 Qpct Actn1

Table S2: Genes shared by SILP CD103+CD11b+ and CD103–CD11b+ DC Subsets Dhrs3 Apba1 Il13ra1 Hfe Arrb2 Tmcc3 Ncf1 Mreg Ccdc88c Rnf149 Stap1 Isg20 Fmnl3 Cebpa Cyp4f16 LOC637260 Micu1 Cd164 Ldlr Mxd1 Fhl3 Ms4a6c Tmem106a Pde2a Smpdl3b Por Casp1 Gm14455 Cxcr4 Nrros Ctsz Napsa Dusp7 Igkv3-9 Il1rl2 Stk17b Adora2b Spib Crtc3 Trappc5 Sulf2 Abi3 Ifi27l2a Rbpms Dhx40 Krt80 Lta4h Gngt2 Zc3hav1 Mvb12b Smad7

Tcn2 Arl4c Neurl3 Gm23100 Pcyt1a Rgs12 Il21r Bin1 Stard9 Chn2 Ssh2 Plcxd2 Plxnc1 Ly86 Dusp22 Zcwpw1 Dock4 Csf2rb Ifi27 Cdkn1a Prkch Sidt2 Elmsan1 Panx1 Map4k3 Gpr183 Lgals8 Hrh1 Ripk2 Irak2 Tpp1 Plxnd1 Tfrc Pla2g4a Rab20 Pirb Hcar2 Nfkbid Cers6 Smox AF251705 Ctsa Lpp Tctex1d2 Cd14 Pilrb1 Casp4 St6gal1 Pvt1 Ptger4 Vopp1

Pvr Lrrc16a Rasgrp2 G6pdx Chd7 Tnfrsf18 Arl5c Fam49a Capg Rgs1 Ltb4r1 Acsl1 Etos1 1700064E03Rik Ppp1r3b Stambpl1 Ank Syk Bach1 Pou2f2 Ntpcr Slc2a6 Rasal3 I730030J21Rik Arhgap39 Slc16a3 Emilin2 Fyb Lst1 Ggta1 Tnfrsf1b Tbx21 Zeb2os Lgals9 App Ddx26b Pla2g7 Ccnd2 Igsf6 Dgat1 Mycbp2 Zfp719 Ctsc Nedd9 Klrd1 Cfp Ddr1 Gapt Mmd Nr4a3 Tlr2

Zfp667 Gp49a Trps1 Il18 Abcb1a Klk8 Tyrobp E230008N13Rik Siglecg Ifitm6 Lilrb4 Tnip3 Atp13a3 Gch1 S100a10 Cass4 Ndst1 Trp53i11 AW112010 Ddx58 Zeb2 Slc2a3 Oasl2 Cyp4f18 Cd300ld Nfkbiz A530064D06Rik Ggt5 Acp5 Gadd45b Gm9733 I830077J02Rik Gm5150 Arap2 Gm1966 Ncf2 Cd274 Wls Lifr Ifitm1 Samsn1 Rin2 Ifitm2 B430306N03Rik Fcgr3 St18 Bhlhe40 Ifit3 Mgat4a Plk2 Dennd3

Sorl1 Ehf Oas1a Ston2 Tnfsf8 Kcne3 Stk38l Spns3 Ffar2 Atrnl1 Hilpda Fam46a Fosl2 Abcg3 Rgl1 Sema7a Ms4a6d Gpr141 Nod1 Frrs1 Malt1 Fgfr1 Gbp3 Fabp5l2 Gbp4 Ramp3 Art2a-ps Clec4g Lair1 Gcnt2 Arhgef3 Milr1 Nlrp3 Rtp4 Pecam1 Emr1 Mefv Pilrb2 F11r 1300002K09Rik Il1b Prdm1 Cd300lf Plaur Plau Clec7a Gbp8 Mcemp1 Hpgd Il1a Lphn3

Cd69 Clec10a Ccrl2 Fgr Cd72 Clec4b1 Mmp12 Clec4a1 Ctnnd2 Pygl Tgm2 Irf4 B4galt6 Stat4 Slc15a3 Cd300a Clec4n Clec4a2 Cd209b Ptgs2 Sh2d1b1 Cd7 Clec4a4 Emb Fcer1g Cd209c Atp1a3 Pltp Pilra Il1r2 Cybb Trem1 Sirpa Ccr1 Cd33 Mgl2 Siglece Itgam 1810011H11Rik Cd209a Cd101 Wfdc17 Ccl3 Serpinb10 Dnajb4 Tlr1 Oas2 Ltb Lat2 Hivep2 Nxpe5

Neurl2

Trem3

Ggh

Ms4a6b

Gbp7

Bcl3

Igkv4-57

Lpcat2

Ier2

Arid5a

Maml3

Ddx60

Il7r

Dusp3

Rsad2

Bcl11a

Coro2a

Elk3

Gm8995

Slc44a2

St7

Eif4e3

Runx3

Lamp1

Table S3: Genes unique to the SILP CD103–CD11b+ DC Subset mem176b Tnfsf9 Tmem176a Apobec1 Csf1r C1qb C1qc S100a4 C1qa Dab2 Klra17 Pla2g2d S100a6 Ccl6 Ptafr Plxdc2 Osm Ms4a4c Il22ra2 Emr4 Apoe Klra2 Mrc1 Emp3 Clec4a3 Mafb Fcgr2b Csf3r Abca9 Socs3

Il17ra Lilra6 Msr1 Ccl9 Il1rn Nccrp1 Abcb1b St8sia6 Plxnb2 Slamf9 Ccl4 Cx3cr1 Mmp9 C3ar1 Alox5 Mef2c Prkce Dram1 Lpar1 BC005685 Rasgrp1 St8sia1 Anxa3 Rasgef1b Clec5a Cd93 Rassf4 Cercam Spn Foxred2

Mzb1

Table S4: Genes unique to the SILP CD103+CD11b+ DC Subset Impact Slc27a2 Gcnt1 Pglyrp1 Epcam Slc16a6 Rilpl1 Abhd14b Mylk 2900026A02Rik Rell1 Sash1 D330045A20Rik Cwc25 Plk3 Slc52a3

Ppp1r14a Rasgrf2 Card9 Pgf Ppp1r1a Mospd4 Tnfaip2 Mtss1 Trim25 Siglec5 Fam189a2 Cdh1 Cpm Plet1 Gp2

Table S5: Genes shared by SILP CD103+CD11b+ and CD103–CD11b+ DC subsets and highly significantly differentially expressed compared with CD103+CD11b– DC.

Gene

Surface marker

Plaur Mcemp1 Clec10a Clec4a1 Tgm2 Irf4 B4galt6 Stat4 Slc15a3 Cd300a Clec4n Clec4a2 Ptgs2 Sh2d1b1 Cd7 Clec4a4 Emb Fcer1g Cd209c Atp1a3 Pltp Pilra Il1r2 Cybb Trem1 Sirpa Ccr1 Cd33 Mgl2 Siglece Itgam 1810011H11Rik Cd209a Cd101

x x x

Wfdc17

x x x

FACS Antibody

x

x x x

x x

x x

x x

x x x

x x x

x x

x x

Table S6: Antibodies used for Flow Cytometry Antibody

Clone

Source

Dilution

CD3e

145-2c11

Biolegend

1:200

CD4

RM4-5

Biolegend

1:200

CD11b

M1/70

Biolegend

1:200

CD11c

N418

Biolegend

1:200

CD44

IM7

Biolegend

1:200

CD45

30-F11

Biolegend

1:200

CD45.1

A20

Biolegend

1:200

CD45.2

104

Biolegend

1:200

CD62L

MEL-14

Biolegend

1:200

CD64

X54-5/7.1

Biolegend

1:200

CD69

H1.2F3

Biolegend

1:200

CD101

Moushi101

eBioscience

1:200

CD103

2E7

Biolegend

1:200

EpCAM

G8.8

Biolegend

1:200

FoxP3

FJK16s

eBioscience

1:200

GP2

D278-A48

MBL

1:200

IA-IE

M5/114.15.2

Biolegend

1:400

IFNγ

XMG1.2

BD Bioscience

1:200

IL17A

TC11-18H10.1

Biolegend

1:200

Ly6C

HK1.4

Biolegend

1:200

SiglecF

E50-2440

BD Bioscience

1:200

TREM1

TR3MBL1

eBioscience

1:200

Vα2

B20.1

Biolegend

1:200

Fc Block

2.4G2

Biolegend

1:200

Table S7: Primers used for Genomic PCR Gene

Primer sequences

Product size (in Kb)

Tgfbr1

5’- ACCCTCTCACTCTTCCTGAGT- 3’ 5’- ATGAGTTATTAGAAGTTGTTT- 3’ 5’- GGAACTGGGAAAGGAGATAAC- 3’

WT = 150 Flox = 250 Del = 350

Cre

5’- CCGGTCGATGCAACGAGTGA- 3’ 5’- GGCCCAAATGTTGCTGGATA- 3’

WT = absent Cre = 235

Rag1

5’ – TGGATGTGGAATGTGTGCGAG- 3’ 5’ – GAGGTTCCGCTACGACTCTG- 3’ 5’ – CCGGACAAGTTTTTCATCGT- 3’

WT = 474 Del = 520

Table S8: Primers used for RT-qPCR

 

Gene

Forward primer sequence

Reverse primer sequence

Il6

TCTAATTCATATCTTCAACCAAGAGG

TGGTCCTTAGCCACTCCTTC

Il1b

TGTAATGAAAGACGGCACACC

TCTTCTTTGGGTATTGCTTGG

Tnfa

CCACGTCGTAGCAAACCAC

TTTGAGATCCATGCCGTTG

Ifng

ATCTGGAGGAACTGGCAAAA

TTCAAGACTTCAAAGAGTCTGAGGTA

Il17a

TTTTCAGCAAGGAATGTGGA

TTCATTGTGGAGGGCAGAC

Nos2

GGGCTGTCACGGAGATCA

CCATGATGGTCACATTCTGC

Ccl5

TGCAGAGGACTCTGAGACAGC

GAGTGGTGTCCGAGCCATA

Gzmb

GCTGCTCACTGTGAAGGAAGT

TGGGGAATGCATTTTACCAT