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CUTTING EDGE |
Department of Immunology, Genetics Institute, Cambridge, MA 02081
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Abstract |
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 Top Abstract IntroductionMaterials and MethodsResults and DiscussionReferences |
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Introduction |
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TopAbstractIntroductionMaterials and MethodsResults and DiscussionReferences |
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A recent innovation in the isolation of cDNA encoding secreted proteins has been developed (3) permitting cDNAs encoding signal peptides to be selected and used as a probe for isolation of the full length cDNA sequence. Using lymph nodes from IL-12-treated tumor-bearing mice as a source of cDNA, a library of signal trapped clones were obtained, of which one B7-like clone was found to be ICOS ligand.
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Materials and Methods |
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TopAbstractIntroductionMaterials and MethodsResults and DiscussionReferences |
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Mice (C57BL/6) injected with MB49 bladder carcinoma cells were treated with 1 µg/mouse recombinant IL-12 on days 7–11 and 14–18. Day 9, 12, and 19 lymph nodes were pooled. Wild-type spleen, yolk sac, and fetal liver were isolated from timed pregnant Swiss Webster mice. Splenic tissues were also isolated from Rag-/- mice. Human PBL were isolated by Ficoll-Paque density centrifugation of human leukopac samples.
Nucleic acid manipulation
RNA was extracted using RNAStat 60 total RNA isolation reagent (Tel-Test B, Friendswood, TX). cDNAs were synthesized with Superscript RT enzyme (Life Technologies, Rockville, MD) in 20-µl reactions. Additional cDNA sources include a previously described C3H/Hej fetal thymus library (4). 3' Rapid amplification of cDNA end (RACE)2 was performed with 5 µg of total RNA according to the method of Frohman (5). Signal sequence trap was performed (3) followed by Rec A isolation of cDNAs based on a method by Rigas et al. (6). Full-length PCR isolation of human GL50 (hGL50; GenBank accession no. AF199028) was accomplished by using the oligonucleotide primers 5'-GGCCCGAGGT CTCCGCCCGC ACCATG-3' and 5'-TCACGAGAGC AGAAGGAGCA GGTTCC-3' according to previously described conditions (7).
Sequence analysis
TBlastX, FastX, pFam, Pileup, and Sigcleave of Genetics Computer Group (Madison, WI) package and Geneworks 2.5.1 were used for DNA sequence manipulation, database searching and sequence analysis. Identity scores for pileup analysis were assigned according to the following values: 1 = 1x pair; 2 = 2x pair; 3 = 3x pair; 4 = 3 of a kind; 5 = 3 of a kind plus 1x pair; 6 = 2x 3 of a kind; 7 = 4 of a kind; 8 = 4 of a kind plus 1x pair; 9 = 5 of a kind.
Gene expression analysis
For analysis of commercially prepared RNA blots (Clontech, Palo Alto CA), DNA fragments encompassing nucleotides 1065–1588 of mouse GL50 (mGL50; GenBank accession no. AF199027) (494 bp) or nucleotides 84–782 of hGL50 (699 bp) were radiolabeled and hybridized to filter membranes according to the manufacturer’s protocol. Northern analysis of 5 µg of total RNA from developmentally regulated tissues was performed using the NorthernMax-Plus kit (Ambion, Austin, TX).
Cell preparation and culture
Cell suspensions were isolated from BALB/c mice (
3 mo old).
RBC were lysed, and washed splenocytes (1 x
107 cells/ml/well) from BALB/c mice were cultured
with 25 µg/ml LPS (Sigma), while splenocytes from Swiss Webster mice
were cultured with 10 ng/ml PMA and 1 µg/ml ionomycin.
Flow cytometry
The mICOS-mIgG2am protein was made at the Genetics Institute consisting of human oncostatin M leader, predicted extracellular domain of mICOS sequence, and IgG2a hinge-carboxyl tail with mutations introduced to lower Fc binding (8). For analysis of surface proteins, COS cells were transfected using lipofectamine (Life Technologies) with mGL50 in pcDEF3 (9) or kit ligand/membrane (KLM) from cDNA in pED expression vectors. Cells were blocked with PBS supplemented with 10% rabbit serum and then were stained with 0.5 µg of fusion protein in 100 µl of PBS supplemented with 2% FCS. Secondary staining was performed with PE-linked goat anti-mouse IgG. All Ab reagents were purchased from PharMingen (San Diego, CA). Splenocytes were incubated in 20 µg/ml Fc block, 10% rabbit serum, and incubated with either mICOS-mIgG2a or murine IgG2a control followed by secondary staining with biotinylated anti-mouse IgG2a and FITC-conjugated mAb as indicated. Cells were analyzed by flow cytometry using a FACScalibur and CellQuest software (Becton Dickinson, San Jose, CA).
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Results and Discussion |
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TopAbstractIntroductionMaterials and MethodsResults and DiscussionReferences |
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). The hydropathy plot of the
open reading frame predicted a leader sequence, an extracellular
domain, hydrophobic transmembrane region, and potential intracellular
cytoplasmic domain. Pfam structural analysis revealed an IgV-like
domain and an IgC-like domain based on domain delineation of B7-1 and
B7-2 (10). Comparison of mGL50 revealed identity to the
recently published mouse costimulatory molecule, B7h
(11).
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3' RACE analysis of human PBL with oligonucleotides primers
corresponding to extracellular domains of AB014553 resulted in four
RACE products that encoded a cDNA divergent from the AB014553 cDNA
sequence and that resulted in a truncated 3' coding region encoding 9
aa, a termination codon, and a short untranslated domain. By RT-PCR of
leukocyte RNA using primers specific for the full-length coding
sequence predicted by RACE, an amplified product (hGL50) was isolated
encoding a 309-aa protein that shared 42% sequence identity with mGL50
(Fig. 1
), predicting this sequence to be the human ortholog of mGL50.
Sequence identity levels in the 40% range are also found in
orthologous sequence comparisons between mouse and human B7-1 (41%)
and mouse and human B7-2 (48%), whereas paralog sequence comparison of
GL50, B7-1, and B7-2 demonstrate homology levels at 20%
identity.
Northern blot analysis using probes specific to 3' untranslated regions
of mGL50 revealed hybridization to a 2.7-kb message in brain, lung,
liver, skeletal muscle, and testis with dominant expression in spleen,
heart, and kidney samples (Fig. 2A). Northern analysis was
performed on 5 µg total RNA extracted from either day 11.5 yolk sac,
day 14.5 fetal liver, Rag-2-/- spleen,
activated splenocytes, and WEHI 231 (7). With the
exception of WEHI 231 samples, 2.7-kb hybridization signals were
detected clearly in all samples with the highest levels of signal in
activated splenocytes (Fig. 2B). Phosphoimage quantitation
revealed the 2.7-kb hybridization signal to be 2-fold greater in
activated splenocytes than whole spleen samples.
Rag-2-/- mouse splenocytes, genetically devoid
of mature B and T cells, also exhibited levels of transcripts
commensurate to wild-type splenocytes, suggesting the presence of mGL50
on cells other than mature B and T cells.
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Northern hybridizations of human multiple tissue panels indicated the
presence of a number of transcripts found in all tissues with
approximate molecular sizes of 2.4, 3.0, and 7.0 kb, with the highest
levels of signal present in brain, heart, kidney, and liver samples,
while low hybridization signals were detected in colon and thymus.
Additional transcripts of 8.5 and 3.8 kb in certain samples were also
detected (Fig. 2C). A unique 1.1-kb transcript detected only
in PBL samples corresponded to the predicted size of hGL50. None of the
obvious transcripts correlate with the 4.3-kb published AB014553 cDNA,
and, in addition, no PCR products were obtained from any cDNA source
when amplified using primers specific to the sequences of
hGL50/AB014553 and the 3' sequences of AB014553 not shared with hGL50
(data not shown).
To determine the extent of relatedness between mGL50, hGL50, and human
and mouse B7-1 and B7-2, protein sequence alignments were performed.
From Pileup analysis (Fig. 1), 18 aa locations aligned identically
between all six molecules within the extracellular domain. Of the 32
positions that define the predicted IgV-like and IgC-like folds of the
B7 molecule, 13 are identically conserved between all six molecules,
including the four cysteines that allow intramolecular folding of
domains. The identities of mGL50 and hGL50 sequences in some locations
aligned more closely with B7-1 (e.g., mGL50 Y87) and in other locations
more similarly with B7-2 (e.g., mGL50 V86). Of the 16 positions in GL50
with identity scores of 8, five positions were shared by B7-1, four
positions were shared by B7-2, and six positions are shared between
B7-1 and B7-2. Five locations in the GL50 sequences exhibited complete
identity with B7 residues critical for CTLA4/CD28 binding
(10), while six sites exhibited similarity with respect to
conservative amino acid substitutions. These results suggest that the
GL50 sequences occupies a phylogenetic space nearly parallel to the B7
family of proteins.
To date, three receptors of the CD28 family of proteins have been
reported to share similar structure: CTLA4, CD28, and ICOS
(2). Flow cytometric assays were performed to determine
whether GL50 proteins were able to bind to either CTLA4, CD28, or ICOS.
COS cells transiently expressing mGL50 were stained with either
mICOS-mIgG2am, mCD28-IgG2am, or mCTLA4-Ig2am fusion proteins (7),
resulting in detection of binding by mICOS-mIg2am (20%) fusion
protein, but not by either mCD28-mIg2am or mCTLA4-Ig2am fusion proteins
(Fig. 3), although we cannot rule out the
possibility of very-low-affinity binding and signaling of mGL50 through
CD28 or CTLA-4 (14). No binding of any fusion protein was
detected for the control KLM cDNA transfectants, suggesting that mGL50
is a ligand specific for mICOS-Ig2am.
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). CD19+ B cell
populations were highly positive for mICOS-mIgG2am staining (84%),
consistent with RNA expression data for mGL50 (11).
Initial immunohistochemical characterization of ICOS expression using
the anti-ICOS Ab F44 revealed anti-ICOS reactivity in the
apical regions of germinal center light zones, an area linked to B cell
maturation into terminal plasma or memory cells (2). Flow
cytometric analysis suggested that germinal T cells express ICOS late
in activation and would bind to a B7-like protein on B cells.
Consistent with these observations, we demonstrated high levels of
surface expression of ICOS ligand on freshly isolated
CD19+ splenocytes, suggesting that mGL50 is
constitutively expressed on splenic B cells.
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Low to negligible staining was observed on cells expressing markers for macrophage, activated lymphoid cell, granulocyte, or NK cell lineages. It should be noted that the presence of 21% of CD19-, ICOS ligand+ cells cannot be accounted for by the CD3+, ICOS ligand+ T cell component of ICOS-Ig staining, suggesting additional subpopulations of lymphoid cells display surface expression of ICOS ligand.
Our data indicate that GL50, like CD40, is constitutively expressed on B cells, suggesting that production of Th2 cytokines such as IL-4 and IL-10 (2) could be regulated by the induction of ICOS on germinal center T cells. Swallow et al. (11) also found that B7h (mGL50) expression is induced in fibroblasts and nonlymphoid tissues by TNF, suggesting that the ICOS-GL50/B7h interaction may play a unique role in inflammatory sites. Thus, there may be two scenarios by which GL50/B7h signals are transduced: one in which costimulation dependent T cell ICOS interacts with constituitively expressed GL50/B7h on B and other lymphoid cells, and a second that is dependent upon TNF induction of nonlymphoid cells.
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Footnotes |
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2 Abbreviations used in this paper: RACE, rapid amplification of cDNA end; hGL50, human GL50; mGL50, mouse GL50; KLM, kit ligand/membrane.
Received for publication October 20, 1999. Accepted for publication December 13, 1999.
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References |
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TopAbstractIntroductionMaterials and MethodsResults and DiscussionReferences |
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2: molecular cloning, characterization, and comparison with murine IL-13 receptor 1. J. Immunol. 161:2317.. Immunity 11:423.[Medline]
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A. G. Tesciuba, S. Subudhi, R. P. Rother, S. J. Faas, A. M. Frantz, D. Elliot, J. Weinstock, L. A. Matis, J. A. Bluestone, and A. I. Sperling Inducible Costimulator Regulates Th2-Mediated Inflammation, but Not Th2 Differentiation, in a Model of Allergic Airway Disease J. Immunol., August 15, 2001; 167(4): 1996 - 2003. [Abstract] [Full Text] [PDF]
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J. J. Wallin, L. Liang, A. Bakardjiev, and W. C. Sha Enhancement of CD8+ T Cell Responses by ICOS/B7h Costimulation J. Immunol., July 1, 2001; 167(1): 132 - 139. [Abstract] [Full Text] [PDF]
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V. Ling, P. W. Wu, J. S. Miyashiro, S. Marusic, H. F. Finnerty, and M. Collins Differential Expression of Inducible Costimulator-Ligand Splice Variants: Lymphoid Regulation of Mouse GL50-B and Human GL50 Molecules J. Immunol., June 15, 2001; 166(12): 7300 - 7308. [Abstract] [Full Text] [PDF]
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J. Guo, M. Stolina, J. V. Bready, S. Yin, T. Horan, S. K. Yoshinaga, and G. Senaldi Stimulatory Effects of B7-Related Protein-1 on Cellular and Humoral Immune Responses in Mice J. Immunol., May 1, 2001; 166(9): 5578 - 5584. [Abstract] [Full Text] [PDF]
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J. L. Riley, P. J. Blair, J. T. Musser, R. Abe, K. Tezuka, T. Tsuji, and C. H. June ICOS Costimulation Requires IL-2 and Can Be Prevented by CTLA-4 Engagement J. Immunol., April 15, 2001; 166(8): 4943 - 4948. [Abstract] [Full Text] [PDF]
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H. Tamura, H. Dong, G. Zhu, G. L. Sica, D. B. Flies, K. Tamada, and L. Chen B7-H1 costimulation preferentially enhances CD28-independent T-helper cell function Blood, March 15, 2001; 97(6): 1809 - 1816. [Abstract] [Full Text] [PDF]
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P. Bostik, A. E. Mayne, F. Villinger, K. P. Greenberg, J. D. Powell, and A. A. Ansari Relative Resistance in the Development of T Cell Anergy in CD4+ T Cells from Simian Immunodeficiency Virus Disease-Resistant Sooty Mangabeys J. Immunol., January 1, 2001; 166(1): 506 - 516. [Abstract] [Full Text] [PDF]
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P. Schaerli, K. Willimann, A. B. Lang, M. Lipp, P. Loetscher, and B. Moser Cxc Chemokine Receptor 5 Expression Defines Follicular Homing T Cells with B Cell Helper Function J. Exp. Med., December 4, 2000; 192(11): 1553 - 1562. [Abstract] [Full Text] [PDF]
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A. J. McAdam, T. T. Chang, A. E. Lumelsky, E. A. Greenfield, V. A. Boussiotis, J. S. Duke-Cohan, T. Chernova, N. Malenkovich, C. Jabs, V. K. Kuchroo, et al. Mouse Inducible Costimulatory Molecule (ICOS) Expression Is Enhanced by CD28 Costimulation and Regulates Differentiation of CD4+ T Cells J. Immunol., November 1, 2000; 165(9): 5035 - 5040. [Abstract] [Full Text] [PDF]
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S. Wang, G. Zhu, A. I. Chapoval, H. Dong, K. Tamada, J. Ni, and L. Chen Costimulation of T cells by B7-H2, a B7-like molecule that binds ICOS Blood, October 15, 2000; 96(8): 2808 - 2813. [Abstract] [Full Text] [PDF]
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G. J. Freeman, A. J. Long, Y. Iwai, K. Bourque, T. Chernova, H. Nishimura, L. J. Fitz, N. Malenkovich, T. Okazaki, M. C. Byrne, et al. Engagement of the Pd-1 Immunoinhibitory Receptor by a Novel B7 Family Member Leads to Negative Regulation of Lymphocyte Activation J. Exp. Med., October 2, 2000; 192(7): 1027 - 1034. [Abstract] [Full Text] [PDF]
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 L. H. Glimcher and K. M. Murphy Lineage commitment in the immune system: the T helper lymphocyte grows up Genes & Dev., July 15, 2000; 14(14): 1693 - 1711. [Full Text]
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S. Wang, G. Zhu, K. Tamada, L. Chen, and J. Bajorath Ligand Binding Sites of Inducible Costimulator and High Avidity Mutants with Improved Function J. Exp. Med., April 15, 2002; 195(8): 1033 - 1041. [Abstract] [Full Text] [PDF]
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