The V-J Recombination of T Cell Receptor-{gamma} Genes Is Blocked in Interleukin-7 Receptor-deficient Mice

doi:10.1084/jem.184.6.2423

This Article

	Abstract
	Full Text (PDF, 256K)
	PPT slides of all figures
	Alert me when this article is cited
	Citation Map

Services

	Email this article
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new content in the JEM
	Download to citation manager

Citing Articles

	Citing Articles via HighWire
	Citing Articles via CrossRef
	Citing Articles via Google Scholar

Google Scholar

	Articles by Maki, K.
	Articles by Ikuta, K.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Maki, K.
	Articles by Ikuta, K.


Social Bookmarking

	What's this?

© The Rockefeller University Press, 0022-1007/1996/12/2423/ $5.00
The Journal of Experimental Medicine, Volume 184, Number 6, December 1, 1996 2423-2428

Brief Definitive Reports

The V–J Recombination of T Cell Receptor- ${gamma}$ Genes Is Blocked in Interleukin-7 Receptor–deficient Mice

Kazushige Maki^*, Shinji Sunaga^*, and Koichi Ikuta^*^,

From the ^* Department of Disease-related Gene Regulation Research (Sandoz), Faculty of Medicine, The University of Tokyo, Tokyo 113, Japan; and the Department of Medical Chemistry, Faculty of Medicine, Kyoto University, Kyoto 606, Japan

Abstract

Top
Abstract
Materials and Methods
Results
Discussion
References

IL-7R-deficient mice have severely impaired expansion of earlylymphocytes and lack ${gamma}$ ${delta}$ T cells. To elucidate the role of IL-7Ron ${gamma}$ ${delta}$ T cell development, we analyzed the rearrangements of TCR- ${alpha}$ ,β, ${gamma}$ , and ${delta}$ genes in the thymus of the IL-7R-deficient mice.Southern blot analysis with a J ${gamma}$ 1 probe revealed that more than70% of J ${gamma}$ 1 and J ${gamma}$ 2 alleles are recombined to form distinct V ${gamma}$ 1.2–J ${gamma}$ 2and V ${gamma}$ 2–J ${gamma}$ 1 fragments in control mice. On the contrary,no such recombination was detected in the mutant mice. The rearrangementsin the TCR- ${alpha}$ , β, and ${delta}$ loci were comparably observed incontrol and mutant mice. PCR analysis indicated that the V–J recombination of all the V ${gamma}$ genes is severely hampered in themutant mice. The mRNA of RAG-1, RAG-2, Ku-80, and terminaldeoxynucleotidyl transferase (TdT) genes was equally detectedbetween control and mutant thymi, suggesting that the expressionof common recombination machinery is not affected. These datademonstrated that the V–J recombination of the TCR ${gamma}$ genesis specifically blocked in the IL-7R-deficient mice and suggestedthe presence of highly specific regulation for TCR ${gamma}$ gene rearrangement.

Address correspondence to Koichi Ikuta, Department of MedicalChemistry, Faculty of Medicine, Kyoto University, Yoshida,Sakyo-ku, Kyoto 606, Japan.

IL-7 is a growth factor for early B and T cell precursors. It was first characterized by its ability to support the growth of pre-B cells. Subsequently, it has been shown to support survival and growth of early thymocytes and promote rearrangementof TCR β and ${gamma}$ chains in fetal thymus and fetal liver cultures(1, 2). In vivo administration of neutralizing antibodies toIL-7 and IL-7R resulted in the inhibition of both B and T lymphopoiesis(3, 4). Finally, IL-7- and IL-7Rdeficient mice have severelyimpaired expansion of early lymphocytes (5, 6).

${gamma}$ ${delta}$ T cells have unique features in contrast with ${alpha}$ β T cells (7, 8). ${gamma}$ ${delta}$ T cells expressing specific V ${gamma}$ chain appear as severalsuccessive waves in the developing thymus and each of themshows specific tissue distribution in the adult mouse. However,little is known about the mechanism of ${gamma}$ ${delta}$ T cell development.In fetal thymic organ culture, addition of IL-7 promotes expansionof mature ${gamma}$ ${delta}$ T cells but prevents generation of mature ${alpha}$ βT cells (9). The epithelial cells in the skin and the gut produceIL-7 (10, 11), and dendritic epidermal T cells proliferate inresponse to IL-7 (10). Additionally, IL-7 induced rearrangementof V ${gamma}$ 2 and V ${gamma}$ 4, but not V ${gamma}$ 3 or V ${gamma}$ 5 genes, and sustained expressionof RAG-1 and RAG-2 genes (1, 2). Collectively, these resultssuggested that IL-7 may be involved in development and maintenanceof ${gamma}$ ${delta}$ T cells in the thymus and the periphery.

Although T and B lymphopoiesis is severely hampered, decreasedbut certain numbers of ${alpha}$ β T cells and B cells exist inthe periphery of the IL-7R-deficient mice, and they normallyrespond to mitogenic stimuli such as Con A and LPS (12). Incontrast, ${gamma}$ ${delta}$ T cells are completely absent in the IL-7R-deficientmice as well as in IL-2R- ${gamma}$ - and Jak3-deficient mice: no ${gamma}$ ${delta}$ T cellswere detected in fetal and adult thymus, spleen, skin, smallintestine, and liver of IL-7Rdeficient mice (12–14). Twopossibilities can be considered to explain the lack of ${gamma}$ ${delta}$ T cellsin the IL-7R-deficient mice. The one is that ${gamma}$ ${delta}$ T cell precursorsmay completely depend on IL-7 for their survival and/or proliferation.The other is that IL-7 may be a key factor for the inductionof the TCR ${gamma}$ gene rearrangements in T cell precursors.

To test the latter hypothesis, we analyzed the recombinationstatus of TCR loci in the ${alpha}$ β T cells remaining in IL-7R-deficientmice. The V–J recombination was almost completely blockedin the TCR ${gamma}$ locus in the mutant thymus, whereas the TCR ${alpha}$ , β,and ${delta}$ loci were rearranged at comparable levels with controlthymus. These results clearly demonstrated that the signalfrom IL-7R plays an indispensable role on the induction of TCR ${gamma}$ gene rearrangement. Thus, the mouse TCR ${gamma}$ locus will providea unique system to analyze the mechanism of cytokine-inducedgene rearrangements.

Materials and Methods

Top
Abstract
Materials and Methods
Results
Discussion
References

Mice.
IL-7R-deficient mice were established by replacing the exon2 with a PGK–neo cassette as described (12). Animals heterozygous (+/–) and homozygous (–/–) forthe IL-7R mutation were on the (129/Ola x C57BL/6)F₃ hybridbackground. The age of fetuses was determined by scoring forthe appearance of a vaginal plug and taking as day 0 the morningon which the mating plug was observed. All mice were maintainedunder the specific pathogen-free conditions in the Animal Centerfor Biomedical Research, Faculty of Medicine (The Universityof Tokyo).

Southern Blot Analysis.
Thymocyte genomic DNA was digested with HindIII or EcoRI restrictionenzyme and electrophoresed through 0.7% agarose gel. The DNAwas transferred to polyvinylidene difluoride filters (Immobilon;Millipore, Bedford, MA) and hybridized with ³²P-labeled probes.The following fragments were used as probes: J ${gamma}$ 1, a 1.1 kb StyI–HindIIIfragment containing the J ${gamma}$ 1 segment and its 3' flanking regionof genomic DNA from KN6 (15); J ${alpha}$ 1, a 3.5 kb EcoRI–HindIIIfragment of TA28.1 (16); J ${delta}$ 1, a 2.5 kb SacI fragment of pCDS17(17); Jβ2, a 2.3 kb EcoRI fragment of mouse genomic Jβregion (18). To confirm equal loading of genomic DNA, the membraneswere hybridized with a 1.3 kb KpnI fragment of mouse RAG-2cDNA (19). Southern blots were analyzed and radioactivity wasquantitated using a Bio-image Analyzer (Fujix BAS2000; FujiFilm, Tokyo, Japan). The percentage of rearranged alleles wascalculated by normalizing with the radioactivity of the RAG-2probe.

PCR Analysis.
Thymocyte DNA was prepared from fetuses at day 17 of gestationand mice at 4 wk old. PCR was carried out in a 25 µlreaction mixture containing 0.5 ng template DNA (0.5 µg for TCR β genes), 50 pmol each primer, 200 mM each dNTP, and 2.5 U Taq DNA polymerase. For TCR ${gamma}$ genes, samples wereamplified for 30 cycles of 45 s at 94°C, 2 min at 50°C,and 1 min at 72°C. For TCR ${delta}$ and β genes, PCR was performedas described previously (20–23). The PCR products wereelectrophoresed in 3% agarose gel, blotted onto nylon membranes,and hybridized with ³²P-labeled oligonucleotide probes. PCRprimers are as follows: V ${gamma}$ 1.1 and V ${gamma}$ 1.2, 5'-CTTCCATATTTCTCCAACACAGC-3';J ${gamma}$ 2, 5'-ACTATGAGCTTTGTTCCTTCTG-3'; J ${gamma}$ 4, 5'-ACTACGAGCTTTGTCCCTTTGG-3'; 5' RAG-2, 5'-CACATCCACAAGCAGGAAGTACAC-3'; 3' RAG-2, 5'-GGTTCAGGGACATCTCCTACTAAG-3'.V ${gamma}$ 2, V ${gamma}$ 3, V ${gamma}$ 4, V ${gamma}$ 5, J ${gamma}$ 1, V ${delta}$ 1, V ${delta}$ 4, V ${delta}$ 5, J ${delta}$ 1, Vβ8.2, Dβ2, andJβ2 primers were described previously (20–23). Oligonucleotide probes used are as follows: J ${gamma}$ 2, 5'-CAAATACCTTGTGAAAGCCCGAGC-3';J ${gamma}$ 4, 5'-CAAATATCTTGACCCATGATGTGC-3'. J ${gamma}$ 1, J ${delta}$ 1, and Jβ2 oligonucleotideprobes were described previously (20, 22). Radioactivity wasanalyzed using the Bio-image Analyzer.

RT-PCR Analysis.
Total RNA was isolated using the AGPC method as described (24).RNA samples were treated with RQ-1 RNase-free DNase (PromegaCorp., Madison, WI) to remove contaminating genomic DNA. Oligo(dT)-primed cDNA was prepared by Molony murine leukemia virusRNase H^– reverse transcriptase (GIBCO BRL, Gaithersburg,MD) at 37°C for 1 h. PCR was carried out for 25 cyclesof 1 min at 94°C, 1 min at 50°C for hypoxanthine phosphoribosyltransferase (HPRT) or at 55°C for others, and 1 min at72°C. The PCR products were electrophoresed in 3% agarosegel, blotted onto nylon membranes, and hybridized with ³²P-labeledprobes. The following DNA fragments were used as probes: RAG-1,a 1.4-kb EcoRI fragment of mouse RAG-1 cDNA (19); terminaldeoxynucleotidyl transferase (TdT), a 1.3-kb EcoRI–EcoRVfragment of mouse TdT cDNA, M16-1b (25); Ku-80, a 540-bp PCRfragment of Ku-80 cDNA; HPRT, a 350-bp PCR fragment of HPRTcDNA. The RAG-2 probe was described above. The following PCRprimers are used: 5' RAG-1, 5'-GCAATGAGGAAGTGAGTCTGGA-3'; 3' RAG-1, 5'-CTGAGGAAGGTATTGACACGGA-3'; 5' Ku-80, 5'-AGAGGACACTATTCAAGGGTAC-3';3' Ku-80, 5'-AGACACTGGTACAATCGCTGAA-3'; 5' TdT, 5'-ACTGCGACATCTTAGAGTCA-3';3' TdT, 5'-CTTCCCCTTAGTCCTGTCAT-3'; 5' HPRT, 5'-CTCGAAGTGTTGGATACAGG-3'; 3' HPRT, 5'-TGGCCTATAGGCTCATAGTG-3'. Radioactivity was analyzedusing the Bio-image Analyzer.

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

V–J Recombination of TCR ${gamma}$ Genes Is Blocked in IL-7Rdeficient Mice.
To examine whether the signal from IL-7R affects the V–Jrecombination, we compared the rearrangement of the TCR ${gamma}$ genesbetween the thymocytes of IL-7R +/– and –/–mice. The thymocyte DNA from 4-wk-old mice was digested withHindIII or EcoRI, and a Southern blot was hybridized with theJ ${gamma}$ 1 probe (Fig. 1 A, left). The J ${gamma}$ 1 probe allows the analysisof DNA rearrangements involving not only J ${gamma}$ 1 but also J ${gamma}$ 2 andJ ${gamma}$ 3 gene segments (15). The ES cell DNA showed a 6.6-kb J ${gamma}$ 1,a 9.0-kb J ${gamma}$ 3, and a 11.7-kb J ${gamma}$ 2 germline fragment. The thymocyteDNA from IL-7R +/– mice showed decreased intensity ofJ ${gamma}$ 1 and J ${gamma}$ 2 germline fragments compared with embryonic stem (ES)cell DNA. Furthermore, a 3.6-kb V ${gamma}$ 1.2–J ${gamma}$ 2 and a 1.4-kbV ${gamma}$ 2–J ${gamma}$ 1 fragment was clearly detected in IL-7R +/–mice. Quantification of the radioactivity revealed that 71%and 74% of J ${gamma}$ 1 and J ${gamma}$ 2 alleles, respectively, were rearrangedin thymocytes. Because ${gamma}$ ${delta}$ T cells are only 0.3% of total thymocytes(12), the majority of the V ${gamma}$ 1.2–J ${gamma}$ 2 and V ${gamma}$ 2–J ${gamma}$ 1 recombinedfragments are derived from ${alpha}$ β T cells or precursor cells.On the other hand, no fragment derived from V ${gamma}$ 1.2–J ${gamma}$ 2 orV ${gamma}$ 2–J ${gamma}$ 1 recombination was detected in IL-7R –/–mice (Fig. 1 A). This result demonstrates that V ${gamma}$ 1.2–J ${gamma}$ 2and V ${gamma}$ 2–J ${gamma}$ 1 rearrangements are almost completely blockedin ${alpha}$ β T cells in IL-7R-deficient mice.

View larger version (148K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 1 TCR gene rearrangements in the thymus of IL-7R-deficient mice. Lane 1, thymocytes from IL-7R +/– mice; lane 2, thymocytes from IL-7R –/– mice; lane 3, E14.1 ES cells. The position of HindIIIdigested phage ${lambda}$ DNA fragments was shown on the right. (A) Thymocyte DNA was digested with HindIII. A Southern blot was sequentially hybridized with the J ${gamma}$ 1 (left), the Jβ2 (middle), and the RAG-2 (right) probes. (B) Thymocyte DNA was digested with EcoRI. A Southern blot was sequentially hybridized with the J ${delta}$ 1 (left), the J ${alpha}$ 1 (middle), and the RAG-2 (right) probes.

We next examined adult and fetal thymus DNA by PCR with V ${gamma}$ 1.1+1.2,V ${gamma}$ 2, V ${gamma}$ 3, V ${gamma}$ 4, V ${gamma}$ 5, J ${gamma}$ 1, J ${gamma}$ 2, and J ${gamma}$ 4 primers. Thymus DNA revealedlarge amounts of PCR products with all the V ${gamma}$ –J ${gamma}$ primerpairs in IL-7R +/– mice. On the other hand, V–Jrearrangement was greatly reduced in all the TCR ${gamma}$ genes inIL-7R –/– thymus; the signal of V ${gamma}$ 5–J ${gamma}$ 1 productwas 150-fold reduced relative to IL-7R +/– mice, and thoseof V ${gamma}$ 1.1– J ${gamma}$ 4, V ${gamma}$ 1.2–J ${gamma}$ 2, V ${gamma}$ 2–J ${gamma}$ 1, V ${gamma}$ 3–J ${gamma}$ 1,and V ${gamma}$ 4–J ${gamma}$ 1 products were undetectable in IL-7R –/–mice (Fig. 2 A). Amplification with RAG-2 primers produced roughlythe equal amount of PCR products in both IL-7R +/– and–/– thymus, suggesting that approximately the sameamount of DNA was used in this analysis. These results supportthe data of Southern blot analysis and suggest that the V–Jrecombination is almost completely blocked in IL-7R-deficientmice not only in V ${gamma}$ 1.2 and V ${gamma}$ 2 genes but also in all the otherV ${gamma}$ genes.

View larger version (40K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 2 TCR gene rearrangements in the thymocytes detected by PCR. Rearrangement of TCR ${gamma}$ (A), ${delta}$ (B), and β (C) genes. The DNA from thymocytes of fetuses at day 17 of gestation (for V ${gamma}$ 3–J ${gamma}$ 1, V ${gamma}$ 4– J ${gamma}$ 1, and V ${delta}$ 1–J ${delta}$ 1 rearrangements) and at 4 wk old (for V ${gamma}$ 1.1–J ${gamma}$ 4, V ${gamma}$ 1.2–J ${gamma}$ 2, V ${gamma}$ 2– J ${gamma}$ 1, V ${gamma}$ 5–J ${gamma}$ 1, V ${delta}$ 4–J ${delta}$ 1, V ${delta}$ 5– J ${delta}$ 1, and all the β gene rearrangements) was amplified by PCR, and the Southern blots of the products were hybridized with oligonucleotide probes. Combination of primers used are shown on the left side (A and B). Dβ–Jβ2 and Vβ8.2–Dβ–Jβ2 rearranged fragments are shown on the left side (C).

Rearrangements of TCR ${alpha}$ , β, and ${delta}$ Genes Take Place Normally in IL-7R-deficient Mice.
We next analyzed the rearrangement of other TCR genes by Southernblot analysis. First, the Southern blot was hybridized withJβ2 probe (see Fig. 1 A, middle). The ES cell DNA showeda 4.8-kb germline Jβ2 fragment. Thymocyte DNA showed decreasedintensity of the Jβ2 germline fragment and smear patternsof Jβ2 recombined fragments in both IL-7R +/– and–/– mice. Quantification revealed that 81% and69% of Jβ2 alleles are rearranged in IL-7R +/– and–/– thymus, respectively. Thus, the frequency ofJβ2 rearrangement is slightly decreased in IL-7R –/–mice compared with IL-7R +/– mice. Next, we hybridizeda Southern blot with J ${delta}$ 1 and J ${alpha}$ 1 probes (see Fig. 1 B). A 6.8-kbJ ${delta}$ 1 and a 7.7-kb J ${alpha}$ 1 germline fragment was detected in ES cell DNA. These were greatly reduced in the thymus because of deletionof the ${delta}$ locus by V ${alpha}$ –J ${alpha}$ recombination in ${alpha}$ β T cells.Extra faint fragments and a smear pattern of J ${delta}$ recombined fragmentswere detected in IL-7R –/– mice as well as in IL-7R+/– mice. Thymocyte DNA from IL-7R –/– miceshowed several V ${delta}$ –D ${delta}$ –J ${delta}$ and D ${delta}$ –J ${delta}$ recombined fragmentsat the comparable intensity with that from IL-7R +/–mice.

The rearrangement of TCR ${delta}$ genes was further examined by PCRwith V ${delta}$ 1, V ${delta}$ 4, V ${delta}$ 5, and J ${delta}$ 1 primers. In contrast with TCR ${gamma}$ genes,the signals of V ${delta}$ 1–D ${delta}$ –J ${delta}$ 1, V ${delta}$ 4– D ${delta}$ –J ${delta}$ 4, andV ${delta}$ 5–D ${delta}$ –J ${delta}$ 1 fragments were only slightly diminished(two- to eightfold reduction) in IL-7R –/– micerelative to IL-7R +/– mice (Fig. 2 B). Because IL-7R–/– thymus lacks ${gamma}$ ${delta}$ T cells (12), the V ${delta}$ –J ${delta}$ recombinedfragments are probably derived from ${alpha}$ β T cells and precursorcells. Thus, the difference in the amounts of TCR ${delta}$ productsmay be attributed to the presence and absence of ${gamma}$ ${delta}$ T cells inthe thymus of IL-7R +/– and –/– mice, respectively.Collectively, TCR ${delta}$ gene rearrangement seems not to be severelyhampered in the IL-7R-deficient mice, supporting the data ofSouthern blot analysis.

Next, PCR amplification with Vβ8.2, Dβ2, and Jβ2 primers revealed six Dβ–Jβ and six Vβ–Jβrecombined fragments in both the IL-7R +/– and –/–thymus DNA (Fig. 2 C). These results demonstrate that IL-7Ris not essential for both Dβ–Jβ and Vβ–Dβ–Jβrecombinations. It is recently reported that IL-7 supportedDβ to Jβ rearrangements but not Vβ to DβJβrearrangement in fetal thymic organ culture of fetal liverprecursor cells (26). However, our results do not support thenotion that IL-7 may play some specific role on Dβ–Jβrecombination. All these results suggested that the rearrangementsof TCR ${alpha}$ , β, and ${delta}$ genes take place normally in IL-7R-deficient mice.

Expression of Common Recombination Machinery in IL-7Rdeficient Mice.
RAG-1 and RAG-2 are indispensable for V–D–J recombination,and several other gene products such as TdT, Ku p70/80 andDNA-dependent protein kinase catalytic subunit are also involvedin V–D–J recombination (27). To examine whetherthe signal from IL-7R affects the expression of these genes,we amplified cDNA prepared from adult thymocytes of IL-7R +/–and –/– mice by PCR with RAG-1, RAG-2, TdT, andKu-80 primers, and hybridized with each cDNA probes (Fig. 3). The levels of RAG-1, RAG-2, TdT, and Ku-80 transcripts inIL-7R –/– mice were almost comparable to those of IL-7R +/– mice. These results suggest that the mutation of IL-7R did not inhibit the expression of RAG-1, RAG-2, TdT,and Ku-80 genes.

View larger version (66K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 3 Expression of V–(D)–J recombination-associating genes in the thymus of the IL-7R-deficient mice. cDNA prepared from 4-wk-old adult thymocytes was amplified by PCR using RAG-1, RAG-2, TdT, Ku-80, and HPRT primers, and the Southern blots of PCR products were hybridized with each probe.

	Discussion

Top Abstract Materials and Methods Results Discussion References

TCR ${gamma}$ genes are frequently recombined in ${alpha}$ β T cells (28).More than 70% of V ${gamma}$ 1.2 and V ${gamma}$ 2 alleles are recombined in totalthymocytes. In this study, we used this phenomenon to examinewhether TCR ${gamma}$ recombination is blocked in ${alpha}$ β T cell precursorsof IL-7R-deficient mice. IL-7R-deficient mice had no detectableTCR ${gamma}$ recombination by Southern blot analysis. Furthermore, therecombination of all the V ${gamma}$ genes was undetectable in fetal and adult thymi by PCR analysis. Thus, we demonstrated that thesignal from IL-7R is indispensable for the V–J recombinationof TCR ${gamma}$ genes in ${alpha}$ β T cell precursors. And it is highlypossible that the TCR ${gamma}$ recombination is also blocked in ${gamma}$ ${delta}$ Tcell precursors as well as in ${alpha}$ β T cell precursors. Thiswould be certainly one reason why IL-7Rdeficient mice lack ${gamma}$ ${delta}$ T cells.

There are three significant features in our observation. First,this blockade is specific for TCR ${gamma}$ genes. The recombinationof TCR ${alpha}$ , β, and ${delta}$ genes are not affected. In addition,the recombination of IgH and L chain genes is probably nothampered by the mutation, because the IL-7Rdeficient mice havedecreased but certain numbers of surface IgM⁺ B cells in theperiphery (12). Second, the recombination of all the V ${gamma}$ genesis blocked. In a previous report, IL-7 induced the rearrangementof V ${gamma}$ 2 and V ${gamma}$ 4, but not V ${gamma}$ 3 or V ${gamma}$ 5 genes in fetal thymic organculture of fetal liver precursors (2). In contrast, not onlyV ${gamma}$ 2 and V ${gamma}$ 4 but also all the other V ${gamma}$ genes in the TCR ${gamma}$ 1, ${gamma}$ 2, and ${gamma}$ 4 clusters are hampered to recombine in the mutant mice. Third,TCR ${gamma}$ gene recombination is blocked not only in ${gamma}$ ${delta}$ but also in ${alpha}$ β T cell precursors. These features suggest the presenceof highly specific regulation for TCR ${gamma}$ gene rearrangement.

To explain the specific inhibition of TCR ${gamma}$ recombination inthe IL-7R-deficient mice, one possibility can be considered.It is to suppose that the TCR ${gamma}$ locus may contain a specificcis-control element(s). One possible candidate for this elementis TCR ${gamma}$ enhancers. Recently, it was reported that IL-7 inducesthe phosphorylation and DNA binding activity of Stat5 proteinin T cells (29). Because each TCR ${gamma}$ enhancer contains a Stat5binding sequence (30, 31), Stat5 may play a role on the regulationof TCR ${gamma}$ recombination. It is also possible that some unknownfactor(s) other than Stat5 may specifically regulate the recombinationof TCR ${gamma}$ locus.

	Acknowledgments

We thank Drs. Y. Takagaki, H. Yamagishi, O. Koiwai, and Y. Hashimotofor probes and discussion; Ms. M. Sugimori and M. Iidaka fortechnical assistance; Dr. S. Takeda for critically reading themanuscript; and Drs. M. Fujiwara and T. Honjo for encouragement.

Submitted: 9 August 1996

This work was supported by a grant-in-aid from the Ministryof Education, Science, and Culture of Japan, and by the grantprovided by the Ichiro Kanehara Foundation.

References

Top
Abstract
Materials and Methods
Results
Discussion
References

1 Muegge K, Vila MP & Durum SK. Interleukin-7: a cofactor for V(D)J rearrangement of the T cell receptor β gene, Science (Wash DC), 1993, 261, 93–95.[Abstract/Free Full Text]

2 Appasamy PM, Kenniston TJ, Weng Y, Holt EC, Kost J & Chambers WH. Interleukin-7-induced expression of specific T cell receptor ${gamma}$ variable region genes in murine fetal liver cultures, J Exp Med, 1993, 178, 2201–2206.[Abstract/Free Full Text]

3 Grabstein KH, Waldschmidt TJ, Finkelman FD, Hess BW, Alpert AR, Boiani NE, Namen AE & Morrissey PJ. Inhibition of murine B and T lymphopoiesis in vivo by an anti-interleukin-7 monoclonal antibody, J Exp Med, 1993, 178, 257–264.[Abstract/Free Full Text]

4 Sudo T, Nishikawa S, Ohno N, Akiyama N, Tamakoshi M, Yoshida H & Nishikawa S. Expression and function of the interleukin-7 receptor in murine lymphocytes, Proc Natl Acad Sci USA, 1993, 90, 9125–9129.[Abstract/Free Full Text]

5 von Freeden-Jeffry U, Vieira P, Lucian LA, McNeil T, Burdach SE & Murray R. Lymphopenia in interleukin (IL)-7 gene-deleted mice identifies IL-7 as a nonredundant cytokine, J Exp Med, 1995, 181, 1519–1526.[Abstract/Free Full Text]

6 Peschon JJ, Morrissey PJ, Grabstein KH, Ramsdell FJ, Maraskovsky E, Gliniak BC, Park LS, Ziegler SF, Williams DE, Ware CB, Meyer JD & Davison BL. Early lymphocyte expansion is severely impaired in interleukin-7 receptor-deficient mice, J Exp Med, 1994, 180, 1955–1960.[Abstract/Free Full Text]

7 Ikuta K, Uchida N, Friedman J & Weissman IL. Lymphocyte development from stem cells, Annu Rev Immunol, 1992, 10, 759–783.[Medline]

8 Haas W, Pereira P & Tonegawa S. Gamma/delta cells, Annu Rev Immunol, 1993, 11, 637–685.[Medline]

9 Watanabe Y, Sudo T, Minato N, Ohnishi A & Katsura Y. Interleukin 7 preferentially supports the growth of ${gamma}$ ${delta}$ T cell receptor–bearing T cells from fetal thymocytes in vitro. , Int Immunol, 1991, 3, 1067–1075.[Abstract/Free Full Text]

10 Matsue H, Bergstresser PR & Takashima A. Keratinocyte-derived IL-7 serves as a growth factor for dendritic epidermal T cells in mice, J Immunol, 1993, 151, 6012–6019.[Abstract]

11 Watanabe M, Ueno Y, Yajima T, Iwao Y, Tsuchiya M, Ishikawa H, Aiso S, Hibi T & Ishii H. Interleukin 7 is produced by human intestinal epithelial cells and regulates the proliferation of intestinal mucosal lymphocytes, J Clin Invest, 1995, 95, 2945–2953.[Medline]

12 Maki K, Sunaga S, Komagata Y, Kodaira Y, Mabuchi A, Karasuyama H, Yokomuro K, Miyazaki J & Ikuta K. Interleukin-7 receptor–deficient mice lack ${gamma}$ ${delta}$ T cells, Proc Natl Acad Sci USA, 1996, 93, 7172–7177.[Abstract/Free Full Text]

13 Cao X, Shores EW, Hu LJ, Anver MR, Kelsall BL, Russell SM, Drago J, Noguchi M, Grinberg A, Bloom ET, Paul WE, Katz SI, Love PE & Leonard WJ. Defective lymphoid development in mice lacking expression of the common cytokine receptor ${gamma}$ chain, Immunity, 1995, 2, 223–238.[Medline]

14 Park SY, Saijo K, Takahashi T, Osawa M, Arase H, Hirayama N, Miyake K, Nakauchi H, Shirasawa T & Saito T. Developmental defects of lymphoid cells in Jak3 kinase-deficient mice, Immunity, 1995, 3, 771–782.[Medline]

15 Takagaki Y, Nakanishi N, Ishida I, Kanagawa O & Tonegawa S. T cell receptor- ${gamma}$ and - ${delta}$ genes preferentially utilized by adult thymocytes for the surface expression, J Immunol, 1989, 142, 2112–2121.[Abstract]

16 Winoto A, Mjolsness S & Hood L. Genomic organization of the genes encoding mouse T-cell receptor ${alpha}$ -chain, Nature (Lond), 1985, 316, 832–836.[Medline]

17 Takeshita S, Toda M & Yamagishi H. Excision products of the T cell receptor gene support a progressive rearrangement model of the ${alpha}$ / ${delta}$ locus, EMBO (Eur Mol Biol Organ) J, 1989, 8, 3261–3270.[Medline]

18 Ikuta K, Hattori M, Wake K, Kano S, Honjo T, Yodoi J & Minato N. Expression and rearrangement of the ${alpha}$ , β, and ${gamma}$ chain genes of the T cell receptor in cloned murine large granular lymphocyte lines: no correlation with the cytotoxic spectrum, J Exp Med, 1986, 164, 428–442.[Abstract/Free Full Text]

19 Oettinger MA, Schatz DG, Gorka C & Baltimore D. RAG-1 and RAG-2, adjacent genes that synergistically activate V(D)J recombination, Science (Wash DC), 1990, 248, 1517–1523.[Abstract/Free Full Text]

20 Itohara S, Mombaerts P, Lafaille J, Iacomini J, Nelson A, Clarke AR, Hooper ML, Farr A & Tonegawa S. T cell receptor ${delta}$ gene mutant mice: independent generation of ${alpha}$ β T cells and programmed rearrangements of ${gamma}$ ${delta}$ TCR genes, Cell, 1993, 72, 337–348.[Medline]

21 Palacios R & Samaridis J. Bone marrow clones representing an intermediate stage of development between hematopoietic stem cells and pro-T-lymphocyte or proB-lymphocyte progenitors, Blood, 1993, 81, 1222–1238.[Abstract/Free Full Text]

22 Levin SD, Anderson SJ, Forbush KA & Perlmutter RM. A dominant–negative transgene defines a role for p56^lckin thymopoiesis, EMBO (Eur Mol Biol Organ) J, 1993, 12, 1671–1680.[Medline]

23 Anderson SJ, Abraham KM, Nakayama T, Singer A & Perlmutter RM. Inhibition of T-cell receptor β-chain gene rearrangement by overexpression of the non-receptor protein tyrosine kinase p56^l^ck, EMBO (Eur Mol Biol Organ) J, 1992, 11, 4877–4886.[Medline]

24 Chomczynski P & Sacchi N. Single-step method of RNA isolation by acid guanidinium thiocyanate–phenol– chloroform extraction, Anal Biochem, 1987, 162, 156–159.[Medline]

25 Koiwai O, Yokota T, Kageyama T, Hirose T, Yoshida S & Arai K. Isolation and characterization of bovine and mouse terminal deoxynucleotidyltransferase cDNAs expressible in mammalian cells, Nucleic Acids Res, 1986, 14, 5777–5792.[Abstract/Free Full Text]

26 Tsuda S, Rieke S, Hashimoto Y, Nakauchi H & Takahama Y. IL-7 supports D–J but not V–DJ rearrangement of TCR-β gene in fetal liver progenitor cells, J Immunol, 1996, 156, 3233–3242.[Abstract]

27 Lin WC & Desiderio S. V(D)J recombination and the cell cycle, Immunol Today, 1995, 16, 279–289.[Medline]

28 Heilig JS & Tonegawa S. T-cell ${gamma}$ gene is allelically but not isotypically excluded and is not required in known functional T-cell subsets, Proc Natl Acad Sci USA, 1987, 84, 8070–8074.[Abstract/Free Full Text]

29 Foxwell BM, Beadling C, Guschin D, Kerr I & Cantrell D. Interleukin-7 can induce the activation of Jak 1, Jak 3 and STAT 5 proteins in murine T cells, Eur J Immunol, 1995, 25, 3041–3046.[Medline]

30 Vernooij BT, Lenstra JA, Wang K & Hood L. Organization of the murine T-cell receptor ${gamma}$ locus, Genomics, 1993, 17, 566–574.[Medline]

31 Ihle JN. STATs: signal transducers and activators of transcription, Cell, 1996, 84, 331–334.[Medline]

CiteULike

Complore

Connotea

Del.icio.us Add to Digg

Digg

Facebook

Technorati

Twitter What's this?

This article has been cited by other articles:

Tani-ichi, S., Satake, M., Ikuta, K. (2009). Activation of the mouse TCR{gamma} enhancers by STAT5. Int Immunol 21: 1079-1088 [Abstract] [Full Text]
Maki, K., Ikuta, K. (2008). MEK1/2 Induces STAT5-Mediated Germline Transcription of the TCR{gamma} Locus in Response to IL-7R Signaling. J. Immunol. 181: 494-502 [Abstract] [Full Text]
Riera-Sans, L., Behrens, A. (2007). Regulation of {alpha}beta/{gamma}{delta} T Cell Development by the Activator Protein 1 Transcription Factor c-Jun. J. Immunol. 178: 5690-5700 [Abstract] [Full Text]
Nonaka, S., Naito, T., Chen, H., Yamamoto, M., Moro, K., Kiyono, H., Hamada, H., Ishikawa, H. (2005). Intestinal {gamma}{delta} T Cells Develop in Mice Lacking Thymus, All Lymph Nodes, Peyer's Patches, and Isolated Lymphoid Follicles. J. Immunol. 174: 1906-1912 [Abstract] [Full Text]
Hagenbeek, T. J., Naspetti, M., Malergue, F., Garcon, F., Nunes, J. A., Cleutjens, K. B.J.M., Trapman, J., Krimpenfort, P., Spits, H. (2004). The Loss of PTEN Allows TCR {alpha}{beta} Lineage Thymocytes to Bypass IL-7 and Pre-TCR-mediated Signaling. JEM 200: 883-894 [Abstract] [Full Text]
Kang, J., DiBenedetto, B., Narayan, K., Zhao, H., Der, S. D., Chambers, C. A. (2004). STAT5 Is Required for Thymopoiesis in a Development Stage-Specific Manner. J. Immunol. 173: 2307-2314 [Abstract] [Full Text]
Laky, K., Lewis, J. M., Tigelaar, R. E., Puddington, L. (2003). Distinct Requirements for IL-7 in Development of TCR{gamma}{delta} Cells During Fetal and Adult Life. J. Immunol. 170: 4087-4094 [Abstract] [Full Text]
Minagawa, M., Watanabe, H., Miyaji, C., Tomiyama, K., Shimura, H., Ito, A., Ito, M., Domen, J., Weissman, I. L., Kawai, K. (2002). Enforced Expression of Bcl-2 Restores the Number of NK Cells, But Does Not Rescue the Impaired Development of NKT Cells or Intraepithelial Lymphocytes, in IL-2/IL-15 Receptor {beta}-Chain-Deficient Mice. J. Immunol. 169: 4153-4160 [Abstract] [Full Text]
De Creus, A., Van Beneden, K., Stevenaert, F., Debacker, V., Plum, J., Leclercq, G. (2002). Developmental and Functional Defects of Thymic and Epidermal V{gamma}3 Cells in IL-15-Deficient and IFN Regulatory Factor-1-Deficient Mice. J. Immunol. 168: 6486-6493 [Abstract] [Full Text]
Franchimont, D., Galon, J., Vacchio, M. S., Fan, S., Visconti, R., Frucht, D. M., Geenen, V., Chrousos, G. P., Ashwell, J. D., O'Shea, J. J. (2002). Positive Effects of Glucocorticoids on T Cell Function by Up-Regulation of IL-7 Receptor {alpha}. J. Immunol. 168: 2212-2218 [Abstract] [Full Text]
Huang, J., Durum, S. K., Muegge, K. (2001). Cutting Edge: Histone Acetylation and Recombination at the TCR{gamma} Locus Follows IL-7 Induction. J. Immunol. 167: 6073-6077 [Abstract] [Full Text]
Ye, S.-K., Maki, K., Lee, H.-C., Ito, A., Kawai, K., Suzuki, H., Mak, T. W., Chien, Y.-h., Honjo, T., Ikuta, K. (2001). Differential Roles of Cytokine Receptors in the Development of Epidermal {gamma}{delta} T Cells. J. Immunol. 167: 1929-1934 [Abstract] [Full Text]
Lee, H.-C., Ye, S.-K., Honjo, T., Ikuta, K. (2001). Induction of Germline Transcription in the Human TCR{{gamma}} Locus by STAT5. J. Immunol. 167: 320-326 [Abstract] [Full Text]
Huang, J., Muegge, K. (2001). Control of chromatin accessibility for V(D)J recombination by interleukin-7. J. Leukoc. Biol. 69: 907-911 [Abstract] [Full Text]
Kang, J., Volkmann, A., Raulet, D. H. (2001). Evidence That {gamma}{delta} versus {alpha}{beta} T Cell Fate Determination Is Initiated Independently of T Cell Receptor Signaling. JEM 193: 689-698 [Abstract] [Full Text]
Porter, B. O., Scibelli, P., Malek, T. R. (2001). Control of T Cell Development In Vivo by Subdomains Within the IL-7 Receptor {{alpha}}-Chain Cytoplasmic Tail. J. Immunol. 166: 262-269 [Abstract] [Full Text]
Baird, A. M., Lucas, J. A., Berg, L. J. (2000). A Profound Deficiency in Thymic Progenitor Cells in Mice Lacking Jak3. J. Immunol. 165: 3680-3688 [Abstract] [Full Text]
Karawajew, L., Ruppert, V., Wuchter, C., Kosser, A., Schrappe, M., Dorken, B., Ludwig, W.-D. (2000). Inhibition of in vitro spontaneous apoptosis by IL-7 correlates with Bcl-2 up-regulation, cortical/mature immunophenotype, and better early cytoreduction of childhood T-cell acute lymphoblastic leukemia. Blood 96: 297-306 [Abstract] [Full Text]
Laky, K., Lefrancois, L., Lingenheld, E. G., Ishikawa, H., Lewis, J. M., Olson, S., Suzuki, K., Tigelaar, R. E., Puddington, L. (2000). Enterocyte Expression of Interleukin 7 Induces Development of {gamma}{delta} T Cells and Peyer's Patches. JEM 191: 1569-1580 [Abstract] [Full Text]
Maki, K., Nagata, K., Kitamura, F., Takemori, T., Karasuyama, H. (2000). Immunoglobulin {beta} Signaling Regulates Locus Accessibility for Ordered Immunoglobulin Gene Rearrangements. JEM 191: 1333-1340 [Abstract] [Full Text]
Oida, T., Suzuki, K., Nanno, M., Kanamori, Y., Saito, H., Kubota, E., Kato, S., Itoh, M., Kaminogawa, S., Ishikawa, H. (2000). Role of Gut Cryptopatches in Early Extrathymic Maturation of Intestinal Intraepithelial T Cells. J. Immunol. 164: 3616-3626 [Abstract] [Full Text]
Schlissel, M. S., Durum, S. D., Muegge, K. (2000). The Interleukin 7 Receptor Is Required for T Cell Receptor {gamma} Locus Accessibility to the V(D)j Recombinase. JEM 191: 1045-1050 [Abstract] [Full Text]
Wei, C., Zeff, R., Goldschneider, I. (2000). Murine Pro-B Cells Require IL-7 and Its Receptor Complex to Up-Regulate IL-7R{alpha}, Terminal Deoxynucleotidyltransferase, and c{micro} Expression. J. Immunol. 164: 1961-1970 [Abstract] [Full Text]
Kang, J., Coles, M., Raulet, D. H. (1999). Defective Development of {gamma}/{delta} T Cells in Interleukin 7 Receptor-Deficient Mice Is Due to Impaired Expression of T Cell Receptor {gamma} Genes. JEM 190: 973-982 [Abstract] [Full Text]
Kohyama, M., Nanno, M., Kawaguchi-Miyashita, M., Shimada, S., Watanabe, M., Hibi, T., Kaminogawa, S., Ishikawa, H. (1999). Cytolytic and IFN-gamma -producing activities of gamma delta T cells in the mouse intestinal epithelium are T cell receptor-beta -chain dependent. Proc. Natl. Acad. Sci. USA 96: 7451-7455 [Abstract] [Full Text]
Tomita, K., Hattori, M., Nakamura, E., Nakanishi, S., Minato, N., Kageyama, R. (1999). The bHLH gene Hes1 is essential for expansion of early T cell precursors. Genes Dev. 13: 1203-1210 [Abstract] [Full Text]
Lu, L., Chaudhury, P., Osmond, D. G. (1999). Regulation of Cell Survival During B Lymphopoiesis: Apoptosis and Bcl-2/Bax Content of Precursor B Cells in Bone Marrow of Mice with Altered Expression of IL-7 and Recombinase-Activating Gene-2. J. Immunol. 162: 1931-1940 [Abstract] [Full Text]
AKASHI, K., KONDO, M., CHESHIER, S., SHIZURU, J., GANDY, K., DOMEN, J., MEBIUS, R., TRAVER, D., WEISSMAN, I.L. (1999). Lymphoid Development from Stem Cells and the Common Lymphocyte Progenitors. Cold Spring Harb Symp Quant Biol 64: 1-12 [Abstract]
MORIGGL, R., MARINE, J.-C., TOPHAM, D.J., TEGLUND, S., SEXL, V., MCKAY, C., PIEKORZ, R., WANG, D., PARGANAS, E., YOSHIMURA, A., IHLE, J.N. (1999). Differential Roles of Cytokine Signaling during T-cell Development. Cold Spring Harb Symp Quant Biol 64: 389-396 [Abstract]
Durum, S. K., Candeias, S., Nakajima, H., Leonard, W. J., Baird, A. M., Berg, L. J., Muegge, K. (1998). Interleukin 7 Receptor Control of T Cell Receptor {gamma} Gene Rearrangement: Role of Receptor-associated Chains and Locus Accessibility. JEM 188: 2233-2241 [Abstract] [Full Text]
Laky, K., Lefrancois, L., von Freeden-Jeffry, U., Murray, R., Puddington, L. (1998). The Role of IL-7 in Thymic and Extrathymic Development of TCR{gamma}{delta} Cells. J. Immunol. 161: 707-713 [Abstract] [Full Text]
Kim, K., Lee, C.-k., Sayers, T. J., Muegge, K., Durum, S. K. (1998). The Trophic Action of IL-7 on Pro-T Cells: Inhibition of Apoptosis of Pro-T1, -T2, and -T3 Cells Correlates with Bcl-2 and Bax Levels and Is Independent of Fas and p53 Pathways. J. Immunol. 160: 5735-5741 [Abstract] [Full Text]
Malissen, M., Pereira, P., Gerber, D. J., Malissen, B., DiSanto, J. P. (1997). The Common Cytokine Receptor {gamma} Chain Controls Survival of {gamma}/{delta} T Cells. JEM 186: 1277-1285 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF, 256K)
	PPT slides of all figures
	Alert me when this article is cited
	Citation Map

Services

	Email this article
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new content in the JEM
	Download to citation manager

Citing Articles

	Citing Articles via HighWire
	Citing Articles via CrossRef
	Citing Articles via Google Scholar

Google Scholar

	Articles by Maki, K.
	Articles by Ikuta, K.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Maki, K.
	Articles by Ikuta, K.


Social Bookmarking

	What's this?

TABLE OF CONTENTS