Coordination between CCR7- and CCR9-mediated chemokine signals in prevascular fetal thymus colonization

doi:10.1182/blood-2006-05-024190

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Blood, 15 October 2006, Vol. 108, No. 8, pp. 2531-2539.
Prepublished online as a Blood First Edition Paper on June 29, 2006; DOI 10.1182/blood-2006-05-024190.

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CHEMOKINES, CYTOKINES, AND INTERLEUKINS
Coordination between CCR7- and CCR9-mediated chemokine signals in prevascular fetal thymus colonization
Cunlan Liu, Fumi Saito, Zhijie Liu, Yu Lei, Shoji Uehara, Paul Love, Martin Lipp, Shunzo Kondo, Nancy Manley, and Yousuke Takahama
From the Division of Experimental Immunology, Institute for Genome Research, University of Tokushima, Japan; the Department of Genetics, University of Georgia, Athens; the Laboratory of Mammalian Genes and Development, National Institute of Child Health and Human Development, National Institutes of Health, Bethesda, MD; the Department of Molecular Tumorgenetics and Immunogenetics, Max-Delbrück Center (MDC) for Molecular Medicine, Berlin, Germany; and JEOL, Akishima, Tokyo, Japan.

   Abstract

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Thymus seeding by T-lymphoid progenitor cells is a prerequisitefor T-cell development. However, molecules guiding thymus colonizationand their roles before and after thymus vascularization areunclear. Here we show that mice doubly deficient for chemokinereceptors CCR7 and CCR9 were defective specifically in fetalthymus colonization before, but not after, thymus vascularization.The defective prevascular fetal thymus colonization was followedby selective loss of the first wave of T-cell development generatingepidermal V ${gamma}$ 3⁺ ${gamma}$ ${delta}$ T cells. Unexpectedly, CCL21, a CCR7 ligand,was expressed not by Foxn1-dependent thymic primordium but byGcm2-dependent parathyroid primordium, whereas CCL25, a CCR9ligand, was predominantly expressed by Foxn1-dependent thymicprimordium, revealing the role of the adjacent parathyroid inguiding fetal thymus colonization. These results indicate coordinationbetween Gcm2-dependent parathyroid and Foxn1-dependent thymicprimordia in establishing CCL21/CCR7- and CCL25/CCR9-mediatedchemokine guidance essential for prevascular fetal thymus colonization.

   Introduction

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Seeding of the thymus by hematopoietic stem cell-derived T-lymphoidprogenitor cells is essential for the generation of T lymphocytesin the thymus. T lymphopoiesis in the thymus is initiated onthe embryonic colonization by T-lymphoid progenitor cells ofthe thymic primordium that is generated at the third pharyngealpouch endoderm. The colonization of the fetal thymus beginsat gestation week 7 to 8 in humans and at embryonic day 11.5(E11.5) in mice, before the development of vasculatures in thethymus.^1,2 It was suggested that chemotactic guidance regulatesthe recruitment of T-lymphoid progenitor cells by the fetalthymus.^3,4 However, the molecules that guide fetal thymus colonizationand their roles before and after the thymus vascularizationhave not been established.
It was shown that the fetal thymus produces several chemokinesincluding CCL21, CCL25, and CXCL12.^5,6 We recently reportedthat the in vitro attraction of T-lymphoid progenitor cellsto the fetal thymus rudiment is mediated by G-protein-dependentchemotactic signals and is impaired by neutralizing antibodiesspecific for CCL21 and CCL25 but not by antibodies specificfor CXCL12, suggesting the involvement of CCL21 and CCL25 infetal thymus colonization.⁶ In the naturally occurring mutantmouse strain plt/plt, which is deficient for CCL21, or in micedeficient for CCR7, which is the receptor for CCL21, the numberof fetal thymocytes was lower than that in normal mice untilE14.5.⁶ Similarly, mice deficient for CCR9, the receptor forCCL25, exhibited a 3-fold decrease in total thymocyte cellularityuntil E17.5.⁷ On the other hand, it was shown that mice deficientfor CXCL12 or its receptor CXCR4 were not defective in fetalthymus colonization.⁸ These results suggested that fetal thymuscolonization involved CCL21 and CCL25 rather than CXCL12. However,it is unclear whether the combination of CCL21 and CCL25 issufficient for fetal thymus colonization or whether other chemotacticfactors additionally play a role in fetal thymus colonization.It is also unclear how these 2 chemokines are involved in thymuscolonization before and after thymus vascularization duringembryogenesis. Furthermore, it is not known where, when, andhow these chemokines are expressed in the thymic primordiumand neighboring regions.
In the present study, we show that the coordination betweenCCL21/CCR7- and CCL25/CCR9-mediated chemokine signals is essentialfor guiding fetal thymus colonization before, but not after,thymus vascularization. By regulating prevascular fetal thymuscolonization, the combination of these chemokine signals selectivelyregulates the first wave of T-cell development that includesthe generation of canonical epidermal V ${gamma}$ 3⁺ ${gamma}$ ${delta}$ T cells. The resultsalso reveal an unexpected role of the parathyroid primordiumin prevascular fetal thymus colonization. The expression ofCCL21 in the third pharyngeal pouch region is neither localizedat the thymic primordium nor controlled by the transcriptionfactor Foxn1. Instead, CCL21 is expressed by neighboring parathyroidprimordium and is controlled by the parathyroid-specifying transcriptionfactor Gcm2. On the other hand, CCL25 is expressed by both parathyroidand thymic primordia, and is regulated in both Foxn1-dependentand Foxn1/Gcm2-independent manners. Thus, our results indicatethat parathyroid and thymic primordia coordinate in guidingprevascular fetal thymus colonization, by providing spatiallydistinct expressions of CCL21 and CCL25.

   Materials and methods

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Mice
Mice deficient for CCR7,⁹ CCR9,¹⁰ and Gcm2¹¹ were describedpreviously. CCR7- and Gcm2-deficient mice were originated ona 129 x C57BL/6 mixed background and backcrossed to C57BL/6mice for at least 7 and 4 generations, respectively. CCR9-deficientmice were on a 129 x C57BL/6 mixed background. nu/nu mice crossedwith Gcm2-deficient mice were of C57BL/6 background. C57BL/6(B6), BALB/c, and BALB/c-nu/nu mice were obtained from SLC,Shizuoka, Japan. The day when a vaginal plug was first observedwas designated as gestation day 0.5.
Bromodeoxyuridine labeling of fetal thymocytes in vivo
Pregnant mice were given intraperitoneal injections of 2 mgbromodeoxyuridine (BrdU). At 2 hours after the injection, fetalthymocytes were stained with FITC-labeled anti-BrdU monoclonalantibody (BD Pharmingen, San Diego, CA) and PE-labeled anti-CD45antibody, and analyzed by flow cytometry.
Annexin V staining of fetal thymocytes
Fetal thymocytes were stained with PE-labeled annexin V (BDPharmingen) according to the manufacturer's instructions.
Analysis of postnatal thymus immigration in vivo
Equal numbers of lineage (CD3, CD4, CD8, CD11b, CD11c, B220,Gr1, TER119, Thy1)-negative bone marrow cells were labeled withcarboxyfluorescein succinimidyl ester (CFSE). Short-term thymushoming was analyzed as described.¹²
Analysis of fetal thymus attraction in vitro
Attraction of equal numbers of CD45⁺TER119^-FcR^- E14.5 fetalliver lymphoid progenitor cells was measured in a 24-hour cultureas described.^6,13
Fetal thymus organ culture
Organ culture of fetal thymus lobes was carried out as previouslydescribed.¹³
Preparation of epidermal cells
Epidermal cells were prepared as previously described,¹⁴ withslight modification. Briefly, skin from the abdomen of newbornmice and from the ears of adult mice was digested with 0.25%Trypsin-EDTA for 60 and 30 minutes, respectively. Epidermalsheets were separated from dermal tissue and were mechanicallydissociated for the preparation of single-cell suspensions ofepidermal cells.
Multicolor confocal microscopy analysis
Immunofluorescence staining and confocal microscopy analysisof frozen sections and epidermal sheets were performed as previouslydescribed.^6,15-17 Monoclonal antibodies specific for mouse CCL21and CCL25 were purchased from R&D Systems (Minneapolis,MN), rabbit antikeratin polyclonal antibody was from Dako (Carpinteria,CA), and FITC-anti-V ${gamma}$ 3 antibody (clone 536) was from BD Pharmingen.
Confocal images were acquired by TCS SP2 laser scanning microscopyequipped with argon and helium-neon lasers (Leica, Mannheim,Germany) and 40 x/1.25-0.75 CS oil objectives. Imaging mediumwas obtained from Dako. Images were acquired using Leica confocalsoftware version 2.0.
Multicolor flow cytometry analysis
Immunofluorescence staining and flow cytometry analysis of single-cellsuspensions were performed as previously described.⁶ CCR7 wasdetected with CCL19-Ig reagent kindly provided by Dr K. Hieshima(Kinki University, Osaka, Japan).¹⁷ Anti-CCR9 monoclonal antibodywas purchased from R&D Systems.
Scanning electron microscopy analysis of embryonic blood vessels
Normal mouse embryos were given injections of resin throughthe umbilical cord and the tissues were digested.¹⁸ Images werevisualized using a Hitachi S-800 electron microscope (Hitachinaka,Ibaraki, Japan).
Statistics
All values are expressed as means plus or minus standard errors.Statistical comparison was performed with the Student t testusing StatView software.

   Results

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Defective colonization of fetal thymus primordium in mice lacking CCR7 and CCR9
We previously showed that neutralizing antibodies specific forCCL21 and CCL25 significantly inhibit the in vitro attractionof T-lymphoid progenitor cells to the fetal thymus rudiment,suggesting that CCL21 and CCL25 are involved in fetal thymuscolonization.⁶ In order to examine the role of CCL21 and CCL25in fetal thymus colonization, we analyzed the numbers of fetalthymocytes in mice deficient for CCR7 (a receptor for CCL21)and/or CCR9 (a receptor for CCL25). As shown in Figure 1A andin agreement with previous reports,^6,7 mice deficient for eitherCCR7 or CCR9 had reduced numbers (30%-40% of normal number)of E14.5 fetal thymocytes. Strikingly, however, the reductionin fetal thymocyte number was marked (2% of normal number) inmice deficient for both CCR7 and CCR9 (Figure 1A).
The reduced number of E14.5 fetal thymocytes might be due toreduced thymus colonization by T-lymphoid progenitor cells and/orreduced expansion of thymocytes after thymus colonization. Thenumber of leukocytes that colonized the third pharyngeal pouch-derivedthymic primordium at E11.5 (the earliest stage at which fetalthymus colonization is detected in mouse embryogenesis¹) wasmarkedly reduced in CCR7/CCR9 double-deficient mice, as shownby the confocal microscopy analysis of embryonic sections (Figure 1B-C).The number of E14.5 fetal liver lymphoid progenitor cells attractedto normal fetal thymus rudiment was significantly reduced inCCR7/CCR9 double-deficient mice, as shown in the in vitro visualizationanalysis⁶ (Figure 1D). Technical differences among direct cell-numberdetermination (Figure 1A), 2-dimensional section analysis (Figure 1C),and the in vitro visualization analysis (Figure 1D) might havecontributed to the different ratios of cell numbers obtainedby these analyses. On the other hand, in vivo bromodeoxyuridinelabeling and in vitro annexin V staining indicated that thefrequencies of proliferating cells and apoptotic cells werenot affected in E14.5 fetal thymocytes of CCR7/CCR9 double-deficientmice (Figure 2A-B). The expression of CCL21 and CCL25 as wellas the stromal architecture identified by the generation ofkeratin 5 or keratin 8 single-positive thymic epithelial cellswas not impaired in the fetal thymus of CCR7/CCR9 double-deficientmice (Figure S1, available on the Blood website; see the SupplementalFigure link at the top of the online article). These resultsindicate that the reduced number of E14.5 fetal thymocytes inCCR7/CCR9 double-deficient mice resulted from reduced thymuscolonization by T-lymphoid progenitor cells rather than reducedexpansion of thymocytes after thymus colonization. These resultsalso indicate that the combination of chemokine signals mediatedby CCR7 and CCR9 plays a major role in the initial colonizationof the fetal thymus primordium by T-lymphoid progenitor cells.

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Figure 1.. Fetal thymus colonization in CCR7/CCR9-deficient mice between E11.5 and E14.5. (A) Single-cell suspensions isolated from the fetal thymus of indicated mice (WT, wild-type; R9KO, CCR9-knockout; R7KO, CCR7-knockout; R7/R9KO, CCR7/CCR9-double-knockout) were stained for CD45. The frequency of CD45⁺ cells was measured by flow cytometry. Thymocyte numbers were calculated from the frequency of CD45⁺ cells and the total viable cell numbers identified by the trypan blue dye exclusion method. Symbols indicate thymocyte numbers in individual embryos, and bars indicate means plus or minus standard errors. Numbers indicate means. (B, C) Sagittal sections of frozen embryos from indicated mice were 2-color-stained for CD45 (Alexa 633; green in panel C) and keratin (FITC; red in panel C). Plotted in panel B are the means plus or minus standard errors of the numbers of CD45⁺ cells in and attached to the third pharyngeal pouch that contains the thymic primordium. Representative images are shown in panel C, and the numbers of sections analyzed are indicated in panel B. (D) Number (means ± standard errors) of CD45⁺TER119^-FcR^- E14.5 fetal liver cells from indicated mice that were attracted to the deoxyguanosine-treated E14.5 B6 fetal thymus lobe in 1-day culture was determined as previously described.⁶ ^*P < .05; ^***P < .001; NS, not significant.

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Figure 2.. T-lymphoid progenitor cells in CCR7/CCR9-deficient embryos. (A) BrdU was pulsed for 2 hours to pregnant mice carrying E14.5 embryos, and the frequency of BrdU-incorporated cells in CD45⁺ embryonic thymocytes was measured by flow cytometry. Bars indicate means plus or minus standard errors (n = 3 to 8), and the results show no significant difference. (B) Ex vivo E14.5 fetal thymocytes of indicated mice were stained with annexin V. Bars indicate means plus or minus standard errors (n = 4 to 10), and the results show no significant difference. (C-F) Fetal liver cells (FL, panels C and E) and fetal blood cells (FB, panels D and F) from E12.5 embryos of indicated mice were 3-color stained for Lin (TER119, B220, Gr-1, Thy1.2 and NK1.1), CD117, and PIR. Plotted in panels C and D are the means plus or minus standard errors (n = 3 to 7) of the number (FL, panel C) and the frequency (FB, panel D) of Lin^-CD117⁺PIR⁺ cells, and no significant difference was noted among the 4 groups. Representative flow cytometry profiles are shown in panels E and F. Histograms shown on the left indicate Lin expression profiles and the gates for Lin^- cells. Numbers with dot profiles of CD117 versus PIR in Lin^- cells indicate frequency within the boxes. (G) Fetal liver cells from E12.5 embryos of B6 mice were 4-color stained for Lin, PIR, CCR9, and either CD117 or CCR7. Representative flow cytometry profiles of Lin versus PIR (left, bold), CCR9 versus CD117 within Lin^-PIR⁺ population (left, top), and CCR9 versus CCR7 within indicated Lin/PIR populations (right) from 3 independent measurements are indicated. Numbers indicate frequency within the boxes.

The reduced fetal thymus colonization in CCR7/CCR9 double-deficientmice did not coincide with the accumulation of T-lymphoid progenitorcells, which were identified as Lin^-CD117⁺PIR⁺,¹⁹ in E12.5 fetalliver (Figure 2C,E). In addition, Lin^-CD117⁺PIR⁺ T-lymphoidprogenitor cells in fetal blood were detected at normal levelsand not reduced in CCR7/CCR9 double-deficient E12.5 embryos(Figure 2D,F). These results indicate that the reduced fetalthymus colonization in CCR7/CCR9 double-deficient mice is dueto impaired migration of T-lymphoid progenitor cells from thecirculation to the thymus, and not to impaired emigration ofT-lymphoid progenitor cells from hematopoietic organs, suchas fetal liver, to the circulation. It should also be notedthat the Lin^-CD117⁺PIR⁺ fetal liver cells in normal embryoswere predominantly CCR9⁺ and the Lin^-CCR9⁺PIR⁺ fetal liver cellswere mostly CCR7⁺ (Figure 2G), indicating that Lin^-CD117⁺PIR⁺T-lymphoid progenitor cells generated in fetal liver are highlyenriched for cells that express both CCR7 and CCR9.
Role of CCR7 and CCR9 in prevascular but not postvascular fetal thymus seeding
The reduction in the number of thymocytes present in CCR7/CCR9double-deficient fetal mice was reversed during subsequent embryogenesis,as thymocyte numbers in CCR7/CCR9 double-deficient mice by postnatalday 1 (P1) were equal to those in normal mice (Figure 3A). Accordingly,whereas thymocyte development in CCR7/CCR9 double-deficientmice was delayed during embryogenesis, as shown by the reducedgeneration of CD4⁺CD8⁺ cells at E16.5, thymocyte developmentin CCR7/CCR9 double-deficient mice was normal at day P1 (Figure 3B).The recovery of thymocyte development was partially, but notentirely, attributed to the compensatory proliferation of asmall number of thymocytes that colonized CCR7/CCR9 double-deficientthymi by E14.5, because (1) in vitro organ culture of fetalthymus lobes showed that the number of thymocytes in the thymusisolated at E14.5 from CCR7/CCR9 double-deficient mice was partiallyrecovered but remained small even after 6 days of culture (34%of normal number after the culture, as shown in Figure 3C, and2% of normal number before the culture, as shown in Figure 1A),and (2) in vivo bromodeoxyuridine labeling of E14.5 and E16.5fetal thymocytes showed that the frequency of proliferatingcells was not significantly elevated compared with the normallevel in CCR7/CCR9 double-deficient mice (Figure 2A and Figure 3D).It was therefore reasoned that the recovery of thymocyte numberin CCR7/CCR9 double-deficient mice during late embryogenesiswas due to the combination of thymocyte proliferation and subsequentseeding of T-lymphoid progenitor cells at and after E14.5, andthat this late seeding of the thymus was mediated by a mechanismthat was independent of CCR7 and CCR9. The embryonic timingof such CCR7/CCR9-independent seeding coincided with the thymusvascularization (Figure 3E). Indeed, vasculature developmentin the embryonic thymus was detected at and after E15.5 (Figure 3E-F),in both normal mice and CCR7/CCR9 double-deficient mice (Figure 3E).It was also shown that bone marrow progenitor cells isolatedfrom CCR7/CCR9 double-deficient mice were capable of enteringthe postnatal thymus (Figure 3G-H), into which the entry ofT-lymphoid progenitor cells is mediated by the vasculature enrichedat the cortico-medullary junction²⁰ (also shown in Figure 3H).Thus, chemokine signals mediated by CCR7 and CCR9 are essentialfor fetal thymus seeding before, but not after, vascularizationof the thymus.

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Figure 3.. Postvascular thymus colonization in CCR7/CCR9-deficient mice. (A) Numbers of thymocytes from indicated mice at E16.5, postnatal day 1 (P1), and P14 are plotted. (B) Two-color flow cytometry analysis of indicated thymocytes for CD4 and CD8. Numbers indicate the frequency of cells in each quadrant. (C) E14.5 fetal thymus lobes were organ-cultured, and thymocyte numbers were measured at day 6 of culture. (D) BrdU was pulsed for 2 hours to pregnant mice carrying E16.5 embryos, and the frequency (means ± SE) of BrdU-incorporated embryonic thymocytes was measured by flow cytometry. (E) Frozen sections of indicated embryos were 3-color stained for endothelial CD31 (green, Alexa 568), mesenchymal ER-TR7 (red, Alexa 633), and keratin (blue, FITC). Higher magnification of the vasculatures is shown in the insets. (F) Scanning electron microscopy images of the vascular architecture in normal mouse embryos at the indicated gestational age. Embryos were intravenously microinjected with resin, and the tissues were digested, as described in "Materials and methods." (G, H) Equal numbers of lineage-negative bone marrow cells from indicated mice were labeled with CFSE and intravenously administered into adult wild-type mice. On day 2 after the administration, the number of CFSE⁺ cells in thymocytes and blood leukocytes was measured by flow cytometry (panel G), and frozen sections of the thymus were analyzed for migrated CFSE⁺ cells (green), CD31⁺ endothelial cells (blue, Alexa 568), and ER-TR5⁺ medullary thymic epithelial cells (red, Alexa 633) (panel H). ^*P < .05; ^***P < .001; NS, not significant.

Distinct localization of CCL21 and CCL25 in third pharyngeal pouch region
We then addressed how the 2 sets of chemokine signals via CCL21/CCR7and CCL25/CCR9 cooperate to attract T-lymphoid progenitor cellsto the fetal thymus. As was previously reported^5,6 and as isshown in Figure 4A,C, CCL21 protein was prominently expressedin the third pharyngeal pouch region, which contained the fetalthymus primordium, at E11.5. The prominent expression of CCL21in the third pharyngeal pouch region was detected even earlierat E10.5 (Figure S1). On the other hand, the expression of CCL25protein in the third pharyngeal pouch region was pronouncedat E13.5 and faintly detectable at E11.5⁶ (Figure 4E,G). Interestingly,CCL21 and CCL25 proteins were differently localized within thethird pharyngeal pouch region; CCL21 was exclusively localizedin an area at the dorsal-anterior aspect (Figure 4A,C), whereasCCL25 was detected in both dorsal-anterior and ventral-posteriorareas (Figure 4E,G).

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Figure 4.. Chemokine expression and fetal thymus colonization in Foxn1-deficient mice. Sagittal sections of frozen embryos from indicated mice of BALB/c background were 2-color stained for CCL21 (Alexa 633, red) and keratin (FITC, blue) (A-D), CCL25 (Alexa 633, red) and keratin (areas surrounded by dashed lines indicate keratin-positive areas) (E-H), or CD45 (Alexa 633, green) and keratin (FITC, red) (I-L). Control IgG staining shows the specificity of CCL21 and CCL25 signals (M-P). Anterior-posterior (a-p) and dorsal-ventral (d-v) orientation of the images is indicated. The means plus or minus standard errors of the numbers of CD45⁺ cells in and attached to the third pharyngeal pouch region that contains the thymic primordium are shown in panels Q and R. ^***P < .001; NS, not significant.

Foxn1 regulation of CCL25 but not CCL21 in third pharyngeal pouch region
As the third pharyngeal pouch gives rise to the thymus at theventral-posterior domain and the parathyroid gland at the dorsal-anteriordomain,²¹ it was interesting to determine how the expressionof the differently localized chemokines was regulated by transcriptionalfactors Foxn1 and Gcm2 that are essential for the developmentof the thymus^22,23 and the parathyroid,^11,24 respectively. InFoxn1-deficient nu/nu mice, fetal thymus development, includingthymocyte seeding, is severely defective,^21,23,25 which wasapparent at and after E13.5 (Figure 4K-L,R). CCL25 expressionin the third pharyngeal pouch region was lower in nu/nu micethan in normal mice (Figure 4E-H,O-P). The defect in CCL25 expressionwas obvious at the ventral-posterior domain of the thymic primordium,whereas the expression of CCL25 in the dorsal-anterior domainof the third pharyngeal pouch region was low but detectablein nu/nu mice (Figure 4F,H,P). Interestingly, the prominentexpression of CCL21 in the dorsal-anterior domain of the thirdpharyngeal pouch region was not reduced in nu/nu mice at E11.5or E13.5 (Figure 4A-D). Accordingly, the initial attractionof leukocytes to the third pharyngeal pouch region at E11.5was not impaired in nu/nu mice (Figure 4I-J,Q). Thus, CCL21is expressed in the dorsal-anterior domain of the third pharyngealpouch region independent of Foxn1, whereas CCL25 is expressedin both the Foxn1-dependent ventral-posterior domain and theFoxn1-independent dorsal-anterior domain of the third pharyngealpouch region.

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Figure 5.. Chemokine expression and fetal thymus colonization in Gcm2-deficient mice. Sagittal sections of frozen embryos from indicated mice were analyzed as in Figure 4. ^**P < .005; NS, not significant. Scale bars indicate 100 µm.

Gcm2-dependent expression of CCL21 but not CCL25 in third pharyngeal pouch region
The dorsal-anterior aspect of the third pharyngeal pouch givesrise to the parathyroid gland, which is essentially dependenton the transcriptional factor Gcm2.^11,24 We found that the expressionof CCL21 in the developing third pharyngeal pouch region wasundetectable in Gcm2-deficient mice (Figure 5A-D), whereas theexpression of CCL25 in the thymic primordium was not impairedin Gcm2-deficient mice (Figure 5E-H,O-P). Accordingly, the initialphase of leukocyte attraction to the third pharyngeal pouchregion at E11.5 was significantly reduced in Gcm2-deficientmice (Figure 5I-J,Q), in agreement with the E11.5 phenotypeof CCR7-deficient mice expressing CCL25 and CCR9 (Figure 1A-B).Nonetheless, the number of thymocytes that were subsequentlyaccumulated within the thymic primordium was not significantlyreduced in Gcm2-deficient mice (Figure 5K-L,R), possibly reflectingthe combination of CCL25-mediated recruitment of T-lymphoidprogenitor cells and intrathymic compensatory proliferationof colonized cells. Fetal thymus colonization in Gcm2-deficientmice seemed less severe than that in CCR7-deficient mice (Figures1 and 5), suggesting that an undetectable level of CCL21 maybe expressed in the third pharyngeal pouch region of Gcm2-deficientembryos. These results indicate that CCL21 localized at thedorsal-anterior domain of the third pharyngeal pouch regionis expressed by the parathyroid primordium under the controlof Gcm2 and not Foxn1, and this Gcm2-dependent CCL21 expressioncontributes significantly to the initial attraction of hematopoieticprogenitor cells to the third pharyngeal pouch region.
Expression of CCL21 and CCL25 in third pharyngeal pouch region in mice lacking Foxn1 and Gcm2
As shown in Figure 4, CCL25 was expressed both in the Foxn1-dependentventral-posterior domain and in the Foxn1-independent dorsal-anteriordomain of the third pharyngeal pouch region. Although the CCL25expression was not clearly impaired in Gcm2-deficient mice (Figure 5),it was interesting to address whether the dorsal-anterior expressionof CCL25 independent of Foxn1 might be dependent on Gcm2. Tothis end, we examined chemokine expression and fetal thymuscolonization in Gcm2-deficient nu/nu mice (Figure 6). As speculatedfrom the phenotypes of Gcm2-deficient mice and Foxn1-deficientnu/nu mice, CCL21 expression in the third pharyngeal pouch regionwas undetectable and leukocyte recruitment to the thymic regionwas impaired in E11.5 embryos of Gcm2-deficient nu/nu mice (Figure 6A-D,I-L).We found that the expression of CCL25 in the third pharyngealpouch region was reduced but detectable in Gcm2-deficient nu/numice (Figure 6E-H,Q-T). The localization and expression levelsof CCL25 in the third pharyngeal pouch region were comparablebetween Gcm2-deficient nu/nu mice and nu/nu mice (Figure 6G-H,S-T).Thus, the expression of CCL25 in the third pharyngeal pouchregion is induced even in the absence of Foxn1 and Gcm2, andFoxn1 enhances CCL25 expression in the thymic primordium.
Defective generation of V ${gamma}$ 3⁺ T cells in mice lacking CCR7 and CCR9
Finally, we examined how the chemokine-mediated prevascularcolonization of the fetal thymus may contribute to the formationof the postnatal immune system. It was shown that dendriticepidermal V ${gamma}$ 3⁺ T cells, which critically modulate innate immunesurveillance and homeostasis in the skin,^26-29 are derived fromthe first wave of T-cell development in the fetal thymus.^15,30It was speculated that the chemokine-mediated prevascular colonizationof the fetal thymus might play a role in the development ofcanonical ${gamma}$ ${delta}$ T cells in the skin. As shown in Figure 7, the generationof V ${gamma}$ 3⁺ T cells, which represented the majority of ${gamma}$ ${delta}$ T cells inthe fetal thymus at E15.5 (Figure 7A,C) and the postnatal skinat P7 (Figure 7B-D), was significantly reduced in CCR7/CCR9double-deficient mice (1% and 14% of normal numbers in the E15.5fetal thymus and the P7 skin, respectively). Unlike the reductionof prenatal V ${gamma}$ 3⁺ thymocyte generation, the numbers of systemicallydistributing V ${gamma}$ 2⁺ thymocytes at E15.5 and P7 were not impaired(Figure 7A), suggesting that the first-wave skin-homing V ${gamma}$ 3⁺T cells are selectively defective in CCR7/CCR9 double-deficientmice. In the skin of CCR7/CCR9 double-deficient newborn mice,the generation of MHC class II⁺ Langerhans cells was not reducedunlike V ${gamma}$ 3⁺ T cells (Figure 7D), suggesting that the skin homingof hematopoietic cells is not generally impaired in mice lackingCCR7 and CCR9. Nevertheless, the reduced number of epidermalV ${gamma}$ 3⁺ T cells in CCR7/CCR9 double-deficient newborn mice was restoredto normal numbers at 7 to 9 weeks of age (Figure 7B-C). Thus,the defective colonization of the prevascular thymus in CCR7/CCR9double-deficient mice was followed by the defective generationof V ${gamma}$ 3⁺ T cells in the prenatal thymus and the postnatal skinin newborn mice.

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Figure 6.. Chemokine expression and fetal thymus colonization in Foxn1/Gcm2-deficient mice. Sagittal sections of frozen embryos from indicated mice were analyzed as in Figure 4. Scale bars indicate 100 µm.

   Discussion

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Colonization of the thymus begins during embryonic developmentand before the thymus is vascularized. It has been suggestedthat chemotactic factors are involved in the attraction of T-lymphoidprogenitor cells toward the fetal thymus, but how T-lymphoidprogenitor cells are attracted to the fetal thymus at the pre-and postvascular stages has remained unclear. The present resultsshow that mice deficient for both CCR7 and CCR9 are defectivein fetal thymus colonization before, but not after, vascularizationof the thymus. These results reveal that the combination ofchemokine signals mediated by CCR7 and CCR9 is essential forearly fetal thymus colonization at the prevascular stage andthat these chemokine signals are not needed for the postvascularstage of perinatal and postnatal thymus seeding.
Our results show that CCL25, a CCR9 ligand, is expressed bothby the Foxn1-dependent ventral-posterior domain and by the Foxn1-independentdorsal-anterior domain of the third pharyngeal pouch region,whereas CCL21, a CCR7 ligand, is expressed in the third pharyngealpouch region exclusively by the Gcm2-dependent and Foxn1-independentdorsal-anterior domain. Although the roles of CCL21 and CCL25in various aspects of development and function of immune cellshave been reported,^9,10,31,32 their combinatorial role in fetalthymus colonization, as described in this study, is, to ourknowledge, the earliest function of these 2 chemokines in ontogeny.More importantly, the coordination between these 2 chemokinesthat are expressed in a spatially different manner offers anovel insight into the mechanisms underlying the colonizationof the fetal thymus by T-lymphoid progenitor cells at the prevascularstage, predicting a vasculature-independent yet orientation-specificguidance of T-lymphoid progenitor cells toward the thymus bythe sequential deposition of chemotactic molecules. Indeed,the data presented here suggest the directional migration ofT-lymphoid progenitor cells into the prevascular fetal thymusfrom the dorsal-anterior edge of the thymic primordium, theedge adjacent to the CCL21-expressing parathyroid primordium(Figure 4K,L).

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Figure 7.. Generation of V ${gamma}$ 3⁺ T cells in the thymus and skin of CCR7/CCR9-deficient mice. (A) E15.5 fetal thymocytes (top panels) and 7-day-old newborn thymocytes (P7, bottom panels) isolated from indicated mice were stained for CD45 and either one of TCR-C ${delta}$ (for total ${gamma}$ ${delta}$ ), V ${gamma}$ 3, or V ${gamma}$ 2. Cell number of indicated population was calculated from total viable thymocyte number and the frequency of that population. Symbols indicate the number of indicated thymocyte populations in individual mice, and bars indicate their means. (B) Epidermal cells isolated from abdomen skin of 7-day-old (P7) newborn mice or ear skin of 7- to 9-week-old adult mice were stained for TCR-C ${delta}$ or V ${gamma}$ 3. Symbols indicate the frequency of indicated cell populations within the total viable epidermal cells, and bars indicate means plus or minus standard errors. (C) Representative flow cytometry profiles of indicated thymocytes and epidermal cells are shown. Numbers in the dot plots indicate the frequency of cells within the quadrant. (D) Representative immunofluorescence images of 7-day-old epidermal sheets of V ${gamma}$ 3⁺ T cells or I-A⁺ Langerhans cells were visualized (FITC signals in green) in epidermal sheets (background signals in blue) from indicated mice. Images were obtained using a 63 x/1.40-0.60 oil objective. ^**P < .005; ^***P < .001; NS, not significant.

Our results further indicate the involvement of the Gcm2-dependentparathyroid in thymus development, revealing a previously unidentifiedrole of this endocrine organ in immune system development. Atthe E11.5 prevascular stage, the defect in attracting T-lymphoidprogenitor cells to the vicinity of the thymic primordium wasmore pronounced in CCR7-deficient mice than in CCR9-deficientmice (Figure 1), in agreement with the more prominent expressionof CCL21 than CCL25 in the third pharyngeal pouch region atE11.5⁶ and with the more severe reduction of leukocyte colonizationat E11.5 in Gcm2-deficient (and CCL21-defective in the thirdpharyngeal pouch region) mice than in Foxn1-deficient (and CCL25-defectiveonly in the thymus primordium) nu/nu mice (Figures 4 and 5).It is possible that the earlier expression of CCL21 by the Gcm2-dependentparathyroid primordium and the later increase of CCL25 expressionby the Foxn1-dependent thymic primordium sequentially guidethe prevascular fetal thymus colonization.
Unlike CCR7 and CCR9 double deficiency, our results also showthat selective deficiency of either CCR7 or CCR9 only partiallyreduces, but does not nullify, the number of fetal thymocytesat E14.5. Similarly, fetal thymus colonization in CCL21-deficientplt/plt mice or Gcm2-deficient (and CCL21-defective in the parathyroidprimordium) mice was deficient only in the early stages of embryogenesisand was restored during late embryogenesis, as shown in Liuet al⁶ and in this study. Thus, the recruitment of T-lymphoidprogenitor cells to the thymic primordium is unlikely to besolely controlled by the tandem coordination between the 2 chemokines,CCL21 and CCL25. Rather, it is possible that either CCL21 orCCL25 is partially capable of mediating prevascular thymus colonization.Alternatively, but not mutually exclusively, it is also possiblethat prevascular thymus colonization may be additionally controlledby factors other than these 2 chemokines, including adhesionmolecules and/or interstitial flow, which can partially compensatefor the absence of either one of the chemokine signals.
We found that vasculature development in the embryonic thymuswas detected as early as E15.5, and this timing coincided withthe restoration of thymocyte numbers in CCR7/CCR9 double-deficientmice. The results also show that T-lymphoid progenitor cellsfrom CCR7/CCR9 double-deficient mice were normally capable ofentering the adult thymus, which is well vascularized. Theseresults suggest that the chemokine signals mediated by CCL21/CCR7and CCL25/CCR9 are not needed for thymus seeding by T-lymphoidprogenitor cells after thymus vascularization. It was previouslyshown that in adult mice, T-lymphoid progenitor cells enterthe postnatal thymus through the vasculature enriched at thecortico-medullary junction,²⁰ and this postnatal thymus seedingis regulated by the adhesive interaction between P-selectinexpressed by endothelial cells and its ligand PSGL-1 expressedby T-lymphoid progenitor cells.¹² Thus, seeding of the thymusis likely mediated by at least 2 different mechanisms: (1) theCCL21/CCL25-dependent and vasculature-independent mechanism,which is operational during fetal thymus colonization beforethymus vascularization, and (2) the CCL21/CCL25-independentand vasculature-dependent mechanism, which is operational inthe vascularized thymus during late embryogenesis and afterbirth, and is regulated by the P-selectin-mediated adhesivecell-cell interaction. It is still unclear whether chemokinesother than CCL21 and CCL25 may be involved in the latter seedingmechanism in the vascularized thymus.
Finally, the present results show that the defective thymuscolonization in CCR7/CCR9 double-deficient mice was followedby the defective generation of V ${gamma}$ 3⁺ T cells in the prenatal thymusand the neonatal skin. It was shown that epidermal ${gamma}$ ${delta}$ T cellsexpressing the canonical V ${gamma}$ 3⁺ T-cell receptor are an essentialcomponent of innate immune surveillance and homeostasis in theskin,^26-29 and are derived from the first wave of T-cell developmentin the fetal thymus.^15,30 However, the reduced number of epidermalV ${gamma}$ 3⁺ T cells in CCR7/CCR9 double-deficient newborn mice was restoredto normal numbers during growth to adulthood. This restorationmay be due to the in situ proliferation of the small numberof V ${gamma}$ 3⁺ T cells that home to the skin, as previously noted,^16,33and/or the additional supply of late appearing V ${gamma}$ 3⁺ thymocytesfrom the newborn thymus. Nonetheless, it was speculated thatthe epidermal V ${gamma}$ 3⁺ T cells might be particularly important soonafter birth before the full acquisition of pathogen-specificsystemic responses.³⁴ Thus, the loss of epidermal V ${gamma}$ 3⁺ T cellsin newborn CCR7/CCR9 double-deficient mice may impair the firstline of defense against infectious pathogens attacking the surfaceof infants.
Unlike V ${gamma}$ 3⁺ fetal thymocytes, the V ${gamma}$ 2⁺ thymocytes that developsubsequently were not defective in CCR7/CCR9 double-deficientperinatal mice, suggesting that the skin-homing V ${gamma}$ 3⁺ T cellsare selectively defective in CCR7/CCR9 double-deficient mice.We think that the defective generation of V ${gamma}$ 3⁺ T cells in theskin of CCR7/CCR9 double-deficient mice is largely due to thedefective generation of first-wave T cells in the thymus ratherthan the defective homing of V ${gamma}$ 3⁺ T cells from the thymus tothe skin, because (1) the number of V ${gamma}$ 3⁺ T cells in CCR7/CCR9double-deficient mice was severely reduced in the fetal thymus(more severe than the reduction in newborn skin), (2) the distributionof Langerhans cells in the skin of CCR7/CCR9 double-deficientmice was not affected, suggesting that skin homing of hematopoieticcells is not generally impaired in the absence of CCR7 and CCR9,and (3) skin homing of V ${gamma}$ 3⁺ T cells was shown to be regulatedby other molecules such as CCR10/CCL27 and integrin ${alpha}$ E.^35,36Together, we conclude that the CCL21- and CCL25-mediated prevascularcolonization of the fetal thymus plays a critical role in thefirst wave of T-cell development, including the developmentof postnatal epidermal V ${gamma}$ 3⁺ T cells.
In summary, we have identified 2 major chemokine attractantsrequired specifically for colonization of the fetal thymus priorto vascularization, and have demonstrated a surprising and hithertounknown role of the developing parathyroid in immune systemdevelopment.

   Acknowledgements

We thank Drs E. Richie and A. Venables for sharing their unpublisheddata on fetal thymus vascularization, Dr K. Hieshima for theCCL19-Ig reagent, and Drs T. Ushiki, N. Iwanami, T. Nitta, andA. Singer for reading the manuscript.

   Footnotes

Submitted May 22, 2006; accepted June 12, 2006.
Prepublished online as Blood First Edition Paper, June 29, 2006;DOI 10.1182/blood-2006-05-024190.

Supported by the MEXT (Ministry of Education, Culture, Sports,Science, and Technology) grants-in-aid for scientific research,the JSPS (Japanese Society for the Promotion of Science) core-to-coreprogram, and the JSPS center-of-excellence program (Y.T.).

C.L. and Y.T. designed the study and wrote the paper; N.M. conceivedthe idea of parathyroid involvement; C.L. performed the majorityof experiments; F.S. performed confocal microscopy analysis;C.L. and Y.L. performed flow cytometry analysis; S.K. performedelectron microscopy analysis; Z.L. and N.M. provided Gcm2-deficientembryos; S.U. and P.L. provided CCR9-deficient mice; and M.L.provided CCR7-deficient mice.

The online version of this article contains a data supplement.

An Inside Blood analysis of this article appears at the frontof this issue.

The publication costs of this article were defrayed in partby page charge payment. Therefore, and solely to indicate thisfact, this article is hereby marked "advertisement" in accordancewith 18 U.S.C. section 1734.

Reprints: Yousuke Takahama, Division of Experimental Immunology, Institute for Genome Research, University of Tokushima, Tokushima 770-8503, Japan; e-mail: takahama{at}genome.tokushima-u.ac.jp.

   References

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Abstract
Introduction
Materials and methods
Results
Discussion
References

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  Copyright © 2006 by American Society of Hematology         Online ISSN: 1528-0020





	Copyright © 2006 by American Society of Hematology Online ISSN: 1528-0020