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(American Journal of Pathology. 2001;159:285-295.)
© 2001 American Society for Investigative Pathology

Regular Articles

Phenotypic Characterization of Five Dendritic Cell Subsets in Human Tonsils

From the Hematology/Immunology Research Group, Christchurch Hospital, Christchurch, New Zealand

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Heterogeneous expression of several antigens on the three currently defined tonsil dendritic cell (DC) subsets encouraged us to re-examine tonsil DCs using a new method that minimized DC differentiation and activation during their preparation. Three-color flow cytometry and dual-color immunohistology was used in conjunction with an extensive panel of antibodies to relevant DC-related antigens to analyze lin^- HLA-DR⁺ tonsil DCs. Here we identify, quantify, and locate five tonsil DC subsets based on their relative expression of the HLA-DR, CD11c, CD13, and CD123 antigens. In situ localization identified four of these DC subsets as distinct interdigitating DC populations. These included three new interdigitating DC subsets defined as HLA-DR^hi CD11c⁺ DCs, HLA-DR^mod CD11c⁺ CD13⁺ DCs, and HLA-DR^mod CD11c^- CD123^- DCs, as well as the plasmacytoid DCs (HLA-DR^mod CD11c^- CD123⁺). These subsets differed in their expression of DC-associated differentiation/activation antigens and co-stimulator molecules including CD83, CMRF-44, CMRF-56, 2-7, CD86, and 4-1BB ligand. The fifth HLA-DR^mod CD11c⁺ DC subset was identified as germinal center DCs, but contrary to previous reports they are redefined as lacking the CD13 antigen. The definition and extensive phenotypic analysis of these five DC subsets in human tonsil extends our understanding of the complexity of DC biology.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

Tonsils have been used as a readily available source of lymphoid tissue to characterize human DCs.¹⁵ Three tonsil DC subsets have been identified: interdigitating DCs (IDCs),¹⁶ plasmacytoid DCs,¹⁷ and germinal center DCs (GCDCs).¹⁸ These DC subsets were isolated after a period of in vitro culture, which is likely to alter cell phenotype and morphology.¹⁹ They were also positively selected from lin^- cells based on their expression of the CD4, CD11c, or CD40 antigens, which would exclude any DC subsets lacking these antigens and would incorporate all DC subsets expressing those antigens into one population. The observation that both IDCs and GCDCs were heterogeneous with regard to CD11c, CD83, HLA-DR, and CD13 intensity raised the possibility that these tonsil DC populations might contain additional subsets.

This is the first study to analyze the composition of tonsil DC subsets within the entire lin^- HLA-DR⁺ DC population isolated using a new method that maintains the cells at 4°C to minimize changes in cellular differentiation/activation induced by the isolation procedure. We report the presence of five distinct DC subsets within human tonsils. The phenotype of each tonsil DC subset was analyzed by three-color flow cytometry and two-color immunohistochemistry using an extensive panel of antigens relevant to DC lineage, activation state, and function.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Patients and Samples

After approval by the Canterbury Ethics Committee and appropriate informed consent, tonsils were obtained from 68 patients undergoing routine tonsillectomies, which were excised in a noninflamed state. They were transported in sterile saline and processed immediately after excision. Tissue specimens for immunohistochemistry were snap-frozen in Tissue-Tek OCT compound (Sakura Finetek, Torrance, CA) and stored at -80°C until required. The remaining fresh tissue was used for DC isolation.

Monoclonal Antibodies (mAbs) and Soluble Ligands

The mAbs and recombinant proteins used in this study are listed in Table 1 and were used at optimal working concentration established by staining relevant control cell populations.

Enzymatic digestion was avoided as it subjects the cells to a period of incubation at 37°C and has been shown previously to release follicular DCs.¹⁵ Tonsil tissue was carefully minced using scissors and dissociated using a syringe plunger. Released cells were passed through a 40-grade mesh sieve into cold 10% fetal calf serum/RPMI media (RPMI 1640 supplemented with 100 U/ml penicillin, 1 mmol/L glutamine, and 100 U/ml streptomycin). Cellular debris was allowed to settle for 5 minutes. Remaining supernatant was filtered through a 70-µm nylon cell strainer (Falcon, Becton Dickinson Labware, NJ) and spun over a Ficoll-Hypaque density gradient (d = 1.077) to obtain mononuclear cells. The DC isolation was continued as previously described for blood DCs²⁰ and synovial fluid DCs.²¹ Briefly, T cells were depleted by rosetting with neuraminidase-treated sheep erythrocytes for 1.5 to 16 hours at 4°C. Non-T cells were isolated over a Ficoll-Hypaque density gradient and labeled with a mixture of mAbs (OKT3, CMRF-31, HuNK2, FMC-63) against the mature lineage-specific markers CD3 (T cells), CD14 (monocytes), CD16 (NK cells), and CD19 (B cells), respectively. In some cases, CD13 (WM-15) was added to the mAb mixture to isolate CD13^- DCs or CD11c (KB90) was added to the mAb mixture to isolate CD11c^- DC subsets. Labeled cells were depleted by positive selection using BioMag goat anti-mouse IgG-coated immunomagnetic beads (PerSeptive Biosystems, Framingham, MA) on a Dynamagnet (Dynal, Oslo, Norway) followed by sorting on a flow cytometer (FACS Vantage; Becton Dickinson, Australia), which resulted in >97% pure unlabeled cells. The resulting cells lacked lineage-specific markers (lin^-) and comprised the final DC-enriched populations. DCs were identified within the lin^- populations as CD45⁺, HLA-DR⁺ cells. May-Grunswald Giemsa stain was used to analyze cell morphology on cytospins.

Isolation of T Cells

T cells were obtained from tonsils and normal blood by hypotonic lysis of Er⁺ cells after rosetting. Contaminating non-T cells were labeled with a mAb mixture against CD14, CD16, CD19, and HLA-DR and removed using BioMag immunomagnetic beads and a Dynamagnet. This resulted in >97% pure CD3⁺ T cells.

Mixed Leukocyte Reaction

Tonsil lin^- cells were sorted into CD11c⁺ and CD11c^- DC subsets and added at the indicated numbers to 2 x 10⁵ purified allogeneic CD3⁺ blood T cells in triplicate wells. ³H-Thymidine (0.5 µCi) was added in the last 18 hours of a 6-day culture and uptake measured on a scintillation counter.

Cell Immunofluorescence Staining

Freshly sorted tonsil lin^- cells were labeled with an extensive panel of mAbs using standard two- and three-color immunofluorescence staining. Intracytoplasmic staining using mAbs against p55, CD68, and Ig was performed using a Perm & Fix kit (Caltag Laboratories, Burlingame, CA). In the former case, the primary mAb was detected with fluorescein isothiocyanate (FITC)-conjugated sheep anti-mouse (SAM) IgG F(ab')₂ (Silenus Laboratories, Hawthorne, Australia), whereas the second mAb was HLA-DR-PE-conjugated. Triple-color staining was used to analyze DC subsets on lin^- cells and CD13^-/lin^- cells using FITC-conjugated CD11c, PE/Cy5-conjugated HLA-DR and PE-SAM to detect the third antigen; or on CD11c^-/lin^- cells using CD123 or CD4 plus FITC-SAM, PE/Cy5-conjugated HLA-DR and a PE-conjugated third mAb. Isotype-matched controls were used for each mAb. In all phenotypic analyses HLA-DR was used as a marker to identify the DC population. A total of 10,000 events was collected for each sample. Cells were either analyzed on the FACS immediately or were fixed in 1% paraformaldehyde and stored at 4°C for next day analysis. The staining pattern and intensity appeared unaltered by cell fixation.

Tissue Immunohistochemistry

Cryostat sections of fresh tonsil tissue were dual-labeled as previously described.²² Alkaline phosphatase staining with a Fast Blue substrate (Sigma, St Louis, MO) detected the primary mAb (blue color), whereas immunoperoxidase staining with diaminobenzidine (DAKO Corporation, Carpinteria, CA) detected the second mAb (brown color). Double-stained cells were a grayish-green color. Stained sections were analyzed by light microscopy (BX50; Olympus Optical Co. Ltd., Tokyo, Japan) and photographed using the Olympus PM30 photomicrography system.

Tissue Immunofluorescence

Sections of fresh tonsil tissue were dual-labeled as described above for cell immunofluorescence staining. Briefly, after labeling the tissue for 30 minutes with an unconjugated mAb, excess mAb was removed using three 5 minutes washes with phosphate-buffered saline (PBS) and bound mAb detected with FITC-SAM. After another wash to remove excess FITC-SAM, 10% mouse serum/PBS was added to the tissue for 20 minutes to block nonspecific staining of a PE-conjugated second mAb. Tissue sections were analyzed using a fluorescent microscope (BX50, Olympus) and photographed using the Olympus PM30 photomicrography system.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Characterization of lin^- Tonsil Cells Based on HLA-DR Density

Depletion of lin⁺ cells (CD3, CD14, CD16, and CD19⁺) from the tonsil mononuclear cell fraction resulted in lin^- preparations that were highly enriched for DCs, as defined by HLA-DR expression (74.9% ± 11.5 SD, n = 18). Based on the surface density of the HLA-DR molecule, tonsil DCs could be clearly subdivided into distinct HLA-DR^hi- and HLA-DR^mod-expressing populations (Figure 1A) . HLA-DR^hi DCs represented a minor subset, accounting for only 4.1% ± 1.8 SD (n = 18) of the total HLA-DR⁺ lin^- DC population. All tonsil DCs expressed HLA-DQ and HLA-ABC at a similar density (Table 2) and showed weaker nonspecific esterase activity than autologous tonsil macrophages (data not shown).

View larger version (53K): [in this window] [in a new window]   Figure 1. Expression of selected antigens on HLA-DRhi and HLA-DRmod tonsil DC subsets. Flow cytometric analyses of fresh lin- tonsil cells using test-FITC mAb and HLA-DR-PE. A: Intensity of HLA-DR divided tonsil lin- cells into HLA-DRhi, HLA-DRmod, and HLA-DRneg cells. Dot plots of DC-associated markers (B), lineage markers (C), DC-associated activation markers (D), and co-stimulator molecules (E). Quadrant markers are set on the basis of isotype-matched control and HLA-DR staining to define the HLA-DRhi, HLA-DRmod, and HLA-DRneg populations. Data are from representative experiments of 18 performed.

Phenotype of All Tonsil DCs (lin^- HLA-DR⁺ Cells)

DC-Associated Markers

All tonsil DCs constitutively expressed the intracytoplasmic p55/fascin protein but lacked the CD1a antigen. The majority of tonsil DCs expressed the cytoplasmic CD68 antigen (Figure 1B , Table 2 ).

Leukocyte Common Antigen

All tonsil DCs expressed the CD45 antigen but lacked its CD45RC isoform. There was differential expression of the CD45RA, RB, and RO isoforms between and within DC subsets (Table 2) .

T Cell, B Cell, and Myeloid Antigens

Because of the high number of B cells in the non-T cell fraction of tonsil, an extensive panel of B-cell-specific antigens was examined to confirm that DCs were not subsets of B cells or plasma cells. Antigens expressed on tonsil B cells that were absent from DCs included CD10, CD20, CD21, CD24 (using ALB9 and BA-1 mAb), CD70, CD72, CD79a, CD79a peptide, and CD79b. In addition the unclustered B cell antigen, FMC-1, and the plasma cell marker, VS38,²³ were absent from all tonsil DC subsets. Furthermore neither cytoplasmic nor membrane bound IgA, IgD, IgG, IgM, , or light chains were detected. The carbohydrate-specific CD24 epitope detected by the mAb vib-e3, the CD123, CD2, CD4, and the myeloid CD13 antigen showed heterogeneous expression on DCs. The CD8 and CD33 antigens were absent on all DC subsets, as confirmed by the lack of staining using four different CD33 mAbs (Figure 1C , Table 2 ). Culture in media for 16 hours, dramatically reduced CD4 expression and induced CD13 expression on DCs (lin^- HLA-DR⁺ cells) (data not shown). This may reflect the differential survival of distinct DC subsets in culture.

CD95 and bcl₂ Antigens

The CD95 (Fas) antigen was constitutively expressed on all tonsil DC subsets, and cytoplasmic bcl₂ was absent (Table 2) .

Adhesion, Activation, and Co-Stimulator Molecules

The CD11a (LFA-1ß), CD18 (LFA-1ß), CD50 (ICAM-3), CD54 (ICAM-1), and CD40 molecules were expressed constitutively on all DC subsets. In contrast the CD11b, CD25, CD58 (LFA-3), and CD80 antigens were not expressed on any DC subsets. CD11c had heterogeneous expression on HLA-DR^mod DCs. The DC activation antigens CMRF-44 and 2-7 showed heterogeneous expression on DCs. Expression of 4-1BB ligand, CD86, CMRF-56, and CD83 was restricted to HLA-DR^hi DCs (Figure 1; B, D, and E , and Table 2 ). Expression of co-stimulator (CD40, CD80, CD86) and activation (CMRF-44, CMRF-56, CD83) antigens was up-regulated on HLA-DR^hi DCs and a significant number of HLA-DR^mod DCs after in vitro culture in media (data not shown). CMRF-44⁺ lin^- cells formed more stable clusters and were twice (mean, 2.3x; n = 5) as effective at stimulating allogeneic blood T cells than CMRF-44^- lin^- tonsil cells (data not shown).

Identification of Three Tonsil DC Subsets Based on HLA-DR and CD11c Expression

The above phenotypic analyses demonstrated that the CD11c antigen was constitutively expressed on HLA-DR^hi DCs, but subdivided HLA-DR^mod DCs into CD11c⁺ (17.7% ± 6.2 SD, n = 7) and CD11c^- (81.4% ± 6.0 SD, n = 7) subsets. CD11c^- DCs had the lowest density expression of HLA-DR (Figure 2A) . Therefore three tonsil DC subsets could be clearly defined as 1) HLA-DR^hi CD11c⁺ DCs; 2) HLA-DR^mod CD11c⁺ DCs; and 3) HLA-DR^mod CD11c^- DCs.

View larger version (55K): [in this window] [in a new window]   Figure 2. CD11c defines three tonsil DC subsets. A: Flow cytometric analyses of fresh lin- tonsil cells using CD11c-FITC and HLA-DR-PE. CD11c was present on all HLA-DRhi DCs and divided HLA-DRmod DCs into CD11c+ and CD11c- subsets. Boxes indicate these three DC subsets. B: Allogeneic MLR performed using sorted CD11c+ DCs (HLA-DRhi/mod DCs) and CD11c- (HLA-DRmod/neg) cells. Data are shown as mean ± SEM and are from a representative experiment of four performed. C, D, and E: May-Grunswald Giemsa stain of the three CD11c DC subsets. Original magnification, x1197. Scale bars, 10 mm. F: Flow cytometric analyses of fresh lin- tonsil cells triple-labeled with CD11c-FITC, HLA-DR-PE/Cy5, and test-PE mAb. Expression of CD68, HLA-DP, and CD40 was examined on HLA-DRhi CD11c+ DCs (dashed line), HLA-DRmod CD11c+ DCs (thick straight line), and HLA-DRmod CD11c- DCs (thin straight line). Isotype-matched controls are shown as dotted lines. Data are from representative experiments of four performed.

The phenotypes of these three tonsil DC subsets were analyzed further by triple labeling for CD68/HLA-DP/CD40, CD11c, and HLA-DR on purified lin^- cells. The density of CD68 differed between the DC subsets with the highest expression on HLA-DR^mod CD11c^- DCs, whereas HLA-DR^hi CD11c⁺ DCs and HLA-DR^mod CD11c⁺ DCs expressed CD68 at an equally lower density (Figure 2F , left). The highest density of HLA-DP was found on HLA-DR^hi CD11c⁺ DCs with decreasing levels on HLA-DR^mod CD11c⁺ DCs and HLA-DR^mod CD11c^- DCs, respectively. HLA-DP was absent on a subset of CD11c^- DCs (Figure 2F , middle). CD40 was present on all tonsil DC subsets with the highest density on HLA-DR^hi CD11c⁺ DCs followed by decreasing levels on HLA-DR^mod CD11c⁺ DCs and HLA-DR^mod CD11c^- DCs, respectively (Figure 2F , right, and Table 2 ).

Identification of Five Tonsil DC Subsets Based on HLA-DR, CD11c, CD13, and CD123 Expression

A more extensive phenotypic analysis was undertaken using triple labeling on sorted lin^- cells. The resultant phenotypes and relative proportions of the five DC subsets identified are outlined in Table 2 .

Phenotype of the HLA-DR^hi CD11c⁺ DC Subset

Expression of the DC-associated activation markers CMRF-56 and CD83 and the co-stimulator molecules CD86 and 4-1BB ligand were restricted to the HLA-DR^hi CD11c⁺ DC subset, with CD83 being expressed only at low density. This DC subset expressed the highest density of HLA-DP, the DC-activation markers CMRF-44 and 2-7 and the CD40 co-stimulator molecule. HLA-DR^hi CD11c⁺ DCs expressed CD4 at moderate density and CD68 at low density, whereas CD2 was not expressed. Differential expression of the CD123, CD45 isoforms, CD24 (vib-e3), CD38, and CD13 antigens may subdivide this population, however as the total number of HLA-DR^hi CD11c⁺ DCs was already low (<10% of the total DC population) it was difficult to further characterize these subsets separately (Figure 1; B, D, and E , and Table 2 ).

Phenotyping of HLA-DR^mod CD11c⁺ DCs Reveals CD13⁺ and CD13^- Subsets

As shown in Figure 1C , HLA-DR^mod DCs could be subdivided based on their expression of CD13. Triple labeling of sorted lin^- cells with CD13, CD11c, and HLA-DR confirmed that CD13 expression was restricted to a subset of HLA-DR^mod CD11c⁺ DCs (Figure 3A , top, and Table 2 ). CD13⁺ DCs were the predominant subset comprising 69.3% ± 5.5 SD (n = 3) of the total HLA-DR^mod CD11c⁺ DC population. The phenotype of HLA-DR^mod CD11c⁺ CD13⁺ DCs was analyzed by triple labeling sorted lin^- cells with HLA-DR, CD13, and test mAbs. HLA-DR^mod CD11c⁺ CD13^- DCs were analyzed by triple labeling sorted CD13^- lin^- cells with HLA-DR, CD11c, and test mAbs. Both CD13⁺ and CD13^- DC subsets expressed the HLA-DP, CD68, CD45RB, CD4, CD38, and CD40 antigens. Neither subset expressed the CMRF-56, CD83, CD24 (vib-e3), CD86, 4-1BB ligand, or CD123 antigens.

View larger version (41K): [in this window] [in a new window]   Figure 3. Phenotype of HLA-DRmod CD11c+ tonsil DCs. A: Gating on the HLA-DRmod lin- tonsil cells shows heterogeneous expression of CD13 on CD11c+ DCs (top). Triple labeling of sorted lin- tonsil cells with HLA-DR-PE/Cy5, CD13-PE, and test-FITC mAb determined antigen expression on HLA-DRmod CD11c+ CD13+ DCs (thick straight line). Triple labeling of sorted CD13- lin- tonsil cells with HLA-DR-PE/Cy5, CD11c-FITC, and test-PE mAb determined antigen expression on HLA-DRmod CD11c+ CD13- DCs (thin straight line). Isotype-matched controls were identical on both populations and are shown as dotted lines. B: HLA-DRmod CD11c+ CD13+ DCs could be subdivided into CD13hi- and CD13lo-expressing DCs. Triple labeling of sorted lin- tonsil cells with HLA-DR-PE/Cy5, CD13-PE, and test-FITC mAb determined antigen expression on HLA-DRmod CD11c+ CD13hi and CD13lo DCs. Quadrants are set on isotype-matched controls. Data are from representative experiments of four performed.

Phenotyping of HLA-DR^mod CD11c^- DCs Reveals CD123⁺ and CD123^- Subsets

Triple labeling of sorted lin^- cells with CD11c, HLA-DR, and CD123 confirmed that HLA-DR^mod CD11c^- DCs were a heterogeneous population based on CD123 expression (Figures 1C and 4A) . HLA-DR^mod CD11c^- CD123⁺ DCs comprised the majority (78.5% ± 9.2 SD, n = 4) of the total HLA-DR^mod CD11c^- DC population.

View larger version (39K): [in this window] [in a new window]   Figure 4. Phenotype of HLA-DRmod CD11c- DCs. A: Flow cytometric analyses of fresh lin- tonsil cells triple labeled with CD11c-FITC, HLA-DR-PE/Cy5, and CD123-PE. Gating on the CD11c- DCs showed heterogeneous expression of CD123. B: Flow cytometric analyses of CD11c- lin- tonsil cells triple labeled with HLA-DR-PE/Cy5, CD123-FITC, and test-PE mAb determined antigen expression on gated CD11c- CD123+ DCs (thin straight line) and CD11c- CD123- DCs (thick straight line). Isotype-matched controls are shown as dotted lines.

Identification of Tonsil DC Subsets in Situ

HLA-DR staining was not useful as a single marker to identify all tissue DCs or discriminate DC subsets because of its extensive expression in tonsil tissue and the difficulty of quantitative analyses in situ, respectively. However based on flow cytometric analyses, the entire tonsil DC population (including all DC subsets) could be best identified in situ as either CD68⁺/CD14^- cells (Figure 5A) or p55⁺ cells (data not shown). There were limitations to both methods however as the former combination excluded the minor HLA-DR^mod CD11c^- CD123^- CD68^- DC subset, whereas p55 overrepresented the number of DCs because of its expression on endothelial cells and HLA-DR^neg lin^- tonsil cells. Both methods revealed similar findings in that DCs formed an extensive network of interconnecting cells throughout the T-cell-enriched areas of tonsils. An additional population of DCs was sparsely scattered within the follicles.

View larger version (100K): [in this window] [in a new window]   Figure 5. Identification of five tonsil DC subsets in situ. A: Majority of DCs (brown cells) were identified in the follicles and T cell areas as CD68+ (brown)/CD14- (blue) cells. B: Subset 1: The HLA-DRhi CD11c+ DC subset (brown cells, arrow) could be identified as CD83+ (brown)/CD3- (blue) cells. C: CD83+ DCs (red cells) were located near CD8+ (green) T cells. D: A small number of the total CD68+ (green) DC population were CD83+ (red) DCs (yellow cells). E: CD11c+ DCs (green cells) were located near CD3+ (red) T cells in both the follicles and T cell areas. F: CD11c+ (green) CMRF-44+ (red) DCs (yellow cells) were located in the T cell areas. G: Subset 2: CD11c+ (green) CD13+ (red) DCs (yellow cells) were located in the T cell areas. Subset 3: CD11c+ CD13- DCs (green cells) were located in the follicle. H: Subset 4: CD11c- (green) CD123+ DCs (red cells) and (I) subset 5: CD11c- CD123- CD14- (red) CD68+ DCs (green cells, arrows) were located in the T cell areas. Boxed F defines follicular areas. Original magnifications: x240 (A), x573 (B and D), x286 (C, E–I).

HLA-DR^hi CD11c⁺ DCs could be identified in fresh tonsil tissue as either CD83⁺/CD14^-/CD19^- cells (Figure 5B) or CMRF-56⁺/CD19^- cells (data not shown). This DC subset was situated in close contact with CD8⁺ (and CD4⁺) T cells in the T cell areas of tonsils (Figure 5C) . Although CD4⁺ T cells dominate in paracortical areas, it was difficult to decipher their interaction with adjacent CD4⁺ DCs. To determine the percentage of HLA-DR^hi CD11c⁺ DCs within the total DC population accurately, triple labeling immunohistochemistry techniques would be necessary. As this was not technically possible, double labeling of serial sections was used instead and sequential sections analyzed. The CD68⁺/CD14^- phenotype was used to define tonsil DCs, CD83⁺/CD14^-/CD19^- to define HLA-DR^hi CD11c⁺ DCs and CD68⁺/CD83⁺ to examine these activated DCs within the total DC population. The number of activated HLA-DR^hi CD83⁺ DCs comprised a minority of the total number of CD68⁺ paracortical DCs (Figure 5D) , which is in similar proportions found in isolated DC preparations.

Double labeling using the CMRF-44 antigen plus the CD80 or CD86 co-stimulator molecules confirmed flow cytometric findings that all CMRF-44⁺ DCs (HLA-DR^hi CD11c⁺ DCs and HLA-DR^mod CD11c⁺ CD13^lo DCs) lacked CD80 and only some CMRF-44⁺ DCs (presumably the HLA-DR^hi CD11c⁺ DCs) expressed the CD86 antigen (data not shown).

HLA-DR^mod CD11c⁺ Tonsil DC Subsets

The CD11c⁺ DCs (HLA-DR^mod and HLA-DR^hi DC subsets) were located in both the germinal center and T cell areas of tonsils (Figure 5E) . CD11c⁺ GCDCs appeared to be larger in size than CD11c⁺ paracortical DCs and, as opposed to the latter population, GCDCs lacked expression of the CMRF-44 antigen (Figure 5F) .

HLA-DR^mod CD11c⁺ CD13⁺ DCs were located in the T cell areas, whereas HLA-DR^mod CD11c⁺ CD13^- DCs were located in tonsil follicles (Figure 5G) . Thus HLA-DR^mod CD11c⁺ CD13^- DCs clearly represented GCDCs. Because of technical limitations with triple-color analyses in situ, it remained unclear whether some HLA-DR^mod CD11c⁺ CD13^- DCs were also located in the T cell areas.

HLA-DR^mod CD11c^- Tonsil DC Subsets

The vast majority of CD123⁺ cells lacked CD11c expression and were located near high endothelial venules in the T cell areas of tonsil (Figure 5H) . Therefore GCDCs do not express the CD123 antigen. Using a combination of the CD68, CD11c, and CD123 antigens, CD11c^- CD123^- DCs could be identified as a minor population within the T cell areas of tonsil tissue (Figure 5I) . It was not technically possible to identify the CD11c^- CD123^- CD68^- DC subset in situ because of the lack of defining antigens on these cells.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
In this study we demonstrate using a new method of DC preparation that five distinct DC subsets are present in human tonsils (Figure 6) . Extensive analysis of a large number of lin^- HLA-DR⁺ tonsil DC preparations revealed the presence of HLA-DR^hi CD11c⁺ DCs, HLA-DR^mod CD11c⁺ CD13⁺ DCs, HLA-DR^mod CD11c⁺ CD13^- DCs, HLA-DR^mod CD11c^- CD123⁺ DCs, and HLA-DR^mod CD11c^- CD123^- DCs subsets. In situ localization identified four of these subsets as distinct IDC populations, which included plasmacytoid DCs¹⁷ and three new DC subsets. We also confirmed the presence of GCDCs¹⁸ but clarified their phenotype as a fifth HLA-DR^mod CD11c⁺ CD13^- DC subset.

View larger version (20K): [in this window] [in a new window]   Figure 6. Five distinct subsets of DCs in human tonsils. In situ localization identified four of these subsets as distinct IDC populations, which included: 1) plasmacytoid DCs (HLA-DRmod CD11c- CD123+ DCs) and three new DC subsets; 2) HLA-DRhi CD11c+ DCs; 3) HLA-DRmod CD11c+ CD13+ DCs; and 4) HLA-DRmod CD11c- CD123- DCs. GCDCs were also clarified as 5) HLA-DRmod CD11c+ CD13- DCs. The three CD11c+ DC subsets are likely to represent different stages of DC maturation/activation. The CD11c+ DCs and CD11c- DCs are thought to arise from separate myeloid and lymphoid developmental pathways, respectively. IDC, interdigitating DCs; GCDC, germinal center DCs; HEV, high endothelial venule.

These five tonsil DC subsets each shared a number of phenotypic features including expression of HLA-DQ, HLA-ABC, the DC-associated p55 marker,²⁴ and CD95 antigen. They also expressed HLA-DR, CD40, and CD45RB albeit at varying density between DC subsets, but lacked the CD33, CD45RC, and CD1a antigens. The absence of CD33 contradicts previous reports of low-level expression on GCDCs, which may relate to the absence of cell culture as CD33 is inducible. In contrast to previous reports, we did not detect CD80¹⁶ or bcl₂²⁵ within any tonsil DC subsets. This may again reflect a difference in isolation procedures because CD80 is induced by in vitro culture, which was used in previous studies on tonsil DCs. Similar to blood DCs,⁸ high-density expression of cytoplasmic CD68 was associated with CD11c^- tonsil DCs. A separate population of HLA-DR^neg lin^- tonsil cells was also identified, as described previously in normal blood²⁶ and chronic arthritic synovial fluid.²⁷ Although these cells expressed p55 and showed heterogeneous expression of CD45, CD13, and adhesion antigens, they did not express MHC class II antigens either before or after in vitro culture. They therefore did not seem to represent DC precursor cells or a separate DC subset.

The majority (80%) of tonsil DCs are HLA-DR^mod lin^- cells, which can be subdivided into morphologically distinct smaller CD11c⁺ and more substantial CD11c^- DC subsets. These are found in similar proportions to normal blood.⁹ The CD11c⁺ DCs can be further subdivided into a small CD13^- subset and a CD13⁺ subset that are localized in the germinal center and T cell areas, respectively. The CD13^- and CD13⁺ DC subsets comprised 5.1% ± 2.1 SD and 13.7 ± 4.6 SD (n = 4) of the total DC population, respectively. HLA-DR^mod CD11c⁺ CD13^- and CD13⁺ DCs shared a similar phenotype with the exception that only the CD13⁺ DCs expressed the 2-7 and CD45RO activation antigens. The CD13⁺ DCs could be further subdivided based on CD13 intensity into CD13^hi and CD13^lo subsets. These CD13⁺ DC subsets only differed in their expression of the CMRF-44, CD2, and CD45RA antigens, which were present only on the CD13^lo DC subset. HLA-DR^mod CD11c⁺ CD13^- DCs were the only subset to express the CD2 antigen.

In addition to location, the HLA-DR^mod CD11c⁺ CD13^- DC subset phenotypically resembled GCDCs as they lacked DC-associated activation and co-stimulator molecules. The previously described GCDCs were isolated based on a CD11c⁺ CD4⁺ lin^- cell phenotype¹⁸ but, as outlined in this study, this phenotype is common to three distinct DC subsets located in both the T cell areas and germinal centers, one of which expresses CD13. This fact, plus the observation that CD13 can be induced on a subpopulation of tonsil DCs after culture (data not shown), could explain the heterogeneous expression of CD13 originally reported on GCDCs. Our study further extends their phenotype and shows that GCDCs have many phenotypic similarities to mature/myeloid blood DCs^9,14 including low-density CD68 and lack of CD123 expression. However, unlike CD11c⁺ blood DCs,⁹ the GCDCs identified in this study did not express the CD13 or CD33 antigens.

Consistent with a low activation state, the HLA-DR^mod CD11c^- DC subset lacked expression of DC activation antigens, CD45RO, and co-stimulator molecules, although CD40 was expressed at low levels. The CD2 and CD13 antigens were also absent. Heterogeneous expression of CD123 and CD4 enabled us to define two distinct HLA-DR^mod CD11c^- DC subsets. The predominant HLA-DR^mod CD11c^- DC subset (comprising 61.4% ± 11.6 SD of the total DC population) was CD123⁺, CD4⁺, CD68^hi, and closely resembled in phenotype, morphology, and localization near paracortical high endothelial venules²⁸ the plasmacytoid tonsil DCs¹⁷ and immature CD11c^- DCs described in blood,^9,10 bone marrow, and thymus.¹⁰ As a result, it has been suggested that this tonsil DC subset may be derived from CD11c^- immature/lymphoid blood DCs.^12,17 Our study further extends the phenotype of plasmacytoid DCs and demonstrates that they express p55, CD45RB, CD24 (vib-e3), low levels of HLA-DP, but lack DC activation markers and 4-1BB ligand.

HLA-DR^mod CD11c^- CD123^- DCs were the only subset that lacked CD4 and HLA-DP expression. A small number of these cells also lacked cytoplasmic CD68, CD45RA, CD45RB, and CD38. Interestingly a minor CD68^- CD4^- lin^- cell population had also been observed in a study of blood DCs.⁸ Unfortunately it was not possible to identify these cells in tonsil sections because of their lack of suitable discriminatory markers.

The HLA-DR^hi CD11c⁺ DC subset was the only subset that expressed the DC activation antigens, CD83²⁹ and CMRF-56³⁰ and the co-stimulator molecules, CD86³¹ and 4-1BB ligand.³² This tonsil DC subset also expressed the highest levels of the DC-associated activation marker CMRF-44,^26,33 HLA-DP, CD40, and 2-7,¹⁹ which we newly identify as a DC-associated activation marker. Morphologically this DC subset resembled activated blood DCs.² In tissue sections these activated DCs comprised only a minority of the total paracortical DC population, comparable to their low numbers present in DC isolates (4.1% ± 1.8 SD, n = 18, of the total DC population. The close association of HLA-DR^hi CD11c⁺ DCs to paracortical T cells and their low frequency resembles the characteristics of antigen-bearing DCs in lymph nodes that have a rapid turnover after antigen presentation events.^34-36 The phenotypes of the HLA-DR^hi CD11c⁺ DCs and HLA-DR^mod CD11c⁺ CD13^- DC subsets are broadly similar, differing mainly in their expression of activation-associated antigens. As in vitro activation of blood DCs induces similar changes,^29-31,33 this raises the possibility that HLA-DR^hi CD11c⁺ DCs represent a more activated form of HLA-DR^mod CD11c⁺ CD13^- DCs.

IDCs have been identified in tonsils as CD40^hi lin^- cells, however the constitutive presence of CD40 on all five DC subsets described in our study indicates that these IDCs incorporated several DC subsets. This is verified by the heterogeneous expression of the CD11c and CD83 antigens described on the former IDC population.¹⁶ Here we report that, in addition to plasmacytoid DCs (HLA-DR^mod CD11c^- CD123⁺ DCs), three other newly described DC subsets are located in the T cell areas of tonsils and can be defined as 1) HLA-DR^hi CD11c⁺ DCs, 2) HLA-DR^mod CD11c⁺ CD13^- DCs, and 3) HLA-DR^mod CD11c^- CD123^- DCs (Figure 6) . Interestingly IDCs have been reported to stimulate activated B cells^16,37 suggesting that at least one DC subset may be involved in primary B cell responses.

There is accumulating evidence in mice that DC subsets arise from different lymphoid and myeloid developmental pathways.^4,38 However, although the immature DC subsets (ie, CD11c^-, CD33^lo, CD68^hi, and CD123^hi) and mature DC subsets (ie, CD11c⁺, CD33^hi, CD68^lo, and CD123^lo) within human blood display a number of lymphoid and myeloid features, respectively^4,8-10,14,38 , it remains unclear whether they develop from distinct cell lineages. A recent report provides evidence that, as opposed to different maturation states, CD11c⁺ blood DCs represent multipotent myeloid precursor cells, whereas CD11c^- blood DCs represent lymphoid progenitors.¹² The tonsil CD11c⁺ DC subsets described in this study share a number of features with CD11c⁺ mature/myeloid blood DCs being CD68^lo and CD123^lo/neg. They do however, differ from each other in their expression of CD13, CD33, activation, and co-stimulator molecules. As each of these antigens can be up-regulated after culture on tonsil DCs, one could speculate that the CD11c⁺ DC subsets represent different maturation stages, ie, CD11c⁺ CD13^- DR^mod (early), CD11c⁺ CD13⁺ DR^mod (intermediate), and CD11c⁺ CD13⁺ DR^hi (late). However, functional studies would be necessary to establish the relationship of these five tonsil DC subsets both to each other and to other tissue DCs. Consistent with previous studies on blood DC subsets, CD11c⁺ DCs,⁹ as well as activated DCs,^33,39 were the most potent stimulators of allogeneic T cell responses in the tonsil.

The HLA-DR^hi CD11c⁺ DCs and GCDCs seem to represent highly immunogenic DCs that are actively presenting antigens to paracortical and germinal center T and/or B cells, respectively. The other less-activated IDC subsets may represent DCs that have migrated to the draining lymph node (tonsil) either without receiving up-regulatory signals or else receiving negative regulatory signals from interacting self T cells.⁴⁰ These distinct DC subsets may play different roles in regulating immunity or tolerance, although it remains unclear whether the type of T cell response is driven by intrinsic properties of the DC subset¹³ or by local environmental factors.⁴¹ Ultimately, targeting a specific DC subset may provide more effective therapeutic regulation of immunological disorders.

	Acknowledgements

 
We thank the ENT surgeons and nursing staff from Christchurch, St George’s and Southern Cross Hospitals for providing us with tonsil specimens, Dr. Axel Heiser for helpful suggestions, and Lisa Haring for providing assistance with flow cytometry.

	Footnotes

 
Address reprint requests to Professor Derek N. J. Hart, Director, Mater Medical Research Institute, Aubigny Place, Raymond Terrace, South Brisbane 4101, QLD, Australia. E-mail: dhart{at}mmri.mater.org.au

Supported by New Zealand Lotteries Grant Board (to D. H.) and Canterbury Medical Research Foundation (to K. S.).

Accepted for publication March 27, 2001.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

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