Tracking dendritic cells: use of an in situ method to label all blood leukocytes

Bill Ristevski1, Alan J. Young2,5, Lisbet Dudler2, Ross N. P. Cahill3, Wayne Kimpton3, Elizabeth Washington3 and John B. Hay1,4

1 Department of Laboratory Medicine and Pathobiology, University of Toronto, 1 Kings’ College Circle, Toronto, Ontario M5S 1A8, Canada 2 Basel Institute for Immunology, 4005 Basel, Switzerland 3 Laboratory for Foetal and Neonatal Immunology, University of Melbourne, Parkville, Victoria 3052, Australia 4 Department of Immunology, University of Toronto, Toronto, Ontario M5S 1A8, Canada 5 Present Address: Department of Biology and Microbiology, South Dakota State University, Brookings, SD 57007, USA

Correspondence to: J. B. Hay; E-mail: jack.hay{at}utoronto.ca
Transmitting editor: P. Ohashi


    Abstract
 Top
 Abstract
 Introduction
 Methods
 Results
 Discussion
 References
 
Here we describe an in situ procedure with a labeling index (percent of labeled blood leukocytes) >98%, which is high enough to permit the direct tracking of dendritic cell (DC) precursors from blood into lymphoid tissues, while circumventing the pitfalls associated with in vitro labeling. DC and lymphocytes have similar blood to afferent lymph migratory capabilities. This method has additional applications in tracking other rare cell populations in both normal and pathological states.

Keywords: carboxyfluorescein diacetate succinimidyl ester, lymph, lymph node, recirculation


    Introduction
 Top
 Abstract
 Introduction
 Methods
 Results
 Discussion
 References
 
Numerous investigators including our three laboratories have studied leukocyte migration, particularly as it relates to lymphocytes. This reassortment and recirculation of lymphocytes is fundamental for normal immune surveillance, dissemination of the immune response, immunological memory, and also plays a role in many pathologies and infectious diseases (1). Previous investigations have characterized a variety of unique cell traffic migration streams. Among these are tissue-specific and subset-specific cell traffic patterns, such as the differential homing of lymphocytes derived from blood, intestinal lymph or s.c. lymph (25). Furthermore, the current paradigm of the blood to lymph migratory differences between naive and memory lymphocytes was established in sheep (6). The dynamic kinetics of cell migration during normal and pathological conditions has also been well characterized (1,7,8).

All of these experiments have involved the isolation, labeling and washing of cells in vitro with subsequent re-injection into animals. Maintenance of physiologic integrity has always been a concern, not only due to the time (several hours) of in vitro preparation of cells, but also with respect to the number of cells obtained for labeling. Typically, in long-term experiments lasting several days or weeks, optimizing these conditions has yielded labeling indices in the blood and lymph that are of the order of 1% (9,10). This labeling index has been sufficient to study the traffic and recirculation patterns of major subsets of cells. However, analysis of the kinetics and migration intricacies of minor subsets of cells via staining with mAb in second and third colors has been virtually impossible.

We have devised an in situ labeling approach which has permitted a minor dendritic cell (DC) population to be directly tracked from blood to lymphoid tissue. This in vivo administration of carboxyfluorescein diacetate succinimidyl ester (CFSE) has achieved a blood leukocyte labeling index >98%. The implications of this instantaneous labeling technique extend beyond the tracking of DC to other low-frequency cell populations in a variety of species. Compartments with inherently low cell counts (e.g. afferent lymph, peritoneal cavity) can now be more efficiently analyzed. This might be particularly relevant to extending studies of the relationship of leukocytes in cerebral spinal fluid and the lymphatic exit pathways from the central nervous system (1113).


    Methods
 Top
 Abstract
 Introduction
 Methods
 Results
 Discussion
 References
 
Animals
Outbred ewes 30–35 kg in weight were obtained from Renwick farms (London, Ontario, Canada) or Versuchsbetrieb Sennweid (Olsberg, Switzerland). Cannulae were surgically established in prescapular efferent lymphatics or prescapular pseudo-afferent lymphatics to allow chronic sampling of lymph as previously described (14). In addition, a catheter was also placed in the jugular vein to allow blood sampling. A full day after surgery was allowed before cell labeling was initiated to re-establish normal physiology. Handling of animals and experimental procedures were conducted in accordance with institutional and national guidelines for animal care and use.

Immunophenotyping
Afferent lymph samples were collected at various intervals for 72 h after cell labeling. Staining for CD4, CD8, {gamma}{delta}TCR, CD21, CD1 and CD11c was performed using standard procedures in conjunction with an appropriate allophycocyanin-conjugated secondary antibodies (Southern Biotechnology Associates, Birmingham, AL). Cells were fixed in 1% paraformaldehyde and analyzed on a FACSCalibur (Becton Dickinson, San Jose, CA).

Cell labeling
Leukocyte labeling in Wistar rats was accomplished by dissolving 0.8 mg of CFSE (Molecular Probes, Eugene, OR) in 200 µl dimethyl sulfoxide (DMSO) with 10 µl heparin and injecting this solution via the tail vein.

Leukocyte labeling in sheep was accomplished by dissolving 37 mg of CFSE in 6 ml of DMSO and 60 µl of heparin (1000 U/ml). This solution was injected into the blood via the jugular vein in order to label blood leukocytes. Both blood and lymph samples were collected in heparin, and kept on ice whenever possible. Heparin is not needed to obtain cell labeling, but was used as a precaution to avoid clotting. Other animals did not receive heparin and equivalent labeling results were obtained.

Cell preparation for FACS
Blood samples were collected in heparin and kept on ice whenever possible. Erythrocytes were lysed with distilled water or ammonium chloride and cells were washed in PBS twice. Cells were fixed in 1% paraformaldehyde in PBS and analyzed on a FACSCalibur flow cytometer within a maximum of 12 h.


    Results
 Top
 Abstract
 Introduction
 Methods
 Results
 Discussion
 References
 
Blood leukocyte labeling
To investigate the efficacy of this labeling procedure we used outbred ewes and female Wistar rats. Flow cytometric analysis was employed to measure the fluorescence intensity of blood leukocytes, before and after labeling for sheep (Fig. 1A and 1B) and rats (Fig. 1C and 1D) respectively. Blood samples from both species taken 10 min after i.v. infusion of CFSE demonstrated that >98% of all leukocytes in the sample fluoresced with a greater intensity than unstained leukocytes.






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Fig. 1. In vivo labeling of blood leukocytes. Blood samples were taken before labeling and 10 min after injection of CFSE i.v. in both sheep and rats. (A and B) Histograms generated by flow cytometric analysis, showing cell count versus CFSE intensity of unstained sheep blood leukocytes and leukocytes 10 min post CFSE injection. (C and D) Results obtained using rat blood.

 
Recirculation of labeled lymphocytes
The functional capacity of cells loaded with CFSE was investigated by observing the ability of lymphocytes to recirculate from blood to lymph after in situ labeling. This is a direct indication of cell function, as lymphocyte transendothelial migration is an active process and dead or damaged lymphocytes are not capable of recirculating (5). Chronic efferent lymph collections from a cannulated prefemoral efferent lymphatic in a conscious sheep were made to track the migration of labeled lymphocytes from blood to lymph. Histograms of cell count versus CFSE intensity are shown for a lymph sample prior to blood labeling and for a sample collected 18–20 h after blood labeling (Fig. 2A and B respectively). This clearly demonstrates the functional status of CFSE+ lymphocytes. In the example shown, 5.6% of efferent lymph cells were CFSE+. Continuous sampling of efferent lymph cells was also made over 40 h, by collecting all the lymph exiting a single cannulated prefemoral efferent lymphatic (Fig. 2C). In this representative example shown the highest percent of CFSE+ efferent lymph cells was recovered in the collection made between 7 and 18 h. Propidium iodide staining of cells from efferent lymph with 2% CFSE-labeled cells was very similar: 1.8% of CFSE+ cells and 2.0% of non-CFSE-labeled cells were propidium iodide-positive.





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Fig. 2. Recirculation of labeled blood lymphocytes into efferent lymph. Histograms showing cell count versus CFSE fluorescence intensity of efferent lymph cells collected from a prefemoral efferent lymphatic before in vivo labeling (A), and a 2-h collection made between 18 and 20 h after CFSE injection (B). (C) Percent of CFSE-labeled lymphocytes found following chronic sampling of the same prefemoral lymphatic over a 40-h period. Samples were analyzed on different days, after daily calibration of the flow cytometer.

 
In vivo versus ex vivo labeling index
Direct comparison of ex vivo versus in vivo labeling techniques was performed to assess the labeling index of lymphocytes. The percent of labeled lymphocytes in the blood versus time was investigated over a period of ~100 h. The reduction of CFSE+ lymphocytes from the blood is shown for ex vivo labeled cells where the lymphocytes contained in a unit of blood (~400 ml) were incubated with CFSE in vitro and returned to the venous circulation of a sheep (Fig. 3A). Also shown is the reduction of lymphocytes after i.v. injection of CFSE labeling the entire blood leukocyte pool (Fig. 3B). Both curves show a similar reduction of lymphocytes from the blood compartment. However, the labeling index of lymphocytes in the blood is ~2000% higher with the in situ technique. Figure 4(A and B) shows histograms of cell count versus fluorescence for spleen and mesenteric lymph node cells respectively. Due to the fenestrated sinusoids in the spleen creating a very open system of cellular exchange with the blood, it is expected that CFSE+ cells would be present after 1 h. However, migration of cells into lymph nodes from the blood would be very minimal after 1 h, as this phenomenon reaches it peak at 24 h. This difference of migratory capabilities after in vivo labeling is demonstrated in Fig. 4. This also demonstrates that CFSE is not capable of leaving the blood compartment in sufficient quantity to stain lymph node cells at the concentrations used for this study.




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Fig. 3. Reduction of labeled lymphocytes from the blood: in vitro versus in vivo labeling. A direct comparison was made between in vitro and in vivo labeling by plotting the reduction of labeled lymphocytes from the blood compartment using both methods. Results show (A) the percent of CFSE+ lymphocytes in the blood versus time, after the cells contained within a unit of blood were labeled in vitro with CFSE and returned to the sheep’s venous circulation (n = 5); (B) the percent of CFSE+ lymphocytes in the blood versus time, after in vivo labeling with CFSE (n = 3). Error bars indicate SEM.

 


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Fig. 4. CFSE+ cells in spleen versus mesenteric lymph node 1 h after in vivo labeling. Histograms showing cell count versus CFSE fluorescence intensity of cells from a biopsy performed on the spleen (A) and mesenteric lymph node (B) 1 h after in vivo labeling.

 
In vivo tracking of DC
The large increase in labeling index using this in situ method indicated that tracking of low-frequency leukocyte populations was possible. Afferent lymph was collected either through direct cannulation or through the cannulation of pseudo-afferent lymph as previously described (14). The phenotype of labeled cells recovered in pseudo-afferent lymph 24–48 h after in vivo labeling is shown in Fig. 5. Cells were gated to include small lymphocytes according to previously established forward and side-scatter parameters (15). In order to enhance for DC inclusion, afferent lymph cells were stained with a panel of mAb, including CD1, mannose receptor, CD11c and CD21. It has previously been established that antibody 20-27 (CD1) specifically identifies afferent lymph DC (16). Based on staining with CD1, cells were gated to include all afferent lymph DC. The majority of CD1+ cells (DC), including the labeled population, were recovered in the large-cell (high forward scatter) gate, rather than the low forward scatter gate used to analyze lymphocytes. When this gate was used, labeled CD1+ cells accounted for ~0.1% of the total population. More importantly, 54% of the larger, CFSE-labeled cells recovered in afferent lymph are CD1+.



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Fig. 5. Phenotype of labeled peripheral blood cells recovered in afferent lymph. Cells collected 24–48 h after in vivo blood labeling were reacted with appropriate antibodies and analyzed by flow cytometry. As DC are significantly larger than lymphocytes, and to allow more detailed analysis of the lymphoid and non-lymphoid populations, cells were either gated as low side scatter/low forward scatter (lymphocytes) or as high forward scatter/high side scatter (DC). At least 100,000 cells were then analyzed for each antibody to determine either the population of gated cells which were positive for both CFSE and the antibody of interest (large number) or the proportion of labeled cells reactive for each antibody (bracketed number). Antibody controls not shown.

 
In addition to the simple identification of labeled DC in afferent lymph after in situ blood labeling, it was possible for the first time to assess the kinetics and recovery of labeled afferent lymph DC. While the peak of the recovery of DC was slightly later than lymphocytes, the magnitude of recovery was similar for both populations (Fig. 6). These data were consistent independent of whether CD1 or high expression of CD11c was used to identify DC in afferent lymph. When the number of labeled cells within each subset was calculated as a proportion of that subset, it became clear that similar numbers of labeled DC and labeled lymphocytes migrated into the afferent lymph after whole-blood labeling.



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Fig. 6. Appearance of labeled lymphocytes and DC in afferent lymph after in vivo labeling. Cells collected from pseudo-afferent lymph at various times after whole-blood labeling (t = 0) were reacted with appropriate antibodies to determine recirculation into the lymph. In order to quantitate the degree to which labeled cells recirculated into lymph, the number of labeled cells reactive with each antibody was expressed as a percentage of the total number of cells reactive with each antibody. (Clearly, CD1+ or CD11c+ DC migrate into afferent lymph in significant numbers after whole-blood labeling and with similar kinetics to lymphocytes.)

 

    Discussion
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 Abstract
 Introduction
 Methods
 Results
 Discussion
 References
 
This is the first report of labeling the blood in situ, even though FITC and CFSE have been used to label cells in other tissues in situ (1719), and PKH-26 has been able to selectively label neutrophils for 24 h (20). The present study is the first to use DC markers to track this minor population from blood into normal afferent lymph.

CFSE is an ester combined with the fluorescein moiety. It is highly membrane permeable, and requires esterases found in cells to cleave the molecule and allow binding of the fluorochrome to intracellular proteins. We found, as was previously reported by others (21), that the intensity of CFSE-labeled cells declines over a 24-h period, but then stabilized, allowing long-term tracking of labeled cells. There may be further analytical procedures which could be developed to distinguish cell division from other phenomena which affect loss of intensity, such as cell death or turnover of labeled intracellular elements. Labeling of platelets may allow future studies to make relative comparisons between lymphocyte or leukocyte subsets and these non-dividing, blood elements. Using our labeling conditions, only blood leukocytes were labeled. For example, insufficient CFSE reached lymph nodes to directly label cells in this compartment. This is supported by two observations made. (i) Lymph nodes collected 1 h after blood labeling remained unlabeled. (ii) Kinetics of recovery of labeled lymphocytes in lymph were similar to the kinetics found with in vitro labeling studies. However, it is conceivable that by increasing the dye concentration, blood vascular cells and other organs/tissues might be directly labeled.

The present methodology enhances and validates a substantial literature on the use of cell-tracking dyes to define lymphocyte migration patterns (1,7,8). Leukocyte migration is a dynamic and complex process, which requires analysis of an ever-changing cellular mosaic in a physiological environment. In vivo cell tracking has been the principal technique to investigate this phenomenon. While rodent studies have been particularly useful in establishing the molecular basis of leukocyte homing, particularly with respect to interactions with endothelial cells (22,23), investigations in sheep have defined the physiology of lymphocyte recirculation. This is a powerful experimental approach as large animals allow surgical techniques to sequentially sample blood and many different lymphatic compartments during the course of a single experiment. Chronic lymph collection in conscious sheep, combined with fluorescent cell-tracking compounds and flow cytometry, has documented kinetics and quantitative recovery of i.v. injected labeled cells. Lymphocyte migration patterns for a variety of subsets and a variety of normal and pathological tissues have been well characterized (46,10). In fact, this physiological system has been crucial in validating cellular tracking labels. Only viable undamaged lymphocytes traffic from blood to lymph (5).

Because DC have a fundamental role in antigen presentation they have received considerable attention over the last few years (24). It should be noted that the intimate association of veiled cells with lymphocytes was described in afferent lymph several decades ago (25). Typically the special status of lymphocytes has been recognized due to their recirculation capabilities, meaning that they continuously exit the blood compartment and return via the lymphatic system. However, a truncated migration pathway from blood to lymph nodes via afferent lymphatics exists for monocytes, DC and macrophages. It is interesting that the cellular composition of afferent lymph in terms of the proportion of DC and macrophages to lymphocytes is very similar to blood (~1:10). We have shown that the capacity of DC to migrate from the blood to afferent lymph is similar to lymphocytes. In addition, the kinetics of the appearance of DC and lymphocytes in afferent lymph is comparable. Since monocytes, DC and macrophages are not found in normal efferent lymph, this indicates that selective cellular filtering solely resides in the lymph node.

Surprisingly there is a lack of detailed quantitative data on labeled leukocytes in the blood. In addition, the technical limitations associated with various labeling techniques used and sequential sampling have yielded a wide range of published half-times (10,2629). We have been able to use the combination of this labeling technique with multiple sequential sampling to define detailed blood curves for lymphocytes, monocytes, neutrophils and platelets (Hay and Ristevski, in preparation). We think the application of this method will permit a series of sound physiological experiments providing new information in the areas of normal hematology, leukemia, systemic infectious diseases and chronic inflammation.


    Abbreviations
 
CFSE—carboxyfluorescein diacetate succinimidyl ester

DC—dendritic cell

DMSO—dimethyl sulfoxide


    References
 Top
 Abstract
 Introduction
 Methods
 Results
 Discussion
 References
 

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