Cell surface receptor-antibody association constants and enumeration of receptor sites for monoclonal antibodies

BACKGROUND: Fluorescent markers (labeled antibodies) and flow cytometry are used to enumerate the average number of receptors (antigens) on formed bodies (cells) in whole blood by using a new method that avoids the extra steps of separating bound from unbound fluorescent markers or the use of external standards. METHODS: Mean channel fluorescence intensities of equilibrated marker-cell suspension mixtures, total concentrations of marker, and targeted cell counts obtained by standard cytometry procedures are used to complete the analyses for receptors per cell. Also, flow cytometric assays using competitive binding between fluorescent marker (CD4-RD1, CD8-FITC, CD3-FITC, CD3-RD1) and unlabeled antibody (CD4, CD8, CD3, CD3-dextran) for receptors on white blood cells in whole blood are described for determination of relative and specific binding constants of unlabeled/labeled antibody for targeted receptors. RESULTS: Ranges that were obtained for receptors per cell (lymphocytes) in normal blood donors were as follows: CD4, 4.9 x 10(4)-1.5 x 10(5); CD8, 5.0 x 10(5)-2.1 x 10(6); CD3, 6.6-7.8 x 10(5). Binding constants were highest for unlabeled CD4 antibody, 2. 7 x 10(10)-2.1 x 10(12) M(-1), and then unlabeled CD3 antibody, 1.1 x 10(10)-1.9 x 10(11) M(-1). FITC- and RD1-labeled antibodies typically had binding constants that were 10-to 100-fold lower than the native antibodies. CONCLUSIONS: Values of receptors per cell and binding constants obtained by the new method from flow cytometric analyses of mixtures of whole blood with FITC- or RD1-labeled CD4, CD8, and CD3 antibodies compare well with literature values determined by other methods.     

A simple trogocytosis-based method to detect, quantify, characterize and purify antigen-specific live lymphocytes by flow cytometry, via their capture of membrane fragments from antigen-presenting cells

We have developed a method exploiting the phenomenon of trogocytosis to detect lymphocytes reacting specifically with target cells by flow cytometry. Trogocytosis is a process by which lymphocytes capture fragments of the plasma membrane from the antigen-presenting cells (APCs) expressing their cognate antigen. For this method, a label (such as a fluorescent lipid or biotin) is first incorporated in the membrane of APCs. These labeled cells are then co-cultured for a few hours with a population of cells containing the lymphocytes to be detected. After this period of stimulation, lymphocytes that have performed trogocytosis are identified by their acquisition of the label initially present on the APC membrane using flow cytometry. A major advantage of this method is its compatibility with the simultaneous detection of phenotypic and/or functional markers on the lymphocytes. Furthermore, cells can be recovered alive and active after detection of trogocytosis, and are therefore available for further characterization or even conceivably for therapeutic purposes.     

A dual fluorescence flow cytometric analysis of bacterial adherence to mammalian host cells

Flow cytometry has provided a powerful tool for analyzing bacteria-host cell associations. Established approaches have used bacteria, labeled either directly with fluorochromes or indirectly with fluorescently conjugated antibodies, to detect these associations. Although useful, these techniques are consistently unable to include all host cells in the analysis while excluding free, aggregated bacteria. This study describes a new flow cytometry method of assessing bacterial adherence to host cells based on direct fluorescent labeling of both bacteria and host cells. Eukaryotic host cells were labeled with PKH-26, a red fluorescent dye, and bacteria were labeled with fluorescein isothiocyanate, a green fluorescent dye. The red host cells were gated and the mean green fluorescence intensity (MFI) of these red cells was determined. We used MFI values obtained from control samples (unlabeled and labeled host cells with unlabeled bacteria) to eliminate contributions due to autofluorescence. The final MFI values represent fluorescence of host cells resulting from the adherent bacteria. Because all red fluorescent cells are analyzed, this method includes all the eukaryotic cells for analysis but excludes all free or aggregated bacteria that are not bound to target cells.     

Homing of in vitro-generated donor antigen-reactive CD4+ T lymphocytes to renal allografts is alpha 4 beta 1 but not alpha L beta 2 integrin dependent

The extravasation and sequestration of Ag-reactive T lymphocytes into vascularized organ allografts depend on a cascade of complex interactions among circulating lymphocytes, endothelial cells, and extracellular matrix proteins. Ag-activated donor-specific CD4 T cells are major initiators and effectors in the allograft rejection response. Interfering with the intragraft homing of activated CD4 T cells may represent a novel therapeutic approach in transplant recipients. We have developed a FACS-based short-term homing assay that allows tracing in vitro-generated Ag-reactive CD4 T cells after adoptive transfer in test rat recipients. Allospecific cell lines were preincubated with anti-alpha(4)beta(1) or anti-alpha(L)beta(2) mAb, because of enhanced expression of both integrin receptors after alloactivation. The pretreated Lewis(BN) lymphocytes were carboxyfluorescein diacetate succinimidyl ester labeled and adoptively transferred into Lewis rat recipients of Brown Norway kidney allografts. The injection of equal numbers of PKH-26-labeled untreated cells allowed quantitative comparison of both populations in the same animal. Ex vivo treatment with anti-alpha(4)beta(1) mAb diminished intragraft infiltration of adoptively transferred T cells by 85% in a donor-specific fashion. In contrast, treatment with anti-alpha(L)beta(2) mAb did not affect intragraft cell sequestration. Hence, blocking alpha(4)beta(1) integrin interactions represents a novel strategy in preventing local intragraft recruitment of Ag-reactive CD4 T cells in transplant recipients.     

Differentiation of lymphocytes in mouse bone marrow. I. Quantitative radioautographic studies of antiglobulin binding by lymphocytes in bone marrow and lymphoid tissues

The density of surface immunoglobulin on small lymphocytes in the bone marrow and other lymphoid tissues has been compared by radioautographic measurements of antiglobulin binding.Cell suspensions from CBA mice were exposed to ¹²⁵I-labeled rabbit anti-mouse globulin in a wide range of concentrations for 30 min at 0 °C. With increasing concentration of antiglobulin-¹²⁵I the percentage of labeled antiglobulin-binding small lymphocytes in spleen and lymph node suspensions reached well-defined plateau levels. Very few normal or cortisone-resistant thymus cells were labeled under identical conditions. Bone marrow small lymphocytes showed a linear increment in labeled cells throughout the antiglobulin-¹²⁵I dose range, their labeling intensity varied widely, and approximately one half remained unlabeled at high antiglobulin-¹²⁵I concentrations. In 6 wk-old congenitally athymic mice the bone marrow small lymphocyte labeling pattern resembled that in CBA mice, while nearly all (91–97%) small lymphocytes in lymph nodes, thoracic duct lymph and blood, and 75% of those in the spleen, became labeled under plateau conditions. Treatment of cells from 10 wk-old CBA mice with AKR anti-θ C3H serum and complement resulted in almost complete (93%) antiglobulin-labeling of residual small lymphocytes from the spleen but had little effect on bone marrow lymphocyte labeling. Under germfree conditions the proportion of antiglobulin-binding small lymphocytes was slightly elevated in all lymphoid tissues of CBA mice.The results demonstrate that many of the small lymphocytes in mouse bone marrow have readily detectable surface immunoglobulin molecules which vary considerably in density from cell to cell, while others neither have detectable surface immunoglobulin, nor are they θ-bearing, thymus-dependent or recirculating cells. The concept of bone marrow small lymphocytes as a maturing cell population is discussed.     

Monitoring lymphocyte proliferation in vitro and in vivo with the intracellular fluorescent dye carboxyfluorescein diacetate succinimidyl ester

This protocol outlines the carboxyfluorescein diacetate succinimidyl ester (CFSE) method for following the proliferation of human lymphocytes in vitro and mouse lymphocytes both in vitro and in vivo. The method relies on the ability of CFSE to covalently label long-lived intracellular molecules with the highly fluorescent dye, carboxyfluorescein. Following each cell division, the equal distribution of these fluorescent molecules to progeny cells results in a halving of the fluorescence of daughter cells. The CFSE labeling protocol described, which typically takes <1 h to perform, allows the detection of up to eight cell divisions before CFSE fluorescence is decreased to the background fluorescence of unlabeled cells. Protocols are outlined for labeling large and small numbers of human and mouse lymphocytes, labeling conditions being identified that minimize CFSE toxicity but maximize the number of cell divisions detected. An important feature of the technique is that division-dependent changes in the expression of cell-surface markers and intracellular proteins are easily quantified by flow cytometry.     

New immunolatex spheres: visual markers of antigens on lymphocytes for scanning electron microscopy

New immunochemical reagents consisting of antibodies bound to small latex spheres were used as visual markers for the detection and localization of cell surface antigens by scanning electron microscopy. Cross-linked latex spheres of various sizes from 300 to 3,4000 A in diameter were synthesized by aqueous emulsion copolymerization of methacrylate derivatives containing hydroxyl and carboxyl functional groups. Proteins and other molecules containing primary amino groups were covalently bonded to the acrylic spheres under a variety of mild conditions by the aqueous carbodiimide, cyanogen bromide, and glutaraldehyde methods. For use in the indirect immunochemical-labeling technique, goat antibodies directed against rabbit immunoglobulins were bonded to the spheres. These immunolatex reagents were shown to bind only to cells (red blood and lymphocytes) which had previously been sensitized with rabbit antibodies against cell surface antigens. Mouse spleen lymphocytes with exposed immunoglobulins on their surface (B cells) were labeled with these spheres and distinguished from unlabeled or T lymphocytes by scanning electron microscopy. The distribution of Ig receptors on lymphocytes was also studied using the spheres as visual markers. When lymphocytes were fixed with glutaraldehyde and subsequently labeled with the immunolatex reagents, a random distribution was observed by scanning electron microscopy; a patchy distribution was observed when unfixed lymphocytes were used. These results are consistent with studies using ferritin-labeled antibodies (S. De Petris and M. Raff. 1973. Nature [Lond.]. 241:257.) and support the view that Ig receptors on lymphocytes undergo translational diffusion. In addition to serving as visual markers for scanning electron microscopy, these latex spheres tagged with fluorescent or radioactive molecules have applications as highly sensitive markers for fluorescent microscopy and as reagents for quantitative studies of cell surface antigens and other receptors.     

A dual laser analysis of the migration of XRITC-labeled, FITC-labeled, and double-labeled lymphocytes in sheep

Substituted rhodamine isothiocyanate (XRITC) has been used to study lymphocyte migration in sheep. After being labeled in vitro with XRITC, lymphocytes appeared in the efferent lymph of single lymph nodes with the same kinetics as cells labeled with fluorescein isothiocyanate (FITC). The recovery of intravenously injected XRITC-labeled cells was followed in lymph for several days. The kinetics and recoveries were compared with data obtained using FITC, chromium-51, and indium-111. XRITC was found to be a suitable label and, using dual laser (argon and krypton) flow cytometry, it could be analyzed simultaneously with FITC. In addition, it was possible to relabel FITC-stained cells with XRITC after they were recovered in lymph. The migratory characteristics of such double-labeled cells were not different from single-labeled cells.     

Continuous flow magnetic cell fractionation based on antigen expression level

Cell separation is important in medical and biological research and plays an increasingly important role in clinical therapy and diagnostics, such as rare cancer cell detection in blood. The immunomagnetic labeling of cells with antibodies conjugated to magnetic nanospheres gives rise to a proportional relationship between the number of magnetic nanospheres attached to the cell and the cell surface marker number. This enables the potential fractionation of cell populations by magnetophoretic mobility (MM). We exploit this feature with our apparatus, the Dipole Magnet Flow Fractionator (DMFF), which consists of an isodynamic magnetic field, an orthogonally-oriented thin ribbon of cell suspension in continuous sheath flow, and ten outlet flows. From a sample containing a 1:1 mixture of immunomagnetically labeled (label+) and unlabeled (label-) cells, we achieved an increase in enrichment of the label+ cell fraction with increasing outlet numbers in the direction of the magnetic field gradient (up to 10-fold). The total recovery of the ten outlet fractions was 90.0+/-7.7%. The mean MM of label+ cells increased with increasing outlet number by up to a factor of 2.3. The postulated proportionality between the number of attached magnetic beads and the number of cell surface markers was validated by comparison of MM measured by cell tracking velocimetry (CTV) with cell florescence intensity measured by flow cytometry.     

A theory for analysis of cell populations with non-cycling S phase cells

Analyses of cell populations that have been labeled in vivo with analogs of thymidine that are incorporated by cells synthesizing DNA and then monitored over time by bivariate flow cytometry sometimes detect populations of cells that have S phase DNA content but that have not acquired label. Two alternative explanations for the lack of labeling are that either the cells were not exposed to the label or that the cells stopped DNA synthesis and ceased progression through S phase. To help determine which scenario is the more likely, a model has been devised for studying a population of cells that includes the possibility that cells in S phase will cease DNA synthesis. In this model, the initial fraction of unlabeled cells in S phase depends on two rates: the growth rate of the total population and the number of cells that cease progression through S phase per unit time. The model is used to analyze the changing quantities which can be measured by monitoring the population of cells over time and is used to estimate the two rates required to compute the initial fraction of unlabeled S phase cells. Thus, the initial fraction of unlabeled cells can be compared with that predicted by the population dynamics to determine whether one explanation for the failure of some cells to be labeled is preferable to the other, which in turn might offer information about tumor microvascular or cytologic properties.     

Use of a lectin as an enterocyte-specific cell surface marker for flow cytometric analysis of isolated native small intestinal epithelial cells

Little use has been made of flow cytometry in evaluating small intestinal epithelial cells. Obtaining pure epithelial cell populations devoid of peripheral blood contaminants and intraepithelial lymphocytes contributes to the difficulties encountered in flow cytometry studies. We have investigated the use of lectins as enterocyte specific cell markers using lectin histochemistry, and have identified one lectin, UEA-1, which binds exclusively and specifically to intestinal epithelial cell brush border. Additionally, we have exploited that specificity using flow cytometry and FITC-UEA-1 to identify and separate native intestinal epithelial cells from a mixed cell population isolated by mechanical vibration. This fluorescent-lectin technique is a unique and simple method to identify native small intestinal epithelial cells in a mixed cell population; it may be exploited by flow cytometric sorting of a pure population for biochemical study or as an enterocyte specific label for surface receptor flow cytometric studies in the research or clinical setting.     

Cultured tonsillar lymphocytes excrete [3H]thymidine labeled DNA and revert to resting state

Large tonsillar lymphocytes labeled with [3H]thymidine reverted to small lymphocytes with concomitant loss of [3H]DNA upon culturing. The decrease of labeled DNA content and size of large lymphocytes was demonstrated by flow cytometry and cell sorting. These observations suggest that stimulated lymphocytes may revert from their proliferative phase to resting phase by shedding 'extra'DNA under cell culture conditions. This released DNA is not due to cell damage and can be hybridized to chromosomal DNA.     

Fixation and long-term storage of human lymphocytes for surface marker analysis by flow cytometry

A method to preserve stained human lymphocytes for subsequent cell surface analysis by flow cytometry (FCM) is described. Cells stained with fluorescein isothiocyanate (FITC) and phycoerythrin (PE)-conjugated monoclonal antibodies and then fixed in 1% paraformaldehyde, followed by extensive washing and resuspension in 1% BSA medium, could be stored at 4 degrees C for at least 2 weeks prior to FCM analysis without significant alteration in the light scatter or fluorescence properties of the cells. Furthermore, the method was also suitable for analyzing lymphocytes that express T-cell activation markers in certain disease conditions. In addition, we have identified monoclonal antibody combinations that discriminate different lymphocyte subsets that are satisfactory for multiparameter analysis after 2 weeks of storage. This method should prove useful for enumerating lymphocyte subsets in field study sites remote from flow cytometry laboratories.     

Effect of shear stress on efferent lymph-derived lymphocytes in contact with activated endothelial monolayers

L.ymphocyte interactions with endothelial cells in microcirculation are an important regulatory step in the delivery of lymphocytes to peripheral sites of inflammation. In normal circumstances, the predicted wall shear stress in small venules range from 10 to 100 dyn/cm2. Attempts to measure the adhesion of lymphocytes under physiologic conditions have produced variable results, suggesting the importance of studying biologically relevant migratory lymphocytes. To quantify the effect of shear stress on these migratory lymphocytes, we used lymphocytes obtained from sheep efferent lymph ducts, defined as migratory cells, to perfuse sheep endothelial monolayers under conditions of flow. Quantitative cytomorphometry was used to distinguish cells in contact with the endothelial monolayers from cells in the flow stream. As expected, migratory cells in contact with the normal endothelial monolayer demonstrated flow velocities less than the velocity of cells in the adjacent flow stream. The flow velocities of these efferent lymphocytes were independent of cell size. To model the inflammatory microcirculation, lymphocytes were perfused over sequential endothelial monolayers to directly compare the velocity of cells in contact with cytokine-activated and unactivated control monolayers. The tumor necrosis factor and interleukin-1-activated endothelial monolayers marginally decreased cell velocities at 1.2 dyn/cm2 (3.6%), but significantly reduced cell velocities 0.3 dyn/cm2 (27.4%; P < 0.05). Similarly, the fraction of statically adherent lymphocytes decreased as shear stress increased to 1.2 dyn/cm2. These results suggest that typical wall shear stress in small venules. of the order of 20 dyn/cm2, are too high to permit adhesion and transmigration of migratory lymphocytes. Additional mechanisnis must be present in vivo to facilitate lymphocyte transmigration in the inflammatory microcircu-     

Immunospecific labeling of mouse lymphocytes in the scanning electron microscope

Bone marrow-derived (B) and thymus-derived (T) Balb/c mouse lymphocytes were identified in the scanning electron microscope (SEM) by the immunospecific attachment of one of several kinds of large-molecular-weight markers distinguishable in SEM. These markers (tobacco mosaic virus, keyhole limpet hemocyanin, bushy stunt virus, and bacteriophage T4) could be modified with hapten groups and linked with anti-hapten antibody, in an indirect (sandwich) scheme, to hapten-modified anti-cell-surface antibody bound to the cell surface. Hapten-modified antibodies to B cell antigens (goat anti-mouse-immunoglobulin) or to T cell antigens (rabbit anti-mouse brain) were employed to identify these two lymphoid cell types in unfractionated spleen, mesenteric lymph node, bone marrow, and thymus cell populations. The topography of B cells was always indistinguishable from that of T cells. No surface features were found to be unique to either cell type. In suspension, the majority of B and T cells had one or no microvilli regardless of the tissue source of the labeled cells. Cells in suspension that had microvilli (usually 10% of the total cell population) were always unlabeled. However, after cell contact with a glass surface, approximately half of both the B and T cell populations had a villous topography.     

Characterization of human T lymphocytes that express the C3b receptor

The presence of the C3b receptor (C3bR) on human peripheral blood T lymphocytes was recognized by the capacity of rabbit F(ab')2 anti-C3bR and tetramethylrhodamine isothiocyanate (TRITC)-conjugated goat F(ab')2 anti-rabbit F(ab')2 to stain 14.5 +/- 3.7% (mean +/- SEM; n = 5) of lymphocytes forming rosettes with sheep erythrocytes (E). The F(ab')2 anti-C3bR also blocked the capacity of peripheral blood lymphocytes stained with OKT11 to form rosettes with bovine E bearing C3b and immunoprecipitated a single membrane protein having a m.w. of approximately 250,000 from detergent lysates of 125I-labeled, purified T cells. Measurement by fluorescent flow cytometry of the quantitative expression of the C3bR indicated that T cells had slightly more antigenic sites/cell than did E and approximately 10-fold fewer sites than were present on B cells. The surface constituents of the peripheral blood T cells expressing the C3bR were assessed in an assay that employed simultaneously three markers: rosette formation with sheep E, TRITC staining with anti-C3bR and fluorescein isothiocyanate (FITC)-staining with a panel of monoclonal antibodies or with aggregated IgG. Among lymphocytes forming rosettes with sheep E and expressing the C3bR, 99.6 +/- 0.4%, 65.0 +/- 5.8%, 17.2 +/- 6.2%, and 15.3 +/- 5.0% of the cells expressed antigens detected by OKT3, OKT4, OKT8, and OKM1 monoclonal antibodies, respectively. Ninety-seven per cent of the C3bR-bearing T cells were also capable of specifically binding aggregated IgG, indicating the presence of Fc receptors for IgG (Fc gamma R) on these cells. The T cells expressing the C3bR had large nuclei, thin rims of basophilic cytoplasm and no azurophilic granules. Thus, the C3bR is present on some T cells, all of which have a typical lymphocyte morphology, the T3 antigen and the Fc gamma R.     

Prolonged recycling of internalized neurotrophins in the nerve terminal

BACKGROUND: Neurons require contact with their target tissue in order to survive and make correct connections. The retrograde axonal transport of neurotrophins occurs after receptor-mediated endocytosis into vesicles at the nerve terminal. However, the mechanism by which the neurotrophin signal is propagated from axon terminal to cell body remains unclear. METHODS: Retrograde axonal transport was examined using the transport of I(125)-labeled neurotrophins from the eye to sympathetic and sensory ganglia. The phenomena was further studied by adding rhodamine-labeled nerve growth factor (NGF) to cultures of dissociated sympathetic ganglia and the movement of organelles followed with the aid of video microscopy. RESULTS: I(125)-labeled neurotrophins were transported from the eye to the sympathetic and sensory ganglia. A 100-fold excess of unlabeled neurotrophin, administered up to 4 h after the labeled material, completely prevented accumulation of labeled neurotrophin in the ganglia. The effect was specific for the labeled neurotrophin as administration of a high concentration of a different neurotrophin failed to inhibit the transport. In dissociated cultures, we found rapid binding of label, to surface membrane receptors, followed by an accumulation of labeled vesicles in the growth cone. Incubation of these cultures with unlabeled NGF led to a rapid loss of label in the growth cones. CONCLUSIONS: These results suggest that there is a pool of internalized neurotrophin, in vesicles in the nerve terminal, which is in rapid equilibrium with the external environment. It is from this pool that a small fraction of the neurotrophin-containing vesicles is targeted for retrograde transport. Potential models for this system are presented.     

Simple method for comparing large numbers of flow cytometry histograms exemplified by analysis of the CD4 (T4) antigen and LDL receptor on human peripheral blood lymphocytes

We have developed a simple method for comparing the relative fluorescence intensity (FI) of flow cytometry histograms. It entails assessment of the FI (equivalent to the fluorescence-activated cell sorter (FACS) channel) of the 50th or 75th percentiles of either positively stained cells or the total cell population. We illustrate the method with dilution curves of 1) monoclonal antibodies against the T4 surface antigen of human peripheral blood lymphocytes and 2) fluorescent low density lipoprotein (LDL) binding to the human peripheral blood lymphocytes LDL receptor. We demonstrate the versatility of the method by characterizing the binding properties of fluorescent LDL to their receptors. Binding was shown to be specific and of high affinity, and to reach a steady state plateau at about 2 hr; the affinity of fluorescent LDL for the receptor was found to be two to three times higher than that of the unlabeled LDL.     

Kinetics of changes in peritoneal cell populations following acute inflammation

The kinetics of macrophage (M phi) recruitment to the peritoneum following the induction of acute inflammation by thioglycollate broth (TG) was evaluated after prelabeling resident M phi with the fluorescent cell tracking dye, PKH-1. Most of the PKH-1-labeled resident M phi disappeared from the recoverable peritoneal cell population within the first hour after injection of TG. This disappearance coincided with the inflammatory influx of neutrophils (PMNs) and was sustained for at least 5 days after administration of TG, although the PMN number had returned to resident levels by this time. PKH-1-labeled peritoneal M phi were observed again in most animals at 7 days after injection of TG. The number of labeled M phi recovered at 7 days was approximately twice the number of resident peritoneal M phi in control animals which did not receive the TG broth. These additional M phi may include progeny of either the resident M phi or other local M phi precursors, such as omental M phi, which were labeled by the PKH-1 injection.     

Reduced Expression of CD27 by Collagenase Treatment: Implications for Interpreting B Cell Data in Tissues

Surface markers have been used to identify distinct cell subpopulations and to delineate various stages of maturation or activation of lymphocytes. In particular CD27 is used for delineation of naïve and memory B cell populations, and is readily detected by flow cytometry. We here used flow cytometry to examine the expression of CD27 on lymphocytes isolated from various tissues of rhesus macaques, and found its expression was consistently low to absent on intestinal cell suspensions. However, immunohistochemistry revealed abundant CD27+ cells in intestinal tissue sections. Further investigation showed the marked loss of CD27 expression on processed intestinal cells was due to collagenase digestion of intestinal tissues, yet CD27 expression was recoverable within hours of cell isolation. By combining confocal microscopy, we confirmed that only a fraction of B cells express CD27, in contrast to expression on all T cells from tissues examined including the gut. Taken together, our results suggest that CD27 may be a memory marker for B cells, but not for T cells, since essentially all CD3 T cells expressed CD27. In summary, it is important to consider the influence of isolation procedures on cell surface expression of phenotypic markers, especially when examining tissue-resident lymphocytes by flow cytometry.