A rapid method for isolation of human mononuclear cells free of significant platelet contamination

Evaluation of quantitative biomarkers of aging in human PBMCs

Functional decline with age contributes significantly to the burden of disease in developed countries. There is growing interest in the development of therapeutic interventions which slow or even reverse aging. Time and cost constraints prohibit the testing of a large number of interventions for health and lifespan extension in model organisms. Cell-based models of aging could enable high throughput testing of potential interventions. Despite extensive reports in the literature of cell properties that correlate with donor age, few are robustly observed across different laboratories. This casts doubt on the extent that aging signatures are captured in cultured cells. We tested molecular changes previously reported to correlate with donor age in peripheral blood mononuclear cells (PBMCs) and evaluated their suitability for inclusion in a panel of functional aging measures. The tested measures spanned several pathways implicated in aging including epigenetic changes, apoptosis, proteostasis, and intracellular communication. Surprisingly, only two markers correlated with donor age. DNA methylation age accurately predicted donor age confirming this is a robust aging biomarker. Additionally, the apoptotic marker CD95 correlated with donor age but only within subsets of PBMCs. To demonstrate cellular rejuvenation in response to a treatment will require integration of multiple read-outs of cell function. However, building a panel of measures to detect aging in cells is challenging and further research is needed to identify robust predictors of age in humans.

Non-invasive and label-free identification of human natural killer cell subclasses by biophysical single-cell features in microfluidic flow

Natural killer (NK) cells are indicated as favorite candidates for innovative therapeutic treatment and are divided into two subclasses: immature regulatory NK CD56^bright and mature cytotoxic NK CD56^dim. Therefore, the ability to discriminate CD56^dim from CD56^bright could be very useful because of their higher cytotoxicity. Nowadays, NK cell classification is routinely performed by cytometric analysis based on surface receptor expression. Here, we present an in-flow, label-free and non-invasive biophysical analysis of NK cells through a combination of light scattering and machine learning (ML) for NK cell subclass classification. In this respect, to identify relevant biophysical cell features, we stimulated NK cells with interleukine-15 inducing a subclass transition from CD56^bright to CD56^dim. We trained our ML algorithm with sorted NK cell subclasses (≥86% accuracy). Next, we applied our NK cell classification algorithm to cells stimulated over time, to investigate the transition of CD56^bright to CD56^dim and their biophysical feature changes. Finally, we tested our approach on several proband samples, highlighting the potential of our measurement approach. We show a label-free way for the robust identification of NK cell subclasses based on biophysical features, which can be applied in both cell biology and cell therapy.

Optimized in vitro isolation of different subpopulation of immune cells from peripheral blood and comparative techniques for generation of monocyte-derived macrophages in small ruminants

Peripheral blood from healthy sheep (n = 3) and goats (n = 3) were employed to establish an efficient method for simultaneous isolation of peripheral blood mononuclear cells (PBMCs) and neutrophils and to standardize protocols for monocyte purification and generation of monocyte-derived macrophages (MDMs). In both species, a significantly enriched population of PBMCs, with higher purity and number of cells determined by flow cytometry, was achieved when processing through a density gradient a mixture of buffy-coat and red blood cell layer (RBC) in comparison to the use of just the buffy-coat (p <  0.05). Neutrophils could be subsequently isolated from the layer, located underneath PBMCs fraction with significant higher purity rates, higher than 85 % determined by flow cytometry, than those obtained with protocols without density gradients (< 60 %) (p <  0.05). This technique would allow the isolation of both cell populations from the same sample of blood. A pure cell population of monocytes, CD14⁺ cells, was purified from PBMCs when using immunomagnetic columns, which allow for 17 % (nº monocytes/nº PBMCs) of yield and high percentages of expression of CD14⁺ (88 %), MHC-II⁺ (91.5 %) and CD11b⁺ (94 %) established by flow cytometry. On the other hand, the classical and non-expensive purification of monocytes from PBMCs based on the adherence capacity of the former, allowed significantly lower yield of monocytes (4.6 %), with percentages of surface markers expression that dropped to 35 %, 65 % and 55 %, respectively (p < 0.001), suggesting the isolation of a mixed population of cells. The addition of GM-CSF to the culture, at concentration from 25 to 125 ng/mL, enhanced proportionally the number of MDMs generated compared to the absence of supplementation or the use of autologous serum from 5% to 20 %. However, purification of monocytes through the adherence method achieved higher yields of MDMs than those isolated through immunomagnetic columns in both species (p <  0.001). Under the conditions of this study, the use of centrifugation in density gradients allow for the simultaneous purification of PBMCs and neutrophils, with high purity of both populations, from the same sample of blood. The isolation of monocytes could be subsequently achieved through two different methods, i.e. based on immunomagnetic columns or adherence. The preference between both methods would depend on the necessities of the experiment, the initial sample with high purity of monocytes or a final population of MDMs required.

CD4+ versus CD8+ T-lymphocyte identification in an integrated microfluidic chip using light scattering and machine learning

T lymphocytes are a group of cells representing the main effectors of human adaptive immunity. Characterization of the most representative T-lymphocyte subclasses, CD4+ and CD8+, is challenging, but has a significant impact on clinical decisions. Up to now, T lymphocytes have been identified by quite complex cytometric assays, which are based on antibody labeling. However, a label-free approach based on pure biophysical evaluation at a single-cell level could enable the ability to distinguish between these subclasses. Here, we report a light-scattering approach, supported by accurate data mining, to evaluate cell biophysical properties on an integrated microfluidic chip. In order to perform single-cell optical analysis in viscoelastic fluids, such a chip is composed of mixing, alignment, readout and collection sections. In particular, we measured the cell dimensions, the refractive index of the cell nucleus, the refractive index of the cytosol, and the nucleus-to-cytosol ratio. Combining measurement of biophysical properties and machine learning allows us to both distinguish and count human CD4+ and CD8+ cells with an accuracy of 79%. An enhanced identification accuracy of 88% can be achieved by stimulating the cells with a selective anti-apoptotic protein, which results in increased biophysical differences between CD4+ and CD8+ cells. This approach has been successfully validated by analysis of samples that recapitulate physiological and pathological scenarios (CD4+/CD8+ ratios). The results are encouraging for the possible application of our approach in hematological clinical routines, as well as in diagnosis and follow-up of specific pathologies, such as human immunodeficiency virus (HIV) progression.

Single-cell screening of multiple biophysical properties in leukemia diagnosis from peripheral blood by pure light scattering

Histology and histopathology are based on the morphometric observations of quiescent cells. Their diagnostic potential could largely benefit from a simultaneous screening of intrinsic biophysical properties at single-cell level. For such a purpose, we analyzed light scattering signatures of individual mononuclear blood cells in microfluidic flow. In particular, we extracted a set of biophysical properties including morphometric (dimension, shape and nucleus-to-cytosol ratio) and optical (optical density) ones to clearly discriminate different cell types and stages. By considering distinctive ranges of biophysical properties along with the obtained relative cell frequencies, we can identify unique cell classes corresponding to specific clinical conditions (p < 0.01). Based on such a straightforward approach, we are able to discriminate T-, B-lymphocytes, monocytes and beyond that first results on different stages of lymphoid and myeloid leukemia cells are presented. This work shows that the simultaneous screening of only three biophysical properties enables a clear distinction between pathological and physiological mononuclear blood stream cells. We believe our approach could represent a useful tool for a label-free analysis of biophysical single-cell signatures.

Isolation of Endothelial Progenitor Cells from Healthy Volunteers and Their Migratory Potential Influenced by Serum Samples After Cardiac Surgery

Endothelial progenitor cells (EPCs) are recruited from the bone marrow under pathological conditions like hypoxia and are crucially involved in the neovascularization of ischemic tissues. The origin, classification and characterization of EPCs are complex; notwithstanding, two prominent sub-types of EPCs have been established: so-called "early" EPCs (subsequently referred to as early-EPCs) and late-outgrowth EPCs (late-EPCs). They can be classified by biological properties as well as by their appearance during in vitro culture. While "early" EPCs appear in less than a week after culture of peripheral blood-derived mononuclear cells in EC-specific media, late-outgrowth EPCs can be found after 2-3 weeks. Late-outgrowth EPCs have been recognized to be directly involved in neovascularization, mainly through their ability to differentiate into mature endothelial cells, whereas "early" EPCs express various angiogenic factors as endogenous cargo to promote angiogenesis in a paracrine manner. During myocardial ischemia/reperfusion (I/R), various factors control the homing of EPCs to regions of blood vessel formation. Macrophage migration inhibitory factor (MIF) is a chemokine-like pro-inflammatory and ubiquitously expressed cytokine and was recently described to function as key regulator of EPCs migration at physiological concentrations¹. Interestingly, MIF is stored in intracellular pools and can rapidly be released into the blood stream after several stimuli (e.g. myocardial infarction). This protocol describes a method for the reliable isolation and culture of early-EPCs from adult human peripheral blood based on CD34-positive selection with subsequent culture in medium containing endothelial growth factors on fibronectin-coated plates for use in in vitro migration assays against serum samples of cardiac surgical patients. Furthermore, the migratory influence of MIF on chemotaxis of EPCs compared to other well-known angiogenesis-stimulating cytokines is demonstrated.

Factor VIII and von Willebrand factor are ligands for the carbohydrate-receptor Siglec-5

BACKGROUND

Factor VIII (FVIII) and von Willebrand factor (VWF) circulate in plasma in a tight non-covalent complex, being critical to hemostasis. Although structurally unrelated, both share the presence of sialylated glycan-structures, making them potential ligands for sialic-acid-binding-immunoglobulin-like-lectins (Siglecs).

DESIGN AND METHODS

We explored the potential interaction between FVIII/VWF and Siglec-5, a receptor expressed in macrophages using various experimental approaches, including binding experiments with purified proteins and cell-binding studies with Siglec-5 expressing cells. Finally, Siglec-5 was overexpressed in mice via hydrodynamic gene transfer.

RESULTS

In different systems using purified proteins, saturable, dose-dependent and reversible interactions between a soluble Siglec-5 fragment and both hemostatic proteins were found. Sialidase treatment of VWF resulted in a complete lack of Siglec-5 binding. In contrast, sialidase treatment left interactions between FVIII and Siglec-5 unaffected. FVIII and VWF also bound to cellsurface exposed Siglec-5, as was visualized by classical immunostaining as well as by Duolinkproximity ligation assays. Co-localization of FVIII and VWF with early endosomal markers further suggested that binding to Siglec-5 is followed by endocytosis of the proteins. Finally, overexpression of human Siglec-5 in murine hepatocytes following hydrodynamic gene transfer resulted in a significant decrease in plasma levels of FVIII and VWF in these mice.

CONCLUSIONS

Our data indicate that FVIII and VWF may act as a ligand for Siglec-5, and that Siglec-5 may contribute to the regulation of plasma levels of the FVIII/VWF complex.

A method for the preparation of mononuclear cells devoid of platelet contamination and its application to the evaluation of putative alpha-receptors in normal and asthmatic subjects

Receptor studies of human mononuclear leukocytes (MNLs) are complicated by the presence of contaminating platelets which have common receptors. A method was devised to produce MNLs free of platelets (less than 1%) and consists of sequential Ficoll-Hypaque gradients, a BSA gradient and a washing step. Lack of platelet contamination was confirmed by the following criteria: (a) microscopic evaluation using fluorescent dyes showed less than 1% platelets; (b) PGE1 stimulation of the leukocyte membrane adenylate cyclase required addition of exogenous GTP while the platelet cyclase did not; (c) immunoblots of the cells and membranes using antibodies strongly reactive against platelet membranes showed no reactivity against MNL membranes; (d) [3H]yohimbine showed no binding in MNL membranes under conditions where substantial binding to platelets was detected. MNLs were viable as judged by dye exclusion. PHA stimulation of lymphocytes was unimpaired. Plasma membranes of MNLs were prepared by brief sonication and fractionation on a sucrose step gradient. Binding studies using 3H-DHE, an alpha-receptor ligand, revealed no binding in MNLs from normal subjects (n = 6). By contrast, studies on cells from subjects with mild asthma with medication appropriately withheld (n = 8) showed low levels of binding (60-300 fmol/10(6) cells). The subtype and functionality of the putative alpha-receptors are being further evaluated.

Effects of cell isolation procedures and radioligand selection on the characterization of human leukocyte beta-adrenergic receptors

Radioligand binding techniques are commonly used in the characterization of beta-adrenergic receptors on human peripheral leukocytes. Accurate interpretation of receptor binding parameters necessitates appropriate radioligand selection. In addition, cell isolation techniques should have minimal effect on the binding parameters of receptors. Our observation of curvilinear Scatchard plots with (-)-[125I]iodocyanopindolol (ICYP) resulted in a re-evaluation of this radioligand and the influence of cell isolation techniques on leukocyte beta-adrenergic receptor binding parameters. Membranes from mononuclear (MN) and polymorphonuclear (PMN) cells isolated by a standard procedure (Ficoll-Hypaque) resulted in biphasic Scatchard plots with ICYP in three of four subjects. In contrast, linear Scatchard plots were observed for ICYP binding to membranes from MN and PMN cells isolated from the same four subjects with an alternative procedure utilizing plasma Percoll. Competition and saturation binding assays with ICYP identified a high degree of nonspecific binding. Decreased stereoselectivity with (-)- and (+)-propranolol was observed with membranes from Ficoll-Hypaque cells as compared to plasma Percoll cells. Kinetic analysis with ICYP demonstrated apparent irreversible binding whether displacement was initiated with a beta-adrenergic receptor antagonist or agonist. These problems with ICYP prompted evaluation of an alternative radioligand, (-)-[125I]iodopindolol (IPIN); this radioligand demonstrated rapid and completely reversible binding, improved stereoselectivity, and low nonspecific binding. Using IPIN, Scatchard plots from three additional subjects were linear for both cell isolation procedures. Based on these observations, the preferred method of human leukocyte beta-adrenergic receptor analysis incorporates the plasma Percoll cell isolation technique and the radioligand IPIN.

In vitro and in vivo methods in immunotoxicology

One approach to assessment of the immunotoxic effects of drugs and chemicals upon the immune system is briefly described. Appropriate in vivo and in vitro methods and techniques are delineated. It is likely that programs implemented at individual institutions will be modified to specific circumstances.

Cell surface markers of the canine natural killer (NK) cell

Studies were performed to determine which of several cell surface markers are expressed on canine peripheral blood leukocyte (PBL) natural killer (NK) cells. Chromium-51 release assays showed a decrease in NK activity after depletion of PBL by carbonyl iron ingestion and adherence to IgG-antibody-coated ovine erythrocytes (EA gamma) and to IgM-antibody-complement-coated ovine erythrocytes (EA mu C). Effector cell adherence to and subsequent lysis of canine thyroid adenocarcinoma (CTAC) target cell monolayers provided direct visual identification of the putative canine NK cell. These surface immunoglobulin-negative cells, individually identified by their physical adherence to dead CTAC target cells, failed to form nonimmune rosettes with guinea pig erythrocytes or rosettes with EA mu or EA mu C. However, 39.0 +/- 4.2% of these adherent cells formed rosettes with EA gamma and 73.3 +/- 0.8% expressed the canine T-lymphocyte marker, Thy-1.

Human monocyte-derived mucus secretagogue

Human peripheral monocytes were stimulated with opsonized zymosan or protein A-containing Staphylococcus aureus to examine whether factors might be released that were capable of stimulating mucous glycoprotein release from cultured human airways, as has recently been described with human pulmonary macrophages. While the supernatant from monocytes exposed to opsonized zymosan or protein A-containing S. aureus caused an impressive activity was found in the control samples that were cultured in parallel and exposed to nonactivated zymosan or S. aureus that was deficient in protein A. The responsible factor was termed monocyte-derived mucus secretagogue (MMS). The maximum MMS release was reached 4-8 h after stimulation, and the amount of MMS released was dependent on the dose of opsonized zymosan added. Chromatographic analyses of MMS indicate that its molecular weight was approximately 2,000 and that the isoelectric point (pI) was 5.2, with a smaller second peak of 7.4 on isoelectric focusing. MMS itself was not detected in monocyte lysates, nor was it formed by monocytes treated with the protein synthesis inhibitor, cycloheximide, before exposure to activating particles. MMS was not a prostaglandin, could not be extracted into organic solvents, and is probably not an eicosanoid. Based on these observations, we conclude that stimulated human peripheral monocytes synthesize a small, acidic molecule, termed MMS, that is capable of stimulating human airways to secrete mucus and in nearly every respect is identical to pulmonary macrophage-derived MMS.

Characterization of histamine H-1 receptors on human mononuclear cells

Histamine H-1 receptors on peripheral human mononuclear cells were characterized by radioligand binding of the H-1 receptor antagonist [3H]pyrilamine to lymphocyte-rich preparations. Simultaneous computerized analyses of sixteen separate equilibrium-binding assays indicated the presence of two distinct classes of binding sites with dissociation constants (Kds) of 4 +/- 1 nM and 55 +/- 9 microM and binding capacities of 21 +/- 7 fmol and 117 +/- 15 pmol/million cells, respectively. Competition binding curves for displacement of [3H]pyrilamine binding by histamine receptor agonists and antagonists also indicated the presence of multiple binding sites for the H-1 receptor. Further, the ED50 values determined for histamine receptor agonists and antagonists were entirely consistent with the expected rank order of potency for interactions with H-1 receptors. Thus, human mononuclear cells have a large number of H-1 receptors that exhibit two distinct binding sites, and the Kds for these sites are within the range of histamine concentrations achieved either in physiologic states or after mast cell (or basophil) degranulation.

Heterogeneity in leukocyte preparations: effects on defining eicosanoid metabolism by human lymphocytes and monocytes

The capacity of preparations of human monocytes and lymphocytes to generate lipoxygenase products of arachidonic acid is largely attributable to platelet and occasionally to neutrophil contamination. Removal of platelets by several techniques eliminates the lipoxygenase activity of lymphocytes and substantially diminishes that of monocytes. The definition of profiles of lipoxygenation for each type of leukocyte will increase the meaning of studies of cell-cell interactions.

Two-dimensional separation of alpha-naphthyl acetate esterases in human leucocytes and platelets

Normal human leucocytes and platelets contain esterases which hydrolyse alpha-naphthyl acetate (alpha NA). Purified preparations from these cells were investigated by isoelectric focusing and subsequent polyacrylamide gradient gel electrophoresis at pH 9.0. Extractable alpha NA esterases were separated according to isoelectric point (pI) and molecular weight (MW). Monocytes, lymphocytes, granulocytes and platelets contain a unique pattern of alpha NA esterases, most of which can be inhibited by diisopropyl fluorophosphate (DFP; 0.1 mM). Their activity, however, is not affected by eserine (0.1 mM) or p-hydroxymercuribenzoate (1 mM). No protease activity of these enzymes was detected; it is likely that the majority constitute carboxylesterases (EC 3.1.1.1). Monocytes contain five alpha NA esterases which are additionally inhibited by bis(4-nitrophenyl)-phosphate (0.1 mM) and sodium fluoride (40 mM). PIs are in the range 5.7-6.2 and MWs are 145 000, 155 000, 250 000, 290 000 and 340 000. These enzymes are specific for monocytes. Platelets are characterized by a group of alpha NA esterases having pIs between 6.5 and 8.0, these corresponding to MWs ranging from 15 000 to 400 000.

Detection of beta-adrenergic receptors on rabbit mononuclear cells isolated free of significant contamination by other cell types

In order to study rabbit mononuclear cell surface receptors, it was necessary to develop a procedure to isolate mononuclear cell preparations that are free of significant contamination by other cell types, especially platelets. Centrifugation of dextran-sedimented, anti-coagulated whole blood through Hypaque (density 1.060) at 600 X g for 5 min at 22 degrees C eliminated greater than 93% of starting platelets. A second 5-min Hypaque centrifugation of Hypaque-Ficoll-isolated mononuclear cells (MNC) (approximately 80% lymphocytes) at 450 X g for 5 min at 22 degrees C reduced platelet contamination to less than one platelet per three MNC, and resulted in the overall removal of greater than 99.5% of starting platelets. These relatively pure MNC which were isolated in less than 2 hr were identified as having beta-adrenergic receptors by radioligand binding techniques using [125I]iodohydroxybenzylpindolol [( 125I]IHYP). Binding of [125I]IHYP to intact rabbit MNC was a saturable, stereospecific, and rapid process with a dissociation constant (KD) of 0.53 +/- 0.18 nM and a binding capacity of 3,461 +/- 235 sites/cell.