E. Michael Meyer

Nitric Oxide Scavenging by Red Blood Cell Microparticles and Cell-Free Hemoglobin as a Mechanism for the Red Cell Storage Lesion

Background— Intravascular red cell hemolysis impairs nitric oxide (NO)–redox homeostasis, producing endothelial dysfunction, platelet activation, and vasculopathy. Red blood cell storage under standard conditions results in reduced integrity of the erythrocyte membrane, with formation of exocytic microvesicles or microparticles and hemolysis, which we hypothesized could impair vascular function and contribute to the putative storage lesion of banked blood. Methods and Results— We now find that storage of human red blood cells under standard blood banking conditions results in the accumulation of cell-free and microparticle-encapsulated hemoglobin, which, despite 39 days of storage, remains in the reduced ferrous oxyhemoglobin redox state and stoichiometrically reacts with and scavenges the vasodilator NO. Using stopped-flow spectroscopy and laser-triggered NO release from a caged NO compound, we found that both free hemoglobin and microparticles react with NO about 1000 times faster than with intact erythrocytes. In complementary in vivo studies, we show that hemoglobin, even at concentrations below 10 &mgr;mol/L (in heme), produces potent vasoconstriction when infused into the rat circulation, whereas controlled infusions of methemoglobin and cyanomethemoglobin, which do not consume NO, have substantially reduced vasoconstrictor effects. Infusion of the plasma from stored human red blood cell units into the rat circulation produces significant vasoconstriction related to the magnitude of storage-related hemolysis. Conclusions— The results of these studies suggest new mechanisms for endothelial injury and impaired vascular function associated with the most fundamental of storage lesions, hemolysis.

Stromal vascular progenitors in adult human adipose tissue

The in vivo progenitor of culture‐expanded mesenchymal‐like adipose‐derived stem cells (ADSC) remains elusive, owing in part to the complex organization of stromal cells surrounding the small vessels, and the rapidity with which adipose stromal vascular cells adopt a mesenchymal phenotype in vitro. Immunohistostaining of intact adipose tissue was used to identify three markers (CD31, CD34, and CD146), which together unambiguously discriminate histologically distinct inner and outer rings of vessel‐associated stromal cells, as well as capillary and small vessel endothelial cells. These markers were used in multiparameter flow cytometry in conjunction with stem/progenitor markers (CD90 and CD117) to further characterize stromal vascular fraction (SVF) subpopulations. Two mesenchymal and two endothelial populations were isolated by high speed flow cytometric sorting, expanded in short term culture, and tested for adipogenesis. The inner layer of stromal cells in contact with small vessel endothelium (pericytes) was CD146+/α‐SMA+/CD90±/CD34−/CD31−; the outer adventitial stromal ring (designated supra adventitial‐adipose stromal cells, SA‐ASC) was CD146−/α‐SMA−/CD90+/CD34+/CD31−. Capillary endothelial cells were CD31+/CD34+/CD90+ (endothelial progenitor), whereas small vessel endothelium was CD31+/CD34−/CD90− (endothelial mature). Flow cytometry confirmed these expression patterns and revealed a CD146+/CD90+/CD34+/CD31− pericyte subset that may be transitional between pericytes and SA‐ASC. Pericytes had the most potent adipogenic potential, followed by the more numerous SA‐ASC. Endothelial populations had significantly reduced adipogenic potential compared with unsorted expanded SVF cells. In adipose tissue, perivascular stromal cells are organized in two discrete layers, the innermost consisting of CD146+/CD34− pericytes, and the outermost of CD146−/CD34+ SA‐ASC, both of which have adipogenic potential in culture. A CD146+/CD34+ subset detected by flow cytometry at low frequency suggests a population transitional between pericytes and SA‐ASC.

Maturation and trafficking of monocyte-derived dendritic cells in monkeys: implications for dendritic cell-based vaccines.

Human dendritic cells (DC) have polarized responses to chemokines as a function of maturation state, but the effect of maturation on DC trafficking in vivo is not known. We have addressed this question in a highly relevant rhesus macaque model. We demonstrate that immature and CD40 ligand-matured monocyte-derived DC have characteristic phenotypic and functional differences in vitro. In particular, immature DC express CC chemokine receptor 5 (CCR5) and migrate in response to macrophage inflammatory protein-1α (MIP-1α), whereas mature DC switch expression to CCR7 and respond exclusively to MIP-3β and 6Ckine. Mature DC transduced to express a marker gene localized to lymph nodes after intradermal injection, constituting 1.5% of lymph node DC. In contrast, cutaneous DC transfected in situ via gene gun were detected in the draining lymph node at a 20-fold lower frequency. Unexpectedly, the state of maturation at the time of injection had no influence on the proportion of DC that localized to draining lymph nodes, as labeled immature and mature DC were detected in equal numbers. Immature DC that trafficked to lymph nodes underwent a significant up-regulation of CD86 expression indicative of spontaneous maturation. Moreover, immature DC exited completely from the dermis within 36 h of injection, whereas mature DC persisted in large numbers associated with a marked inflammatory infiltrate. We conclude that in vitro maturation is not a requirement for effective migration of DC in vivo and suggest that administration of Ag-loaded immature DC that undergo natural maturation following injection may be preferred for DC-based immunotherapy.

Measurement of multiple drug resistance transporter activity in putative cancer stem/progenitor cells.

Multiple drug resistance, mediated by the expression and activity of ABC-transporters, is a major obstacle to antineoplastic therapy. Normal tissue stem cells and their malignant counterparts share MDR transporter activity as a major mechanism of self-protection. Although MDR activity is upregulated in response to substrate chemotherapeutic agents, it is also constitutively expressed on both normal tissue stem cells and a subset of tumor cells prior to the initiation of therapy, representing a built-in obstacle to therapeutic ratio. Constitutive and induced MDR activity can be detected in cellular subsets of disaggregated tissues, using the fluorescent substrates Rhodamine 123 and Hoechst 33342 for ABCB1 (also known as P-gp and MDR1) and ABCG2 (BCRP1). In this chapter, we will describe the complete procedure for the detection of MDR activity, including: (1) Preparing single-cell suspensions from tumor and normal tissue specimens; (2) An efficient method to perform cell surface marker staining on large numbers of cells; (3) Flow cytometer setup and controls; (4) Simultaneous measurement of Hoechst 33342 and Rhodamine123 transport; and (5) Data acquisition and analysis.

The cell-surface proteome of cultured adipose stromal cells.

In this technical note we describe a method to evaluate the cell surface proteome of human primary cell cultures and cell lines. The method utilizes the BD Biosciences lyoplate, a system covering 242 surface proteins, glycoproteins, and glycosphingolipids plus relevant isotype controls, automated plate‐based flow cytometry, conventional file‐level analysis and unsupervised K‐means clustering of markers on the basis of percent of positive events and mean fluorescence intensity of positive and total clean events. As an example, we determined the cell surface proteome of cultured adipose stromal cells (ASC) derived from 5 independent clinical isolates. Between‐sample agreement of very strongly expressed (n = 32) and strongly expressed (n =16) markers was excellent, constituting a reliable profile for ASC identification and determination of functional properties. Known mesenchymal markers (CD29, CD44, CD73, CD90, CD105) were among the identified strongly expressed determinants. Among other strongly expressed markers are several that are potentially immunomodulatory including three proteins that protect from complement mediated effects (CD46, CD55, and CD59), two that regulate apoptosis (CD77 and CD95) and several with ectoenzymatic (CD10, CD26, CD13, CD73, and CD143) or receptor tyrosine kinase (CD140b (PDGFR), CD340 (Her‐2), EGFR) activity, suggesting mechanisms for the anti‐inflammatory and tissue remodeling properties of ASC. Because variables are standardized for K‐means clustering, results generated using this methodology should be comparable between instrumentation platforms. It is widely generalizable to human primary explant cultures and cells lines and will prove useful to determine how cell passage, culture interventions, and gene expression and silencing affect the cell‐surface proteome.

Classification and Functional Characterization of Vasa Vasorum-Associated Perivascular Progenitor Cells in Human Aorta

Summary In the microcirculation, pericytes are believed to function as mesenchymal stromal cells (MSCs). We hypothesized that the vasa vasorum harbor progenitor cells within the adventitia of human aorta. Pericytes, endothelial progenitor cells, and other cell subpopulations were detected among freshly isolated adventitial cells using flow cytometry. Purified cultured pericytes were enriched for the MSC markers CD105 and CD73 and depleted of the endothelial markers von Willebrand factor and CD31. Cultured pericytes were capable of smooth muscle lineage progression including inducible expression of smooth muscle myosin heavy chain, calponin, and α-smooth muscle actin, and adopted a spindle shape. Pericytes formed spheroids when cultured on Matrigel substrates and peripherally localized with branching endothelial cells in vitro. Our results indicate that the vasa vasorum form a progenitor cell niche distinct from other previously described progenitor populations in human adventitia. These findings could have important implications for understanding the complex pathophysiology of human aortic disease.

Adipose stem cell function maintained with age: An intra-subject study of long-term cryopreserved cells

Background The progressive decline in tissue mechanical strength that occurs with aging is hypothesized to be due to a loss of resident stem cell number and function. As such, there is concern regarding use of autologous adult stem cell therapy in older patients. To abrogate this, many patients elect to cryopreserve the adipose stromal-vascular fraction (SVF) of lipoaspirate, which contains resident adipose stem cells (ASC). However, it is not clear yet if there is any clinical benefit from banking cells at a younger age. Objectives We performed a comparative analysis of SVF composition and ASC function from cells obtained under GMP conditions from the same three patients with time gap of 7 to 12 years. Methods SVF, cryobanked under good manufacturing practice (GMP) conditions, was thawed and cell yield, viability, and cellular composition were assessed. In parallel, ASC proliferation and efficiency of tri-lineage differentiation were evaluated. Results The results showed no significant differences existed in cell yield and SVF subpopulation composition within the same patient between harvest procedures 7 to 12 years apart. Further, no change in proliferation rates of cultured ASCs was found, and expanded cells from all patients were capable of tri-lineage differentiation. Conclusions By harvesting fat from the same patient at two time points, we have shown that despite the natural human aging process, the prevalence and functional activity of ASCs in an adult mesenchymal stem cell, is highly preserved. Level of Evidence 5.

CD34 affinity pheresis attenuates a surge among circulating progenitor cells following vascular injury

BACKGROUND Intimal hyperplasia (restenosis) is an exaggerated healing response leading to failure of half of vascular interventions. Increasing evidence suggests that circulating progenitor cells contribute to intimal pathology, and clinical studies have demonstrated a correlation between progenitor cells and the incidence of restenosis after cardiovascular interventions. The aims of this study were to characterize the temporal response of CD34+ progenitors following vascular injury in an ovine model and to evaluate an affinity pheresis approach to attenuate this response. METHODS An ovine model underwent either operative vascular injury or a nonvascular surgery (n = 3 per group). Blood was examined perioperatively over 2 weeks by flow cytometry. Next, an affinity pheresis approach to mediate systemic depletion of CD34 progenitors was designed. Custom agarose pheresis matrix with antibody affinity toward CD34 or an isotype control was evaluated in vitro. Next, following vascular injury, sheep underwent perioperative whole blood volume pheresis toward either the progenitor cell marker CD34 (n = 3) or an isotype control (n = 4) for 14 days. Animals were monitored by physical exam as well as complete blood counts. Cells recovered by pheresis were eluted and examined by flow cytometry. RESULTS Flow cytometry revealed a focal surge of circulating CD34 cells after vascular injury but not among surgical controls (P = .05). Toward the goal of an approach to attenuate the surge of CD34 progenitors, an evaluation of high-flow affinity matrix revealed efficacy in removal of progenitors from ovine blood in vitro. Next, a separate group of animals undergoing affinity pheresis after vascular injury was evaluated to mediate systemic depletion of CD34+ cells. Again, a surge of CD34+ cells was observed among isotype pheresis animals following vascular intervention but was attenuated over 20-fold by a CD34 pheresis approach (P = .029). Furthermore, an average of 77 million CD34-positive cells were eluted from the CD34 pheresis matrix. Despite multiple sessions of pheresis, complete blood counts remained essentially unchanged over 2 weeks. CONCLUSIONS Despite evidence suggesting a role for CD34+ circulating progenitor cells in restenotic pathology, the temporal pattern of CD34 progenitors after vascular injury has not been previously defined. We have demonstrated a surge among circulating CD34+ cells that appears confined to procedures involving vascular injury and that this event seems to occur early after vascular injury. We further conclude that CD34 affinity pheresis attenuates the surge. This approach for direct depletion of progenitors may have important implications for the study of progenitors in vascular restenosis.

Proteomic Profiling of Native Unpassaged and Culture-Expanded Mesenchymal Stromal Cells (MSC): Proteomic Profiling of MSC

Human culture‐expanded mesenchymal stromal cells (MSC) are being considered for multiple therapeutic applications because of their regenerative and anti‐inflammatory properties. Although a large number of MSC can be propagated from a small initial sample, several lines of evidence indicate that MSC lose their immunosuppressive and regenerative potency aftaer multiple passages. In this report, we use the FACSCAP Lyoplate proteomic analysis system to detect changes in cell surface protein expression of CD45−/CD31−/CD34−/CD73+/CD105+ stromal cells in unpassaged bone marrow (BM) and through 10 serial culture passages. We provide for the first time a detailed characterization of native unpassaged BM MSC (0.08% of BM mononuclear cells) as well as the changes that occur during the initial expansion. Adipogenic and osteogenic differentiative potential was determined though the serial passages and correlated with immunophenotypic changes and senescence. Among the most prominent were striking decreases in Fas ligand, CD98, CD205, and CD106, accompanied by a gain in the expression of CD49c, CD63, CD98, and class 1 and class 2 major histocompatibility complex (MHC) molecules. Other molecules that are down‐modulated with later passage include CD24, CD54, CD59, CD243/P‐glycoprotein, and CD273/PD‐L2. Early senescence, as defined by the loss of replicative capacity occurring with the loss of differentiative capacity, increase in CDKN2A p16, and increased time to confluence, was accompanied by loss of the motility‐associated metalloproteinase CD10 and the proliferation‐associated transferrin receptor CD71. Among the strongest statistical associations were loss of MAC‐inhibitory protein/CD59, loss of ICAM‐1/CD54, and increase in CDKN2A as a function of increasing passage, as well as increased CD10 expression with adipogenic and osteogenic capacities. The data provide a clear set of markers that can be used to assess MSC quality. We suggest that clinically relevant numbers of highly functional low passage MSC can be manufactured starting with large quantities of BM, which are readily available from cadaveric organ donors.

Flow cytometric detection of most proteins in the cell surface proteome is unaffected by trypsin treatment: Flow Cytometric Detection of Most Proteins in the Cell Surface Proteome is Unaffected by Trypsin Treatment

Flow cytometry is often performed on adherent cells or solid tissues that have been released from their growth substrate or disaggregated by enzymatic digestion. Although detection of strongly expressed cell surface proteins following such procedures indicates that many survive treatment with proteolytic enzymes, applications such as cell surface proteomics involve assessment of the expression of more than 200 proteins and it is important to know how to interpret negative results. To address this problem, we performed flow cytometry‐based cell surface proteomic analysis on two non‐adherent cell lines, THP1 and K562, after mock and authentic trypsin treatment, according to a widely used protocol to remove adherent cells (0.25% trypsin, 2.21 mM EDTA, 37°C, 5 min). In a single screening experiment, we examined the effect of treatment on mean fluorescence intensity and on the percent of positive cells and determined the false negative rate. Of 164 determinations that were ≥20% positive after mock treatment, 13 (7.9%) were <20% positive after trypsin treatment. Four proteins were chosen for time‐course studies (performed in triplicate), confirming initial sensitivity results but revealing significant variability in the magnitude of the trypsin effect. When trypsin sensitivity of individual proteins was examined as a function of the number of predicted high probability extracellular trypsin cleavage sites, we found that the markers that yielded false negatives all had high numbers of sites (>30), but even so, the majority of proteins with high numbers of trypsin sites could still be detected after mild trypsin treatment. We conclude that the great majority of cell surface proteins can be detected after mild trypsin treatment, but that negative results should not be over‐interpreted, due to the possibility of false negatives.