Berend Hooibrink

Ultrasensitive in situ visualization of active glucocerebrosidase molecules

Deficiency of glucocerebrosidase (GBA) underlies Gaucher disease, a common lysosomal storage disorder. Carriership for Gaucher disease has recently been identified as major risk for parkinsonism. Presently, no method exists to visualize active GBA molecules in situ. We here report the design, synthesis and application of two fluorescent activity-based probes allowing highly specific labeling of active GBA molecules in vitro and in cultured cells and mice in vivo. Detection of in vitro labeled recombinant GBA on slab gels after electrophoresis is in the low attomolar range. Using cell or tissue lysates, we obtained exclusive labeling of GBA molecules. We present evidence from fluorescence-activated cell sorting analysis, fluorescence microscopy and pulse-chase experiments of highly efficient labeling of GBA molecules in intact cells as well as tissues of mice. In addition, we illustrate the use of the fluorescent probes to study inhibitors and tentative chaperones in living cells.

CD103 is a marker for alloantigen-induced regulatory CD8(+) T cells

The αEβ7 integrin CD103 may direct lymphocytes to its ligand E-cadherin. CD103 is expressed on T cells in lung and gut and on allograft-infiltrating T cells. Moreover, recent studies have documented expression of CD103 on CD4+ regulatory T cells. Approximately 4% of circulating CD8+ T cells bear the CD103 molecule. In this study, we show that the absence or presence of CD103 was a stable trait when purified CD103− and CD103+CD8+ T cell subsets were stimulated with a combination of CD3 and CD28 mAbs. In contrast, allostimulation induced CD103 expression on ∼25% of purified CD103−CD8+ T cells. Expression of CD103 on alloreactive cells was found to be augmented by IL-4, IL-10, or TGF-β and decreased by addition of IL-12 to MLCs. The alloantigen-induced CD103+CD8+ T cell population appeared to be polyclonal and retained CD103 expression after restimulation. Markedly, in vitro-expanded CD103+CD8+ T cells had low proliferative and cytotoxic capacity, yet produced considerable amounts of IL-10. Strikingly, they potently suppressed T cell proliferation in MLC via a cell-cell contact-dependent mechanism. Thus, human alloantigen-induced CD103+CD8+ T cells possess functional features of regulatory T cells.

Productive HIV-1 infection of macrophages restricted to the cell fraction with proliferative capacity.

Retroviruses establish productive infection only in proliferating cells. Macrophages are often considered to be non‐proliferating in vitro yet are susceptible to HIV‐1 infection. This has led to the conclusion that HIV‐1 can establish infection independent of host cell proliferation. We here report that a small proportion of macrophages does have proliferative capacity. A comparable small fraction of monocyte derived macrophages (MDM) supported productive HIV‐1 infection as demonstrated in limiting dilution culture. Fluorescence activated cell sorting on the basis of incorporation of BrdUrd, a thymidine analog, and subsequent PCR analysis revealed the presence of proviral DNA only in the BrdUrd positive cell fraction with DNA synthesizing activity. To identify which phase of cell cycle is required for establishment of productive infection, growth arrest in G1 or G1/S phase prior to inoculation was performed. gamma‐Irradiation, which arrests primary cells in G1, prevented both cell proliferation and establishment of productive infection in MDM. Treatment of MDM with aphidicolin, a specific inhibitor of DNA polymerase alpha and delta which arrests cells in G1/S phase of the cell cycle, also inhibited DNA synthesis but did not prevent establishment of productive infection which is completely analogous to observations in T cells. Our data thus indicate that not cell division itself but cellular conditions that coincide with cell proliferation are apparently indispensable for establishment of productive infection.

Interferon-γ impairs proliferation of hematopoietic stem cells in mice

Balancing the processes of hematopoietic stem cell (HSC) differentiation and self-renewal is critical for maintaining a lifelong supply of blood cells. The bone marrow (BM) produces a stable output of newly generated cells, but immunologic stress conditions inducing leukopenia increase the demand for peripheral blood cell supply. Here we demonstrate that the proinflammatory cytokine interferon-γ (IFN-γ) impairs maintenance of HSCs by directly reducing their proliferative capacity and that IFN-γ impairs restoration of HSC numbers upon viral infection. We show that IFN-γ reduces thrombopoietin (TPO)-mediated phosphorylation of signal transducer and activator of transcription (STAT) 5, an important positive regulator of HSC self-renewal. IFN-γ also induced expression of suppressor of cytokine signaling (SOCS) 1 in HSCs, and we demonstrate that SOCS1 expression is sufficient to inhibit TPO-induced STAT5 phosphorylation. Furthermore, IFN-γ deregulates expression of STAT5-mediated cell-cycle genes cyclin D1 and p57. These findings suggest that IFN-γ is a negative modulator of HSC self-renewal by modifying cytokine responses and expression of genes involved in HSC proliferation. We postulate that the occurrence of BM failure in chronic inflammatory conditions, such as aplastic anemia, HIV, and graft-versus-host disease, is related to a sustained impairment of HSC self-renewal caused by chronic IFN-γ signaling in these disorders.

Cytolytic mechanisms and expression of activation-regulating receptors on effector-type CD8+CD45RA+CD27- human T cells.

Circulating CD8+ T cells with a CD45RA+CD27− phenotype resemble cytolytic effector cells because they express various cytolytic mediators and are able to execute cytotoxicity without prior stimulation in vitro. We here demonstrate that CD8+CD45RA+CD27− T cells can use both granule exocytosis and Fas/Fas ligand pathways to induce apoptosis in target cells. The availability of these cytolytic mechanisms in circulating T cells suggests that the activity of these cells must be carefully controlled to prevent unwanted tissue damage. For this reason, we analyzed the expression of surface receptors that either enhance or inhibit T cell function. Compared with memory-type cells, effector cells were found to express normal levels of CD3ε and TCRζ and relatively high levels of CD8. CTLA-4 was absent from freshly isolated effector cells, whereas a limited number of unstimulated memory cells expressed this molecule. In line with recent findings on CD8+CD28− T cells, CD45RA+CD27− T cells were unique in the abundant expression of NK cell-inhibitory receptors, both of Ig superfamily and C-type lectin classes. Binding of NK cell-inhibitory receptors to classical and nonclassical MHC class I molecules may inhibit the activation of the cytolytic machinery induced by either Ag receptor-specific or nonspecific signals in CD8+CD45RA+CD27− T cells.

High IL-13 production by human neonatal T cells: neonate immune system regulator?

Neonates are highly susceptible to diseases and display biased type 2 immune responses, although no skewing to type 2 cytokines has been reported. In view of the emerging importance of IL‐13 in type 2 inflammatory responses and clinical allergy, we analyzed IL‐13 production by neonatal T cells. We found that, mainly CD8 T cells produced high levels of IL‐13, while producing low levels ofIL‐4, IL‐10 and IFN‐γ, upon primary and secondary stimulation. Our results point towards a possible immunoregulatory role of CD8 T cells in neonate responses. Moreover, they suggest that the abundance of IL‐13 in the neonate immune system might account for the type 2 bias in neonates, providing a basis for the high disease susceptibility of newborns, for instance to allergic diseases.

Properties of murine CD8+CD27– T cells

In humans, loss of CD27 expression is associated with the stable acquisition of effector functions by CD8+ T cells. We found that murine CD8+CD27– T cells were confined to the primed CD62Ldull/–CD44brightCCR7– T cell population. CD8+CD27– T cells were absent from lymph nodes but could be found in blood, spleen and in non‐lymphoid organs such as lung and liver. Late after primary influenza virus infection, low percentages of antigen‐specific CD27– cells emerged in the lung and spleen. After recovery from secondary influenza virus infection, high percentages of influenza‐specific CD27– T cells were found in the lung and the loss of CD27 on lung CD8+ T cells coincided with high granzyme B expression. After murine cytomegalovirus infection, loss of CD27 expression on virus‐specific CD8+ T cell populations was sustained and especially marked in liver and lung. We suggest that in mice, CD27 is lost from CD8+ T cells only after repetitive antigenic stimulation. Moreover, the high expression of both granzyme B and perforin in the CD27– T cells suggests that the lack of CD27 on murine CD8+ T cells can be used to identify memory T cells with expression of cytotoxic effector molecules.

Mitochondrial oxygen tension within the heart

By using a newly developed optical technique which enables non-invasive measurement of mitochondrial oxygenation (mitoPO(2)) in the intact heart, we addressed three long-standing oxygenation questions in cardiac physiology: 1) what is mitoPO(2) within the in vivo heart?, 2) is mitoPO(2) heterogeneously distributed?, and 3) how does mitoPO(2) of the isolated Langendorff-perfused heart compare with that in the in vivo working heart? Following calibration and validation studies of the optical technique in isolated cardiomyocytes, mitochondria and intact hearts, we show that in the in vivo condition mean mitoPO(2) was 35+/-5 mm Hg. The mitoPO(2) was highly heterogeneous, with the largest fraction (26%) of mitochondria having a mitoPO(2) between 10 and 20 mm Hg, and 10% between 0 and 10 mm Hg. Hypoxic ventilation (10% oxygen) increased the fraction of mitochondria in the 0-10 mm Hg range to 45%, whereas hyperoxic ventilation (100% oxygen) had no major effect on mitoPO(2). For Langendorff-perfused rat hearts, mean mitoPO(2) was 29+/-5 mm Hg with the largest fraction of mitochondria (30%) having a mitoPO(2) between 0 and 10 mm Hg. Only in the maximally vasodilated condition, did the isolated heart compare with the in vivo heart (11% of mitochondria between 0 and 10 mm Hg). These data indicate 1) that the mean oxygen tension at the level of the mitochondria within the heart in vivo is higher than generally considered, 2) that mitoPO(2) is considerably heterogeneous, and 3) that mitoPO(2) of the classic buffer-perfused Langendorff heart is shifted to lower values as compared to the in vivo heart.

Immune activation modulates hematopoiesis through interactions between CD27 and CD70.

The differentiation of hematopoietic stem cells into mature blood cell lineages is tightly regulated. Here we report that CD27, which is expressed on stem and early progenitor cells in bone marrow, can be important in this process. Deletion of CD27 increased the myeloid colony–forming potential of stem and early progenitor cells and enhanced B lymphoid reconstitutive capacity in competitive transplantation experiments. Conversely, stimulation of CD27+ progenitor cells with CD70, the unique ligand for CD27, inhibited colony-forming potential in vitro and lymphocyte outgrowth in vivo. As CD70 is expressed only on activated immune cells, we suggest that CD27 triggering on early progenitor cells provides a negative feedback signal to leukocyte differentiation during immune activation.

Myeloid blasts are the mouse bone marrow cells prone to differentiate into osteoclasts

Cells of the myeloid lineage at various stages of maturity can differentiate into multinucleated osteoclasts. Yet, it is unclear which developmental stages of this lineage are more prone to become osteoclasts than others. We investigated the osteoclastogenic potential of three successive stages of myeloid development isolated from mouse bone marrow. Early blasts (CD31hi/Ly‐6C–), myeloid blasts (CD31+/Ly‐6C+), and monocytes (CD31–/Ly‐6Chi), as well as unfractionated marrow cells, were cultured in the presence of M‐CSF and receptor activator of NF‐κB ligand (RANKL), and the differentiation toward multinucleated cells and their capacity to resorb bone was assessed. Myeloid blasts developed rapidly into multinucleated cells; in only 4 days, maximal numbers were reached, whereas the other fractions required 8 days to reach maximal numbers. Bone resorption was observed after 6 (myeloid blasts and monocyte‐derived osteoclasts) and 8 (early blast‐derived osteoclasts) days. This difference in kinetics in osteoclast‐forming capacity was confirmed by the analysis of osteoclast‐related genes. In addition, the myeloid blast fraction proved to be most sensitive to M‐CSF and RANKL, as assessed with a colony‐forming assay. Our results show that osteoclasts can develop from all stages of myeloid differentiation, but myeloid blasts are equipped to do so within a short period of time.