Morphological types of horizontal cell in the retina of the domestic cat.

Two morphologically distinct types of horizontal cell are described from Golgi-stained whole mounts of the cat retina. They are referred to as A-type and B-type cells. The two types differ in their dendritic branching pattern, their overall size and the absence or presence of an axon. At every retinal position the dendrites of B-type cells branch more densely and overlap each other more frequently than do the dendrites of A-type cells. At equivalent retinal positions the dendritic field size of A-type cells is greater than that of B-type cells by a factor of about 1.5. Only B-type cells have an axon, which branches at the end into a large axon terminal system. The axons have no preferred direction of orientation. The stain-ability of horizontal cells by different Golgi methods is discussed.     

Dendritic cells and host resistance to infection

Host defence against infection requires an integrated response of both the innate and adaptive arms of the immune system. Emerging data indicate that dendritic cells contribute an essential part to the initiation and regulation of adaptive immunity. Dendritic cells guard the sites of pathogen entry to the host and are uniquely suited to detect and capture invading microbes. Upon recognition of microbial structures and appropriate activation, a maturation programme is triggered and dendritic cells migrate to lymphoid organs to stimulate a primary cell-mediated immune response. Moreover, dendritic cells play a critical role in shaping the emerging response, thereby controlling the course of infection. They can discriminate between various types of microorganisms and are capable of producing different cytokines in response to different microbial stimuli. On the other hand, pathogens developed numerous strategies to evade and subvert dendritic cell functions. Elucidating the interactions of dendritic cells with microbial pathogens may lead to novel strategies for combating infectious diseases by dendritic cell-based vaccination and immunotherapy. This review highlights recent advances in our knowledge of the unique role of dendritic cells in counteracting microbial infections.     

Macropinocytosis

Macropinocytosis is a form of endocytosis that accompanies cell surface ruffling. It is distinct in many ways from the better characterized micropinocytosis, which includes clathrin-coated vesicle endocytosis and small uncoated vesicles. Because macropinosomes are relatively large, they provide an efficient route for non-selective endocytosis of solute macromolecules. This route may facilitate MHC-class-II-restricted antigen presentation by dendritic cells. Because the ruffling that leads to macropinocytosis is regulated, it has been exploited by some pathogenic bacteria as a novel route for entry into cells.     

RASSF1A suppresses the activated K-Ras-induced oxidative DNA damage

Dendritic cells are the most potent antigen presenting cells responsible for the development of immune responses in cancer. However, it is known that the function of dendritic cells in tumor-bearing hosts is severely compromised. Our previous studies demonstrated that the defects in dendritic cell function are due, to a large extent, to the accumulation of high amounts of lipids – predominantly triglycerides – in a substantial proportion of dendritic cells in tumor-bearing mice and patients with cancer. The dendritic cells accumulation of lipids is likely associated with their up-regulation of a scavenger receptor A. This receptor is primarily responsible for uptake of modified lipids. Here, by using different versions of liquid chromatography–mass spectrometry, we identified several molecular species of oxygenated lipids in plasma of tumor-bearing animals that may be responsible for their uptake and accumulation by dendritic cells via scavenger receptor A-dependent pathway – the effect that may be associated with the loss of dendritic cell’s immune surveillance function in cancer.     

Investigation into the prevalence of a novel dendritic‐like cell subset in vivo

A novel dendritic‐like cell subset termed L‐DC was recently identified in murine spleen based on marker expression of a homogeneous cell population derived from long‐term culture of neonatal spleen. The function of L‐DC is distinct from other splenic dendritic and myeloid cell subsets because of their high endocytic capacity and their ability to cross‐present antigen to CD8⁺ T cells. This paper shows the subset to be unique to spleen and blood, with a similar, but possibly functionally distinct subset also present in bone marrow. The prevalence of the subset is low; ~6% of all dendritic and myeloid cells in the spleen and ~5% in blood. However, they are a distinct cell type on the basis of marker expression, and endocytic and T‐cell stimulatory capacity. Attempts to identify an enriched population of these cells in mutant mouse strains with reported increases in myelopoiesis showed either a lack of L‐DC or an altered phenotype reflective of the phenotype of the mouse strain.     

The function and origin of follicular dendritic cells

Follicular dendritic cells (dendritic reticular cells) in germinal centres bind antigen-antibody complexes via C3 receptors and retain the complexes at their surface for long periods of time. The follicular dendritic cells (FDC) are distinct from macrophages and from dendritic cells found in T-dependent areas, and are not derived from bone marrow stem cells. On histological evidence it has been proposed that they are derived from reticulum cells. Complexes are probably transported to FDC by a subpopulation of B cells in the marginal zone. Binding of complexes to FDC causes germinal centre enlargement and is a very efficient, and possibly essential stimulus to the generation of B memory cells which recognize epitopes on antigen or antibody in the complexes. An hypothesis is discussed which draws together these observations and suggests that antigen on FDC plays a central role in control of humoral immunity.     

Analysis of Subcellularly Localized mRNAs Using in Situ Hybridization,mRNA Amplification,and Expression Profiling

Targeting of mRNAs to distinct subcellular regions occurs in all polarized cells. The mechanisms by which RNA transport occurs are poorly understood. With the advent of RNA amplification methodologies and expression profiling it is now possible to catalogue the RNAs that are targeted to particular subcellular regions. In particular, neurons are polarized cells in which dendrites receive signals from presynaptic neurons. Upon stimulation (information receipt) the dendrite processes the information such that an immediate dendritic response is generated as well as a longer-term somatic response. The integrated cellular response results in a signal that can be propagated through the axon to the next post-synaptic neuron. Much previous work has shown that mRNAs can be localized in dendrites and that local translation in dendrites can occur. In this chapter the methods for analysis of RNAs that are localized to dendrites are reviewed and a partial list of dendritically localized RNAs is presented. This information may be useful in identifying RNA regulatory regions that are responsible for specifying rate of RNA transport and the dendritic sites at which targeted RNAs dock so that they can be translated.     

The effect of visual deprivation upon the basal dendrites of Meynert cells in the striate cortex of the monkey

The basal dendrites of Meynert cells in the striate cortex have been studied with the Golgi method in the brains of monkeys that had been reared for varying periods with the eyelids closed over one eye. The lengths and arrangement of the dendrites were compared with those in normal brains. In the visually deprived brain almost half of the cells had basal dendrites that were apparently normal with the dendritic fields in the form of an ellipse and the long axes parallel to the direction of the ocular dominance bands. The other cells had dendritic fields that have rarely been seen in normal material and two distinct types could be recognized. The 'lop-sided' cell had an ellipsoidal dendritic field with the major axis parallel to the ocular dominance bands, but the extents of the dendrites along the minor axis were very asymmetric; the ratio of the means of the long and short arms of the minor axis of the 'lop-sided' cell is 2.3:1 compared with 1.1:1 in normal brains. The 'perpendicular' type of cell also had an ellipsoidal dendritic field but the relation of the major and minor axes to the direction of the ocular dominance bands was the reverse of the normal cell, with the long axis of the ellipse being aligned perpendicular to the bands. 'Lop-sided' cells formed approximately 18% of the total of Meynert cells studied and the 'perpendicular' 32%. The proportion of the cells with abnormal basal dendritic fields, and particularly the 'perpendicular', increased with longer durations of eyelid closure. It is suggested that the alterations in the dendritic fields of the 'lop-sided' and 'perpendicular' cells may be correlated with the changes in width of the ocular dominance bands that are known to occur after monocular eyelid suture.     

Nonphagocytic dendritic cells are effective accessory cells for anti-mycobacterial responses in vitro

The accessory cell requirements for a given T cell response may be examined in vitro by using highly purified lymph node T cells. We have examined the capacity of different antigen-presenting cells to stimulate proliferation of Mycobacterium tuberculosis-primed T cells when the antigenic challenge is either soluble or particulate in nature. By titrations of cell number and antigen concentration, it was shown that dendritic cells are not only extremely efficient at presenting soluble mycobacterial antigen compared with various macrophage populations, but also that they are capable of presenting whole mycobacteria. Because phagocytosis of mycobacteria does not occur with these cells, we suggest that processing of antigen by dendritic cells may be initiated at the plasma membrane. Because macrophages are not essential for this in vitro response, a role for dendritic cells in antibacterial immunity in vivo is implicated.     

Dynamics of dendritic cell development from precursors maintained in stroma-dependent long-term cultures

Two distinct subsets of dendritic cells are produced within the non-adherent cell population of the stroma-dependent long-term culture system. These are the small subset containing dendritic cell precursors and their progeny, large long-term culture-dendritic cells, which resemble immature CD11c+CD11b+MHCIIloCD8alpha- dendritic cells. The replicative and developmental potential of cells produced in long-term culture were investigated as a model for production of dendritic cells from progenitors. Cell proliferation and apoptosis were examined by labelling with bromodeoxyuridine and Annexin-V, respectively. The developmental potential of cells was analysed following transfer on to stromal monolayers or into in vitro colony and transwell assays. Results demonstrate that small long-term culture-dendritic cells are stromal cell-dependent. In the absence of stroma, they become apoptotic and die. Furthermore, direct contact with stromal cells is necessary for the differentiation and proliferation of small precursor cells. The small cell subset contains no long-term self-renewing cells, but instead appears to contain cells committed to developing into large long-term culture dendritic cells. The large long-term culture dendritic cell subset also contains dividing cells. Survival of large long-term culture-dendritic cells is dependent on soluble stroma-derived factor(s) and not direct contact with the stromal layer. All data suggest that the long-term culture system supports dendritic cell development from a self-renewing progenitor population resident within the stroma that gives rise to committed dendritic cell precursors and immature dendritic cells.     

In vivo imaging reveals dendritic targeting of laminated afferents by zebrafish retinal ganglion cells

Targeting of axons and dendrites to particular synaptic laminae is an important mechanism by which precise patterns of neuronal connectivity are established. Although axons target specific laminae during development, dendritic lamination has been thought to occur largely by pruning of inappropriately placed arbors. We discovered by in vivo time-lapse imaging that retinal ganglion cell (RGC) dendrites in zebrafish show growth patterns implicating dendritic targeting as a mechanism for contacting appropriate synaptic partners. Populations of RGCs labeled in transgenic animals establish distinct dendritic strata sequentially, predominantly from the inner to outer retina. Imaging individual cells over successive days confirmed that multistratified RGCs generate strata sequentially, each arbor elaborating within a specific lamina. Simultaneous imaging of RGCs and subpopulations of presynaptic amacrine interneurons revealed that RGC dendrites appear to target amacrine plexuses that had already laminated. Dendritic targeting of prepatterned afferents may thus be a novel mechanism for establishing proper synaptic connectivity.     

Tissue distribution of the C3d/EBV-receptor: CD21 monoclonal antibodies reactive with a variety of epithelial cells,medullary thymocytes,and peripheral T-cells

Summary The CD21 antigen has been described to represent CR2, the receptor for the complement fragment C3d and also the receptor for the Epstein-Barr virus (EBV). Monoclonal antibodies B2, HB5, and B-ly4 belong to the CD21 cluster, recognizing different epitopes of the CD21-molecule. Immunohistology of lymphoid tissues employing these antibodies showed the known staining of B cells and dendritic reticulum cells. Surprisingly, B2, but not HB5 or B-ly4, stained a distinct spot in the cytoplasm of a major proportion of medullary thymocytes, in almost all peripheral blood lymphocytes, and in a substantial amount of cells in T-cell areas of peripheral lymphoid tissues. This distinct cytoplasmic B2 staining was confirmed by immuno-electronmicroscopy. A similar B2+ cytoplasmic dot was observed in B-lymphoblastic lymphomas. Staining of non-lymphoid tissues showed reactivity with all three CD21 mAb with epithelial cells of skin, lung, esophagus, jejunum, colon, pancreas, tonsil, adrenal cortex, renal tubuli, and parotid glands, and with hepatocytes and tongue muscle. In addition, endothelial cells of small vessels showed B2 staining. One possible explanation for our results is, that apart from the presence of B cells and follicular dendritic cells, a CD21-molecule may be expressed by other cell types. However, a maybe more likely explanation may be that the recognized epitopes are not exclusively associated with the C3d/EBV-receptor, but also with other structures. In particular should the possibility be recognized of cross-reactivity with CR2-related proteins, encoded by the large gene family, to which CR2 belongs.     

Tissue distribution of the C3d/EBV-receptor: CD21 monoclonal antibodies reactive with a variety of epithelial cells, medullary thymocytes, and peripheral T-cells

The CD21 antigen has been described to represent CR2, the receptor for the complement fragment C3d and also the receptor for the Epstein-Barr virus (EBV). Monoclonal antibodies B2, HB5, and B-ly4 belong to the CD21 cluster, recognizing different epitopes of the CD21-molecule. Immunohistology of lymphoid tissues employing these antibodies showed the known staining of B cells and dendritic reticulum cells. Surprisingly, B2, but not HB5 or B-ly4, stained a distinct spot in the cytoplasm of a major proportion of medullary thymocytes, in almost all peripheral blood lymphocytes, and in a substantial amount of cells in T-cell areas of peripheral lymphoid tissues. This distinct cytoplasmic B2 staining was confirmed by immuno-electronmicroscopy. A similar B2+ cytoplasmic dot was observed in B-lymphoblastic lymphomas. Staining of non-lymphoid tissues showed reactivity with all three CD21 mAb with epithelial cells of skin, lung, esophagus, jejunum, colon, pancreas, tonsil, adrenal cortex, renal tubuli, and parotid glands, and with hepatocytes and tongue muscle. In addition, endothelial cells of small vessels showed B2 staining. One possible explanation for our results is, that apart from the presence of B cells and follicular dendritic cells, a CD21-molecule may be expressed by other cell types. However, a maybe more likely explanation may be that the recognized epitopes are not exclusively associated with the C3d/EBV-receptor, but also with other structures. In particular should the possibility be recognized of cross-reactivity with CR2-related proteins, encoded by the large gene family, to which CR2 belongs.     

Tiling of the Drosophila epidermis by multidendritic sensory neurons

Insect dendritic arborization (da) neurons provide an opportunity to examine how diverse dendrite morphologies and dendritic territories are established during development. We have examined the morphologies of Drosophila da neurons by using the MARCM (mosaic analysis with a repressible cell marker) system. We show that each of the 15 neurons per abdominal hemisegment spread dendrites to characteristic regions of the epidermis. We place these neurons into four distinct morphological classes distinguished primarily by their dendrite branching complexities. Some class assignments correlate with known proneural gene requirements as well as with central axonal projections. Our data indicate that cells within two morphological classes partition the body wall into distinct, non-overlapping territorial domains and thus are organized as separate tiled sensory systems. The dendritic domains of cells in different classes, by contrast, can overlap extensively. We have examined the cell-autonomous roles of starry night (stan) (also known as flamingo (fmi)) and sequoia (seq) in tiling. Neurons with these genes mutated generally terminate their dendritic fields at normal locations at the lateral margin and segment border, where they meet or approach the like dendrites of adjacent neurons. However, stan mutant neurons occasionally send sparsely branched processes beyond these territories that could potentially mix with adjacent like dendrites. Together, our data suggest that widespread tiling of the larval body wall involves interactions between growing dendritic processes and as yet unidentified signals that allow avoidance by like dendrites.     

Specific Sorting and Post-Golgi Trafficking of Dendritic Potassium Channels in Living Neurons

Proper membrane localization of ion channels is essential for the function of neuronal cells. Particularly, the computational ability of dendrites depends on the localization of different ion channels in specific subcompartments. However, the molecular mechanisms that control ion channel localization in distinct dendritic subcompartments are largely unknown. Here, we developed a quantitative live cell imaging method to analyze protein sorting and post-Golgi vesicular trafficking. We focused on two dendritic voltage-gated potassium channels that exhibit distinct localizations: Kv2.1 in proximal dendrites and Kv4.2 in distal dendrites. Our results show that Kv2.1 and Kv4.2 channels are sorted into two distinct populations of vesicles at the Golgi apparatus. The targeting of Kv2.1 and Kv4.2 vesicles occurred by distinct mechanisms as evidenced by their requirement for specific peptide motifs, cytoskeletal elements, and motor proteins. By live cell and super-resolution imaging, we identified a novel trafficking machinery important for the localization of Kv2.1 channels. Particularly, we identified non-muscle myosin II as an important factor in Kv2.1 trafficking. These findings reveal that the sorting of ion channels at the Golgi apparatus and their subsequent trafficking by unique molecular mechanisms are crucial for their specific localizations within dendrites.     

Amacrine cells, displaced amacrine cells and interplexiform cells in the retina of the rat

The amacrine cells in the retina of the rat are described in Golgi-stained whole-mounted retinae. Nine morphologically distinct types of cell were found: one type of diffuse cell, five types of unistratified cell, two types of bistratified cell, and one type of stratified diffuse cell. Measurements show that the largest unistratified cells have a dendritic field 2 mm across. One type of interplexiform cell is also described. Wide-field diffuse amacrine cells and unistratified amacrine cells were found with their somata located in either the inner nuclear layer or the ganglion cell layer. It is clear that there may be an amacrine cell system in the ganglion cell layer of the rat retina.     

Towards a Better Way to Die with Chemotherapy: Role of Heat Shock Protein Exposure on Dying Tumor Cells

The ultimate goal of most anti-tumor therapies is to kill tumor cells. While most of the attention in cancer therapy has been towards enhancing the death of tumor cells, the effect of dying tumors on the immune system has been less studied. Recent studies have suggested that cell death induced by different agents may have distinct consequences for the immune system. One of the immunogenic signals may be the expression of heat shock proteins on dying tumor cells under certain settings. For example, bortezomib (a proteasome inhibitor) induces the expression of heat shock protein 90 (hsp90) on the surface of dying human myeloma tumor cells. Recognition of such tumor cells by antigen presenting dendritic cells leads to the generation of anti-tumor T cells. Harnessing the properties of some anti-tumor agents to induce immunogenic death of tumor cells may facilitate the recruitment of adaptive immunity and promote the durability of anti-tumor effects.     

Functional dissociation of the basolateral transcytotic compartment from the apical phago-lysosomal compartment in human osteoclasts.

Tartrate-resistant acid phosphatase (TRAP) is essential for elimination of Staphylococcus aureus, the main infectious agent responsible for osteomyelitis. This in vitro study investigated uptake and processing of fluorescence-labeled S. aureus by human osteoclasts and dendritic cells. The cells were stained for TRAP and the acidic compartment using a fluorescence-based protocol. In dendritic cells, TRAP and bacteria were colocalized. In osteoclasts, there was no colocalization of bacteria, TRAP, or the acidic compartment, indicating that there are three distinct vesicular compartments: the apical phago-lysosomal compartment, the basal secretory compartment, and the basolateral transcytotic compartment. Dissociation of the TRAP-containing transcytotic vesicles from the apical phago-lysosomal compartment may restrain osteoclasts from eliminating S. aureus.     

Type I interferon inhibition and dendritic cell activation during gammaherpesvirus respiratory infection

The respiratory tract is a major mucosal site for microorganism entry into the body, and type I interferon (IFN) and dendritic cells constitute a first line of defense against viral infections. We have analyzed the interaction between a model DNA virus, plasmacytoid dendritic cells, and type I IFN during lung infection of mice. Our data show that murine gammaherpesvirus 68 (gammaHV68) inhibits type I IFN secretion by dendritic cells and that plasmacytoid dendritic cells are necessary for conventional dendritic cell maturation in response to gammaHV68. Following gammaHV68 intranasal inoculation, the local and systemic IFN-alpha/beta response is below detectable levels, and plasmacytoid dendritic cells are activated and recruited into the lung with a tissue distribution that differs from that of conventional dendritic cells. Our results suggest that plasmacytoid dendritic cells and type I IFN have important but independent roles during the early response to a respiratory gammaHV68 infection. gammaHV68 infection inhibits type I IFN production by dendritic cells and is a poor inducer of IFN-alpha/beta in vivo, which may serve as an immune evasion strategy.