Cutting edge: CD1a+ antigen-presenting cells in human dermis respond rapidly to CCR7 ligands

Recent data from murine models have confirmed that Langerhans cells are not the only population of APCs in the skin involved in initiating immune responses. In healthy human skin, we identify CD1a(+) dermal APCs located close to the lymphatic vessels in the upper layers of the dermis that are unequivocally distinct from migrating Langerhans cells but exhibit both potent allostimulatory capacity and a chemotactic response to CCR7 ligands. In contrast, CD14(+) dermal APCs are distributed throughout the dermis and lack a chemotactic response to CCR7 ligands. CD1a(+) dermal APCs therefore represent an APC population distinct from Langerhans cells that are capable of migrating to lymph nodes and stimulating naive T cells. In humans, CD1a(+) dermal APCs may fulfill some of the roles previously ascribed to Langerhans cells.     

Human papillomavirus virus-like particles do not activate Langerhans cells: a possible immune escape mechanism used by human papillomaviruses

High-risk human papillomaviruses are linked to several malignancies including cervical cancer. Because human papillomavirus-infected women do not always mount protective antiviral immunity, we explored the interaction of human papillomavirus with Langerhans cells, which would be the first APCs the virus comes into contact with during infection. We determined that dendritic cells, normally targeted by vaccination procedures and Langerhans cells, normally targeted by the natural virus equally internalize human papillomavirus virus-like particles. However, in contrast to dendritic cells, Langerhans cells are not activated by human papillomavirus virus-like particles, illustrated by the lack of: up-regulating activation markers, secreting IL-12, stimulating T cells in an MLR, inducing human papillomavirus-specific immunity, and migrating from epidermal tissue. Langerhans cells, like dendritic cells, can display all of these characteristics when stimulated by proinflammatory agents. These data may define an intriguing immune escape mechanism used by human papillomavirus and form the basis for designing optimal vaccination strategies.     

Epstein-Barr virus infection of Langerhans cell precursors as a mechanism of oral epithelial entry, persistence, and reactivation

Epstein-Barr virus (EBV) is a ubiquitous human herpesvirus associated with many malignant and nonmalignant human diseases. Life-long latent EBV persistence occurs in blood-borne B lymphocytes, while EBV intermittently productively replicates in mucosal epithelia. Although several models have previously been proposed, the mechanism of EBV transition between these two reservoirs of infection has not been determined. In this study, we present the first evidence demonstrating that EBV latently infects a unique subset of blood-borne mononuclear cells that are direct precursors to Langerhans cells and that EBV both latently and productively infects oral epithelium-resident cells that are likely Langerhans cells. These data form the basis of a proposed new model of EBV transition from blood to oral epithelium in which EBV-infected Langerhans cell precursors serve to transport EBV to the oral epithelium as they migrate and differentiate into oral Langerhans cells. This new model contributes fresh insight into the natural history of EBV infection and the pathogenesis of EBV-associated epithelial disease.     

Evidence for genetic recombination between endogenous and exogenous mouse RNA type C viruses

Two viruses isolated following prolonged growth of serologically distinct mouse type C RNA viruses in human cells have previously been shown to have acquired common envelope properties distinct from those of either parental virus. Virus neutralization tests show that the viruses selected in human cells possess envelope antigens identical to those of endogenous mouse type C viruses of cells in which the parental viruses had been propagated. In contrast, the p12 polypeptide of each virus selected in human cells is antigenically indistinguishable from that of its respective parental virus and different from those of known endogenous mouse type C viruses. Molecular hybridization indicates significant differences in the genetic sequences of one virus and its parent, excluding the possibility that it arose from a point mutation. These findings indicate that the viruses selected in human cells represent genetic recombinants between exogenous and endogenous mouse type C viruses.     

Epidermal Langerhans cells are not principal reservoirs of virus in HIV disease

Several reports implicate Langerhans cells of skin as susceptible targets, reservoirs, and vectors for transmission of HIV: 1) numbers of Langerhans cells in skin of HIV-infected patients were decreased about 50% of that in control skin; 2) as many as 30% of Langerhans cells in the skin of HIV-infected patients were morphologically abnormal; 3) viral particles typical for HIV were identified in or around 2 to 5% of these cells; and 4) infectious HIV was isolated from skin biopsies of infected patients. These results were consistent with similar observations of HIV-infected macrophages in such tissues as brain, lung, and lymph node. Despite these findings, other investigators find no evidence for virus infection in the epidermis of HIV-infected patients by any of several immunohistochemical or ultrastructural criteria. To address this controversy, we obtained skin from 28 HIV-seropositive subjects at various clinical stages by full thickness biopsy or suction blister. Samples were analyzed by transmission electron microscopy for presence of HIV virions, by immunofluorescent staining for viral proteins, by in situ hybridization for HIV-specific mRNA, by polymerase chain reaction amplification of virus-specific DNA, and by direct virus isolation by coculture of epidermis onto monocyte target cells. By any of these techniques, demonstration of HIV in the epidermis of infected patients was equivocal and even then, infrequent. In contrast, viral DNA was detected from the dermis of the same skin samples (26 of 28 samples). Moreover, the number and morphology of Langerhans cells in skin of infected patients were within normal limits, regardless of stage of disease. These studies in toto suggest that a role for Langerhans cells as a principal viral reservoir or vector of transmission is highly unlikely.     

Development of ATPase-positive,immature Langerhans cells in the fetal mouse epidermis and their maturation during the early postnatal period

Summary The development and maturation of Langerhans cells during the differentiation of skin was studied in mice from fetal day 13 to adult using 3 indices: (1) ATPase activity; (2) ultrastructure; and (3) quantitative evaluation of the cell population.ATPase-positive Langerhans cells appeared in the epidermis at first at fetal day 16, and they increased in number in the differentiating epidermis during the late fetal period. The earliest appearance of Birbeck granules was at postnatal day 4. Cored tubules were also formed in the Langerhans cells in the dermis at around the same age. The cells containing Birbeck granules or cored tubules are considered to be mature Langerhans cells. In the Langerhans-cell lineage, those cells in the epidermis at stages earlier than postnatal day 4 and not yet containing specific organelles are considered to be immature Langerhans cells. These immature Langerhans cells can be identified ultrastructurally in the epidermis at fetal day 16, coinciding with the appearance of ATPase-positive cells. The increase in the number of immature Langerhans cells during the perinatal period was shown by quantitative analysis of nuclear density and relative Langerhans-cell area on the electron micrographs.It is concluded that ATPase is a marker of the Langerhans-cell lineage from the early development stages, while Birbeck granules and cored tubules are markers that identify mature Langerhans cells in electron micrographs.     

Preferential infection of immature dendritic cells and B cells by mouse mammary tumor virus

Until now it was thought that the retrovirus mouse mammary tumor virus preferentially infects B cells, which thereafter proliferate and differentiate due to superantigen-mediated T cell help. We describe in this study that dendritic cells are infectable at levels comparable to B cells in the first days after virus injection. Moreover, IgM knockout mice have chronically deleted superantigen-reactive T cells after MMTV injection, indicating that superantigen presentation by dendritic cells is sufficient for T cell deletion. In both subsets initially only few cells were infected, but there was an exponential increase in numbers of infected B cells due to superantigen-mediated T cell help, explaining that at the peak of the response infection is almost exclusively found in B cells. The level of infection in vivo was below 1 in 1000 dendritic cells or B cells. Infection levels in freshly isolated dendritic cells from spleen, Langerhans cells from skin, or bone marrow-derived dendritic cells were compared in an in vitro infection assay. Immature dendritic cells such as Langerhans cells or bone marrow-derived dendritic cells were infected 10- to 30-fold more efficiently than mature splenic dendritic cells. Bone marrow-derived dendritic cells carrying an endogenous mouse mammary tumor virus superantigen were highly efficient at inducing a superantigen response in vivo. These results highlight the importance of professional APC and efficient T cell priming for the establishment of a persistent infection by mouse mammary tumor virus.     

Herpes simplex virus type 1 pathogenicity in footpad and ear skin of mice depends on Langerhans cell density, mouse genetics, and virus strain.

Skin Langerhans cells have been shown to be very efficient in presenting antigens to T-helper cells and stimulating the immune response. The present study demonstrates their essential role in the control of primary herpetic infections in the skin. Two unrelated stimuli (abrasion and steroids) were shown to cause depletion of the Langerhans cells in the murine epidermis, and both caused enhancement of the virulence of herpes simplex type 1 (HSV-1) in the skin. The Langerhans cell density was found to be lower in the skin of the ear than in the footpad. HSV-1 was consistently more virulent when injected into the ear epidermis than in the footpad. Thus, HSV-1 pathogenicity in mouse skin depends on the mouse age and strain, the virus strain, and the state of the epidermal Langerhans cells. These findings are discussed in relation to the antigen-presenting cell function of the Langerhans cells.     

Immature monocyte-derived dendritic cells are productively infected with herpes simplex virus type 1

Herpes simplex viruses (HSV) have developed several immunoevasive strategies. Here we demonstrate a novel mechanism by which HSV type 1 may interfere with the immune response through infection of immature dendritic cells (DC) and selective downmodulation of costimulatory molecules. In our study we show productive infection of immature monocyte-derived DC, which closely resemble sessile Langerhans cells, by sequential expression of immediate-early, early, and late viral proteins and of glycoprotein D mRNA, as well as production of infectious virus of moderate titers. Infection was cytopathic, with the progressive loss of 20 to 45% of cells from 24 to 48 h after infection, with no more than 80% of DC found to be infected. These results are in contrast to those of previous findings of nonpermissive or abortive infection of monocytes and mature monocyte-derived DC. Infection of immature DC also led to selective and asynchronous downregulation of CD1a, CD40, CD54 (ICAM-1) (12 h postinfection), CD80 (24 h postinfection), and CD86 (48 h postinfection) but not of CD11c or major histocompatibility complex class I and II molecules when compared to DC exposed to UV-inactivated virus. Thus, we propose that productive infection of epidermal Langerhans cells in vivo may lead to delayed activation of T cells, allowing more time for replication of HSV type 1 in epidermal cells.     

Crystal structure of the matrix protein VP40 from Ebola virus

Ebola virus maturation occurs at the plasma membrane of infected cells and involves the clustering of the viral matrix protein VP40 at the assembly site as well as its interaction with the lipid bilayer. Here we report the X-ray crystal structure of VP40 from Ebola virus at 2.0 A resolution. The crystal structure reveals that Ebola virus VP40 is topologically distinct from all other known viral matrix proteins, consisting of two domains with unique folds, connected by a flexible linker. The C-terminal domain, which is absolutely required for membrane binding, contains large hydrophobic patches that may be involved in the interaction with lipid bilayers. Likewise, a highly basic region is shared between the two domains. The crystal structure reveals how the molecule may be able to switch from a monomeric conformation to a hexameric form, as observed in vitro. Its implications for the assembly process are discussed.     

Clonal and territorial development of the pancreas as revealed by eGFP-labelled mouse chimeras

The clonal structure of the pancreas was analysed in neonatal and adult mouse chimeras in which one partner displayed cell patches expressing green fluorescent protein (eGFP). Coherent growth during pancreatic histogenesis was suggested by the presence of large eGFP-labelled acinar clusters rather than a scattered distribution of individual labelled acinar cells. The adult chimeric pancreas contained monophenotypic acini, whereas surprisingly 5% of acini in neonates were polyclonal. Monophenotypic acini presumably arose by coherent expansion leading to large 3D patches and may not be monoclonal. Islets of Langerhans were oligoclonal at both ages investigated. The proportion of eGFP positive cells within islets did not correlate with that of the surrounding acinar tissue indicating clonal independence of islets from their neighbourhood. The patterns observed argue against a secondary contribution of blood-borne progenitor/stem cells to the acinar compartment during tissue turnover. The different clonal origins of acini and islets are integrated into a model of pancreatic histogenesis.     

Distribution of substance P receptors on murine spleen and Peyer's patch T and B cells

Previous studies have demonstrated that the sensory neuropeptide substance P (SP) can modulate immune responses in vitro. Work from this laboratory has shown that SP enhances immunoglobulin synthesis by murine splenic and Peyer's patch lymphocytes stimulated with concanavalin A. One mechanism underlying these effects is the binding of SP to specific receptors on lymphocytes. We examined the distribution of SP receptors on murine T and B lymphocytes and their subsets by one and two color fluorescence-activated cell sorter analysis. The specificity and nature of binding was examined using radiolabeled SP, and competitive inhibition experiments were performed with cold SP. In cytofluorimetry experiments, both T and B lymphocytes from Peyer's patches and spleen were bound to SP, with those from Peyer's patches having a higher proportion than lymphocytes from the spleen. The majority of T cells from both organs bound SP with binding being evenly distributed between Lyt-1+ and Lyt-2+ cells. Similarly, the majority of B lymphocytes from spleen and Peyer's patches showed SP binding. There were no significant isotype-specific differences within any organ. Studies using 125I-labeled SP showed specific binding to all lymphocyte subpopulations examined. SP receptors were fewer in number on cells isolated from spleen than on cells from Peyer's patches although the dissociation constants were similar for all populations examined. These studies demonstrated that SP receptors are present both on murine T and B lymphocytes from Peyer's patches and spleen. There is no evidence for differential SP receptor expression on distinct lymphocyte subsets in spleen or Peyer's patches.     

A comparative study of the gut-associated lymphoid tissue of primates and rodents

Previous studies have suggested that the gut-associated lymphoid tissue (GALT) of man is distinct from that of laboratory animals, but it is not clear whether this is due to environmental or true species difference. We have made a comparative study of rats and baboons because, like rats, baboons are herbivorous and relatively unhygienic but they are phylogenetically much more closely related to man. The Peyer's patches of rats, baboons and man are morphologically very similar in all three species but phenotypically those of man and baboons are different to those of rats. Cells with irregular nuclei ("centrocyte-like" cells) surround the mantle zone in all three species. While these cells express surface IgD and IgM in rats, in man and baboons they express surface IgM or IgA. A population of immunoblasts which express cytoplasmic IgA are present in association with the high endothelial venules of rat Peyer's patches. These cells are not present to the same extent in man or baboons. This suggests that the events between the antigenic stimulation of Peyer's patches and the ultimate seeding of the lamina propria with IgA secreting plasma cells may be different in rodents and primates.     

Down-regulation of Toll-like receptor expression in monocyte-derived Langerhans cell-like cells: implications of low-responsiveness to bacterial components in the epidermal Langerhans cells

In the skin, there are unique dendritic cells called Langerhans cells, however, it remains unclear why this particular type of dendritic cell resides in the epidermis. Langerhans cell-like dendritic cells (LCs) can be generated from CD14(+) monocytes in the presence of GM-CSF, IL-4, and TGF-beta1. We compared LCs with monocyte-derived dendritic cells (DCs) generated from CD14(+) monocytes in the presence of GM-CSF and IL-4 and examined the effect of exposure to two distinct bacterial stimuli via Toll-like receptors (TLRs), such as peptidoglycan (PGN) and lipopolysaccharide (LPS) on LCs and DCs. Although stimulation with both ligands induced a marked up-regulation of CD83 expression on DCs, PGN but not LPS elicited up-regulation of expression CD83 on LCs. Consistent with these results, TLR2 and TLR4 were expressed on DCs, whereas only TLR2 was weakly detected on LCs. These findings suggest the actual feature of epidermal Langerhans cells with low-responsiveness to skin commensals.     

Qualitative and quantitative characteristics of rotavirus-specific CD8 T cells vary depending on the route of infection

CD8 T-cell response provides an important defense against rotavirus, which infects a variety of systemic locations in addition to the gut. Here we investigated the distribution, phenotype, and function of rotavirus-specific CD8 T cells in multiple organs after rotavirus infection initiated via the intranasal, oral, or intramuscular route. The highest level of virus-specific CD8 T cells was observed in the Peyer's patches of orally infected mice and in the lungs of intranasally infected animals. Very low levels of virus-specific CD8 T cells were detected in peripheral blood or spleen irrespective of the route of infection. Rotavirus-specific CD8 T cells from Peyer's patches of orally infected mice expressed high levels of CCR9, while CXCR6 and LFA-1 expression was associated with virus-specific CD8 T cells in lungs of intranasally infected mice. Oral infection induced the highest proportion of gamma interferon(-) CD107a/b(+) CD8 T cells in Peyer's patches. When equal numbers of rotavirus-specific CD8 T cells were transferred into Rag-1 knockout mice chronically infected with rotavirus, the donor cells derived from Peyer's patches of orally infected mice were more efficient than those derived from lungs of intranasally infected animals in clearing intestinal infection. These results suggest that different routes of infection induce virus-specific CD8 T cells with distinct homing phenotypes and effector functions as well as variable abilities to clear infection.     

Characterization of cryopreserved human Langerhans cells

Epidermal Langerhans cells are potent antigen-presenting cells in the epidermis. The establishment of a cryopreservation method for human Langerhans cells would greatly contribute to our ability to successfully conduct various experiments dealing with Langerhans cells. Since Langerhans cells are known to be sensitive to cold injury, there have been no reports concerning the cryopreservation of Langerhans cells. We have investigated the effect of cryopreservation on the function and phenotype of human Langerhans cells. Langerhans cells from human foreskins were isolated with the immunomagnetic microbead method using monoclonal antibodies for CD1a. Langerhans cells were cryopreserved in the presence of dimethylsulfoxide (DMSO) 10% and fetal calf serum 90%. Cryopreserved Langerhans cells were phenotypically assessed by flowcytometry using monoclonal antibodies to HLA-DR and CD1a. The ultrastructures of the Langerhans cells were compared using electron microscopy. An autologous T cell stimulation test was performed to compare the functions of cryopreserved Langerhans cells and fresh Langerhans cells. The viability of the cryopreserved Langerhans cells was able to be maintained at more than 90%. Cryopreserved Langerhans cells expressed high levels of HLA-DR and CD1a antigens and stimulated autologous T cells to an extent almost identical to that obtained from fresh Langerhans cells. These findings indicate that the cryopreservation of human Langerhans cells could lead to a breakthrough in various experiments dealing with human Langerhans cells.     

Electron microscope examination of two plaque variants from a nuclear polyhedrosis virus of the alfalfa looper, Autographa californica

This investigation looks into the ultrastructural differences between plaque variants of the alfalfa looper nuclear polyhedrosis virus. The variants exhibit distinct differences in polyhedra morphology and enveloping of the nucleocapsids.Tissues from larvae infected per os or subcutaneously with virus from one type of plaque always contained virus representative of both plaques. This was not true of the in vitro cultured cells. In those cells, a culture infected with one plaque type always developed infections that were typical of that particular plaque.     

Macrophages containing langerhans cell granules in normal lymph nodes of the rabbit

Summary Light and electron microscopic studies on macrophages of normal rabbit lymph nodes showed two types, one with little phagocytic activity and many features similar to those of epidermal Langerhans cells. Among these are characteristic Langerhans cell granules. From these findings it is concluded that the Langerhans cells may be derived from lymph node macrophages.The helpful advice and criticism of Dr. Toshio Nagano, Department of Anatomy, are gratefully acknowledged. The discussion with Dr. Mitsumasa Itoh, Department of Dermatology, was also helpful.     

Distinct roles for DC-SIGN+-dendritic cells and Langerhans cells in HIV-1 transmission

Dendritic cells (DCs) are thought to mediate HIV-1 transmission but it is becoming evident that different DC subsets at the sites of infection have distinct roles. In the genital tissues, two different DC subsets are present: the Langerhans cells (LCs) and the DC-SIGN(+)-DCs. Although DC-SIGN(+)-DCs mediate HIV-1 transmission, recent data demonstrate that LCs prevent HIV-1 transmission by clearing invading HIV-1 particles. However, this protective function of LCs is dependent on the function of the C-type lectin Langerin: blocking Langerin function by high virus concentrations enables HIV-1 transmission by LCs. Here, we will discuss the molecular mechanisms involved in HIV-1 transmission and viral clearance. A better understanding of these processes is crucial to understand and develop strategies to combat transmission.     

Differential regulation of single CFTR channels by PP2C, PP2A, and other phosphatases

Cystic fibrosistransmembrane conductance regulator (CFTR)Cl channel activitydeclines rapidly when excised from transfected Chinese hamster ovary(CHO) or human airway cells because of membrane-associated phosphataseactivity. In the present study, we found that CFTR channels usuallyremained active in patches excised from baby hamster kidney (BHK) cellsoverexpressing CFTR. Those patches with stable channel activity wereused to investigate the regulation of CFTR by exogenous proteinphosphatases (PP). Adding PP2A, PP2C, or alkaline phosphatase toexcised patches reduced CFTR channel activity by >90% but did notabolish it completely. PP2B caused weak deactivation, whereas PP1 hadno detectable effect on open probability(P_o).Interestingly, the time course of deactivation by PP2C was identical tothat of the spontaneous rundown observed in some patches afterexcision. PP2C and PP2A had distinct effects on channel gating;P_o declinedduring exposure to exogenous PP2C (and during spontaneous rundown, whenit was observed) without any change in mean burst duration. Bycontrast, deactivation by exogenous PP2A was associated with a dramaticshortening of burst duration similar to that reported previously inpatches from cardiac cells during deactivation of CFTR by endogenousphosphatases. Rundown of CFTR-mediated current across intact T84epithelial cell monolayers was insensitive to toxic levels of the PP2Ainhibitor calyculin A. These results demonstrate that exogenous PP2C is a potent regulator of CFTR activity, that its effects on single-channel gating are distinct from those of PP2A but similar to those of endogenous phosphatases in CHO, BHK, and T84 epithelial cells, and thatmultiple protein phosphatases may be required for complete deactivationof CFTR channels.