Profiling early lung immune responses in the mouse model of tuberculosis

Tuberculosis (TB) is caused by the intracellular bacteria Mycobacterium tuberculosis, and kills more than 1.5 million people every year worldwide. Immunity to TB is associated with the accumulation of IFNγ-producing T helper cell type 1 (Th1) in the lungs, activation of M.tuberculosis-infected macrophages and control of bacterial growth. However, very little is known regarding the early immune responses that mediate accumulation of activated Th1 cells in the M.tuberculosis-infected lungs. To define the induction of early immune mediators in the M.tuberculosis-infected lung, we performed mRNA profiling studies and characterized immune cells in M.tuberculosis-infected lungs at early stages of infection in the mouse model. Our data show that induction of mRNAs involved in the recognition of pathogens, expression of inflammatory cytokines, activation of APCs and generation of Th1 responses occurs between day 15 and day 21 post infection. The induction of these mRNAs coincides with cellular accumulation of Th1 cells and activation of myeloid cells in M.tuberculosis-infected lungs. Strikingly, we show the induction of mRNAs associated with Gr1+ cells, namely neutrophils and inflammatory monocytes, takes place on day 12 and coincides with cellular accumulation of Gr1+ cells in M.tuberculosis-infected lungs. Interestingly, in vivo depletion of Gr1+ neutrophils between days 10-15 results in decreased accumulation of Th1 cells on day 21 in M.tuberculosis-infected lungs without impacting overall protective outcomes. These data suggest that the recruitment of Gr1+ neutrophils is an early event that leads to production of chemokines that regulate the accumulation of Th1 cells in the M.tuberculosis-infected lungs.     

Intravital multiphoton imaging of immune responses in the mouse ear skin

Multiphoton (MP) microscopy enables the direct in vivo visualization, with high spatial and temporal resolution, of fluorescently tagged immune cells, extracellular matrix and vasculature in tissues. This approach, therefore, represents a powerful alternative to traditional methods of assessing immune cell function in the skin, which are mainly based on flow cytometry and histology. Here we provide a step-by-step protocol describing experimental procedures for intravital MP imaging of the mouse ear skin, which can be easily adapted to address many specific skin-related biological questions. We demonstrate the use of this procedure by characterizing the response of neutrophils during cutaneous inflammation, which can be used to perform in-depth analysis of neutrophil behavior in the context of the skin microanatomy, including the epidermis, dermis and blood vessels. Such experiments are typically completed within 1 d, but as the procedures are minimally invasive, it is possible to perform longitudinal studies through repeated imaging.     

Junin virus infects mouse cells and induces innate immune responses

Junín virus is the causative agent for Argentine hemorrhagic fever, and its natural host is the New World rodent Calomys musculinus. The virus is transmitted to humans by aerosolization, and it is believed that many of the clinical symptoms are caused by cytokines produced by sentinel cells of the immune system. Here we used the Junín virus vaccine strain Candid 1 to determine whether mouse cells could be used to study virus entry and antiviral innate immune responses. We show that Candid 1 can infect and propagate in different mouse-derived cell lines through a low-pH-dependent, transferrin receptor 1-independent mechanism, suggesting that there is a second entry receptor. In addition, Candid 1 induced expression of the antiviral cytokines tumor necrosis factor alpha and beta interferon in macrophages, and this induction was independent of viral replication. Using Candid 1, as well as virus-like particles bearing the viral glycoprotein, to infect different primary cells and established macrophage cell lines with deletions in the Toll-like receptor (TLR) pathway, we show that TLR2 is a cellular sensor of both the Parodi and Candid 1 viral glycoproteins. Because Junín virus is highly lethal in humans, the use of an experimentally tractable model system, such as the mouse, could provide a better understanding of the antiviral innate cellular responses to Junín virus and the role of these responses in pathogenesis.     

Toll-like receptor 3 activation induces antiviral immune responses in mouse sertoli cells

Toll-like receptors (TLRs) recognize pathogen-associated molecular patterns and elicit antimicrobial immune responses. In the testis, viruses can induce pathological conditions, such as orchitis, and may participate in the etiology of testicular cancer; however, the molecular mechanisms involved remain under investigation. It has been suggested that because they constitutively express interferon (IFN)-inducible antiviral proteins, Sertoli cells participate in the testicular antiviral defense system. Previously, we demonstrated a key function of mouse Sertoli cells in the bactericidal testicular defense mechanism mediated by a panel of TLRs. To better characterize the potential role of Sertoli cells in the response against testicular viral infections, we investigated the TLR3 expression and function in these cells. Sertoli cells express TLR3, and under stimulation with the synthetic double-stranded RNA analogue poly (I:C), they produce the proinflammatory molecule ICAM1 and secrete functionally active CCL2 chemokine. Using both pharmacological and genetic approaches, we found that these effects are TLR3-dependent. Moreover, using ELISA, we found that IFNA is constitutively produced and not further inducible, whereas IFNB1 is absent and dramatically induced only by transfected poly (I:C), indicating different control mechanisms underlying IFNA and IFNB1 production. To conclude, poly (I:C) elicits both inflammatory and antiviral responses in Sertoli cells.     

Aberrant maturational characteristics of the immune responses of NZB mice to autologous and heterologous erythrocyte antigens

The maturational characteristics of the humoral immune responses of C3H and NZB mice to autologous and heterologous erythrocyte antigens were investigated. Clonal selection of antibody-secreting B lymphocytes was examined at the plaque-forming cell level of analysis of changes in mean antibody affinity and the heterogeneity of binding affinities. The primary immune response of C3H mice to SRBC exhibited a progressive temporal increase in mean relative antibody affinity and a concomitant restriction in the heterogeneity of binding affinities consistent with clonal selection and restriction of B lymphocytes to high affinity antibody-secreting cells. By contrast, the anti-SRBC immune response of NZB mice displayed aberrant maturational characteristics with a progressive decrease in mean relative antibody affinity but also clonal restriction with selection of clones of cells secreting low affinity antibodies. The spontaneous autoimmune responses of NZB mice to autologous erythrocyte surface autoantigens X and HB were different from the response to heterologous erythrocytes in that there was neither a progressive change in mean relative binding affinity nor evidence of progressive clonal restriction. Although the precise mechanisms responsible for the aberrant selection and derepression of B lymphocyte clones in NZB mice have not been identified, the very nature of the aberration suggests the existence of one or more defects which may be intrinsic to the B lymphocytes of NZB mice.     

Role of Toll-like receptor 4 in innate immune responses in a mouse model of acute otitis media

Nontypeable Haemophilus influenzae (NTHi) is considered a major pathogen underlying middle ear infection. This study characterized the role of Toll-like receptor 4 in the innate immune responses to acute otitis media induced by NTHi in mice. We used C3H/HeJ mice, which have nonfunctional Toll-like receptor 4, and normal wild-type C3H/HeN mice. NTHi were injected into the tympanic bulla, and middle ear effusions and tissues were collected. In C3H/HeN mice, the severity of acute otitis media decreased promptly with a significant reduction in bacterial recovery from middle ear effusions 48 h after injection. In contrast, all C3H/HeJ mice had otitis media at all time points examined, and increasing bacterial counts from middle ear effusions were detected in C3H/HeJ mice 72 h after injection. Expression of intracellular adhesion molecule-1 by the middle ear mucosa paralleled the number of polymorphonuclear cells in the middle ear in both strains. The findings of transmission electron microscopy revealed that phagocytosis and phagosome maturation of polymorphonuclear cells was impaired in C3H/HeJ mice. Our findings indicate that Toll-like receptor 4 plays a part in the early accumulation and functional promotion of polymorphonuclear cells in the middle ear for eradicating NTHi infection.     

Antiviral immune responses of fully allogeneic irradiation bone marrow mouse chimeras

In (B10.BR----B10) chimeras infected with lymphocytic choriomeningitis (LCM) virus higher titers were attained in spleens and livers than in organs of the mice used for their construction, and the subsequent elimination was retarded, but eventually the virus was cleared. The numbers of LCM virus-specific CTL and their precursors as quantitated with chromium-release assay and limiting dilution method, respectively, were lower in chimeras than in B10.BR or C57BL/10J mice, and fewer were restricted for the haplotypes of the donors than of the recipients. The same was true with regard to antiviral effector cells, which were determined by adoptive immunization. The numbers of spleen cells releasing IgM and IgG antiviral antibodies were virtually as high in chimeras as they were in C57BL/10J and B10.BR mice. Transfer of immune splenocytes from either B10.BR or C57BL/10J mice resulted in incomplete virus elimination from the spleens of infected chimeras, whereas injection of a mixture of the two types of immune cells led to efficient clearance. We conclude that in the chimeras cells of both donor and recipient haplotypes participate in the infection, which is terminated by H-2k- and H-2b-restricted T lymphocytes that these animals are capable of generating. We conclude, furthermore, that clearance of the LCM virus from the tissues requires contact between effector and target cells.     

Bradley's Benzedrine studies on children with behavioral disorders

In 1937, psychiatrist Charles Bradley administered Benzedrine sulfate, an amphetamine, to "problem" children at the Emma Pendleton Bradley Home in Providence, Rhode Island, in an attempt to alleviate headaches; however, Bradley noticed an unexpected effect upon the behavior of the children: improved school performance, social interactions, and emotional responses. Drawing on Bradley's published articles on his experiments, this paper explores the historical context of his experiments and the effect this background had on the emerging field of child psychiatry. Bradley's studies went largely ignored in the field of child psychiatry for nearly 25 years. However, they proved to be an important precursor to studies of amphetamines like Ritalin and their use in conditions such as attention deficit hyperactivity disorder. Bradley's Benzedrine trials were thus highly influential in shaping modern objective understandings of children with behavior disorders.     

Modeling immune responses with handling time

Simple predator-prey type models have brought much insight into the dynamics of both nonspecific and antigen-specific immune responses. However, until now most attention has been focused on examining how the dynamics of interactions between the parasite and the immune system depends on the nature of the function describing the rate of activation or proliferation of immune cells in response to the parasite. In this paper we focus on the term describing the killing of the parasite by cell-mediated immune responses. This term has previously been assumed to be a simple mass-action term dependent solely on the product of the densities of the parasite and the immune cells and does not take into account a handling time (which we define as the time of interaction between an immune cell and its target, during which the immune cell cannot interact with and/or destroy additional targets). We show how the handling time (i) can be incorporated into simple models of nonspecific and specific immunity and (ii) how it affects the dynamics of both nonspecific and antigen-specific immune responses, and in particular the ability of the immune response to control the infection.     

Modulating immune responses with probiotic bacteria

For many years, probiotic bacteria have been known to confer health benefits to the consumer. One possible mechanism for this may be the ability of probiotic bacteria to modulate immune responses. Oral administration of Lactobacillus casei strain Shirota (LcS) has been found to enhance innate immunity by stimulating the activity of splenic NK cells. Oral feeding with killed LcS was able to stimulate the production of Th1 cytokines, resulting in repressed production of IgE antibodies against Ovalbumin in experimental mice. The ability to switch mucosal immune responses towards Th1 with probiotic bacteria provides a strategy for treatment of allergic disorders. Growth of Meth A tumour cells in the lungs was also inhibited by intrapleural injection of LcS. Oral administration of other probiotic bacteria, such as Streptococcus thermophilus (St), Lactobacillus fermentum (Lf) and yeast (Y), elicited different immune responses. Mice that were prefed yeast or Lf followed by feeding with ovalbumin (OVA) responded better to vaccination with OVA than mice not given either probiotic or OVA or mice that had been prefed only OVA. However, antibody responses were significantly suppressed in response to vaccination with OVA in mice that had been prefed yeast followed by yeast and OVA as well as mice prefed Lf followed by Lf and OVA. Prefeeding St followed by OVA feeding enhanced cellular immune responses against ovalbumin. In contrast, mice prefed St followed by St + OVA were hyporesponsive against OVA. While antigen feeding alone appears to prime for an immune response, cofeeding antigen with probiotic bacteria can suppress both antibody and cellular immune responses and may provide an efficacious protocol to attenuate autoimmune diseases, such as experimental allergic encephalomyelitis, by jointly dosing with myelin basic protein and probiotic bacteria.     

Tuning immune tolerance with vasoactive intestinal peptide: a new therapeutic approach for immune disorders

The induction of immune tolerance is essential for the maintenance of immune homeostasis and to limit the occurrence of exacerbated inflammatory and autoimmune conditions. Multiple mechanisms act together to ensure self-tolerance, including central clonal deletion, cytokine deviation and induction of regulatory T cells. Identifying the factors that regulate these processes is crucial for the development of new therapies of autoimmune diseases and transplantation. The vasoactive intestinal peptide (VIP) is a well-characterized endogenous anti-inflammatory neuropeptide with therapeutic potential for a variety of immune disorders. Here, we examine the latest research findings, which indicate that VIP participates in maintaining immune tolerance in two distinct ways: by regulating the balance between pro-inflammatory and anti-inflammatory factors, and by inducing the emergence of regulatory T cells with suppressive activity against autoreactive T-cell effectors.     

A Catalogus Immune Muris of the mouse immune responses to diverse pathogens

Immunomodulation strategies are crucial for several biomedical applications. However, the immune system is highly heterogeneous and its functional responses to infections remains elusive. Indeed, the characterization of immune response particularities to different pathogens is needed to identify immunomodulatory candidates. To address this issue, we compiled a comprehensive map of functional immune cell states of mouse in response to 12 pathogens. To create this atlas, we developed a single-cell-based computational method that partitions heterogeneous cell types into functionally distinct states and simultaneously identifies modules of functionally relevant genes characterizing them. We identified 295 functional states using 114 datasets of six immune cell types, creating a Catalogus Immune Muris. As a result, we found common as well as pathogen-specific functional states and experimentally characterized the function of an unknown macrophage cell state that modulates the response to Salmonella Typhimurium infection. Thus, we expect our Catalogus Immune Muris to be an important resource for studies aiming at discovering new immunomodulatory candidates.Subject terms: Immunology, Cell death and immune response     

T cell receptor-transgenic mouse models for studying cellular immune responses to Salmonella in vivo

Cellular immune responses are crucial both for protective immunity against salmonellosis, and for the immunogenicity of oral vaccines based on avirulent live Salmonella as antigen carriers. The crucial early steps of T cell induction are difficult to investigate in conventional animals, but recently developed T cell receptor (TCR)-transgenic models allow visualization of antigen-specific T cells in vivo while they become induced. In this review, the results obtained with four different TCR-transgenic Salmonella infection models are described, and advantages and potential limits of each of the different models are compared.     

Intellectual functioning and behavioral disorders

The paper discusses areas of behavioral functioning of children with intellectual disability, such as behavior with or without hyperactivity. The study covered 124 children with intellectual disability attending elementary schools in Belgrade. The Conners Rating Scale was used, and the areas of behavior in the classroom, participation in the group and attitude towards authority were covered. The results of our study suggest the presence of disorders in behavior and social-emotional functioning ranging from 11.2 to 40.4%. We have highlighted the importance of the use of multimodal approach and method of reeducation of psychomotor activity in rehabilitation of the studied children.     

Antitumour immune responses

The role of the immune system in combating tumour progression has been studied extensively. The two branches of the immune response - humoral and cell-mediated - act both independently and in concert to combat tumour progression, the success of which depends on the immunogenicity of the tumour cells. The immune system discriminates between transformed cells and normal cells by virtue of the presence of unique antigens on tumour cells. Despite this, the immune system is not always able to detect and kill cancerous cells because neoplasms have also evolved various strategies to escape immune surveillance. Attempts are being made to trigger the immune system into an early and efficient response against malignant cells, and various therapeutic modalities are being developed to enhance the strength of the immune response against tumours. This review aims to elucidate the tumoricidal role of various components of the immune system, including macrophages, lymphocytes, dendritic cells and complement.     

Cell-mediated immune responses to sperm antigens: effects on mouse sperm and embryos

Sperm antigens were assessed for their ability to induce cell-mediated immune (CMI) responses. Purified fertilization antigen (FA-1), protamine, and the lithium diiodosalicylate (LIS)-solubilized sperm preparation activated presensitized lymphocytes to secrete soluble mediators that activated macrophages and significantly inhibited sperm motility and embryonic development. The FA-1, however, was the most potent antigen in inducing proliferative response as well as the release of soluble mediators. LIS-sperm preparation, which contained numerous antigens, showed the least activity. The unsensitized control spleen cells did not secrete any factor(s) when activated with the antigen. In conclusion, these results indicate that sperm antigens can specifically induce (CMI) factors that have detrimental effects on sperm motility and preimplantation embryos. These findings may have potential clinical implications for humans, especially in immunologic and unexplained infertility, recurrent abortions, and development of antisperm contraceptive vaccines.     

Comparison of immune responses to diphtheria and tetanus toxoids of various mouse strains

Immune responses of 11 mouse strains with known genetical characteristics and two outbred strains to diphtheria and to tetanus toxoids were compared. Both diphtheria and tetanus antitoxins were titrated by passive hemagglutination. From the pattern of the immune response, the mouse strains tested may be classified into four groups. [1] Strains ddY (SPF) and ddY (conv) and those with haplotype H-2b, such as C57BL/6 and C57BL/10, were high responders to both toxoids. [2] Strains with H-2d, such as BALB/c, B10.D2 and DBA/2Cr, were intermediate responders to both toxoids. [3] Strains with H-2k, H-2a or, H-2m, such as C3H/He, B10.BR, B10.BR/SgSn, B10.A/SgSnJ and B10.AKM/O1a, were high responders to diphtheria toxoid but low responders to tetanus toxoid. [4] The strain with H-2h4, B10.A (4R), was a poor responder to both toxoids.