The Mouse Genome Database (MGD): from genes to mice--a community resource for mouse biology.

The Mouse Genome Database (MGD) forms the core of the Mouse Genome Informatics (MGI) system (http://www.informatics.jax.org), a model organism database resource for the laboratory mouse. MGD provides essential integration of experimental knowledge for the mouse system with information annotated from both literature and online sources. MGD curates and presents consensus and experimental data representations of genotype (sequence) through phenotype information, including highly detailed reports about genes and gene products. Primary foci of integration are through representations of relationships among genes, sequences and phenotypes. MGD collaborates with other bioinformatics groups to curate a definitive set of information about the laboratory mouse and to build and implement the data and semantic standards that are essential for comparative genome analysis. Recent improvements in MGD discussed here include the enhancement of phenotype resources, the re-development of the International Mouse Strain Resource, IMSR, the update of mammalian orthology datasets and the electronic publication of classic books in mouse genetics.

The identification of a common pathogen-specific HLA class I A*0201-restricted cytotoxic T cell epitope encoded within the heat shock protein 65.

Bacterial antigens recognized by CD8(+) T cells in the context of MHC class I are thought to play a crucial role in protection against pathogenic intracellular bacteria. Here, we demonstrate the induction of HLA-A*0201-restricted CD8(+) T cell responses against six new high-affinity HLA-A*0201-binding CTL epitopes, encoded within an immunodominant and highly conserved antigen of Mycobacteria, the heat shock protein 65 (hsp65). One of these epitopes, Mhsp65(9(369)), is identical in a large number of pathogenic bacteria, and is recognized in a CD8-independent fashion. Mhsp65(9(369)) could be presented by either mycobacterial hsp65-pulsed target cells or BCG-infected macrophages. Interestingly, T cells specific for this epitope did not recognize the corresponding human hsp65 homologue, probably due to structural differences as revealed by modeling studies. Furthermore, in vitro proteasome digestion analyses show that, whereas the mycobacterial hsp65 epitope is efficiently generated, the human hsp65 homologue is not, thus avoiding the induction of autoreactivity. Collectively, these findings describe high-affinity HLA class I-binding epitopes that are naturally processed and are recognized efficiently by MHC class I-restricted CD8(+) T cells, providing a rational basis for the development of subunit vaccine strategies against tuberculosis and other intracellular infectious diseases.

Emergence of CD8+ T cells expressing NK cell receptors in influenza A virus-infected mice.

Both innate and adaptive immune responses play an important role in the recovery of the host from viral infections. In the present report, a subset of cells coexpressing CD8 and NKR-P1C (NK1.1) was found in the lungs of mice infected with influenza A virus. These cells were detected at low numbers in the lungs of uninfected mice, but represented up to 10% of the total CD8(+) T cell population at day 10 postinfection. Almost all of the CD8(+)NK1.1(+) cells were CD8alphabeta(+)CD3(+)TCRalphabeta(+) and a proportion of these cells also expressed the NK cell-associated Ly49 receptors. Interestingly, up to 30% of these cells were virus-specific T cells as determined by MHC class I tetramer staining and by intracellular staining of IFN-gamma after viral peptide stimulation. Moreover, these cells were distinct from conventional NKT cells as they were also found at increased numbers in influenza-infected CD1(-/-) mice. These results demonstrate that a significant proportion of CD8(+) T cells acquire NK1.1 and other NK cell-associated molecules, and suggests that these receptors may possibly regulate CD8(+) T cell effector functions during viral infection.

Impaired immune responses and altered peptide repertoire in tapasin-deficient mice.

Tapasin is a component of the major histocompatibility complex (MHC) class I antigen-loading complex. Here we show that mice with a disrupted tapasin gene display reduced MHC class I expression. Cytotoxic T cell (CTL) responses to viruses are impaired, and dendritic cells of tapasin-deficient mice do not cross-present protein antigen via the MHC class I pathway, indicating a defect in antigen processing. Natural killer (NK) cells from tapasin-deficient mice have an altered repertoire and are self-tolerant. In addition, the repertoire of class I-bound peptides is altered towards less stably binding ones. Thus tapasin plays a role in CTL and NK immune responses and in optimal peptide selection.

Selective targeting of habenular, thalamic midline and monoaminergic brainstem neurons by neurotropic influenza A virus in mice.

Infections caused by influenza A virus have been proposed to be associated with neuropsychiatric complications, the mechanisms of which remain to be unravelled. We here report that a neurotropic strain of influenza A virus (A/WSN/33) introduced into the olfactory bulbs of C57BL/6 (B6) mice, selectively attacks habenular, paraventricular thalamic, and brainstem monoaminergic neurons. In the habenular and paraventricular thalamic areas, infection was followed by an almost total loss of neurons within 12 days. In the brain stem monoaminergic areas, viral gene products were eliminated from neurons by 12 days in B6 wildtype mice, but remained for at least 35 days in immunodefective TAP1 (Transporter associated with Antigen Presentation 1) mutant mice. In conclusion, we show that influenza A virus infection in the brain selectively targets regions which have been implicated in neuropsychiatric disturbances, and that this virus can remain for a significant period of time in specific regions of the brain in immunodefective mice.

Altered expression of Ly49 inhibitory receptors on natural killer cells from MHC class I-deficient mice.

MHC class I molecules in the host affect the specificity of NK cells. Previous work has suggested that this specificity is conferred by the expression of products encoded by the Ly49 gene family. This gene family encodes receptors that upon specific recognition of MHC class I ligands mediate an inhibitory signal that prevents killing by NK cells. The pattern of expression of the Ly49 MHC class I binding inhibitory receptors on NK cells is thought to be adapted to the host to ensure the generation of a self-tolerant, yet functional, NK cell repertoire. In the present study we have examined the expression of inhibitory receptors (Ly49A, Ly49C, and Ly49G2) on NK1.1+ cells from B6 (H-2b) and D8 (B6 mice transgenic for H-2Dd) mice as well as corresponding TAP1 -/-, beta2m -/-, and TAP1/beta2m -/- mutants of these mice. We demonstrate that receptor expression on NK1.1+ cells can be specifically modulated by host MHC class I molecules in at least two different ways: alteration of numbers of cells expressing a given receptor and modulation of the levels of expression of a given receptor at the cell surface. The degree of this modulation varies significantly among the various receptors studied and may depend upon the nature of their MHC class I ligands. The results are discussed in relation to the influence of MHC class I molecules on the development of an NK cell repertoire.

TAP peptide transporter-independent presentation of heat-killed Sendai virus antigen on MHC class I molecules by splenic antigen-presenting cells.

Immunization of C57BL/6 (B6) mice with heat-killed Sendai virus generates a Sendai virus-specific CD8+ T cell response. This suggests that APC have the capacity to take up and present exogenous (nonreplicative) Sendai virus Ag on MHC class I molecules. Little is known about the intracellular requirements for processing of this form of Ag and its presentation on MHC class I. Therefore, we have studied the processing and presentation of heat-killed Sendai virus Ag on MHC class I molecules in splenic APC. Heat-killed Sendai virus Ags were efficiently processed by normal B6 as well as by TAP-1(-/-) splenic APC. Presentation was MHC class I restricted, since no presentation was seen by APC from TAP-1/beta2m-/- mice that lack expression of MHC class I. Presentation occurred even in the presence of brefeldin A, but was blocked by cytochalasin D as well as chloroquine. Finally, B6 as well as TAP-1(-/-) splenic APC, loaded with heat-killed Sendai virus Ag in vitro, primed naive CD8+ T cells in vivo. These studies suggest the existence of a TAP-independent pathway for Ag presentation on MHC class I in normal splenic APC, bearing many similarities with the MHC class II pathway for Ag presentation. The present results are discussed in relation to the events underlying the processing and presentation of exogenous Ag on MHC class I, the molecular basis for CD8+ T cell priming during viral infections, and prospects for vaccine development.