Modes of Calreticulin Recruitment to the Major Histocompatibility Complex Class I Assembly Pathway

Major histocompatibility complex (MHC) class I molecules are ligands for T-cell receptors of CD8⁺ T cells and inhibitory receptors of natural killer cells. Assembly of the heavy chain, light chain, and peptide components of MHC class I molecules occurs in the endoplasmic reticulum (ER). Specific assembly factors and generic ER chaperones, collectively called the MHC class I peptide loading complex (PLC), are required for MHC class I assembly. Calreticulin has an important role within the PLC and induces MHC class I cell surface expression, but the interactions and mechanisms involved are incompletely understood. We show that interactions with the thiol oxidoreductase ERp57 and substrate glycans are important for the recruitment of calreticulin into the PLC and for its functional activities in MHC class I assembly. The glycan and ERp57 binding sites of calreticulin contribute directly or indirectly to complexes between calreticulin and the MHC class I assembly factor tapasin and are important for maintaining steady-state levels of both tapasin and MHC class I heavy chains. A number of destabilizing conditions and mutations induce generic polypeptide binding sites on calreticulin and contribute to calreticulin-mediated suppression of misfolded protein aggregation in vitro. We show that generic polypeptide binding sites per se are insufficient for stable recruitment of calreticulin to PLC substrates in cells. However, such binding sites could contribute to substrate stabilization in a step that follows the glycan and ERp57-dependent recruitment of calreticulin to the PLC.     

Dynamics of Major Histocompatibility Complex Class I Association with the Human Peptide-loading Complex

Although the human peptide-loading complex (PLC) is required for optimal major histocompatibility complex class I (MHC I) antigen presentation, its composition is still incompletely understood. The ratio of the transporter associated with antigen processing (TAP) and MHC I to tapasin, which is responsible for MHC I recruitment and peptide binding optimization, is particularly critical for modeling of the PLC. Here, we characterized the stoichiometry of the human PLC using both biophysical and biochemical approaches. By means of single-molecule pulldown (SiMPull), we determined a TAP/tapasin ratio of 1:2, consistent with previous studies of insect-cell microsomes, rat-human chimeric cells, and HeLa cells expressing truncated TAP subunits. We also report that the tapasin/MHC I ratio varies, with the PLC population comprising both 2:1 and 2:2 complexes, based on mutational and co-precipitation studies. The MHC I-saturated PLC may be particularly prevalent among peptide-selective alleles, such as HLA-C4. Additionally, MHC I association with the PLC increases when its peptide supply is reduced by inhibiting the proteasome or by blocking TAP-mediated peptide transport using viral inhibitors. Taken together, our results indicate that the composition of the human PLC varies under normal conditions and dynamically adapts to alterations in peptide supply that may arise during viral infection. These findings improve our understanding of the quality control of MHC I peptide loading and may aid the structural and functional modeling of the human PLC.     

Mauritian Cynomolgus Macaques Share Two Exceptionally Common Major Histocompatibility Complex Class I Alleles That Restrict Simian Immunodeficiency Virus-Specific CD8+ T Cells

Vaccines that elicit CD8⁺ T-cell responses are routinely tested for immunogenicity in nonhuman primates before advancement to clinical trials. Unfortunately, the magnitude and specificity of vaccine-elicited T-cell responses are variable in currently utilized nonhuman primate populations, owing to heterogeneity in major histocompatibility (MHC) class I genetics. We recently showed that Mauritian cynomolgus macaques (MCM) have unusually simple MHC genetics, with three common haplotypes encoding a shared pair of MHC class IA alleles, Mafa-A*25 and Mafa-A*29. Based on haplotype frequency, we hypothesized that CD8⁺ T-cell responses restricted by these MHC class I alleles would be detected in nearly all MCM. We examine here the frequency and functionality of these two alleles, showing that 88% of MCM express Mafa-A*25 and Mafa-A*29 and that animals carrying these alleles mount three newly defined simian immunodeficiency virus-specific CD8⁺ T-cell responses. The epitopes recognized by each of these responses accumulated substitutions consistent with immunologic escape, suggesting these responses exert antiviral selective pressure. The demonstration that Mafa-A*25 and Mafa-A*29 restrict CD8⁺ T-cell responses that are shared among nearly all MCM indicates that these animals are an advantageous nonhuman primate model for comparing the immunogenicity of vaccines that elicit CD8⁺ T-cell responses.The immunogenicity and efficacy of vaccines intended for human use are commonly evaluated in rhesus and cynomolgus macaques. Indeed, researchers studied an estimated one million macaques in the search for a polio vaccine (5). More recently, these animals have become the dominant preclinical model for human immunodeficiency virus (HIV) vaccine evaluation. Rhesus and cynomolgus macaques are susceptible to infection with pathogenic strains of simian immunodeficiency virus (SIV), lentiviruses that share close genetic homology to HIV and cause AIDS-defining illnesses (11, 14). Vaccines designed to provide sterilizing immunity or control immunodeficiency virus replication can therefore be evaluated in macaques. In addition, the immune systems of humans and macaques are highly similar, providing hope that promising vaccines in macaques can be readily adapted for use in humans.CD8⁺ T cells are particularly attractive candidates for vaccine development. Several lines of evidence indicate that CD8⁺ T cells are important to the control of HIV/SIV viral replication. Expansion of HIV/SIV-specific CD8⁺ T cells during acute viremia is associated with a sharp decline in viral load (6, 21, 50), while the depletion of CD8⁺ cells in SIV-infected macaques results in increased viral loads (13, 27) and abrogates the protection elicited by live, attenuated vaccination (30, 38). Furthermore, major histocompatibility complex (MHC) genotyping studies have identified multiple MHC class I alleles enriched in human and macaque elite controllers (17, 19, 26, 31, 49).Recently, Merck and the HIV Vaccine Trials Network cancelled a phase IIb clinical trial evaluating an HIV vaccine designed to elicit CD8⁺ T-cell immunity. An interim analysis revealed the vaccine was ineffective and that participants with prior immunity to the vaccine vector actually had a higher incidence of HIV infection (7, 28, 39, 43). Dozens of additional vaccines that aim to elicit CD8⁺ T cells are in various stages of preclinical and early-stage clinical development, and testing these vaccines in macaques will provide the proof-of-concept necessary to predict their success.Unfortunately, it has been impossible to definitively associate the breadth, magnitude, or phenotype of SIV-specific CD8⁺ T-cell responses, elicited by competing vaccine modalities, to viral control. Indian rhesus macaques are the most commonly used model for HIV vaccine testing but have extremely diverse MHC class I genetics, giving rise to heterogeneous CD8⁺ T-cell responses. SIV derived CD8⁺ T-cell epitopes have been defined for eight Indian rhesus macaque MHC class I alleles (24). However, more than 400 classical MHC class I alleles have been identified in rhesus macaques, leaving an enormous gap in our understanding of the overall CD8⁺ T-cell repertoire following SIV infection (37). Identifying large cohorts of Indian rhesus macaques matched for one or more MHC class I alleles, and thus predicted to mount CD8⁺ T-cell responses against the same epitopes, is both difficult and expensive. An abundant nonhuman primate model with limited MHC diversity could standardize testing of each new vaccine entering preclinical development. Indeed, head-to-head testing of CD8⁺ T-cell vaccines is essential to maximize the efficiency of the global vaccine enterprise and prioritize rapid advancement of promising candidates.In contrast to Indian rhesus macaques, Mauritian cynomolgus macaques (MCM) are an insular population that expanded from a small number of founder animals (23) over the last 500 years. The unique natural history of these animals is manifest by exceptionally low genetic diversity. We have characterized the MHC genetics of this population and found only seven common haplotypes containing fewer than 30 MHC class I alleles (12, 48). The three most common MHC haplotypes each express Mafa-A*25 and Mafa-A*29. We examine here the frequency and functionality of these two alleles, showing that 88% of MCM express Mafa-A*25 and Mafa-A*29 and that animals carrying these alleles mount three newly defined SIV-specific CD8⁺ T-cell responses that drive SIV variation. These results suggest that MCM will provide an exceptionally valuable resource for head-to-head evaluations of competing vaccine modalities.     

Contribution of Lysine 11-linked Ubiquitination to MIR2-mediated Major Histocompatibility Complex Class I Internalization

The polyubiquitin chain is generated by the sequential addition of ubiquitin moieties to target molecules, a reaction between specific lysine residues that is catalyzed by E3 ubiquitin ligase. The Lys⁴⁸-linked and Lys⁶³-linked polyubiquitin chains are well established inducers of proteasome-dependent degradation and signal transduction, respectively. The concept has recently emerged that polyubiquitin chain-mediated regulation is even more complex because various types of atypical polyubiquitin chains have been discovered in vivo. Here, we demonstrate that a novel complex ubiquitin chain functions as an internalization signal for major histocompatibility complex class I (MHC I) membrane proteins in vivo. Using a tetracycline-inducible expression system and quantitative mass spectrometry, we show that the polyubiquitin chain generated by the viral E3 ubiquitin ligase of Kaposi sarcoma-associated herpesvirus, MIR2, is a Lys¹¹ and Lys⁶³ mixed-linkage chain. This novel ubiquitin chain can function as an internalization signal for MHC I through its association with epsin1, an adaptor molecule containing ubiquitin-interacting motifs.     

Distortion of the Major Histocompatibility Complex Class I Binding Groove to Accommodate an Insulin-derived 10-Mer Peptide

The non-obese diabetic mouse model of type 1 diabetes continues to be an important tool for delineating the role of T-cell-mediated destruction of pancreatic β-cells. However, little is known about the molecular mechanisms that enable this disease pathway. We show that insulin reactivity by a CD8⁺ T-cell clone, known to induce type 1 diabetes, is characterized by weak T-cell antigen receptor binding to a relatively unstable peptide-MHC. The structure of the native 9- and 10-mer insulin epitopes demonstrated that peptide residues 7 and 8 form a prominent solvent-exposed bulge that could potentially be the main focus of T-cell receptor binding. The C terminus of the peptide governed peptide-MHC stability. Unexpectedly, we further demonstrate a novel mode of flexible peptide presentation in which the MHC peptide-binding groove is able to “open the back door” to accommodate extra C-terminal peptide residues.     

Susceptibility to HLA-DM Protein Is Determined by a Dynamic Conformation of Major Histocompatibility Complex Class II Molecule Bound with Peptide

HLA-DM mediates the exchange of peptides loaded onto MHCII molecules during antigen presentation by a mechanism that remains unclear and controversial. Here, we investigated the sequence and structural determinants of HLA-DM interaction. Peptides interacting nonoptimally in the P1 pocket exhibited low MHCII binding affinity and kinetic instability and were highly susceptible to HLA-DM-mediated peptide exchange. These changes were accompanied by conformational alterations detected by surface plasmon resonance, SDS resistance assay, antibody binding assay, gel filtration, dynamic light scattering, small angle x-ray scattering, and NMR spectroscopy. Surprisingly, all of those changes could be reversed by substitution of the P9 pocket anchor residue. Moreover, MHCII mutations outside the P1 pocket and the HLA-DM interaction site increased HLA-DM susceptibility. These results indicate that a dynamic MHCII conformational determinant rather than P1 pocket occupancy is the key factor determining susceptibility to HLA-DM-mediated peptide exchange and provide a molecular mechanism for HLA-DM to efficiently target unstable MHCII-peptide complexes for editing and exchange those for more stable ones.     

Mycobacterium tuberculosis Promotes HIV trans-Infection and Suppresses Major Histocompatibility Complex Class II Antigen Processing by Dendritic Cells

Mycobacterium tuberculosis is a leading killer of HIV-infected individuals worldwide, particularly in sub-Saharan Africa, where it is responsible for up to 50% of HIV-related deaths. Infection by HIV predisposes individuals to M. tuberculosis infection, and coinfection accelerates the progression of both diseases. In contrast to most other opportunistic infections associated with HIV, an increased risk of M. tuberculosis infection occurs during early-stage HIV disease, long before CD4 T cell counts fall below critical levels. We hypothesized that M. tuberculosis infection contributes to HIV pathogenesis by interfering with dendritic cell (DC)-mediated immune control. DCs carry pathogens like M. tuberculosis and HIV from sites of infection into lymphoid tissues, where they process and present antigenic peptides to CD4 T cells. Paradoxically, DCs can also deliver infectious HIV to T cells without first becoming infected, a process known as trans-infection. Lipopolysaccharide (LPS)-activated DCs sequester HIV in pocketlike membrane invaginations that remain open to the cell surface, and individual virions are delivered from the pocket into T cells at the site of contact during trans-infection. Here we report that M. tuberculosis exposure increases HIV trans-infection and induces viral sequestration within surface-accessible compartments identical to those seen in LPS-stimulated DCs. At the same time, M. tuberculosis dramatically decreases the degradative processing and major histocompatibility complex class II (MHC-II) presentation of HIV antigens to CD4 T cells. Our data suggest that M. tuberculosis infection promotes a shift in the dynamic balance between antigen processing and intact virion presentation, favoring DC-mediated amplification of HIV infections.Dendritic cells (DCs) comprise a diverse family of cell types whose primary function is to initiate and drive immune responses. Myeloid DCs (myDCs) are essential antigen-presenting cells that monitor peripheral tissues for invading pathogens. myDCs bind and internalize bacteria and viruses using a variety of surface receptors. When stimulated by pathogenic or inflammatory signals, peripheral-tissue DCs migrate to lymphoid tissues and undergo maturation, degrading stored antigens into peptides that are loaded onto major histocompatibility complex class II (MHC-II) molecules and expressed on the cell surface for presentation to CD4 T cells (reviewed in reference 4). In addition to presentation of processed peptide antigens, DCs carry intact, unprocessed proteins and pathogens from peripheral tissues to lymph nodes, where they can be passed to other antigen-presenting cells to increase the breadth of the immune response (reviewed in reference 10).HIV can exploit the natural trafficking of DCs to establish and amplify infection of CD4 T cells. DCs efficiently transfer intact, infectious HIV to T cells during immune interactions through a process known as trans-infection (14). DCs trans-infect HIV by binding and concentrating the intact virus at the cellular interface, forming an “infectious synapse” that concentrates HIV receptors on the T cell to the same site (24). Importantly, trans-infection does not require productive infection of the DCs, which are not infected efficiently by HIV in vitro or in vivo (14). Immature DCs significantly enhance infection of T cells through trans-infection, and prior activation by cytokine or bacterial stimuli markedly increases infectious synapse formation and concomitant trans-infection (2, 24, 33).Worldwide, nearly one-third of HIV-infected people are coinfected with Mycobacterium tuberculosis, and active tuberculosis disease (TB) is the number one cause of death in HIV-infected people. Coinfected individuals are 30 times more likely to progress to active TB, which can in turn increase HIV replication and accelerate the progression to AIDS (35). The mechanisms by which coinfection with M. tuberculosis and HIV accelerates the progression of both diseases are poorly understood.Lung macrophages are the primary target of M. tuberculosis infection, and active disease is characterized by unconstrained replication in these cells. Dendritic cells can also be infected by M. tuberculosis, but M. tuberculosis growth is restricted due to a lack of nutrient access in the DC phagolysosomal structure in which it resides (20). Importantly, M. tuberculosis-infected DCs traffic between the infected lung and draining lymph nodes, bringing bacterial antigens into lymphoid tissues to initiate CD4 T cell responses essential for disease control (39).Others have established that M. tuberculosis binds to and is internalized by DCs via an interaction between the mycobacterial cell wall component mannosylated lipoarabinomannan (ManLAM) and the cell surface receptor DC-SIGN on dendritic cells (15). After ManLAM stimulation, DCs begin to secrete interleukin-10 (IL-10) and show defects in immunostimulatory functions (15). However, a more recent study suggests that ManLAM may not be solely responsible for these outcomes (1).Previously, it has been shown that lipopolysaccharide (LPS) potently stimulates HIV trans-infection of CD4 T cells by DCs (24, 33). Therefore, we reasoned that M. tuberculosis and its products might similarly stimulate DC trans-infection during active M. tuberculosis infections. Further, we hypothesized that DC activation by M. tuberculosis would result in downmodulation of processing and MHC-II presentation of newly bound HIV particles, shifting the balance away from immune control in favor of viral dissemination and pathogenesis.Here, we demonstrate that M. tuberculosis infection of DCs enhances HIV trans-infection mediated through surface-accessible, pocketlike invaginations of the plasma membrane. Increased HIV trans-infection is accompanied by decreased MHC-II processing and presentation of HIV antigens to CD4 T cells. Our results suggest one mechanism whereby M. tuberculosis infection can fuel HIV dissemination in coinfected individuals and at the same time decrease immune control of both HIV and M. tuberculosis infections.     

Mechanisms of Function of Tapasin,a Critical Major Histocompatibility Complex Class I Assembly Factor

For their efficient assembly in the endoplasmic reticulum (ER), major histocompatibility complex (MHC) class I molecules require the specific assembly factors transporter associated with antigen processing (TAP) and tapasin, as well as generic ER folding factors, including the oxidoreductases ERp57 and protein disulfide isomerase (PDI), and the chaperone calreticulin. TAP transports peptides from the cytosol into the ER. Tapasin promotes the assembly of MHC class I molecules with peptides. The formation of disulfide‐linked conjugates of tapasin with ERp57 is suggested to be crucial for tapasin function. Important functional roles are also suggested for the tapasin transmembrane and cytoplasmic domains, sites of tapasin interaction with TAP. We show that interactions of tapasin with both TAP and ERp57 are correlated with strong MHC class I recruitment and assembly enhancement. The presence of the transmembrane/cytosolic regions of tapasin is critical for efficient tapasin–MHC class I binding in interferon‐γ‐treated cells, and contributes to an ERp57‐independent mode of MHC class I assembly enhancement. A second ERp57‐dependent mode of tapasin function correlates with enhanced MHC class I binding to tapasin and calreticulin. We also show that PDI binds to TAP in a tapasin‐independent manner, but forms disulfide‐linked conjugates with soluble tapasin. Thus, full‐length tapasin is important for enhancing recruitment of MHC class I molecules and increasing specificity of tapasin–ERp57 conjugation. Furthermore, tapasin or the TAP/tapasin complex has an intrinsic ability to recruit MHC class I molecules and promote assembly, but also uses generic folding factors to enhance MHC class I recruitment and assembly.     

Mechanism for Amyloid Precursor-like Protein 2 Enhancement of Major Histocompatibility Complex Class I Molecule Degradation

Earlier studies have demonstrated interaction of the murine major histocompatibility complex (MHC) class I molecule K^d with amyloid precursor-like protein 2 (APLP2), a ubiquitously expressed member of the amyloid precursor protein family. Our current findings indicate that APLP2 is internalized in a clathrin-dependent manner, as shown by utilization of inhibitors of the clathrin pathway. Furthermore, we demonstrated that APLP2 and K^d bind at the cell surface and are internalized together. The APLP2 cytoplasmic tail contains two overlapping consensus motifs for binding to the adaptor protein-2 complex, and mutation of a tyrosine shared by both motifs severely impaired APLP2 internalization and ability to promote K^d endocytosis. Upon increased expression of wild type APLP2, K^d molecules were predominantly directed to the lysosomes rather than recycled to the plasma membrane. These findings suggest a model in which APLP2 binds K^d at the plasma membrane, facilitates uptake of K^d in a clathrin-dependent manner, and routes the endocytosed K^d to the lysosomal degradation pathway. Thus, APLP2 has a multistep trafficking function that influences the expression of major histocompatibility complex class I molecules at the plasma membrane.     

Us3 Kinase Encoded by Herpes Simplex Virus 1 Mediates Downregulation of Cell Surface Major Histocompatibility Complex Class I and Evasion of CD8+ T Cells

Detection and elimination of virus-infected cells by CD8⁺ cytotoxic T lymphocytes (CTLs) depends on recognition of virus-derived peptides presented by major histocompatibility complex class I (MHC-I) molecules on the surface of infected cells. In the present study, we showed that inactivation of the activity of viral kinase Us3 encoded by herpes simplex virus 1 (HSV-1), the etiologic agent of several human diseases and a member of the alphaherpesvirinae, significantly increased cell surface expression of MHC-I, thereby augmenting CTL recognition of infected cells in vitro. Overexpression of Us3 by itself had no effect on cell surface expression of MHC-I and Us3 was not able to phosphorylate MHC-I in vitro, suggesting that Us3 indirectly downregulated cell surface expression of MHC-I in infected cells. We also showed that inactivation of Us3 kinase activity induced significantly more HSV-1-specific CD8⁺ T cells in mice. Interestingly, depletion of CD8⁺ T cells in mice significantly increased replication of a recombinant virus encoding a kinase-dead mutant of Us3, but had no effect on replication of a recombinant virus in which the kinase-dead mutation was repaired. These results indicated that Us3 kinase activity is required for efficient downregulation of cell surface expression of MHC-I and mediates evasion of HSV-1-specific CD8⁺ T cells. Our results also raised the possibility that evasion of HSV-1-specific CD8⁺ T cells by HSV-1 Us3-mediated inhibition of MHC-I antigen presentation might in part contribute to viral replication in vivo.     

Peptide Modulation of Class I Major Histocompatibility Complex Protein Molecular Flexibility and the Implications for Immune Recognition

T cells use the αβ T cell receptor (TCR) to recognize antigenic peptides presented by class I major histocompatibility complex proteins (pMHCs) on the surfaces of antigen-presenting cells. Flexibility in both TCRs and peptides plays an important role in antigen recognition and discrimination. Less clear is the role of flexibility in the MHC protein; although recent observations have indicated that mobility in the MHC can impact TCR recognition in a peptide-dependent fashion, the extent of this behavior is unknown. Here, using hydrogen/deuterium exchange, fluorescence anisotropy, and structural analyses, we show that the flexibility of the peptide binding groove of the class I MHC protein HLA-A*0201 varies significantly with different peptides. The variations extend throughout the binding groove, impacting regions contacted by TCRs as well as other activating and inhibitory receptors of the immune system. Our results are consistent with statistical mechanical models of protein structure and dynamics, in which the binding of different peptides alters the populations and exchange kinetics of substates in the MHC conformational ensemble. Altered MHC flexibility will influence receptor engagement, impacting conformational adaptations, entropic penalties associated with receptor recognition, and the populations of binding-competent states. Our results highlight a previously unrecognized aspect of the “altered self” mechanism of immune recognition and have implications for specificity, cross-reactivity, and antigenicity in cellular immunity.     

Disruption of Hydrogen Bonds between Major Histocompatibility Complex Class II and the Peptide N-Terminus Is Not Sufficient to Form a Human Leukocyte Antigen-DM Receptive State of Major Histocompatibility Complex Class II

Peptide presentation by MHC class II is of critical importance to the function of CD4+ T cells. HLA-DM resides in the endosomal pathway and edits the peptide repertoire of newly synthesized MHC class II molecules before they are exported to the cell surface. HLA-DM ensures MHC class II molecules bind high affinity peptides by targeting unstable MHC class II:peptide complexes for peptide exchange. Research over the past decade has implicated the peptide N-terminus in modulating the ability of HLA-DM to target a given MHC class II:peptide combination. In particular, attention has been focused on both the hydrogen bonds between MHC class II and peptide, and the occupancy of the P1 anchor pocket. We sought to solve the crystal structure of a HLA-DR1 molecule containing a truncated hemagglutinin peptide missing three N-terminal residues compared to the full-length sequence (residues 306–318) to determine the nature of the MHC class II:peptide species that binds HLA-DM. Here we present structural evidence that HLA-DR1 that is loaded with a peptide truncated to the P1 anchor residue such that it cannot make select hydrogen bonds with the peptide N-terminus, adopts the same conformation as molecules loaded with full-length peptide. HLA-DR1:peptide combinations that were unable to engage up to four key hydrogen bonds were also unable to bind HLA-DM, while those truncated to the P2 residue bound well. These results indicate that the conformational changes in MHC class II molecules that are recognized by HLA-DM occur after disengagement of the P1 anchor residue.     

Equus caballus Major Histocompatibility Complex Class I Is an Entry Receptor for Equine Herpesvirus Type 1

In this study, Equus caballus major histocompatibility complex class I (MHC-I) was identified as a cellular entry receptor for the alphaherpesvirus equine herpesvirus type 1 (EHV-1). This novel EHV-1 receptor was discovered using a cDNA library from equine macrophages. cDNAs from this EHV-1-susceptible cell type were inserted into EHV-1-resistant B78H1 murine melanoma cells, these cells were infected with an EHV-1 lacZ reporter virus, and cells that supported virus infection were identified by X-Gal (5-bromo-4-chloro-3-indolyl-β-d-galactopyranoside) staining. Positive cells were subjected to several rounds of purification to obtain homogeneous cell populations that were shown to be uniformly infected with EHV-1. cDNAs from these cell populations were amplified by PCR and then sequenced. The sequence data revealed that the EHV-1-susceptible cells had acquired an E. caballus MHC-I cDNA. Cell surface expression of this receptor was verified by confocal immunofluorescence microscopy. The MHC-I cDNA was cloned into a mammalian expression vector, and stable B78H1 cell lines were generated that express this receptor. These cell lines were susceptible to EHV-1 infection while the parental B78H1 cells remained resistant to infection. In addition, EHV-1 infection of the B78H1 MHC-I-expressing cell lines was inhibited in a dose-dependent manner by an anti-MHC-I antibody.Equine herpesvirus type 1 (EHV-1) is a major pathogen affecting horses worldwide. Clinical signs of infection range from initial respiratory distress, fever, inappetance, and malaise to more serious secondary conditions including paralysis in some cases and abortigenic disease in pregnant mares (2). The virus is readily spread via direct transmission from horse to horse or via contact with contaminated surroundings. Due to the latent program of the virus, there is a constant reservoir of EHV-1 within the equine population, and frequent reactivation events trigger outbreaks and expose naïve horses to the virus (35).At the cellular level, EHV-1 initially attaches to cells via an interaction between two of its glycoproteins, gC and gB, and cell surface heparin sulfate (36, 41). While these electrostatic interactions mediate virus binding, they do not trigger the entry of the virus into cells. For entry to proceed, a secondary triggering event mediated by gD must occur (10, 14). After entry is initiated, EHV-1 enters cells either by directly fusing with the plasma membrane or via endocytosis (17). After fusion between the viral envelope and a cellular membrane, viral capsids are released into the cytoplasm and then actively transported to the nucleus along microtubules (18).Previous studies showed that EHV-1 utilizes a cell receptor that is distinct from any of the known alphaherpesvirus entry receptors (14). The goal of the present study was to identify a functional EHV-1 entry receptor by screening an equine macrophage cDNA library. To identify a receptor, we transferred equine cDNAs (48) from an equine macrophage library into cells that are highly resistant to EHV-1. These cDNA-transduced cells were then screened for their ability to mediate EHV-1 infection. Using this approach, we successfully converted a set of highly resistant cells to a state of complete susceptibility to EHV-1. From this converted set of cells, we amplified and sequenced the incorporated equine cDNA. The sequencing results revealed that the equine cDNA isolated from our screen codes for Equus caballus major histocompatibility complex class I (MHC-I) protein, and further assays confirmed that this receptor is utilized by EHV-1 for entry into cells.     

Cyclophilin C Participates in the US2-Mediated Degradation of Major Histocompatibility Complex Class I Molecules

Human cytomegalovirus uses a variety of mechanisms to evade immune recognition through major histocompatibility complex class I molecules. One mechanism mediated by the immunoevasin protein US2 causes rapid disposal of newly synthesized class I molecules by the endoplasmic reticulum-associated degradation pathway. Although several components of this degradation pathway have been identified, there are still questions concerning how US2 targets class I molecules for degradation. In this study we identify cyclophilin C, a peptidyl prolyl isomerase of the endoplasmic reticulum, as a component of US2-mediated immune evasion. Cyclophilin C could be co-isolated with US2 and with the class I molecule HLA-A2. Furthermore, it was required at a particular expression level since depletion or overexpression of cyclophilin C impaired the degradation of class I molecules. To better characterize the involvement of cyclophilin C in class I degradation, we used LC-MS/MS to detect US2-interacting proteins that were influenced by cyclophilin C expression levels. We identified malectin, PDIA6, and TMEM33 as proteins that increased in association with US2 upon cyclophilin C knockdown. In subsequent validation all were shown to play a functional role in US2 degradation of class I molecules. This was specific to US2 rather than general ER-associated degradation since depletion of these proteins did not impede the degradation of a misfolded substrate, the null Hong Kong variant of α₁-antitrypsin.     

Possible Polyphyletic Origin of Major Histocompatibility Complex Class I Chain-Related Gene A (MICA) Alleles

Phylogenetic relationships among 23 nonhuman primate (NHP) major histocompatibility complex class I chain-related gene (MIC) sequences, 54 confirmed human MICA alleles, and 16 human MICE alleles were constructed with methods of sequence analysis. Topology of the phylogenetic tree showed separation between NHP MICs and human MICs. For human MICs, the topology indicated monophyly for the MICB alleles, while MICA alleles were separated into two lineages, LI and LII. Of these, LI MICA alleles shared a common ancestry with gorilla (Ggo) MIC. One conservative amino acid difference and two nonconservative amino acid differences in the 3 domain were found between the MICA lineages. The nonconservative amino acid differences might imply structural and functional differences. Transmembrane (TM) trinucleotide-repeat variants were found to be specific to the MICA lineages such as A4, A9, and A10 to LI and A5 to LII. Variants such as A5.1 and A6 were commonly found in both MICA lineages. Based on these analyses, we postulate a polyphyletic origin for MICA alleles and their division into two lineages, LI and LII. As such, there would be 30 alleles in LI and 24 alleles in LII, thereby reducing the current level of polymorphism that exists, based on a presumed monophyletic origin. The lower degree of polymorphism in MICA would then be in line with the rest of the human major histocompatibility complex nonclassical class I genes.