Polymorphism in Human Cytomegalovirus UL40 Impacts on Recognition of Human Leukocyte Antigen-E (HLA-E) by Natural Killer Cells*

Background: Human cytomegalovirus (CMV) can manipulate natural killer (NK) cell function. Results: Polymorphisms in UL40 modulate the interaction between HLA-E and activating and inhibitory CD94-NKG2 receptors. Conclusion: Variation in UL40 may provide a further mechanism for CMV to control NK cell function. Significance: CMV persistence may be enhanced by modifying NK cell function. Natural killer (NK) cell recognition of the nonclassical human leukocyte antigen (HLA) molecule HLA-E is dependent on the presentation of a nonamer peptide derived from the leader sequence of other HLA molecules to CD94-NKG2 receptors. However, human cytomegalovirus can manipulate this central innate interaction through the provision of a “mimic” of the HLA-encoded peptide derived from the immunomodulatory glycoprotein UL40. Here, we analyzed UL40 sequences isolated from 32 hematopoietic stem cell transplantation recipients experiencing cytomegalovirus reactivation. The UL40 protein showed a “polymorphic hot spot” within the region that encodes the HLA leader sequence mimic. Although all sequences that were identical to those encoded within HLA-I genes permitted the interaction between HLA-E and CD94-NKG2 receptors, other UL40 polymorphisms reduced the affinity of the interaction between HLA-E and CD94-NKG2 receptors. Furthermore, functional studies using NK cell clones expressing either the inhibitory receptor CD94-NKG2A or the activating receptor CD94-NKG2C identified UL40-encoded peptides that were capable of inhibiting target cell lysis via interaction with CD94-NKG2A, yet had little capacity to activate NK cells through CD94-NKG2C. The data suggest that UL40 polymorphisms may aid evasion of NK cell immunosurveillance by modulating the affinity of the interaction with CD94-NKG2 receptors.

[1]  Y. Aida,et al.  Identification of bovine leukocyte antigen class II haplotypes associated with variations in bovine leukemia virus proviral load in Japanese Black cattle. , 2013, Tissue antigens.

[2]  P. Tomasec,et al.  Human Cytomegalovirus UL40 Signal Peptide Regulates Cell Surface Expression of the NK Cell Ligands HLA-E and gpUL18 , 2012, The Journal of Immunology.

[3]  Y. Aida,et al.  The diversity of bovine MHC class II DRB3 and DQA1 alleles in different herds of Japanese Black and Holstein cattle in Japan. , 2011, Gene.

[4]  A. Angulo,et al.  NKp46 and DNAM-1 NK-cell receptors drive the response to human cytomegalovirus-infected myeloid dendritic cells overcoming viral immune evasion strategies. , 2011, Blood.

[5]  J. Velly,et al.  Variability and recombination of clinical human cytomegalovirus strains from transplantation recipients. , 2010, Journal of clinical virology : the official publication of the Pan American Society for Clinical Virology.

[6]  H. Fleury,et al.  UL40 Human Cytomegalovirus Variability Evolution Patterns Over Time in Renal Transplant Recipients , 2008, Transplantation.

[7]  Jamie Rossjohn,et al.  Subtle changes in peptide conformation profoundly affect recognition of the non-classical MHC class I molecule HLA-E by the CD94-NKG2 natural killer cell receptors. , 2008, Journal of molecular biology.

[8]  T. Beddoe,et al.  CD94-NKG2A recognition of human leukocyte antigen (HLA)-E bound to an HLA class I leader sequence , 2008, The Journal of experimental medicine.

[9]  P. Tomasec,et al.  Modulation of natural killer cells by human cytomegalovirus. , 2008, Journal of clinical virology : the official publication of the Pan American Society for Clinical Virology.

[10]  J. Coligan,et al.  The heterodimeric assembly of the CD94-NKG2 receptor family and implications for human leukocyte antigen-E recognition. , 2007, Immunity.

[11]  H. Fleury,et al.  Variability of UL18, UL40, UL111a and US3 immunomodulatory genes among human cytomegalovirus clinical isolates from renal transplant recipients. , 2007, Journal of clinical virology : the official publication of the Pan American Society for Clinical Virology.

[12]  Roberta Castriconi,et al.  Surface NK receptors and their ligands on tumor cells. , 2006, Seminars in immunology.

[13]  A. Angulo,et al.  Expansion of CD94/NKG2C+ NK cells in response to human cytomegalovirus-infected fibroblasts. , 2006, Blood.

[14]  Roland K. Strong,et al.  Interactions between NKG2x Immunoreceptors and HLA-E Ligands Display Overlapping Affinities and Thermodynamics1 , 2005, The Journal of Immunology.

[15]  A. McMichael,et al.  Requirement of the Proteasome for the Trimming of Signal Peptide-derived Epitopes Presented by the Nonclassical Major Histocompatibility Complex Class I Molecule HLA-E* , 2003, Journal of Biological Chemistry.

[16]  J. Altman,et al.  Analysis of HLA-E Peptide-Binding Specificity and Contact Residues in Bound Peptide Required for Recognition by CD94/NKG2 1 , 2003, The Journal of Immunology.

[17]  R. Strong,et al.  CORRELATING DIFFERENTIAL EXPRESSION, PEPTIDE AFFINITIES, CRYSTAL STRUCTURES, AND THERMAL STABILITIES* , 2003 .

[18]  J. Yewdell,et al.  Viral interference with antigen presentation , 2002, Nature Immunology.

[19]  T. Bellón,et al.  Differential expression of inhibitory and activating CD94/NKG2 receptors on NK cell clones. , 2002, Journal of immunological methods.

[20]  P. Tomasec,et al.  UL40-mediated NK evasion during productive infection with human cytomegalovirus , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[21]  E. Carbone,et al.  Synergistic effect of IFN‐γ and human cytomegalovirus protein UL40 in the HLA‐E‐dependent protection from NK cell‐mediated cytotoxicity , 2001, European journal of immunology.

[22]  J. Ellwart,et al.  Cutting Edge: The Human Cytomegalovirus UL40 Gene Product Contains a Ligand for HLA-E and Prevents NK Cell-Mediated Lysis1 , 2000, The Journal of Immunology.

[23]  A. McMichael,et al.  Surface expression of HLA-E, an inhibitor of natural killer cells, enhanced by human cytomegalovirus gpUL40. , 2000, Science.

[24]  J. Strominger,et al.  Molecular analyses of the interactions between human NK receptors and their HLA ligands. , 2000, Human immunology.

[25]  J. Strominger,et al.  Kinetics and peptide dependency of the binding of the inhibitory NK receptor CD94/NKG2‐A and the activating receptor CD94/NKG2‐C to HLA‐E , 1999, The EMBO journal.

[26]  J. Coligan,et al.  Specific recognition of HLA-E, but not classical, HLA class I molecules by soluble CD94/NKG2A and NK cells. , 1999, Journal of immunology.

[27]  M. Llano,et al.  HLA‐E‐bound peptides influence recognition by inhibitory and triggering CD94/NKG2 receptors: preferential response to an HLA‐G‐derived nonamer , 1998, European journal of immunology.

[28]  J. Coligan,et al.  Recognition of Human Histocompatibility Leukocyte Antigen (HLA)-E Complexed with HLA Class I Signal Sequence–derived Peptides by CD94/NKG2 Confers Protection from Natural Killer Cell–mediated Lysis , 1998, The Journal of experimental medicine.

[29]  D. Stuart,et al.  Structural features impose tight peptide binding specificity in the nonclassical MHC molecule HLA-E. , 1998, Molecular cell.

[30]  J. Bell,et al.  HLA-E binds to natural killer cell receptors CD94/NKG2A, B and C , 1998, Nature.

[31]  A. McMichael,et al.  TAP- and tapasin-dependent HLA-E surface expression correlates with the binding of an MHC class I leader peptide , 1998, Current Biology.

[32]  K. Fish,et al.  Reactivation of Latent Human Cytomegalovirus by Allogeneic Stimulation of Blood Cells from Healthy Donors , 1997, Cell.

[33]  M. Carretero,et al.  The CD94 and NKG2‐A C‐type lectins covalently assemble to form a natural killer cell inhibitory receptor for HLA class I molecules , 1997, European journal of immunology.

[34]  Roderic D. M. Page,et al.  TreeView: an application to display phylogenetic trees on personal computers , 1996, Comput. Appl. Biosci..

[35]  R. Biassoni,et al.  In vitro expansion of CD3/TCR- human thymocyte populations that selectively lack CD3 delta gene expression: a phenotypic and functional analysis , 1990, The Journal of experimental medicine.

[36]  G von Heijne,et al.  Patterns of amino acids near signal-sequence cleavage sites. , 1983, European journal of biochemistry.