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Inhibitory MHC class I receptors on NK cells and T cells
IMMUNOLOGY
TODAY
Inhibitory MHC class NK cells Phillips
Lewis L. Lanier and Joseph
and
they
DeMars9:
demonstrated
that
human NK cells kill MHC class I-deficient Epstein-Barr
virus
lymphoblastoid
(EBVJ-transformed
B-
cell lines (e.g. the ClR or
721.221 cell lines), but fail to lyse these cell
tempts to generate tumor-specific cytotoxic T lymphocytes (CTLs). In the absence of
lines when transfected
with certain HLA-A
deliberate immunization, lymphocytes from control animals killed certain tumor cell
or -B genes. Moreover, NK cells could dis-
lines, and since this activity was also pres-
ing wild-type HLA-A2 and HLA-A2 with a
ent in athymic mice, a novel cell type was proposed to be responsible for this function.
site-directed mutation at amino acid 74 in the 0~~domain’O. An analysis of NK-cell
NK cells are capable of lysing tumor cells that express allogeneic major histocompat-
clones indicated
ibility complex (MHC) antigens
alleles and demonstrate
criminate between ClR target cells express-
that individual
can recognize multiple
or tumors
that completely lack MHC molecules. Thus, in contrast to the prevailing evidence for MHC restriction of T-cell recognition, NK cells were considered ‘MHC unrestricted’. However, observations by Karre and colleagues’ suggested that NK cells might in fact serve a unique role in the immune system by
in class I recognition”.
clonal diversity These findings pre-
dicted the existence of multiple NK-cell receptors polymorphic
MHC class I determinants
NK cells
HLA-A, -B and -C
that recognize
and ,ransmit an inhibitory
signal to prevent NK cells from killing target cells that express certain HLA alleles.
detecting and eliminating cells that had lost expression of MI-K class I molecules. This clever strategy may represent the first exMurine inhibitory receptors for polymorphic I-i-2
ample of a biological defense against the stealth technology that is used by certain viruses to evade T-cell recognition by disrupting
molecules
MHC synthesis. The concept of surveillance for ‘missing self-MHC’
While studying
was proposed in 1986, but only a decade later are we beginning to understand the molecular mechanisms responsible for this process.
tiation antigen, Yokoyama and colleagues12 observed that Ly-49A+
the distribution
of the murine
Ly-49A differen-
NK cells were unable to kill H-2Dd ar.d H-2Dk tumor cells, whereas
There is an emerging consensus that NK-cell recognition is regu-
Ly-49A- NK cells efficiently lysed these targets. This suggests that
lated by a delicate balance between positive signals that initiate their effector cell function and inhib:tory signals that prevent cy-
interactions between the Ly-49A receptor and its H-2 ligand on the
tolysis. NK cells can be activated ‘oy the interaction of several mem-
direct binding of Ly-49A to H-2Dd molecules, formally proving that
brane receptors (e.g. CD2, CD16, CD69 and NKF-Pl) with their li-
Ly-49A is a receptor for MHC (Refs 13, 14). Ly-49A interacts with
gands or monoclonal antibodies
(mAbs)2-7. At present, there is no
evidence for a unique NK-cell-specific
receptor that is responsible
target cell inactivate the NK cell. Subsequent experiments have shown
the 0~~and (Yedomains of H-2 (Ref. 12) and ligand recognition apparently requires a stable peptide-H-2
complex. Correa and Rauleti5
for initiating the cytolytic response; rather, it is likely that different receptors may be used depending upon the activation state of the
have shown that Ly-49A+ NK cells can r lcognize a diverse array of
NK cell and the availability of the relevant ligands on the target cell. In contrast to the limited understanding of the molecules re-
self-peptides
sponsible for positive signaling in NK cells, the involvement
peptides.
of re-
peptides bound to H-2Dd molecules, but are unable to distinguish from peptides of viral or bacterial origin; thus, NK-ceil
receptors do not necessarily discriminate However,
between self- and foreign-
evidence has been presented
ceptors in negative signaling is well defined: it is now clear that NK
that NK cells may be capable of distinguishing
cells possess receptors for polymorphic
molecules with different bound peptidesi6.
MHC class I molecules on
potential target cells, and these receptors apparently nals that prevent NK-cell-mediated cytotoxicity. Direct evidence for NK-cell recognition
transmit sig-
of MHC class I mol-
ecules was provided by the studies of Storkus et nl.8 and Shimizu 0 ! 996
E serer Scence Ltd 0167-5699196cS15
FEBRUARY
‘IO
1996
to demonstrate
between MHC class I
Ly-49A is one of at least seven closely related genes on mouse chromosome
6 that are preferentially
expressed
by NK cells*7-19.
These genes are memberr of the superfamily of C-type lectins and encode type II membrane proteins 17-i9.Although Ly-49 genes do not
IMMUNOLOGY
rearrange, there is evidence for alternative splicing and alfeiic polymorphism*8a19. mAbs have been generated
against
the Ly-49A,
TODAY
(a) Human KIR
Ly-49C and Ly-49G.2 glycoproteins, and used to demonstrate that these receptors are expressed as disulfide-bonded homodimers on subsets of NK cells20-23.Because the subsets of NK cells expressing
COOH
~58
P70
Ly-49A, Ly-49C and Ly-49G.2 overlap extensively, most NK cells
COOH
must express more than a single Ly-49 gene. Recent studies have indicated that only a single allele of each Ly-49 iocus may be transcribed in a single NK cell 24;however, the molecular mechanisms responsible for the transcriptional regulation of the Ly-49 genes have not been established. Since they are C-type lectins, the Ly-49 receptors may require carbohydrate
COOH
I
I
NH2
NH2
for ligand binding. In support of this notion, fucoidan
(a sulfated polysaccharide) between
I
I COOH
has been shown to inhibit interactions
Ly-49A or Ly-49C receptors
Nevertheless,
and their H-2 ligands2j,26.
Fig.
I. Strzlcturnl fentwes of(n) hunran killer-cell inhibiton/ wce,vtor (KIR)
md 07) mouse L!y-49 receptor
it is unlikely that the Ly-49 receptors discriminate
between different H-2 alleles on the basis of carbohydrate tion alone. Rather, the lectin interactions of Ly-49 to determinants
recogni-
may enhance the binding
of the H-2 polypeptide.
mains3’. Furthermore,
NKBl KIRs can recognize MHC class I heavy
chains that have been mutated to remove the site for N-linked glycosylation, indicating that carbohydrates are not required for receptor function37.
Inhibitory
C receptors for polymorphic
class I
Although the murine Ly-49 receptors demonstrate no structural homology with the human KIRs, there are striking similarities in
molecules
their distribution
In common with murine NK cells, human NK cells also express re-
KIRs are expressed
ceptors for polymorphic
ently transmit an inhibitory signal upon interaction with MHC class I
MHC class I molecules that inhibit killing
of target cells bearing appropriate nated killer-cell inhibitory
alleles. These receptors, desig-
receptors
(KIRs)27 (see Long, Colonna
and Lanier, this issue), are encoded
by a small family of related
genes located on human chromosome Surprisingly,
the KIRs are members
superfamily
and possess no homology
19 at 19q13.4 (Refs 28-32). of the immunoglobulin
and function. In common with Ly-49, the human on overlapping
subsets of NK cells and appar-
on potential target cells. In addition, KIRs and Ly-49 receptors interact with comparable regions of the human and mouse MHC class I heavy chain molecules, recognize MHC complexed
respectively,
and both appear to
with peptide.
(Ig)
to the murine Q-49 genes
The repertoire of inhibitory WC class I receptors and have a molecular mass of about 58 kDa (p58)28,29*33, Genes encoding Ly-49 receptors and KIRs do not :earrange, but are whereas other KIRs contain three Ig-like loops and have a molecular likely to generate a repertoire of receptors by alternative splicing and (Fig. 1). Certain KIRs contain two Ig-like loops in their extracellular
domains
mass of about 70 kDa (~70) 3oB. At present, 13 different cDNAs of
allelic polymorphism.
the KIR family have been reported,
neouslyexpress several inhibitory MHC receptors, which appa-ently
demonstrated
throughout
and differences
the extracellular,
have been
transmembrane
and
An individual
function independently
NK-cell clone may simulta-
of each other upon encountering
their MHC
cytoplasmic domains (Table 1). While many of the KIRs possess an element similar to the immunoreceptor tyrosine-based activation
ligands39. Therefore, the inhibitory MHC class I receptors are distinct from the rearranging T-cell receptors (TCRs), which also interact
motifs (ITAMs) in the cytoplasmic domains, ITAMs are not found in
with MHC-peptide complexes. Only Ly-49 homodimers have been deteckd LinX I*.osv (see above), but there is the possibility of hetero-
ihe cytoplasmic
regions of the Ly-49 receptors (Table 1).
Certain KIRs that contain two Ig-like loops in the extracellular
dimer formation between different Ly-49 isoforms. The KIRs are not
domain are recognized by mAbs GL183 and El36(Table 1). Expression
disulfide bonded and, as yet, there is no formal demonstration
of the GLI83 and EB6 epitopes correlates with the ability of NK-cell
noncovalent associations
of
between the different isoforms.
clones to recognize two groups of HLA-C alleles that differ at two
Paradoxically, Ly-49 receptors and KIRs can be expressed on NK
residues in the (Y,domain of the HLA-C molecule: GL183’ NK cells
cells in hosts that do not appear to express an MHC class I molecule
recognize ‘group 1’ HLA-C alleles, which express Ser at residue 77
capable of interacting with the receptor. For example, C57BL/6 mice express H-2h yet approximately 20% of their NK cells are Ly-49A+, which is incapable of recognizing H-2b ligands”. Similarly,
and Asn at residue 80; and EB6+ NK cells recognize ‘group 2’ alleles, which express Asn at residue 77 and Lys at residue 80 (Refs 35,36) The mAb DX9 reacts with a KIR, previously
called NKBl (Refs 30,
we have observed expression of the NKBl receptor for HLA-Bw4 in
34), which expresses three Ig-like loops in the extracellular domain.
individuals who are homozygous
NKBI KIRs recognize a site on the HLA-B molecule that maps to
unpublished). Moreover, the frequency of Ly-49A i or NKBl + NK cells is not increased in hosts that express a reactive MHC ligand. However, this does not imply that expression Jf the inhibitory
the HLA-Bw4 structural mow7 in a region similar to the site on HLA-C that interacts with the KIRs that contain two Ig-like do-
FEBRUARY
for HLA-Bw6 CJ.Gumperz C[ai.,
1990
IMMUNOLOGY
TODAY
Table 1. Characteristics of inhibitory MHC class 1 receptors
On NK Ce~(s19’22’27’30’3’*35 Representative reactive mAbs
Putative ligands
ITAtWike motif
KIR-cl42 (NKATI)”
HLA-C ‘group 2’
+
EEW
KIR-~147. II
HLA-C ‘group 2
+
EB6
KIR-cl6(NKATZ)
HLA-C ‘group I ’
+
GLl83
KIR-cl43
HLA-C ‘group I ’
+
GL183
cl49 (NKAT5)c
HIA-C ‘group I’
GLl83
cl39
?
NDd
NKB I (KIR-~12)”
HLA-Bw4
+
DX9
NKB I Be
HLA-Bw4
+
DX9
KIR-clI I (NKAT3)
HL%Bw4
+
DX9
KIR-cl5(NKAT4)’
?
+
ND
Ly-49A
H2-Dd, H2-Dk
-
Al
Ly-49B
?
ND
Ly-49c
H_2d.kb.s
SE6
Ly-49D
?
ND
Ly-49E
?
ND
Ly-49F
?
ND
Ly-49G.I g
?
ND
Ly-49G.29
H2-Dd, H2-L“
LGL- I
Ly-49G.3s
?
Receptors Human KIR-related
MouseQ-49
ND
-
Ly-49H ? ND -Abbreviations:Ig, immunoglobulin;ITAM,immunoreceptortyrosine-basedactivationmotif;KIR,killer-cellinhibitoryreceptor;mAb, monoclonalantibody;MHC, major histocompatibilitycomplex; NK, natural killer. WR-~147.11and NKATldiffer by two amino acids in the extracelIuIardomain. bReactivityof NKATlwith EB6has not been directly shown, but is likely. ‘cl49and NKATSdiffer by two amino acids in the leader sequence. ‘ND indicates that none of the existing mAbs is known to react with the protein encoded by the cDNA. ‘NKBIBis identical to NKBIwith the exception of an 18 amino acid deletion between the Q-proximal domain and transmembrane domain, probably resulting from alternative splicing. ‘KU7-cl5and NKAT4differ by one amino acid in the extracellulardomain. h’Ly-49G.1, G.2 and G.3 probably represent splice variants of the same gene. MHC receptors is unaffected by the MHC of the host. In honcmarrow-chimeric mice that express H-2D1’either on donor marrow or host cells, the Ly49A receptors on NK cells are clo~~~nr~gulatcd, presumably as a conscqu~ncc of ligand binding”‘. Similarly, expression and function of the Ly--WA receptor are affected in C37BL/h
11~the observation
tha7tNK ccalls in mice wit-11disrupted
globulin genes arc’unable to kill MHC class I lymplddasts,
How is the repertoire genemed?
cells in normal B6 mice reject transplanted
It can bc assumed
cells”. ‘Education’ of NK cells by self-MHC class I is also suggested
FEBRUARY
I996
whcrca:;
NK cells from syngcneic, wild-type mice efficiently lysc MHC class I I~mphoblast targ&‘.
mice tha! evpress dn H-2Di transgene ” . H-2D”-t-ransgcnic B6 mice < acccpi: allografts fmn- H-3nLi bone marrow donors, ivhcrcas NK H-2D” bone marrow
&-micro-.
inhibitory
that each NK ccl1 must express at least onto
receptor for at least one self-MHC class I molecule irk
IMMUNOLOGY
order to avoid autoimmunity. progenitor
An NK-cell
TZDAY
Bone marrow donor
that fails to express an inhibitory
receptor for a self-MHC class I allele at an appropriate time would presumably fail to differentiate,
whereas
an inhibitory would
interaction
receptor
permit
between
and a self-ligand
development
to proceed.
Expression of inhibitory MHC receptors for MHC alleles that are not present in the host would not be deleterious and therefore may represent a neutral event. To provide for expression of inhibitory MHC receptors
on
the Ly-49 and KIR
subsets of lymphocytes,
genes may be controlled by a stochastic process whereby differentgenes in the family are independently
regulated. Thus, an in-
dividual cell may transcribe one or more of these
genes,
with the only
requirement
being that at least one of the receptors binds to a self-ligand. this would potentially
enable the F, host to reject bone marrow
lmpIicarions
grafts from either parent, but not syngeneic F, marrow. Consistent with this model, Sentman ct d.4’ have implicated Ly-49C- NK cells
If the repertoire of inhibitory MHC class I receptors does function
in the rejection of Hh-incomuatib!?
in this manner, what are the implications in an outbred population of a species with several MHC class I genes? For example, humans
be noted that Hh resistance only prevents engraftment of hematopoietic tissues, whereas parental skin and organ transplants
have three polymorphic MHC class I genes (HLA-A, -B and -C) and most normal tissues co-dominantly express the gene products of all
are readily tolerated in F, hosts. The antigens recognized by NK cells that initiate the cytolytic responses may be preferentially ex-
loci (i.e. potentially six different MHC class I ligands). If a stochastic process regulates expression of the inhibitory MHC receptors, at
pressed by hematopoietic tissues; other tissues may be ignored by the host NK cells because the!. lack an appropriate stimulus.
bone marrow grafts. It should
least some of the NK cells in a host may express only a single receptor for one of the six available ligands. This would be advantaC receptors for MMC class I on T cells
geous in that alteration or loss of a single MHC molecule in a cell would be sufficient for an NK cell to recognize and eliminate the abnormal
cell. This would provide
mechanism potentially
a more sensitive surveillance
than a system that required
tion or transformation.
or loss of of infec-
This may also explain why these receptors
have evolved to recognize polymorphic, determinants
modification
six different MHC molecules as a consequence
rather than monomorphic,
on the MHC molecules. In addition, if allelic isoforms
of the Ly-49 receptors recognize distinct H-2 ligands, this would also provide a rationale for the expression of only a single allele of
is often considered
to be an NK-cell receptor, it
was in fact discovered on T cellsJ”,J7and is expressed on a minor subset of thymocytes and peripheral 1 cell@. Similarly, the human ~58 (Refs 49, 50) and NKBl receptor” are also present on T cells. NKBl is not restricted to any particular type of T cell, and the molecule expressed by T cells is indistinguishable NK ~11s~‘. Inleractions
from that present on
bet-deen NKBI on the T cell and an HLA-Bw4 li-
each Ly-49 gene locuP.
gand on an antigen-presenting cell (APC) can inhibit signals transduced through the TCR complex. This was demonstrated by co-
Hybrid histocompatibility
enterotoxin B (SEB) superantigen presented by either the HLA class I721.221 cell line or 721.221 cells transfected with several different
culturing human CD4- or CDS’ T-cell clones with staphylococcal
The existence of inhibitory MHC receptors that are differentially expressed on NK-cell subsets may explain the phenomenon histocompatibility’
of ‘hybrid
(Hh), a process whereby NK cells in F, recipients
reject parental bone marrow grafts from certain mouse strain&“. As
HLA class I genes. SEB presented by class I 721.221 cells activated in killing of the APC, whereas the
the T-cell clones and resulted
presence of HLA-Bw4 molecules on the APC inhibited T-cell stimulation and effector cell function”. Although only a minor subset of
shown in Fig. 2, NK cells in an F, host would on!y need to express
T cells express NKBl, many T-cell clones appear to express other in-
an inhibitory MHC receptor for either parent ‘A’ or parent ‘B’ MHC
hibitory MHC class I receptors for HLA-A, -B and -C, as revealed by
in order to avoid autoimmunity. However, because a subset of NK
functional
cells in the F, would not express anti-‘A’ or anti-3 MHC receptors,
T-cell clone$‘. Furthermore,
analysis
of a panel of randomly generated NKBl northern blot analysis has confirmed
IMMUNOLOGY
TODAY
adhesion molecules (ICAMs), CD28 ligands and CD401. In this case, expression inhibitory
receptor
that
of an
recognizes
self-
peptide-MHC complexes may serve as a fail-safe mechanism to prevent inappropri-
Foreign-peptide-MHC
ate responses and destruction of normal bystander cells at a site of inflammation. Thus, the net result is dictated by a delicate balance between
inhibitory
and stimulatory
signals. The finding that T-cell responses are regulated by stimulatory
and inhibitory
MHC
receptors that bind MHC ligands provides a new conceptual framework for understandFig, 3. A h!ypotheticnlmodel for the regdntiorz of T-cell responses b!ythe T-cell receptor (TCR) ad
inhibitoy mnjor histocompntibility cotnplex (MHCJ clnss 1 receptor follozoing internctiotz zoith nn nntigen-presenting cell (AK). (2) Biding of the TCR to a foreign-peptide-MHC complex initintcs n positive signnl thnt results it1 nctivntiolz of tyrositze kinnses. (2) TCR-nctivnted tyrosine kinnses phosphoylnte tzenrby inhibitory MHC clnss I receptors, zdzich then become functionally active. (3) Activnted inhibitory MHC clnss I receptors inhibit further TCR signal trnusductz’on,possibly by
ing the regulation Although
of an immune response.
the biochemical
rently unknown,
events are cur-
a hypothetical
scheme of
how this might operate is shown in Fig. 3. When an NK or T cell encounters an APC, or other potential target cell, a positive signal is
transmitted via a stimulatory receptor on recruitment of n tyrosine phosphntnsethnt dephosphorylntesmolecules in the TCR signnl trnnsductiolz the NK cell or through the TCR on T cells. pnthzvny(e.g. CD3 5 chain nd ZAP-70) nmf subsequently innctives the inhibitory receptor. This This event immediately activates the inmodel mi,cht also apply to rznturnlkiller 0.Wcell recognition. hibitory receptor, making it functionally competent.
If normal peptide-MHC
com-
the presence of transcripts of the KIR gene family in certain NKBl -
plexes are present on the cell surface of the APC that has initiated
T-cell clonego. NKBl is preferentially
the positive signal, the inhibitory MHC receptor on the responder expressed
on T cells with a memory
cell will transmit a negative signal, serving to dampen the response
phenotype, and is not frequently expressed on either thymocytes or
rapidly by interfering
cord blood T cells (L. Lanier, unpublished). This suggests that inhibitory MHC class I receptors may appear on T cells only after
tory signals (possibly by the recruitment of phosphatases).
Because
APCs or potential target cells will usually simultaneously
express
activation, at which point they are needed to control the extent of an
foreign-peptide-MHC
immune reaction. While the events regulating expression
cell surface, both the stimulatory
inhibitory
MHC receptors
are unknown,
induction
chronic exposure to antigen or the environmental
of these
with, and possibly terminating,
and self-peptide-MHC
the stimula-
complexes on their
and inhibitory
MHC receptors
may require
will be engaged. Therefore, the ultimate response will depend
on
influences that are
the strength of the opposing signals, which may be influenced
by
responsible for the generation of long-lived memory T cells. Short-
the affinity of the TCR (or other stimulatory
term stimulation of naive T cells itz vitro with polyclonal mitogens
cell) and the amount
does not induce expression of the KlRs (L. Lanier, unpublished).
Thus, a sufficiently strong stimulus can overcome the inhibitory sig-
of contribution
receptors on an NK
by costimulatory
receptors.
nals, enabling T cells or NK cells to respond to APCs in appropriate circumstances.
Inhibitory
Reg6dotion of immune responses
nism for peripheral
The presence of TCRs and inhibitory MHC receptors on a T cell provides a mechanism to fine-tune an immune response. What is the
these receptors
advantage
of this system? During differentiation
in the thymus,
MHC receptors
to function properly
disease. Not only can the model be tested experimentally, accounts for several previous observations
deleted by negative selection. However, during this process, thymo-
of inhibitory
cytes are also positively
receptors only operate if the stimulating
for recognition
Therefore, all T cells are potentially
of self-MHC.
autoreactive, but presumably
have low affinity for self-peptide-MHC,
which is insufficient to ac-
and failure of
could result in autoimmune
immature T cells that express a TCR with high affinity for self are selected
may provide a mecha-
tolerance against self-antigens,
MHC receptors.
but it also
relating to the behavior
For example,
the inhibitory
MHC
antigen and the relevant
MHC class I molecule are present on the surface of the same APC or target cell. Normal bystander
cells that express a relevant MHC
tivate a resting T cell. However, in the situation where T cells are strongly stimulated by a foreign antigen, the threshold for activation
class I molecule do not inactivate the T or NK cell. In addition, inactivation of the effector cell via these inhibitory MHC receptors is
may be lower, and these low-affinity TCR interactions with self may be adequate to initiate a response, particularly if the APC expresses
only transient and does not result in anergy. Because NK and T cells
an abundance
MHC class I molecules, inactivation by bystander cells or induction
FEBRUARY
of costimulatory
ligands [e.g. the intercellular
1996
cell
are constantly
surrounded
by normal, healthy tissues expressing
IMMUNOLOGY
of anergy by these inhibitory productive
MHC receptors would be counter-
in an immune surveillance system designed to seek and
TODAY
2287-2295 21 Mason, L.H., Ortaldo, J.R., Young, H.A., Kumar, K., Bennett, M. and
destroy infected or abnormal cells present at a low frequency in the
Anderson, S.K. (1995) 1. Exy. Med. 182,293-304
host.
22 Stoneman, E-R., Bennett, M., An, J. et RI. (1995) I. Ex,v. Mecl. 182,305-314 23 Yokoyama, W.M., Jacobs, L.B., Kanagawa,
O., Shevach, E.M. and
Cohen, D.I. (1989) I. I~nr~om~l. 143,1379-1386 24 Held, W., Roland, J. and Raulet, D.H. (1995) Nnfure 376,355-358
Concluding remarks Following
25 Daniels, B.F., Nakamura,
the cloning of the KIR and Ly-49 genes, substantial
progress wiII undoubtedly be made in elucidating their ligand specificity, transcriptional regulation and signal transduction pathways. The question of whether serve redundant
these two unrelated gene families
or complementary
functions will need to be re-
solved. Finally, recent evidence suggests that glycoproteins
related
Seaman, W.E. (1994) btmrrrify
MC., Rosen, S.D., Yokoyama, W.M. and 1, 785-792
26 Brennan, J., Takei, F., Wong, S. and Mager, D.L. (1995) J. Bid. Chem. 270, 9691-9694 27 Rajagopalan,
S., Winter, C.C., Wagtmann, N. and Long, E.O. (1995)
1. Inzmurrol. 155, 4143-4146 28 Wagtmann, N., Biassoni, R., Cantoni, C. et al. (1995) Imwtunif!y2,439-449
t the* KIRs may stimulate, rather than inhibit, cell responses upon
29 Colonna, M. and Samaridis, J. (1995) Scieme 268,405-408
binding their MHC class I ligands5’, providing yet another puzzle
30 D’Andrea, A., Chang, C., F:allz-Bacon, K., McClanahan, T., Phillips, J.H. and Lanier, L.L. (1995) I. hmrrrrol. 155, 2306-2310
to solve.
31 Wagtmann, N., Raiagopalan, S., Winter, CC., Peruzzi, M. and Long, E.O. Irmrrnify
DNAX Research Institute is supported
by Schering Plough Corporation.
We
thank W. Yokoyama and E. Long for helpful discussions. Lewis Lanier ([email protected]) Resemch Insfifufe
of Molecular
G.R. and Lanier, L.L.
Clrromosowe Res. (in press)
33 Moretta, A., Bottino, C., Pende, D. et al. (1990) I. Ex,u. Ma-l. 172,
md Joseph Phillips me at fhe DNAX and Cehlw
(in press)
32 Baker, E., D’Andrea, A., Phillips, J.H., Sutherland,
Biology, 901 Cdifornin
Avenue, Pdo Alto, CA 94304, USA.
1589-1598 34 Litwin, V., Gumperz, J., Parham, I’., Phillips, J.H. and Lanier, L.L. (1994) 1. E.y. Med. 180,537-543 35 Moretta, A., Vitale, M., Bottino, C.
t’tnl. 11993) 1. El/l.
Med. 178,597-604
36 Colonna, M., Borsellino, G., Falco, M., Ferrara, G.B. and Strominger, J.L.
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Chambers,
Herberman,
USA 92,1649-l 653
W.H., Vujanovic, N.L., DeLeo, A.B., Olszowy, M.W.,
42 Ohlen, C., Kling, G., Hoglund,
R.B. and Hiserodt, J.C. (1989) 1. Esy. Med. 169,137~1389
I? rf nl. (1989) Science 246,666-668
43 Bix, M., Liao, N-S., Zijlstra, M., Loring, J., Jaenisch, R. and Raulet, D.
8 Storkus, W.J., Alexander, J., rayne, J.A., Dawson, J-R. and Cresswell, I?
(1991) Nature 349,329-331
(1989) hoc. Nafl Awl. Sci. USA 86,2361-2364
44 Yu, Y.Y.L., Kumar, V. and Bennett, M. (1992) Awzzc. Ret?. Inz~~~r~~~ol. 10,
9 Shirnizu, Y. and DeMars, R. (1989) Eur. 1. btzt~zutd. 19,447-451 10 Storkus, W-J., Salter, R.D., Alexander, J. et RI. (1991) Pm. NnflAd.
189-214 Sci.
USA 88,5983-5992
45 Sentman, C.L., Kumar, V. and Bennett, M. (1991) Eur. \. Dn~awzol. 21, 282 l-2828
11 Litwin, V., Gumperz, J., Parham, I’., Phillips, J.H. and Lanier, L.L. (1993)
46 Chan, P-Y. and Takei, E (1986) I. b~m~u~ol.136, 1?-16-1353
1. Exp. Met!. 178,1321-1336
47 Nagasawa, I?., Gross, J., Kanagawa, 0.
12 Kadhofer, EM., Ribuado, R.K. and Yokoyama, W.M. (1992) Nnfure 358,66-70
48 RoIand, J. and Cazenave, P-A. (1992) Zrlt. htmrr~ol. 4, 699-706
13 Daniels, B., Karlhofer, EM., Seaman, W.E. and Yokoyama, W.M. (1994)
49 Ferrini, S., Cambiaggi,
1. Exy. Mecl. 180,687-692
2294-2298
et
nl. (1987) F. Inzrslrsol. 138,815-824
A., Meazza, R. ct d. (1994) Eur. 1. In~ra~d. 24,
14 Kane, K.I? (1994) 1. Exp Med. 179,1011-1015
50 Mingari, MC., Vitale, C., Cambiaggi, A. rt RI. (1995) Znt. I~IWZWZO~. 7,
15 Correa, I. and Raulet, D.H. (1995) bznzwify 2, 61-71
697-703 51 PhiIIips, J.H., Gumperz, J.E., Parham, I? and Lanier, L.L. (1995) Scifwc~
16 Malnati, M.S., Peruzzi, M., Parker, K.C. cf al. (1995) Scimce 267,1016-1018 17 Yokoyama, W.M., Kehn, I?J., Cohen, D.I. and Shevach, E.M. (1990) J. Inmwd.
145,2353-2358
268,403-405 52 Moretta, L., Sivori, S., Vitale, M. ct nl. (1995) J. E.Y/P.Med. 182,875-884
18 Wong, S., Freeman, J.D., Kelleher, C., Mager, D. and Takei, E (1991)
J.lnmunol. 147,1417-1423
E.O. Long, M. Colonna and L.L. Lanier describe a standard nomen19 Smith, H.R.C., Karlhofer, EM. and Yokoyama, v?!M. (1994) 1. ~~ZIIU~~ZO~. clature for inhibitory MHC class I receptors on NK and T cells on 153,106&1079 p. I00 of this issue.
20 Brennan, J., Mager, D., Jefferies, W. and Takei, E (1994) 1. E.ry. Med. 180,
FEBRUARY
1996
TODAY
Inhibitory MHC class NK cells Phillips
Lewis L. Lanier and Joseph
and
they
DeMars9:
demonstrated
that
human NK cells kill MHC class I-deficient Epstein-Barr
virus
lymphoblastoid
(EBVJ-transformed
B-
cell lines (e.g. the ClR or
721.221 cell lines), but fail to lyse these cell
tempts to generate tumor-specific cytotoxic T lymphocytes (CTLs). In the absence of
lines when transfected
with certain HLA-A
deliberate immunization, lymphocytes from control animals killed certain tumor cell
or -B genes. Moreover, NK cells could dis-
lines, and since this activity was also pres-
ing wild-type HLA-A2 and HLA-A2 with a
ent in athymic mice, a novel cell type was proposed to be responsible for this function.
site-directed mutation at amino acid 74 in the 0~~domain’O. An analysis of NK-cell
NK cells are capable of lysing tumor cells that express allogeneic major histocompat-
clones indicated
ibility complex (MHC) antigens
alleles and demonstrate
criminate between ClR target cells express-
that individual
can recognize multiple
or tumors
that completely lack MHC molecules. Thus, in contrast to the prevailing evidence for MHC restriction of T-cell recognition, NK cells were considered ‘MHC unrestricted’. However, observations by Karre and colleagues’ suggested that NK cells might in fact serve a unique role in the immune system by
in class I recognition”.
clonal diversity These findings pre-
dicted the existence of multiple NK-cell receptors polymorphic
MHC class I determinants
NK cells
HLA-A, -B and -C
that recognize
and ,ransmit an inhibitory
signal to prevent NK cells from killing target cells that express certain HLA alleles.
detecting and eliminating cells that had lost expression of MI-K class I molecules. This clever strategy may represent the first exMurine inhibitory receptors for polymorphic I-i-2
ample of a biological defense against the stealth technology that is used by certain viruses to evade T-cell recognition by disrupting
molecules
MHC synthesis. The concept of surveillance for ‘missing self-MHC’
While studying
was proposed in 1986, but only a decade later are we beginning to understand the molecular mechanisms responsible for this process.
tiation antigen, Yokoyama and colleagues12 observed that Ly-49A+
the distribution
of the murine
Ly-49A differen-
NK cells were unable to kill H-2Dd ar.d H-2Dk tumor cells, whereas
There is an emerging consensus that NK-cell recognition is regu-
Ly-49A- NK cells efficiently lysed these targets. This suggests that
lated by a delicate balance between positive signals that initiate their effector cell function and inhib:tory signals that prevent cy-
interactions between the Ly-49A receptor and its H-2 ligand on the
tolysis. NK cells can be activated ‘oy the interaction of several mem-
direct binding of Ly-49A to H-2Dd molecules, formally proving that
brane receptors (e.g. CD2, CD16, CD69 and NKF-Pl) with their li-
Ly-49A is a receptor for MHC (Refs 13, 14). Ly-49A interacts with
gands or monoclonal antibodies
(mAbs)2-7. At present, there is no
evidence for a unique NK-cell-specific
receptor that is responsible
target cell inactivate the NK cell. Subsequent experiments have shown
the 0~~and (Yedomains of H-2 (Ref. 12) and ligand recognition apparently requires a stable peptide-H-2
complex. Correa and Rauleti5
for initiating the cytolytic response; rather, it is likely that different receptors may be used depending upon the activation state of the
have shown that Ly-49A+ NK cells can r lcognize a diverse array of
NK cell and the availability of the relevant ligands on the target cell. In contrast to the limited understanding of the molecules re-
self-peptides
sponsible for positive signaling in NK cells, the involvement
peptides.
of re-
peptides bound to H-2Dd molecules, but are unable to distinguish from peptides of viral or bacterial origin; thus, NK-ceil
receptors do not necessarily discriminate However,
between self- and foreign-
evidence has been presented
ceptors in negative signaling is well defined: it is now clear that NK
that NK cells may be capable of distinguishing
cells possess receptors for polymorphic
molecules with different bound peptidesi6.
MHC class I molecules on
potential target cells, and these receptors apparently nals that prevent NK-cell-mediated cytotoxicity. Direct evidence for NK-cell recognition
transmit sig-
of MHC class I mol-
ecules was provided by the studies of Storkus et nl.8 and Shimizu 0 ! 996
E serer Scence Ltd 0167-5699196cS15
FEBRUARY
‘IO
1996
to demonstrate
between MHC class I
Ly-49A is one of at least seven closely related genes on mouse chromosome
6 that are preferentially
expressed
by NK cells*7-19.
These genes are memberr of the superfamily of C-type lectins and encode type II membrane proteins 17-i9.Although Ly-49 genes do not
IMMUNOLOGY
rearrange, there is evidence for alternative splicing and alfeiic polymorphism*8a19. mAbs have been generated
against
the Ly-49A,
TODAY
(a) Human KIR
Ly-49C and Ly-49G.2 glycoproteins, and used to demonstrate that these receptors are expressed as disulfide-bonded homodimers on subsets of NK cells20-23.Because the subsets of NK cells expressing
COOH
~58
P70
Ly-49A, Ly-49C and Ly-49G.2 overlap extensively, most NK cells
COOH
must express more than a single Ly-49 gene. Recent studies have indicated that only a single allele of each Ly-49 iocus may be transcribed in a single NK cell 24;however, the molecular mechanisms responsible for the transcriptional regulation of the Ly-49 genes have not been established. Since they are C-type lectins, the Ly-49 receptors may require carbohydrate
COOH
I
I
NH2
NH2
for ligand binding. In support of this notion, fucoidan
(a sulfated polysaccharide) between
I
I COOH
has been shown to inhibit interactions
Ly-49A or Ly-49C receptors
Nevertheless,
and their H-2 ligands2j,26.
Fig.
I. Strzlcturnl fentwes of(n) hunran killer-cell inhibiton/ wce,vtor (KIR)
md 07) mouse L!y-49 receptor
it is unlikely that the Ly-49 receptors discriminate
between different H-2 alleles on the basis of carbohydrate tion alone. Rather, the lectin interactions of Ly-49 to determinants
recogni-
may enhance the binding
of the H-2 polypeptide.
mains3’. Furthermore,
NKBl KIRs can recognize MHC class I heavy
chains that have been mutated to remove the site for N-linked glycosylation, indicating that carbohydrates are not required for receptor function37.
Inhibitory
C receptors for polymorphic
class I
Although the murine Ly-49 receptors demonstrate no structural homology with the human KIRs, there are striking similarities in
molecules
their distribution
In common with murine NK cells, human NK cells also express re-
KIRs are expressed
ceptors for polymorphic
ently transmit an inhibitory signal upon interaction with MHC class I
MHC class I molecules that inhibit killing
of target cells bearing appropriate nated killer-cell inhibitory
alleles. These receptors, desig-
receptors
(KIRs)27 (see Long, Colonna
and Lanier, this issue), are encoded
by a small family of related
genes located on human chromosome Surprisingly,
the KIRs are members
superfamily
and possess no homology
19 at 19q13.4 (Refs 28-32). of the immunoglobulin
and function. In common with Ly-49, the human on overlapping
subsets of NK cells and appar-
on potential target cells. In addition, KIRs and Ly-49 receptors interact with comparable regions of the human and mouse MHC class I heavy chain molecules, recognize MHC complexed
respectively,
and both appear to
with peptide.
(Ig)
to the murine Q-49 genes
The repertoire of inhibitory WC class I receptors and have a molecular mass of about 58 kDa (p58)28,29*33, Genes encoding Ly-49 receptors and KIRs do not :earrange, but are whereas other KIRs contain three Ig-like loops and have a molecular likely to generate a repertoire of receptors by alternative splicing and (Fig. 1). Certain KIRs contain two Ig-like loops in their extracellular
domains
mass of about 70 kDa (~70) 3oB. At present, 13 different cDNAs of
allelic polymorphism.
the KIR family have been reported,
neouslyexpress several inhibitory MHC receptors, which appa-ently
demonstrated
throughout
and differences
the extracellular,
have been
transmembrane
and
An individual
function independently
NK-cell clone may simulta-
of each other upon encountering
their MHC
cytoplasmic domains (Table 1). While many of the KIRs possess an element similar to the immunoreceptor tyrosine-based activation
ligands39. Therefore, the inhibitory MHC class I receptors are distinct from the rearranging T-cell receptors (TCRs), which also interact
motifs (ITAMs) in the cytoplasmic domains, ITAMs are not found in
with MHC-peptide complexes. Only Ly-49 homodimers have been deteckd LinX I*.osv (see above), but there is the possibility of hetero-
ihe cytoplasmic
regions of the Ly-49 receptors (Table 1).
Certain KIRs that contain two Ig-like loops in the extracellular
dimer formation between different Ly-49 isoforms. The KIRs are not
domain are recognized by mAbs GL183 and El36(Table 1). Expression
disulfide bonded and, as yet, there is no formal demonstration
of the GLI83 and EB6 epitopes correlates with the ability of NK-cell
noncovalent associations
of
between the different isoforms.
clones to recognize two groups of HLA-C alleles that differ at two
Paradoxically, Ly-49 receptors and KIRs can be expressed on NK
residues in the (Y,domain of the HLA-C molecule: GL183’ NK cells
cells in hosts that do not appear to express an MHC class I molecule
recognize ‘group 1’ HLA-C alleles, which express Ser at residue 77
capable of interacting with the receptor. For example, C57BL/6 mice express H-2h yet approximately 20% of their NK cells are Ly-49A+, which is incapable of recognizing H-2b ligands”. Similarly,
and Asn at residue 80; and EB6+ NK cells recognize ‘group 2’ alleles, which express Asn at residue 77 and Lys at residue 80 (Refs 35,36) The mAb DX9 reacts with a KIR, previously
called NKBl (Refs 30,
we have observed expression of the NKBl receptor for HLA-Bw4 in
34), which expresses three Ig-like loops in the extracellular domain.
individuals who are homozygous
NKBI KIRs recognize a site on the HLA-B molecule that maps to
unpublished). Moreover, the frequency of Ly-49A i or NKBl + NK cells is not increased in hosts that express a reactive MHC ligand. However, this does not imply that expression Jf the inhibitory
the HLA-Bw4 structural mow7 in a region similar to the site on HLA-C that interacts with the KIRs that contain two Ig-like do-
FEBRUARY
for HLA-Bw6 CJ.Gumperz C[ai.,
1990
IMMUNOLOGY
TODAY
Table 1. Characteristics of inhibitory MHC class 1 receptors
On NK Ce~(s19’22’27’30’3’*35 Representative reactive mAbs
Putative ligands
ITAtWike motif
KIR-cl42 (NKATI)”
HLA-C ‘group 2’
+
EEW
KIR-~147. II
HLA-C ‘group 2
+
EB6
KIR-cl6(NKATZ)
HLA-C ‘group I ’
+
GLl83
KIR-cl43
HLA-C ‘group I ’
+
GL183
cl49 (NKAT5)c
HIA-C ‘group I’
GLl83
cl39
?
NDd
NKB I (KIR-~12)”
HLA-Bw4
+
DX9
NKB I Be
HLA-Bw4
+
DX9
KIR-clI I (NKAT3)
HL%Bw4
+
DX9
KIR-cl5(NKAT4)’
?
+
ND
Ly-49A
H2-Dd, H2-Dk
-
Al
Ly-49B
?
ND
Ly-49c
H_2d.kb.s
SE6
Ly-49D
?
ND
Ly-49E
?
ND
Ly-49F
?
ND
Ly-49G.I g
?
ND
Ly-49G.29
H2-Dd, H2-L“
LGL- I
Ly-49G.3s
?
Receptors Human KIR-related
MouseQ-49
ND
-
Ly-49H ? ND -Abbreviations:Ig, immunoglobulin;ITAM,immunoreceptortyrosine-basedactivationmotif;KIR,killer-cellinhibitoryreceptor;mAb, monoclonalantibody;MHC, major histocompatibilitycomplex; NK, natural killer. WR-~147.11and NKATldiffer by two amino acids in the extracelIuIardomain. bReactivityof NKATlwith EB6has not been directly shown, but is likely. ‘cl49and NKATSdiffer by two amino acids in the leader sequence. ‘ND indicates that none of the existing mAbs is known to react with the protein encoded by the cDNA. ‘NKBIBis identical to NKBIwith the exception of an 18 amino acid deletion between the Q-proximal domain and transmembrane domain, probably resulting from alternative splicing. ‘KU7-cl5and NKAT4differ by one amino acid in the extracellulardomain. h’Ly-49G.1, G.2 and G.3 probably represent splice variants of the same gene. MHC receptors is unaffected by the MHC of the host. In honcmarrow-chimeric mice that express H-2D1’either on donor marrow or host cells, the Ly49A receptors on NK cells are clo~~~nr~gulatcd, presumably as a conscqu~ncc of ligand binding”‘. Similarly, expression and function of the Ly--WA receptor are affected in C37BL/h
11~the observation
tha7tNK ccalls in mice wit-11disrupted
globulin genes arc’unable to kill MHC class I lymplddasts,
How is the repertoire genemed?
cells in normal B6 mice reject transplanted
It can bc assumed
cells”. ‘Education’ of NK cells by self-MHC class I is also suggested
FEBRUARY
I996
whcrca:;
NK cells from syngcneic, wild-type mice efficiently lysc MHC class I I~mphoblast targ&‘.
mice tha! evpress dn H-2Di transgene ” . H-2D”-t-ransgcnic B6 mice < acccpi: allografts fmn- H-3nLi bone marrow donors, ivhcrcas NK H-2D” bone marrow
&-micro-.
inhibitory
that each NK ccl1 must express at least onto
receptor for at least one self-MHC class I molecule irk
IMMUNOLOGY
order to avoid autoimmunity. progenitor
An NK-cell
TZDAY
Bone marrow donor
that fails to express an inhibitory
receptor for a self-MHC class I allele at an appropriate time would presumably fail to differentiate,
whereas
an inhibitory would
interaction
receptor
permit
between
and a self-ligand
development
to proceed.
Expression of inhibitory MHC receptors for MHC alleles that are not present in the host would not be deleterious and therefore may represent a neutral event. To provide for expression of inhibitory MHC receptors
on
the Ly-49 and KIR
subsets of lymphocytes,
genes may be controlled by a stochastic process whereby differentgenes in the family are independently
regulated. Thus, an in-
dividual cell may transcribe one or more of these
genes,
with the only
requirement
being that at least one of the receptors binds to a self-ligand. this would potentially
enable the F, host to reject bone marrow
lmpIicarions
grafts from either parent, but not syngeneic F, marrow. Consistent with this model, Sentman ct d.4’ have implicated Ly-49C- NK cells
If the repertoire of inhibitory MHC class I receptors does function
in the rejection of Hh-incomuatib!?
in this manner, what are the implications in an outbred population of a species with several MHC class I genes? For example, humans
be noted that Hh resistance only prevents engraftment of hematopoietic tissues, whereas parental skin and organ transplants
have three polymorphic MHC class I genes (HLA-A, -B and -C) and most normal tissues co-dominantly express the gene products of all
are readily tolerated in F, hosts. The antigens recognized by NK cells that initiate the cytolytic responses may be preferentially ex-
loci (i.e. potentially six different MHC class I ligands). If a stochastic process regulates expression of the inhibitory MHC receptors, at
pressed by hematopoietic tissues; other tissues may be ignored by the host NK cells because the!. lack an appropriate stimulus.
bone marrow grafts. It should
least some of the NK cells in a host may express only a single receptor for one of the six available ligands. This would be advantaC receptors for MMC class I on T cells
geous in that alteration or loss of a single MHC molecule in a cell would be sufficient for an NK cell to recognize and eliminate the abnormal
cell. This would provide
mechanism potentially
a more sensitive surveillance
than a system that required
tion or transformation.
or loss of of infec-
This may also explain why these receptors
have evolved to recognize polymorphic, determinants
modification
six different MHC molecules as a consequence
rather than monomorphic,
on the MHC molecules. In addition, if allelic isoforms
of the Ly-49 receptors recognize distinct H-2 ligands, this would also provide a rationale for the expression of only a single allele of
is often considered
to be an NK-cell receptor, it
was in fact discovered on T cellsJ”,J7and is expressed on a minor subset of thymocytes and peripheral 1 cell@. Similarly, the human ~58 (Refs 49, 50) and NKBl receptor” are also present on T cells. NKBl is not restricted to any particular type of T cell, and the molecule expressed by T cells is indistinguishable NK ~11s~‘. Inleractions
from that present on
bet-deen NKBI on the T cell and an HLA-Bw4 li-
each Ly-49 gene locuP.
gand on an antigen-presenting cell (APC) can inhibit signals transduced through the TCR complex. This was demonstrated by co-
Hybrid histocompatibility
enterotoxin B (SEB) superantigen presented by either the HLA class I721.221 cell line or 721.221 cells transfected with several different
culturing human CD4- or CDS’ T-cell clones with staphylococcal
The existence of inhibitory MHC receptors that are differentially expressed on NK-cell subsets may explain the phenomenon histocompatibility’
of ‘hybrid
(Hh), a process whereby NK cells in F, recipients
reject parental bone marrow grafts from certain mouse strain&“. As
HLA class I genes. SEB presented by class I 721.221 cells activated in killing of the APC, whereas the
the T-cell clones and resulted
presence of HLA-Bw4 molecules on the APC inhibited T-cell stimulation and effector cell function”. Although only a minor subset of
shown in Fig. 2, NK cells in an F, host would on!y need to express
T cells express NKBl, many T-cell clones appear to express other in-
an inhibitory MHC receptor for either parent ‘A’ or parent ‘B’ MHC
hibitory MHC class I receptors for HLA-A, -B and -C, as revealed by
in order to avoid autoimmunity. However, because a subset of NK
functional
cells in the F, would not express anti-‘A’ or anti-3 MHC receptors,
T-cell clone$‘. Furthermore,
analysis
of a panel of randomly generated NKBl northern blot analysis has confirmed
IMMUNOLOGY
TODAY
adhesion molecules (ICAMs), CD28 ligands and CD401. In this case, expression inhibitory
receptor
that
of an
recognizes
self-
peptide-MHC complexes may serve as a fail-safe mechanism to prevent inappropri-
Foreign-peptide-MHC
ate responses and destruction of normal bystander cells at a site of inflammation. Thus, the net result is dictated by a delicate balance between
inhibitory
and stimulatory
signals. The finding that T-cell responses are regulated by stimulatory
and inhibitory
MHC
receptors that bind MHC ligands provides a new conceptual framework for understandFig, 3. A h!ypotheticnlmodel for the regdntiorz of T-cell responses b!ythe T-cell receptor (TCR) ad
inhibitoy mnjor histocompntibility cotnplex (MHCJ clnss 1 receptor follozoing internctiotz zoith nn nntigen-presenting cell (AK). (2) Biding of the TCR to a foreign-peptide-MHC complex initintcs n positive signnl thnt results it1 nctivntiolz of tyrositze kinnses. (2) TCR-nctivnted tyrosine kinnses phosphoylnte tzenrby inhibitory MHC clnss I receptors, zdzich then become functionally active. (3) Activnted inhibitory MHC clnss I receptors inhibit further TCR signal trnusductz’on,possibly by
ing the regulation Although
of an immune response.
the biochemical
rently unknown,
events are cur-
a hypothetical
scheme of
how this might operate is shown in Fig. 3. When an NK or T cell encounters an APC, or other potential target cell, a positive signal is
transmitted via a stimulatory receptor on recruitment of n tyrosine phosphntnsethnt dephosphorylntesmolecules in the TCR signnl trnnsductiolz the NK cell or through the TCR on T cells. pnthzvny(e.g. CD3 5 chain nd ZAP-70) nmf subsequently innctives the inhibitory receptor. This This event immediately activates the inmodel mi,cht also apply to rznturnlkiller 0.Wcell recognition. hibitory receptor, making it functionally competent.
If normal peptide-MHC
com-
the presence of transcripts of the KIR gene family in certain NKBl -
plexes are present on the cell surface of the APC that has initiated
T-cell clonego. NKBl is preferentially
the positive signal, the inhibitory MHC receptor on the responder expressed
on T cells with a memory
cell will transmit a negative signal, serving to dampen the response
phenotype, and is not frequently expressed on either thymocytes or
rapidly by interfering
cord blood T cells (L. Lanier, unpublished). This suggests that inhibitory MHC class I receptors may appear on T cells only after
tory signals (possibly by the recruitment of phosphatases).
Because
APCs or potential target cells will usually simultaneously
express
activation, at which point they are needed to control the extent of an
foreign-peptide-MHC
immune reaction. While the events regulating expression
cell surface, both the stimulatory
inhibitory
MHC receptors
are unknown,
induction
chronic exposure to antigen or the environmental
of these
with, and possibly terminating,
and self-peptide-MHC
the stimula-
complexes on their
and inhibitory
MHC receptors
may require
will be engaged. Therefore, the ultimate response will depend
on
influences that are
the strength of the opposing signals, which may be influenced
by
responsible for the generation of long-lived memory T cells. Short-
the affinity of the TCR (or other stimulatory
term stimulation of naive T cells itz vitro with polyclonal mitogens
cell) and the amount
does not induce expression of the KlRs (L. Lanier, unpublished).
Thus, a sufficiently strong stimulus can overcome the inhibitory sig-
of contribution
receptors on an NK
by costimulatory
receptors.
nals, enabling T cells or NK cells to respond to APCs in appropriate circumstances.
Inhibitory
Reg6dotion of immune responses
nism for peripheral
The presence of TCRs and inhibitory MHC receptors on a T cell provides a mechanism to fine-tune an immune response. What is the
these receptors
advantage
of this system? During differentiation
in the thymus,
MHC receptors
to function properly
disease. Not only can the model be tested experimentally, accounts for several previous observations
deleted by negative selection. However, during this process, thymo-
of inhibitory
cytes are also positively
receptors only operate if the stimulating
for recognition
Therefore, all T cells are potentially
of self-MHC.
autoreactive, but presumably
have low affinity for self-peptide-MHC,
which is insufficient to ac-
and failure of
could result in autoimmune
immature T cells that express a TCR with high affinity for self are selected
may provide a mecha-
tolerance against self-antigens,
MHC receptors.
but it also
relating to the behavior
For example,
the inhibitory
MHC
antigen and the relevant
MHC class I molecule are present on the surface of the same APC or target cell. Normal bystander
cells that express a relevant MHC
tivate a resting T cell. However, in the situation where T cells are strongly stimulated by a foreign antigen, the threshold for activation
class I molecule do not inactivate the T or NK cell. In addition, inactivation of the effector cell via these inhibitory MHC receptors is
may be lower, and these low-affinity TCR interactions with self may be adequate to initiate a response, particularly if the APC expresses
only transient and does not result in anergy. Because NK and T cells
an abundance
MHC class I molecules, inactivation by bystander cells or induction
FEBRUARY
of costimulatory
ligands [e.g. the intercellular
1996
cell
are constantly
surrounded
by normal, healthy tissues expressing
IMMUNOLOGY
of anergy by these inhibitory productive
MHC receptors would be counter-
in an immune surveillance system designed to seek and
TODAY
2287-2295 21 Mason, L.H., Ortaldo, J.R., Young, H.A., Kumar, K., Bennett, M. and
destroy infected or abnormal cells present at a low frequency in the
Anderson, S.K. (1995) 1. Exy. Med. 182,293-304
host.
22 Stoneman, E-R., Bennett, M., An, J. et RI. (1995) I. Ex,v. Mecl. 182,305-314 23 Yokoyama, W.M., Jacobs, L.B., Kanagawa,
O., Shevach, E.M. and
Cohen, D.I. (1989) I. I~nr~om~l. 143,1379-1386 24 Held, W., Roland, J. and Raulet, D.H. (1995) Nnfure 376,355-358
Concluding remarks Following
25 Daniels, B.F., Nakamura,
the cloning of the KIR and Ly-49 genes, substantial
progress wiII undoubtedly be made in elucidating their ligand specificity, transcriptional regulation and signal transduction pathways. The question of whether serve redundant
these two unrelated gene families
or complementary
functions will need to be re-
solved. Finally, recent evidence suggests that glycoproteins
related
Seaman, W.E. (1994) btmrrrify
MC., Rosen, S.D., Yokoyama, W.M. and 1, 785-792
26 Brennan, J., Takei, F., Wong, S. and Mager, D.L. (1995) J. Bid. Chem. 270, 9691-9694 27 Rajagopalan,
S., Winter, C.C., Wagtmann, N. and Long, E.O. (1995)
1. Inzmurrol. 155, 4143-4146 28 Wagtmann, N., Biassoni, R., Cantoni, C. et al. (1995) Imwtunif!y2,439-449
t the* KIRs may stimulate, rather than inhibit, cell responses upon
29 Colonna, M. and Samaridis, J. (1995) Scieme 268,405-408
binding their MHC class I ligands5’, providing yet another puzzle
30 D’Andrea, A., Chang, C., F:allz-Bacon, K., McClanahan, T., Phillips, J.H. and Lanier, L.L. (1995) I. hmrrrrol. 155, 2306-2310
to solve.
31 Wagtmann, N., Raiagopalan, S., Winter, CC., Peruzzi, M. and Long, E.O. Irmrrnify
DNAX Research Institute is supported
by Schering Plough Corporation.
We
thank W. Yokoyama and E. Long for helpful discussions. Lewis Lanier ([email protected]) Resemch Insfifufe
of Molecular
G.R. and Lanier, L.L.
Clrromosowe Res. (in press)
33 Moretta, A., Bottino, C., Pende, D. et al. (1990) I. Ex,u. Ma-l. 172,
md Joseph Phillips me at fhe DNAX and Cehlw
(in press)
32 Baker, E., D’Andrea, A., Phillips, J.H., Sutherland,
Biology, 901 Cdifornin
Avenue, Pdo Alto, CA 94304, USA.
1589-1598 34 Litwin, V., Gumperz, J., Parham, I’., Phillips, J.H. and Lanier, L.L. (1994) 1. E.y. Med. 180,537-543 35 Moretta, A., Vitale, M., Bottino, C.
t’tnl. 11993) 1. El/l.
Med. 178,597-604
36 Colonna, M., Borsellino, G., Falco, M., Ferrara, G.B. and Strominger, J.L.
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FEBRUARY
1996