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Anti-Inflammatory & Anti-Allergy
Agents in Medicinal Chemistry
ISSN: 1871-5230
Anti-Inflammatory & Anti-Allergy
Agents in Medicinal Chemistry
Volume 5, Number 3, August 2006
Contents
Interleukin-10 Family – Old and New
Promising Cytokines
Guest Editors: Khusru Asadullah & Robert Sabat
Editorial Pp. 205-206
Membrane-Bound Receptors of the Interleukin-10 Family
of Cytokines Pp. 207-214
Alexander Zdanov
[Abstract]
Soluble Receptors of the Interleukin-10 Family
of Cytokines: Interleukin-22 Receptor Alpha 2 Pp.
215-221
Robert Sabat, Elizabeth Wallace, Khusru Asadullah, Wolfram
Sterry, Hans-Dieter Volk and Kerstin Wolk
[Abstract]
Interleukin-10 Pp. 223-231
Khusru Asadullah, Robert Sabat, Markus Friedrich, Wolf
Dietrich Döcke, Hans-Dieter Volk and Wolfram Sterry
[Abstract]
Human Interleukin-19: Structure, Function and
Disease Associations Pp. 233-242
Grant Gallagher, Joyce Eskdale, William Jordan, Michele
Boniotto, Michelle Rodia, Danielle Kellner, Ellen Witte, Robert
Sabat and Kerstin Wolk
[Abstract]
Interleukin 20 Pp. 243-250
Benjamin E. Rich and Thomas S. Kupper
[Abstract]
IL-22 and Its Receptors, New Players in the Inflammatory
Network Pp. 251-257
Laure Dumoutier and Jean-Christophe Renauld
[Abstract]
Melanoma Differentiation Associated Gene-7 (mda-7)/
Interleukin-24 (IL-24), mda-7/IL-24: Current Perspectives
on a Unique Member of the IL-10 Family of Cytokines
Pp. 259-274
Devanand Sarkar, Paul Dent and Paul B. Fisher
[Abstract]
Interleukin-26, An Epitheliotropic T-Cell Cytokine
Pp. 275-277
Oliver Braum, Heide Pirzer and Helmut Fickenscher
[Abstract]
The IFN-
Family (IL-28/29) Pp. 279-285
Sergei V. Kotenko and Raymond P. Donnelly
[Abstract]
Abstracts
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Editorial
Interleukin-10 Family – Old and New Promising Cytokines
Khusru Asadullah1, and Robert Sabat2,
Cytokines are key mediators of the immune system, play-ing
a major role in health and disease. Their crucial impor-tance
in host defense, hematopoiesis, inflammation, autoimmunity,
tumor and other diseases became obvious over the last two
to three decades. Today, targeting components of the cytokine
network represents a promising new therapeutic approach, which
includes both strategies for antagonizing cytokine action
as well the application of recombinant cytokines. Impressive
examples are the antagonization of tumor necrosis factor (TNF)-alpha,
which represents a break-through for the therapy of several
inflammatory and auto-immune diseases, the interferon-alpha
application, which improved therapy for several tumors, the
interferon-beta therapy in patients with multiple sclerosis,
the erythropoietin substitution in patients with kidney insufficiency,
and the granulocyte-monocyte colony stimulating factor (GM-CSF)
application in patients with immune deficiency [1-4].
Intervening into the cytokine network is already well established
by using ‘biologicals’ i.e. recombinant proteins
including cytokines, neutralizing anti-cytokines and anti-receptor
antibodies, soluble receptors and various fusion proteins.
Novel small molecule approaches may either mimic the cytokine
effects, inhibit the cytokine function, or modulate the cytokine
expression, but are further down the road. Targeting of cytokines
has contributed to the symptom-free life of thousands of patients
and has even saved many lives to date. Currently, it is a
billion dollar industry and this market will most likely continue
to grow in the upcoming years.
With the remarkable potential of cytokines in mind, it is
no surprise that the discovery of novel cytokines significantly
raises the interest of basic and applied research scientists
in academia as well as in pharmaceutical companies. Their
discoveries trigger questions particularly regarding their
biological functions (such as whether they play an important
role in disease) and their “mode of action”. Many
cytokines, discovered in the last few years, were delegated
to the so-called IL-10 family [5]. Although IL-10 has been-known
since 1989, this family has only recently grown to be comprised
of eight additional mediators, namely of IL-19, IL-20, IL-22,
IL-24, IL-26, IL-28-alpha, IL-28-beta, and IL-29 [6]. Interestingly,
these cytokines were not grouped in a family based on similar
biological effects but rather due to three other reasons:
i) they show a similar amino acid sequence and secondary structure,
ii) their genes have similar structures and are genomically
clustered, and iii) these cytokines bind to receptor complexes
composed of two different members of the cytokine receptor
family class II.
IL-10 is primarily an important immunosuppressive and anti-inflammatory
cytokine in humans [7]. As far as the bio-logical effects
of the new members of the IL-10 family are known, these novel
mediators do not appear to share IL-10’s function. However,
the current knowledge lets us assume that at least three of
the new members also represent promising therapeutic targets.
In fact, application of IL-24 is a possible new and potentially
effective therapy for eliminating tumors [8]. Moreover, inhibition
of the effects of IL-20 and IL-22 may lead to the improvement
of chronic skin diseases [9-11]. The possible therapeutic
potential of influencing the effects of IL-20, IL-22, and
IL-24 in addition to the contribution of expanding our knowledge
on the immune system makes researching the biology of the
IL-10 family members both very interesting and important.
The purpose of this hot-topic issue is to review the current
knowledge with regard to these important immune mediators
and their receptors. Top experts contributed chapters for
each of the IL-10 family members and their receptors. Thus,
this hot-topic issue forms a comprehensive, state-of-the-art
volume giving a valuable overview.
REFERENCES
[1] Asadullah, K.; Sterry, W.; Trefzer, U. Exp. Dermatol.
2002, 11, 97-106.
[2] Disis, M.L. Oncology (Williston Park),
2005, 19, 5-9.
[3] Henry, D.H.; Bowers, P.; Romano, M.T.; Provenzano, R.
Arch Intern. Med., 2004,
164, 262-276.
[4] Schottelius, A.J.; Moldawer, L.L.; Dinarello, C.A.; Asadullah,
K.; Sterry, W.; Edwards, C.K., 3rd. Exp. Dermatol.,
2004, 13, 193-222.
[5] Volk, H.; Asadullah, K.; Gallagher, G.; Sabat, R.; Grutz,
G. Trends Immunol., 2001, 22,
414-417.
[6] Pestka, S.; Krause, C.D.; Sarkar, D.; Walter, M.R.; Shi,
Y.; Fisher, P.B. Annu Rev. Immunol., 2004,
22, 929-979.
[7] Moore, K.W.; de Waal Malefyt, R.; Coffman, R.L.; O'Garra,
A. Annu. Rev. Immunol., 2001, 19,
683-765.
[8] Sauane, M.; Gopalkrishnan, R.V.; Sarkar, D.; Su, Z.Z.;
Lebedeva, I.V.; Dent, P.; Pestka, S.; Fisher, P.B. Cytokine
Growth Factor Rev., 2003, 14,
35-51.
[9] Blumberg, H.; Conklin, D.; Xu, W.F.; Grossmann, A.; Brender,
T.; Carollo, S.; Eagan, M.; Foster, D.; Haldeman, B.A.; Hammond,
A.; Haugen, H.; Jelinek, L.; Kelly, J.D.; Madden, K.; Maurer,
M.F.; Parrish-Novak, J.; Prunkard, D.; Sexson, S.; Sprecher,
C.; Waggie, K.; West, J.; Whitmore, T.E.; Yao, L.; Kuechle,
M.K.; Dale, B.A.; Chandrasekher, Y.A. Cell, 2001,
104, 9-19.
[10] Wolk, K.; Kunz, S.; Witte, E.; Friedrich, M.; Asadullah,
K.; Sabat, R. Immunity. 2004, 21,
241-254.
[11] Wolk, K.; Witte, E.; Wallace, E.; Docke, W.D.; Kunz,
S.; Asadullah, K.; Volk, H.D.; Sterry, W.; Sabat, R. Eur.
J. Immunol., 2006, 36, 4309-4323.
[Back to top]
Membrane-Bound Receptors of the Interleukin-10 Family of Cytokines
Alexander Zdanov
The interleukin-10 (IL-10) family of cytokines includes IL-10,
its viral homologs, and eight cellular cytokines: IL-19, IL-20,
IL-22, IL-24, IL-26, IFN-1,
IFN-2,
and IFN-3.
Cellular homologs use for signaling five recently discovered
membrane-bound receptors: three long receptor chains (IL-20R1,
IL-22R1, and IFN-R)
and two short receptor chains (IL-20R2 and IL-10R2). Signal
transduction is initiated when cytokine binds two receptor
chains, one long and one short, forming a ternary complex.
Based on the analysis of known structures of ternary and binary
complexes, a homology model of the structure of the ternary
complex of IL-10/sIL-10R1/sIL-10R2 has been generated. The
structure agrees well with all published experimental data,
including the crystal structure of the binary IL-10/sIL-10R1
complex and data of peptide scans, mapping the sIL-10R2 binding
site. sIL-10R1, sIL-10R2, and inter-receptor interface sites
show that most of the intermolecular interactions have a polar
nature, although hydrophobic interactions constituting between
20% and 35% from the total number of interactions are also
important. Putative complexes of other cytokines of the IL-10
family and the role of glycosylation in ligand/receptor interactions
and how it affects biological activity are also discussed.
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Soluble Receptors of the Interleukin-10 Family
of Cytokines: Interleukin-22 Receptor Alpha 2
Robert Sabat, Elizabeth Wallace, Khusru Asadullah, Wolfram
Sterry, Hans-Dieter Volk and Kerstin Wolk
The interleukin (IL)-10 family of cytokines comprising IL-10,
IL-19, IL-20, IL-22, IL-24, IL-26, IL-28α,
IL-28β,
and IL-29 uses receptors of the cytokine receptor family class
2. Here we review the current knowledge about IL-22 receptor-α2
(IL-22Rα2)
which is the first known soluble receptor of that cytokine
family. The human IL-22Rα2-encoding
gene includes seven exons and is located on chromosome 6 between
the genes for interferon-γ
receptor-1 and IL-20 receptor-1. The products of this gene
are three different mRNA splice variants. The genes for the
mouse and rat IL-22Rα2
have a very similar genomic location and structure to those
in humans, although they lack the human exon 4 counterpart
and produce only one variant which corresponds to the human
variant 2. Irrespective of the species and splice variant,
IL-22Rα2
lacks any sequence for a transmembrane or an intracellular
part, and is a secreted protein. It is particularly expressed
in the placenta, the mammary glands, and the lymph nodes but
also in the gastrointestinal system, the lungs, the skin,
and other lymphatic organs. It seems, however, that the variants
3 and 1 are more restricted in their expression. Variant 2
binds to and inhibits the activity of IL-22 in vitro,
whereas the specificity of variants 3 and 1 has not been identified.
The discovery of IL-22Rα2
represents a first step towards understanding the regulatory
network regarding the action of IL-22 and perhaps of other
members of the IL-10 family. It also may open up new ways
for targeting the action of these cytokines for therapeutic
interests.
[Back to top]
Interleukin-10
Khusru Asadullah, Robert Sabat, Markus Friedrich, Wolf
Dietrich Döcke, Hans-Dieter Volk and Wolfram Sterry
Interleukin (IL)-10, initially described as cytokine synthesis
inhibitory factor, is a pleotropic cytokine produced by many
cell populations. Its main biological functions appear to
be quite diverse: on the one hand it is involved in the limitation
and termination of inflammatory responses and the regulation
of differentiation and proliferation of several immune cells,
and on the other hand it mediates immunostimulatory properties
that support the elimination of infectious and non-infectious
particles with limited inflammation. Numerous investigations,
including expression analyses in patients, and both in
vitro and in vivo studies suggest a major physiological
and pathophysiological impact of IL-10. Activation of the
neuro-endocrine axis following acute stress reactions leads
to systemic IL-10 release, preventing hyperinflammatory reactions.
IL-10 is overexpressed in many solid tumors and lymphomas
and considered to promote further tumor development. In contrast,
a relative IL-10 deficiency has been observed and is regarded
to be of pathophysiological relevance in certain inflammatory
disorders characterized by a type 1 cytokine pattern such
as psoriasis. Recombinant human IL-10 has been tested in several
clinical trials including rheumatoid arthritis, inflammatory
bowel disease, psoriasis, organ transplantation, and hepatitis
C. The results are heterogeneous and give new insight into
the immunobiology of IL-10. However, further investigations
would be desirable to better determine the effect/side effect
profile as well as the best first line target indication and
optimal therapeutic regimen.
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Human Interleukin-19: Structure, Function and
Disease Associations
Grant Gallagher, Joyce Eskdale, William Jordan, Michele
Boniotto, Michelle Rodia, Danielle Kellner, Ellen Witte, Robert
Sabat and Kerstin Wolk
Interleukin(IL) -19 is a member of the recently described
IL-10 family of cytokines. Based on the genomic localization
of its gene, its structure, conserved amino acids, cellular
sources and receptor, IL-19 forms a subfamily with IL-20 and
IL-24. The IL-19-encoding gene comprises seven exons and is
located on chromosome 1. Secreted IL-19 is composed of 159
amino acids that form an α-helical
structure. IL-19 is produced by activated monocytes, and to
a lesser extent, by B cells. As known so far, IL-19 functions
through a receptor complex composed of IL-20R1 and IL-20R2,
which is also utilized by IL-20 and IL-24. High levels of
both receptor chains are present in several stromal tissues
including the skin, lungs, and tissues from the reproductive
organs. However, no expression is found in any immune cell
population. Nonetheless, all effects of IL-19 described so
far concern immune cells. Such conflicting data may be due
to the existence of an additional (so far undiscovered) receptor
complex for IL-19, or to the ability of the known IL-19 receptor
to mediate its effects when present on the cell surface at
a very low density. IL-19 has been shown to enhance the production
of Th2 cytokines in T cells. Furthermore, it induced IL-10
expression in monocytes. Apart from the implied role for IL-19
in atopic and allergic responses and disorders, it also seems
to be involved in the pathogenesis of the Th1-type skin disease
psoriasis. IL-19 therefore represents an exciting new cytokine
with immunoregulatory functions.
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Interleukin 20
Benjamin E. Rich and Thomas S. Kupper
IL-20 is a member of the IL-10 family of cytokines that also
includes IL-10, IL-19, IL-22, IL-24, and IL-26 as well as
a number of viral homologs. Keratinocytes and monocytes in
states of activation can produce IL-20. It transmits signals
via two different cell-surface receptor complexes resulting
in the activation of STAT3 in keratinocytes and other epithelial
cells. Thus it appears to be primarily an inducible autocrine
and paracrine factor that regulates proliferation and differentiation
of keratinocytes in the context of inflammation. Several findings
indicate that IL-20 mediates the hyperpro-liferation of keratinocytes
associated with cutaneous inflammation. As such it is likely
to have a central role in inflammatory skin diseases such
as psoriasis and eczema. IL-20 also promotes the expansion
of multipotential hematopoietic pro-genitor cells indicating
a role beyond the response of epithelial cells to inflammation.
Increased understanding of the biology of IL-20 may provide
novel opportunities for diagnostic methods and therapeutic
intervention.
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IL-22 and Its Receptors, New Players in the
Inflammatory Network
Laure Dumoutier and Jean-Christophe Renauld
Originally identified as a gene specifically induced by IL-9
in a mouse T cell lymphoma, IL-22 is mainly produced by TH1
cells or by activated T cells. Human IL-22, which shares 79%
amino acid identity with its mouse orthologue and 25% with
IL-10 is encoded by a single copy gene and located on chromosome
12, close to the IFNγ
gene, whereas the murine IL-22 gene is located on chromosome
10 and is duplicated in some mouse strains. Structurally,
IL-22 appears to be a monomer composed of six alpha helices,
whose organization is reminiscent of the helices of the IL-10
dimer. Despite its structural relationship with IL-10, IL-22
exerts completely different activities, acting mainly on non
hematopoietic cells, such as epithelial cells from lung and
colon, hepatocytes and keratinocytes. IL-22 might therefore
be involved in inflammatory processes, at least in liver and
skin. IL-22 exerts its activity via a complex formed by IL-10Rβ
and IL-22R, associated with Tyk2 and Jak1, respectively. The
main signaling pathways triggered by IL-22 involve STAT-1,
-3, -5 and the ERK, JNK and p38 MAPKinases. Beside its transmembrane
receptor, IL-22 also binds to a soluble receptor, called IL-22BP.
This soluble receptor turns out to be a natural antagonist
of IL-22 biological activities at least in vitro.
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Melanoma Differentiation Associated Gene-7 (mda-7)/
Interleukin-24 (IL-24), mda-7/IL-24: Current Perspectives
on a Unique Member of the IL-10 Family of Cytokines
Devanand Sarkar, Paul Dent and Paul B. Fisher
Developing effective and safe therapies for cancer continues
to be a primary objective of both basic researchers and clinicians.
However, despite evidence of progress in treating specific
tumors, in many instances, especially in the context of metastasis,
no effective therapies are available. A focus of our laboratories
is to develop improved cancer therapeutics that exploit differences
in signaling pathways and gene expression in tumor versus
normal cells. An approach, which we have pioneered, is the
use of ‘differentiation therapy’ combined with
subtraction hybridization, DISH (differentiation induction
subtraction hybridization), to define genes that are relevant
to cancer growth control, differentiation and apoptosis. Application
of DISH to human melanoma cells permitted the cloning of melanoma
differentiation associated (mda) genes that display
elevated expression as a function of induction of terminal
differentiation and loss of tumorigenic potential in cancer
cells. One mda gene, mda-7, has emerged as a potential
therapeutic for cancer because of its unique ability to selectively
induce apoptosis in cancer cells, without affecting normal
cells. Based on structure, location and properties, mda-7,
a cytokine belonging to the IL-10 family, is now designated
as IL-24. mda-7/IL-24 exhibits multiple levels of
anti-cancer effects that include inhibition of angiogenesis,
radiosensitization and potent antitumor bystander activities.
As a cytokine it also demonstrates immunostimulatory properties.
An adenovirus expressing mda-7/IL-24, INGN 241, has
entered the clinic and been shown to be safe and display significant
activity toward solid tumors, including melanoma, in a Phase
I clinical trial. We presently provide a brief overview of
mda-7/IL-24.
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Interleukin-26, An Epitheliotropic T-Cell Cytokine
Oliver Braum, Heide Pirzer and Helmut Fickenscher
Interleukin-26 (IL-26) belongs to the family of cellular cytokines
which share sequence homology with IL-10, however, without
functional conservation. The il-26 gene is situated
on the human chromosome 12q15 in close neighbourhood to the
genes for the related T-cellular cytokines interferon-γ
(IFN-γ
) and IL-22. il-26 was discovered due to its
overexpression in T cells after growth transformation with
herpesvirus saimiri. IL-26 is produced by activated T cells,
forms homodimers, and acts on epithelial target cells such
as colon carcinoma cells or keratinocytes. Presumably due
to its positive net charge, IL-26 adheres to glycosaminoglycans
on cell surfaces. Stimulation with IL-26 results in the phosphorylation
and activation of the transcription factors STAT1 and STAT3
and in the induction of CD54 surface expression and secretion
of cytokines such as IL-8 and IL-10. These effects are mediated
by an IL-26-specific receptor complex consisting of IL-20R1
and IL-10R2. Thus, IL-26 appears to be a rather proinflammatory
and cell-surface associated cytokine linking local T-cell
activation with epithelial functions.
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The IFN-
Family (IL-28/29)
Sergei V. Kotenko and Raymond P. Donnelly
IFN-s
or type III IFNs are also known as IL-28/29. This group of
cytokines is the latest addition to the family of cytokines
that signal through receptors of the class II cytokine receptor
family (CRF2). Although IFN-s
and IFN-α
/β
(type I IFNs) utilize distinct receptor complexes for signaling,
type I and type III IFNs activate the same intracellular signaling
pathway and many similar biological activities, including
the ability to induce antiviral state in cells. Consistent
with their antiviral activity, the expression of IFN-
mRNAs is inducible by viral an infections. Therefore, IFN-s
functionally resemble type I IFNs, supporting their designation
as IFNs. However, IFN-s
also share several common features with cytokines of the IL-10
family that includes IL-19, IL-20, IL-22, IL-24 and IL-26.
Their genes have a similar intronexon structure, they share
some sequence homology, and most likely they share a similar
structural organization. IFN-s
also share a common receptor subunit, IL-10R2, with IL-10,
IL-22 and IL-26. However, the ligand-binding chain, IFN-R1,
is a unique component of the IFN-
receptor complex. Although the relative importance of the
IFN-s
remains to be fully determined, recent experiments demonstrate
their strong potential as antiviral and antitumor therapeutics.
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