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[Prevention of cell death using midkine]
Midkine has anti-apoptotic activity; the effect is best illustrated using embryonic neurons as target cells. Rentinal photoreceptor cells die after exposure to constant light in rats. Prior injection of midkine to the retina prevents the cell death. Temporary brain ischemia in gerbils leads to delayed neuronal death in the hippocampus. Prior delivery of midkine to the ventricle retards this process.
Midkine is heavily deposited in senile plaques of patients with Alzheimerユs disease. Midkine binds to amyloid b-peptide and suppresses the cytotoxic activity. There is a possibility that midkine is produced to counteract the toxicity of amyloid β-peptide. Midkine enhances the survival of bovine embryos cultured in vitro. Furthermore, midkine suppresses infection of HIV in target cells.
The anti-apoptotic and cell-protecting activites make midkine a promising therapeutic. However, the proinflammatory activity and protective activity of midkine should be carefully evaluated in each case.
[Essentials of midkine]
Protein
Midkine is a basic protein, essentialy composed of two domains held together by disulfide linkages. Each domain contains three anti-paralel b-sheets (Fig. 3).
Fig. 3
The domain organization of midkine and three dimensional structure of the domains. Two heparin-binding sites in the C-domain are encircled. Cited from Muramatsu, T., J. Biochem. 132, 359-371 (2002); Wiley Encyclopedia Mol. Med. pp2086-2088 (2002) [・2002, John Wiley & Sons]. This material is used by permission of John Wiley & Sons, Inc.
The more C-terminally located domain is usually responsible for midkine
activity. Midkine is dimerized through the action of transglutaminase. Some
midkine activity requires this dimerization. Pleiotrophin[also called HB-GAM (heparin-binding
growth-associeted molecule)]has 45 % sequence identity with midkine (Fig. 4).
Fig.4
Protein structure of human midkine (MK). Amino acids conserved with pleiotrophin (PTN) are boxed. S-S linkages are shown by lines. Arrowheads show exon boundaries. Amino acids conserved also in Drosophila miple are shaded. Cited from Muramatsu, T., J. Biochem., 132, 359-371 (2002)
Midkine has been found in all vertebrata examined, namely from human to
zebrafish. Zebrafish has two species of midkine. Although Drosophila lacks
midkine, miple, and miple 2 molecules with repeating units homologous to the
C-terminal half of both the midkine and pleiotrophin are present.
Gene
The human midkine gene is present in chromosome 11 band p.11.2, and is flanked
by DGKz (diacyglycerokinase z gene) and CHRM4 (muscarnic acetylcholine receptor
4 gene) (Fig.5).
Fig.5
Structure of the human midkine gene (MDK). For comparison, the human pleiotrophin gene (PTN) is also shown. <,exon, RARE, retinoic acid responsive element; WT1, binding site for WT1 protein. cited from Muramatsu, T., J. Biochem. 132, 359-371 (2002)
The symbol for the human midkine gene is MDK. The mouse midkine gene (Mdk)
is present on chromosome 2. In the upsteam of MDK, there is a retinoic
acid responsive element, and midkine gene expression is induced by retinoic
acid. Furthermore, the upstream region has a binding site for Wilmsユ
tumor suppressor WT1. When the function of WT1 is lost, suppression does not
take place, and midkine comes to be expressed. Although the pleiotrophin gene is
located in a broader region of the human genome, the fundamental structure is
similar.
Function and action mechanisms
Midkine is most strongly expressed in midgestation. Epithelial tissues involved
in epithelial mesenchymal interactions, nervous tissues during differentiation
and mesenchymal tissues undergoing remodeling are the principal sites of
expression. In the adult, midkine expression is restricted. Endothelial cells of
blood vessels and mucus epithelium of certain organs are important sites of
expression. When a tissue is injured, midkine expression is increased or newly
induced. Midkine promotes the survival and migration of various cells, and also
has many other activities (
Table 1). Using a blood vessel model, in which endothelial cells are layered
on gels with smooth muscle cells, the complex mode of midkine action during
epithelial mesenchymal interactions has been clarified (Fig. 6).
Fig.6
The action mechanism of midkine in epithelial mesenchymal interactions.
Among midkine receptors, receptor-type protein tyrosine phophafase z (PTP z) has
been studied extensively. Midkine binds to the chondroitin sulfate portion with
high affinity and to the protein portion with low affinity. In addition, low
density lipoprotein receptor-related protein (LRP) and anaplastic leukemia
kinase (ALK) have also been identified as receptors. Syndecans, a family of
transmembrane heparan sulfate proteoglycans, can also participate in midkine
signaling. The midkine receptor is considered to be a molecular complex
containing these proteins. Very recently, integrins have been found as
components of the receptor. The downstream signaling system contains PI3 kinase
followed by ERK (Fig.7).
Fig.7
The signal receptor complex of midkine (MK) and the downstream signaling system. Cited from Muramatsu, T., J. Biochem., 132, 359-371 (2002)
Midkine binds to the oversulfated portion of heparan sulfate and chondroitin
sulfate. The structure is shown in Fig. 8
Fig.8
Carbohydrate structure required for strong binding to midkine. The Trisulfated structure in heparan sulfate and chondroitin sulfate E structure are shown.
Midkine is also incorporated into the cell and translocated to the nuclers. The
survival promoting activity requires the nuclear translocation. LRP is involved
in the uptake and nuclelin or laminin-binding protein precursor participates in
the nuclear translocation.
[Further information]
More detailed information is available through reading review articles or
visiting other home pages. The following are recommended.
1. Muramatsu, T. (2002) Midkine and pleiotrophin: two related proteins involved
in development, survival, inflammation and tumorigenesis. J. Biochem 132,
359-371.
[http://jb.oxfordjournals.org/cgi/reprint/132/3/359]
2. Muramatsu, T. (2002) Midkine in Wiley Encyclopedia of Molecular Medicine
pp2086-2088. John Wiley & Sons., Inc. New York, USA
3. Muramatsu, T. Chondroitin sulfate E in signaling of the growth factor
midkine. [http://www.glycoforum.gr.jp/science/glycogenes/09/09E.html]
4. Kurtz, A., Schulte, A. M., and Wellstein, A. (1995) Pleiotrophin and midkine
in normal development and tumor biology. Crit. Rev. Oncol. 6, 151-177
5. Locus link (http://www.ncbi.nlm.nih.gov/LocusLink/LocRpt.cgi?l=4192)
6. Kadomatsu, K., and Muramatsu, T. (2004) Midkine and pleiotrophin in neural
development and cancer. Cancer Lett. 204, 127-143.
7. Muramatsu T, Muramatsu H, Kaneda N, Sugahara K. (2003) Recognition of
glycosaminoglycans by midkine. Methods Enzymol. 363, 365-376.
It is also possible to read original articles listed in
Original articles as references. By
searching Pub Med [http://www.ncbi.nlm.nih.gov/PubMed/]
using midkine as a key word, more articles become available. The summary of an
article listed in
Original articles as references can be
accessed using the PMID number written at the end of each reference.
