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Progress in Chemistry 2005, Vol. 17 Issue (03): 468-476 Previous Articles   Next Articles

• Review •

Synthesis and Applications of Peptide Dendrimer

He Jun;Ma Yuan**;Zhao Yufen   

  1. Key Laboratory of Bioorganic Phosphorus Chemistry & Chemical Biology, Ministry of Education, Department of Chemistry, Tsinghua University,Beijing 100084,China
  • Received: Revised: Online: Published:
  • Contact: Ma Yuan
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Peptide dendrimer, as a member of dendrimeric materials, has a lot of unique physical and chemical characteristics compared to normal peptide chains. It has a great varieties of applications in biological areas. Synthetic approaches, as well as the applications in immunoreactions, biological mimetics, artificial enzyme, immuno diagnosis and gene delivery systems are discussed in this review.
Key words: peptide dendrimer, synthesis, applications

CLC Number: 

[ 1 ] Bosman A W, Janssen H M, Meijer E W. Chem. Rev. , 1999 ,99 : 1665 —1688
[ 2 ] Tomalia D A , Baker H , Dewald J R , et al . Polym. J . (Tokyo) ,1985 , 17 : 117 —132
[ 3 ] Tomalia D A , Baker H , Dewald J R , et al . Macromolecules ,1986 , 19 : 2466 —2468
[ 4 ] Newkome G R , Yao Z Q , Baker G R , et al . J . Org. Chem. ,1985 , 50 : 2003 —2004
[ 5 ] Hawker C J , Fréchet J M J . J . Am. Chem. Soc. , 1990 , 112 :7638 —7647
[ 6 ] Sadler K, Tam J P. Reviews in Molecular Biotechnology , 2002 ,90 : 195 —229
[ 7 ] Bell T W. Science , 1996 , 271 : 1077 —1078
[ 8 ] 沙耀武(Sha Y W) , 武 (Wu J ) . 湖南化工(Hunan Chemical Industry) , 2000 , 30 (4) : 1 —5
[ 9 ] Smith D K. Tetrahedron , 2003 , 59 : 3797 —3798
[10] Chow H F , Mong T K K, Nongrum M F , et al . Tetrahedron ,1998 , 54 : 8543 —8660
[11] Cloninger C R. Curr. Opin. Chem. Biol . , 2002 , 6 : 742 —748
[12] TamJ P. Proc. Natl . Acad. Sci . USA , 1988 , 85 : 5409 —5413
[13] 许家喜(Xu J X) . 高等学校化学学报(Chemical Journal of Chinese Universities) , 2000 , 21 : 1688 —1693
[14] TamJ P , Lu Y A. Proc. Natl . Acad. Sci . USA , 1989 , 86 :9084 —9088
[15] Merrifield R B. J . Am. Chem. Soc. , 1963 , 85 : 2149 —2154
[16] Li X F , ZhangL , Zhang W, et al . Org. Lett . , 2000 , 2 : 3075 —3078
[17] TamJ P , Lu Y A. J . Am. Chem. Soc. , 1995 , 117 : 12058 —12063
[18] Chan W C , White P D. Fmoc Solid Phase Peptide Synthesis : A Practical Approach. Oxford : Oxford University Press , 2000.236 —239
[19] Crespo L , Sanclimens G, Montaner B , et al . J . Am. Chem.Soc. , 2002 , 124 : 8876 —8883
[20] Rodriguez2Hemández J , Gatti M, Klok H A. Biomacromolecules ,2003 , 4 : 249 —258
[21] Baigude H , Katsuraya K, Okuyama K. Macromolecules , 2003 ,36 : 7100 —7106
[22] Choi J S , Joo D K, Kim C H , et al . J . Am. Chem. Soc. , 2002 ,122 : 474 —480
[23] Shao J , TamJ P. J . Am. Chem. Soc. , 1995 , 117 : 3893 —3899
[24] TamJ P , Yu Q , Miao Z. Biopolymers , 1999 , 51 : 311 —332
[25] Yajima H , Fuji N. J . Am. Chem. Soc. , 1981 , 103 : 5867 —5871
[26] Sasaki T, Kaiser E T. J . Am. Chem. Soc. , 1989 , 111 : 380 —381
[27] Eom K D , Miao Z W, Yang J L , et al . J . Am. Chem. Soc. ,2003 , 125 : 73 —82
[28] Muir T W, Williams M J , Ginsberg M H , et al . Biochemistry ,1994 , 33 : 7701 —7708
[29] TamJ P , Lu Y A , Liu C F , Shao J . Proc. Natl . Acad. Sci .USA , 1995 , 92 : 12485 —12489
[30] Vilaseca L A , Rose K, Werlen R , et al . Bioconj . Chem. , 1993 ,4 : 515 —520
[31] TamJ P , Yu Q , Yang J L. J . Am. Chem. Soc. , 2001 , 123 :2487 —2494
[32] TamJ P , Xu J X, Eom K D. Biopolymers , 2001 , 60 : 194 —205
[33] Mitchell J P , Roberts K D , Langley J , et al . Bioorg. Med.Chem. Lett . , 1999 , 9 : 2785 —2788
[34] Zeng F W, Zimmerman S C. Chem. Rev. , 1997 , 97 : 1681 —1712
[35] TamJ P , Clavijo P , Lu Y A , et al . J . Exp. Med. , 1990 , 171 :299 —306
[36] Defoort J P , Nardelli B , TamJ P , et al . Proc. Natl . Acad. Sci .USA , 1992 , 89 : 3879 —3883
[37] de Oliveira E , Villén J , Giralt E , et al . Bioconjugate Chem. ,2003 , 14 : 144 —152
[38] Baigude H , Katsuraya K, Okuyama K, et al . Macromol . Chem.Phys. , 2004 , 205 : 684 —691
[39] Tallima H , Montash M, Veprek P , et al . Vaccine , 2003 , 21 :3290 —3300
[40] Bisang C , Jiang L , Freund E , et al . J . Am. Chem. Soc. , 1998 ,120 : 7439 —7449
[41] TamJ P , Zavala F. J . Immunol . Methods , 1989 , 124 : 53 —61
[42] Marguerite M, Bossus M, Mazingue C , et al . Mol . Immunol . ,1992 , 29 : 793 —800
[43] Adesida A B , Aojula R R , Aojula H S , et al . Vaccine , 1999 ,18 : 315 —320
[44] Gómara M J , Riedemann S , Vega I , et al . J . Immunol .Methods , 2000 , 234 : 23 —34
[45] Marsden H S , Owsianka A M, Graham S , et al . J . Immunol .Methods , 1992 , 147 : 65 —72
[46] Sinnis P , Clavijo P , Fenyo D , et al . J . Exp. Med. , 1994 , 180 :297 —306
[47] Yahi N , Sabatier J M, Nickel P , et al . J . Biol . Chem. , 1994 ,269 : 24349 —24353
[48] Nomizu M, Yamamura K, Kleinman H K, et al . Cancer Res. ,1993 , 53 : 3459 —3461
[49] James J A , Harley J B. J . Immunol . , 1998 , 160 : 502 —508
[50] Mason L J , Timothy L M, Isenberg D A , et al . J . Immunol . ,1999 , 162 : 5099 —5105
[51] Farris A D , Brown L , Reynolds P , et al . J . Immunol . , 1999 ,162 : 3079 —3087
[52] Costa O , Divoux D , Ischenko A , et al . Journal of Autoimmunity ,2003 , 20 : 51 —61
[53] Bracci L , Lozzi L , Pini A , et al . Biochemistry , 2002 , 41 :10194 —10199
[54] Putterman C , Diamond B. J . Exp. Med. , 1998 , 188 : 29 —38
[55] Goodman M, Cai W, Kinberger G A. Maromol . Symp. , 2003 ,201 : 223 —236
[56] Kasai S , Nagasawa H , Shimamura M, et al . Bioorganic & Medicinal Chemistry Letters , 2002 , 12 : 951 —954
[57] Azuma M, Kojima T, Yokoyama I , et al . J . Pept . Res. , 1999 ,54 : 237 —241
[58] TamJ P , Lu Y A , Yang J L. Eur. J . Biochem. , 2002 , 269 :923 —932
[59] Sheldon K, Liu D M, Ferguson J , et al . Proc. Natl . Acad. Sci .USA , 1995 , 92 : 2056 —2060
[60] Cattani-Scholz A , Renner C , Oesterhelt D , et al . Chembiochem ,2001 , 2 : 542 —549
[61] Brokx R D , Bisland S K, Gariépy J . Journal of Controlled Release , 2002 , 78 : 115 —123
[62] Sarracino D A , Richert C. Bioorg. Med. Chem. Lett . , 2001 ,11 : 1733 —1736
[63] Wu G Y, Wu C H. J . Biol . Chem. , 1987 , 262 : 4429 —4432
[64] Wadhwa MS , Collard W T, Adami R C , et al . Bioconj . Chem. ,1997 , 8 : 81 —88
[65] Pouton C W, Lucas P , Thomas B J , et al . Journal of Controlled Release , 1998 , 53 : 289 —299
[66] Brown M D , Sch? tzlein A G, Uchegbu I F. International Journal of Pharmaceutics , 2001 , 229 : 1 —21
[67] Xu H , Kinsel G R , Zhang J , et al . Tetrahedron , 2003 , 59 :5837 —5848
[68] Hahn K W, Klis W A , Stewart J M. Science , 1990 , 248 :1544 —1547
[69] Kwon M, Jeong S , Lee K H , et al . J . Am. Chem. Soc. , 2002 ,124 : 13996 —13997
[70] Scofield R H , Kurien B T, Zhang F , et al . Molecular Immuno logy , 1999 , 36 : 1093 —1106
[71] Chapman T M, Hillyer G L , Mahan E J , et al . J . Am. Chem.Soc. , 1994 , 116 : 11195 —11196
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