Full Journal - Journal of Cell and Molecular Biology - Haliç Üniversitesi

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Journal of Cell and Molecular Biology 1: 57-67, 2002. Golden Horn University, Printed in Turkey. Polyamines in living organisms Mustafa Yatin Harvard Medical School, Massachusetts General Hospital, Department of Radiology, Division of Nuclear Medicine, Boston MA, 02114, USA Received 30 June 2002; Accepted 10 July 2002 Abstract Natural polyamines, putrescine, spermidine and spermine are ubiquitous cell components essential for normal cellular functions and growth. Chemically these compounds are very simple organic aliphatic cations and fully protonated under physiological conditions. There is a strong correlation between proliferation rate of the cells and their polyamine contents. Adjustments of intracellular concentrations of polyamines to physiological requirements are orchestrated by de novo synthesis, polyamine uptake and catabolic reactions. De novo synthesis can in principle be substituted by polyamine uptake from extracellular environment. Over accumulation of polyamines is controlled by release and by a feedback regulation system that involves synthesis of a protein, antizyme that leads to degradation of ornithine decarboxylase and repression of polyamine uptake. The development of specific polyamine biosynthesis inhibitors and structural analogues of polyamines have revealed that maintaining polyamine levels are a prerequisite for animal cell proliferation to occur. The interruption of polyamine biosynthesis or minimizing the uptake of exogenous polyamines via the polyamine transport system offers meaningful targets for treatment of certain hyperproliferative diseases, most notably cancer. The polyamines influence confusingly large number biological processes, yet despite several decades of intensive research work, their exact functions in living organisms remains obscure. In this review, the current state of scientific knowledge regarding polyamines, their functions and their metabolism in mammalian cells is presented. KKeeyy wwoorrddss:: Polyamine, ODC, AdoMetDC, polyamine analogues, cancer Canl› organizmalarda poliaminler Özet Do¤al poliaminler putresin, spermidin ve spermin hücrenin normal ifllev ve büyümesi için esas olan yayg›n hücresel bilefliklerdir. Bu bileflikler kimyasal yönden çok basit organik alifatik katyonlard›r ve fizyolojik koflullarda tamamen protonlanm›fl durumdad›rlar. Hücrenin ço¤alma h›z› ile poliamin içeri¤i aras›nda çok yak›n bir iliflki vard›r. Poliamin konsantrasyonlar›n›n fizyolojik ihtiyaca göre ayarlanmas› yeni sentez, poliamin al›nmas› ve katabolik reaksiyonlar aras›ndaki uyumlulu¤a ba¤l›d›r. Yeni sentez prensip olarak hücre d›fl› ortam›ndan poliamin al›nmas› ile sa¤lan›r. Poliaminlerin fazla birikimi, sal›nmas› ve protein sentezi, ornitin dekarboksilaz y›k›m›na neden olan antizim ve poliamin al›m›n›n bask›lanmas›n› içeren feedback regulasyon sistemi taraf›ndan kontrol edilir. Spesifik poliamin biyosentez inhibitörlerinin ve poliaminlerin yap›sal analoglar›n›n geliflimi, hayvan hücre ço¤almas›n›n meydana gelmesinin poliamin düzeyine ba¤l› oldu¤unu ortaya koymufltur. Poliamin biyosentezinin kesintiye u¤rat›lmas› veya poliamin tafl›nma sistemi vas›tas› ile d›fl ortamdan poliaminlerin al›nmas›n›n azalt›lmas›, çok h›zl› hücre ço¤almas›n›n söz konusu oldu¤u belirli hastal›klar›n, en önemlisi kanserin, tedavisinde anlaml› sonuçlar vermifltir. Poliaminler çok fazla say›daki biyolojik olaylar› etkiler, onlarca y›ld›r yap›lan yo¤un araflt›rmalara ra¤men, canl› organizmalardaki tam ifllevleri hala aç›k de¤ildir. Bu derlemede poliaminlerle ilgili son bilimsel veriler, ifllevleri ve memeli hücrelerindeki metabolizmalar› sunulmufltur. AAnnaahhttaarr ssöözzccüükklleerr:: Poliamin, ODC, AdoMetDC, poliamin analoglar›, kanser 57
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Page 5 and 6: 46 Gülriz Bayçu Cd Contamination
Page 7 and 8: 48 Gülriz Bayçu Figure 2: Optimiz
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Page 11 and 12: 52 Gülriz Bayçu plants and fungi
Page 13: 54 Gülriz Bayçu References Abraha
Page 17 and 18: cells (cancer), inflammatory sites
Page 19 and 20: 1991, Russel and Synder, 1968; Pegg
Page 21 and 22: Figure 3: Several sources of PAs ar
Page 23 and 24: chemotherapy and lead to a very lar
Page 25 and 26: Thomas T and Thomas T. Polyamines i
Page 27 and 28: 70 Tülin Aktaç and Elvan Bakar Ma
Page 29 and 30: 72 Tülin Aktaç and Elvan Bakar Ak
Page 31 and 32: 74 Seyhan Altun et al. Altun (1996)
Page 33 and 34: 76 Seyhan Altun et al. increased a
Page 35 and 36: 78 Seyhan Altun et al. PH ratio and
Page 39 and 40: epirubicin + tamoxifen were added t
Page 41 and 42: Murphy B and Muss HB. Hormonal ther
Page 43 and 44: 88 Gülruh Ulako¤lu et al., 1993).
Page 45 and 46: 90 Gülruh Ulako¤lu According to t
Page 49 and 50: pad3 locus from the Col-pad3 mutant
Page 51 and 52: Table 2: Phenotypic interaction bet
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Page 55 and 56: 102 Narçin Palavan-Ünsal et al. I
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Page 63 and 64: 110 Ayfle TABAKO⁄LU-O⁄UZ, Anima
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112 by superscript small letters an
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114 Volume 1, No. 2 Review articles
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