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Çѱ¹½Ä¹°ÇÐȸ / v.28, no.1, 1985³â, pp.69-77 
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º¸¸® ¿±·ÏüÀÇ ÀüÀÚÀü´Þ°ú ±¤ÀλêÈ È°¼º¿¡ ¹ÌÄ¡´Â ${Zn}^{2+}$ÀÇ ¿µÇâ
( Effects of ${Zn}^{2+}$ on the Activities of Electron Transport and Photophosphorylation of Barley Chloroplasts ) |
| ±èÁö¼÷;È«¿µ³²;±Ç¿µ¸í; ¼¿ï´ëÇб³ ÀÚ¿¬°úÇдëÇÐ ½Ä¹°Çаú;¼¿ï´ëÇб³ ÀÚ¿¬°úÇдëÇÐ ½Ä¹°Çаú;¼¿ï´ëÇб³ ÀÚ¿¬°úÇдëÇÐ ½Ä¹°Çаú;
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| ${Zn}^{2+}$ÀÌ ¿±·ÏüÀÇ ±¤ÇÕ¼º°è¿¡ ¹ÌÄ¡´Â ¿µÇâÀ» ±¸¸íÄÚÁ® º¸¸® ¿±·Ïü¸¦ »ç¿ëÇÏ¿© ÀüÀÚÀü´Þ, ±¤ÀλêȹÝÀÀÀÇ È°¼ºÃøÁ¤ ¹× Àü±â¿µµ¿¿¡ ÀÇÇÑ CPº¹ÇÕüÀÇ ¾ÈÁ¤¼ºÀ» Á¶»çÇÏ¿´´Ù. ${Zn}^{2+}$Àº ÃßÃâµÈ ºÐ¸®¿±·Ïü Á¶°Ç¿¡¼ »Ó¾Æ´Ï¶ó, »ýÀ°½Ã ¹ÝÀÀ¿ë¾× Á¶°Ç¿¡¼µµ ÀüÀÚÀü´Þ, ƯÈ÷, PS IIÀÇ È°¼ºÀ» ÀúÇØÇÏ¿´À¸¸ç, À̺¸´Ù ±¤ÀλêÈÈ°¼ºÀ» ´õ¿í ´õ Å©°Ô ÀúÇØÇÏ¿´´Ù. ÀüÀÚÀü´Þ´ÉÀÇ ÀúÇØ´Â ${Mn}^{2+}$¿¡ ÀÇÇÏ¿© ȸº¹µÉ ¼ö ÀÖ¾úÀ¸¸ç, ±¤ÀλêȹÝÀÀ¿¡¼ ${Mg}^{2+}$°ú ${Zn}^{2+}$´Â ¼·Î ±â´É»óÀÇ °æÀïÀ» ³ªÅ¸³Â´Ù. ÇÑÆí Àü±â¿µµ¿¿¡¼ CP IÀº ${Zn}^{2+}$°ú mercaptoethanolÀÌ Á¸ÀçÇÏ¸é ½±°Ô Æı«µÊÀ» º¼ ¼ö ÀÖ¾ú´Ù. |
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| The degree of The degree of The degree of ${Zn}^{2+}$ effect on the photosynthetic electron transport and photophosphorylation activities in barley chloroplasts has been tested.${Zn}^{2+}$treatment was done in the 2 ways. One was that it was added into the chloroplasts suspensions isolated from the plants grown under the normal ${Zn}^{2+}$level (10$^{-6}$ M). The other was that the different concentrations of ${Zn}^{2+}$was applied in each growth medium. Then, it was not added into the chloroplasts suspensions isolated from the plants. PS II activity in both way of the treatments was more severely inhibited than PS I by the increment of ${Zn}^{2+}$ concentration. The photophosphorylation activity measured by pH measurement was gradually decreased with the increase of ${Zn}^{2+}$concentration in both ways, too. However, it was shown that M $n^{2+}$ could be near fully overcome the inhibitory effect of ${Zn}^{2+}$in PS II, and $Mg^{2+}$ could also reduce the Z $n^{2+}$ inhibition in the photophosphorylation. In the low concentrations of $Mg^{2+}$ (3 to 5$ imes$10$^{-3}$ M) in the suspension, ${Zn}^{2+}$(2$ imes$10$^{-5}$ M) could increase the activity of photophosphorylation. As compares to other cations, Z $n^{2+}$ caused less inhibitory effect on the photophosphorylation activity than Cu, Cd, but more than Pb and Ni. It may be assumed that a complex from reaction of Z $n^{2+}$ and mercaptoethanol was produced and it could reduce the stability of CPI band during SDS-PAGE.effect on the photosynthetic electron transport and photophosphorylation activities in barley chloroplasts has been tested. Z $n^{2+}$ treatment was done in the 2 ways. One was that it was added into the chloroplasts suspensions isolated from the plants grown under the normal Z $n^{2+}$ level (10$^{-6}$ M). The other was that the different concentrations of Z $n^{2+}$ was applied in each growth medium. Then, it was not added into the chloroplasts suspensions isolated from the plants. PS II activity in both way of the treatments was more severely inhibited than PS I by the increment of Z $n^{2+}$ concentration. The photophosphorylation activity measured by pH measurement was gradually decreased with the increase of Z $n^{2+}$ concentration in both ways, too. However, it was shown that M $n^{2+}$ could be near fully overcome the inhibitory effect of Z $n^{2+}$ in PS II, and $Mg^{2+}$ could also reduce the Z $n^{2+}$ inhibition in the photophosphorylation. In the low concentrations of $Mg^{2+}$ (3 to 5$ imes$10$^{-3}$ M) in the suspension, Z $n^{2+}$ (2$ imes$10$^{-5}$ M) could increase the activity of photophosphorylation. As compares to other cations, Z $n^{2+}$ caused less inhibitory effect on the photophosphorylation activity than Cu, Cd, but more than Pb and Ni. It may be assumed that a complex from reaction of Z $n^{2+}$ and mercaptoethanol was produced and it could reduce the stability of CPI band during SDS-PAGE.effect on the photosynthetic electron transport and photophosphorylation activities in barley chloroplasts has been tested. Z $n^{2+}$ treatment was done in the 2 ways. One was that it was added into the chloroplasts suspensions isolated from the plants grown under the normal Z $n^{2+}$ level (10$^{-6}$ M). The other was that the different concentrations of Z $n^{2+}$ was applied in each growth medium. Then, it was not added into the chloroplasts suspensions isolated from the plants. PS II activity in both way of the treatments was more severely inhibited than PS I by the increment of Z $n^{2+}$ concentration. The photophosphorylation activity measured by pH measurement was gradually decreased with the increase of Z $n^{2+}$ concentration in both ways, too. However, it was shown that M $n^{2+}$ could be near fully overcome the inhibitory effect of Z $n^{2+}$ in PS II, and $Mg^{2+}$ could also reduce the Z $n^{2+}$ inhibition in the photophosphorylation. In the low concentrations of $Mg^{2+}$ (3 to 5$ imes$10$^{-3}$ M) in the suspension, Z $n^{2+}$ (2$ imes$10$^{-5}$ M) could increase the activity of photophosphorylation. As compares to other cations, Z $n^{2+}$ caused less inhibitory effect on the photophosphorylation activity than Cu, Cd, but more than Pb and Ni. It may be assumed that a complex from reaction of Z $n^{2+}$ and mercaptoethanol was produced and it could reduce the stability of CPI band during SDS-PAGE.ld reduce the stability of CPI band during SDS-PAGE. |
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Journal of Plant Biology / v.28, no.1, 1985³â, pp.69-77
Çѱ¹½Ä¹°ÇÐȸ
ISSN : 1226-9239
UCI : G100:I100-KOI(KISTI1.1003/JNL.JAKO198511922411340)
¾ð¾î : Çѱ¹¾î |
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| ³í¹® Á¦°ø : KISTI Çѱ¹°úÇбâ¼úÁ¤º¸¿¬±¸¿ø |
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