JMS/sandbox9

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Extraordinary Proteins
By adapting their proteins, organisms have managed to colonize extraordinary environments. "Extreme" proteins demonstrate many intriguing biophysical features neccessary for living in harsh environments.

Well-tuned surface charges enable solubility in a broad range of salt conditions
The green alga Dunaliella salina lives in the Dead Sea of Israel where water currents can change its environment swiftly and dramatically from low to high salt concentrations. The problem for its proteins is staying soluble in both solvents.

In 2005, scientists from the Weizmann Institute reported the first crystal structure of a halotolerant enzyme, from D. salina, a (1y7w). In 1995, they solved (together with scientists from Tel Aviv University) the first structure of a halophilic enzyme, a (1hlp) from Haloarcula marismortui.

They conclude that a general solution for remaining soluble in salty conditions is to become "anion-like" through increasing the negative charge surface density. Too little negative charge and the enzyme can only tolerate low salt conditions, too much negative charge and the enzyme can only stand high salt conditions, but the "right" amount of negative charge enables an enzyme to remain soluble in both low and high salt conditoins.

In the list below, notice how the negative surface charge density - the ratio of negative "redish" amino acids to positive "bluish" amino acids - is low for the mesophilic enzymes, high for the halophilic enzymes, and medium for the halotolerant enzyme. These ratios are approximately 1:1 (negative to positive amino acids on the surface) for the mesophilic enzymes; 3:1 for the halophilic enzyme, and 2:1 for the halotolerant enzyme.

Halotolerant carbonic anhydrase. Notice this enzyme has fewer positive "blue" amino acids than its mesophilic counterpart

Drag the structure with the mouse to rotate

Halophilic malate/lactate dehydrogenase. Notice this enzyme has both fewer positive "bluish" amino acids, as well as many more negative "redish" amino acids than its mesophilic counterpart

Drag the structure with the mouse to rotate

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Joseph M. Steinberger

Retrieved from "http://52.214.119.220/wiki/index.php/JMS/sandbox9"

@@ Line 1: / Line 1: @@
 <StructureSection load='1hlp' size='350' side='right' caption='halophilic enzyme (PDB entry [[1hlp]])' scene='Extremophile/1hlp_secondary/2'>
-== Extraordinary Proteins ==
+'''Extraordinary Proteins'''
+<br/>
+By adapting their proteins, organisms have managed to colonize extraordinary environments. "Extreme" proteins demonstrate many intriguing biophysical features neccessary for living in harsh environments.
-Organisms have managed to colonize extraordinary environments, but without proteins, living doesn't happen. "Extreme" proteins demonstrate many intriguing biophysical features neccessary for living in harsh environments.
-== Well-tuned negative surface charge density enables solubility in a broad range of salt conditions ==
+----
+'''Well-tuned surface charges enable solubility in a broad range of salt conditions'''
+<br/>
 The green alga ''Dunaliella salina'' lives in the Dead Sea of Israel where water currents can change its environment swiftly and dramatically from low to high salt concentrations. The problem for its proteins is staying soluble in both solvents.
-In 2005, Scientists from the Weizmann Institute reported the first crystal structure for the first halotolerant enzyme, from ''D. salina'', a <scene name='JMS/sandbox9/Carbonic_anhydrase/1'>carbonic anhydrase</scene> ([[1y7w]]), having solved in 1995 (together with scientists from Tel Aviv University) the structure of the first halophilic enzyme, a <scene name='Extremophile/1hlp_secondary/2'>malate/lactate dehydrogenase</scene> ([[1hlp]]) from ''Haloarcula marismortui''.
+In 2005, scientists from the Weizmann Institute reported the first crystal structure of a halotolerant enzyme, from ''D. salina'', a <scene name='JMS/sandbox9/Carbonic_anhydrase/1'>carbonic anhydrase</scene> ([[1y7w]]). In 1995, they solved (together with scientists from Tel Aviv University) the first structure of a halophilic enzyme, a <scene name='Extremophile/1hlp_secondary/2'>malate/lactate dehydrogenase</scene> ([[1hlp]]) from ''Haloarcula marismortui''.
-They conclude that a general solution for remaining soluble in salty conditions it to become "anion-like" through increasing the negative charge surface density. Too little negative charge and the enzyme can only tolerate low salt conditions, too much negative charge and the enzyme can only stand high salt conditions, but the "right" amount of negative charge enables an enzyme to remain soluble in both low and high salt conditoins.
+They conclude that a general solution for remaining soluble in salty conditions is to become "anion-like" through increasing the negative charge surface density. Too little negative charge and the enzyme can only tolerate low salt conditions, too much negative charge and the enzyme can only stand high salt conditions, but the "right" amount of negative charge enables an enzyme to remain soluble in both low and high salt conditoins.
-In the list below, notice how the negative surface charge density is lowest for the mesophilic, highest for the halophilic, and intermediate for the halotolerant enzyme. The negative, positive, and neutral amino acids are colored red, blue and white, respectively:
+In the list below, notice how the negative surface charge density - the ratio of negative "redish" amino acids to positive "bluish" amino acids - is low for the mesophilic enzymes, high for the halophilic enzymes, and medium for the halotolerant enzyme.  These ratios are approximately ''1:1'' (negative to positive amino acids on the surface) for the mesophilic enzymes; ''3:1'' for the halophilic enzyme, and ''2:1'' for the halotolerant enzyme.
-* <scene name='JMS/sandbox9/1raz/1'>''mesophilic'' carbonic anhydrase </scene> [[1raz]]
+{|
-* <scene name='JMS/sandbox9/1y7w/1'>''halotolerant'' carbonic anhydrase </scene> [[1y7w]]
+|<applet load='1raz.pdb' name='A' size='300' frame='true' align='right' caption='Mesophilic carbonic anhydrase' align='left' scene='JMS/sandbox9/1raz/5'/>
-* <scene name='JMS/sandbox9/Mesophile_dehydrogenase/2'>''mesophilic'' malate/lactate dehydrogenase </scene>[[1ldm]]
+|<applet load='1y7w.pdb' name='B' size='300' frame='true' align='right' caption='Halotolerant carbonic anhydrase.  Notice this enzyme has fewer positive "blue" amino acids than its mesophilic counterpart' align='left' scene='JMS/sandbox9/1y7w/4'/>
-* <scene name='JMS/sandbox9/1hlp/1'>''halophilic'' malate/lactate dehydrogenase </scene> [[1hlp]]
+|}
 {{Clear}}
-== High temperatures encourage using proline to lower entropy loss and between-chain ion-network bonding to increase enthalpy gain ==
+{|
+|<applet load='Ncbi.pdb' name='C' size='300' frame='true' align='right' caption='Mesophilic malate/lactate dehydrogenase' align='left' scene='JMS/sandbox9/1ldm_qua/3'/>
+|<applet load='4JCO.pdb' name='D' size='300' frame='true' align='right' caption='Halophilic malate/lactate dehydrogenase. Notice this enzyme has both fewer positive "bluish" amino acids, as well as many more negative "redish" amino acids than its mesophilic counterpart' align='left' scene='JMS/sandbox9/1hlp_new/5'/>
+|}
+{{Clear}}
+<!--
+'''High temperatures encourage using proline to lower entropy loss'''
 Some bacteria and even animals can survive great temperatures. Eggs fry - meaning their proteins denature, at 65℃. But ''Thermoanearobacter brockii'', discovered in Yellowstone Park, continues to grow in 80℃.
@@ Line 27: / Line 41: @@
 Professors Yigal Burstein (Weizmann Institute) and Felix Frolow (Tel Aviv University) studied a<scene name='JMS/sandbox5/Tbadh/1'>thermophilic alcohol dehydrogenase</scene> ([[1ykf]]) from ''T. brockii'' that maintains its structure in over 83℃.
-They identified two contributing factors to this enzymes thermal prowess. Firstly, he found the thermophilic enzyme had a unique <scene name='JMS/sandbox5/Ion_network/4'>four amino acid binding-network</scene> that encompassed two monomers of the tetrameric enzyme, repeating between each monomer and its two partner monomers. This network apparently makes the oligomer more stable. Secondly, the thermophilic enzyme was <scene name='JMS/sandbox5/Proline/2'>enriched for proline</scene>. Because proline's side chain has minimal degree of freedom, proline's, unlike other amino acids, are minimally restricted by folding. There is therefore a smaller loss of entropy upon folding into the native structure.
+They identified that the hyperthermophilic enzyme was <scene name='JMS/sandbox5/Proline/2'>enriched for proline</scene> in position 275, as was the thermophilic enzyme in position 100. Because proline's side chain has minimal degree of freedom, proline's, unlike other amino acids, are minimally restricted by folding. There is therefore a smaller loss of entropy upon folding into the native structure.
 <scene name='JMS/sandbox9/Tbadh/1'>TextToBeDisplayed</scene>
 <scene name='JMS/sandbox9/Ehadh1/1'>TextToBeDisplayed</scene>
 <scene name='JMS/sandbox9/Cbadh/1'>TextToBeDisplayed</scene>
+//-->
 </StructureSection>

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