Ann Taylor/Hemoglobin

From Proteopedia

(Difference between revisions)

Revision as of 17:38, 27 January 2014

Human Hemoglobin α chain (grey and pink) β chain (green and yellow) with bound O2 1gzx

Drag the structure with the mouse to rotate

Hemoglobin is an oxygen-transport protein. Hemoglobin is an allosteric protein. It is a tetramer composed of two types of subunits designated α and β, with stoichiometry . The of hemoglobin sit roughly at the corners of a tetrahedron, facing each other across a at the center of the molecule. Each of the subunits prosthetic group. The give hemoglobin its red color.

The α and β subunits have very similar structures, despite their sequence differences. We will use a single to examine the subunit structure more closely. The 6 major and 2 short α-helices that make up the structure of a Hb subunit (the "globin fold") are , which is the traditional naming scheme. The helices form an approximately-cylindrical bundle, with the heme and its central Fe atom bound in a (hydrophobic = grey; hydrophilic = purple). The proximal histidine (the tightest protein-Fe intraction) is often called , since it is residue 9 on helix F (it is residue 87 in the human α chain). A second histidine is near the bound oxygen. In the deoxy state, the Fe2+ is of the porphyrin ring. When oxygen is bound, the iron changes spin state, resulting in the iron moving of the heme.

Perhaps the most well-known disease caused by a mutation in the hemoglobin protein is sickle-cell anemia. It results from a mutation of the sixth residue in the β hemoglobin monomer from . This hemoglobin variant is termed 'hemoglobin S' (2hbs).

Hemoglobin subunit binding O₂

For hemoglobin to function as an oxygen-carrier in the blood, it must have an equilibrium between the two main states of its quaternary structure, the unliganded "deoxy" or "T state" versus the liganded "oxy" or "R state". The unliganded (deoxy) form is called the "T" (for "tense") state because it contains extra stabilizing interactions between the subunits. In the high-affinity R-state conformation the interactions which oppose oxygen binding and stabilize the tetramer are somewhat weaker or "relaxed". In some organisms this difference is so pronounced that their Hb molecules dissociate into dimers in the oxygenated form. Structural changes that occur during this transition can illuminate how such changes result in important functional properties, such as cooperativity of oxygen binding and allosteric control by pH and anions. Hemoglobin is definitely not a pure two-state system, but the T to R transition provides the major, first-level explanation of its function.

Content Donators

Much of this page's content originally came from the Hemoglobin page. To ensure stability during my class and to include some specific data we will be using in a paper discussion, this page was created.

Proteopedia Page Contributors and Editors (what is this?)

Ann Taylor

Retrieved from "http://52.214.119.220/wiki/index.php/Ann_Taylor/Hemoglobin"

@@ Line 1: / Line 1: @@
 <StructureSection load='1gzx' size='350' side='right' caption="Human Hemoglobin α chain (grey and pink) β chain (green and yellow) with bound O2 [[1gzx]]" scene="Hemoglobin/1gzx/2" >
-'''Hemoglobin''' is an oxygen-transport protein.  Hemoglobin is an [[allosteric protein]].  It is a tetramer composed of two types of subunits designated α and β, with stoichiometry <scene name='Hemoglobin/Alpha2beta2/7'>α2β2</scene>. The <scene name='Hemoglobin/Foursubunits/5'>four subunits</scene> of hemoglobin sit roughly at the corners of a tetrahedron, facing each other across a <scene name='57/576710/Cavity/1'>cavity</scene> at the center of the molecule.
+'''Hemoglobin''' is an oxygen-transport protein.  Hemoglobin is an [[allosteric protein]].  It is a tetramer composed of two types of subunits designated α and β, with stoichiometry <scene name='Hemoglobin/Alpha2beta2/7'>α2β2</scene>. The <scene name='Hemoglobin/Foursubunits/5'>four subunits</scene> of hemoglobin sit roughly at the corners of a tetrahedron, facing each other across a <scene name='57/576710/Cavity/1'>cavity</scene> at the center of the molecule. Each of the subunits <scene name='Hemoglobin/Bbsubunitswithheme/5'>contains a heme</scene> prosthetic group. The <scene name='Hemoglobin/4heme/3'>heme molecules</scene> give hemoglobin its red color.
-The α and β subunits have very similar structures, despite their sequence differences. We will use a single <scene name='57/576710/A_subunit_rainbow/1'>α chain</scene>  to examine the subunit structure more closely.  The 6 major and 2 short α-helices that make up the structure of a Hb subunit (the "globin fold") are <scene name='57/576710/A_subunit_labelled_helices/1'>labeled A through H</scene>, which is the traditional naming scheme.  For example, the proximal histidine (the tightest protein Fe ligand) is often called <scene name='Hemoglobin/3hhb_chaina_hisf9/5'>His F9</scene>, since it is residue 9 on helix F (it is residue 87 in the human α chain).  The helices form an approximately-cylindrical bundle, with the heme and its central Fe atom bound in a <scene name='Hemoglobin/3hhb_chaina_efpocket/4'>hydrophobic pocket between the E and F helices</scene>.
-Each of the subunits <scene name='Hemoglobin/Bbsubunitswithheme/5'>contains a heme</scene> prosthetic group. The <scene name='Hemoglobin/4heme/3'>heme molecules</scene> give hemoglobin its red color.  Each individual <scene name='Hemoglobin/Deoxyheme/8'>heme</scene> molecule contains one
-<scene name='Hemoglobin/Deoxyheme_fe/9'>Fe2+</scene> atom.  The spacefill view of the hemoglobin polypeptide subunit with an oxygenated heme group shows how the <scene name='Hemoglobin/Oxysubunitsf/4'>oxygenated heme group is held</scene> within the polypeptide.  <scene name='Hemoglobin/Anchortrace/5'>Anchoring of the heme</scene> is facilitated by a histidine nitrogen that binds to the iron. A second histidine is near the bound oxygen. The "arms" (propanoate groups) of the heme are hydrophilic and face the surface of the protein while the hydrophobic portions of the heme are buried among the hydrophobic amino acids of the protein.  In the deoxy state, the Fe2+ is <scene name='57/576710/Deoxy_non_planarity/1'>below the plane</scene> of the porphyrin ring.  When oxygen is bound, the iron changes spin state, resulting in the iron moving <scene name='57/576710/Oxy_fe_planarity/2'>into the plane</scene> of the heme.
-In the lungs, where oxygen is abundant, an <scene name='Hemoglobin/Oxyheme_fe/7'>oxygen molecule</scene> binds to the ferrous iron atom of the heme molecule and is later released in tissues needing oxygen. The heme group binds oxygen while still attached to the <scene name='Hemoglobin/Oxysubunit/8'>hemoglobin monomer</scene>.
+The α and β subunits have very similar structures, despite their sequence differences. We will use a single <scene name='57/576710/A_subunit_rainbow/1'>α chain</scene>  to examine the subunit structure more closely.  The 6 major and 2 short α-helices that make up the structure of a Hb subunit (the "globin fold") are <scene name='57/576710/A_subunit_labelled_helices/1'>labeled A through H</scene>, which is the traditional naming scheme. The helices form an approximately-cylindrical bundle, with the heme and its central Fe atom bound in a <scene name='57/576710/Hydrophobic_pocket/1'>hydrophobic pocket</scene> (hydrophobic = grey; hydrophilic = purple).  The proximal histidine (the tightest protein-Fe intraction) is often called <scene name='57/576710/His_f9/1'>His F9</scene>, since it is residue 9 on helix F (it is residue 87 in the human α chain).   A second histidine is near the bound oxygen. In the deoxy state, the Fe2+ is <scene name='57/576710/Deoxy_non_planarity/1'>below the plane</scene> of the porphyrin ring.  When oxygen is bound, the iron changes spin state, resulting in the iron moving <scene name='57/576710/Oxy_fe_planarity/2'>into the plane</scene> of the heme.
 Perhaps the most well-known disease caused by a mutation in the hemoglobin protein is sickle-cell anemia.  It results from a mutation of the sixth residue in the β hemoglobin monomer from <scene name='Hemoglobin/Hemoglobins_1hho/7'>glutamic acid to a valine</scene>.  This hemoglobin variant is termed 'hemoglobin S' ([[2hbs]]).
-<!-- <applet load='3hhb' size='400' frame='true' align='right' caption='Human deoxyhemoglobin (PDB code [[3hhb]])'/> -->
 ==Hemoglobin subunit binding O<sub>2</sub>==
-For hemoglobin, its function as an oxygen-carrier in the blood is fundamentally linked to the equilibrium between the two main states of its quaternary structure, the unliganded "deoxy" or "T state" versus the liganded "oxy" or "R state".  The unliganded (deoxy) form is called the "T" (for "tense") state because it contains extra stabilizing interactions between the subunits.  In the high-affinity R-state conformation the interactions which oppose oxygen binding and stabilize the tetramer are somewhat weaker or "relaxed".  In some organisms this difference is so pronounced that their Hb molecules dissociate into dimers in the oxygenated form.  Structural changes that occur during this transition can illuminate how such changes result in important functional properties, such as cooperativity of oxygen binding and allosteric control by pH and anions. Hemoglobin is definitely not a pure two-state system, but the T to R transition provides the major, first-level explanation of its function.
+For hemoglobin to function as an oxygen-carrier in the blood, it must have an equilibrium between the two main states of its quaternary structure, the unliganded "deoxy" or "T state" versus the liganded "oxy" or "R state".  The unliganded (deoxy) form is called the "T" (for "tense") state because it contains extra stabilizing interactions between the subunits.  In the high-affinity R-state conformation the interactions which oppose oxygen binding and stabilize the tetramer are somewhat weaker or "relaxed".  In some organisms this difference is so pronounced that their Hb molecules dissociate into dimers in the oxygenated form.  Structural changes that occur during this transition can illuminate how such changes result in important functional properties, such as cooperativity of oxygen binding and allosteric control by pH and anions. Hemoglobin is definitely not a pure two-state system, but the T to R transition provides the major, first-level explanation of its function.
 =='''Content Donators'''==
 Much of this page's content originally came from the [[Hemoglobin]] page.  To ensure stability during my class and to include some specific data we will be using in a paper discussion, this page was created.

Ann Taylor/Hemoglobin

From Proteopedia

Revision as of 17:38, 27 January 2014

Hemoglobin subunit binding O₂

Content Donators

Proteopedia Page Contributors and Editors (what is this?)

Views

Personal tools

Navigation

Search

Toolbox

Ann Taylor/Hemoglobin

From Proteopedia

Revision as of 17:38, 27 January 2014

Hemoglobin subunit binding O2

Content Donators

Proteopedia Page Contributors and Editors (what is this?)

Views

Personal tools

Navigation

Search

Toolbox

Hemoglobin subunit binding O₂