Presentation is loading. Please wait.

Presentation is loading. Please wait.

 Phospholipid bilayer  “Mosaic” of proteins The fluid-mosaic model.

Published byCaroline Montgomery Modified over 9 years ago

Similar presentations

Presentation on theme: " Phospholipid bilayer  “Mosaic” of proteins The fluid-mosaic model."— Presentation transcript:

1  Phospholipid bilayer  “Mosaic” of proteins The fluid-mosaic model

2  Carry out a cell’s functions:  Cell division  Energy generation  Protein synthesis  Synthesis of hormones  Response to hormone signals  Structure  Motility  Recycling of cell materials  DNA replication  RNA synthesis  Transport across membrane  Transport within cell  Response to infection  etc., etc., etc…. Proteins “What is the secret of life?” I asked. “I forget,” said Sandra. “Protein,” the bartender declared. “They found out something about protein.“ “Yeah,” said Sandra, “that's it.” --Kurt Vonnegut in Cat’s Cradle

3  Polymers of amino acids Proteins

4  Side chain gives distinctive chemical properties Amino acids

5  Protein = any of 20 amino acids arranged in any order Amino acids

6  Amino acids joined by peptide bonds Protein structure

7  Primary (1 ° ) structure = amino-acid sequence Protein structure methionineaspartateglycinephenylalaninevalinelysine N-Met-Asp-Gly-Phe-Val-Lys-C MDGFVK

8  Primary (1 ° ) structure = amino-acid sequence Protein structure Lysozyme, 211 amino acids: MetLeuGlyLysAsnAspProMetCysLeuValLeu ValLeuLeuGlyLeuThrAlaLeuLeuGlyIleCys GlnGlyGlyThrGlyCysTyrGlySerValSerArg IleAspThrThrGlyAlaSerCysArgThrAlaLys ProGluGlyLeuSerTyrCysGlyValArgAlaSer ArgThrIleAlaGluArgAspLeuGlySerMetAsn LysTyrLysValLeuIleLysArgValGlyGluAla LeuCysIleGluProAlaValIleAlaGlyIleIle SerArgGluSerHisAlaGlyLysIleLeuLysAsn GlyTrpGlyAspArgGlyAsnGlyPheGlyLeuMet GlnValAspLysArgTyrHisLysIleGluGlyThr TrpAsnGlyGluAlaHisIleArgGlnGlyThrArg IleLeuIleAspMetValLysLysIleGlnArgLys PheProArgTrpThrArgAspGlnGlnLeuLysGly GlyIleSerAlaTyrAsnAlaGlyValGlyAsnVal ArgSerTyrGluArgMetAspIleGlyThrLeuHis AspAspTyrSerAsnAspValValAlaArgAlaGln TyrPheLysGlnHisGlyTyr

9  Shape is critical to function!  Enzyme binds substrate  Antibody binds invading virus  Transport protein binds specific molecule Protein structure HIV Protease

10  Folding determines 3D shape  Amino-acid sequence determines folding Protein structure Lysozyme, 211 amino acids: MetLeuGlyLysAsnAspProMetCysLeuValLeu ValLeuLeuGlyLeuThrAlaLeuLeuGlyIleCys GlnGlyGlyThrGlyCysTyrGlySerValSerArg IleAspThrThrGlyAlaSerCysArgThrAlaLys ProGluGlyLeuSerTyrCysGlyValArgAlaSer ArgThrIleAlaGluArgAspLeuGlySerMetAsn LysTyrLysValLeuIleLysArgValGlyGluAla LeuCysIleGluProAlaValIleAlaGlyIleIle SerArgGluSerHisAlaGlyLysIleLeuLysAsn GlyTrpGlyAspArgGlyAsnGlyPheGlyLeuMet GlnValAspLysArgTyrHisLysIleGluGlyThr TrpAsnGlyGluAlaHisIleArgGlnGlyThrArg IleLeuIleAspMetValLysLysIleGlnArgLys PheProArgTrpThrArgAspGlnGlnLeuLysGly GlyIleSerAlaTyrAsnAlaGlyValGlyAsnVal ArgSerTyrGluArgMetAspIleGlyThrLeuHis AspAspTyrSerAsnAspValValAlaArgAlaGln TyrPheLysGlnHisGlyTyr

11  Secondary (2 ° ) structure = local folding Protein structure  -helix  -sheet

12  Held together by non-covalent interactions Protein structure

13  Tertiary (3 ° ) structure = overall 3D structure Protein structure

14  Tertiary (3 ° ) structure = overall 3D structure Protein structure myoglobin fatty acid binding protein CheY

15  Protein may fold into distinct domains Protein structure pyruvate kinase PEP + ADP → Pyruvate + ATP regulatory domain PEP binding domain ADP binding domain

16  Quaternary (4 ° ) structure = intermolecular interaction Protein structure

17  Quaternary (4 ° ) structure = intermolecular interaction Protein structure

18

19  Unfolding: disruption of non-covalent interactions Denaturation

20  Proteins can be denatured by heating Denaturation

21  Proteins have optimum temperature and pH for activity Denaturation temperature → protein function → pH → protein function → enzyme from Listeria bacteria enzyme from human cells enzyme from hot spring bacteria pepsin yeast enzyme human hemoglobin 737

22  What happens when a protein denatures, or misfolds? Denaturation

23 Prions: Pathogens without genes Normal form of Prion Protein is found in nerve cells but exact function is unknown. Abnormal form is folded in “sheets” rather than helices

24  Loss of dopaminergic neurons of the substantia nigra in the midbrain.  Loss of motor skills Parkinson’s Disease

25 alpha synuclein

26  Causes Parkinson’s Disease.  Can be passed from cell to cell. Alpha-Synuclein JA Steiner et al. 2011

27  Trans-membrane (integral) proteins  Peripheral membrane proteins Fluid-mosaic model

28 Rhodopsin structure retinal trans-membrane domain (hydrophobic)

29 RPE65 structure

Download ppt " Phospholipid bilayer  “Mosaic” of proteins The fluid-mosaic model."

Similar presentations

Proteins.

Proteins.
PROTEINS Proteins are the most complex and most diverse group of biological compounds. If you weigh about 70 kg: About 50 of your 70 kg is water. Many.

PROTEINS Proteins are the most complex and most diverse group of biological compounds. If you weigh about 70 kg: About 50 of your 70 kg is water. Many.
Organic Nutrients: The Building Blocks of Life 1. Carbohydrates 2.Lipids 3.Proteins 4.Nucleic Acids.

Organic Nutrients: The Building Blocks of Life 1. Carbohydrates 2.Lipids 3.Proteins 4.Nucleic Acids.
 Structural support: cacoons, webs, tendons, ligaments  Storage: egg whites  Enzymes: for digestion and to speed up life processes  Transport: hemoglobin,

 Structural support: cacoons, webs, tendons, ligaments  Storage: egg whites  Enzymes: for digestion and to speed up life processes  Transport: hemoglobin,
1 PROTEINS. 2 Proteins Proteins are polymers made of monomers called amino acids (aka building blocks) 8-10 we can not make. All proteins are made of.

1 PROTEINS. 2 Proteins Proteins are polymers made of monomers called amino acids (aka building blocks) 8-10 we can not make. All proteins are made of.
G-protein linked Plasma membrane receptor. Works with “G-protein”, an intracellular protein with GDP or GTP. Involved in yeast mating factors, epinephrine.

G-protein linked Plasma membrane receptor. Works with “G-protein”, an intracellular protein with GDP or GTP. Involved in yeast mating factors, epinephrine.
PROTEINS The most complex and multifunctional class of organic molecules Most genes are instructions for making protein molecules Large molecules with.

PROTEINS The most complex and multifunctional class of organic molecules Most genes are instructions for making protein molecules Large molecules with.
Chapter 5 Structure & Function of Macromolecules.

Chapter 5 Structure & Function of Macromolecules.
Diverse Macromolecules. V. proteins are macromolecules that are polymers formed from amino acids monomers A. proteins have great structural diversity.

Diverse Macromolecules. V. proteins are macromolecules that are polymers formed from amino acids monomers A. proteins have great structural diversity.
Proteins  Organic compounds made of C, O, H, N and S  Building blocks – 20 different amino acids  Peptide and Polypeptides: Dehydration (Condensation)/

Proteins  Organic compounds made of C, O, H, N and S  Building blocks – 20 different amino acids  Peptide and Polypeptides: Dehydration (Condensation)/
Chapter 3 Protein Structure and Function. Key Concepts Most cell functions depend on proteins. Amino acids are the building blocks of proteins. Amino.

Chapter 3 Protein Structure and Function. Key Concepts Most cell functions depend on proteins. Amino acids are the building blocks of proteins. Amino.
1 Proteins AP Biology Proteins Multipurpose molecules.

1 Proteins AP Biology Proteins Multipurpose molecules.
 Proteins have many different functions in the body  Structure – proteins help provide structure and support, make up muscles and bones.

 Proteins have many different functions in the body  Structure – proteins help provide structure and support, make up muscles and bones.
Life and Chemistry: Large Molecules. Macromolecules monomers are linked together to form polymers monomers are linked together to form polymers dehydration.

Life and Chemistry: Large Molecules. Macromolecules monomers are linked together to form polymers monomers are linked together to form polymers dehydration.
A protein’s function depends on its specific conformation (shape) A functional proteins consists of one or more polypeptides that have been precisely twisted,

A protein’s function depends on its specific conformation (shape) A functional proteins consists of one or more polypeptides that have been precisely twisted,
2005-2006 AP Biology Proteins. AP Biology Proteins  Most structurally & functionally diverse group of biomolecules  Function:  involved in almost everything.

AP Biology Proteins. AP Biology Proteins  Most structurally & functionally diverse group of biomolecules  Function:  involved in almost everything.
AP Biology Proteins Multipurpose molecules Proteins Most structurally & functionally diverse group Function: involved in almost everything – enzymes.

AP Biology Proteins Multipurpose molecules Proteins Most structurally & functionally diverse group Function: involved in almost everything – enzymes.
AP Biology 2008-2009 Proteins Multipurpose molecules.

AP Biology Proteins Multipurpose molecules.
Proteins.

Proteins.
AP Biology Chemical Building Blocks  3.4 Proteins.

AP Biology Chemical Building Blocks  3.4 Proteins.

Similar presentations

Ads by Google