SlideShare una empresa de Scribd logo

Proteins and nucleic acids 2014

Descargar como PPT, PDF
Sharda Berfect
Sharda Berfect

A&P

Ciencias
1 de 35
Proteins and Nucleic Acids BIO 351 Human Anatomy and Physiology I
Proteins: Characteristics  Make up 10 to 30% of cell mass.  Basic structural material of the body.  Play vital roles in cell functioning.  All contain carbon, hydrogen, oxygen, and nitrogen. Some contain sulfur or phosphorus also.  All proteins are made up of building blocks called amino acids.
Muscle tissue contains the proteins myosin and actin. Muscles
Amino Acids  20 commonly occur in nature, 8 of these are essential AA (can’t be synthesized by human body, must be included in diet)  Two important functional groups—the amino group (can act as a base and accept protons) and the carboxyl group (can act as an acid and donate protons).  All amino acids are identical except for the R group—the R groups are what make each amino acid different and chemically unique.
Basic Amino Acid Structure
R Groups Highlighted
Protein Formation  Proteins are formed from amino acids by dehydration synthesis.  The bonds between adjacent amino acids are called peptide bonds.  Most proteins contain over 100 amino acids and are truly macromolecules. Some contain up to 10,000 amino acids.
Organization of Proteins - 4 Structural Levels of Proteins  Primary structure– the linear sequence of amino acids in the chain.  Secondary structure—formed by coiling of the primary chain into an alpha helix (with hydrogen bonds maintaining the coiled structure) or a beta pleated sheet (hydrogen bonds hold primary polypeptide chains side by side in a pleated structure like an accordion).
Structural Levels of Proteins  Tertiary structure—achieved when an alpha helix or beta pleated sheet folds in a three dimensional way to produce a globular molecule.  The structure is maintained by both hydrogen and covalent bonds.
Structural Levels  Quaternary structure—happens when two or more polypeptide chains aggregate in a regular manner to form a complex protein.  The shape of a protein determines its function. Anything that causes the protein to unfold will result in the protein being unable to perform its job.
Hemoglobin
Fibrous Proteins  Strand-like  Also called structural proteins.  Most exhibit secondary structure only but some have quaternary structure as well (collagen is an example of a protein with quaternary structure).  Insoluble in water  Very stable  Provide mechanical support and tensile strength.  Examples include collagen and keratin (both of which are present in skin), and the muscle proteins actin and myosin
Globular Proteins  Spherical and compact  Tertiary structure; some with quaternary structure as well  Water soluble  Chemically active  Examples are enzymes and antibodies  Also called functional proteins  Susceptible to denaturing
Protein Denaturation  The activity of functional proteins depends on their three dimensional structure.  The hydrogen bonds responsible for maintaining the structure are fragile and can be broken by changes in both the physical and chemical environment.  Hydrogen bonds begin to break when the pH changes or the temperature rises above normal.  The proteins unfold and lose their biological activity.
Enzymes  Enzymes are globular proteins that act as biological catalysts.  Each enzyme is chemically specific.  Enzymes work by lowering the activation energy of a reaction.  Enzymes act on substrates and trigger chemical reactions in the body.
Enzyme Activity
Nucleic Acids  Contain carbon, hydrogen, oxygen, nitrogen, and phosphorus  Two types—DNA and RNA  DNA is the genetic material of the cell and is found in the nucleus.  It replicates itself in order for cell division to occur.  It provides instructions for protein synthesis.  There are 3 major types of RNA (messenger, transfer and ribosomal). Each has a different function.
DNA  DNA is coiled like a spiral staircase or ladder, known as a double helix  The 2 “backbones” are composed of alternating sugar and phosphate groups  Each “rung” of the ladder is composed of 2 nitrogenous bases hooked together by hydrogen bonds  Chromosomes are formed from DNA. Genes are sections of chromosomes. Taken together, all of the genetic material in a cell’s nucleus is known as a genome
Nucleotides  The structural units of nucleic acids  Each nucleotide has three components  N-containing base  5-carbon sugar (a pentose)  Phosphate group (Note: A nucleoside consists of just a base plus a pentose sugar without the phosphate)
N-containing Bases  There are 5 different N-containing bases found in nucleic acids. These are divided into 2 types, purines and pyrimidines.  They follow these base-pairing rules:  Adenine pairs with thymine  Cytosine pairs with guanine  Uracil replaces thymine in RNA  Adenine and guanine are purines. They each contain 2 rings.  Cytosine, uracil, and thymine are pyrimidines. They each have a single ring structure.
The nucleic acids are the largest molecules in the body.
DNA  DNA replicates itself before cell division and provides instructions for making all of the proteins found in the body.  The structure of DNA is a double-stranded polymer containing the nitrogenous bases A, T, G, and C, and the sugar deoxyribose.  Bonding of the nitrogenous bases in DNA is very specific; A bonds to T (via 2 hydrogen bonds), and G bonds to C (via 3 hydrogen bonds)  The bases that always bind together are known as complementary bases.
DNA polymerase III adds one nucleotide at a time to the 3’ end of the newly formed strand following base pairing rules
RNA  The major types of RNA are produced inside the nucleus, and then transported into the cytoplasm, where they are used to make proteins according to the instructions provided by the DNA.  The structure of most types of RNA is a single-stranded polymer containing the nitrogenous bases A (adenine), G (guanine), C (cytosine), and U (uracil), and the sugar ribose.  In RNA, G bonds with C, and A bonds with U.
Genetic Code
ATP  ATP is the energy currency used by the cell.  ATP is an adenine-containing RNA nucleotide that has two additional phosphate groups attached.  The additional phosphate groups are connected by high energy bonds.  Breaking the high energy bonds releases energy the cell can use to do work.
Proteins and nucleic acids 2014

Recomendados

Classification of proteins
Classification of proteinsClassification of proteins
Classification of proteins
ShaliniSingh678
 
STRUCTURAL ORGANIZATION OF PROTEINS
STRUCTURAL ORGANIZATION OF PROTEINSSTRUCTURAL ORGANIZATION OF PROTEINS
STRUCTURAL ORGANIZATION OF PROTEINS
Shylesh M
 
Protein biochemistry
Protein biochemistryProtein biochemistry
Protein biochemistry
yaseen khan
 
Protein sturucture
Protein stuructureProtein sturucture
Protein sturucture
Dr Syed Ismail Ibrahim
 
Protein structure & function
Protein structure & functionProtein structure & function
Protein structure & function
Dr. Sunil Kumar
 
Protein structure
Protein structureProtein structure
Protein structure
paigep
 
Structure of Proteins
Structure of ProteinsStructure of Proteins
Structure of Proteins
clairebloom
 
Introduction to protein and classification by sohail
Introduction to protein and classification by sohailIntroduction to protein and classification by sohail
Introduction to protein and classification by sohail
Quaid-e-Azam University, Islamabad
 

Recomendados

Classification of proteins
Classification of proteinsClassification of proteins
Classification of proteins
ShaliniSingh678
 
STRUCTURAL ORGANIZATION OF PROTEINS
STRUCTURAL ORGANIZATION OF PROTEINSSTRUCTURAL ORGANIZATION OF PROTEINS
STRUCTURAL ORGANIZATION OF PROTEINS
Shylesh M
 
Protein biochemistry
Protein biochemistryProtein biochemistry
Protein biochemistry
yaseen khan
 
Protein sturucture
Protein stuructureProtein sturucture
Protein sturucture
Dr Syed Ismail Ibrahim
 
Protein structure & function
Protein structure & functionProtein structure & function
Protein structure & function
Dr. Sunil Kumar
 
Protein structure
Protein structureProtein structure
Protein structure
paigep
 
Structure of Proteins
Structure of ProteinsStructure of Proteins
Structure of Proteins
clairebloom
 
Introduction to protein and classification by sohail
Introduction to protein and classification by sohailIntroduction to protein and classification by sohail
Introduction to protein and classification by sohail
Quaid-e-Azam University, Islamabad
 
Fibrous proteins
Fibrous proteinsFibrous proteins
Fibrous proteins
Kinza Ayub
 
Protein and its classification
Protein and its classificationProtein and its classification
Protein and its classification
kumaarvikas
 
AS Level Biology - 1) Biological Molecules
AS Level Biology - 1) Biological MoleculesAS Level Biology - 1) Biological Molecules
AS Level Biology - 1) Biological Molecules
Arm Punyathorn
 
Protein as a Biomolecule
Protein as a BiomoleculeProtein as a Biomolecule
Protein as a Biomolecule
Dr. Pranabjyoti Das
 
Biochemistry lecture notes nucleic acids
Biochemistry lecture notes nucleic acidsBiochemistry lecture notes nucleic acids
Biochemistry lecture notes nucleic acids
Rengesh Balakrishnan
 
Proteins biochem
Proteins biochemProteins biochem
Proteins biochem
Maria Chermille Boiser
 
Macromolecular structure and biological function of primary protiens
Macromolecular structure and biological function of primary protiensMacromolecular structure and biological function of primary protiens
Macromolecular structure and biological function of primary protiens
Arjun K Gopi
 
Biological molecules
Biological moleculesBiological molecules
Biological molecules
Bantato
 
Structural organisation of protiens
Structural organisation of protiensStructural organisation of protiens
Structural organisation of protiens
Vikas CJ Vikki
 
Protein Structure and Function
Protein Structure and FunctionProtein Structure and Function
Protein Structure and Function
Veronica B
 
Proteins
ProteinsProteins
Proteins
obanbrahma
 
Proteins
ProteinsProteins
Proteins
Dr Muhammad Mustansar
 
Structure, functions and folding problems of protein
Structure, functions and folding problems of proteinStructure, functions and folding problems of protein
Structure, functions and folding problems of protein
Rawat DA Greatt
 
Protein Structure & Function
Protein Structure & FunctionProtein Structure & Function
Protein Structure & Function
iptharis
 
Architecture of proteins
Architecture of proteinsArchitecture of proteins
Architecture of proteins
Arnabesh das
 
Part I : Introduction to Protein Structure
Part I : Introduction to Protein StructurePart I : Introduction to Protein Structure
Part I : Introduction to Protein Structure
Mohamed Ramadan Hassan Attalla
 
Protein structure
Protein structureProtein structure
Protein structure
nidhiinjbp
 
Tertiary structure of proteins
Tertiary structure of proteinsTertiary structure of proteins
Tertiary structure of proteins
Kinza Ayub
 
7.5 proteins2
7.5 proteins27.5 proteins2
7.5 proteins2
Наталья Григорьева
 
Protein structure
Protein structureProtein structure
Protein structure
ranjani n
 
The chemical nature of the cell
The chemical nature of the cellThe chemical nature of the cell
The chemical nature of the cell
Ian Anderson
 
Cell Chemistry
Cell Chemistry Cell Chemistry
Cell Chemistry
Nawfal Aldujaily
 

Más contenido relacionado

La actualidad más candente

Fibrous proteins
Fibrous proteinsFibrous proteins
Fibrous proteins
Kinza Ayub
 
Macromolecular structure and biological function of primary protiens
Macromolecular structure and biological function of primary protiensMacromolecular structure and biological function of primary protiens
Macromolecular structure and biological function of primary protiens
Arjun K Gopi
 
Protein Structure & Function
Protein Structure & FunctionProtein Structure & Function
Protein Structure & Function
iptharis
 
Tertiary structure of proteins
Tertiary structure of proteinsTertiary structure of proteins
Tertiary structure of proteins
Kinza Ayub
 

La actualidad más candente (20)

Fibrous proteins
Fibrous proteinsFibrous proteins
Fibrous proteins
 
Protein and its classification
Protein and its classificationProtein and its classification
Protein and its classification
 
AS Level Biology - 1) Biological Molecules
AS Level Biology - 1) Biological MoleculesAS Level Biology - 1) Biological Molecules
AS Level Biology - 1) Biological Molecules
 
Protein as a Biomolecule
Protein as a BiomoleculeProtein as a Biomolecule
Protein as a Biomolecule
 
Biochemistry lecture notes nucleic acids
Biochemistry lecture notes nucleic acidsBiochemistry lecture notes nucleic acids
Biochemistry lecture notes nucleic acids
 
Proteins biochem
Proteins biochemProteins biochem
Proteins biochem
 
Macromolecular structure and biological function of primary protiens
Macromolecular structure and biological function of primary protiensMacromolecular structure and biological function of primary protiens
Macromolecular structure and biological function of primary protiens
 
Biological molecules
Biological moleculesBiological molecules
Biological molecules
 
Structural organisation of protiens
Structural organisation of protiensStructural organisation of protiens
Structural organisation of protiens
 
Protein Structure and Function
Protein Structure and FunctionProtein Structure and Function
Protein Structure and Function
 
Proteins
ProteinsProteins
Proteins
 
Proteins
ProteinsProteins
Proteins
 
Structure, functions and folding problems of protein
Structure, functions and folding problems of proteinStructure, functions and folding problems of protein
Structure, functions and folding problems of protein
 
Protein Structure & Function
Protein Structure & FunctionProtein Structure & Function
Protein Structure & Function
 
Architecture of proteins
Architecture of proteinsArchitecture of proteins
Architecture of proteins
 
Part I : Introduction to Protein Structure
Part I : Introduction to Protein StructurePart I : Introduction to Protein Structure
Part I : Introduction to Protein Structure
 
Protein structure
Protein structureProtein structure
Protein structure
 
Tertiary structure of proteins
Tertiary structure of proteinsTertiary structure of proteins
Tertiary structure of proteins
 
7.5 proteins2
7.5 proteins27.5 proteins2
7.5 proteins2
 
Protein structure
Protein structureProtein structure
Protein structure
 

Similar a Proteins and nucleic acids 2014

The chemical nature of the cell
The chemical nature of the cellThe chemical nature of the cell
The chemical nature of the cell
Ian Anderson
 
Proteins.pdf
Proteins.pdfProteins.pdf
Proteins.pdf
zainulabideen762825
 
Biomolecule Examples
Biomolecule ExamplesBiomolecule Examples
Biomolecule Examples
BeatrizAspiras
 
Apch5ppt
Apch5pptApch5ppt
Apch5ppt
hursmi
 
Unit 3 Biology Study Cards
Unit 3 Biology Study CardsUnit 3 Biology Study Cards
Unit 3 Biology Study Cards
Martin Jellinek
 

Similar a Proteins and nucleic acids 2014 (20)

The chemical nature of the cell
The chemical nature of the cellThe chemical nature of the cell
The chemical nature of the cell
 
Cell Chemistry
Cell Chemistry Cell Chemistry
Cell Chemistry
 
Biochemistry of cells
Biochemistry of cellsBiochemistry of cells
Biochemistry of cells
 
Biological molecules
Biological moleculesBiological molecules
Biological molecules
 
Biology for Majors, Macromolecules
Biology for Majors, MacromoleculesBiology for Majors, Macromolecules
Biology for Majors, Macromolecules
 
Structures and Functions of Biological Molecules Grade 11 Biology.pptx
Structures and Functions of Biological Molecules Grade 11 Biology.pptxStructures and Functions of Biological Molecules Grade 11 Biology.pptx
Structures and Functions of Biological Molecules Grade 11 Biology.pptx
 
Protein metabolism and nitrogen fixation and metabolism
Protein metabolism and nitrogen fixation and metabolismProtein metabolism and nitrogen fixation and metabolism
Protein metabolism and nitrogen fixation and metabolism
 
biomolecules.pdf
biomolecules.pdfbiomolecules.pdf
biomolecules.pdf
 
Biomolecule for class 11 science
Biomolecule for class 11 scienceBiomolecule for class 11 science
Biomolecule for class 11 science
 
Proteins.pdf
Proteins.pdfProteins.pdf
Proteins.pdf
 
Biomolecule Examples
Biomolecule ExamplesBiomolecule Examples
Biomolecule Examples
 
Biochemistry (protein synthesis)
Biochemistry (protein synthesis)Biochemistry (protein synthesis)
Biochemistry (protein synthesis)
 
Apch5ppt
Apch5pptApch5ppt
Apch5ppt
 
Proteins
ProteinsProteins
Proteins
 
BIOMOLECULES.pptx
BIOMOLECULES.pptxBIOMOLECULES.pptx
BIOMOLECULES.pptx
 
macromolecules by kk sahu sir
macromolecules by kk sahu sir macromolecules by kk sahu sir
macromolecules by kk sahu sir
 
The different Biomolecules
The different BiomoleculesThe different Biomolecules
The different Biomolecules
 
DNA, RNA, PROTEIN.pptx
DNA, RNA, PROTEIN.pptxDNA, RNA, PROTEIN.pptx
DNA, RNA, PROTEIN.pptx
 
Unit 3 Biology Study Cards
Unit 3 Biology Study CardsUnit 3 Biology Study Cards
Unit 3 Biology Study Cards
 
Organic Macromolecules
Organic MacromoleculesOrganic Macromolecules
Organic Macromolecules
 

Más de Sharda Berfect

Bones and skeletal tissues 2014
Bones and skeletal tissues 2014Bones and skeletal tissues 2014
Bones and skeletal tissues 2014
Sharda Berfect
 
Axial skeleton cranial images
Axial skeleton cranial imagesAxial skeleton cranial images
Axial skeleton cranial images
Sharda Berfect
 
The integumentary system 2015
The integumentary system 2015The integumentary system 2015
The integumentary system 2015
Sharda Berfect
 

Más de Sharda Berfect (11)

Skeletal system 2014
Skeletal system 2014Skeletal system 2014
Skeletal system 2014
 
Axial skeleton
Axial skeletonAxial skeleton
Axial skeleton
 
Bones and skeletal tissues 2014
Bones and skeletal tissues 2014Bones and skeletal tissues 2014
Bones and skeletal tissues 2014
 
Axial skeleton cranial images
Axial skeleton cranial imagesAxial skeleton cranial images
Axial skeleton cranial images
 
Appendicular skeleton
Appendicular skeletonAppendicular skeleton
Appendicular skeleton
 
Epithelial tissue (2011)
Epithelial tissue (2011)Epithelial tissue (2011)
Epithelial tissue (2011)
 
Cells anatomy 2013
Cells anatomy 2013Cells anatomy 2013
Cells anatomy 2013
 
Cell physiology 2013
Cell physiology 2013Cell physiology 2013
Cell physiology 2013
 
Biochemistry 2015
Biochemistry 2015Biochemistry 2015
Biochemistry 2015
 
Connective tissue 2013
Connective tissue 2013Connective tissue 2013
Connective tissue 2013
 
The integumentary system 2015
The integumentary system 2015The integumentary system 2015
The integumentary system 2015
 

Último

Conjugation, transduction and transformation
Conjugation, transduction and transformationConjugation, transduction and transformation
Conjugation, transduction and transformation
Areesha Ahmad
 
Human genetics..........................pptx
Human genetics..........................pptxHuman genetics..........................pptx
Human genetics..........................pptx
Silpa
 
The Mariana Trench remarkable geological features on Earth.pptx
The Mariana Trench remarkable geological features on Earth.pptxThe Mariana Trench remarkable geological features on Earth.pptx
The Mariana Trench remarkable geological features on Earth.pptx
seri bangash
 
Porella : features, morphology, anatomy, reproduction etc.
Porella : features, morphology, anatomy, reproduction etc.Porella : features, morphology, anatomy, reproduction etc.
Porella : features, morphology, anatomy, reproduction etc.
Silpa
 

Último (20)

Clean In Place(CIP).pptx .
Clean In Place(CIP).pptx .Clean In Place(CIP).pptx .
Clean In Place(CIP).pptx .
 
Bhiwandi Bhiwandi ❤CALL GIRL 7870993772 ❤CALL GIRLS ESCORT SERVICE In Bhiwan...
Bhiwandi Bhiwandi ❤CALL GIRL 7870993772 ❤CALL GIRLS ESCORT SERVICE In Bhiwan...Bhiwandi Bhiwandi ❤CALL GIRL 7870993772 ❤CALL GIRLS ESCORT SERVICE In Bhiwan...
Bhiwandi Bhiwandi ❤CALL GIRL 7870993772 ❤CALL GIRLS ESCORT SERVICE In Bhiwan...
 
Factory Acceptance Test( FAT).pptx .
Factory Acceptance Test( FAT).pptx .Factory Acceptance Test( FAT).pptx .
Factory Acceptance Test( FAT).pptx .
 
Thyroid Physiology_Dr.E. Muralinath_ Associate Professor
Thyroid Physiology_Dr.E. Muralinath_ Associate ProfessorThyroid Physiology_Dr.E. Muralinath_ Associate Professor
Thyroid Physiology_Dr.E. Muralinath_ Associate Professor
 
Conjugation, transduction and transformation
Conjugation, transduction and transformationConjugation, transduction and transformation
Conjugation, transduction and transformation
 
Grade 7 - Lesson 1 - Microscope and Its Functions
Grade 7 - Lesson 1 - Microscope and Its FunctionsGrade 7 - Lesson 1 - Microscope and Its Functions
Grade 7 - Lesson 1 - Microscope and Its Functions
 
FAIRSpectra - Enabling the FAIRification of Analytical Science
FAIRSpectra - Enabling the FAIRification of Analytical ScienceFAIRSpectra - Enabling the FAIRification of Analytical Science
FAIRSpectra - Enabling the FAIRification of Analytical Science
 
Human genetics..........................pptx
Human genetics..........................pptxHuman genetics..........................pptx
Human genetics..........................pptx
 
The Mariana Trench remarkable geological features on Earth.pptx
The Mariana Trench remarkable geological features on Earth.pptxThe Mariana Trench remarkable geological features on Earth.pptx
The Mariana Trench remarkable geological features on Earth.pptx
 
Introduction of DNA analysis in Forensic's .pptx
Introduction of DNA analysis in Forensic's .pptxIntroduction of DNA analysis in Forensic's .pptx
Introduction of DNA analysis in Forensic's .pptx
 
Proteomics: types, protein profiling steps etc.
Proteomics: types, protein profiling steps etc.Proteomics: types, protein profiling steps etc.
Proteomics: types, protein profiling steps etc.
 
Stages in the normal growth curve
Stages in the normal growth curveStages in the normal growth curve
Stages in the normal growth curve
 
Porella : features, morphology, anatomy, reproduction etc.
Porella : features, morphology, anatomy, reproduction etc.Porella : features, morphology, anatomy, reproduction etc.
Porella : features, morphology, anatomy, reproduction etc.
 
CURRENT SCENARIO OF POULTRY PRODUCTION IN INDIA
CURRENT SCENARIO OF POULTRY PRODUCTION IN INDIACURRENT SCENARIO OF POULTRY PRODUCTION IN INDIA
CURRENT SCENARIO OF POULTRY PRODUCTION IN INDIA
 
Use of mutants in understanding seedling development.pptx
Use of mutants in understanding seedling development.pptxUse of mutants in understanding seedling development.pptx
Use of mutants in understanding seedling development.pptx
 
Velocity and Acceleration PowerPoint.ppt
Velocity and Acceleration PowerPoint.pptVelocity and Acceleration PowerPoint.ppt
Velocity and Acceleration PowerPoint.ppt
 
Human & Veterinary Respiratory Physilogy_DR.E.Muralinath_Associate Professor....
Human & Veterinary Respiratory Physilogy_DR.E.Muralinath_Associate Professor....Human & Veterinary Respiratory Physilogy_DR.E.Muralinath_Associate Professor....
Human & Veterinary Respiratory Physilogy_DR.E.Muralinath_Associate Professor....
 
Site Acceptance Test .
Site Acceptance Test .Site Acceptance Test .
Site Acceptance Test .
 
Zoology 5th semester notes( Sumit_yadav).pdf
Zoology 5th semester notes( Sumit_yadav).pdfZoology 5th semester notes( Sumit_yadav).pdf
Zoology 5th semester notes( Sumit_yadav).pdf
 
COMPUTING ANTI-DERIVATIVES (Integration by SUBSTITUTION)
COMPUTING ANTI-DERIVATIVES (Integration by SUBSTITUTION)COMPUTING ANTI-DERIVATIVES (Integration by SUBSTITUTION)
COMPUTING ANTI-DERIVATIVES (Integration by SUBSTITUTION)
 

Proteins and nucleic acids 2014

  • 1. Proteins and Nucleic Acids BIO 351 Human Anatomy and Physiology I
  • 2. Proteins: Characteristics  Make up 10 to 30% of cell mass.  Basic structural material of the body.  Play vital roles in cell functioning.  All contain carbon, hydrogen, oxygen, and nitrogen. Some contain sulfur or phosphorus also.  All proteins are made up of building blocks called amino acids.
  • 3. Muscle tissue contains the proteins myosin and actin. Muscles
  • 4. Amino Acids  20 commonly occur in nature, 8 of these are essential AA (can’t be synthesized by human body, must be included in diet)  Two important functional groups—the amino group (can act as a base and accept protons) and the carboxyl group (can act as an acid and donate protons).  All amino acids are identical except for the R group—the R groups are what make each amino acid different and chemically unique.
  • 5. Basic Amino Acid Structure
  • 7. Protein Formation  Proteins are formed from amino acids by dehydration synthesis.  The bonds between adjacent amino acids are called peptide bonds.  Most proteins contain over 100 amino acids and are truly macromolecules. Some contain up to 10,000 amino acids.
  • 8. Organization of Proteins - 4 Structural Levels of Proteins  Primary structure– the linear sequence of amino acids in the chain.  Secondary structure—formed by coiling of the primary chain into an alpha helix (with hydrogen bonds maintaining the coiled structure) or a beta pleated sheet (hydrogen bonds hold primary polypeptide chains side by side in a pleated structure like an accordion).
  • 9.
  • 10. Structural Levels of Proteins  Tertiary structure—achieved when an alpha helix or beta pleated sheet folds in a three dimensional way to produce a globular molecule.  The structure is maintained by both hydrogen and covalent bonds.
  • 11.
  • 12. Structural Levels  Quaternary structure—happens when two or more polypeptide chains aggregate in a regular manner to form a complex protein.  The shape of a protein determines its function. Anything that causes the protein to unfold will result in the protein being unable to perform its job.
  • 14.
  • 15. Fibrous Proteins  Strand-like  Also called structural proteins.  Most exhibit secondary structure only but some have quaternary structure as well (collagen is an example of a protein with quaternary structure).  Insoluble in water  Very stable  Provide mechanical support and tensile strength.  Examples include collagen and keratin (both of which are present in skin), and the muscle proteins actin and myosin
  • 16. Globular Proteins  Spherical and compact  Tertiary structure; some with quaternary structure as well  Water soluble  Chemically active  Examples are enzymes and antibodies  Also called functional proteins  Susceptible to denaturing
  • 17.
  • 18. Protein Denaturation  The activity of functional proteins depends on their three dimensional structure.  The hydrogen bonds responsible for maintaining the structure are fragile and can be broken by changes in both the physical and chemical environment.  Hydrogen bonds begin to break when the pH changes or the temperature rises above normal.  The proteins unfold and lose their biological activity.
  • 19. Enzymes  Enzymes are globular proteins that act as biological catalysts.  Each enzyme is chemically specific.  Enzymes work by lowering the activation energy of a reaction.  Enzymes act on substrates and trigger chemical reactions in the body.
  • 21. Nucleic Acids  Contain carbon, hydrogen, oxygen, nitrogen, and phosphorus  Two types—DNA and RNA  DNA is the genetic material of the cell and is found in the nucleus.  It replicates itself in order for cell division to occur.  It provides instructions for protein synthesis.  There are 3 major types of RNA (messenger, transfer and ribosomal). Each has a different function.
  • 22.
  • 23. DNA  DNA is coiled like a spiral staircase or ladder, known as a double helix  The 2 “backbones” are composed of alternating sugar and phosphate groups  Each “rung” of the ladder is composed of 2 nitrogenous bases hooked together by hydrogen bonds  Chromosomes are formed from DNA. Genes are sections of chromosomes. Taken together, all of the genetic material in a cell’s nucleus is known as a genome
  • 24. Nucleotides  The structural units of nucleic acids  Each nucleotide has three components  N-containing base  5-carbon sugar (a pentose)  Phosphate group (Note: A nucleoside consists of just a base plus a pentose sugar without the phosphate)
  • 25. N-containing Bases  There are 5 different N-containing bases found in nucleic acids. These are divided into 2 types, purines and pyrimidines.  They follow these base-pairing rules:  Adenine pairs with thymine  Cytosine pairs with guanine  Uracil replaces thymine in RNA  Adenine and guanine are purines. They each contain 2 rings.  Cytosine, uracil, and thymine are pyrimidines. They each have a single ring structure.
  • 26. The nucleic acids are the largest molecules in the body.
  • 27. DNA  DNA replicates itself before cell division and provides instructions for making all of the proteins found in the body.  The structure of DNA is a double-stranded polymer containing the nitrogenous bases A, T, G, and C, and the sugar deoxyribose.  Bonding of the nitrogenous bases in DNA is very specific; A bonds to T (via 2 hydrogen bonds), and G bonds to C (via 3 hydrogen bonds)  The bases that always bind together are known as complementary bases.
  • 28.
  • 29. DNA polymerase III adds one nucleotide at a time to the 3’ end of the newly formed strand following base pairing rules
  • 30. RNA  The major types of RNA are produced inside the nucleus, and then transported into the cytoplasm, where they are used to make proteins according to the instructions provided by the DNA.  The structure of most types of RNA is a single-stranded polymer containing the nitrogenous bases A (adenine), G (guanine), C (cytosine), and U (uracil), and the sugar ribose.  In RNA, G bonds with C, and A bonds with U.
  • 31.
  • 33.
  • 34. ATP  ATP is the energy currency used by the cell.  ATP is an adenine-containing RNA nucleotide that has two additional phosphate groups attached.  The additional phosphate groups are connected by high energy bonds.  Breaking the high energy bonds releases energy the cell can use to do work.