Structure of ATP
Structure and function of atp.
ATP is called a nucleotide derivative because it is a modified form of a nucleotide.
Components of ATP
- Adenine - a nitrogenous base.
- Ribose - a five-carbon sugar.
- Three phosphate groups.
Function of ATP
- ATP is a small, relatively simple molecule.
- ATP is the cell's equivalent of money, which people exchange for things they need.
- ATP is used to power most energy-requiring cellular reactions.
1 Biological Molecules
1.1 Monomers & Polymers
1.1.1 Monomers & Polymers
1.1.2 Condensation & Hydrolysis Reactions
1.2 Carbohydrates
1.2.1 Structure of Carbohydrates
1.2.2 Types of Polysaccharides
1.2.3 End of Topic Test - Monomers, Polymers and Carbs
1.2.4 Exam-Style Question - Carbohydrates
1.2.5 A-A* (AO3/4) - Carbohydrates
1.3.1 Triglycerides & Phospholipids
1.3.2 Types of Fatty Acids
1.3.3 Testing for Lipids
1.3.4 Exam-Style Question - Fats
1.3.5 A-A* (AO3/4) - Lipids
1.4 Proteins
1.4.1 The Peptide Chain
1.4.2 Investigating Proteins
1.4.3 Primary & Secondary Protein Structure
1.4.4 Tertiary & Quaternary Protein Structure
1.4.5 Enzymes
1.4.6 Factors Affecting Enzyme Activity
1.4.7 Enzyme-Controlled Reactions
1.4.8 End of Topic Test - Lipids & Proteins
1.4.9 A-A* (AO3/4) - Enzymes
1.4.10 A-A* (AO3/4) - Proteins
1.5 Nucleic Acids
1.5.1 DNA & RNA
1.5.2 Nucleotides
1.5.3 Polynucleotides
1.5.4 DNA Replication
1.5.5 Exam-Style Question - Nucleic Acids
1.5.6 A-A* (AO3/4) - Nucleic Acids
1.6.1 Structure of ATP
1.6.2 Hydrolysis of ATP
1.6.3 Resynthesis of ATP
1.6.4 End of Topic Test - Nucleic Acids & ATP
1.7.1 Importance of Water
1.7.2 Structure of Water
1.7.3 Properties of Water
1.7.4 A-A* (AO3/4) - Water
1.8 Inorganic Ions
1.8.1 Inorganic Ions
1.8.2 End of Topic Test - Water & Inorganic Ions
2.1 Cell Structure
2.1.1 Introduction to Cells
2.1.2 Eukaryotic Cells & Organelles
2.1.3 Eukaryotic Cells & Organelles 2
2.1.4 Prokaryotes
2.1.5 A-A* (AO3/4) - Organelles
2.1.6 Methods of Studying Cells
2.1.7 Microscopes
2.1.8 End of Topic Test - Cell Structure
2.1.9 Exam-Style Question - Cells
2.1.10 A-A* (AO3/4) - Cells
2.2 Mitosis & Cancer
2.2.1 Mitosis
2.2.2 Stages of Mitosis
2.2.3 Investigating Mitosis
2.2.4 Cancer
2.2.5 A-A* (AO3/4) - The Cell Cycle
2.3 Transport Across Cell Membrane
2.3.1 Cell Membrane Structure
2.3.2 A-A* (AO3/4) - Membrane Structure
2.3.3 Diffusion
2.3.4 Osmosis
2.3.5 Active Transport
2.3.6 End of Topic Test - Mitosis, Cancer & Transport
2.3.7 Exam-Style Question - Membranes
2.3.8 A-A* (AO3/4) - Membranes & Transport
2.3.9 A-A*- Mitosis, Cancer & Transport
2.4 Cell Recognition & the Immune System
2.4.1 Immune System
2.4.2 Phagocytosis
2.4.3 T Lymphocytes
2.4.4 B Lymphocytes
2.4.5 Antibodies
2.4.6 Primary & Secondary Response
2.4.7 Vaccines
2.4.9 Ethical Issues
2.4.10 End of Topic Test - Immune System
2.4.11 Exam-Style Question - Immune System
2.4.12 A-A* (AO3/4) - Immune System
3 Substance Exchange
3.1 Surface Area to Volume Ratio
3.1.1 Size & Surface Area
3.1.2 A-A* (AO3/4) - Cell Size
3.2 Gas Exchange
3.2.1 Single-Celled Organisms
3.2.2 Multicellular Organisms
3.2.3 Control of Water Loss
3.2.4 Human Gas Exchange
3.2.5 Ventilation
3.2.6 Dissection
3.2.7 Measuring Gas Exchange
3.2.8 Lung Disease
3.2.9 Lung Disease Data
3.2.10 End of Topic Test - Gas Exchange
3.2.11 A-A* (AO3/4) - Gas Exchange
3.3 Digestion & Absorption
3.3.1 Overview of Digestion
3.3.2 Digestion in Mammals
3.3.3 Absorption
3.3.4 End of Topic Test - Substance Exchange & Digestion
3.3.5 A-A* (AO3/4) - Substance Ex & Digestion
3.4 Mass Transport
3.4.1 Haemoglobin
3.4.2 Oxygen Transport
3.4.3 The Circulatory System
3.4.4 The Heart
3.4.5 Blood Vessels
3.4.6 Cardiovascular Disease
3.4.7 Heart Dissection
3.4.8 Xylem
3.4.9 Phloem
3.4.10 Investigating Plant Transport
3.4.11 End of Topic Test - Mass Transport
3.4.12 A-A* (AO3/4) - Mass Transport
4 Genetic Information & Variation
4.1 DNA, Genes & Chromosomes
4.1.2 Genes
4.1.3 Non-Coding Genes
4.1.4 The Genetic Code
4.1.5 A-A* (AO3/4) - DNA
4.2 DNA & Protein Synthesis
4.2.1 Protein Synthesis
4.2.2 Transcription & Translation
4.2.3 End of Topic Test - DNA, Genes & Protein Synthesis
4.2.4 Exam-Style Question - Protein Synthesis
4.2.5 A-A* (AO3/4) - Coronavirus Translation
4.2.6 A-A* (AO3/4) - Transcription
4.2.7 A-A* (AO3/4) - Translation
4.3 Mutations & Meiosis
4.3.1 Mutations
4.3.2 Meiosis
4.3.3 A-A* (AO3/4) - Meiosis
4.3.4 Meiosis vs Mitosis
4.3.5 End of Topic Test - Mutations, Meiosis
4.3.6 A-A* (AO3/4) - DNA,Genes, CellDiv & ProtSynth
4.4 Genetic Diversity & Adaptation
4.4.1 Genetic Diversity
4.4.2 Natural Selection
4.4.3 A-A* (AO3/4) - Natural Selection
4.4.4 Adaptations
4.4.5 Investigating Natural Selection
4.4.6 End of Topic Test - Genetic Diversity & Adaptation
4.4.7 A-A* (AO3/4) - Genetic Diversity & Adaptation
4.5 Species & Taxonomy
4.5.1 Courtship Behaviour
4.5.2 Phylogeny
4.5.3 Classification
4.5.4 DNA Technology
4.5.5 A-A* (AO3/4) - Species & Taxonomy
4.6 Biodiversity Within a Community
4.6.1 Biodiversity
4.6.2 Index of diversity
4.6.3 Agriculture
4.6.4 End of Topic Test - Species,Taxonomy& Biodiversity
4.6.5 A-A* (AO3/4) - Species,Taxon&Biodiversity
4.7 Investigating Diversity
4.7.1 Genetic Diversity
4.7.2 Quantitative Investigation
5 Energy Transfers (A2 only)
5.1 Photosynthesis
5.1.1 Overview of Photosynthesis
5.1.2 Photoionisation of Chlorophyll
5.1.3 Production of ATP & Reduced NADP
5.1.4 Cyclic Photophosphorylation
5.1.5 Light-Independent Reaction
5.1.6 A-A* (AO3/4) - Photosynthesis Reactions
5.1.7 Limiting Factors
5.1.8 Photosynthesis Experiments
5.1.9 End of Topic Test - Photosynthesis
5.1.10 A-A* (AO3/4) - Photosynthesis
5.2 Respiration
5.2.1 Overview of Respiration
5.2.2 Anaerobic Respiration
5.2.3 A-A* (AO3/4) - Anaerobic Respiration
5.2.4 The Link Reaction
5.2.5 The Krebs Cycle
5.2.6 Oxidative Phosphorylation
5.2.7 Respiration Experiments
5.2.8 End of Topic Test - Respiration
5.2.9 A-A* (AO3/4) - Respiration
5.3 Energy & Ecosystems
5.3.1 Biomass
5.3.2 Production & Productivity
5.3.3 Agricultural Practices
5.4 Nutrient Cycles
5.4.1 Nitrogen Cycle
5.4.2 Phosphorous Cycle
5.4.3 Fertilisers & Eutrophication
5.4.4 End of Topic Test - Nutrient Cycles
5.4.5 A-A* (AO3/4) - Energy,Ecosystems&NutrientCycles
6 Responding to Change (A2 only)
6.1 Nervous Communication
6.1.1 Survival
6.1.2 Plant Responses
6.1.3 Animal Responses
6.1.4 Reflexes
6.1.5 End of Topic Test - Reflexes, Responses & Survival
6.1.6 Receptors
6.1.7 The Human Retina
6.1.8 Control of Heart Rate
6.1.9 End of Topic Test - Receptors, Retina & Heart Rate
6.2 Nervous Coordination
6.2.1 Neurones
6.2.2 Action Potentials
6.2.3 Speed of Transmission
6.2.4 End of Topic Test - Neurones & Action Potentials
6.2.5 Synapses
6.2.6 Types of Synapse
6.2.7 Medical Application
6.2.8 End of Topic Test - Synapses
6.2.9 A-A* (AO3/4) - Nervous Comm&Coord
6.3 Muscle Contraction
6.3.1 Skeletal Muscle
6.3.2 Sliding Filament Theory
6.3.3 Contraction
6.3.4 Slow & Fast Twitch Fibres
6.3.5 End of Topic Test - Muscles
6.3.6 A-A* (AO3/4) - Muscle Contraction
6.4 Homeostasis
6.4.1 Overview of Homeostasis
6.4.2 Blood Glucose Concentration
6.4.3 Controlling Blood Glucose Concentration
6.4.4 End of Topic Test - Blood Glucose
6.4.5 Primary & Secondary Messengers
6.4.6 Diabetes Mellitus
6.4.7 Measuring Glucose Concentration
6.4.8 Osmoregulation
6.4.9 Controlling Blood Water Potential
6.4.11 End of Topic Test - Diabetes & Osmoregulation
6.4.12 A-A* (AO3/4) - Homeostasis
7 Genetics & Ecosystems (A2 only)
7.1 Genetics
7.1.1 Key Terms in Genetics
7.1.2 Inheritance
7.1.3 Linkage
7.1.4 Multiple Alleles & Epistasis
7.1.5 Chi-Squared Test
7.1.6 End of Topic Test - Genetics
7.1.7 A-A* (AO3/4) - Genetics
7.2 Populations
7.2.1 Populations
7.2.2 Hardy-Weinberg Principle
7.3 Evolution
7.3.1 Variation
7.3.2 Natural Selection & Evolution
7.3.3 End of Topic Test - Populations & Evolution
7.3.4 Types of Selection
7.3.5 Types of Selection Summary
7.3.6 Overview of Speciation
7.3.7 Causes of Speciation
7.3.8 Diversity
7.3.9 End of Topic Test - Selection & Speciation
7.3.10 A-A* (AO3/4) - Populations & Evolution
7.4 Populations in Ecosystems
7.4.1 Overview of Ecosystems
7.4.2 Niche
7.4.3 Population Size
7.4.4 Investigating Population Size
7.4.5 End of Topic Test - Ecosystems & Population Size
7.4.6 Succession
7.4.7 Conservation
7.4.8 End of Topic Test - Succession & Conservation
7.4.9 A-A* (AO3/4) - Ecosystems
8 The Control of Gene Expression (A2 only)
8.1 Mutation
8.1.1 Mutations
8.1.2 Effects of Mutations
8.1.3 Causes of Mutations
8.2 Gene Expression
8.2.1 Stem Cells
8.2.2 Stem Cells in Disease
8.2.3 End of Topic Test - Mutation & Gene Epression
8.2.4 A-A* (AO3/4) - Mutation & Stem Cells
8.2.5 Regulating Transcription
8.2.6 Epigenetics
8.2.7 Epigenetics & Disease
8.2.8 Regulating Translation
8.2.9 Experimental Data
8.2.10 End of Topic Test - Transcription & Translation
8.2.11 Tumours
8.2.12 Correlations & Causes
8.2.13 Prevention & Treatment
8.2.14 End of Topic Test - Cancer
8.2.15 A-A* (AO3/4) - Gene Expression & Cancer
8.3 Genome Projects
8.3.1 Using Genome Projects
8.4 Gene Technology
8.4.1 Recombinant DNA
8.4.2 Producing Fragments
8.4.3 Amplification
8.4.4 End of Topic Test - Genome Project & Amplification
8.4.5 Using Recombinant DNA
8.4.6 Medical Diagnosis
8.4.7 Genetic Fingerprinting
8.4.8 End of Topic Test - Gene Technologies
8.4.9 A-A* (AO3/4) - Gene Technology
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- Revision notes >
- A-Level Biology Revision Notes >
- CIE A-level Biology Revision Notes
ATP as an Energy Source (A-level Biology)
Atp as an energy source, hydrolysing atp, atp is an immediate energy source.
- The body cannot directly get its energy from glucose. Glucose is not a direct energy source. Instead, the body uses the energy released from breaking down glucose, to drive phosphorylation of ADP. This makes ATP , which is an immediate energy source that cells can use quickly.
- Energy is stored in the bonds joining phosphate groups . The energy in ATP molecules is stored within the phosphoanhydride bonds (high energy between the three phosphate groups. In order to release this energy, the bond must be broken. This happens through hydrolysis, which we will recap here.
- The phosphate bonds are broken by hydrolysis . Hydrolysis of ATP forms ADP (adenosine diphosphate) and an inorganic phosphate group (Pi). This hydrolysis is catalysed by the enzyme ATP hydrolase . ATP hydrolase can further catalyse ADP into adenosine monophosphate (AMP) and a second inorganic phosphate group.
ATP, or adenosine triphosphate, is a molecule that serves as the main source of energy for cellular processes in living organisms. It acts as a currency for energy transactions within cells.
Table of Contents
ATP stores energy in the bonds between its phosphate groups. When the bond between the second and third phosphate groups is broken, energy is released and can be used by cells for various processes.
ATP is used as an energy source for a variety of cellular processes, including muscle contraction, ion transport across membranes, and the synthesis of proteins and lipids. It is also used for energy-intensive processes such as cell division and growth.
ATP is produced in cells through cellular respiration and photosynthesis. Cellular respiration is a process that takes place in the mitochondria of eukaryotic cells and generates ATP through the breakdown of glucose. Photosynthesis, which takes place in the chloroplasts of plants, generates ATP through the capture of light energy.
Cellular respiration is the process that generates ATP in cells. This process takes place in the mitochondria and involves the breakdown of glucose to release energy. The energy is then used to produce ATP.
The breakdown of ATP releases energy by breaking the bond between the second and third phosphate groups. This reaction releases energy that can be used by cells for various processes.
The production of ATP plays a critical role in the energy balance of cells. By producing ATP, cells can maintain their energy levels and carry out their vital processes. If the production of ATP decreases, cells can become energy-deficient and may stop functioning properly.
ATP is considered the universal energy source for cells because it can be produced by all living organisms and is used by all cells for energy transactions. This makes ATP a critical component of cellular metabolism and essential for the survival of living organisms.
The study of ATP is important for future careers in Biology because it provides a fundamental understanding of cellular energy metabolism. This knowledge is essential for careers in areas such as biochemistry, physiology, and medicine, where an understanding of cellular energy metabolism is crucial.
The study of ATP is approached in A-level Biology through a combination of theoretical and practical work. Students learn about the structure and function of ATP, the stages of cellular respiration, and the role of ATP in cellular processes. They also conduct practical experiments to demonstrate cellular respiration and the production of ATP, gaining hands-on experience in cellular energy metabolism.
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CIE 1 Cell structure
Roles of atp (a-level biology), the synthesis and hydrolysis of atp (a-level biology), the structure of atp (a-level biology), magnification and resolution (a-level biology), calculating cell size (a-level biology), studying cells: confocal microscopes (a-level biology), studying cells: electron microscopes (a-level biology), studying cells: light microscopes (a-level biology), life cycle and replication of viruses (a-level biology), cie 10 infectious disease, bacteria, antibiotics, and other medicines (a-level biology), pathogens and infectious diseases (a-level biology), cie 11 immunity, types of immunity and vaccinations (a-level biology), structure and function of antibodies (a-level biology), the adaptive immune response (a-level biology), introduction to the immune system (a-level biology), primary defences against pathogens (a-level biology), cie 12 energy and respiration, anaerobic respiration in mammals, plants and fungi (a-level biology), anaerobic respiration (a-level biology), oxidative phosphorylation and chemiosmosis (a-level biology), oxidative phosphorylation and the electron transport chain (a-level biology), the krebs cycle (a-level biology), the link reaction (a-level biology), the stages and products of glycolysis (a-level biology), glycolysis (a-level biology), the structure of mitochondria (a-level biology), the need for cellular respiration (a-level biology), cie 13 photosynthesis, limiting factors of photosynthesis (a-level biology), cyclic and non-cyclic phosphorylation (a-level biology), the 2 stages of photosynthesis (a-level biology), photosystems and photosynthetic pigments (a-level biology), site of photosynthesis, overview of photosynthesis (a-level biology), cie 14 homeostasis, ectotherms and endotherms (a-level biology), thermoregulation (a-level biology), plant responses to changes in the environment (a-level biology), cie 15 control and co-ordination, the nervous system (a-level biology), sources of atp during contraction (a-level biology), the ultrastructure of the sarcomere during contraction (a-level biology), the role of troponin and tropomyosin (a-level biology), the structure of myofibrils (a-level biology), slow and fast twitch muscles (a-level biology), the structure of mammalian muscles (a-level biology), how muscles allow movement (a-level biology), the neuromuscular junction (a-level biology), features of synapses (a-level biology), cie 16 inherited change, calculating genetic diversity (a-level biology), how meiosis produces variation (a-level biology), cell division by meiosis (a-level biology), importance of meiosis (a-level biology), cie 17 selection and evolution, types of selection (a-level biology), mechanism of natural selection (a-level biology), types of variation (a-level biology), cie 18 biodiversity, classification and conservation, biodiversity and gene technology (a-level biology), factors affecting biodiversity (a-level biology), biodiversity calculations (a-level biology), introducing biodiversity (a-level biology), the three domain system (a-level biology), phylogeny and classification (a-level biology), classifying organisms (a-level biology), cie 19 genetic technology, cie 2 biological molecules, properties of water (a-level biology), structure of water (a-level biology), test for lipids and proteins (a-level biology), tests for carbohydrates (a-level biology), protein structures: globular and fibrous proteins (a-level biology), protein structures: tertiary and quaternary structures (a-level biology), protein structures: primary and secondary structures (a-level biology), protein formation (a-level biology), proteins and amino acids: an introduction (a-level biology), phospholipid bilayer (a-level biology), cie 3 enzymes, enzymes: inhibitors (a-level biology), enzymes: rates of reaction (a-level biology), enzymes: intracellular and extracellular forms (a-level biology), enzymes: mechanism of action (a-level biology), enzymes: key concepts (a-level biology), enzymes: introduction (a-level biology), cie 4 cell membranes and transport, transport across membranes: active transport (a-level biology), investigating transport across membranes (a-level biology), transport across membranes: osmosis (a-level biology), transport across membranes: diffusion (a-level biology), signalling across cell membranes (a-level biology), function of cell membrane (a-level biology), factors affecting cell membrane structure (a-level biology), structure of cell membranes (a-level biology), cie 5 the mitotic cell cycle, chromosome mutations (a-level biology), cell division: checkpoints and mutations (a-level biology), cell division: phases of mitosis (a-level biology), cell division: the cell cycle (a-level biology), cell division: chromosomes (a-level biology), cie 6 nucleic acids and protein synthesis, transfer rna (a-level biology), transcription (a-level biology), messenger rna (a-level biology), introducing the genetic code (a-level biology), genes and protein synthesis (a-level biology), synthesising proteins from dna (a-level biology), structure of rna (a-level biology), dna replication (a-level biology), dna structure and the double helix (a-level biology), polynucleotides (a-level biology), cie 7 transport in plants, translocation and evidence of the mass flow hypothesis (a-level biology), the phloem (a-level biology), importance of and evidence for transpiration (a-level biology), introduction to transpiration (a-level biology), the pathway and movement of water into the roots and xylem (a-level biology), the xylem (a-level biology), cie 8 transport in mammals, controlling heart rate (a-level biology), structure of the heart (a-level biology), transport of carbon dioxide (a-level biology), transport of oxygen (a-level biology), exchange in capillaries (a-level biology), structure and function of blood vessels (a-level biology), cie 9 gas exchange and smoking, lung disease (a-level biology), pulmonary ventilation rate (a-level biology), ventilation (a-level biology), structure of the lungs (a-level biology), general features of exchange surfaces (a-level biology), understanding surface area to volume ratio (a-level biology), the need for exchange surfaces (a-level biology), edexcel a 1: lifestyle, health and risk, phospholipids – introduction (a-level biology), edexcel a 2: genes and health, features of the genetic code (a-level biology), gas exchange in plants (a-level biology), gas exchange in insects (a-level biology), edexcel a 3: voice of the genome, edexcel a 4: biodiversity and natural resources, edexcel a 5: on the wild side, reducing biomass loss (a-level biology), sources of biomass loss (a-level biology), transfer of biomass (a-level biology), measuring biomass (a-level biology), net primary production (a-level biology), gross primary production (a-level biology), trophic levels (a-level biology), edexcel a 6: immunity, infection & forensics, microbial techniques (a-level biology), the innate immune response (a-level biology), edexcel a 7: run for your life, edexcel a 8: grey matter, inhibitory synapses (a-level biology), synaptic transmission (a-level biology), the structure of the synapse (a-level biology), factors affecting the speed of transmission (a-level biology), myelination (a-level biology), the refractory period (a-level biology), all or nothing principle (a-level biology), edexcel b 1: biological molecules, inorganic ions (a-level biology), edexcel b 10: ecosystems, nitrogen cycle: nitrification and denitrification (a-level biology), the phosphorus cycle (a-level biology), nitrogen cycle: fixation and ammonification (a-level biology), introduction to nutrient cycles (a-level biology), edexcel b 2: cells, viruses, reproduction, edexcel b 3: classification & biodiversity, edexcel b 4: exchange and transport, edexcel b 5: energy for biological processes, edexcel b 6: microbiology and pathogens, edexcel b 7: modern genetics, edexcel b 8: origins of genetic variation, edexcel b 9: control systems, ocr 2.1.1 cell structure, structure of prokaryotic cells (a-level biology), eukaryotic cells: comparing plant and animal cells (a-level biology), eukaryotic cells: plant cell organelles (a-level biology), eukaryotic cells: the endoplasmic reticulum (a-level biology), eukaryotic cells: the golgi apparatus and lysosomes (a-level biology), ocr 2.1.2 biological molecules, introduction to eukaryotic cells and organelles (a-level biology), ocr 2.1.3 nucleotides and nucleic acids, ocr 2.1.4 enzymes, ocr 2.1.5 biological membranes, ocr 2.1.6 cell division, diversity & organisation, ocr 3.1.1 exchange surfaces, ocr 3.1.2 transport in animals, ocr 3.1.3 transport in plants, examples of xerophytes (a-level biology), introduction to xerophytes (a-level biology), ocr 4.1.1 communicable diseases, structure of viruses (a-level biology), ocr 4.2.1 biodiversity, ocr 4.2.2 classification and evolution, ocr 5.1.1 communication and homeostasis, the resting potential (a-level biology), ocr 5.1.2 excretion, ocr 5.1.3 neuronal communication, hyperpolarisation and transmission of the action potential (a-level biology), depolarisation and repolarisation in the action potential (a-level biology), ocr 5.1.4 hormonal communication, ocr 5.1.5 plant and animal responses, ocr 5.2.1 photosynthesis, ocr 5.2.2 respiration, ocr 6.1.1 cellular control, ocr 6.1.2 patterns of inheritance, ocr 6.1.3 manipulating genomes, ocr 6.2.1 cloning and biotechnology, ocr 6.3.1 ecosystems, ocr 6.3.2 populations and sustainability, related links.
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Notes || Flashcards || Questions by Topic
- Definitions
- Summary Notes
- 1.1 Monomers and polymers + 1.2 Carbohydrates
- 1.3 Lipids + 1.7 Water + 1.8 Inorganic ions
- 1.4 Proteins
- 1.5 Nucleic acids + 1.6 ATP
- 1.1 Monomers and Polymers
- 1.2 Carbohydrates
- 1.5 Nucleic Acids
- 1.7 Water and Inorganic Ions
Questions by Topic
2016-2021 papers.
- 1.1 Monomers and Polymers MS
- 1.1 Monomers and Polymers QP
- 1.2 Carbohydrates MS
- 1.2 Carbohydrates QP
- 1.3 Lipids MS
- 1.3 Lipids QP
- 1.4 Proteins and Enzymes MS
- 1.4 Proteins and Enzymes QP
- 1.5 Nucleic Acids MS
- 1.5 Nucleic Acids QP
- 1.7 Water MS
- 1.7 Water QP
- 1.8 Inorganic Ions MS
- 1.8 Inorganic Ions QP
pre-2016 papers
- 1.5 Nucleic Acids - Structure and Replication MS
- 1.5 Nucleic Acids - Structure and Replication QP
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AS and A-level Biology
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- Introduction
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- 3.1 Biological molecules
- 3.3 Organisms exchange substances with their environment
- 3.4 Genetic information, variation and relationships between organisms
- 3.5 Energy transfers in and between organisms (A-level only)
- 3.6 Organisms respond to changes in their internal and external environments (A-level only)
- 3.7 Genetics, populations, evolution and ecosystems (A-level only)
- 3.8 The control of gene expression (A-level only)
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| A single molecule of adenosine triphosphate (ATP) is a nucleotide derivative and is formed from a molecule of ribose, a molecule of adenine and three phosphate groups.
Hydrolysis of ATP to adenosine diphosphate (ADP) and an inorganic phosphate group (P ) is catalysed by the enzyme ATP hydrolase. ATP is resynthesised by the condensation of ADP and P . This reaction is catalysed by the enzyme ATP synthase during photosynthesis, or during respiration. |
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ATP importance essay- biology paper 3 explain the importance of atp to organisms (25 marks) adenosine triose phosphate (atp) is central to the health and growth ... AQA Biology Essay Titles; What are the uses of DNA in science and technology? ... Shape essay; Essays overview - A level Bio essay; Atp-importance-essay; RP8 - This my required ...
Biology is detailed and comprehensive A-level content, uses appropriate terminology, and is very well written and always clearly explained. No significant errors or irrelevant material. For top marks in the band, the answer shows evidence of reading beyond specification requirements. 16-20. Relational.
The importance of shapes fitting together in cells and organisms. 1) Enzyme properties and digestion. 2) Protein structure. 3) Plasma membrane structure and cell transport. 4) Antigens, antibodies, B cells & T cells. 5) Vaccines. 6) Structure of DNA. 7) DNA Replication (not PCR) 8) Transcription & translation.
Revision Notes. Chemistry. ChemistryLast Exams 2024SL. Topic Questions. Revision Notes. Revision notes on 1.6.1 The Structure of ATP for the AQA A Level Biology syllabus, written by the Biology experts at Save My Exams.
Activated adenyl cyclase converts ATP to cAMP. 5. Active protein kinase converts glycogen to glucose. The Importance of proteins in the control of processes and responses in organisms. • Antibodies are blood proteins produced in response to and counteracting a specific antigen. • Lymphocytes produce antibodies.
Advice for the essay. The levels scheme states that more than two A-level topics need to be addressed to get higher than 10 marks. A minimum of four topics is required to get higher than 15 marks. A topic area is a numbered sub-section in the specification. For example, for the 2017 'diffusion' essay, gas exchange (3.3.2) was a topic area.
One of the major roles of ATP is the use it has in glycolysis. 2 ATP molecules are used during glycolysis to form 2 ADP and two phosphate group (P i). ATP is formed during glycolysis. As well as being used in glycolysis, ATP is also formed during glycolysis. In fact, there is a net production of 2 ATP molecules, which we will cover later.
‒ When it is made, ATP diffuses to the part of the cell that requires the energy ‒ The energy is stored in high energy bonds between the phosphate groups and is released via hydrolysis reactions The structure of ATP shows the basic components of a two-ring adenine, five-carbon ribose, and three phosphate groups. AQA A-Level Biology 3.1.6 ATP
AQA Education (AQA) is a registered charity (number 1073334) and a company limited by guarantee registered in England and Wales (number 3644723). Our registered address is AQA, Devas Street, Manchester M15 6EX. Biology essay titles This document contains the essay titles and mark schemes used in AQA A-level Biology examinations since 2007.
ATP is a small, relatively simple molecule. This molecule can be thought of as the primary energy currency of cells. ATP is the cell's equivalent of money, which people exchange for things they need. ATP is used to power most energy-requiring cellular reactions. Affordable 1:1 tutoring from the comfort of your home.
All Questions Full Mark Scheme. Question 1. Mark Scheme. Next. Past paper questions for the ATP topic of A-Level AQA Biology.
The importance of ions in biology. Click the card to flip 👆. 1.) Na+ ions in cotransport of glucose. - importance: Na+ ion concentration gradient is what drives the movement of glucose into cell - utilising energy efficiently. 2.) Na+ ions in osmoregulation. - Loop of Henle - maintains Na+ ion gradient. - importance: ensures water can leave ...
Topic 6: Responding to Changes in Environment. Topic 7: Genetics, Populations, Evolution and Ecosystems. Topic 8: Control of Gene Expression. Practical Skills. Practical Skills. Revision for AQA Biology AS and A Level Papers, including summary notes, worksheets and past exam questions for each topic.
ATP is an Immediate Energy Source. The body cannot directly get its energy from glucose. Glucose is not a direct energy source. Instead, the body uses the energy released from breaking down glucose, to drive phosphorylation of ADP. This makes ATP, which is an immediate energy source that cells can use quickly.
1.5 Nucleic Acids - Structure and Replication MS. 1.5 Nucleic Acids - Structure and Replication QP. 1.6 ATP MS. 1.6 ATP QP. 1.7 Water MS. 1.7 Water QP. 1.8 Inorganic Ions MS. 1.8 Inorganic Ions QP. Summary notes, flashcards and past exam questions by topic for AQA Biology AS and A-Level Topic 1 - Biological Molecules.
3.1.6 ATP. A single molecule of adenosine triphosphate (ATP) is a nucleotide derivative and is formed from a molecule of ribose, a molecule of adenine and three phosphate groups. Hydrolysis of ATP to adenosine diphosphate (ADP) and an inorganic phosphate group (P i) is catalysed by the enzyme ATP hydrolase.
Terms in this set (5) The uses and the importance of ATP in an organism. - DNA replication. - Photosynthesis. - Active transport. - Respiration. DNA replication. - ATP is required for the enzymes involved in DNA replication to function. - DNA helicase requires ATP in order to synthesise the breaking of the hydrogen binds between DNA strands so ...
synthesis of ATP associated with electron transfer chain. ATP production in anaerobic respiration. ... AQA A level biology essay titles and mark schemes. Module: Biology. 555 Documents. Students shared 555 documents in this course. University: Exeter College, Exeter. Info More info. Download.
Marked grade A biology A level essay-the importance of ATP in living organisms. Written to meet the mark scheme criteria, 5 paragraphs and 829 words. Written this year. ... AQA A Level Sociology Book One Including AS Level R. Webb, H. Westergaard. AQA Psychology for A Level Year 1 & AS - Student Book R. Liddle, C. Flanagan.
ATP provides the energy needed to build up macromolecules from their basic units - eg. making starch from glucose. - Movement. ATP provides the energy for muscle contraction so that the filaments of muscle can slide past one another and therefore shorten the overall length of a muscle fibre. - Active transport.
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Biology AQA A-Level ATP Questions. ATP is useful in many biological processes. Explain why? Click the card to flip it 👆. Release energy in small amounts so enzymes are not denatured. Click the card to flip it 👆. 1 / 15.
AQA A level Biology Essay. The importance of responses to changes in the internal and external environment of an organism. Click the card to flip it 👆. Control of heart rate (changes in pH and pressure) Control of blood glucose (glucagon and insulin) Osmoregulation (water potential changes) Action potentials/ pacinian corpuscles (stimulus)
AS Biology Past Papers for AQA, CIE, Edexcel A (SNAB), OCR, WJEC. Clear and structured resources to guide you through key topics.