2. Biochemistry for Environmental Health Lecture 1 Ahmad Razali Ishak Department of Environmental Health Faculty of Health Sciences UiTM Puncak Alam 1

3. Biochemistry Biochemistry has become the foundation for understanding all biological processes. It has provided explanations for the causes of many diseases in humans, animals and plants 2

4. What is Biochemistry ? Biochemistry is the application of chemistry to the study of biological processes at the cellular and molecular level. It emerged as a distinct discipline around the beginning of the 20th century when scientists combined chemistry, physiology and biology to investigate the chemistry of living systems by: A.Studying the structure and behavior of the complex molecules found in biological material and B.the ways these molecules interact to form cells, tissues and whole organism 3

5. Practical application of Biochemistry 1.In medicine and health care Enzymes as a marker for disease e.g. Lactate dehydrogenase (hearth attack can be diagnosed by an increase of IDH from hearth muscle Acetyl cholinesterase (Ace) important in controlling certain nerve impulse. Many pesticides interfere with this enzyme 2. Designer drugs- new and improved antibiotics and chemotherapy agents. 3. In agriculture- herbicides, pesticides, genetics engineering 4. Chemical industries-synthesis and detoxification 4

6. Principles of Biochemistry Cells (basic structural units of living organisms) are highly organized and constant source of energy is required to maintain the ordered state. Living processes contain thousands of chemical pathways. Precise regulation and integration of these pathways are required to maintain life Certain important pathways e.g. Glycolysis is found in almost all organisms. All organisms use the same type of molecules: carbohydrates, proteins, lipids & nucleic acids. Instructions for growth, reproduction and developments for each organism is encoded in their DNA 5

7. Biochemical Evolution ? CH 4, H 2 O, NH 3, HCN How did organic complex molecules evolved from more simple molecules? 6

8. Types of element in organism 90 element in earth, only 27 component essential in organism. In earth, 4 most abundant element are oxygen, silicone, aluminum and Ferum. In organism, 4 most abundant element are hydrogen, oxygen, carbon and nitrogen.-most endurance element with different types of process in organism. 7

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10. Cont.. H, C, O, N can form covalent bond by sharing pair of electrons This 4 types of elements form a large number of different types of compound 3 from this element (O,N,C) can share either 1 or 2 pair of electron which produce single ore double bond. This make this element can form different types of chemical bonds. This element also very light and can form very strong covalent bond. 9

11. Cont.. Carbon can share 4 electron pairs thus can form 4 covalent bond with 4 other carbon element -forming the straight chain/cyclic for different types of organic molecules. C also produce different types of functional group since it can form covalent bond with N, O and sulfur. 10

12. Cont.. C also permit the 3 dimensional structure for biomolecule since it can form tetrahedron configuration with other carbon No other element like C which can form different in size, configuration different types of bond with functional group. Unique characteristics of C enable a hierarchy of molecule organization in cell 11

13. Revision-basic chemistry Covalent bond- sharing of pairs of electrons between atomselectrons atoms Hydrogen bond- interaction of a hydrogen atom with an electronegative atom, such as nitrogen, oxygen or fluorine, that comes from another molecule or chemical grouphydrogenelectronegativenitrogenoxygen fluorine chemical group Van der Waal force- Van der Waals forces include attractions between atoms, molecules, and surfaces, as well as other intermolecular forces Disulphide bond- a covalent bond, usually derived by the coupling of two thiol groups. The linkage is also called an SS-bond or disulfide bridgecovalent bondthiolgroups 12

14. Cont.. Covalent bond Hydrogen bond Van der waals force Disulphide bond 13

15. Table 1-1, p. 4

16. Molecular Organisation of a cell 15

17. Cells Basic building blocks of life Smallest living unit of an organism Grow, reproduce, use energy, adapt, respond to their environment Many cannot be seen with the naked eye A cell may be an entire organism or it may be one of billions of cells that make up the organism Basis Types of Cells 16

18. Fig. 1-11, p. 17

19. Table 1-3, p. 15

20. Characteristic Bio-membranes and Organelles Mitochondrion Surrounded by a double membrane with a series of folds called cristae. Functions in energy production through metabolism. Contains its own DNA, and is believed to have originated as a captured bacterium. Plasma Membrane A lipid/protein/carbohydrate complex, providing a barrier and containing transport and signaling systems. Nucleus Double membrane surrounding the chromosomes and the nucleolus. Pores allow specific communication with the cytoplasm. The nucleolus is a site for synthesis of RNA making up the ribosome Chloroplasts (plastids) Surrounded by a double membrane, containing stacked thylakoid membranes. Responsible for photosynthesis, the trapping of light energy for the synthesis of sugars. Contains DNA, and like mitochondria is believed to have originated as a captured bacterium. 19

21. . Rough endoplasmic reticulum (RER) A network of interconnected membranes forming channels within the cell. Covered with ribosomes (causing the "rough" appearance) which are in the process of synthesizing proteins for secretion or localization in membranes. Ribosomes Protein and RNA complex responsible for protein synthesis Smooth endoplasmic reticulum (SER) A network of interconnected membranes forming channels within the cell. A site for synthesis and metabolism of lipids. Also contains enzymes for detoxifying chemicals including drugs and pesticides. Golgi apparatus A series of stacked membranes. Vesicles (small membrane surrounded bags) carry materials from the RER to the Golgi apparatus. Vesicles move between the stacks while the proteins are "processed" to a mature form. Vesicles then carry newly formed membrane and secreted proteins to their final destinations including secretion or membrane localization. Lysosymes A membrane bound organelle that is responsible for degrading proteins and membranes in the cell, and also helps degrade materials ingested by the cell. 20

22. Vacuoles Membrane surrounded "bags" that contain water and storage materials in plants. Peroxisomes or Microbodies Produce and degrade hydrogen peroxide, a toxic compound that can be produced during metabolism. Cell wall Plants have a rigid cell wall in addition to their cell membranes Cytoplasm enclosed by the plasma membrane, liquid portion called cytosol and it houses the membranous organelles. Cytoskeleton Arrays of protein filaments in the cytosol. Gives the cell its shape and provides basis for movement. E.g. microtubules and microfilaments. http://www.biology.arizona.eduhttp://www.biology.arizona.edu copyright © 1997 - 2004.. 21

23. 22 Biochemistry Biolog. Nanostructures

24. Fig. 1-1, p. 2

25. Bio-molecules Just like cells are building blocks of tissues likewise molecules are building blocks of cells. Animal and plant cells contain approximately 10, 000 kinds of molecules (bio-molecules) Water constitutes 50-95% of cells content by weight. Ions like Na+, K+ and Ca+ may account for another 1% Almost all other kinds of bio-molecules are organic (C, H, N, O, P, S) Infinite variety of molecules contain C. Most bio-molecules considered to be derived from hydrocarbons. The chemical properties of organic bio-molecules are determined by their functional groups. Most bio-molecules have more than one. 24

26. 25 Biomolecules – Structure Building block Simple sugar Amino acid Nucleotide Fatty acid Macromolecule Polysaccharide Protein (peptide) RNA or DNA Lipid Anabolic Catabolic

27. 26 Linking Monomers Cells link monomers by a process called dehydration synthesis (removing a molecule of water) This process joins two sugar monomers to make a double sugar Remove H Remove OH H 2 O Forms

28. 27 Breaking Down Polymers Cells break down macromolecules by a process called hydrolysis (adding a molecule of water) Water added to split a double sugar

29. Sugars Carbohydrates most abundant organic molecule found in nature. Initially synthesized in plants from a complex series of reactions involving photosynthesis. Basic unit is monosaccharides. Monosaccharides can form larger molecules e.g. glycogen, plant starch or cellulose. Functions Store energy in the form of starch (photosynthesis in plants) or glycogen (in animals and humans). Provide energy through metabolism pathways and cycles. Supply carbon for synthesis of other compounds. Form structural components in cells and tissues. Intercellular communications 28

30. 29 Monosaccharides -Polysaccharides Glycosidic bonds connecting glucose residues are in red Glucose - Cellulose

31. Fatty acids - Lipids Are monocarboxylic acid contains even number C atoms Two types: saturated (C-C sb) and unsaturated (C-C db) Fatty acids are components of several lipid molecules. E,g. of lipids are triacylglycerol, steriods (cholestrol, sex hormones), fat soluble vitamins. Functions Storage of energy in the form of fat Membrane structures Insulation (thermal blanket) Synthesis of hormones 30

32. 31 Triglyceride Glycerol Fatty Acid Chains

33. 32 Structure of a biological membrane A lipid bilayer with associated proteins

34. 33 Steroids The carbon skeleton of steroids is bent to form 4 fused rings Cholesterol is the “base steroid” from which your body produces other steroids Estrogen & testosterone are also steroids Cholesterol Testosterone Estrogen Synthetic Anabolic Steroids are variants of testosterone

35. 34 Nucleic Acids Store hereditary information Contain information for making all the body’s proteins Two types exist --- DNA & RNA

36. Amino acids - Proteins: Amino acids: Building blocks of proteins. R Group (side chains) determines the chemical properties of each amino acids. Also determines how the protein folds and its biological function. Functions as transport proteins, structural proteins, enzymes, antibodies, cell receptors. 35

37. 36 Proteins as Enzymes Many proteins act as biological catalysts or enzymes Thousands of different enzymes exist in the body Enzymes control the rate of chemical reactions by weakening bonds, thus lowering the amount of activation energy needed for the reaction -> Catalysator -> No not interfere with the equilibrium of reaction -> Enzymes are reusable !!!!

38. 37 Macromolecules

39. 38 Macromolecules

40. Thank You 39