BIOKIMIAIr. Eko Widodo, M.Agr.Sc.PhDnonrum1@wordpress.comEmail : ekowidodo_nmt@yahoo.co.id

Buku Acuan• Trudy McKee and James McKee. 2003.

Biochemistry: The Molecular Basis of Life. Third edition. McGraw-Hill, Boston.

• Lehninger, Nelson, & Cox. 1997. Principles of Biochemistry.2nd edition. Worth Publishers.

• Albert L. Lehninger. 1995. Dasar-dasar Biokimia. (Alih bahasa: Maggy Thenawidjaja). Penerbit Erlangga, Jakarta.

• David S. Page. 1995. Prinsip-prinsip Biokimia. Penerbit Unair, Surabaya.

• Soeharsono. 1982. Biokimia I dan II. Gadjah Mada University Press, Yogyakarta.

Tata Tertib Kuliah

• Tepat waktu, toleransi maks. 15 menit• Tidak Berisik• HP tidak diaktifkan• Hadir minimal 70% • Paham bahasa Indonesia & Inggris • Baca salah satu / dua buku acuan• Kerjakan Tugas, Mid, & Ujian

Tujuan Perkuliahan

• Mengenalkan dan memahamkan bahasa biokimia : Kosakata (istilah dan struktur kimia), tatabahasa (reaksi-reaksi kimia), struktur kalimat (Jalur metabolisme) dan arti (keterkaitan metabolik)

What is biochemistry?

• Definition:– Webster’s dictionary: Bios = Greek,

meaning “life” “The chemistry of living organisms; the chemistry of the processes incidental to, and characteristic of, life.”

– WebNet dictionary: “Biochemistry is the organic chemistry of compounds and processes occuring in organisms; the effort to understand biology within the context of chemistry.“

What is biochemistry?

• Understanding biological forms and functions in chemical terms

• Biochemistry aims to understand how the lifeless molecules interact to make the complexity and efficiency of the life phenomena and to explain the diverse forms of life in unifying chemical terms.

Issues addressed by biochemistry

• What are the chemical and three-deminsional structure of biomolecules?

• How do biomolecules interact with each other?

• How does the cell synthesize and degrade biomolecules?

• How is energy conserved and used by the cell?

• What are the mechanisms for organizing biomolecules and coordinating their activities?

• How is genetic information stored, transmitted, and expressed?

History of Biochemistry

• First to reveal the chemical composition of living organisms.

The six principle elements for lifeare: C, H, N, O, P, and S.

The biologically most abundant elements are only minor constituents of the earth’s crust (which contains 47% O, 28% Si, 7.9% Al, 4.5% Fe, and 3.5% Ca).

99% of a cell is made of H, O, N, and C

Element # unpaired e’s Fractional amount

H 1 2/3

O 2 1/4

N 3 1/70

C 4 1/10

Most of the elements in living matter have relatively low atomic numbers; H, O, N and C are the lightest elements capable of forming one, two, three and four bonds, respectively.

The lightest elements form the strongest bonds in general.

History of Biochemistry

• Then to identify the types of molecules found in living organisms.• Amino Acids

• Nucleotides

• Carbohydrates

• Lipids

History of Biochemistry

• Then to understand how the biomolecules make life to be life.

Relationship between Biochemistry and other subjects

• Organic chemistry, which describes the properties of biomolecules.

• Biophysics, which applies the techniques of physics to study the structures of biomolecules.

• Medical research, which increasingly seeks to understand disease states in molecular terms.

• Nutrition, which has illuminated metabolism by describing the dietary requirements for maintenance of health.

Relationship between Biochemistry and other subjects

• Microbiology, which has shown that single-celled organisms and viruses are ideally suited for the elucidation of many metabolic pathways and regulatory mechanisms.

• Physiology, which investigates life processes at the tissue and organism levels.

• Cell biology, which describes the biochemical division of labor within a cell.

• Genetics, which describes mechanisms that give a particular cell or organism its biochemical identity.

(1) ENERGY, which it must know how to:

• Extract• Transform• Utilize

Life needs 3 things:

Life needs 3 things:

(2) SIMPLE MOLECULES, which it must know how to:

• Convert• Polymerize• Degrade

(3) CHEMICAL MECHANISMS, to:• Harness energy• Drive sequential chemical reactions• Synthesize & degrade macromolecules• Maintain a dynamic steady state• Self-assemble complex structures• Replicate accurately & efficiently• Maintain biochemical “order” vs outside

Trick #1: Life uses chemical coupling to drive otherwise unfavorable reactions

Trick #2: Life uses enzymes to speed up otherwise slow reactions

How does an enzyme do it, thermodynamically?

How does an enzyme do it, mechanistically?

The Versatile Carbon Atom is the Backbone of Life

Chemical IsomersInterconversion requires breaking covalent bonds

Stereoisomers: Chemically identical Biologically different!

Stereoisomers: Chemically identical Biologically different!

Biochemical Transformations Fall into Five Main Groups

• Group transfer reactions• Oxidation-reduction reactions• Rearrangements

(isomerizations)• Cleavage reactions• Condensation reactions

Biomolecules – Structure

• Building block• Simple sugar• Amino acid• Nucleotide• Fatty acid

• Macromolecule• Polysaccharide• Protein (peptide)• RNA or DNA• Lipid

Anabolic

Catabolic

Biosynthesis Requires Simple Molecules to Combine Covalently in Many Ways…

1. Relative electronegativities of the two atoms

• O 3.5

• Cl 3.0

• N 3.0

• C 2.5

• P 2.1

• H 2.1

• Na 0.9

• K 0.8

Bond strength includes dependence on

High electronegativity = High affinity for electrons

2. The number of bonding electrons

Common Bond Strengths

Approx. Avg.

Triple: 820 kJ/mole

Double: 610 kJ/mole

Single: 350 kJ/mole

Common Functional Groups

Important Biological Nucleophiles:

Electron-rich functional groups

In summary…

• Tetrahedral carbon has versatile bonding properties

• Compounds with many atoms may exist in many isomeric forms

• Interconversion requires breaking chemical bonds

• Large molecules are built from small ones by making new chemical bonds