Protein Synthesis and Cell Division PDF - W17N

Summary

This document provides an overview of protein synthesis and cell division, covering concepts such as gene expression, transcription, translation, somatic cell division, reproductive cell division, and the cell cycle. It details the stages and significance of each process, including the events and signals involved.

Full Transcript

Protein Synthesis and Cell Division

Learning Objectives

Understand and explain in detail the sequences of events in protein synthesis with knowledge of gene
expression, transcription and translation
Understand and explain the different stages, events and significance of somatic and reproductive cell
division
Understand, explain and describe in detail the signal that induce somatic cell division
Introduction to Protein Synthesis

Cell synthesize many chemicals to maintain homeostasis
Cellular machinery is devoted to synthesizing large numbers of diverse proteins
Proteins determine the physical and chemical characteristics of cells
Proteins
- Help assemble cellular structures such as the plasma membrane, the cytoskeleton, and other
organelles
- Others serve as hormones, antibodies, and contractile elements in muscular tissue
- Still others act as enzymes, regulating the rates of the numerous chemical reactions that occur in
cells, or transporters, carrying various materials in the blood
DNA is used as a template for synthesis of a specific protein
Transcription
- Information encoded in a specific region of DNA is transcribed (copied) to produce a specific
molecule of RNA (ribonucleic acid)
Translation
- The RNA attaches to a ribosome, where the information contained in RNA is translated into a
corresponding sequence of amino acids to form a new protein molecule

Transcription – Protein Synthesis

During the transcription, three types of RNA are made from the DNA template:
1) Messenger RNA (mRNA) directs the synthesis of a protein
2) Ribosomal RNA (rRNA) joins with ribosomal proteins to make ribosomes
3) Transfer RNA (tRNA) binds to an amino acid and holds it in place on a ribosome until it is
incorporated into a protein during translation
Transcription – Protein Synthesis

Enzyme RNA polymerase catalyses transcription of DNA
Only one of two DNA strands serves as a template for RNA synthesis
Segment of DNA where transcription begins, a special nucleotide sequence called a promoter
Transcription, bases pair in a complementary manner
Transcription of the DNA strand ends at another special end sequence called the terminator

Translation – Protein Synthesis

The nucleotide sequence in an mRNA molecule specifies the amino acid sequence of a protein
Ribosomes in the cytoplasm carry out translation
Small sub-unit of a ribosome has a binding site for mRNA
Large sub-unit has two binding sites for tRNA molecules, a P site and an A site the next
Introduction to Cell Division

Human body undergo cell division
Two types of cell division somatic cell division and reproductive cell
Somatic cell: any cell of the body other than a germ cell (reproductive cell)
- In somatic cell division, a cell undergoes a nuclear division called mitosis and a cytoplasmic
division called cytokinesis
- Somatic cell division replaces dead or injured cells and adds new ones during tissue growth
Reproductive cell division is the mechanism that produces gametes
Cells needed to form the next generation of sexually reproducing organisms
Process consists of a special two-step division called meiosis, in which the number of chromosomes in
the nucleus is reduced by half
Somatic Cell Division – Cell Division

Cell cycle is an orderly sequence of events in which a somatic cell duplicates its contents and divides in
two
Human cells, such as those in the brain, stomach, and kidneys, contain 23 pairs of chromosomes, for a
total of 46
One member of each pair is inherited from each parent
The two chromosomes that make up each pair are called homologous chromosomes they contain
similar genes arranged in the same (or almost the same) order
Exception to this rule is one pair of chromosomes called the sex chromosomes (designated X and Y)
In females the homologous pair of sex chromosomes consists of two large X chromosomes
In males the pair consists of an X and a much smaller Y chromosome
Somatic cells contain two sets of chromosomes, they are called diploid cells, symbolized 2n
Cell cycle consists of two major periods: interphase, when a cell is not dividing, and the mitotic (M)
phase, when a cell is dividing
The Cell Cycle

Interphase – Cell Division

The G1 phase is the interval between the mitotic phase and the S
phase
The cell is metabolically active; it replicates most of its organelles
and cytosolic components but not its DNA
Replication of centrosomes also begins in the G1 phase
For a cell with a total cell cycle time of 24 hours, G1 lasts 8-10
hours
Cells that remain in G1 for a very long time, perhaps destined
never to divide again, are said to be in the G0 phase
The S phase, the interval between G1 and G2, lasts about 8 hours
During S phase, DNA replication occurs, resulting into two
identical cells formed during cell division later in the cell cycle will
have the same genetic material
 The G2 phase if the interval between the S phase and the mitotic phase, lasts 4 to 6 hours
During G2, cell growth continues, enzymes and other proteins are synthesized in preparation for
division, and replication of centrosomes is completed
When DNA replicates during the S phase, its helical structure partially uncoils, and the two strands
separate at the points where hydrogen bonds connect base pairs
Original DNA molecule become two identical DNA molecules

·
cytokinesis
cytoplasmic division
i contractile
ring
forms clearage
furrow around
centre of cell ,
chromatin fibres
dividing cytoplasm condense into
into
separated paired chromated
equal portion
i nucleolus/nuclear
envelope disappear
i each centrosome
moves on
opposite
pole of the cell

nuclear I
and
envelopes centromeres of
nucleos
reappear chromatic pors
i chromosomes line up at
resume metaphase
chromatin form plate
i mitotic
spindle disappears

↑ centromeres split
3 Checkpoint Control System – G1, G2, M (Mitotic) Checkpoint ; identical sets of
chromosomes more to
opposite poles of cell
Cell cycle controlled by STOP & GO chemical signals at critical points
Signals indicate if key cellular processes have been completed correctly
Checkpoints Control System – Go-ahead signal

Signals that promote cell growth & division
- Proteins
- Internal signals
- “Promoting factors”
External signals
- “Growth factors”
Primary mechanism of control
- Phosphorylation
- Kinase enzymes

Cyclin & Cyclin Dependent Kinases CDK

CDKs & cyclin drive cell from one phase to next in cell cycle
Proper regulation of cell cycle is so key to life that the genes for these regulatory proteins have been
highly conserved through evolution
The genes are basically the same in yeast, insects, plants & animals (including humans)
Reproductive Cell Division

Sexual reproduction, each new organism is the result of the union of two different gametes (fertilization),
one produced by each parent
Meiosis, the reproductive cell division that occurs in the gonads (ovaries and testes), produces gametes
in which the number of chromosomes is reduced by half
Gametes contain a single set of 23 chromosomes and thus are haploid (n) cells
Fertilization restores the diploid number of chromosomes
- diplad
cells (2n)
Meiosis occurs in two successive stages: meiosis I and meiosis II
Comparison between Mitosis and Meiosis

cell division
= sometic =>
reproductive
cell
division

REMEMBER this for MCQ !

Mitosis Meiosis

Number of divisions 1 2

Number of daughter cells 2 4

Genetically identical? YES NO

Chromosome Number Same as parent Half of parent

Where Somatic cells Germ cells

When Throughout life At sexual maturity

Role Growth and repair Sexual reproduction
 SUMMARY

Event Mitosis Meiosis

Occurs during interphase before nuclear Occurs once, during the interphase before
DNA replication
division begins meiosis I begins

Number of One, including prophase, metaphase, Two, each including prophase, metaphase,
divisions anaphase, telophase anaphase, telophase

Synapsis is unique to meiosis; During
prophase I, the homologous chromosomes
Synapsis of
join along their length, forming tetrads
homologous Does not occur
(groups of four chromatids); synapsis is
chromosomes
associated with crossing over between
nonsister chromatids

Number of Four, each haploid (n), containing half as
daughter cells Two, each diploid (2n) and genetically many chromosomes as the parent cell;
and genetic identical to the parent cell genetically nonidentical to the parent cell
composition and to each other

Enables multicellular adult to arise from Produces gametes; reduces chromosome
Role in the
zygote; produce cells for growth and tissue number by half and introduces genetic
animal body
repair variability among the gametes