Biology of the Cell - BIO 14 LEC - A.Y. 2024-2025 PDF

Summary

These notes cover the subject of cell biology, in particular cell cycle and cell division. It includes information on different stages of mitosis, meiosis and the processes that control them.

Full Transcript

BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

Cell Cycle and Cell Division
Cell Division
Process where parent cell divides to form two daughter cells
Prokaryotic cell division is simpler then eukaryotic cell division
○ Prokaryote → singular circular chromosome, no nucleus, and few organelles
○ Eukaryote → multiple chromosomes, nucleus, organelles
All parts are duplicated then separated as cell divides

Cell Cycle
Repeating series of events including growth, DNA synthesis, and cell division
Asexual Reproduction
○ In prokaryotes → cell grows, DNA replicates, cell divides

Eukaryotic Cell Cycle
1. Mitotic Phase (M) → mitosis and cytokinesis
○ When nucleus and cytoplasm divide
2. Interphase (G1, S, and G2)
○ Cell grows, performs life processes, prepares to divide

Interphase
Growth Phase 1 (G1)
Cell spends most of time here
Rapid growth and performs routine functions
Biosynthetic and metabolic activities occur at a high rate
Synthesis of amino acids and proteins
○ Including those needed for DNA replication
If cell is not dividing, the cell enters the G0 phase

G0 Phase
Resting phase; cell has left the cycle and stopped dividing
Cells may remain here for a long time → such as neurons
○ Also cells that are completely differentiated
Cellular senescence
○ Cell stops dividing due to issues of sustainability or viability of daughter cells
○ Such as DNA damage or degredation
○ Occurs when normal diploid cells lose ability to divide → after 50 cell divisions
Cells are in quiescent stage → inactive

Synthesis Phase (S)
DNA replication
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

○ Both strands of double helix is used as templates for two new complementary
strands
○ Strands hydrogen bond to template strands and two double helices form
Amount of DNA has doubled, but the cell remains a diplod
Sister chromatids are produced → attached at the centromere
Centrosomes are duplicated during S phase
○ Consists of a pair of rod-like centrioles composed of tubulin and other proteins
○ Sit at right angles to one another
Mitotic spindle → two resulting centrosomes
○ Orchestrates movement of chromosomes during mitosis

Growth Phase 2 (G2)
Shortened growth period where organelles are reproduced or manufactured
Parts necessary for mitosis and cell division
Cell replenishes energy stores
Cytoskeleton is dismantled to give resources for mitotic spindle

Mitotic Phase
Cell division occurs through mitosis and cytokinesis

Mitosis
Multi-phase process where nucleus divides
Nuclear envelope/membrane breaks down and then reforms
Chromosomes are sorted and separated to ensure complete set
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

Prophase
Chromatin condenses into chromosome, becoming visible with its identical partner →
sister chromatid
X-shape is formed
Nucleolus disappears, as well as nuclear envelope
Centrioles → origin point for microtubules, pair of centrioles: centrosome
Centrosomes move apart as microtubules extent
Thus, Mitotic spindle is formed from the centrosomes and microtubules
Kinetochore → protein structure on centromere that attaches mitotic spindle and sister
chromatids → prometaphase

Metaphase
Sister chromatids and microtubules line up in the middle of cell
Metaphase plate → plane through the center of spindle, where sister chromatids are
positioned
Microtubules are ready to pull apart chromatids and bring one to opposite side of cell

Anaphase
Sister chromatids are separated, forming individual chromosomes again
Pulled to opposite ends as the microtubules shorten
Two new daughter cells contain identical genetic material

Telophase
Formation of two new daughter nuclcei
Surround genetic material as it uncoils to chromatin
Nucleoli reappears with new nuclei
Mitotic spindle breaks apart
Cell is beginning to split in half

Cytokinesis
Also occurs in prokaryotes
Cytoplasm divides and two daughter cells form
In Animal Cells
○ Contractile ring forms inside plasma membrane at the metaphase plate →
composed of actin filaments
○ Cleavage furrow is formed
In Plant Cells
○ New cell wall must form because cleavage furrow is not possible → due to rigid
cell walls
○ During interphase, Golgi apparatus accumulates enzymes, structural proteins,
and glucose molecules before being divided
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

○ During telophase, golgi vesicles move on microtubules and collect on metaphase
plate
○ Cell plate is formed → fused vesicles
○ Cell plate enlarges until it merges with cell well
○ Enzymes use accumulated glucose to build new cell wall with cellulose
○ Golgi membranes become plasma membrane on the sides of the cell wall

Control of the Cell Cycle
Controlled by regulatory proteins
○ Signals cell to start or delay the next phase of the cycle
○ Ensure that previous phase is completed
Key checkpoints
○ G1 checkpoint → before S phase, decides if cell is big enough to divide
Aka restriction point
If not, the cell goes to G0
○ DNA synthesis checkpoint → S checkpoint determines if DNA was replicated
properly
○ Mitosis Checkpoint → ensures chromosomes are aligned before cell division
Aka spindle checkpoint
Will not proceed until kinetochores are firmly anchored to spindle fibers of
opposite sides

Cancer and the Cell Cycle
Occurs when cell cycle is not regulated; due to damaged DNA
○ Resulting in mutations in the genes regulating cell cycle
Can occur due to exposure to radiation or toxic chemicals
Cancer cells divide faster
○ May form a mass of abnormal cells → tumor
○ Take up nutrients and space
○ Can damage tissues and organs, leading to death
When in bone marrow, abnormal blood cells are produced

HeLa Cells
From Henrietta Lacks, a cancer patient
Taken without her knowledge to a researcher
Her cells continued to divide, copies are still used worldwide
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

Meiosis
Process producing haploid genes
Cell division in which chromosome number is halved
Only occurs in special cells
Homologous chromosomes separate and haploid cells are formed
Composed of Meiosis I and Meiosis II

Meiosis I
Prophase I
homologous chromosomes pair up
○ In mitosis and meiosis II, they do not form pairs
Crossing-over of chromosomes occurs

Metaphase I
Spindle fibers attach to chromosome pairs and line up on the equator
○ In mitosis and meiosis, sister chromatids line up

Anaphase I
Spindle fibers shorten and pairs separate to opposite poles

Telophase I and Cytokinesis
Spindle breaks down and new nuclear membranes form
Cytoplasm divides and two haploid daughter cells are created
Go on to meiosis II
○ DNA does not replicate between meiosis I and meiosis II
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

Meiosis II
Prophase II
Nuclear envelope breaks dorn and spindle forms in each haploid daughter cell
Centrioles begin to separate

Metaphase II
Spindle fibers line up the sister chromatids of each chromosome along the center

Anaphase II
sister chromatids separate to opposite poles

Telephose II and Cytokinesis
Spindle breaks down and new nuclear membrane forms
Cytoplasm divide and four haploid cells are formed

Cellular Differentiation
Development
Zygote → product of sperm meeting egg, single cell
Axes → head vs tail
During development, zygote grows into body with axes and organs
○ Different cell types are also produced

Basic Processes of Development
Number of cells increase through division
Body axes must form
Tissues, organs, and structures must form
Individual cells acquire cell type identities → differentiation

Sources of Information in Development
1. Intrinsic information (lineage)
○ Inhereted from mother cell via cell division
○ Cell inherits molecules telling it that it belongs to the nerve cell-producing lineage
of the body
2. Extrinsic information (positional)
○ Information received from cell’s surroundings
○ Chemical signals from a neighbor, instructing it to become a photoreceptor

Differentiation, Determination, and Stem Cells
Cells become more restricted in development potential
○ Type of cells made through cell division becomes fewer
Totipotent → gives rise to wide range of cells (ex. zygote)
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

Pluripotent → restricted in development potential
Germ Layers
a. Mesoderm
Lungs, skeletal muscle, endothelial cell, cardiac muscle, red blood cell
b. Endoderm
Lining of digestive tract, columnar epithelial cell, liver cell
c. Ectoderm
Skin, central nervous system, hair, epithelial cells, neuron
Process of Cell Status
a. Specified → has certain fate but able to switch given the right cues
b. Determined → irreversibly committed to a certain fate
c. Differentiate → stable, final identity

Adult Stem Cells
Some cells retain the ability to produce multiple cell types
Multipotent → adult stem cells
Undergo asymmetric cell division
○ Two daughter cells that are different from one another
○ One daughter remains a stem cell through self-renewal
○ The other takes on a different identity

Meristems
Centers of cell division and growth
○ In animals, totipotent stem cells differentiate into any tissue type in the early
stages of development
○ In plants, these are present their whole lives
Apical Meristems
○ Located at the ends of shoots → shoot apical meristem
○ Located at the roots → root apical meristem
○ Produces three types of primary meristems
Protoderm → makes epidermis, surrounding the plant
Ground meristem → ground tissue with functions in photosynthesis,
storage and support
Procambium → vascular tissue, functions in transport
Lateral Meristems or Secondary Meristems
○ Result in secondary growth, a woody increase in girth
○ Vascular cambium
Arises from procambium and pericycle in roots
In stems, arises from procambium cells of vascular bundles → fascicular
cambium
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

And parenchyma cells between vascular bundles → interfascicular
cambium
Gives rise to secondary phloem (part of the bark) and secondary xylem
(wood)
○ Cork Cambium
Arises form pericycle in roots and parenchyma cells of the cortex in stems
Produces periderm, secondary dermal tissue (part of bark)
Intercalary Meristems → elongate stem from the middle, in between nodes
Marginal Meristems → located along leaf edges for leaf development

Central Dogma of Molecular Biology
DNA AND RNA: NUCLEIC ACIDS
DNA and RNA
Nucleic acids that carry out cellular processes, especially the regulation and expression
of genes
Key Terms
○ Nucleotide → monomer comprising DNA or RNA molecules; consists of
nitrogenous heterocyclic base of purine or pyrimidine, a five-carbon pentose
sugar, and a phosphate group
○ Genome → cell’s complete genetic information packaged as a double-stranded
DNA molecule
○ Monomer → relatively small molecule which can be covalently bonded to form a
polymer

Types of Nucleic Acids
DNA
○ Genetic material in living organisms
○ Found in nucleus, chloroplast, and mitochondria of eukaryotes
○ In prokaryotes, DNA is free-floating within cytoplasm
○ In eukaryotes, combines with histone proteins to form chromatin
Substance of chromosomes
RNA
○ Involved in protein synthesis
○ In eukaryotes, DNA uses messenger RNA to communicate with rest of cells
○ Other RNA: rRNA, tRNA, microRNA

Nucleotides
Monomers of DNA and RNA
Made up of the following
a. Nitrogenous base
b. Pentose or five-carbon sugar
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

c. Phosphate group
Carbon numbering in pentose sugar
○ Numbered 1′ to 5′
○ Base attached to 1′ carbon
○ Phosphate attached to 5′ carbon
Polynucleotide Formation
○ 5′ phosphate of incoming nucleotide attaches to 3′ hydroxyl group of growing
chain

Types of Pentose Sugars
1. Deoxyribose (in DNA) → has an H at the 2′ position
2. Ribose (in RNA) → Has an OH at the 2′ position

Nitrogenous Base
Contain carbon and nitrogen
Contain amino group that binds extra hydrogen
○ Decreases hydrogen ion concentration
○ Makes the environment more basic
Adenine, Guanine, Cytosine, Thymine
○ Adenine, guanine → purines; two carbon-nitrogen rings
○ Cytosine, thymine, uracil → pyrimidine; single carbon-nitrogen ring

Phosphate Group
Attached to hydroxyl group of the 5’ carbon of one sugar and hydroxyl group of 3’
carbon → 5’3’ phosphodiester linkage
○ Formation involves removal of two phosphate groups

DNA Double Helix
Twisted staircase with sugar and phosphate backbone surrounding complementary
nitrogen bases
Key Terms
○ Mutation → error in base pairing during DNA replication
○ Sugar-phosphate backbone → outer support of ladder; strong covalent bonds
between monomers of DNA
○ Base pairing → AT and GC

Double Helix Structure
Sugar and phosphate backbone
Nitrogenous bases bound by hydrogen bonds
Antiparallel orientation → strands of helix run in opposite directions
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

DNA Replication
Each strand is copied
Forms a daughter DNA double helix with one parental DNA strand and one new strand

DNA Packaging
Key terms
○ Nucleosomes → subunit of chromatin; composed of two turns of DNA wrapped
around eight histones
○ Histones → chief protein component of chromatin; spool where DNA winds

Eukaryotic and Prokaryotic Cells
Eukaryotic → Well-defined nucleus
○ DNA wrapped around histones to form nucleosomes
○ Nucleosome links to each other using Linker DNA
○ Heterochromatin → tightly packed region
○ Euchromatin → less dense region
Prokaryotic → Chromosome lies in cytoplasm in the nucleoid
○ DNA is twisted by supercoiling → either under-wound or over-wound
○ Proteins involved in supercoiling
○ Proteins and enzymes maintain supercoiled structure: DNA gyrase

Types of RNA
Key Terms
○ Codon → sequence of three adjacent nucleotides; encodes for a specific amino
acid during protein synthesis or translation
○ Transcription → synthesis of RNA under direction of DNA

RNA Structure and Function
Nitrogenous base pairings are different: AU and GC

Types of RNA
1. Messenger RNA
○ Carries code out of nucleus to ribosomes for assembly of proteins
2. Transfer RNA (tRNA)
○ Translates information from mRNA
○ Reads codon sequences and form amino acids
3. Ribosomal RNA
○ Ribosome → holds all players in position and facilitates base pairings
○ Ribosomal RNA function inside ribosome
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

CENTRAL DOGMA: GENES TO TRAITS
DNA Encodes mRNA and mRNA Encodes Protein
Transcription → DNA to mRNA
Translation → mRNA to amino acid

Genetic Code is Universal and Redundant
Codons → three nucleotide segments
64 possible combination
○ 61 codons code for one of the 20 common amino acids
○ 3 codons are stop codons or nonsense codons
○ AUG is also a start codon → initiates translation

Genetic code is universal → proof that life shares a common origin
Genetic code is redundant → more nucleotide triplets than amino acids
○ Reduces negative impact of mutations

MUTATIONS
Point Mutation
Single base changed in DNA sequence
1. Missense Mutation
○ Causes different amino acid to be inserted in the protein
○ Sickle-cell disease
2. Nonsense Mutation
○ Changes a codon into a stop codon
3. Silent Mutation
○ Changing a codon to another codon, but same amino acid is produced

Frameshift Mutation
Insertion or deletion of extra base pairs from a gene
Very big consequences
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

Chromosome Mutations
Large-scale mutation at chromosome level
Deletion, duplication, inversion, translocation
○ Deletion and duplication cause serious problems
○ Inversions and translocation are often not problematic → but may cause
problems during reproduction

Results of Mutations
1. Beneficial
2. Neutral
3. Deleterious

TRANSCRIPTION
Process of making an RNA copy of a gene
Mediated by RNA polymerases
○ Synthesized in a 5’ → 3’ direction
Template strand → template to create complementary copy of DNA
Coding strand → nearly identical to RNA copy
Initiation site → first nucleotide pair in DNA; where first RNA nucleotide is transcribed
○ Also known as the +1 site
○ Nucleotides before initiation site are given negative numbers and designated
upstream
○ Nucleotides after are given positive numbers and designated downstream
Three stages: initiation, elongation, termination

Initiation of Transcription
Promoters
○ Specifies where to begin transcription and which DNA strand to copy
○ Exist upstream of the genes they regulate
○ Sequence determines if gene is transcribed all the time, sometimes, or
infrequently
○ TATA box → in prokaryotes, -10 region where promoter binds
○ Sigma → subunit of RNA polymerase, binds to -35 sequence

Initiation Complex
Transcription factors → in eukaryotes, regulates frequency of transcription
Initiation complex → transcription factors and RNA polymerase bound to promoter
Transcription bubble → region of unwinding of DNA for RNA synthesis

Transcription Elongation
RNA polymerase synthesizes mRNA in 5’ to 3’ direction; 40 nucleotides per second
BIO 14 LEC
Biology of the Cell
A.Y. 2024-2025 | 1st Semester

Transcription Termination
Polymerase dissocate from DNA template and new mRNA
In prokaryotes, two kinds of termination signals
a. Rho-dependent termination
Controlled by rho protein
Tracks behind polymerase on growing mRNA chain
Near end of gene, polymerase encounters run of G nucleotides and stalls
Rho protein collides with polymerase and releases mRNA from
transcription bubble
b. Rho-independent termination
Controlled by sequences on DNA template strand
Polymerase encounters region rich in C-G nucleotides
mRNA folds back on itself and the C-G nucleotides bind together
Hairpin is produced and causes polymerase to break away