Mol bio lecture 2 part 2.pdf

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◦Explain the differences in gene transcription during and immediately after mitosis and
why these newer findings were unexpected

2. Differences in Gene Transcription During and Immediately After Mitosis:

During Mitosis:
○ Chromatin Condensation:
During mitosis, chromatin is highly condensed into chromosomes,
and transcriptional activity is generally suppressed.
The mitotic phase is characterized by a global reduction in gene
transcription due to the tight packaging of DNA, which limits the
accessibility of transcriptional machinery to DNA.
Immediately After Mitosis (Cytokinesis and G1 Phase):
○ Transcriptional Reawakening:
After mitosis, cells undergo a period of transcriptional
reactivation. This is a critical phase where cells resume the
transcription of genes required for cell growth and preparation for
the next cell cycle.
New findings have shown that certain genes are transcriptionally
reactivated immediately after mitosis, contrary to previous
expectations that transcription would be largely silent during this
transition.
○ Unexpected Findings:
Recent research has revealed that specific transcription factors
and chromatin remodeling complexes are actively involved in
reestablishing transcriptional programs shortly after mitosis.
This finding was unexpected because it was previously believed
that cells required a longer period of chromatin relaxation and
reorganization before transcription could resume.
The rapid reactivation of transcription highlights the cell's
ability to quickly adapt and prepare for subsequent cell cycle
phases.

◦Explain the role of transcription factors in cellular differentiation and morphogenesis

- Terminal differentiation contributes to cell behaviors including motility and
proliferation
- Differentiation is caused by and results in different patterns of gene
expression
- Differentiated cells frequently do not have the same proliferative potential as
their naïve or stem cell counterparts
- The patterns of expression of key genes associated with cell division
and proliferation are different
- Differentiated cells may also exhibit reduced or altered responsiveness
to growth signaling
 6. Evaluate the role of gene expression, cellular programming, and regulation
of the cell cycle in maintaining pluripotency vs commitment and
differentiation and assess the consequence for changes in gene activity on
pluripotency or differentiation

◦Define: totipotent, pluripotent, embryonic stem cell, determination, specialization,
differentiation, and morphogenesis
- Done

◦Summarize the broad steps associated with morphogenesis
1. Fertilized ovum
2. Multiple Embryos (zygote up to early blastomeres 8-cell stage)
a. totipotent cells.
3. Single embryo in early stages of forming 3 germ layers
a. Pluripotent cells
i. Embryonic Stem Cells
ii. Refers to a cell's ability to differentiate into almost all cell types,
except for extraembryonic tissues.
4. Organogenesis
a. Committed cells
i. Cells are committed to certain fates, building blocks of vital organs
5. Formation of structures
a. Differentiation
b. Maturation
i. All cells

◦Identify when maternal control shifts to zygotic control

Shift from Maternal Control to Zygotic Control
Maternal Control: During early embryonic development, gene expression is
largely controlled by maternal mRNAs and proteins deposited in the egg. This
stage involves maternal contributions to regulate initial cell divisions and
development.
 Zygotic Control: Shifts to zygotic control typically occur at the mid-blastula
transition (MBT). At this point, the embryo begins to use its own genome for
transcription and regulation, marking the transition from maternal to zygotic
control of development.

◦Identify genes associated with pluripotency

Genes Associated with Pluripotency (transcription factors)
Oct4 (POU5F1): A key transcription factor in maintaining pluripotency.
Sox2: Works alongside Oct4 to regulate pluripotency.
Nanog: A transcription factor crucial for maintaining the undifferentiated state of
ESCs.
Klf4: Another transcription factor involved in maintaining pluripotency.

◦List the differences between pluripotent cells and differentiated cells in terms of cell
cycle stage lengths

Differences Between Pluripotent Cells and Differentiated Cells in Terms of
Cell Cycle Stage Lengths
Pluripotent Cells:
○ Shorter G1 and G2 phases
○ Longer S phase
○ Shorter overall cell cycle
They divide rapidly to support the development of the embryo.
○ Altered phosphorylation of Rb and/or altered timing of the phosphorylation
Differentiated Cells:
○ Longer G1 phase
○ Shorter S phase,
○ More controlled and slower cell cycle
This slower rate of proliferation helps maintain tissue homeostasis
and function.

Compare and contrast programming and reprogramming in terms of cell cycle
regulation/regulators and length of cell cycle stages

Programming vs. Reprogramming
Programming: Refers to the process by which a cell differentiates into a specific cell
type from a pluripotent state.
Regulation: This involves changes in gene expression regulated by transcription
factors that promote differentiation.
Cell Cycle Length: Differentiated cells usually have a longer G1 phase and a
regulated cell cycle compared to pluripotent cells.

Reprogramming: Involves converting a differentiated cell back to a pluripotent state, as
seen in induced pluripotent stem cells (iPSCs).

Cell Cycle Regulation: This process often involves introducing transcription
factors that reverse the differentiated state and restore pluripotency.
Cell Cycle Length: During reprogramming, cells may exhibit an intermediate cell
cycle profile, with changes in the duration of G1 and other phases, reflecting their
transition state.

Terms:

Growth: the increase in physical size & cell number via division
Proliferation: the active rates of division of cells
M Phase: nuclear and cell division
Interphase: Cell growth
Cyclins: Regulatory proteins that control the progression of the cell cycle by activating
cyclin-dependent kinases (CDKs).
Cyclin D: Associated with the G1 phase and is crucial for progressing through the
restriction point.
Cyclin E: Works with CDK2 to transition from G1 to S phase.
Retinoblastoma Protein (Rb): Regulates the restriction point by binding to and
inhibiting E2F transcription factors, which are necessary for DNA synthesis.
E2F Transcription Factors: Activated when Rb is phosphorylated, leading to the
initiation of genes required for DNA replication.
p53 and p21: Tumor suppressors that can induce cell cycle arrest if DNA damage is
detected, ensuring that damaged cells do not progress to S phase.
Totipotent: Refers to a cell's ability to differentiate into all possible cell types, including
both embryonic and extraembryonic tissues. The zygote and the early blastomeres (up
to the 8-cell stage) in mammals are examples of totipotent cells.
Pluripotent: Refers to a cell's ability to differentiate into almost all cell types, except for
extraembryonic tissues. Embryonic stem cells (ESCs) are a classic example of
pluripotent cells, as they can become any cell type in the body but not the placenta.
Embryonic Stem Cell (ESC): A type of pluripotent stem cell derived from the inner cell
mass of a blastocyst. ESCs have the ability to self-renew indefinitely and differentiate
into various cell types.
Determination: The process by which a cell's developmental fate becomes more
specific and committed to a particular lineage or cell type, often irreversibly. This is a
step before differentiation.
Specialization: The process by which a cell acquires distinct structural and functional
characteristics specific to its role or cell type.
Differentiation: The process through which a cell changes from a less specialized state
to a more specialized state, acquiring specific functions and properties.
Terminal differentiation: contributes to cell behaviors including motility and
proliferation
Morphogenesis: The process by which cells and tissues develop their shape and form
during development. It involves a series of coordinated events that result in the spatial
organization of tissues and organs.
Pluripotency: Stem Cells that Maintain state capable of generation of all 3 embryonic
germ layers
Transcription Factors: Can be used to induce a pluripotent state (reprogramming)

Dysregulated activation of separase could lead to premature separation of sister
chromatids, which would disrupt proper chromosome segregation, but it wouldn't
necessarily stop mitosis; it would cause errors in mitosis.

Constitutive binding of APC and CDC20 would lead to continuous activation of the
APC/C, potentially causing premature degradation of cyclins and securin, leading
to issues with proper cell cycle progression, but not necessarily a complete halt in
mitosis.

Dysregulated inactivation of securin would prevent the proper activation of
separase, leading to a failure to separate sister chromatids, which could delay or
prevent mitosis from completing, but it is not as direct a block as the constitutive
activation of MAD2.

Two divisions of the cell cycle:
- Interphase and Metaphase
Chromosomes are only visible in which stage:
- M phase
Differentiated cells frequently do not have the same _______ _________ as their
naïve or stem cell counterparts:
- proliferative potential
Differentiation is caused by and results in:
- different patterns of gene expression
Differentiated cells may also exhibit _______ or ________ responsiveness to
growth signaling:
- reduced or altered
Factors affecting determination, differentiation, maintenance and modulation of
the differentiated state of a cell during embryogenesis include what 4 things:
- positional factors, hormones and paracrine factors, and external influences such
as teratogens.
List the following in order from earliest embryo development -> later embryo
development: Pluripotent, Totipotent, Differentiated:
- Totipotent -> Pluripotent -> Differentiated

During which stage(s) would you observe a change in chromosome content? (LO1)
- After S-phase but also after anaphase, true change in total content requires
either replication or change in chromosome number
- An area where Mitosis and meiosis differ
What would you expect to observe for a cell where securin is irreversibly bound to separase?
(LO2 and LO3)
- Separase breaks down cohesion when it is broke free from securin
- If irreversibly bound:
- Cohesion wouldn't break down
- Chromosomes don't separate
- Stuck in metaphase
- Anaphase needs unattached kinetochores
Linking an error to the stage of mitosis:
What sort of errors would cause a cell to stall in Prophase? (LO3)
- Anything that disrupts microtubule dynamics
- Anything preventing spindle formation, or nuclear envelope
breakdown
At which stage would a cell stall if there was an error in microtubule dynamics?
- Generally, in prophase
- if it specifies astral microtubules
- Cytokinesis and formation of contractile ring will be impaired
- We are stuck in telophase
Linking Cytokinesis to Morphogenesis:
How is polarity in a cell or developing embryo generated? (LO4)
- Asymmetrical cell divisions and cytoskeleton activity
- Cytoskeleton controls where cytokinesis takes place