Biooooxxx PDF - DNA Structure and Function

Summary

This document provides a comprehensive overview of DNA structure and function, including genetic information, DNA replication, and its role in protein synthesis. It covers various aspects like the double helix structure, base pairing, and the organization of DNA in eukaryotes. The text also discusses different levels of DNA packaging, chromatin remodeling, and its dynamic nature. Suitable for undergraduate-level biology study and research.

Full Transcript

SUMMARY 1-
Genetic Information: DNA carries genetic information in the form of a linear
sequence of nucleotides (building blocks). These nucleotides determine the
genetic code.
Double Helix Structure: DNA exists as a double helix, formed by two long
strands of nucleotides that twist around each other. These strands are
complementary and antiparallel, meaning they run in opposite directions.
Base Pairing: The two strands are held together by hydrogen bonds between
specific pairs of nucleotides. Guanine (G) always pairs with cytosine (C), and
adenine (A) pairs with thymine (T).
Antiparallel Nature: The two DNA strands are antiparallel, meaning one
strand runs in the 5’ to 3’ direction, while the other runs in the 3’ to 5’ direction.
This orientation is crucial for DNA replication and function.
DNA Replication: During DNA duplication, one strand of DNA serves as a
template for synthesizing a complementary strand. This ensures that genetic
information is accurately passed on during cell division.
Genome: The complete set of genetic information in an organism’s DNA is
referred to as its genome. This genome contains all the instructions required for
the organism to synthesize every RNA molecule and protein it will need
throughout its life.
Role of DNA in Protein Synthesis: The DNA genome provides the blueprint
for creating RNA molecules, which are then translated into proteins, essential for
cellular functions and development.
Location in Eukaryotes: In eukaryotic cells (cells with a nucleus), the DNA is
enclosed within the nucleus, a membrane-bound compartment. This
compartmentalization protects the DNA and regulates the processes of gene
expression, replication, and repair.
Nuclear Function: The nucleus serves as the control center for managing
genetic information, allowing access to specific genes when needed for protein
production or during DNA replication while safeguarding the overall integrity of
the genome.

SUMMARY 2-
 Gene Definition: A gene is a sequence of nucleotides in a DNA
molecule that functions as a unit for producing proteins, structural RNA, or
catalytic/regulatory RNA molecules.
Protein-Coding Genes in Eukaryotes: In eukaryotes, genes that code for
proteins typically consist of alternating introns (non-coding regions) and exons
(coding regions), along with regulatory DNA regions that control gene expression.
Chromosome Structure: A chromosome consists of a single, extremely long
DNA molecule that contains a linear array of many genes. These genes are tightly
bound to various proteins to form chromosomal structure.
Human Genome: The human genome is composed of 3.2 billion (3.2 × 10^9)
DNA nucleotide pairs, organized into 22 autosomes (present in two copies each)
and 2 sex chromosomes. Only a small fraction of this DNA codes for proteins or
functional RNA molecules.
Non-Coding DNA Functions: Apart from coding regions, chromosomal DNA
contains important sequences for replication and cell division:
Replication Origins: Sites where DNA replication begins.
Telomeres: Protective sequences at the ends of chromosomes that facilitate
complete replication.
Centromeres: Attach the sister chromatids to the mitotic spindle during cell
division, ensuring accurate segregation to daughter cells.
DNA Packaging with Histones: In eukaryotes, DNA is tightly bound to
histone proteins, which together form repeated DNA–protein particles called
nucleosomes. This binding ensures efficient packing and protection of the genetic
material.
Nucleosome Structure: Nucleosomes consist of an octameric core of histone
proteins around which the DNA double helix is wrapped. These nucleosomes are
spaced about 200 nucleotide pairs apart, creating a repeating structure along the
DNA.
Chromatin Fiber Formation: Nucleosomes are further packed into a more
compact 30-nm chromatin fiber, aided by histone H1 molecules. This compaction
helps in the organization of large amounts of DNA into the nucleus.
Chromatin Dynamics: Despite being compact, chromatin must remain
dynamic to allow gene expression, replication, and repair. Spontaneous
unwrapping and rewrapping of DNA within nucleosomes occur, allowing
temporary access to specific DNA regions.
 Chromatin Remodeling Complexes: Cells use ATP-driven chromatin
remodeling complexes to actively change the structure of chromatin. These
complexes target specific regions of the chromatin and work at appropriate times
to control access to the DNA.
Role of Histone Chaperones: Remodeling complexes collaborate with
histone chaperones to reposition, replace, or remove nucleosome cores, allowing
exposure of underlying DNA for transcription, replication, or repair.
Regulation of DNA Accessibility: This highly dynamic system of chromatin
remodeling allows cells to regulate access to genetic material, facilitating
controlled gene expression and cell function in response to environmental or
developmental signals.

SUMMARY 3-

Uniform DNA Assembly into Nucleosomes: In eukaryotic chromosomes,
DNA is consistently assembled into nucleosomes, which are fundamental units of
chromatin structure. Despite this uniformity, chromatin can adopt a variety of
structural forms based on chemical modifications to histones.
Histone Modifications: A diverse range of reversible covalent modifications
to the four core histones in nucleosomes creates this variety in chromatin
structure. These modifications include:
Mono-, di-, and trimethylation of lysine side chains on histones.
Acetylation of lysines, which is mutually exclusive with methylation on the
same lysine residues.
These chemical changes alter the interactions between nucleosomes and
various chromatin-associated proteins.
Modification Combinations as Chromatin Marks: Specific combinations of
histone modifications, also known as “marks,” are applied to nucleosomes. These
marks serve as signals that govern nucleosome interactions with proteins,
regulating chromatin function and gene expression.
Reader Proteins and Chromatin Interaction: Specialized proteins called
“reader” proteins, which are part of larger protein complexes, bind to the modified
nucleosomes. These reader proteins recognize the specific histone marks and
recruit additional proteins that carry out various tasks, such as remodeling
chromatin, regulating gene expression, or influencing DNA repair.
 Reader-Writer Complexes: Some of these reader protein complexes also
contain enzymes known as “writers” that add further histone modifications. For
example, a histone lysine methylase can recognize and methylate specific lysines,
propagating the same mark the reader protein recognizes. This reader-writer
system can facilitate the spread of particular chromatin structures along a
chromosome.
Formation of Heterochromatin: This reader-writer mechanism is thought
to contribute to the formation of condensed chromatin, specifically
heterochromatin. Heterochromatin is tightly packed and gene-poor, often
silencing any genes within it. It is typically located around centromeres, telomeres,
and other specific chromosomal regions.
Role of Heterochromatin in Gene Silencing: The compact structure of
heterochromatin prevents access to the DNA within, effectively silencing genes
located in these regions. This silencing is important for maintaining genome
stability and regulating gene expression.
Position Effect Variegation: This phenomenon provides strong evidence
that condensed chromatin states, such as heterochromatin, can be inherited across
cell generations. In position effect variegation, a gene’s expression is affected by its
proximity to heterochromatin, demonstrating that chromatin structure can spread
and be maintained across divisions.
Centromeric Chromatin Maintenance: A similar inheritance mechanism
preserves the specialized chromatin structures at centromeres, which are critical
for proper chromosome segregation during cell division. The maintenance of this
specialized chromatin ensures centromeres remain functional across generations.
Epigenetic Cell Memory: The propagation of specific chromatin structures
across cell generations enables an epigenetic memory system. This epigenetic
mechanism allows cells to “remember” their specific states (e.g., differentiation
states) without altering the underlying DNA sequence. This is crucial for complex
multicellular organisms, where different cell types must retain their identity and
function over time.
Role in Multicellular Organisms: This epigenetic memory system is
essential for maintaining distinct cell states and functions, allowing multicellular
organisms to develop and sustain complex tissues and organs by preserving the
specialized functions of different cell types across generations.

SUMMARY 4-
 Nucleotide Sequence Comparisons in Genomes: Comparing the nucleotide
sequences of modern genomes has greatly enhanced our understanding of gene
and genome evolution, revealing patterns of genetic change over time.
High Fidelity of DNA Replication and Repair: DNA replication and repair
processes are highly accurate, allowing only about one nucleotide out of a
thousand to change every million years in a typical eukaryotic lineage. This low
mutation rate means that evolutionary changes in nucleotide sequences occur
very slowly over time.
Human and Chimpanzee Genome Comparison: Humans and chimpanzees
diverged around 6 million years ago, and comparisons of their genomes reveal
very few differences. Their genes are nearly identical, and the order of genes on
their chromosomes is also almost the same. Although some segmental
duplications (DNA duplications) and segmental deletions (DNA losses) have
occurred, even the positions of transposable elements (noncoding DNA that
moves around in the genome) have remained largely unchanged.
Human and Mouse Genome Comparison: Comparing genomes of more
distantly related species, such as humans and mice (separated by about 80 million
years), shows far more changes. Essential nucleotide sequences, especially in
regulatory regions and coding sequences (exons), have been preserved
through purifying selection (the elimination of harmful mutations), highlighting
the evolutionary pressure to maintain critical functions. In contrast, nonessential
sequences, like much of the DNA in introns, have diverged so much that their
shared ancestry is no longer recognizable.
Role of Purifying Selection: The action of purifying selection makes
comparing the genomes of multiple related species a powerful tool for identifying
DNA sequences with important functions. By maintaining essential sequences over
time, purifying selection highlights regions of the genome that play critical roles in
biology.
Conserved DNA in the Human Genome: Approximately 5% of the human
genome has been conserved due to purifying selection. Despite being conserved
across species, much of this DNA has unknown functions. Tens of thousands of
multispecies conserved sequences remain mysterious, and future research is
expected to reveal their roles in vertebrate biology.
Gene Family Expansion and Genetic Complexity: One of the major drivers
of genetic complexity in modern organisms has been the expansion of ancient
gene families. Through DNA duplication followed by sequence divergence, new
genetic functions have evolved, providing a major source of genetic innovation
over evolutionary time.
 Genetic Variation in Humans: On a more recent evolutionary scale, the
genomes of individual humans vary from one another due to:
Single-nucleotide polymorphisms (SNPs), which are single-base changes in
the DNA.
Copy number variations (CNVs), which involve inherited gains and losses of
DNA sequences that lead to differences in gene copy number between
individuals.
These variations contribute to genetic diversity in humans and have important
implications for human biology and medicine.
Impact on Medicine and Human Biology: Understanding the effects of
genetic variations like SNPs and CNVs will provide valuable insights into human
biology and disease. This knowledge can lead to advancements in medical
treatments and a deeper understanding of human health, evolution, and diversity.
Future Research: Continued research into conserved sequences and genetic
variations will expand our understanding of vertebrate biology and the genetic
differences that underlie human traits and diseases. This could lead to
breakthroughs in personalized medicine and insights into the evolutionary
processes that shape genomes.

SUMMARY 5-

Interphase Chromosome Decondensation: During interphase,
chromosomes are generally decondensed, making their detailed structure difficult
to observe. Despite this, specialized chromosomes such as lampbrush
chromosomes (in vertebrate oocytes) and polytene chromosomes (in insect
secretory cells) serve as exceptions and provide insights into chromatin
organization during this phase.
Chromatin Loop Domains: Studies on lampbrush and polytene
chromosomes suggest that each long DNA molecule in a chromosome is divided
into distinct chromatin loop domains. These loops represent sections of the DNA
that are compacted through additional folding. When genes within a loop are
activated for expression, the loop temporarily unfolds, granting the cell’s
transcription machinery access to the DNA.
 Chromosome Territories in the Nucleus: Interphase chromosomes occupy
discrete territories within the cell nucleus, meaning they are not extensively
intertwined with each other. This organization prevents entanglement and
facilitates proper gene regulation and DNA functions.
Euchromatin and Heterochromatin in Interphase:
Euchromatin: The majority of interphase chromatin is euchromatin, which
consists of relatively loosely packed nucleosomes. Euchromatin is more
accessible for transcription machinery when needed, although, when inactive, it
remains compacted.
Heterochromatin: Within euchromatin, there are stretches of
heterochromatin, where nucleosomes are more tightly packed. This
compacted state renders the DNA largely inaccessible for gene expression.
Heterochromatin plays a critical role in gene silencing and structural
chromosome integrity.
Forms of Heterochromatin:
Heterochromatin exists in various forms, including large blocks around
centromeres and near telomeres. These regions are essential for maintaining
chromosomal stability and for the regulation of gene expression.
Heterochromatin can also be found at other chromosomal positions, where it
helps regulate developmentally important genes, serving as a mechanism
for controlling gene activity during different stages of development.
Dynamic Nuclear Organization:
The interior of the nucleus is highly dynamic. Heterochromatin is often
positioned near the nuclear envelope, while chromatin loops can extend out of
their defined chromosome territories when genes are highly expressed.
This movement and organization reflect the presence of nuclear
subcompartments, specialized regions within the nucleus where specific
biochemical reactions occur. These regions enhance the efficiency of certain
reactions by concentrating relevant proteins and RNAs.
Formation of Nuclear Subcompartments:
Nuclear subcompartments, such as the nucleolus and Cajal bodies, are
formed through self-assembly of their components. These discrete nuclear
structures help coordinate specific cellular processes such as ribosome
synthesis and RNA splicing.
 In some cases, components of nuclear subcompartments can be tethered to
fixed structures like the nuclear envelope, adding to the organization and
functionality of the nucleus.
Chromatin Condensation During Mitosis:
During mitosis, gene expression is largely shut down, and all chromosomes
undergo a significant condensation process. This transition begins in early M
phase to ensure the efficient packaging of the two DNA molecules in each
replicated chromosome as two separately folded chromatids.
The condensation process involves histone modifications, which facilitate
the tighter packing of chromatin. These modifications play a role in
reorganizing the DNA into a more condensed state.
Further Chromosome Condensation:
In addition to histone modifications, additional proteins are required for the
full condensation of chromosomes. This process reduces the overall length of
the DNA by a factor of ten compared to its interphase state, ensuring
chromosomes are compact enough for proper segregation during cell division.
Orderly Chromosome Segregation: The full condensation and folding of
chromatids during mitosis is critical for the orderly segregation of chromosomes
into daughter cells. This highly regulated process ensures that each daughter cell
receives the correct number of chromosomes during division.