Histological Aspects of Cell Nucleus PDF

Summary

This document is a presentation or lecture notes on the histological aspects of the cell nucleus. It covers various aspects of the cell nucleus, including its structure, components, and function. The material would likely be appropriate for an undergraduate-level cell biology course.

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Histological aspects of
cell nucleus
Nuriye Ezgi BEKTUR AYKANAT
Faculty of Medicine
Department of Histology and Embryology
ATILIM UNIVERSITY

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 The nucleus is the largest and membrane- bound organelle of the cell. It contains nearly all
of the deoxyribonucleic acid (DNA) possessed by the cell as well as the mechanisms for
ribonucleic acid (RNA) synthesis.
The most prominent substructure within the nucleus is the nucleolus, which is the site of
rRNA transcription and processing, and of ribosome assembly. 2
 NUCLEUS
STRUCTURES

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 The nucleus, bounded by the
nuclear envelope composed
of two concentric lipid
membranes, houses three
major components:
❑Nucleoplasm, containing
macromolecules and nuclear
particles involved in the
maintenance of the cell.
❑Chromatin, the genetic
material of the cell
❑Nucleolus, the center for
ribosomal RNA (rRNA)
synthesis
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 The nucleus is usually spherical and is centrally
located in the cell; however, in some cells, it may be
spindle shaped to oblong shaped, twisted,
lobulated, or even disk shaped. 5
 Although, usually, each cell has a single
nucleus, some cells (such as osteoclasts)
possess several nuclei, whereas mature
red blood cells have extruded their nuclei.
The size, shape, and form of the nucleus
are generally constant for a particular cell
type, a fact useful in clinical diagnoses of
the degree of malignancy of certain
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cancerous cells.
NUCLEAR ENVELOPE
The nucleus is surrounded by the
nuclear envelope, composed of
two concentric parallel unit
membranes:
the inner and outer nuclear
membranes, separated from each
other by a 20- to 40-nm space called
the perinuclear cisterna. The
nuclear envelope is perforated at
various intervals by nuclear pores
that permit communication
between the cytoplasm and the
nucleus and assists in organizing
the chromatin.
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Outer Nuclear Membrane

The outer nuclear membrane is also about 6 nm thick, faces the cytoplasm, and is
continuous with the rough endoplasmic reticulum (RER) and is considered by some
authors as a specialized region of the RER whose lumen is continuous with the
perinuclear cisterna.
Its cytoplasmic surface is surrounded by a thin, loose meshwork of the
intermediate filaments, vimentin. Its cytoplasmic surface usually possesses
ribosomes actively synthesizing transmembrane proteins that are destined for the
outer or inner nuclear membranes. 8
Inner Nuclear Membrane
The inner nuclear
membrane is about 6 nm
thick and faces the nuclear
contents.
It is in close contact with the
nuclear lamins, an
interwoven meshwork of
intermediate filaments, 80
to 300 nm thick, composed
of lamins A, B1, B2, and C
and located at the periphery
of the nucleoplasm.
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 The nuclear lamins help in 1organizing and providing support to the
lipid bilayer membrane and the 2 perinuclear chromatin as well as
3playing a role in the formation of nuclear pore complexes and
4assembly of vesicles to reform the nuclear envelope subsequent to

cell division. 10
 Nuclear Pores
At certain locations on the surface of the nuclear envelope,
the outer and inner nuclear membranes are continuous
with each other, creating openings about 80 nm in
diameter known as nuclear pores, which permit
communication between the nuclear compartment and
the cytoplasm.
The number of nuclear pores in a nucleus ranges between
a few dozen to several thousand, correlated directly
with the metabolic activity of the cell.

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 Each of the nuclear pore complexes is in
communication with the others via the
nuclear lamina and certain pore-
connecting fibers.
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Nuclear Pore Complex

The nuclear pore complex is about 100 to 125 nm in diameter and spans the two nuclear
membranes.
The nuclear pore complex is composed of about a hundred different proteins, collectively
known as nucleoporins, arranged in three ring-like arrays of proteins stacked on top of the
other.
In addition, the nuclear pore complex has cytoplasmic fibers, a central transporter (plug) ,
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and a nuclear basket.
 Each subunit possesses a
cytoplasmic fiber (cytoplasmic
filament).
It has been suggested that these
fibers may mediate import into
the nucleus through the nuclear
pore complex by moving
substrates along their length
toward the center of the pore.

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Function of the Nuclear Pore Complex
The nuclear pore complex functions in
bidirectional nucleocytoplasmic
transport.
The bidirectional traffic between the
nucleus and the cytoplasm is mediated by
a group of target proteins containing
nuclear localization signals (NLSs)
known as importins and nuclear export
signals known as exportins (also known
as karyopherins, PTACs, transportins, and
Ran-binding proteins).
Exportins transport macromolecules (e.g.,
RNA) from the nucleus into the
cytoplasm, whereas importins transport
cargo (e.g., protein subunits of ribosomes)
from the cytoplasm into the nucleus. 16
 Exportin and importin
transport is regulated by a
family of GTPbinding
proteins known as Ran.
These specialized
proteins along with other
nucleoporins located along
receptor sites in the nuclear
pore complex facilitate the
signal-mediated import
and export processes.
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CHROMATIN

DNA, the cell’s genetic material, resides in the nucleus in the form of chromosomes, which
are clearly visible during cell division.
In the interval between cell divisions (=interphase), the chromosomes are unwound in the
form of chromatin.
Depending on its transcriptional activity, chromatin may be condensed as heterochromatin or
extended as euchromatin. 19
 Heterochromatin is located mostly at the periphery of the nucleus and
comprises almost 90% of the total chromatin of the nucleus.
The remainder of the chromatin scattered throughout the nucleus and
not visible with the light microscope is euchromatin (=less condensed
chromatin). This represents the active form of chromatin where the
genetic material of the DNA molecules is being transcribed into RNA.
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Chromosomes

As the cell leaves the interphase stage and prepares to
undergo mitotic or meiotic activity, the chromatin fibers
are extensively condensed to form chromosomes, visible
with light microscopy. The number of chromosomes in
somatic cells is specific for the species and is called the
genome, the total genetic makeup. 26
 In humans, the genome consists of 46
chromosomes, representing 23
homologous pairs of chromosomes.
One member of each of the
chromosome pairs is derived from the
maternal parent; the other comes from
the paternal parent.
Of the 23 pairs, 22 are called
autosomes; the remaining pair that
determines gender are the sex
chromosomes. The sex
chromosomes of the female are two X
chromosomes (XX); those of a male
are the X and Y chromosomes (XY).

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 Giemsa reagent stains the adenine-thymine–rich
regions of chromosomes, producing a pattern of G
bands that is unique for each chromosome pair and is
characteristic for each species.
Careful analysis of the G bands can help reveal
deletions of certain portions of the chromosome,
nondisjunctions, translocations, and so on, that
may assist in the diagnosis of certain genetic
disorders or diseases resulting from chromosomal
anomalies. 28
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 Telomeres are short, repeated, DNA sequences at the ends of chromosomes. They appear to
protect the ends of the chromosomes from degradation, and in oocytes and spermatogonia as well
as in stem cells an enzyme–RNA complex, known as telomerase, maintains the telomere length.
Interestingly, the RNA portion of the enzyme is used as a template to synthesize the additional DNA
necessary to maintain telomere length. Somatic cells do not possess telomerase, and, with each
successive cell division, the telomeres become shorter, and eventually they become short enough that
they can no longer protect the chromosome, and the cell becomes unable to replicate itself.
This built in senescence is absent in cancer cells because many malignant cells are able to express
the gene that codes for telomerase. 31
Sex Chromatin
Only one of the two X
chromosomes in female
somatic cells is
transcriptionally active.
The inactive X chromosome,
randomly determined early in
development, remains
inactive throughout the life of
that individual.

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 Microscopic study of interphase
nuclei of cells from females
displays a very tightly coiled
clump of chromatin, the sex
chromatin (Barr body), the
inactive counterpart of the
two X chromosomes.
Epithelial cells obtained from
the lining of the cheek and
neutrophils from blood smears
are especially useful for
studying sex chromatin.
The sex chromatin is observed
at the edge of the nuclear
envelope in smears of the oral
epithelial cells and as a small
drumstick-like evagination of
the nuclei of the neutrophils.
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Nucleoplasm

Nucleoplasm, separated from the cytoplasm by the nuclear envelope, is
a somewhat viscous substance that surrounds the chromosomes and
the nucleoli and is composed of interchromatin and perichromatin
granules, water, ribonucleoproteins (RNPs), and the nuclear matrix.
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 It has an amorphous structure.
It helps maintain the shape and structure of
the nucleus.
It plays an important role in the transport of
materials that are vital for cell metabolism
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and function.
 Nucleolus
The nucleolus, a dense nonmembranous
structure located in the nucleus, is
observed only during interphase
because it dissipates during cell
division. It stains basophilic with
hematoxylin and eosin, being rich in
rRNA and protein.
The nucleolus contains only small
amounts of DNA, which is also inactive.
Usually, there are no more than two or
three nucleoli per cell; however, their
number, size, and shape are generally
species specific and relate to the
synthetic activity of the cell. In cells that
are actively synthesizing protein, the
nucleolus may occupy up to 25% of the
nuclear volume.
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 Four distinct areas of the nucleolus have been described:
❑A pale-staining fibrillar center (FC), containing inactive DNA (not being transcribed)
❑Pars fibrosa (PF), containing nucleolar DNAs being transcribed into rRNA as well as the protein
nucleolin, small nucleolar ribonuclear proteins, and ribonucleoprotein enzyme fibrillarin, necessary
for the converting of the pre-rRNA into mature rRNA
❑Pars granulosa (PG), in which maturing ribosomal subunits.
❑Nucleolar matrix, a network of fibers active in nucleolar organization
❑Also located in the pale-staining regions are the tips of chromosomes 13, 14, 15, 21, and 22 (in
humans), containing the nucleolar-organizing regions (NORs), where gene loci that encode rRNA
are located.
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Video links
https://www.youtube.com/watch?v=yxy59vpd33I
https://www.youtube.com/watch?v=rjaudsjiGV8

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