Organization Of Genetic Material In Eukaryotes PDF

Summary

This document provides an overview of the organization of genetic material in eukaryotes. It covers the structure and function of the nucleus, including DNA, chromatin, and histones. The document also touches on the different levels of DNA packing and the role of the nucleolus. This document can be helpful for students taking a biology class.

Full Transcript

Organization of genetic
material in eukaryotes
DNA in eukaryotes

Location:

In nucleus

In
mitochondria
 Nuclear DNA in eukaryotes
Long, linear molecules;

Chromatin chromosomes;

10% of DNA – in genes, 90% - non-coding;

Gene activity depends on:
Ontogenetic period;
Type of cell;
Environment
 Nucleus
Nuclear envelope:
Inner membrane
Outer membrane
Nuclear lamina
Nuclear pore complex

Chromatin
Euchromatin
Heterochromatin

Nucleoli

Karyoplasm
Nuclear skeleton
Nuclear juice
 Nucleus
Functions:

Contains ~ 98% of DNA;

Assures functional packing of DNA:
euchromatin – active DNA;
heterochromatin – inactive DNA.

Differential control of gene expression:
Transcription and processing of RNA;

Control of cell division:
Replication of DNA and mitosis

Biogenesis of ribososmes
Nuclear pore
 Nuclear pore

14:23:28 http://biologiemoleculara.usmf.md 11
http://e.usmf.md
 Transport through nuclear pore
mediated by karyopherins= importins and exportins

Import (cytosol to
nucleus):
Histones
Non-histones
dNTP, NTP
Ribosomal proteins

Export (nucleus to
cytosols):
mRNA
tRNA
scRNA
RNP 40S; RNP 60S
 prophase
CHROMATIN telophase
CHROMOSOME
◼ Chromatin – genetic material (DNA) with
different levels of packing during
interphase;
◼ Chromosome – genetic material at the
highest level of packing during cell division.
◼ Chemical organization:
– 30% DNA + 40% histones + 25% non-
histones + 5% RNA
 Histones
◼ Globular proteins
◼ Basic proteins, rich in Lys and Arg;
◼ 5 types: H1, H2A, H2B, H3, H4
◼ Function:
– DNA packing at first levels
– Non-specific control of gene expression
Type of Basic amino No. of amino
Shape of proteine
histone acids acids
H1 Liz 215 NH2 COOH
H2A Leu, Liz 129 NH2 COOH
H2B Ser, Pro, Liz 125 NH2 COOH
H3 Arg, Cis 135 NH2 COOH
H4 Arg, Liz 102 NH2 COOH
Histones
DNA + histones =
nucleosome

a. Histone core:
2H2A
2H2B
Octamere 2H3
2H4
b. 200 b.p. Nucleosomal
DNA
c. H1 – stabilizes DNP
complex
20
 Non-histones

Heterogeneous proteins;

Nuclear enzymes for:
replication;
repair;
transcription;
processing of RNA;
biogenesis of ribosomes

Site specific proteins;

Proteins of chromosomal scaffold
Helix-Turn-Helix

Zinc finger
 Chromosomal RNAs

Primary transcripts

microRNA – parts of nuclear enzymes.
Nucleus in different stages of cell cycle
 Levels of packing of
nuclear DNA

Ist level – IInd level –
IVth level –
nucleosome = solenoid = 30 IIIrdlevel –
metaphase
10 nm nm chromatin loops
chromosome
chromatin fiber; fiber;
Characteristics of
levels of DNA
condensation:
- Degree of condensation;
- Thickness of chromatin
fibers;
- Mechanism of
condensation;
- Level of transcriptional
activity;
- Period of the cell cycle.
 Ist level - nucleosome:

11 nm polynucleosome filament;

x 6 condensation;

Mechanism:
DNA- interacts with basic proteins+

Transcription is possible.
 Histone’s modification
Methylation H3 (Lys4) – activation of expression

Methylation H3 (Lys9) – attenuation of expression

Acetylation Chromatin relaxation – active transcription

Chromatin condensation – inactivation of
Deacetylation transcription

Phosphorylation H1 Chromatin supercoiling

Dephosphorylation Chromatin decondensation
H1
29
 2nd level – solenoid
30 nm chromatin fiber;

x 40 condensation;

Mechanism:
Phosphorilation of H1  folding of
polynucleosome fiber – 6 nucleosomes per tour;

Transcription - blocked.
Solenoid
 3rd level – loops
Large or small loops , 300nm;

x 600-1000 condensation;

Mechanism:
30 nm fiber attaches to scaffold;
interaction between SAR (MAR) and scaffold

Transcription - blocked
!!! SAR (MAR) - (Scaffold /Matrix
Associated Region) – specific sites in
DNA responsible for binding to scaffold;
!!! scaffold interacts with:
- chromatin;
- lamins / proteins attached to nuclear
envelope.
37
 4th level –
metaphase
chromosome

The highest level of condensation – x10000;

Chromatid ~700nm;

mechanism:
Pfosphorilation of lamins → dissociation of nuclear
envelope;
Total phosphorilation of H1 – condensation of
chromatin, loops are folded around scaffold.

Transcription – blocked
2 nm

11 nm

30 nm

300 nm

700 nm

1400 nm
 Satellite

Secondary
constriction

Centromere Primary
constriction

Sister
chromatids

◼ centromere = primary constriction
◼ telomer
Centromere
 Centromere
A/T-rich DNA repetitive sequences

Constitutive heterochromatin

Histone H3 is substituted with CENP-A

Ensures sister chromatid joining until anaphase of cell division (P.
cohesin)

Ensures kinetochore attachment

Interacts with the spindle of division
43
 Telomere
Tandemly repeated 3-20 kb long G/C-rich nucleotide
sequences (in H. sapiens - TTAGGG)

Forms loops at chromosome ends (P TFR1, TFR2)

Prevents chromosome shortening during replication

Prevents chromosome fusion (individualizes chromosomes)

Ensures resistance to exonuclease attack

44
Telomere
Telomere
DNA condensation related to the
stages of the Cell cycle
◼ Interphase: Level I
– G1 – pre-synthetic; Level II
– S – synthetic;
Level III
– G2 – post-synthetic;
◼ Mitosis:
– Prophase
– Metaphase Level IV
– Anaphase
– Telophase
47
 Types of chromatin

Euchromatin: Heterochromatin:

Active genes; Non-active regions of
DNA is transcribed; DNA,
Contains coding Contains non-coding
regions. regions;
Contains informational
regions, unused in a
specific cell;
Could be constitutive
and facultative.
 Heterochromatin
Constitutive: Facultative:

Contains non-coding, Contains coding, but
repetitive sequences non-active
of DNA; sequences;
Represents May be transformed
centromeres, into euchromatin;
telomeres, satellites, Assures:
spacers between Cell differentiation;
genes.
Sexual
differentiation;
Control of
ontogenesis
 The same fragment of chromosome in three cells (A, B, C).
E – euchromatin,
Hc – constitutive heterochromatin,
Hf – facultative heterochromatin
 Nucleolus –
part of nucleus responsible for biogenesis
of ribosomes:
Transcription of ribosomal genes and
synthesis of precursor of rRNA (45S);

Processing of 45S rRNA and formation of 3
types of rRNA: 5,8S + 18S + 28S;

Assembling of RNP:

rRNA 18 S + 33 ribosomal proteins = 40S – small
ribosomal subunit;
rRNA 28 S + rRNA 5,8 S + rRNA 5 S + 49 ribosomal
proteins = 60S – large ribosomal subunit
 Structure of nucleolus:
Nucleolar organizer – sequences of DNA containing
ribosomal genes;

rRNAs: primary transcripts 45S; rRNA 5S, rRNA 5,8S,
rRNA 18S, rRNA 28S;

Ribosomal proteins;

Enzymes required for synthesis of rRNA;

RNP 40S and 60S.
Steps in expression of ribosomal genes
DNA P +1 18S 5,8S 28S T

Transcription
Pro-rRNA

Processing

18S 5,8S 28S
rRNA
Assembling 40S + 60S

18S + 33 proteins = 40S 28S + 5,8S + 5S + 49 proteins = 60S
14:23:28 http://biologiemoleculara.usmf.md 55
http://e.usmf.md
 Prophase
Prometaphase
Interphase
Metaphase
Telophase
Anaphase
 Human chromosomes

Represent the morphologic substrate of H & V;

Super-molecular organization of genetic information
(DNA + histones + non-histones + RNA)

Have different shape, size, level of condensation,
gene activity
Single- or bi-chromatidian;
Chromatin or chromosome;
Active or non-active.

58
Structure of metaphase chromosomes.
Chromosomal landmarks
Satellite

Secondary
constriction

Primary
Centromere
constriction

Sister
chromatids

The shape of chromosome depends on the position of centromere
59
 landmarks of karyotype:

relative and absolute length of chrs
position of centromere = primary constriction - c
presence of secondary constrictions - h
presence of satellites - s

chromosomes could be analyzed during:

metaphase (homogenous painting or banding)
prometaphase (banding)
interphase (hybridization with fluorescent probes)

60
 p x100
CI = p + q

61
Human karyotype

62
Classification of chromosomes
By length: By shape: By type:
-Large -Metacentric -Autosomes
-Medium -Submetacentric -Gonosomes
-Small -Acrocentric

By presence of Groups:
other landmarks:
A 1-3 E 16-18
-h on p arm
B 4,5 F 19,20
-h on q arm
C X, 6-12 G 21, 22, Y
-satellites
D 13-15
63
 Karyotype

Normal Polymorphism Aneuploid Polyploid Chromosomal
aberrations

46,XX 46,XX,9qh+ 47,XX,+21 69,XXX 46,XX,1q-
46,XY 46,XY,16qh- 45,XY,-12 69,XXY 46,XY,16p+
46,XX,14s++ 48,XXXY 46,X,r(X)
45,X 46,XY,del(5p)
46,XX,t(12,22)
 Human karyotype and
chromosomal formula
46,XX – normal karyotype

46,XY – normal karyotype

47,XXY – gonosomal trisomy (Klinefelter sdr.)

45,X – gonosomal monosomy (Turner sdr.)

47,XY,+21 – autosomal trisomy (Down sdr.)

45,XY,-21 – autosomal monosomy (lethal)

46,XX,5p- - deletion in chrs. 5 (crie du chat)
65
Human karyotype and
chromosomal formula
46,XX,13ps- – polymorphism
46,XY, 15ph++ – polymorphism
46,XX,15qh+ – abnormality
46,XY,16ph++ – abnormality
46,XY,16qh++ – polymorphism
46,XX,16q- – abnormality
46,XX,16p+ – abnormality
46,XX,13p- – polymorphism
66