Table of contents | |
What is Cytoskeleton? | |
Cilia and Flagella | |
Centrosome and Centrioles | |
Nucleus | |
Nucleolus | |
Chromosomes | |
Microbodies |
The cytoskeleton, a complex network of protein fibers including microtubules, microfilaments, and intermediate filaments found in the cell's cytoplasm, serves various roles such as providing structural support, enabling movement, and maintaining cell shape.
Cilia and flagella are like tiny hairs on the surface of cells. Cilia are short and move like paddles, either moving the cell or stirring up surrounding fluids. Flagella are longer and help cells move around. Even bacteria have flagella, but they look different from those in more complex cells.
Under a special microscope, we see that cilia and flagella are covered by a thin layer, like a skin. Inside, there's a central structure called an axoneme made up of tiny tubes. This axoneme usually has nine pairs of tubes around the edges and two in the middle, making a 9+2 pattern. These tubes are linked together with little bridges and spokes. Cilia and flagella come out from structures called basal bodies, which are like cell's "starting points"
The centrosome is a cell part that usually has two cylindrical structures called centrioles. They're surrounded by a mushy material. These centrioles sit at right angles to each other and have a structure like a wheel. Each centriole is made of nine rows of tubulin protein fibers, forming a triplet pattern. These triplets are connected to each other. In the center of the centriole, there's a protein hub that's connected to the tubules of the outer triplets by protein spokes. Centrioles act as the starting point for making cilia, flagella, and the spindle fibers needed for cell division in animals.
[Question: 906861]
(a) Coenocytic Cells: This type of cells, are formed by free nuclear divisions.
Example :- Phycomycetes fungi, Endosperm, rhizopus, vaucheria, etc.
(b) Syncytium: Syncytial condition is formed by the fusion of cells.
Example :- Epidermis of nematods, striped muscles.
(i) Nuclear membrane or nuclear envelope or karyotheca
(ii) Nucleoplasm/Karyoplasm/Karyolymph
(iii) Chromatin net
(iv) Nucleolus/little nucleus/Ribosome factory
Nucleus is surrounded by two unit membranes, thus nucleus is double membranous component of cell. Space (150 to 300 Å) between two membranes is known as perinuclear space. Outer membrane, of nucleus may connected with E.R. at several places and ribosome also may found on it.
Term was given by Strasburger in 1882. Nucleoplasm or Nuclear sap is a ground substance of nucleus which is a complex colloidal formed of a number of chemicals like nucleotides, nucleosides, ATPs, proteins & enzymes of RNA & DNA polymerases, endonucleases, minerals, (Ca++, Mg++) etc.
Nucleoplasm contain high concentration of Nucleotides in the form of triphosphate.
On the basis of relative amount of arginine and lysin there are five type of Histone protein.
(H2A, H2B, H3, H4, H1)
Amino acid | Type of histone |
Lysin rich | H1 |
Slightly lysin rich | H2A, h2b |
Arginine rich | H3 , H4 |
Chromatin net has two type of chromatins (by Emil Heitz):
(a) Euchromatin:- This is lightly stained and diffused part of chromatin. Which is transcriptionally or genetically more active. Generally euchromatin lies at central part of nucleus.
(b) Heterochromatin:- This is dark stained, thick and condensed part of chromatin this part have more histone and less acidic protein. Heterochromatin is genetically less active chromatin and forms stop point in transcription. Heterochromatin occurs near nuclear membrane.
(i) Constitutive heterochromatin:- Occurs in all cells in all stages e.g. centromeric region.
(ii) Facultative heterochromatin:- Occurs in some cells in some stages e.g. barr body.
Difference between Euchromatin and Heterochromatin. | |
Euchromatin | Heterochromatin |
1)Consist of thin, extended, light stained part of chromatin. | 1)Consist of thick aoild, condensed part of Chromatin and dark stained. |
2) Genetically more active chromatin | 2) Less active or inert chromatin. |
3) Lies at centre of nucleus. | 3) Lies near the nuclear membrane. |
4) less histone protein | 4) More histone protein |
5) Replicate in early s phase | 5) Replicate in late s phase |
6) DNA → mRNA | 6) DNA → rRNA, tRNA |
[Question: 906847]
(ii) Transmission of genetic information :- Nucleus takes part in transmission of genetical information from parent cell to daughter cell or the one generation to next.
(iii) In cell-division :- Division of nucleus is pre-requisite to cell division.
(iv) Control of metabolism :- Nucleus controls metabolism of cell by sending m-RNA in cytosol (Basically biomolecule DNA controls cellular activities through directing synthsis of enzyme).
(v) Variations :- Variation develops due to change in genetic material of nucleus. (Evolutionary role).
What is the nucleus?
The nucleus is a double-membraned organelle that contains the genetic material and other instructions required for cellular processes. It is exclusively found in eukaryotic cells and is also one of the largest organelles.
Outline the structure of the Nucleus.
Highlight the functions of the nucleus.
The nucleus has 2 primary functions:
The nucleolus is the distinct structure present in the nucleus of eukaryotic cells. Primarily, it participates in assembling the ribosomes, alteration of transfer RNA and sensing cellular stress. The nucleolus is composed of RNA and proteins, which form around specific chromosomal regions.
It is one of the main components of the nucleus. The chain of RNA and DNA along with other components form the structural components. The main components of the nucleolus are ribonucleic acid, deoxyribonucleic acid and proteins.
In eukaryotic cells, nucleolus has a well-ordered structure with four main ultrastructural components. The components can be further identified as:
The ultrastructure of the nucleolus can be easily visualized through an electron microscope. The arrangement of the nucleolus within the cell can be clearly studied by the techniques – fluorescent recovery after photobleaching and fluorescent protein tagging.
The nucleolus of several plant species has very high concentrations of iron in contrast to the human and animal cell nucleolus.
Ribosome formation is the chief role of nucleolus, thus its called as Ribosme factory of cell, the proteins of ribosomes are synthesised in cytoplasm but it diffused in to nucleus and reach at nucleolus. Here r-RNA and ribosomal proteins are assembled to form ribosomes which move to cytoplasm through nuclear pores.
Note: At the some places heterochromatin forms thickned dense granules which are known as karyosomes or chromocentre or false nucleoli.
The difference between nucleus and nucleolus is mentioned below:
What is the function of nucleolus?
Nucleolus helps in protein synthesis and production of the ribosome in the cells.
Where is the nucleolus located in the cell?
The nucleolus is located inside the nucleus of the eukaryotic cell. It is surrounded by a membrane inside the nucleus.
What does the nucleolus contain?
The nucleolus contains DNA, RNA and proteins. It is a ribosome factory. Cells from other species often have multiple nucleoli.
Is nucleolus an organelle?
The nucleolus is an organelle, and a very unusual one because it is devoid of lipid bilayers, which are characteristic of other organelles.
What would happen if there is no nucleolus in the cell?
If the nucleolus didn’t exist, there would be no production of ribosomes and there would be no synthesis of proteins.
(Parts which appears in metaphase chromosome)
1. Pellicle – This is outermost, thin proteinaceous covering or sheath of chromosome.
2. Matrix – This is a liquid nongenetic achromatic ground substance of chromosome, which has different type of enzymes, minerals, water, proteins.
3. Chromonema (singular Chromonemata) →Term by Vejdovsky. This is an important, genetical, highly coiled thread, throughout the length of a chromosome or chromatid. It was called chromonema.
4. Centromere/Kinetochore :- (Primary constriction)
Centromeric DNA is called as alphoid DNA.
5. Chromatid – At metaphase stage each chromosome is consist of two cylindrical structures - called chromatids.
Both sister chromatids or longitudinal half chromosome are joined together by a common centromere. A chromosome, may have single chromatid (in Anaphase or Telophase) or two chromatid. (as in metaphase)
6. Secondary Constriction : Besides primary constrictions one or two, other constriction may also occurs on some chromosome, which are known as secondary constriction.
Secondary constriction is also known as NOR (Nucleolar organizer region)(13,14,15,21,22 chromosomes in human)
7. Satellite : part of chromosome remains after the NOR is known as chromosomes satellite/ trabent.
Chromosomes with satellite part are called as SAT chromosome (SAT = Sine Acid Thymonucleinico)
8. Telomere : Chromosomes have polarity and polar ends of chromosomes is known as Telomere.
Telomere prevents fusion of one chromosomes to other chromosome. Telomere rich in Guanine base.
Enzyme Telomerase presents in telomere part of chromosome, which is a Ribonucleoprotein.
(i) Telocentric :- When centromere is terminal or located at the tip of chromosome.
ii) Acrocentric :- When the centromere is sub-terminal or located near the tip.
(iii) Metacentric :- When the centromere is located at mid of the chromosome.
(iv) Sub metacentric :- When the centromere located near centre or mid point of chromosome.
The ratio of length of the long arm to the short arm of a chromosome is called arm ratio. Arm ratio is maximum in acrocenteric chromosome.
DNA and an Octamer (Core particle) of four types ( H2A, H2B, H3& H4) of histone proteins". Nucleosome is also known as Nu-body or g-particle.
Nucleosome= Binding DNA (146 bp)+Octamer Core (H2A, H2B, H3, H4 × 2)+Linker DNA +H1 Histone
1. Salivary Gland Chromosome
This type of chromosome was discovered by E.G. Balbiani, in Chironomous larva of Drosophila . Size of this chromosome may upto 2000 micron (2mm) and number of chromatids may be 512 to many thousands. Thus, this type of chromosome also known as Giant chromosome.
2. Lampbrush Chromosome
Discovered by Flemming and Ruckert from oocytes of vertebrates (Amphibia) during diplotene stage of cell division. These chromosomes look like lamp - brush, thus called as lamp brush chromosomes.
Size of these chromosomes may upto 5900 micron, and also called as giant chromosome.
The cells of protozoa, fungi, plants, liver and kidney cells contain certain membrane bounded spherical bodies of 0.3 to 1.5m diameter, filled with enzymes are called as ‘‘Microbodies’’.
On the basis of functions microbodies are of following types:
(1) Sphaerosomes
Sphaerosomes occur only in plant cells. They are major site of lipid storage and synthesis in plants.
Sphaerosomes also have lysosome like activity so they also termed as plant lysosomes.
(2) Peroxisomes or Uricosomes
(3) Glyoxysomes
Glyoxysomes occurs only in plants especially in fatty seeds (castor seed), guard cells of stomata and unripe fruits. Glyoxylate cycle is linked with the TCA cycle and used for production of acids in fruit.
Glyoxysomes are considered as a highly specialised peroxisomes. Glyoxylic acid cycle takes place in glyoxysomes. This cycle convert fats into carbohydrats.
(4) Transosomes
Special microbodies in ovary cells of birds (concern with yolk formation). These covered by three unit membranes.
Electron Microscope (Ultrastructure of Nucleolus) has shown nucleolus to be made of following parts:
(i) Fibrillar region :- This is central fibrous part of nucleolus, which is consist of mainly rDNA and proteins. (Nucleonema)
(ii) Granular region :- This is peripheral granular part of nucleolus which is consist of rRNA and proteins.
(iii) Amorphous matrix or pars amorpha :- This is proteinaceous ground matrix, which contains both fibres and granules.
Plants | 2n | n |
Mucor hemelis (Fungi) | 2 | 1 |
Haplcpappus gracilis (Family compositae) & Brachycome plant | 4 | 2 |
Takakia (Bryophyta) | 4 | 2 |
Pisum sativum (Pea) | 14 | 7 |
Maize (Zea mays) | 20 | 10 |
Wheat (Triticum) | 42 | 21 |
Cphioglossum reticulatum (Pteridophyta) | 1262 | 631 |
Animals |
|
|
Ascaris megalocephala (Round worm) | 2 | 1 |
Drosophila manogaster (Etuit fly) | 8 | 4 |
Chimpanzee/Gdrilla | 48 | 24 |
Homo sapiens | 46 | 23 |
Aulocantha (a protozoan) | 1600 | 800 |
Banding technique is used to study of the specific pattern of bands and interbands on chromosome. This includes the use of fluorochromes (fluorescent dyes):
(i) Q–banding : It is obtained when chromosomes are stained with quinacrine mustard. It stains A–T rich areas (developed by casperson for Y chromosomes).
(ii) G–banding : Chromosomes are stained with Giemsa. It stains sulphur rich protein parts.
A variety of different bands are obtained by the modification of Q–banding and G–banding like C, T and N–bands. Q, C, G and R banding used for animal karyotypes while C and N banding used in plants.
(iii) C-banding :- It is used to stain constitutive heterochromatin , usually in centromeric region of the chromosome. The process involves denaturation of chromosome by heat or trisodium citrate and then apply giemsa stain.
(iv) R-banding :- The process involved incubation of the chromosomes in a buffer at high temperature followed by use of Giemsa stain. This brings about the visualization of sulphur deficient region of chromosomes thus named as reverse giemsa.
Modern techniques used in karyotype preparation are:
ISH, FISH (Fluorescence in Situ Hybridisation), Mc FISH (Multicolour fluorescence in situ Hybridisation) and flow cytometry.
Idiogram: Diagrammatic representation of Karyotype. In idiogram chromosomes are arranged in decreasing order of size. Sex chromosomes are placed in last but in idiogram of Drosophila sex chromosomes are placed first. Idiogram is specific for every species.
(i) It suggests primitive or advanced features of an organism. If karyotype shows a large size difference between the smallest and the largest chromosome of the set and having fewer metacentric chromosomes then it is called asymmetric karyotype, which is a relatively advance feature. Symmetric karyotype is primitive feature.
(ii) The karyotype of different species are compared and similarities in them represent the evolutionary relationships.
(iii) Karyotype is helpful in detection of chromosomal abberrations and polyploidy.
(iv) In research of medical genetics Forensic science cytogenetics and Anthropogenetics.
1. In Situ Hybridization : Using DNA probe labelled with radioactive molecule to locate the position of DNA sequence on chromosome.
2. Fluorescence in Situ Hybridization (FISH) : DNA may also be labelled with fluorochrome to locate the position of DNA sequence on chromosome.
3. Multicolour Fluorescence in Situ Hybridization (Mc FISH) : More fluorochrome colour to locate the position of DNA sequence on chromosome.
4. Flow cytometry : This is recent technique. In this technique a suspension of many thousands of chromosome is made and the suspended chromosome are stained with a DNA binding flurochrome.
Types of Coiling in Chromonema:
(i) Plectonemic-coiling :- When both the chromonema are inter twined and can not be seperated easily. (in mitotic prophase chromosomes)
(ii) Paranemic coiling :- When both chromonema can be easily seperable. (In meiotic prophase)
Types of Chromosomes on the basis of Number of Centromere
(i) Acentric :- Chromosome without centromere.
(ii) Monocentric :- Chromosome with one centromere.
(iii) Dicentric :- When the number of centromere is two.
(iv) Polycentric chromosome :- When the number of centromere is more than two & diffused in throughout chromosome length.
1. B-Chromosome/Accessory Chromosome/Supernuemerary Chromosome
2. Mega Chromosomes
3. Isochromosomes
4. Ring Chromosome
Prokaryotic chromosome are ring chromosome or consists of circular folded DNA without histone.
5. Sex Chromosome
May be XX or XY
6. HACs, MACs, YACs, BACs, etc.
Group (A) : 1–3 chromosomes of largest size and submetacentric or metacentric centromere.
Group (B) : 4–5 chromosomes with less larger size, submetacentric
Group (C) : 6–12 chromosomes with medium sized and submetacentric centromere.
Group (D) : 13–15 chromosomes, shorter than group ‘C’ with centromere near the end (Acrocentric). They are SAT chromosomes or satellite.
Group (E) : 16–18 chromosomes, short sized, with median (Metacenteric) or submedian centromere (Submetaceteric).
Group (F) : 19–20 chromosomes, short sized with median centromere.
Group (G) : 21–22 chromosomes, smallest in size, acrocentric and are also posess satellites.
182 videos|365 docs|153 tests
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1. What is the function of the cytoskeleton in a cell? |
2. How do cilia and flagella differ in terms of structure and function? |
3. What is the role of the centrosome and centrioles in cell division? |
4. What is the primary function of the nucleus in a cell? |
5. How are chromosomes organized within the nucleus during cell division? |
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