Cell biology
This article needs additional citations for verification. (November 2011) |
Cell biology (formerly called cytologiy, from the Greek κυτος, kytos, "vessel") and otherwise known as molecular or cell biology, is a branch of biology that studies the different structures and functions of the cell and focuses mainly on the idea of the cell as the basic unit of life. Cell biology explains the structure, organization of the organelles they contain, their physiological properties, metabolic processes, signalling pathways, life cycle, and interactions with their environment. This is done both on a microscopic and molecular level as it encompasses prokaryotic cells and eukaryotic cells. Knowing the components of cells and how cells work is fundamental to all biological sciences it is also essential for research in bio-medical fields such as cancer, and other diseases. , research in cell biology is closely related to genetics, biochemistry, molecular biology, immunology, and developmental biology.
Internal Cellular Structures by cadaraaxo
Chemical and Molecular Environment
The study of the cell is done on a molecular level; however, most of the processes within the cell is made up of a mixture of small organic molecules, inorganic ions, hormones, and water. Approximately 75-85% of the cell’s volume is due to water making it an indispensable solvent as a result of its polarity and structure.[1] These molecules within the cell, which operate as substrates, provide a suitable environment for the cell to carryout metabolic reactions and signalling. The cell shape varies among the different types of organisms, and are thus then classified into two categories: eukaryotes and prokaryotes. In the case of eukaryotic cells - which are made up of animal, plant, fungi, and protozoa cells - the shapes are generally round and spherical,[2] while for prokaryotic cells – which are composed of bacteria and archaea - the shapes are: spherical (cocci), rods (bacillus), curved (vibrio), and spirals (spirochetes).[3] Cell biology focuses more on the study of eukaryotic cells, and their signalling pathways, rather than on prokaryotes which is covered under microbiology. The main constituents of the general molecular composition of the cell includes: proteins and lipids which are either free flowing or membrane bound, along with different internal compartments known as organelles. This environment of the cell is made up of hydrophilic and hydrophobic regions which allows for the exchange of the above mentioned molecules and ions. The hydrophilic regions of the cell are mainly on the inside and outside of the cell, while the hydrophobic regions are within the phospholipid bilayer of the cell membrane. The cell membrane consists of lipids and proteins which accounts for its hydrophobicity as a result of being non-polar substances.[1] Therefore in order for these molecules to participate in reactions, within the cell, they need to be able to cross this membrane layer to get into the cell. They accomplish this process of gaining access to the cell via: osmotic pressure, diffusion, concentration gradients, and membrane channels. Crossing the phospholipid bilayer to the inside of the cell there are extensive internal sub-cellular membrane-bounded compartments called organelles.
Organelles
- Cell membrane (plasma membrane) - the part of the cell which separates the cells from the outside environment and protects the cell, as well as regulating what goes in and out of the cell
- Cell wall - extra layer of protection and gives structural support (only found in plant cells)
- Chloroplast - key organelle for photosynthesis (only found in plant cells)
- Cilium - motile structure of eukaryotes having a cytoskeleton, the axoneme.
- Cytoplasm - contents of the main fluid-filled space inside cells, chemical reactions also happen in this jelly-like substance.
- Cytoskeleton - protein filaments inside cells (microfilaments, microtubules, and intermediate filaments)
- Endoplasmic reticulum (rough) - major site of membrane protein synthesis
- Endoplasmic reticulum (smooth) - major site of lipid synthesis
- Endosomes - vesicles that traffic membrane and intra and extra cellular contents for recycling or degradation by lysosomes
- Flagellum - motile structure of bacteria, archaea and eukaryotes
- Golgi apparatus - site of protein glycosylation in the endomembrane system
- Lipid bilayer - fundamental organizational structure of cell membranes
- Lysosome - acidic organelle that breaks down cellular waste products and debris into simple compounds (only found in animal cells)
- Microvilli - increases surface area for absorption of nutrients from surrounding medium
- Mitochondrion - major energy-producing organelle by releasing energy in the form of ATP
- Nucleus - contains chromosomes composed of DNA
- Organelle - term used for major subcellular structures
- Peroxisomes - a very small organelle that uses oxygen to breakdown and detoxify long fatty acids and other molecules
- Pili - also called fimbria is used for conjugation and sometimes movement
- Ribosome - RNA and protein complex required for protein synthesis in cells
- Starch grain - found in the cytoplasm of a typical plant cell, it stores chemical energy of the plant.
- Vacuole - contain cell sap (only found in plant cells)
- Vesicle - small membrane-bounded spheres inside cells
Processes
Growth and Development
The growth process of the cell does not refer to the size of the cell, but instead the density of the number of cells present in the organism at a given time. Cell growth pertains to the increase in the number of cells present in an organism as it grows and develops; as the organism gets larger so too does the number of cells present. Cells are the foundation of all organisms, they are the fundamental unit of life. The growth and development of the cell are essential for the maintenance of the host, and survival of the organisms. For this process the cell goes through the steps of the cell cycle and development which involves cell growth, DNA replication, cell division, regeneration, specialization, and cell death. The cell cycle is divided into four distinct phases, G1, S, G2, and M. The G phases – which is the cell growth phase - makes up approximately 95% of the cycle.[4] The proliferation of cells is instigated by progenitors, the cells then differentiate to become specialized, where specialized cells of the same type aggregate to form tissues, then organs and ultimately systems.[1] The G phases along with the S phase – DNA replication, damage and repair - are considered to be the interphase portion of the cycle. While the M phase (mitosis and cytokinesis) is the cell division portion of the cycle.[4] The cell cycle is regulated by a series of signalling factors and complexes such as CDK's, kinases, and p53. to name a few. When the cell has completed its growth process, and if it is found to be damaged or altered it undergoes cell death, either by apoptosis or necrosis, to eliminate the threat it cause to the organism’s survival.
Other cellular processes
- Active transport and Passive transport - Movement of molecules into and out of cells.
- Autophagy - The process whereby cells "eat" their own internal components or microbial invaders.
- Adhesion - Holding together cells and tissues.
- Cell movement - Chemotaxis, contraction, cilia and flagella.
- Cell signaling - Regulation of cell behavior by signals from outside.
- Division - By which cells reproduce either by mitosis (to produce clones of the parent cell) or Meiosis (to produce haploid gametes)
- DNA repair - Cell death and cell senescence.
- Metabolism - Glycolysis, respiration, photosynthesis, and chemosynthesis.
- Signalling - The process by which the activities in the cell are regulated
- Transcription and mRNA splicing - Gene expression.
Techniques used to study cells
Cells may be observed under the microscope, using several different techniques; these include optical microscopy, transmission electron microscopy, scanning electron microscopy, fluorescence microscopy, and confocal microscopy.
There are several different methods used in the study of cells:
- Cell culture is the basic technique of growing cells in a laboratory independent of an organism.
- Immunostaining, also known as immunohistochemistry, is a specialized histological method used to localize proteins in cells or tissue slices. Unlike regular histology, which uses stains to identify cells, cellular components or protein classes, immunostaining requires the reaction of an antibody directed against the protein of interest within the tissue or cell. Through the use of proper controls and published protocols (need to add reference links here), specificity of the antibody-antigen reaction can be achieved. Once this complex is formed, it is identified via either a "tag" attached directly to the antibody, or added in an additional technical step. Commonly used "tags" include fluorophores or enzymes. In the case of the former, detection of the location of the "immuno-stained" protein occurs via fluorescence microscopy. With an enzymatic tag, such as horse radish peroxidase, a chemical reaction is carried out that results in a dark color in the location of the protein of interest. This darkened pattern is then detected using light microscopy.
- Computational genomics is used to find patterns in genomic information [5]
- DNA microarrays identify changes in transcript levels between different experimental conditions.
- Gene knockdown mutates a selected gene.
- In situ hybridization shows which cells are expressing a particular RNA transcript.
- PCR can be used to determine how many copies of a gene are present in a cell.
- Transfection introduces a new gene into a cell, usually an expression construct
Purification of cells and their parts Purification may be performed using the following methods:
- Cell fractionation
- Release of cellular organelles by disruption of cells.
- Separation of different organelles by centrifugation.
- Flow cytometry
- Immunoprecipitation
- The binding of an antibody to a target protein
- Collection of the target protein through elution[6]
- Proteins extracted from cell membranes by detergents and salts or other kinds of chemicals.
Career and Related Fields
Practical job applications for a degree in Cell Molecular Biology includes the following.[7]
|
|
|
Notable Cell Biologists
|
See Also
- Cell disruption
- Cellular microbiology
- Institute of Molecular and Cell Biology (disambiguation)
- Prokaryotic cell
- The American Society for Cell Biology
- Cell physiology
- Green fluorescent protein(GFP)
Notes
- Penner-Hahn, James E. (2013). "Chapter 2. Technologies for Detecting Metals in Single Cells. Section 4. Intrinsic X-Ray Fluorescence". In Banci, Lucia (Ed.) (ed.). Metallomics and the Cell. Metal Ions in Life Sciences. Vol. 12. Springer. doi:10.1007/978-94-007-5561-1_2. ISBN 978-94-007-5560-4.electronic-book ISBN 978-94-007-5561-1 ISSN 1559-0836electronic-ISSN 1868-0402
- Cell and Molecular Biology by Karp 5th Ed., ISBN 0-471-46580-1
- This article incorporates public domain material from Science Primer. NCBI. Archived from the original on 2009-12-08.
- ^ a b c Lodish, Harvey (2013). Molecular Cell Biology. W. H. Freeman and Company. ISBN 978-1-4292-3413-9.
- ^ "The Morphology of Eukaryotic Cells: Shape, Number and Size". YourArticleLibrary.com: The Next Generation Library. Retrieved 2015-11-22.
- ^ "The Size, Shape, And Arrangement Of Bacterial Cells". classes.midlandstech.edu. Retrieved 2015-11-22.
- ^ a b Hardin, Jeff. Becker's World of the Cell. ISBN 978-0-321-71602-6.
- ^ Cristianini, N. and Hahn, M. Introduction to Computational Genomics, Cambridge University Press, 2006. (ISBN 9780521671910 | ISBN 0-521-67191-4)
- ^ "Immunoprecipitation (IP)". www.thermofisher.com. Retrieved 2015-10-16.
- ^ https://www.youtube.com/watch?v=m2HFdEtYDyc.
{{cite web}}
: Missing or empty|title=
(help)