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Tight Junction

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Cell biology is a branch of biology that studies the structure, functioning, and behavior of cells. All life is made up of cells. A cell, the basic unit of life, is what keeps organisms alive and keeps them functioning properly. Cell biology is the study of the functional and structural elements of cells. The study of cell biology covers both prokaryotic and eukaryotic cells, as well as a number of subtopics such as the investigation of cell metabolism, communication, cycle, biochemistry, and composition. The study of cells makes use of cell culture, cell fractionation, and other microscopy techniques. These have made it possible and are still being used to perform research into how cells function, leading to the discovery of new details about more complex organisms. All biological disciplines, as well as biomedical research into conditions like cancer and other illnesses, rely on an understanding of the components of cells and how they work. Research in a number of fields is connected to those in the area of cell biology, including genetics, molecular genetics, molecular biology, medical microbiology, immunology, and cytochemistry.

Tight Junctions

A tight junction is a particular sort of cellular junction created by two or more neighboring epithelial cells. A barrier to the flow of fluid between cells is created when the outer layers of two neighboring cells merge. Tight connections act as a barrier and support the preservation of cell polarity and osmotic balance.

The blood-brain barrier is maintained in part by tight junctions. Tight junctions perform the dual role of keeping cells connected and acting as a barrier between them. According to their presence and their capacity to obstruct the transport of water and solutes, epithelial cells with tight junctions can be categorized as either tight or leaky.

Structure

A junctional complex made up of a branching network made up of sealing strands is what makes up a tight junction. The number of these tight junction strands affects the tight junction’s efficiency, and they each have independent functions. Rows of transmembrane proteins that are rooted in the plasma membrane on one end and exposed to the extracellular domain on the other make up these strands. This network of exposed strands is formed. Thus, each strand contains both transmembrane proteins and cytoplasmic proteins.

The development of the tight junction strand requires the participation of about 40 junctional proteins. There are three main transmembrane tight junction proteins in general:

  1. Occludin: Occludin is a protein that is roughly ~60–65 kDa in size. The occludin protein has intracellular regions at its N- and C-termini. In addition, the protein occludin has four transmembrane domains. The occludin protein creates two external loops and one intracellular loop. The intercellular epithelial barrier function and cellular permeability are both preserved by the occluden protein. Thus, occludin is in charge of distribution and barrier operation.
  2. Claudins: There are about 27 proteins in the claudin protein family, all of which are around ~20 kDa in size. The foundation of the strands of the tight junction is made up of claudin proteins. These proteins are extremely similar in terms of both loop structure and transmembrane domains. It is possible to distinguish claudin proteins from occludin by looking for the W-GLW-C-C residue sequence. Claudin proteins, which have pores in the range of size ~4Ã…, are in charge of charge selectivity in material permeability across the membrane. Some claudins, known as barrier builders, are in charge of constructing the barrier, whereas others, including claudins 1, -3, -4, -8, -11, -14, and -19, are known as tightening claudins because they lower permeability. Claudins 2 and -10b display cation selectivity for a charge, while Claudin -10a displays anion selectivity. The protein occludin and claudin are interacting. Additionally, there is a connection between the gene expression of the claudin protein and the prognosis for cancer.
  3. Junction adhesion molecules JAM proteins: JAM proteins, also known as junctional adhesion molecules, are immunoglobulin superfamily members that are rough ~40 kDa in size. JAM proteins are distinct from other tight junction strand proteins because they only have one transmembrane domain. The main sealants that keep adjacent cells attached to one another are JAM proteins. JAM proteins control how material permeates the membrane with a size-specificity. Another tight junction protein discovered in a human cell is cingulin.
Tight Junction

 

Functions 

Tight junctions serve a variety of purposes. Their primary roles are in assisting cells in forming a barrier that inhibits molecules from passing through and impeding the movement of proteins within the cell membrane. Epithelial cells, which line the body’s surface and fill its cavities, frequently have tight connections. Epithelial cells divide body surfaces within the body, as well as between the body and its surroundings. Therefore, it is crucial to tightly regulate the permeability of molecules through epithelial cell layers.

If tight junctions prevent molecules from physically passing across the space between cells, they must enter by alternate pathways that include penetrating the cells directly. They might be able to cross over specific proteins in the cell membrane or undergo endocytosis to be taken up by the cell. These techniques provide the cell more control over the substances that it takes in and let’s pass through. Certain proteins must be retained on specific sides of endothelial cells, though. Proteins on the apical, or outside layer, of the sheet of cells limit which compounds can pass through. In the basal, or inner layer, cells eject molecules from their membrane in a process known as exocytosis in order to allow molecules to pass through them. Exocytosis also needs particular proteins to function properly. Tight junctions keep the necessary proteins on the correct sides of the cell in order for these processes to occur. Additionally, it preserves the polarity of cells.

Simple cell adhesion is another function of tight junctions. Tight junctions generate a sheet of closely connected neighboring cells thanks to their branching protein strands. These strands are attached to microfilaments, which are made up of lengthy actin protein strands and are a component of the cell’s cytoskeleton. Because microfilaments are found inside the cell, sealing strands and microfilaments work together to bind the cells together on the inside and the exterior.

FAQs on Tight junction

Question 1: What is Tight Junction?

Answer:

Tight junctions are a specific kind of cell junction that function as a tight seal between two adjacent cells by producing an adhesion complex. In essence, the tight junctions are protein complexes that connect two cells. The tight connection or seal regulates para cellular transport and permeability while preventing content leakage. In the cellular membrane, tight junctions thereby provide a continuous semipermeable membrane link.

Question 2: What parts of the body contain tight junctions?

Answer:

Endothelial and epithelial cell membranes include these tight connections.

  • The primary role of tight junctions is that of a barrier or regulator, regulating the flow of solutes and liquids according to their charge and size. Perm-selectivity is another name for the phenomena where material transit is affected by charge and size.
  • Tight junctions are a highly resistant barrier that is crucial for various physiological cellular activities. Different organs’ cellular membranes display a spectrum of tight junction permeability.

Question 3: What are tight junctions used for primarily?

Answer:

The continuous intercellular barrier created by tight connections between epithelial cells is necessary to demarcate tissue compartments and control the selective transport of solutes across the epithelium.

Question 4: How tight junction formed?

Answer:

Tight junctions that occur between cells help to maintain the integrity of the epithelial tissue. The tight junction strands, which are made up of transmembrane proteins including claudin, occludin, and tricellulin, are the fundamental functional components that create sticky connections between cells.

Question 5: Why do kidneys need tight junctions?

Answer:

The operation of the epithelial barrier depends critically on the tight junction, a significant subcellular organelle. The tight junction membrane component claudin generates a para cellular transport channel that allows different ions to be reabsorbed by the kidneys.

Question 6: What Cannot pass through tight junctions?

Answer:

Tight junctions restrict molecules and ions from moving between adjacent cells’ plasma membranes, therefore substances must move inside the cells themselves (either by active transport or diffusion) in order to move through the tissue.



Last Updated : 12 Jan, 2024
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