1) A cellular signaling pathway has four major parts that determine its function. The initial signal, ranging in size and composition, is the first component in the signal. This will then determine what type of signal can occur and which receptor can accept the signal. Once the signal reaches the receptor, either intracellular or extracellular, the receptor responds by altering in order size/shape in order to accept the signaling ions. With completion of the cellular signal, the message is spread throughout the cell, causing short or long-term effects.
2) With the activation of a transcription factor, protein could be produced. With the production of protein, cellular respiration could then occur from the activation of the cell cycle.
3) Phosphorylation
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This particular binding site is composed of a very specific amino acid sequence for kinase. As a result, only specific proteins can bind and be produced at this site, which will determine the location of each enzyme’s activity.
6) A signaling pathway must be regulated for efficiency purposes. This regulation provides cells the ability to create something that the body needs, only when it is needed. If a signaling pathway wasn't regulated, a signal would have no way of stopping how many times they occur or the duration of each. Also without regulation, ion channels could remain open or closed for extended periods, causing a change in metabolism, deactivation of the ion channel completely, or a large build up of enzymes, which would be problematic for the functioning of the cycle cycle.
7) When a muscle contracts, a signal transduction would need to occur rapidly in order for a cellular signal to reach the location in time. If a signal doesn't reach the muscle in time for a contraction, then no movement will be performed. Also if the signal doesn't then relax the muscle contraction after, a muscle spasm can occur. Signal transduction also would need to occur rapidly if an injury or fever were to
In the beginning phases of muscle contraction, a “cocked” motor neuron in the spinal cord is activated to form a neuromuscular junction with each muscle fiber when it begins branching out to each cell. An action potential is passed down the nerve, releasing calcium, which simultaneously stimulates the release of acetylcholine onto the sarcolemma. As long as calcium and ATP are present, the contraction will continue. Acetylcholine then initiates the resting potential’s change under the motor end plate, stimulates the action potential, and passes along both directions on the surface of the muscle fiber. Sodium ions rush into the cell through the open channels to depolarize the sarcolemma. The depolarization spreads. The potassium channels open while the sodium channels close off, which repolarizes the entire cell. The action potential is dispersed throughout the cell through the transverse tubule, causing the sarcoplasmic reticulum to release
...st the sacrolemma will depolarized, thus activation potentials along the T-tubules. This signal will transmit from along the T-tubules to sarcroplasmic reticulum's terminal sacs. Next, sarcoplasmic reticulum will release the calcium into the sarcroplasm leading to the next second event called contraction. The released calcium ions will now bind to troponin. This will cause the inhibition of actin and mysoin interaction to be released. The crossbridge of myosin filaments that are attached to the actin filaments, thus causing tension to be exerted and the muscles will shorten by sliding filament mechanism. The last event is called Relaxation. After the sliding of the filament mechanism, the calcium will be slowly pumped back into the scaroplasmic reticulum. The crossbridges will detach from the filaments. The inhibition of the actin and myosin will go back to normal.
called an active site. This active site is made by a few of the amino
Cellular respiration is a chemical reaction used to create energy for all cells. The chemical formula for cellular respiration is glucose(sugar)+Oxygen=Carbon Dioxide+Water+ATP(energy) or C6H12+6O2=6CO2+6H2O+ energy. So what it is is sugar and
Homeostasis is the biological process that maintains a stable internal environment despite what occurs in the external environment. Chemicals and bodily functions are maintained in a balanced state so the body may function optimally. There are various systems in the human body that require maintenance through the processes of biochemical checks and balances so they may function properly. One of these systems includes the rise and fall of blood glucose and is under the control of the homeostatic regulation process. Homeostasis is essential in blood glucose regulation as high blood glucose levels (hyperglycaemia) and low blood glucose levels (hypoglycaemia) are dangerous and can affect the human body in many ways and can also lead
Cellular respiration and photosynthesis are the two most important processes that animal and plant cells supply themselves with energy to carry out their life cycles. Cellular respiration takes glucose molecules and combines it with oxygen. This energy results in the form of adenosine triphosphate (ATP), with carbon dioxide and water that results in a waste product. Photosynthesis uses carbon dioxide and combines it with water,
Metabolic pathways are a series of reactions catalysed by multiple enzymes. Feedback inhibition, where the end product of the pathway inhibits an earlier step, is an
The entire process starts off when an agonist involved is bound to receptors specific to it, expressed on the endothelial cell surface, activating enzymes like phospholipase C (PLC) directly through vascular endothelial growth factor receptors (VEGFR) or by thrombin or histamine through G protein coupled receptors (GPCR).
Overview of Cellular Respiration and Photosynthesis Written by Cheril Tague South University Online Cellular Respiration and Photosynthesis are both cellular processes in which organisms use energy. However, photosynthesis converts the light obtained from the sun and turns it into a chemical energy of sugar and oxygen. Cellular respiration is a biochemical process in which the energy is obtained from chemical bonds from food. They both seem the same since they are essential to life, but they are very different processes and not all living things use both to survive ("Difference Between Photosynthesis and Cellular Respiration", 2017). In this paper I will go over the different processes for photosynthesis and the processes for cellular respiration and how they are like each other and how they are essential to our everyday life.
The ANS is part of the peripheral nervous system, being split into sympathetic pathways, which prepare the body for action and parasympathetic pathways which prepare the body for rest. This regulates the functions of the body and some of the muscles automatically.
The contraction of a muscle is a complex process, requiring several molecules including ATP and Cl-, and certain regulatory mechanisms [1]. Myosin is motor protein that converts chemical bond energy from ATP into mechanical energy of motion [1]. Muscle contraction is also regulated by the amount of action potentials that the muscle receives [2]. A greater number of actions potentials are required to elicit more muscles fibers to contract thus increasing the contraction strength [2]. Studied indicate that the larger motor units, which were recruited at higher threshold forces, tended to have shorter contraction times than the smaller units [3]. The aims of the experiment were to reinforce the concept that many chemicals are required for skeletal muscle contraction to occur by using the rabbit muscle (Lepus curpaeums) [2]. In addition, the experiment was an opportunity to measure the strength of contraction and to observe the number of motor units that need to be recruited to maintain a constant force as the muscles begin to fatigue [2]. Hypothetically, the rabbit muscle fiber should contract most with ATP and salt solution; and the amount of motor units involved would increase with a decreasing level of force applied until fatigue stage is reached.
for a cell to function as part of cellular respiration. ATP is needed to power
Cellular respiration is the method of breaking down organic molecules to release their stored energy. Plants and animals use cellular respiration to use energy. Aerobic respiration is the release of energy from glucose or another organic substrate in the presence of oxygen while anaerobic does not require oxygen. Cellular respiration takes place in the mitochondrion. The three phases of cellular respiration are glycolysis (fermentation), krebs cycle, and the electron transport chain. Carbon dioxide and water are products of the series of reactions involved in cellular respiration. Fermentation is one catabolic process that is a degradation of sugars that occurs without the use of oxygen (Campbell and Reece, 2008). These pathways help generate energy to fuel thousands of chemical tasks in a cell. Fermentation by yeast is used to make beer, wine and bake bread. This process is summarized by:
According to our text, Campbell Essential Biology with Physiology, 2010, pg. 78. 94. Cellular respiration is stated as “The aerobic harvesting of energy from food molecules; the energy-releasing chemical breakdown of food molecules, such as glucose, and the storage of potential energy in a form that cells can use to perform work; involves glycolysis, the citric acid cycle, the electron transport chain, and chemiosmosis”.
There are many enzyme-catalyzed reactions that occur in cells through control mechanisms, which keep humans in chemical balance. There are two systems that have a major responsibility for regulating body chemistry known as the endocrine system and nervous system. The endocrine system depends on chemical messengers that flow in the bloodstream known as hormones. Hormones travel to target cells, where they connect with receptors that initiate chemical changes within cells. The nervous system depends on neurotransmitters that are electrical impulses in nerve cells activated by its own chemical messengers. The nervous system counts on a much faster means of circulation. This cycle is what allows drugs to work so well, because they mimic the crucial role of hormones and neurotransmitters in the function of the human body.