Introduction
The substrates of glycerate kinase are ATP and D-glycerate and the products are ADP and 3-phospho-D-glycerate. This enzyme belongs to the family of transferases.1 Other common names include: glycerate kinase (phosphorylating), D-glycerate 3-kinase, D-glycerate kinase, glycerate-3-kinase, GK, D-glyceric acid kinase, and ATP: D-glycerate 2-phosphotransferase. 1 This enzyme participates in 3 metabolic pathways: serine/glycine/threonine metabolism, glycerolipid metabolism, and glyoxylate-dicarboxylate metabolism.1
Glycerate kinase is active in photosynthesis.2 Photosynthesis converts CO2 to useable energy.2 There are two different types of photosynthesis: light dependent, which harvests energy from sunlight and the electron transport chain to make ATP and NADPH.2 The second type is light independent, which does not require sunlight; it uses the Calvin Cycle to convert CO2 to ATP and NADPH.2
Glycerate kinase is also an intermediate in glycolysis. Class II glycerate kinase’s form glycerate 2-phosphate (2PGA).3 2PGA is an intermediate of glycolysis as it is a substrate for phosphoglycerate mutase and enolase.4 Phosphoglycerate mutase converts 3-phospho-D-glycerate (3PGA) to 2PGA and enolase converts phosphoenolypyruvate (PEP) to 2PGA.4 Photorespiratory Regulation
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The presence of atmospheric oxygen triggers the oxygenation of RubP, leading to the synthesis of equimolar amounts of 3PGA and 2PG. The ratio of 3PGA to 3PG synthesis is determined by both intrinsic properties of Rubisco and by the CO2:O2 ratio in the enzymes microenvironment. The photorespiratory C2 cycle acts as an ancillary metabolic pathway that compensates for the futile withdraw of RubP from the C3 cycle under aerobic conditions by serving as a carbon recovery system reconverting 2PG to
Photosynthesis and cell respiration are some of the two most important biological processes that organisms go through. Photosynthesis is the biological process plants undergo to convert light energy into chemical energy. In chloroplasts the chlorophyll act as catalysts for this process. The process uses carbon dioxide (CO2) and Water (H2O) in order to produce glucose (C6H1206) and oxygen (02). Thus, it is read as 6CO2 + 6H2O —> C6H12O6 + 6O2. Photosynthesis is split into two different processes. The first process is light Dependent meaning i uses energy being absorbed to break down and molecules at a rapid photosynthetic rate. The second process is Light Independent meaning it uses ATP and NADH absorbed during when light was present to breakdown glucose instead. Therefore, Healthy plants are green because Chlorophyll absorbs red and blue light, but reflects green light signifying stored light.Some Anaerobic bacteria undergo photosynthesis meaning it can’t grow in oxygen and uses Carbon Dioxide and other substances like hydrogen sulfide to photosynthesis. In general all plants need Carbon Dioxide. (Ensminger, 2014)
In contrast, there are four metabolic stages happened in cellular respiration, which are the glycolysis, the citric acid cycle, and the oxidative phosphorylation. Glycolysis occurs in the cytoplasm, in which catabolism is begun by breaking down glucose into two molecules of pyruvate. Two molecules of ATP are produced too. Some of they either enter the citric acid cycle (Krebs cycle) or the electron transport chain, or go into lactic acid cycle if there is not enough oxygen, which produces lactic acid. The citric acid cycle occurs in the mitochondrial matrix, which completes the breakdown of glucose by oxidizing a derivative of pyruvate into carbon dioxide. The citric acid cycle produced some more ATPs and other molecules called NADPH and FADPH. After this, electrons are passed to the electron transport chain through
No, glycolysis does not require the presence of oxygen. It occurs in the cytoplasm of all cells. a single glucose molecule in glycolysis produces a total of 2 molecules of pyruvic acid, 2 molecules of ATP, 2 molecules of NADH and 2 molecules of water. More ATP molecules are generated in step 7 and 2 more in step 10. This gives a total of 4 ATP molecules produced total with a final total of 2 ATP molecules remaining.
Oxidation of NADH and FADH2to H2O (and NAD or FAD). Generates H ion concentration gradient and therefore ATP.
One of the most significant reactions in Glycolysis is reaction one which involves the phosphorylation of glucose to form glucose-6-phosphate. Through the transfer of the hydrolysis of ATP, this supplies energy for the reaction and makes it essentially irreversible, having a negative free energy change, which allows for a spontaneous reaction in cells. Although the preparatory phase is energy consuming and uses up 2 ATP, the pay off phase synthesizes 4 molecules of ATP, with the transfer of 4e- via 2 hydride ions to 2 molecules of NAD+. Therefore, a net gain of 2 ATP is achieved through the glycolytic pathway alone. Following the glycolytic pathway, due to the absence of oxygen, as oxygen cannot be supplied fast enough to undergo aerobic respiration, the athlete will instead, undergo lactic acid fermentation. Lactic acid fermentation involves pyruvate that is formed from the glycolytic pathway to be reduced to lactate, with the aid of the enzyme, lactate dehydrogenase, while the coenzyme Nicotinamide Adenine Dinucleotide (NADH) is oxidised to NAD+. The product NAD+ then re-enters the glycolytic pathway in order to produce 2 ATP. This process of lactic acid fermentation produces 2 ATP for each cycle, and thus, rapidly supplies the body with a small amount of energy. However, with the buildup of lactic acid in the body, the athlete will eventually encounter the feeling of discomfort as this accumulation of lactate causes the body to
A). The anaerobic metabolism of glucose to pyruvate is called glycolysis. This sequence of reactions will generate two molecules of pyruvate for every one molecule of glucose. This metabolism is anaerobic, which means that it does not require oxygen to be completed. The first phase of the process of glycolysis is called the preparatory phase. The entire process of glycolysis is started once glucose is trapped inside
Cellular respiration involves glycolysis, the Krebs cycle, and the electron transport chain. Glycolysis is a
The process of photosynthesis, by which light energy is used to convert inorganic compounds into organic substances with the release of oxygen, may be the most important biological event sustaining life (Keir et al. 2017). In the light-dependent reactions, the chloroplasts of a plant use the pigment chlorophyll to convert light energy into chemical energy. This energy is used to split water and produce oxygen (Eller et al. 2015). The energy is later used in the light independent reactions, where carbon dioxide (CO2) undergoes carbon fixation with the aid of enzyme rubisco, because it catalyses both carboxylation and oxygenation reactions and most of responses of photosynthesis to light, CO2, and temperature (John Evans 2013).
“Photosynthesis is a biochemical process for building carbohydrates using energy from sunlight and carbon dioxide taken from the air”, (Morris, J. (2016) Biology How Life Works. New York, NY.). It is a system that uses plants and specific algae to synthesize molecules from both water and carbon dioxide. The oxygen we breathe and the food we eat is fueled by photosynthesis because it is an energy source. Photosynthesis occurs in eukaryotic and prokaryotic organisms and some examples are humans, trees, and plants. Biological systems use photosynthesis as an energy source. Where there is a source of sunlight, there is a chance
Then, a phosphate is added to one of the the three carbon molecules, in addition to the reduction of NAD⁺ to NADH via triosephosphate dehydrogenase. In the first ATP generating step, a phosphate is transferred form the product of the last reaction to ADP via phosphoglycerate kinase. The next step switches the position of a phosphate group to yield 2-phosphoglycerate. Enolase then catalyzes a dehydration reaction to yield phophoenolpyruvate. The last energy producing step of glycolysis transfers a phosphate group to ADP and in the process, forms
Glycolysis is followed by the Krebs cycle, however, this stage does require oxygen and takes place in the mitochondria. During the Krebs cycle, pyuvic acid is broken down into carbon dioxide in a series of energy-extracting reactions. This begins when pyruvic acid produced by glycolysis enters the mitochondria. As the cycle continues, citric acid is broken down into a 4-carbon molecule and more carbon dioxide is released. Then, high-energy electrons are passed to electron carriers and taken to the electron transport chain. All this produces 2 ATP, 6 NADH, 2 FADH, and 4 CO2 molecules.
Background Research: Cellular Respiration is used by the cells to make ATP, by releasing chemical energy from sugars and other carbon based molecules. There are 3 stages to Cellular Respiration, Glycolysis, Krebs Cycle, and the Electron Transport Chain. The inputs of Glycolysis are 2 ATP’s, a Glucose molecule, and a Pyruvate. The inputs for the Krebs Cycle are oxygen, and. In animals, energy is consumed by eating food. In that food they eat, Glucose is found and broken down by the process of cellular respiration, which then converts into energy known as ATP. When there is a lot of ATP and Glucose, the liver converts it into glycogen.
Uniquely, glycolysis is both anaerobic and aerobic. The end product pyruvate, from glycolysis, is anabolized to lactic acid when there is a need for energy without an adequate supply of oxygen available. This last step or reaction enables glycolysis to continue producing ATP without the need for oxygen, which is why it is called the anaerobic energy system (Fink, 2009).
of glucose has 6 carbons), 2 ATP, 8 NADH and 2 FADH are produced. NADH and FADH
To metabolic pathways involved in photosynthesis are light reaction and dark reaction. The first stage of the photosynthetic system is the light-dependent reaction, which converts solar energy into chemical energy. Light absorbed by chlorophyll or other photosynthetic pigments is used to drive a transfer of electrons and hydrogen from water to and acceptor called NADP , reducing it to the form of NADPH by adding a pair of electrons and a single proton. The water or some other donor molecule is split in the process. The light reaction also generates ADP, a process called photophosphorylation. ATP is a versatile source of chemical energy used in most biological processes. The light reaction produces no carbohydrates such as sugars.