Role of Bioenergetics in Disease and use of Small Molecule Therapeutics
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Role of Bioenergetics in Disease and use of Small Molecule Therapeutics
Introduction
The study of bioenergetics includes and not limited to study of biological membranes incurred in energy conversion and transfer. In particular, the study concentrates on structures acquired using X-ray craystallography, molecular mechanisms of the photosynthesis processes, bacteria respiration, mitochondrial, transport, motility and oxidative phosphorylation. Furthermore, areas of structural biology, spectroscopy, molecular modelling and biophysics of the system applications are not left out while studying the specific chemical process of a disease. Bioenergetics further spans in the biology of mitochondrial that embodies biomedicine, features of mitochondrial disorders and energy metabolism (Zheng et-al, 2010, p.519). Alzheimer’s disease, Parkinson’s disease, aging, cancer and diabetes are among the well-known neurodegenerative illnesses studied under bioenergetics and use of small molecule therapeutics.
Small molecule therapeutics is one of the scientific techniques designed to help visualize the magnanimity of genomics data which is prodigious in the process of making drugs. When this technique is used, genomics data can yield random number of proteins produced in a disease tissue. By understanding the role played by bioenergetics in a particular
gluconeogenesis slow down in which release of glucose to the blood stream is also slowed down
Cellular respiration is a very important process that occurs in all living organisms. In this process, chemical energy is obtained by the organisms’ food source to be turned into ATP or adenosine triphosphate, a form of energy that is easily utilized by the organisms’ bodies to carry out certain bodily functions (Largen, 2008, p.41). The chemical formula for cellular respiration is C6H12O6+6O2+6H2O→6CO2+12H2O+energy. This simply means that, with the use of glucose, six molecules of oxygen, and six molecules of water, an output of six carbon dioxide molecules, twelve molecules of water, and energy (ATP) is produced (Khan, 2010). Glucose is especially important in this process, given that it acts as a fuel in cellular respiration. (Cellular Respiration: Introduction, n.d.). In the biosphere, there is also a vast
Each mitochondrion has a double-layered membrane like the cell membrane, however the inner layer is folder which produces ‘shelves’ which are known as cristae, this is where the end stages of glucose oxidation are located. The energy that has been released is stored until required by a ‘chemical battery’ called adenosine triphosphate.
Hello, my name is Audrey and welcome to my presentation on the chemistry of photosynthesis and cellular respiration.
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.
During that time we learned various steps and methods to purifying protein. We segwayed into enzymes and their ability to catalyze reactions by lowering the activation energy. We also learned the different classifications that specific enzymes depending on the reactions they catalyze. For example, enzymes that are involved in catalyzing hydrolysis reactions are known as hydrolases. Lastly, we looked at polysaccharides for short-term energy storage and their interactions through glycosidic bondage. Nucleotides were also mentioned and their involvement in DNA and RNA. Concluding the course, we observed lipids and their involvement with long-term energy storage. With all that we have learned, I now reflect and appraise the role that biochemistry plays in my everyday life as well as from a global point of view.
The discovery from the Scripps Research Institute in Florida shows promising results in tackling down the cause of Parkinson’s, and their outcomes led to a funding by the National Institutional Disorders and Stroke Research (NINDS). Research staff within the campus discovers that many diseases that relate in twisting a protein from its original structure will result in a cellular death but it isn’t due to the deformed shape. According to the article “Scripps Florida Scientists' 'Mad Cow' Discovery” (2015), one primal cause that leads to Parkinson’s is the lack of “NAD+” which later prohibits the proper energy function of the mitochondria. Researchers further delved into the study to find out this is preventable, by providing the misshaped protein
A. SIGNIFICANCE. Our goal is to screen chemical libraries to identify compounds that modulate mitochondrial transport in hippocampal and cortical neurons. This study is significant in four ways: (1) There is an urgent need to develop CNS (Central Nervous System) active drugs. CNS disorders are not only staggeringly complex but are poorly treated diseases (Palmer and Stephenson, 2005). In the United States alone the annual cost for stroke, depression, Schizophrenia and Alzheimer’s disease are currently estimated to be over $250 billion annually (Pangalos et al., 2007). Despite the advances in translational medicine and pharmaceutical research little progress has been made in developing CNS therapeutics. Improving CNS drug discovery efforts is an urgent goal as an estimated 1.5 billion people suffer from CNS-related diseases worldwide. Unfortunately only a handful of new drugs have been brought to the market with very few in the pharmaceutical pipeline (Kissinger, 2011; Schoepp, 2011; Abbot, 2011). The majority of pharmaceutical companies have recently announced a shift from supporting internal drug discovery efforts in favor of academic and government partnerships (Schoepp, 2011). At Scripps Florida we have close interaction of state of the art high throughput small molecule screening and cutting-edge neuroscience research. Thus we are in a unique position to address the challenges in developing CNS therapeutics. (2) Mitochondrial dysfunction is part of the pathophysiology of
Explain the role of RNA polymerase inhibition in causing the poisonous effect of the death cap mushroom.
There are hundreds of neurodegenerative diseases (NDD) and the etiology for most of the random conditions remain a universal mystery (Nieoullon 2011). A deterioration of specific functions of the neuron cells of the central nervous system is the most common characteristic of NDD. Neurons are responsible for transmitting essential information to other nerve, muscle and glandular cells (Przedborksi, Jackson-Lewis 2003). Emerging research has recently identified mitochondrial dysfunction as a recurrent elemental link in numerous neurodegenerative disorders (Ghano,
The mitochondria has been known as the powerhouse of the cell. What does that even mean? Well, what it means that the mitochondria does all of the cell energy conversion. It takes nutrients from the cell and transforms it into viable ATP. ATP, molecule adenosine triphosphate, is the energy that cells can use. The process in turning nutrients into ATP is called ATP Synthase. The first part of ATP synthase is an ending of cellular respiration. The mitochondria plays a small but large role in the cell. The structure of the mitochondria plays a huge part of cellular respiration. Mitochondrial structure has two membranes an inner and an outer. Inside the inner membrane you have the matrix and the cristae. The first part of cellular respiration is glycolysis, it is made outside of the mitochondria in a gel like fluid called the cytoplasm. Next, is the citric acid cycle, also known as the Krebs cycle, named after the German researcher Hans Krebs, goes in through the outer membrane. Enzyme Acetyl CoA enters and combines the two carbon groups with another four carbon groups. The result is six carbon molecules citrate, which are acidic. The next part in the Krebs cycle is that the hydrogen atoms are stripped and produce NADH molecules. The final Krebs step is; ADP is transferred to ATP the succinate is oxidized forming another four carbon molecule. The two hydrogen carbons react and their electrons transform from FAD to FADH2. The Krebs cycle makes only about 4 ATP and in the
In personalized medicine, advances in protein biology is not limited to preventive care. Advances can aid in curing diseases past development; the drug Kalydeco is proof of that. Through improvements in protein biology, scientist created the first drug addressing
Mitochondrion is an importance structure that lies in the cytoplasm area. Mitochondrion is the plural word for mitochondria, which is the key organelle that converts energy from one form to another. Mitochondria changes the chemical energy stored in food into compounds that are more convenient for the cell to use. The mitochondrion contains two special membranes. The outer membrane surrounds the organelle, and the inner membrane has many folds that increase the surface area of the mitochondrion.
Cellular respiration is a procedure that most living life forms experience to make and get chemical energy in the form of adenosine triphosphate (ATP). The energy is synthesized in three separate phases of cellular respiration: glycolysis, citrus extract cycle, and the electron transport chain. Glycolysis and the citric acid cycle are both anaerobic pathways because they do not bother with oxygen to form energy. The electron transport chain however, is aerobic due to its use of oxidative phosphorylation. Oxidative phosphorylation is the procedure in which ATP particles are created with the help of oxygen atoms (Campbell, 2009, p. 93). During which, organic food molecules are oxidized to synthesize ATP used to drive the metabolic reactions necessary to maintain the organism’s physical integrity and to support all its activities (Campbell, 2009, pp. 102-103).
In the metabolic reactions, oxidation-reduction reactions are very essential for ATP synthesis. The electrons removed in the oxidation are transferred to two major electron carrier enzymes. The electrons are transported through protein complexes in present in the inner mitochondrial membrane. The complexes contain attached chemical groups which are capable of accepting or donating one or more electrons. The protein complexes are known as the electron transfer system (ETS). The ETS allow distribution of the free energy between reduced coenzymes and the O2. The ETS is associated with proton (H+) pumping from the mitochondrial matrix to intermembrane space of the mitochondria.