Chapter 7A- Cellular Respiration: Glycolysis - TJ

... The below figure introduces the 3 stages of cellular respiration. Label the diagram. Include electron transport chain, pyruvate, mitochondrion, citric acid cycle, glycolysis, cytoplasm, glucose, 2 NADH, 6 NADH, 2 FADH2, 2 ATP, 34 ATP, 38 ATP. ...

The Biosphere

... • Producers – 1st trophic level • Consumers – 2nd, 3rd, or higher trophic levels ...

Bacteria - Ector County ISD

... – recycle dead organisms releasing their nutrients back to the environment for use by other organisms – SPONCH ...

Bacteria ppt from 3/11/14

... – recycle dead organisms releasing their nutrients back to the environment for use by other organisms – SPONCH ...

Lecture Test 3 Review Sheet Chapter 6 Be able to define energy

... Understand the first and second laws of thermodynamics, and what the term entropy means. Know the definition of metabolism, anabolism, and catabolism. Know the difference between and endergonic and exergonic reaction. Know what ATP is, and how it is used to drive endergonic reactions using “coupled” ...

CITRIC ACID CYCLE

... central importance in all living cells that utilize oxygen as part of cellular respiration. In aerobic organisms, the citric acid cycle is part of a metabolic pathway involved in the chemical conversion of carbohydrates, fats and proteins into carbon dioxide and water to generate a form of usable en ...

ch05_sec1

... floor, where photosynthesis cannot occur. • The producers in this environment are bacteria that use hydrogen sulfide present in the water. • Other underwater organisms eat the bacteria or the organisms that eat the bacteria. ...

Introduction - Cedar Crest College

... Photosynthesis occurs in the chloroplasts of green plant cells and, like metabolism, is a result of many steps—not just a single step. ...

Chapter 8 Section 3 Notes

... The plant uses the sugars produced by the Calvin cycle to meet its energy needs and to build macromolecules needed for growth and development. When other organisms eat plants, they can use the energy and raw materials stored in these compounds. ...

Matter: Forms, Structure, and Quality.

... down organic waste, dead animal. Plant litter and garbage. Whether dead or alive organisms are potential (standard) sources of food for other organisms. Food Chain-Series of organisms in which each eats or decomposes the preceding one ...

3 Energy from respiration

... body……… In the course of respiration, ……… is broken down to ………and ……… . If oxygen is used for this process, the respiration is called ……… . If oxygen is not used in the process, the respiration is called ……... Each stage of respiration is speeded up by a particular ……... cells, food, carbon dioxide ...

Biotransformation Xenobiotic metabolism

...  Donor molecules include GSH, FAD, NAD(P)H  Oxygen removal ...

Electron Transport and ATP Synthesis

... Numerous Redox Substrates • O2: high “reduction potential” • Substrates – Organic cofactors – Metals (iron/sulfur clusters) – cytochromes ...

Formulae/ Equations homework - St Peter the Apostle High School

... Which of the following pairs of elements would form a compound with a formula X2Y3? X is a metal and Y is a non-metal. ...

Cellular Respiration and Photosynthesis Notes

... ET: Create the vocabulary list: ...

Problem Set 5 (Due February 25th) 1. Show how glucose can be

... 2. What role does the conversion of an aldose to a ketose play in the net glycolytic reaction scheme? This is necessary to prepare the hexose for the reverse aldol condensation. 3. Some organisms replenish the NAD+ pool using alcoholic fermentation which yields ethanol and carbon dioxide. This is a ...

Slide 1

... Mutualism: is a form of symbiosis where both organisms benefit from the association. Note: Mutualism increases the number of both organisms involved in the relationship. ...

U2-D3-03 – PO and Kreb

... The two molecules of acetyl-CoA enter the Krebs cycle where additional free energy transfers occur. The two molecules of NADH proceed to stage 4 (electron transport and chemiosmosis) to produce ATP by oxidative phosphorylation. The two CO 2 molecules produced during pyruvate oxidation diffuse out of ...

Latest research findings Developing the Day

... • Cause: Earth rotation with associated change of sunlight creating day and night time with brightness, darkness and different magnetism • Differences in the environment of living systems ...

Hi Linda - Greeley Schools

... dioxide, and utilizing energy, e.g. light energy from the sun. Photosynthetic organisms such as plants are an example of an autotroph. In a food chain, they are also referred to as the producers. The heterotrophs are those organisms that rely on other organisms to obtain organic matter because they ...

20141104103322

... NAD⁺ +2 electrons + H⁺ ion = NADH ...

Microbes are the Foundation of Life

... give off special digestive enzymes to ...

Biomes and ecosystems presentation

... break down carbohydrates and other organic compounds in their cells to obtain the energy they need.  This is usually done through aerobic respiration. ...

CfE Higher Chemistry Homework 3.5

... To avoid these contaminants, hydrogen sulfide can be made by reacting aluminium sulfide with water. Hydrogen sulfide and aluminium hydroxide are produced. Write a balanced chemical equation for the production of hydrogen sulfide from aluminium sulfide and water. ...

Cellular Respiration

... mitochondrial matrix; pyruvate into carbon dioxide • 3.Electron Transport Chain: inner membrane of mitochondrion; electrons passed to oxygen ...

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Microbial metabolism

Microbial metabolism is the means by which a microbe obtains the energy and nutrients (e.g. carbon) it needs to live and reproduce. Microbes use many different types of metabolic strategies and species can often be differentiated from each other based on metabolic characteristics. The specific metabolic properties of a microbe are the major factors in determining that microbe’s ecological niche, and often allow for that microbe to be useful in industrial processes or responsible for biogeochemical cycles.== Types of microbial metabolism ==All microbial metabolisms can be arranged according to three principles:1. How the organism obtains carbon for synthesising cell mass: autotrophic – carbon is obtained from carbon dioxide (CO2) heterotrophic – carbon is obtained from organic compounds mixotrophic – carbon is obtained from both organic compounds and by fixing carbon dioxide2. How the organism obtains reducing equivalents used either in energy conservation or in biosynthetic reactions: lithotrophic – reducing equivalents are obtained from inorganic compounds organotrophic – reducing equivalents are obtained from organic compounds3. How the organism obtains energy for living and growing: chemotrophic – energy is obtained from external chemical compounds phototrophic – energy is obtained from lightIn practice, these terms are almost freely combined. Typical examples are as follows: chemolithoautotrophs obtain energy from the oxidation of inorganic compounds and carbon from the fixation of carbon dioxide. Examples: Nitrifying bacteria, Sulfur-oxidizing bacteria, Iron-oxidizing bacteria, Knallgas-bacteria photolithoautotrophs obtain energy from light and carbon from the fixation of carbon dioxide, using reducing equivalents from inorganic compounds. Examples: Cyanobacteria (water (H2O) as reducing equivalent donor), Chlorobiaceae, Chromatiaceae (hydrogen sulfide (H2S) as reducing equivalent donor), Chloroflexus (hydrogen (H2) as reducing equivalent donor) chemolithoheterotrophs obtain energy from the oxidation of inorganic compounds, but cannot fix carbon dioxide (CO2). Examples: some Thiobacilus, some Beggiatoa, some Nitrobacter spp., Wolinella (with H2 as reducing equivalent donor), some Knallgas-bacteria, some sulfate-reducing bacteria chemoorganoheterotrophs obtain energy, carbon, and reducing equivalents for biosynthetic reactions from organic compounds. Examples: most bacteria, e. g. Escherichia coli, Bacillus spp., Actinobacteria photoorganoheterotrophs obtain energy from light, carbon and reducing equivalents for biosynthetic reactions from organic compounds. Some species are strictly heterotrophic, many others can also fix carbon dioxide and are mixotrophic. Examples: Rhodobacter, Rhodopseudomonas, Rhodospirillum, Rhodomicrobium, Rhodocyclus, Heliobacterium, Chloroflexus (alternatively to photolithoautotrophy with hydrogen)

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Microbial metabolism