16. What do the mitochondria of parabasalids and diplomonads have in common? Describe these mitochondria and explain how the organisms conduct cellular respiration.
Question
16. The mitochondria of parabasalids and diplomonads have mitochondria that perform anaerobic respiration as they lack electron transport chain . These mitochondria are sometimes known as mitosomes. As these organisms do not have well-developed mitochondria, they are not able to perform electron transport chain and derive ATP only be glycolysis process that generate very less amount of ATP.
16. What do the mitochondria of parabasalids and diplomonads have in common? Describe these mitochondria and...
place the characteristics into the appropriate category of
diplomonads only, parabasalids only, or common to both
Diplomonads and Parabasalids Place the characteristics into the appropriate category of Diplomonads only, Parabasalids only, or common to both Diplomonads Only Parabasalids Only Common to Both Some digest cellulose May contain mitochondrial genes Possess flagella Move with undulating membrane Have two nuclei Lack mitochondria
Cellular respiration takes place largely within the mitochondria and requires a lot of enzymes that are produced in the cytosol. Explain, briefly, how these cellular respiration enzymes will end up in the mitochondria
If the membrane of the mitochondria became permeable to hydrogen ions, how would this affect cellular respiration? Explain.
how to do these two question?
Describe the structure and function of an ATP molecule and explain why it is so valuable to a cell. Include a diagram or sketch ( 16) Identify and explain two ways in which the electron transport system in photosynthesis and cellular respiration are different ( T 74)
5. What are the internal structures of the mitochondria and what parts of cellular respiration take place in each part? (inner/outer membranes, cristae, matrix, intermembrane space)
Ch. 9 11) What are the four steps of cellular respiration? What are the initial reactants and final products from each of these steps (include NADH and FADH2)? Where do they occur in the cell/mitochondria? 12) Why is the pyruvate processing step necessary? Why not go straight to the citric acid cycle? 13) What is homeostasis? How does cellular respiration play a role in anabolic reactions (think intermediates)? 14) How are the first three steps of cellular respiration regulated? 15)...
36. Which of these groups of taxa are not close-relatives? a. Diplomonads & Parabasalids c. Red algae & Green algae b. Spirochetes and Amoebas d. Apicomplexans & Ciliates 57. Which form a monophyletic group (clade)? a. Prokaryotes b. Green Algae c. Flagellates d. Ciliates 58. Which type of protozoans are not able to move (nonmotile)? a. apicomplexans b. ciliates c. flagellates d. amoebas 59. are protists formed by endosymbiosis between a heterotrophic eukaryote and a red algae. a. Rhizarians/Amoebozoans c....
tic of mitochondria? a) They have two membranes. b) They are the site of oxidative cellular respiration c) They carry out glycolysis )They contain DNA and ntbosomes. e) Their materal inside the mitochondrion is actually cytoplasm. TTCCGTGT,b) ACCUAGT, e) UAABTTGT 5,) rthe oowing RN quence, uuGGcuUCA AACCGAAGT, e) None of these. answer the question and give a why the circled answer wasn't correct
You will be assigned a specific cellular respiration inhibitor for this discussion (Cyanide is my cellular respiration). As you know by now, cellular respiration is essential for many organisms including plants, animals, and many single-celled organisms. What happens when a molecule interrupts cellular respiration? How might it do so? You should spend approximately 3 hours on this assignment. Instructions Answer the following questions in a few paragraphs. What is the basic purpose of cellular respiration? What are the reactants and...
What is the best current theory for where mitochondria and chloroplasts come from? Explain. a. they are living organisms that have entered other cells. b. they are proteins that have evolved into organelles. c. they are phospholipid membranes that have evolved into organelles.