Bacteria - WordPress.com

... How do bacteria get food, get energy, and reproduce?  Obtaining food:  Autotrophs using photosynthesis or chemosynthesis  Heterotrophs consume other organisms & often serve as decomposers in the environment  Reproduction  Binary fission: asexual reproduction in which one bacteria divides to fo ...

Science, 2nd 9 weeks

... I can analyze, explain, and illustrate the cycle of carbon from living things to the environment, back to living things (including the processes of photosynthesis and respiration). I can analyze, explain and illustrate the cycle of oxygen from living things to the environment, back to living things ...

Osmosis and diffusion webquest

... After salt (in reality there would be many Na+ and Cl- ions) is added, how do the water molecules move across the membrane? Is there an overall direction of movement (where do most of the molecules end up?) ...

Experiment - 11 Binary fission (Amoeba) Budding (Yeast)

... other of budding in yeast. He was asked to determine any one difference in the nucleus of the two. One such difference is (a) presence of single nucleus each in amoeba, yeast cell and its attatched bud. (b) presence of two distinct nuclei in amoeba. (c) presence of two nuclei in a centrally construc ...

Single-Celled Organisms

... • http://micro.magnet.fsu.edu/moviegallery/p ondscum/protozoa/euglena/rostrifera/t1/ro strifera06.html ...

Cell Organelles and Functions

... • They can live without oxygen • Some can even make their own food ...

Plant Structure and Function

... various organelles, but throughout this unit we are going to relate the structure of what we study to its function. Let us consider the example of glucose and fructose mentioned in the introduction of the unit. Both sugars contain exactly the same kinds and number of atoms (C6H12O6), but the atoms a ...

Biology – Module 2 – Patterns in Nature

... Roots are the structures in plants that absorb water and other inorganic minerals from the Earth. These structures have a significant surface area which allows water and inorganic mineral salts to be absorbed efficiently. The epidermis is the outermost layer of the plants organs and it is through th ...

Meiosis/Mitosis Webquest

... of meiosis. 1. At the start of this example how many chromosomes are in the cell? 2. What happens in the “S” phase to the chromosomes? 3. If a chromosome replicates but remains attached does it count as one or two chromosomes? 4. What happens to the chromosomes at the end of prophase 1 that is diffe ...

Internal Membrane System Division II By Ann, Alex W., Alex O., and

... ● in plants and animals(much smaller in animals) ● membrane-enclosed fluid filled sac ● main functions: ○ make plants rigid by using water to develop hydrostatic pressure ○ store nutrient and non-nutrient chemicals ○ processing and storage of waste products ○ help in cell elongation ...

B2 Additional Biology - Flintshire County Council

... Along the transect, place your quadrat Count the no. of species present, and the no. of individuals of each species Repeat steps along another transect line ...

Short-range control of cell differentiation in the Arabidopsis root

... observed in wild-type roots (Fig. 1f, arrow; Table 1). The QC thus controls the differentiation state of columella initials in the absence of cell division. These results show that columella cell division is not a prerequisite for inhibition of differentiation (Fig. 2, model 2). To determine whether ...

Multiple Choice Review – Eukaryotes and Gene Expression

... a. Contain one or more chromosomes, ribosomes, have a cell wall and a cell membrane. b. Contain cell organelles, ribosomes, vacuoles, and have a cell membrane. c. Contain one or more chromosomes, ribosomes, cytoplasm and a cell membrane. d. Contain circular DNA, lysosomes, ribosomes, and have a cell ...

Millionaire Cells 2

... Template by Bill Arcuri, WCSD ...

Chapter 4: Characteristics of Prokaryotic and Eukaryotic Cells

... • The area between the cytoplasmic membrane and the plasma membrane in gram-negative bacteria • Active area of cell metabolism • Contains the cell wall, digestive enzymes and transport proteins • Gram-positive bacteria lack both an OM and a periplasmic space Distinguishing Bacteria by Cell Walls • G ...

133 Cell Walls of Wood, Composition, Structure and a few

... new cells the cell wall is thin and not very rigid. This allows the young cell to grow. This first cell wall of these growing cells is called the primary cell wall. When the cell is fully grown, it may retain its primary wall, sometimes thickening it, or it may deposit new layers of a different mate ...

June - ANU

... functioning properly, however, it’s still not known exactly how much function remains. The result is that cells tend to be less well shaped than normal plants. For example, in plants with the mutated gene, growth is normal at 21 degrees C but cells start to lose their shape definition if grown at 31 ...

Reece9e_Lecture_C06

... Cell structure and function can by studied by cell fractionation, a technique that takes cells apart and separates major organelles and other subcellular structures from one another. ○ A centrifuge spins test tubes holding mixtures of disrupted cells at various speeds. ○ The resulting forces cause a ...

bovine_tuberculosis_3_pathogenesis

... macrophages acquire an increased capacity to kill the intracellular bacilli. In the centre of these cellmediated immune responses are lymphocytes, which release a range of cytokines, among which interferon gamma plays a leading role, that attract, immobilize and activate additional blood-borne monon ...

Neural stem cells in mammalian development

... Neural stem cells (NSCs) and their progeny in the developing forebrain. The NSCs (shown in blue) of the lateral ventricular wall change their shape and produce different progeny as the brain develops. They begin as neuroepithelial cells and transform into radial glial cells, which mature into astroc ...

3.1 Discovery of cells

... system. These organs and tissues are co-ordinated in the organisms. ...

Cell Transport: Moving molecules in and out of the cell

... AGAINST the gradient (remember that ions can use facilitated diffusion with the gradient) ...

Answers to End-of-Chapter Questions – Brooker et al ARIS site

... most other organisms, and for periods of time that are not tolerated by other organisms. Investigators wanted to know why D. radiodurans was so resistant to radiation. 2. What hypothesis did Daly and associates develop to explain radiation resistance in D. radiodurans? Answer: Daly and associates su ...

Transport in Vascular Plants

... 2) Cohesion-Adhesion: cohesion of H2O molecules to each other & adhesion to cell walls pulls xylem sap ↑ ...

APPLICATION NOTE

... autophagy via standard flow cytometry. However, flow cytometers remain relatively expensive and require a considerable amount of maintenance. Previously, image-based cytometry has been shown to perform automated fluorescence-based cellular analysis comparable to flow cytometry. In this study, we dev ...

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Amitosis

Amitosis (a- + mitosis) is absence of mitosis, the usual form of cell division in the cells of eukaryotes. There are several senses in which eukaryotic cells can be amitotic. One refers to capability for non-mitotic division and the other refers to lack of capability for division. In one sense of the word, which is now mostly obsolete, amitosis is cell division in eukaryotic cells that happens without the usual features of mitosis as seen on microscopy, namely, without nuclear envelope breakdown and without formation of mitotic spindle and condensed chromosomes as far as microscopy can detect. However, most examples of cell division formerly thought to belong to this supposedly ""non-mitotic"" class, such as the division of unicellular eukaryotes, are today recognized as belonging to a class of mitosis called closed mitosis. A spectrum of mitotic activity can be categorized as open, semi-closed, and closed mitosis, depending on the fate of the nuclear envelope. An exception is the division of ciliate macronucleus, which is not mitotic, and the reference to this process as amitosis may be the only legitimate use of the ""non-mitotic division"" sense of the term today. In animals and plants which normally have open mitosis, the microscopic picture described in the 19th century as amitosis most likely corresponded to apoptosis, a process of programmed cell death associated with fragmentation of the nucleus and cytoplasm. Relatedly, even in the late 19th century cytologists mentioned that in larger life forms, amitosis is a ""forerunner of degeneration"".Another sense of amitotic refers to cells of certain tissues that are usually no longer capable of mitosis once the organism has matured into adulthood. In humans this is true of various muscle and nerve tissue types; if the existing ones are damaged, they cannot be replaced with new ones of equal capability. For example, cardiac muscle destroyed by heart attack and nerves destroyed by piercing trauma usually cannot regenerate. In contrast, skin cells are capable of mitosis throughout adulthood; old skin cells that die and slough off are replaced with new ones. Human liver tissue also has a sort of dormant regenerative ability; it is usually not needed or expressed but can be elicited if needed.

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Amitosis