DOCSLIB.ORG

Studies on the Mechanism of Circus Movement in Dissociated Embryonic Cells of a Teleost, Oryzias Latipes: Fine-Structural Observations

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Studies on the Mechanism of Circus Movement in Dissociated Embryonic Cells of a Teleost, Oryzias Latipes: Fine-Structural Observations J. Cell Sci. 22, I33-M7 (1976) 133 Printed in Great Britain STUDIES ON THE MECHANISM OF CIRCUS MOVEMENT IN DISSOCIATED EMBRYONIC CELLS OF A TELEOST, ORYZIAS LATIPES: FINE-STRUCTURAL OBSERVATIONS NOBORU FUJINAMI Laboratory of Developmental Biology, Zoological Institute, Faculty of Science, University of Kyoto, Sakyo-Ku, Kyoto bod, Japan SUMMARY The fine structure of lobopodia in dissociated embryonic cells of the freshwater fish, Orysias latipes, was observed with the electron microscope in order to understand the mechanism of the circus movements which they display. Dense material (granular or fibrillar) is present in the zone between the lobopodium and the endoplasm, as well as in the cortical layer around the cell circumference. The direction of lobopodial movement is related to the distribution of this dense material. The band between the lobopodium and the endoplasm is conspicuous and is connected to the cortical dense layer around the cell periphery at the advancing front of the lobopodium, while the dense material is usually almost absent beneath the cell membrane in the anterior region of the lobopodium. The band between lobopodium and endoplasm is blurred or disrupted near the hind end of the lobopodium, where the peripheral dense layer is well developed. In situ localization of actin/heavy meromyosin complexes in the cell showed that the dense material has actin-like properties. Cytochalasin B (05 /tg/ml) induced constriction of the neck of the bleb, shrinkage of the endoplasm, and herniation of the endoplasmic contents to the enlarged hemispherical bleb, and thus arrested the circus movement. On the basis of these results, an hypothesis concerning the mechanism of circus movement is proposed and discussed. INTRODUCTION Although the mechanism of cell motility has hitherto been investigated mainly in protozoa, knowledge of the motile mechanism of metazoan cells, such as leucocytes or cultured cells, is advancing in the light of recent biochemical and ultrastructural findings (Abercrombie, 1973). In the case of embryonic cells, their motile activity was described in detail in dissociated amphibian cells some thirty years ago (Holtfreter, 1946, 1947, 1948), but we still cannot elucidate its mechanism. Circus movement, which involves the pushing out of a hyaline pseudopodium and the propagation of this lobopodial bleb around the cell circumference, is one of the remarkable movements shown by isolated embryonic cells. This movement was also reported in vivo in deep cells of teleostean blastoderm (Trinkaus, 1973; Kageyama, 1976) and may be related, as Sirakami (1972) stated, to wave-like changes propagating in embryonic cell surfaces, such as surface contraction waves (Hara, 1971). Using a quantitative method for estimating the velocity of the movement (Sirakami, 134 N. Fujinami 1963; Satoh, Kageyama & Sirakami, 1976), circus movement in dissociated embryonic cells of a teleost, Oryzias latipes was reported in earlier papers on the general features of this type of movement (Fujinami & Kageyama, 1975) and its responses to various classes of biologically active agents (Fujinami, 1976). These studies suggest that similar mechanisms may be involved in circus movement and other motile activities such as hyaline cap formation of amoebae (Allen, 1973), peristaltic constrictions in barnacle eggs (Lewis, Chia & Schroeder, 1973), blebbing of the polar lobe in marine mud snail eggs (Conrad, 1973), and zeiosis of cultured cells (Ross, 1966; Price, 1967), supporting the view that circus movement may be regarded as a type of cell behaviour based on fundamental properties of the cell surface and the motile activities of the cell. The present study was undertaken to demonstrate the fine-structural features of cells showing circus movement, in order to understand the mechanism of this move- ment in embryonic teleostean cells. It was also interesting to see the effect of cyto- chalasin B, which causes rapid morphological changes in cells showing circus move- ment (Fujinami, 1976). The present study demonstrated remarkable changes in shape and ultrastructure of cells treated with cytochalasin B. MATERIALS AND METHODS Developing eggs of the orange-red variety of the cyprinodont fish, Oryzias latipes (Japanese Medaka), were used. The fertilized eggs, attached in masses to the abdomen of females, were collected each morning. The detailed procedures employed in obtaining a suspension of isolated cells from the early gastrula have been previously described (Fujinami & Kageyama, 1975). Briefly, eggs were dissected and blastoderms were mechanically dissociated into their constituent cells with watchmaker's forceps in Ca2+-free Yamamoto solution. Cell suspensions were washed and transferred to 35-mm plastic Petri dishes (Falcon Plastics). After the cells had settled and were loosely attached to the substratum, and were showing circus movement, the supernatant fluid was decanted and then fixative, described below, was gently poured into the dishes. For cytochalasin B treatment, cells were immersed in Ca2+-free Yamamoto solution containing 0-5 /<g/ml cytochalasin B (in 0025 % dimethyl sulphoxide) for 5 or 10 min at room temperature before fixation. After several attempts to obtain improved fixation of the ultrastructure of embryonic cells, simultaneous fixation with glutaraldehyde and osmium tetroxide was employed according to Hirsh & Fedorko (1968), with some modifications. Cells placed in the dishes were fixed in situ at 4 °C or room temperature in a freshly-made cold mixture of 2#5 % glutaraldehyde and 1 % 3 osmium tetroxide in 005 M phosphate buffer, pH 7-4, containing io~ M CaCl2 for 30 min. The fixed cells were rinsed with distilled water and prestained in 05 % uranyl acetate solution (dissolved in 50 % ethanol) for 30 min. Dehydration was carried out through a graded series of ethanol solutions and followed by Epon embedding. After Epon polymerization in the Petri dishes was completed, selected bits of flat-embedded dishes containing the fixed cells, trimmed and remounted on Epon blocks, were sectioned parallel (or perpendicular) to the plastic surfaces. Thin sections were stained with ethanolic uranyl acetate and lead citrate, and examined with a Hitachi HU-11D-1 electron microscope. For heavy meromyosin (HMM) treatment, cells were partially lysed by immersing in Ca2+-free Yamamoto solution containing sodium dodecyl sulphate (SDS) because glycerina- tion, the usual method of enabling HMM to penetrate into cells (Ishikawa, Bischoff & Holtzer, 1969), was unsuccessful. As soon as the cells in the dishes were immersed in io~3 M SDS solu- tion, the immersing solution was decanted and the cells were rinsed with Ca2+-free Yamamoto solution. The cells were then reacted with HMM (05—1 mg/ml) for 3 h at room temperature, rinsed with o-i M KC1 and prepared for electron microscopy as described above, except that Circus movement of embryonic cells 135 005 M cacodylate buffer, pH 7-2, was employed instead of phosphate buffer. The contents of partially lysed cells were also dispersed on carbon-coated Formvar films on electron-microscope grids, treated with HMM and negatively stained according to the method described by Perry (1975). HMM prepared from rabbit skeletal muscle was kindly supplied by Dr K. Maruyama, Department of Biophysics, University of Kyoto. It was stocked in 02 M sodium glutamate solution at —20 °C and diluted with 01 M KC1 immediately before use. RESULTS Cells showing circus movement A cell showing circus movement generally has a large lobopodium (Figs. 1, 2). The lobopodial wave usually propagates around the cell circumference in a plane more or less parallel to the substratum. Most of the lobopodium usually contains few mem- branous structures and is composed of ground plasm resembling that in the ectoplasm of amoebae (Komnick & Wohlfarth-Bottermann, 1965; Bowers & Korn, 1968). Polyribosomes are frequently observed in the lobopodium. Numerous small vesicles (approx. 0-2 /<m in diameter) stream into a specific region of the lobopodium and thus serve as an indicator of the direction of lobopodial propagation, because stream- ing of the endoplasmic particles into the lobopodial bulge occurs at the hind end, as described by Holtfreter (1946). Other cytoplasmic components, such as mitochondria and microtubules, are sometimes observed at the hind end of the lobopodium. A thin band (0-05-0-2 /<m wide) of finely granular or fibrillar dense material separates the lobopodium from the endoplasm as described in the electron-microscopic study of intact teleostean embryos (Lentz & Trinkaus, 1967). In some cells, the filamentous material in this zone is more prominent (Fig. 3). The filaments are approximately 6 nm wide and appear to be oriented parallel to each other. The band of granular or fibrillar material separating the lobopodium from the endoplasm is clearly observed near the advancing front of the lobopodium (Fig. 4). This band is continuous with a cortical dense layer of endoplasm around the circumference, which has been described in embryonic amphibian cells (Perry, 1975). In other words, the dense material in the separating band, together with the cortical dense layer at the advancing front of the lobopodium, envelops the endoplasm. On the other hand, the peripheral dense layer of the lobopodium is usually poorly developed or almost absent near the advancing front. Sometimes several small vesicles are observed to form a line above the separating band at the advancing front as shown in Fig. 4. The separating band is curved (Fig. 2) or
Load more

Recommended publications
  • Physical and Chemical Basis of Cytoplasmic Streaming
    Annual Reviews www.annualreviews.org/aronline .4n~t Rev. Plant Physiol 1981. 32:205-36 Copyright© 1981by AnnualReviews In~ All rights reserved PHYSICAL AND CHEMICAL BASIS OF CYTOPLASMIC ~7710 STREAMING Nobur6 Kamiya Department of Cell Biology, National Institute for Basic Biology, Okazaki, 444 Japan CONTENTS INTRODUCTION........................................................................................................ 206 SHUTI’LE STREAMINGIN THE MYXOMYCETEPLASMODIUM ................ 207 General...................................................................................................................... 207 ContractileProperties of the PlasmodialStrand ...................................................... 208 Activationcaused by stretching .................................................................................. 208 Activationcaused by loading .................................................................................... 209 Synchronizationof local ,hythms .............................................................................. 209 ContractileProteins .................................................................................................. 210 Plasmodiumactomyosin .......................................................................................... 210 Plusmodiummyosin ................................................................................................ 210 Plusmodiumactin.................................................................................................... 211
    [Show full text]
  • Overview of the Cytoskeleton from an Evolutionary Perspective
    Downloaded from http://cshperspectives.cshlp.org/ on October 1, 2021 - Published by Cold Spring Harbor Laboratory Press Overview of the Cytoskeleton from an Evolutionary Perspective Thomas D. Pollard1 and Robert D. Goldman2 1Departments of Molecular Cellular and Developmental Biology, Molecular Biophysics and Biochemistry, and Cell Biology ,Yale University, New Haven, Connecticut 06520-8103 2Department of Cell and Molecular Biology, Northwestern University Feinberg School of Medicine, Chicago, Illinois 60611 Correspondence: [email protected] SUMMARY Organisms in the three domains of life depend on protein polymers to form a cytoskeleton that helps to establish their shapes, maintain their mechanical integrity, divide, and, in many cases, move. Eukaryotes have the most complex cytoskeletons, comprising three cytoskeletal poly- mers—actin filaments, intermediate filaments, and microtubules—acted on by three families of motor proteins (myosin, kinesin, and dynein). Prokaryotes have polymers of proteins ho- mologous to actin and tubulin but no motors, and a few bacteria have a protein related to intermediate filament proteins. Outline 1 Introduction—Overview of cellular 4 Overview of the evolution of the cytoskeleton functions 5 Conclusion 2 Structures of the cytoskeletal polymers References 3 Assembly of cytoskeletal polymers Editors: Thomas D. Pollard and Robert D. Goldman Additional Perspectives on The Cytoskeleton available at www.cshperspectives.org Copyright # 2018 Cold Spring Harbor Laboratory Press; all rights reserved; doi: 10.1101/cshperspect.a030288 Cite this article as Cold Spring Harb Perspect Biol 2018;10:a030288 1 Downloaded from http://cshperspectives.cshlp.org/ on October 1, 2021 - Published by Cold Spring Harbor Laboratory Press T.D. Pollard and R.D. Goldman 1 INTRODUCTION—OVERVIEW OF CELLULAR contrast, intermediate filaments do not serve as tracks for FUNCTIONS molecular motors (reviewed by Herrmann and Aebi 2016) but, rather, are transported by these motors.
    [Show full text]
  • The Mechanics of Motility in Dissociated Cytoplasm
    THE MECHANICS OF MOTILITY IN DISSOCIATED CYTOPLASM MICAH DEMBO Theoretical Biophysics, Theoretical Division, Los Alamos National Laboratory, Group T-10, Mail Stop K710, Los Alamos, New Mexico 87545 ABSTRACT We stimulate the dynamical behavior of dissociated cytoplasm using the Reactive Flow Model (Dembo, M., and F. Harlow, 1986, Biophys. J., 50:109-121). We find that for the most part the predicted dynamical behavior of the cytoplasm is governed by three nondimensional numbers. Several other nondimensional parameters, the initial conditions, and boundary conditions are found to have lesser effects. Of the three major nondimensional parameters, one (D#) controls the percentage of ectoplasm, the second (CO) controls the sharpness of the endoplasm-ectoplasm boundary, and the third (R#) controls the topological complexity of the endoplasm-ectoplasm distribution. If R# is very small, then the cytoplasm contracts into a single uniform mass, and there is no bulk streaming. If R# is very large, then the cytoplasmic mass breaks up into a number of clumps scattered throughout the available volume. Between these clumps the solution undergoes turbulent or chaotic patterns of streaming. Intermediate values of R# can be found such that the mass of cytoplasm remains connected and yet undergoes coherent modes of motility similar to flares (Taylor, D.L., J.S. Condeelis, P.L. Moore, and R.D. Allen, 1973, J. Cell Biol., 59:378-394) and rosettes (Kuroda, K., 1979, Cell Motility: Molecules and Organization, 347-362). INTRODUCTION (Dembo et al., 1986). Here we will consider two experi- in which chemical reaction is an essential The reactive flow model is a putative description of motile mental systems fluid part of the dynamics.
    [Show full text]
  • Cell & Molecular Biology
    BSC ZO- 102 B. Sc. I YEAR CELL & MOLECULAR BIOLOGY DEPARTMENT OF ZOOLOGY SCHOOL OF SCIENCES UTTARAKHAND OPEN UNIVERSITY BSCZO-102 Cell and Molecular Biology DEPARTMENT OF ZOOLOGY SCHOOL OF SCIENCES UTTARAKHAND OPEN UNIVERSITY Phone No. 05946-261122, 261123 Toll free No. 18001804025 Fax No. 05946-264232, E. mail [email protected] htpp://uou.ac.in Board of Studies and Programme Coordinator Board of Studies Prof. B.D.Joshi Prof. H.C.S.Bisht Retd.Prof. Department of Zoology Department of Zoology DSB Campus, Kumaun University, Gurukul Kangri, University Nainital Haridwar Prof. H.C.Tiwari Dr.N.N.Pandey Retd. Prof. & Principal Senior Scientist, Department of Zoology, Directorate of Coldwater Fisheries MB Govt.PG College (ICAR) Haldwani Nainital. Bhimtal (Nainital). Dr. Shyam S.Kunjwal Department of Zoology School of Sciences, Uttarakhand Open University Programme Coordinator Dr. Shyam S.Kunjwal Department of Zoology School of Sciences, Uttarakhand Open University Haldwani, Nainital Unit writing and Editing Editor Writer Dr.(Ms) Meenu Vats Dr.Mamtesh Kumari , Professor & Head Associate. Professor Department of Zoology, Department of Zoology DAV College,Sector-10 Govt. PG College Chandigarh-160011 Uttarkashi (Uttarakhand) Dr.Sunil Bhandari Asstt. Professor. Department of Zoology BGR Campus Pauri, HNB (Central University) Garhwal. Course Title and Code : Cell and Molecular Biology (BSCZO 102) ISBN : 978-93-85740-54-1 Copyright : Uttarakhand Open University Edition : 2017 Published By : Uttarakhand Open University, Haldwani, Nainital- 263139 Contents Course 1: Cell and Molecular Biology Course code: BSCZO102 Credit: 3 Unit Block and Unit title Page number Number Block 1 Cell Biology or Cytology 1-128 1 Cell Type : History and origin.
    [Show full text]
  • Structure and Development of the Egg of the Glossiphoniid Leech Theromyzon Rude: Characterization of Developmental Stages and Structure of the Early Uncleaved Egg
    Development 100, 211-225 (1987) 211 Printed in Great Britain © The Company of Biologists Limited 1987 Structure and development of the egg of the glossiphoniid leech Theromyzon rude: characterization of developmental stages and structure of the early uncleaved egg JUAN FERNANDEZ, NANCY OLEA and CECILIA MATTE Departamento de Biologia, Facultad de Ciendas, Untversidad de Chile, Casilla 653, Santiago, Chile Summary Some aspects of the reproductive biology of the meridional bands, during stage le, lead to accumu- glossiphoniid leech, Theromyzon rude, under labora- lation of ooplasm at both egg poles. In this manner, tory conditions, and the staging and structure of its the teloplasm or pole plasm forms. Completion of the uncleaved egg were studied. Sexually mature animals first cleavage furrow, by the end of stage If, is form breeding communities and fertilization occurs in preceded by dorsoventral flattening of the egg and the ovLsacs, presumably around the time of egg rearrangement of its teloplasm and perinuclear laying. Opposition may be postponed for hours or plasm. Structure of the early uncleaved egg has been days, but the eggs in the ovisacs remain blocked at studied with transmission and scanning electron mi- first meiotic metaphase. Development of the croscopy of intact or permeabilized preparations. The uncleaved egg, from the time of oviposit ion to com- plasmalemma forms numerous long and some short pletion of the first cleavage division, has been sub- microvilli evenly distributed across the egg surface. divided into six stages. At 20 °C, the six developmental The ectoplasm includes many vesicles, mitochondria, stages take 5-6 h. Characterization of' the stages is granules and an elaborate network of filament based on observations of both live and fixed/cleared bundles.
    [Show full text]
  • The Mechanism of Cytoplasmic Streaming in Characean Algal Cells: Sliding of Endoplasmic Reticulum Along Actin Filaments Bechara Kachar* and Thomas S
    The Mechanism of Cytoplasmic Streaming in Characean Algal Cells: Sliding of Endoplasmic Reticulum along Actin Filaments Bechara Kachar* and Thomas S. Reese Laboratory of Neum-otolaryngology*and Laboratory of Neumbiology, National Institute of Neurological and Communicative Disorders and Stroke, National Institutes of Health, Bethesda, Maryland 20205 Abstract. Electron microscopy of directly frozen giant is dissociated in a buffer containing ATP. The shear cells of characean algae shows a continuous, tridimen- forces produced at the interface with the dissociated sional network of anastomosing tubes and cisternae of actin cables move large aggregates of endoplasmic rough endoplasmic reticulum which pervade the reticulum and other organelles. The combination of streaming region of their cytoplasm. Portions of this fast-freezing electron microscopy and video micros- endoplasmic reticulum contact the parallel bundles of copy of living cells and dissociated cytoplasm demon- actin filaments at the interface with the stationary cor- strates that the cytoplasmic streaming depends on en- tical cytoplasm. Mitochondria, glycosomes, and other doplasmic reticulum membranes sliding along the small cytoplasmic organelles enmeshed in the endo- stationary actin cables. Thus, the continuous network plasmic reticulum network display Brownian motion of endoplasmic reticulum provides a means of exerting while streaming. The binding and sliding of endoplas- motive forces on cytoplasm deep inside the cell distant mic reticulum membranes along actin cables can also from the cortical actin cables where the motive force be directly visualized after the cytoplasm of these cells is generated. uE coordinated movement of intraceUular elements, Several reports (2, 3, 5, 14, 16, 19) have dealt with the ques- the cytoplasmic streaming, in giant characean algae tion whether the active movement of putative organelles, T cells was discovered by Corti in 1774 (for review see using the translocator molecules on their surfaces to move reference 14).
    [Show full text]
  • Composition of Cytoplasm
    Cytoplasm Definition Cytoplasm is the semi-fluid substance of a cell that is present within the cellular membrane and surrounds the nuclear membrane. It is sometimes described as the nonnuclear content of the protoplasm. All the cellular contents in a prokaryote organisms are contained within cell's cytoplasm. In eukaryote organisms, the nucleus of the cell is separated from the cytoplasm. Cytoplasm is a thick and semi-transparent fluid. The cytoplasm was discovered in the year 1835 by Robert Brown and other scientists. The cytoplasm is made of 70% - 90% water and is colorless usually. Most of the cellular activities occurs in the cytoplasm. Metabolic pathways like glycolysis and cellular processes like cell division take place in the cytoplasm. The outer clear and glassy layer of the cytoplasm is called the ectoplasm or the cell cortex and the inner granular mass is called the endoplasm. In plants cells, a process known as cytoplasmic streaming takes place where there is movements of the cytoplasm around the vacuoles. General Characteristics of Cytoplasm: • Cytoplasm is the fluid substance that fills the space between the cell membrane and the cellular organelles. • Cytoplasm shows differential staining properties, the areas stained with the basic dyes are the basophilic areas of the cytoplasm and is termed as ergatoplasm for this material. • It is heterogenous mixture of opaque granules and organic compounds which gives it its colloidal nature. • The peripheral zone of cytoplasm is thick and jelly-like substance, known as the plasmogel. The surrounding area of the nuclear zone is thin and liquefied in nature and is known as the plasmosol.
    [Show full text]
  • I-Viii Cshperspect-ERT-FM 1..8
    This is a free sample of content from The Endoplasmic Reticulum. Click here for more information or to buy the book. The Endoplasmic Reticulum A subject collection from Cold Spring Harbor Perspectives in Biology © 2013 by Cold Spring Harbor Laboratory This is a free sample of content from The Endoplasmic Reticulum. Click here for more information or to buy the book. OTHER SUBJECT COLLECTIONS FROM COLD SPRING HARBOR PERSPECTIVES IN BIOLOGY Wnt Signaling Protein Synthesis and Translational Control The Synapse Extracellular Matrix Biology Protein Homeostasis Calcium Signaling The Golgi Germ Cells The Mammary Gland as an Experimental Model The Biology of Lipids: Trafficking, Regulation, and Function Auxin Signaling: From Synthesis to Systems Biology The Nucleus Neuronal Guidance: The Biology of Brain Wiring Cell Biology of Bacteria Cell–Cell Junctions Generation and Interpretation of Morphogen Gradients Immunoreceptor Signaling NF-kB: A Network Hub Controlling Immunity, Inflammation, and Cancer Symmetry Breaking in Biology The Origins of Life The p53 Family SUBJECT COLLECTIONS FROM COLD SPRING HARBOR PERSPECTIVES IN MEDICINE Addiction Parkinson’s Disease Type 1 Diabetes Angiogenesis: Biology and Pathology HIV: From Biology to Prevention and Treatment The Biology of Alzheimer Disease © 2013 by Cold Spring Harbor Laboratory This is a free sample of content from The Endoplasmic Reticulum. Click here for more information or to buy the book. The Endoplasmic Reticulum A subject collection from Cold Spring Harbor Perspectives in Biology EDITED BY Susan Ferro-Novick Tom A. Rapoport University of California San Diego Harvard Medical School Randy Schekman University of California at Berkeley COLD SPRING HARBOR LABORATORY PRESS Cold Spring Harbor, New York † www.cshlpress.org © 2013 by Cold Spring Harbor Laboratory This is a free sample of content from The Endoplasmic Reticulum.
    [Show full text]
  • Protists: Amoeba
    Microorganisms – Protists: Amoeba The amoeba is a protozoan that belongs to the Kingdom Protista. The name amoeba comes from the Greek word amoibe, which means change. (Amoeba is also spelled ameba.) Protists are microscopic unicellular organisms that don't fit into the other kingdoms. Some protozoans are considered plant- like while others are considered animal-like. The amoeba is considered an animal-like protist because it moves and consumes its food. Protists are classified by how they move, some have cilia or flagella, but the ameba has an unusual way of creeping along by stretching its cytoplasm into fingerlike extensions called pseudopodia. The word "pseudopodia" means "false foot". Label the pseudopodia. When looking at ameba under a microscope, an observer will note that no amoeba looks the same as any other. The cell membrane is very flexible and allows for the amoeba to change shape. Amoebas live in ponds or puddles, and some can even live inside people. Color and label the cell membrane red. There are two types of cytoplasm in the amoeba. The darker cytoplasm toward the interior of the protozoan is called endoplasm. The clearer cytoplasm that is found near the cell membrane is called ectoplasm. On the diagram, the endoplasm is indicated by the dotted area, and the ectoplasm by the white area. Color and label the endoplasm pink. Color and label the ectoplasm light blue. By pushing the endoplasm toward the cell membrane, the amoeba causes its body to extend and creep along. It is also by this method that the amoeba consumes its food.
    [Show full text]
  • Difference Between Ectoplasm and Endoplasm Key Difference – Ectoplasm Vs Endoplasm
    Difference Between Ectoplasm and Endoplasm www.differencebetween.com Key Difference – Ectoplasm vs Endoplasm Protozoa are single-cell eukaryotic organisms. They resemble animal cells and contain major organelles and the cell nucleus. Protozoan’s cytoplasm has two distinct areas called ectoplasm and endoplasm. The outer layer of the cytoplasm is known as the ectoplasm. The inner layer is known as the endoplasm. The terms endoplasm and ectoplasm are used mainly to describe amoeba cytoplasm and how it helps feeding and locomotion. Amoeba is a single cell eukaryotic organism which is made up of a nucleus and cytoplasm. The cytoplasm of amoeba can be divided into the two layers: endoplasm and ectoplasm. Ectoplasm is the clear outer cytoplasmic layer of amoeba while endoplasm is the inner granule-rich cytoplasmic layer of amoeba. This is the key difference between ectoplasm and endoplasm. What is Ectoplasm? Ectoplasm refers to the outer layer of the cytoplasm of a cell. It is not a granulated area. This part of the cytoplasm is watery and clear. Ectoplasm is located immediately adjacent to the plasma membrane. It is clearly visible in the amoeba cell. Figure 01: Cell Structure Amoeba Amoeba cells locomote by pseudopodia formation. The ectoplasm of the amoeba cell is responsible for changing the direction of the pseudopodium. Location of the pseudopodium changes when the alkalinity and acidity of the water in ectoplasm are changed. A slight change in the acidity or alkalinity is enough for the flowing of cytoplasm which helps in locomotion. Water concentration of the amoeba cell is regulated by the endoplasm. Endoplasm easily absorbs or releases water through the partially permeable membrane.
    [Show full text]
  • 2 the Structure and Ultrastructure of the Cell Gunther Neuhaus Institut Fu¨R Zellbiologie, Freiburg, Germany
    2 The Structure and Ultrastructure of the Cell Gunther Neuhaus Institut fu¨r Zellbiologie, Freiburg, Germany 2.1 Cell Biology . .........................40 2.2.7.6 Isolating Secondary Walls . 107 2.1.1 Light Microscopy . 43 2.2.8 Mitochondria . 109 2.1.2 Electron Microscopy . 45 2.2.8.1 Shape Dynamics and Reproduction . 110 2.2.8.2 Membranes and Compartmentalization in 2.2 The Plant Cell . .........................46 Mitochondria . 112 2.2.1 Overview . 46 2.2.9 Plastids . 113 2.2.2 The Cytoplasm . 50 2.2.9.1 Form and Ultrastructure of 2.2.2.1 The Cytoskeleton . 51 Chloroplasts . 114 2.2.2.2 Motor Proteins and Cellular Kinetic 2.2.9.2 Other Plastid Types, Starches . 116 Processes . 55 2.2.2.3 Flagella and Centrioles . 57 2.3 Cell Structure in Prokaryotes ............. 119 2.2.3 The Cell Nucleus . 59 2.3.1 Reproduction and Genetic Apparatus . 122 2.2.3.1 Chromatin . 60 2.3.2 Bacterial Flagella . 124 2.2.3.2 Chromosomes and Karyotype . 63 2.3.3 Wall Structures . 125 2.2.3.3 Nucleoli and Preribosomes . 64 2.2.3.4 Nuclear Matrix and Nuclear Membrane . 65 2.4 The Endosymbiotic Theory and the 2.2.3.5 Mitosis and the Cell Cycle . 66 Hydrogen Hypothesis . ............. 125 2.2.3.6 Cell Division . 73 2.4.1 Endocytobiosis . 126 2.2.3.7 Meiosis . 73 2.4.2 Origin of Plastids and Mitochondria by 2.2.3.8 Crossing-Over . 79 Symbiogenesis . 127 2.2.3.9 Syngamy . 79 2.2.4 Ribosomes .
    [Show full text]
  • Ultrastructure of the Golgi Apparatus, Mitochondria and Endoplasmic Reticulum
    Proceedings of the Iowa Academy of Science Volume 63 Annual Issue Article 77 1956 Ultrastructure of the Golgi Apparatus, Mitochondria and Endoplasmic Reticulum H. W. Beams State University of Iowa Everett Anderson State University of Iowa Let us know how access to this document benefits ouy Copyright ©1956 Iowa Academy of Science, Inc. Follow this and additional works at: https://scholarworks.uni.edu/pias Recommended Citation Beams, H. W. and Anderson, Everett (1956) "Ultrastructure of the Golgi Apparatus, Mitochondria and Endoplasmic Reticulum," Proceedings of the Iowa Academy of Science, 63(1), 686-692. Available at: https://scholarworks.uni.edu/pias/vol63/iss1/77 This Research is brought to you for free and open access by the Iowa Academy of Science at UNI ScholarWorks. It has been accepted for inclusion in Proceedings of the Iowa Academy of Science by an authorized editor of UNI ScholarWorks. For more information, please contact [email protected]. Beams and Anderson: Ultrastructure of the Golgi Apparatus, Mitochondria and Endoplasm Ultrastructure of the Golgi Apparatus, Mitochondria and Endoplasmic Reticulum1 By H. \V. BEAMS AND EVERETT ANDERSON Golgi apparatus The Golgi apparatus was first observed by Golgi in 1898 and referred to by him as the "apperato reticulare interno". Notwith­ standing the fact that this material has since been described in practically every type of cell, not all imTstigators are agreed that it is a bonafide cellular structure. In fact, it has been characterized as an artifact by Walker and Allen ( 1927), Parat ( 1928), Worley ( 1946), Palade and Claude ( 19-!9), Baker ( l 950) and Thomas (1951). Much credit is due Dalton and Felix ( 1954) for clearly demon­ strating the Golgi apparatus by means of the phase-contrast and electron microscopes.
    [Show full text]