DOCSLIB.ORG

Organelle Location Description Function

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Organelle Location Description Function ORGANELLE LOCATION DESCRIPTION FUNCTION cell wall plant, fungi and bacteria but *outer layer *support (grow tall) not animal *rigid, strong, stiff *protection *made of cellulose *allows H2O, O2, CO2 to pass into and out of cell cell membrane both plant/animal *plant - inside cell wall *support All cells *animal - outer layer; cholesterol *protection *selectively permeable *controls movement of materials in/out of cell *barrier between cell and its environment *maintains homeostasis Nucleus both plant/animal *large, oval generally *controls cell activities nucleus is absent in . *key organelle which has the genetic material and is prokaryotic cells involved in multiplication of cell, growth and maintenance of cell. nucleolus All cells except prokaryotes * Make ribosomes, contains building blocks or mRNA, *Found inside cell’s nucleus tRNA, rRNA * may have more than one *disappears during cell division nuclear membrane both plant/animal *surrounds nucleus *Controls movement of materials in/out of nucleus *selectively permeable Centrioles Animal cells *paired structures near the nucleus *stparate chromosome pairs during mitosis *made of cylinder of microtubule pairs cytoplasm both plant/animal *clear, thick, jellylike material *supports /protects cell organelles All cells (sytosol) * organelles found inside cell membrane *contains cytoskelon fibers endoplasmic both plant/animal *network of tubes or membranes *carries materials through cell reticulum (E.R.) Smooth No ribosomes Rough Attached ribosome Synthesis of fats/lipids Ribosomes synthesis proteins for export ribosome both plant/animal *small bodies free or attached to E.R. *synthesizes proteins *made of rRNA and protein Mitochondria both plant/animal *bean-shaped *breaks down sugar molecules into energy *inner membranes *site of aerobic cellular respiration Double membrane outer smooth inner folded into cristae Golgi/golgi bodies / both plant/animal except These are the vacuoles or sac like * to modify and package proteins for export golgi apparatus Prokaryotes structures. They occupy a considerable *have cis and trans face amount of cytoplasm. *stacks of flattened sacs vacuole plant - few/large *fluid-filled sacs * Vacuoles are pouches in the cell that store materials such animal - small as water, salts, proteins, and carbohydrates, waste products and toxic waste.. *store food, water, waste (plants need to store large amounts of food) Vesicles A lot of small bubble sacs in These are small-sized sac like *These help in storage and release of substances as required animals, large sac in the structures. They are of different types by the cell. For example lysosomes help in cell digestion middle of plant cells lysosomes, peroxisomes. when cell dies. Vacuoles function is to store water. lysosome plant - uncommon *small, round, with a membrane *breaks down larger food molecules into smaller molecules animal - common *digests old cell parts chloroplast plant, not animal *green, oval usually containing *uses energy from sun to make food for the plant chlorophyll (green pigment) (photosynthesis) Cilia Animal cells and protozoa Have a 9-2 arrangement of Movement of cell microtubules *short but numerous flagellum Bacteria cells and protozoan *Have a 9-2 arrangement of movement Sex cells microtubules *long but few in number Micro-tubules = All cells *micro-tubules provide structural * the cell has a fixed structure and does not collapse cytoskeleton strength. * form the cyto-skeleton * These are filamentous extensions *moves organelles within the cell in cytoplasm. http://www.biologyjunction.com/cell_functions.htm .
Load more

Recommended publications
  • For the Safe Delivery of Essential Proteins
    Dedicated ‘Bodyguards’ for the Safe Delivery of Essential Proteins Dr Brigitte Pertschy DEDICATED ‘BODYGUARDS’ FOR THE SAFE DELIVERY OF ESSENTIAL PROTEINS Ribosomes are undoubtedly one of the most essential cellular components in life. These macromolecules are responsible for the synthesis of proteins in all living cells. Dr Brigitte Pertschy, Dr Ingrid Rössler and Jutta Hafner at the Institute of Molecular Biosciences at the University of Graz, Austria, have discovered that the safe delivery of essential ribosomal proteins that make up the ribosomes is dependant on ‘private bodyguards’ or ‘chaperones’. Nascent Ribosomal Proteins Journey Ribosome synthesis is an important of their synthesis and proper folding Across the Cell to the Nucleus and continuous process. Dr Pertschy of the proteins. Importins have also describes that a growing cell requires been reported as aides in the import of The ribosome is the intricate nano- up to 1,000 ribosomes to be synthesised proteins to the cell nucleus as well as in machinery that translates messenger per minute. The r-proteins are protecting proteins from aggregation. RNA strands (mRNA) into protein. Our produced in the cell cytoplasm by the DNA holds the instructions for building ribosome itself (that way, the ribosome The team speculated that since every protein needed for our bodies to participates in its own reproduction). r-proteins are produced at extremely function. Initially, DNA is transcribed From there the r-proteins must travel high amounts and their correct into mRNA, which contains the amino to the cell nucleus where in a complex functioning is so critical for a cell, these acid sequence of a particular protein.
    [Show full text]
  • Evidence for an Alternate Pathway for Lysosomal Enzyme Targeting (Oligosaccharides/Lysosomes/Phosphorylation) CHRISTOPHER A
    Proc. NatL Acad. Sci. USA Vol. 80, pp. 775-779, February 1983 Cell Biology Identification and characterization of cells deficient in the mannose 6-phosphate receptor: Evidence for an alternate pathway for lysosomal enzyme targeting (oligosaccharides/lysosomes/phosphorylation) CHRISTOPHER A. GABEL, DANIEL E. GOLDBERG, AND STUART KORNFELD Departments of Internal Medicine and Biological Chemistry, Division of Hematology-Oncology, Washington University School of Medicine, St. Louis, Missouri 63110 Contributed by Stuart Kornfeld, November 3, 1982 ABSTRACT Newly synthesized lysosomal enzymes acquire dence that this cell line is deficient in Man-6-P receptor activity. phosphomannosyl units, which allow bindingofthe enzymes to the We also identify several additional cell lines that lack receptor mannose 6-phosphate receptor and subsequent translocation to activity yet possess high levels ofintracellular hydrolase activity. lysosomes. In some cell types, this sequence ofevents is necessary These data indicate that some cells possess pathways indepen- for the delivery ofthese enzymes to lysosomes. Using a slime mold dent of the Man-6-P receptor for the intracellular transport of lysosomal hydrolase as a probe, we have identified three murine acid hydrolases to lysosomes. cell lines that lack the receptor and one line that contains very low (3%) receptor activity. Each ofthese lines synthesizes the mannose MATERIALS AND METHODS 6-phosphate recognition marker on its lysosomal enzymes, but, Cells. BW5147 mouse lymphoma, P388D1 mouse macro- unlike cell lines with high levels of receptor, the cells accumulate MOPC 315 oligosaccharides containing phosphomonoesters. The receptor- phage, J774.2 mouse macrophage, mouse L cells, deficient lines possess high levels of intracellular acid hydrolase mouse myeloma, Chinese hamster ovary (CHO), and (human) activity, which is contained in dense granules characteristic of ly- HeLa cells were grown in suspension culture in a minimal es- sosomes.
    [Show full text]
  • Size Changes in Eukaryotic Ribosomes
    Proc. Nat. Acad. Sci. USA Vol. 68, No. 12, pp. 3021-3025, December 1971 Size Changes in Eukaryotic Ribosomes (diffusion constant/sedimentation constant/ribosomal dissociation/chick embryo) JOHN VOURNAKIS AND ALEXANDER RICH Department of Biology, Massachusetts Institute of Technology, Cambridge, Mass. 02139 Contributed by Alexander Rich, September 20, 1971 ABSTRACT Evidence is presented that ribosomes two particles are similar. However, these changes suggest active in protein synthesis and attached to messenger that when the ribosome is attached to messenger RNA it has a RNA on polysomes have a smaller diameter than free cytoplasmic single ribosomes. Measurements have been smaller diameter than is found for the free cytoplastic ribo- made on these two types of ribosomes of differences in some. This more compact form of the ribosome is maintained sedimentation velocity and diffusion constant. Differences even when the nascent polypeptide chain is relased by puro- in these quantities suggest about a 20-A decrease in the mycin. We thus infer that there are substantial differences diameter of the ribosomes from chick embryo muscles in the interactions between the ribosomal subunits when when they are attached to messenger RNA. Similar dif- they ferences are also observed in rabbit reticulocytes and are attached to messenger RNA as compared to the free cyto- mouse ascites tumor cells. These two ribosomal states plasmic single ribosome, which is inactive in protein synthesis. have different sensitivity to Pronase digestion and dis- sociate into ribosomal subunits at different KCI concen- METHODS AND MATERIALS trations. This size difference is not associated with a sig- nificant difference in overall ribosomal mass and appears Preparation of Ribosomes.
    [Show full text]
  • A Mitochondria–Lysosome Transport Pathway
    RESEARCH HIGHLIGHTS Controlling enteric nerve Interestingly, inhibition of integrin signalling The authors used point mutations to establish cell migration or ROCK activity rescued directed migration of that residue Met 44 of actin was essential for the MEFs and normalized the migration of ENCCs F-actin-severing function of Mical. Manipulation A functional gastrointestinal system is in organ cultures. Although the precise function of Mical levels is known to generate abnormal dependent on the enteric nervous system, of Phactr4 remains to be discovered, these data bristle cell processes in Drosophila. In the present which is formed during embryogenesis through demonstrate its role in regulating lamellipodial study, mutation of the Met 44 actin residue colonization of the gut by enteric neural crest actin dynamics through cofilin activity suppressed Mical overexpression phenotypes cells (ENCCs). Now, Niswander and colleagues controlled by integrin and PP1 signalling. CKR and phenocopied Mical loss-of-function effects identify the protein phosphatase 1 (PP1)- and in Drosophila. Together, these findings establish actin-binding protein Phactr4 as a regulator actin as a direct substrate of Mical and reveal of directional and collective ENCC migration a specific oxidation-dependent mechanism (Genes Dev. 26, 69–81; 2012). Actin gets the oxidation to regulate actin filament dynamics and cell Analysis of mouse embryos expressing treatment from Mical processes in vivo. AIZ a Phactr4 mutation known to abolish PP1 binding revealed reduced enteric neuronal Mical, an enzyme mediating redox reactions, numbers and defective organization at is known to promote actin remodelling embryonic day 18.5, and reduced ENCC in response to semaphorin signalling by A mitochondria–lysosome numbers in the gut at earlier stages (E12.5).
    [Show full text]
  • Microorganisms – Protists: Euglena
    Microorganisms – Protists: Euglena Euglena are unicellular organisms classified into the Kingdom Protista, and the Phylum Euglenophyta. All euglena have chloroplasts and can make their own food by photosynthesis. They are not completely autotrophic though, euglena can also absorb food from their environment. Euglena usually live in quiet ponds or puddles. Euglena move by a flagellum (plural flagella), which is a long whip-like structure that acts like a little motor. The flagellum is located on the anterior (front) end, and twirls in such a way as to pull the cell through the water. It is attached at an inward pocket called the reservoir. Color and label the reservoir grey. Color and label the flagellum black. The Euglena is unique in that it is both heterotrophic (must consume food) and autotrophic (can make its own food). Chloroplasts within the euglena trap sunlight that is used for photosynthesis and can be seen as several rod-like structures throughout the cell. Color and label the chloroplasts green. Euglena also have an eyespot at the anterior end that detects light, it can be seen near the reservoir. This helps the euglena find bright areas to gather sunlight to make their food. Color and label the eyespot red. Euglena can also gain nutrients by absorbing them across their cell membrane, hence they become heterotrophic when light is not available, and they cannot photosynthesize. The euglena has a stiff pellicle outside the cell membrane that helps it keep its shape, though the pellicle is somewhat flexible, and some euglena can be observed scrunching up and moving in an inchworm type fashion.
    [Show full text]
  • Building the Interphase Nucleus: a Study on the Kinetics of 3D Chromosome Formation, Temporal Relation to Active Transcription, and the Role of Nuclear Rnas
    University of Massachusetts Medical School eScholarship@UMMS GSBS Dissertations and Theses Graduate School of Biomedical Sciences 2020-07-28 Building the Interphase Nucleus: A study on the kinetics of 3D chromosome formation, temporal relation to active transcription, and the role of nuclear RNAs Kristin N. Abramo University of Massachusetts Medical School Let us know how access to this document benefits ou.y Follow this and additional works at: https://escholarship.umassmed.edu/gsbs_diss Part of the Bioinformatics Commons, Cell Biology Commons, Computational Biology Commons, Genomics Commons, Laboratory and Basic Science Research Commons, Molecular Biology Commons, Molecular Genetics Commons, and the Systems Biology Commons Repository Citation Abramo KN. (2020). Building the Interphase Nucleus: A study on the kinetics of 3D chromosome formation, temporal relation to active transcription, and the role of nuclear RNAs. GSBS Dissertations and Theses. https://doi.org/10.13028/a9gd-gw44. Retrieved from https://escholarship.umassmed.edu/ gsbs_diss/1099 Creative Commons License This work is licensed under a Creative Commons Attribution-Noncommercial 4.0 License This material is brought to you by eScholarship@UMMS. It has been accepted for inclusion in GSBS Dissertations and Theses by an authorized administrator of eScholarship@UMMS. For more information, please contact [email protected]. BUILDING THE INTERPHASE NUCLEUS: A STUDY ON THE KINETICS OF 3D CHROMOSOME FORMATION, TEMPORAL RELATION TO ACTIVE TRANSCRIPTION, AND THE ROLE OF NUCLEAR RNAS A Dissertation Presented By KRISTIN N. ABRAMO Submitted to the Faculty of the University of Massachusetts Graduate School of Biomedical Sciences, Worcester in partial fulfillment of the requirements for the degree of DOCTOR OF PHILOSPOPHY July 28, 2020 Program in Systems Biology, Interdisciplinary Graduate Program BUILDING THE INTERPHASE NUCLEUS: A STUDY ON THE KINETICS OF 3D CHROMOSOME FORMATION, TEMPORAL RELATION TO ACTIVE TRANSCRIPTION, AND THE ROLE OF NUCLEAR RNAS A Dissertation Presented By KRISTIN N.
    [Show full text]
  • Introduction to the Cell Cell History Cell Structures and Functions
    Introduction to the cell cell history cell structures and functions CK-12 Foundation December 16, 2009 CK-12 Foundation is a non-profit organization with a mission to reduce the cost of textbook materials for the K-12 market both in the U.S. and worldwide. Using an open-content, web-based collaborative model termed the “FlexBook,” CK-12 intends to pioneer the generation and distribution of high quality educational content that will serve both as core text as well as provide an adaptive environment for learning. Copyright ©2009 CK-12 Foundation This work is licensed under the Creative Commons Attribution-Share Alike 3.0 United States License. To view a copy of this license, visit http://creativecommons.org/licenses/by-sa/3.0/us/ or send a letter to Creative Commons, 171 Second Street, Suite 300, San Francisco, California, 94105, USA. Contents 1 Cell structure and function dec 16 5 1.1 Lesson 3.1: Introduction to Cells .................................. 5 3 www.ck12.org www.ck12.org 4 Chapter 1 Cell structure and function dec 16 1.1 Lesson 3.1: Introduction to Cells Lesson Objectives • Identify the scientists that first observed cells. • Outline the importance of microscopes in the discovery of cells. • Summarize what the cell theory proposes. • Identify the limitations on cell size. • Identify the four parts common to all cells. • Compare prokaryotic and eukaryotic cells. Introduction Knowing the make up of cells and how cells work is necessary to all of the biological sciences. Learning about the similarities and differences between cell types is particularly important to the fields of cell biology and molecular biology.
    [Show full text]
  • SMC Complexes Orchestrate the Mitotic Chromatin Interaction Landscape
    Curr Genet DOI 10.1007/s00294-017-0755-y REVIEW SMC complexes orchestrate the mitotic chromatin interaction landscape Yasutaka Kakui1 · Frank Uhlmann1 Received: 13 September 2017 / Revised: 14 September 2017 / Accepted: 16 September 2017 © The Author(s) 2017. This article is an open access publication Abstract Chromatin is a very long DNA–protein complex Keywords Chromosome condensation · SMC complex · that controls the expression and inheritance of the genetic Chromatin · Cell cycle · Hi-C information. Chromatin is stored within the nucleus in interphase and further compacted into chromosomes dur- ing mitosis. This process, known as chromosome condensa- Introduction tion, is essential for faithful segregation of genomic DNA into daughter cells. Condensin and cohesin, members of How chromatin is spatially organized within the cell nucleus the structural maintenance of chromosomes (SMC) fam- and within chromosomes is a fundamental question in cell ily, are fundamental for chromosome architecture, both biology. Centimeter-long DNA molecules change their spa- for establishment of chromatin structure in the interphase tial chromatin organization within micrometer-sized cells nucleus and for the formation of condensed chromosomes during cell cycle progression. In interphase, chromatin is in mitosis. These ring-shaped SMC complexes are thought distributed throughout the nucleus to express the genetic to regulate the interactions between DNA strands by topo- information. When cells enter mitosis, chromatin becomes logically entrapping DNA. How this activity shapes chro- compacted to form mitotic chromosomes. Chromosome mosomes is not yet understood. Recent high throughput condensation, the gross morphological change of spatial chromosome conformation capture studies revealed how chromatin organization in mitosis, is indispensable for chromatin is reorganized during the cell cycle and have the faithful inheritance of genetic information.
    [Show full text]
  • The Splicing Factor XAB2 Interacts with ERCC1-XPF and XPG for RNA-Loop Processing During Mammalian Development
    bioRxiv preprint doi: https://doi.org/10.1101/2020.07.20.211441; this version posted July 21, 2020. The copyright holder for this preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The Splicing Factor XAB2 interacts with ERCC1-XPF and XPG for RNA-loop processing during mammalian development Evi Goulielmaki1*, Maria Tsekrekou1,2*, Nikos Batsiotos1,2, Mariana Ascensão-Ferreira3, Eleftheria Ledaki1, Kalliopi Stratigi1, Georgia Chatzinikolaou1, Pantelis Topalis1, Theodore Kosteas1, Janine Altmüller4, Jeroen A. Demmers5, Nuno L. Barbosa-Morais3, George A. Garinis1,2* 1. Institute of Molecular Biology and Biotechnology, Foundation for Research and Technology- Hellas, GR70013, Heraklion, Crete, Greece, 2. Department of Biology, University of Crete, Heraklion, Crete, Greece, 3. Instituto de Medicina Molecular João Lobo Antunes, Faculdade de Medicina da Universidade de Lisboa, Avenida Professor Egas Moniz, 1649-028 Lisboa, Portugal, 4. Cologne Center for Genomics (CCG), Institute for Genetics, University of Cologne, 50931, Cologne, Germany, 5. Proteomics Center, Netherlands Proteomics Center, and Department of Biochemistry, Erasmus University Medical Center, the Netherlands. Corresponding author: George A. Garinis ([email protected]) *: equally contributing authors bioRxiv preprint doi: https://doi.org/10.1101/2020.07.20.211441; this version posted July 21, 2020. The copyright holder for this preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. Abstract RNA splicing, transcription and the DNA damage response are intriguingly linked in mammals but the underlying mechanisms remain poorly understood. Using an in vivo biotinylation tagging approach in mice, we show that the splicing factor XAB2 interacts with the core spliceosome and that it binds to spliceosomal U4 and U6 snRNAs and pre-mRNAs in developing livers.
    [Show full text]
  • Plant & Animal Cells and Their Organelles
    Cells and Their Organelles The cell is the basic unit of life. All cells are surrounded by a cell membrane (which is sometimes called a plasma membrane). The cell membrane is semipermeable, meaning it allows some substances to pass into the cell and blocks others out. Plant cells have an additional layer surrounding them called the cell wall. The cell wall is made of nonliving material called cellulose. The centriole (also called the "microtubule organizing center") is a small body located near the nucleus. The centriole is where microtubules are made. During cell division (mitosis), the centriole divides and the two parts move to opposite sides of the dividing cell. Only animal cells have centrosomes. Microtubules are shaped like soda straws and give the nucleus and cell its shape (like a skeleton gives you shape) Answer the questions after each reading section on your own paper, please! 1. What is the basic unit of living things? 2. What surrounds all cells? 3. What is meant by semipermeable? 4. What additional layer is found around the outside of plant cells? 5. Cell walls in plants are made up of C_ ___ ___ ___ ___ ___ ___ ___ ___. 6. Centrioles are found inside of what type of cell only? 7. Microtubules have what shape and do what jobs for the cell? __________________________________________________________________________________________ The nucleus (in the center of a cell) is a rounded body containing the nucleolus and a cell’s DNA. The nucleus controls most of the functions of the cell by controlling protein synthesis. The nucleus of plant and animal cells is surrounded by the nuclear membrane.
    [Show full text]
  • A Physicochemical Perspective of Aging from Single-Cell Analysis Of
    TOOLS AND RESOURCES A physicochemical perspective of aging from single-cell analysis of pH, macromolecular and organellar crowding in yeast Sara N Mouton1, David J Thaller2, Matthew M Crane3, Irina L Rempel1, Owen T Terpstra1, Anton Steen1, Matt Kaeberlein3, C Patrick Lusk2, Arnold J Boersma4*, Liesbeth M Veenhoff1* 1European Research Institute for the Biology of Ageing, University of Groningen, University Medical Center Groningen, Groningen, Netherlands; 2Department of Cell Biology, Yale School of Medicine, New Haven, United States; 3Department of Pathology, School of Medicine, University of Washington, Seattle, United States; 4DWI-Leibniz Institute for Interactive Materials, Aachen, Germany Abstract Cellular aging is a multifactorial process that is characterized by a decline in homeostatic capacity, best described at the molecular level. Physicochemical properties such as pH and macromolecular crowding are essential to all molecular processes in cells and require maintenance. Whether a drift in physicochemical properties contributes to the overall decline of homeostasis in aging is not known. Here, we show that the cytosol of yeast cells acidifies modestly in early aging and sharply after senescence. Using a macromolecular crowding sensor optimized for long-term FRET measurements, we show that crowding is rather stable and that the stability of crowding is a stronger predictor for lifespan than the absolute crowding levels. Additionally, in aged cells, we observe drastic changes in organellar volume, leading to crowding on the *For correspondence: micrometer scale, which we term organellar crowding. Our measurements provide an initial [email protected] framework of physicochemical parameters of replicatively aged yeast cells. (AJB); [email protected] (LMV) Competing interest: See Introduction page 19 Cellular aging is a process of progressive decline in homeostatic capacity (Gems and Partridge, Funding: See page 19 2013; Kirkwood, 2005).
    [Show full text]
  • A Global Analysis of Enzyme Compartmentalization to Glycosomes
    pathogens Article A Global Analysis of Enzyme Compartmentalization to Glycosomes Hina Durrani 1, Marshall Hampton 2 , Jon N. Rumbley 3 and Sara L. Zimmer 1,* 1 Department of Biomedical Sciences, University of Minnesota Medical School, Duluth Campus, Duluth, MN 55812, USA; [email protected] 2 Mathematics & Statistics Department, University of Minnesota Duluth, Duluth, MN 55812, USA; [email protected] 3 College of Pharmacy, University of Minnesota, Duluth Campus, Duluth, MN 55812, USA; [email protected] * Correspondence: [email protected] Received: 25 March 2020; Accepted: 9 April 2020; Published: 12 April 2020 Abstract: In kinetoplastids, the first seven steps of glycolysis are compartmentalized into a glycosome along with parts of other metabolic pathways. This organelle shares a common ancestor with the better-understood eukaryotic peroxisome. Much of our understanding of the emergence, evolution, and maintenance of glycosomes is limited to explorations of the dixenous parasites, including the enzymatic contents of the organelle. Our objective was to determine the extent that we could leverage existing studies in model kinetoplastids to determine the composition of glycosomes in species lacking evidence of experimental localization. These include diverse monoxenous species and dixenous species with very different hosts. For many of these, genome or transcriptome sequences are available. Our approach initiated with a meta-analysis of existing studies to generate a subset of enzymes with highest evidence of glycosome localization. From this dataset we extracted the best possible glycosome signal peptide identification scheme for in silico identification of glycosomal proteins from any kinetoplastid species. Validation suggested that a high glycosome localization score from our algorithm would be indicative of a glycosomal protein.
    [Show full text]