DOCSLIB.ORG

Trematodes (Ribeiroia) NICHOLAS GLADSTONE, CHEYENNE MULLINS, CHRISTIAN PEAKE

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Trematodes (Ribeiroia) NICHOLAS GLADSTONE, CHEYENNE MULLINS, CHRISTIAN PEAKE 4/24/17 Trematodes (Ribeiroia) NICHOLAS GLADSTONE, CHEYENNE MULLINS, CHRISTIAN PEAKE What are Trematodes? u Class within the Phylum Platyhelminthes (flatworms) u 18,000-28,000 trematode species u Digenetic Trematodes (subclass Digenea) represent majority of diversity – Our Focus u Obligate parasites of molluscs and vertebrates u Characterized by a dorso-ventrally flattened body and by the presence of both an oral and ventral ‘sucker’ Trematode Life Cycle u Life cycles often involve two or more intermediate hosts in addition to a definitive host u All trematodes have a molluscan intermediate host (usually a gastropod) u Other secondary hosts include: u Amphibians u Fish u Insects u The definitive host is generally a vertebrate u Adult trematodes then reside in the digestive tract of the definitive host 1 4/24/17 Habitat and Host-Parasite Interactions u Ribeiroia is specific to snails within the family Planorbidae for their first intermediate host u Distributed throughout North and South America u Occur in lentic or still water habitats u Average prevalence of 5% within snail populations u Post-snail parasitization, the metacercariae transition around the base of the hind limbs, cloaca, and o a lesser extent within the posterior coelom of an amphibian host. Distribution of Ribeiroia Why do We Care? u Malformed amphibians have increased over the last 30 years in several parts of North America u Recently, infection has been a widespread cause of limb malformations in both anurans and caudates u In laboratory infections, Ribeiroia parasites target the developing limb tissue of anuran larvae, inducing high rates of limb malformations similar to those in field reports 2 4/24/17 How do Trematodes Lead to Increased Amphibian Mortality? u Consequences of Ribeiroia infection include: u Extra limbs u Missing limbs u Skin Webbings u In response to Ribeiroia exposure, multiple species have been shown to exhibit reduced survivorship u Western Toads u Northern Leopard Frogs u Pacific Treefrogs Deformed Frog Parasite Life Cycle 3 4/24/17 References u Blaustein, Andrew R., Barbara A. Han, Rick A. Relyea, Pieter TJ Johnson, Julia C. Buck, Stephanie S. Gervasi, and Lee B. Kats. "The complexity of amphibian population declines: understanding the role of cofactors in driving amphibian losses." Annals of the New York Academy of Sciences 1223, no. 1 (2011): 108-119. u Bowerman, Jay, Pieter TJ Johnson, and Tracy Bowerman. "Sublethal predators and their injured prey: linking aquatic predators and severe limb abnormalities in amphibians." Ecology 91, no. 1 (2010): 242-251. u Collins, James P. "Amphibian decline and extinction: what we know and what we need to learn." Diseases of aquatic organisms 92, no. 2-3 (2010): 93-99. u Johnson, Pieter TJ, Kevin B. Lunde, Euan G. Ritchie, and Alan E. Launer. "The effect of trematode infection on amphibian limb development and survivorship." Science 284, no. 5415 (1999): 802-804. u Johnson, Pieter TJ, Daniel R. Sutherland, J. M. Kinsella, and Kevin B. Lunde. "Review of the trematode genus Ribeiroia (Psilostomidae): ecology, life history and pathogenesis with special emphasis on the amphibian malformation problem." Advances in parasitology 57 (2004): 191-253. u Johnson, P. T. J., and Lunde, K. B. 2005. Parasite infection and limb malformations: a growing problem in amphibian conservation. In: Lannoo, M. J., ed., Amphibian Declines: The Conservation Status of United States Species, pp. 124–138. California: University of California Press. u Rohr, J. R., T. R. Raffel, and Stanley K. Sessions. "Digenetic trematodes and their relationship to amphibian declines and deformities." Amphibian biology 8 (2009): 3067-3088. u Rohr, Jason R., Anna M. Schotthoefer, Thomas R. Raffel, Hunter J. Carrick, Neal Halstead, Jason T. Hoverman, Catherine M. Johnson et al. "Agrochemicals increase trematode infections in a declining amphibian species." Nature 455, no. 7217 (2008): 1235-1239. u Rohr, Jason R., Thomas R. Raffel, Stanley K. Sessions, and Peter J. Hudson. "Understanding the net effects of pesticides on amphibian trematode infections." Ecological Applications 18, no. 7 (2008): 1743-1753. u http://www.science-art.com/gallery/52/52_9222008161747.jpg u http://fwgna.org/species/planorbidae/H_anceps2.jpg 4 .
Load more

Recommended publications
  • Farm Ponds As Critical Habitats for Native Amphibians
    23 January 2002 Melinda G. Knutson Upper Midwest Environmental Sciences Center 2630 Fanta Reed Rd. La Crosse, WI 54603 608-783-7550 ext. 68; FAX 608-783-8058; Email [email protected] Farm Ponds As Critical Habitats For Native Amphibians: Field Season 2001 Interim Report Melinda G. Knutson, William B. Richardson, and Shawn Weick 1USGS Upper Midwest Environmental Sciences Center, 2630 Fanta Reed Rd., La Crosse, WI 54603 [email protected] Executive Summary: We studied constructed farm ponds in the Driftless Area Ecoregion of southeastern Minnesota during 2000 and 2001. These ponds represent potentially significant breeding, rearing, and over-wintering habitat for amphibians in a landscape where natural wetlands are scarce. We collected amphibian, wildlife, invertebrate, and water quality data from 40 randomly-selected farm ponds, 10 ponds in each of 4 surrounding land use classes: row crop agriculture, grazed grassland, ungrazed grassland, and natural wetlands. This report includes chapters detailing information from the investigations we conducted. Manuscripts are in preparation describing our scientific findings and several management and public information documents are in draft form. Each of these components will be peer reviewed during winter 2002, with a final report due to LCMR by June 30, 2002. The USGS has initiated an Amphibian Research and Monitoring Initiative (ARMI) over the last 2 years. We obtained additional funding ($98K) in 2000 and 2001 for the radiotelemetry component of the project via a competitive USGS ARMI grant. Field work will be ongoing in 2002 for this component. USGS Water Resources (John Elder, Middleton, WI) ran pesticide analyses on water samples collected June 2001 from seven of the study ponds.
    [Show full text]
  • Ecology of the Columbia Spotted Frog in Northeastern Oregon
    United States Department of Agriculture Ecology of the Columbia Forest Service Pacific Northwest Spotted Frog in Research Station General Technical Northeastern Oregon Report PNW-GTR-640 July 2005 Evelyn L. Bull The Forest Service of the U.S. Department of Agriculture is dedicated to the principle of multiple use management of the Nation’s forest resources for sus- tained yields of wood, water, forage, wildlife, and recreation. Through forestry research, cooperation with the States and private forest owners, and manage- ment of the National Forests and National Grasslands, it strives—as directed by Congress—to provide increasingly greater service to a growing Nation. The U.S. Department of Agriculture (USDA) prohibits discrimination in all its programs and activities on the basis of race, color, national origin, gender, reli- gion, age, disability, political beliefs, sexual orientation, or marital or family status. (Not all prohibited bases apply to all programs.) Persons with disabilities who require alternative means for communication of program information (Braille, large print, audiotape, etc.) should contact USDA’s TARGET Center at (202) 720-2600 (voice and TDD). To file a complaint of discrimination, write USDA, Director, Office of Civil Rights, Room 326-W, Whitten Building, 14th and Independence Avenue, SW, Washington, DC 20250-9410 or call (202) 720-5964 (voice and TDD). USDA is an equal opportunity provider and employer. USDA is committed to making the information materials accessible to all USDA customers and employees Author Evelyn L. Bull is a research wildlife biologist, Forestry and Range Sciences Laboratory, 1401 Gekeler Lane, La Grande, OR 97850. Cover photo Columbia spotted frogs at an oviposition site with an egg mass present (lower center of photo).
    [Show full text]
  • Detection of the Parasite Ribeiroia Ondatrae in Water Bodies and Possible Impacts of Malformations in a Frog Host
    Detection of the parasite Ribeiroia ondatrae in water bodies and possible impacts of malformations in a frog host. by Johannes Huver A Thesis submitted to the Faculty of Graduate Studies of The University of Manitoba in partial fulfillment of the requirements of the degree of MASTER OF SCIENCE Department of Biological Sciences University of Manitoba Winnipeg Copyright© 2013 by Johannes Huver Abstract This study devised a method to detect Ribeiroia ondatrae (class Trematoda) in water-bodies using environmental DNA (eDNA) collected from filtered water samples from selected ponds in the USA and Canada. Species-specific PCR primers were designed to target the Internal Transcribed Spacer-2 (ITS-2) region of the parasite’s genome. The qualitative PCR method was 70% (n=10) accurate in detecting R. ondatrae in ponds previously found to contain the parasite, while the qPCR method was 88.9% (n=9). To examine how the retinoic acid (RA) pathway gene expression may be perturbed during R. ondatrae infections, leading to limb development abnormalities in the wood frog (Lithobates sylvaticus). Multiple sequence alignments were used to design degenerate PCR primers to eight RA biosynthesis genes, but only two gene fragments were identified using this approach. Without effective primer sets it was not possible to measure changes in gene expression in infected frogs. i Acknowledgements This project has been an exciting and challenging journey that I could not have completed on my own. Above all I would like to thank my project supervisors, Dr. Steve Whyard and Dr. Janet Koprivnikar for taking me under their wings and allowing me to conduct this project and who have provided me with a vast amount of support, knowledge, skill, insight and time.
    [Show full text]
  • Curriculum Vitae L
    Curriculum Vitae L. KEALOHA FREIDENBURG ADDRESS 370 Prospect Street School of Forestry & Environmental Studies Phone: (203) 432-5732 Yale University Fax: (203) 432-3929 New Haven, CT 06511 [email protected] EDUCATION 1986-1990 B.A., Biology, Pomona College. 1992-1995 M.S., School of Fisheries, University of Washington. 1997-2003 Ph.D., Department of Ecology & Evolutionary Biology, University of Connecticut. PROFESSIONAL POSITIONS 2012- Lecturer, School of Forestry & Environmental Studies, Yale University 2007-2018 Research Scientist, School of Forestry & Environmental Studies, Yale University. 2010-2011 Adjunct Assistant Professor, Biology Department, Quinnipiac University. 2004-2007 Associate Research Scientist, School of Forestry & Environmental Studies, Yale University. 2003-2006 Lecturer, Department of Ecology & Evolutionary Biology, Yale University. 2004 Visiting Scholar, School of Life Sciences, University of Queensland. 1997-2001 Graduate Teaching Assistant, Department of Ecology & Evolutionary Biology, University of Connecticut. 1996-1997 Teaching Assistant, School of Forestry & Environmental Studies, Yale University. 1996 Program Coordinator, Center for Coastal & Watershed Systems, School of Forestry & Environmental Studies, Yale University. 1994 Fisheries Biologist, National Biological Service, Seattle, Washington. 1991-1992 Fisheries Biologist, U.S. Fish and Wildlife Service, Cook, Washington. LK Freidenburg [email protected] PEER REVIEWED PUBLICATIONS Lambert, M. R., M. S. Smylie, A. J. Roman, L. K. Freidenburg, and D. K. Skelly. 2018. Sexual and somatic development of wood frog tadpoles along a thermal gradient. Journal of Experimental Zoology Part A. 39:1-8. Holgerson, M.A., M. R. Lambert, L. K. Freidenburg, and D. K. Skelly. 2017. Suburbanization alters small pond ecosystems: shifts in nitrogen and food web dynamics. Canadian Journal of Fisheries and Aquatic Sciences.
    [Show full text]
  • A Molecular Phylogenetic Study of the Genus Ribeiroia (Digenea): Trematodes Known to Cause Limb Malformations in Amphibians
    J. Parasitol., 91(5), 2005, pp. 1040±1045 q American Society of Parasitologists 2005 A MOLECULAR PHYLOGENETIC STUDY OF THE GENUS RIBEIROIA (DIGENEA): TREMATODES KNOWN TO CAUSE LIMB MALFORMATIONS IN AMPHIBIANS Wade D. Wilson, Pieter T. J. Johnson*, Daniel R. Sutherland²,HeÂleÁne Mone³, and Eric S. Loker Department of Biology, University of New Mexico, Albuquerque, New Mexico 87131. e-mail: [email protected] ABSTRACT: Species of Ribeiroia (Trematoda: Psilostomidae) are known to cause severe limb malformations and elevated mor- tality in amphibians. However, little is known regarding the number of species in this genus or its relation to other taxa. Species of Ribeiroia have historically been differentiated by slight differences among their larval stages. To better understand the sys- tematics and biogeography of this genus and their potential relevance to the distribution of malformed amphibians, specimens identi®ed as Ribeiroia were collected across much of the known range, including samples from 5 states in the United States (8 sites) and 2 islands in the Caribbean (Puerto Rico and Guadeloupe). A cercaria from East Africa identi®ed as Cercaria lileta (Fain, 1953), with attributes suggestive of Ribeiroia (possibly R. congolensis), was also examined. The intertranscribed spacer region 2 (ITS-2) of the ribosomal gene complex was sequenced and found to consist of 429 nucleotides (nt) for R. ondatrae (United States) and 427 nt for R. marini (Caribbean), with only 6 base differences noted between the 2 species. The ITS-2 region of C. lileta (429 nt) aligned closely with those of the 2 other Ribeiroia species in a phylogenetic analysis that included related trematode genera.
    [Show full text]
  • Northern Leopard Frog Lithobates Pipiens
    Appendix A: Amphibians Northern Leopard Frog Lithobates pipiens Federal Listing N/A State Listing SC Global Rank G5 State Rank S3 High Regional Status Photo by Michael Marchand Justification (Reason for Concern in NH) Northern leopard frogs have apparently declined throughout much of New England and are listed as a species of high regional concern in the northeast (NEPARC 2010, Weir et al. 2014). The decline is likely related to development of floodplains, conversion of grassland habitat and farm abandonment and forest regeneration. The current distribution and abundance of northern leopard frogs and the status of remaining populations in New Hampshire is poorly known. Distribution The northern leopard frog has a broad distribution in the United States and Canada. Northern leopard frogs range from New England to the mid‐Atlantic to west of the Rockies, and in Canada, populations exist from southeastern British Columbia east to the Maritimes. The northern leopard frog is absent from most of the southeast. The recent description of a new leopard frog species, the Atlantic coast leopard frog (Lithobates kauffeldi), likely reduces the previously proposed range and distribution of the northern leopard frog. Feinberg et al. (2014) documented this new species centered in New York City as well as throughout Long Island, eastern Pennsylvania, southern Connecticut, and New Jersey. More research will likely improve the resolution of distribution maps and where overlap exists between the northern, Atlantic coast, and southern leopard frogs (Lithobates sphenocephalus). Throughout its range, the northern leopard frog often has a spotty distribution, and is considered critically imperiled (S1) or imperiled (S2) in several states in the west and south and in British Columbia.
    [Show full text]
  • Effects of Trematode Parasites on Snails and Northern Leopard Frogs (Lithobates Pipiens) in Pesticide-Exposed Mesocosm Communities
    Journal of Herpetology, Vol. 55, No. 3, 229–236, 2021 Copyright 2021 Society for the Study of Amphibians and Reptiles Effects of Trematode Parasites on Snails and Northern Leopard Frogs (Lithobates pipiens) in Pesticide-Exposed Mesocosm Communities 1,2 1 MIRANDA STRASBURG AND MICHELLE D. BOONE 1Department of Biology, Miami University, Oxford, Ohio, 45056, USA ABSTRACT.—Chemical contamination of aquatic environments is widespread, but we have a limited understanding of how Downloaded from http://meridian.allenpress.com/journal-of-herpetology/article-pdf/55/3/229/2891162/i0022-1511-55-3-229.pdf by guest on 29 September 2021 contaminants alter critical host–parasite interactions that can influence disease dynamics. We manipulated Northern Leopard Frog (Lithobates pipiens) exposure to pesticides (no pesticides, the insecticide Bacillus thuringiensis israelensis [Bti], or the herbicide atrazine) and trematode-infected (Ribeiroia ondatrae and Echinostoma spp.) snails in outdoor mesocosms. Bti exposure extended host larval period, and atrazine exposure had a nonsignificant trend toward reducing host survival; however, neither pesticide influenced parasite success nor magnified the effects of parasites on their hosts. Parasites negatively influenced tadpole development and, by metamorphosis, parasitized frogs had severe limb deformities and greater mass than unparasitized frogs. The greater mass in parasitized frogs may have resulted from reduced competition between tadpoles and snails for algal resources because parasites decreased snail abundance in mesocosms. Reduced competition between tadpoles and snails may offset the direct negative effects of trematodes on tadpoles, enabling them to survive with high infection intensities. Trematodes may further facilitate their own success by inducing limb deformities that likely increase anuran consumption by definitive hosts.
    [Show full text]
  • Podcast: Common Parasites Infecting Amphibians
    Amphibian Parasites Nikki Maxwell University of Tennessee 4 March 2008 Lecture Outline • Overview of different types of amphibian parasites • Current information on mechanisms and effects of each type of parasite • Future directions for research concerning amphibian parasites What is a parasite? • A parasite is a plant or an animal that lives on or inside another living organism (host). A parasite is dependent on its host and obtains some benefit, such as survival, usually at the host’s expense 1 Types of Amphibian Parasites • Metazoans (including trematodes and nematodes) • Protozoans • Endoparasitic mites • Ectoparasites (including leeches and flies) Trematode Ribeiroia ondantrae • Frogs were exposed to varying amounts of Ribeiroia cercariae (0, 16, 32, or 48) • Malformations were found in 85% of frogs surviving to metamorphosis Abnormalities • Frequency of abnormalities was positively correlated with parasite density Survival • Severity of abnormalities also increased with parasite density • Few abnormal adult frogs were seen in study – Indirect mortality resulting from increased predation of frogs with malformations Trematode Ribeiroia ondatrae • Cercariae of Ribeiroia encyst around limb buds • Side effects are malformations including multiple extra limbs, skin webbings, bony triangles, and missing or partially missing limbs • An important note: To induce malformations, Ribeiroia must encyst during the window of early limb development. Amphibians exposed after limb development is completed are unlikely to develop malformations 2 Trematode
    [Show full text]
  • Parasite Infection and Limb Malformations: a Growing Problem in Amphibian Conservation
    TWENTY Parasite Infection and Limb Malformations: A Growing Problem in Amphibian Conservation PIETER T.J. JOHNSON AND KEVIN B. LUNDE Over the last two decades, scientists have become increasingly and Hoppe, 1999), and parasites (Sessions and Ruth, 1990; concerned about ongoing trends of amphibian population de- Johnson et al., 1999; Sessions et al., 1999). The recent and cline and extinction (Blaustein and Wake, 1990, 1995; Phillips, widespread nature of the malformations has focused the in- 1990; Pechmann et al., 1991; Wake, 1998). Parasitic pathogens, vestigation on the direct and indirect impacts of human activ- including certain bacteria, fungi, viruses, and helminths ity. One of the prime suspects in the East and Midwest has (see also Sutherland, this volume), have frequently been impli- been water contaminants. Ouellet et al. (1997a) documented cated as causes of gross pathology and mass die-offs, often in high rates of limb malformations in amphibians from agricul- synergism with environmental stressors (Dusi, 1949; Elkan, tural ponds in southeastern Canada; laboratory researchers in 1960; Elkan and Reichenbach-Klinke, 1974; Nyman, 1986; Minnesota have found that water from affected ponds causes Worthylake and Hovingh, 1989; Carey, 1993; Blaustein et al., some malformations in African-clawed frog (Xenopus laevis) 1994b; Faeh et al., 1998; Berger et al., 1998; Morell, 1999; embryos and larvae. Identification of the active compounds Kiesecker, 2002; Lannoo et al., 2003). The effects of human and their role in amphibian limb malformations in the field activity on the epidemiology of endemic and emerging dis- remains under investigation (Fort et al., 1999b). The wide geo- eases remain largely unknown (Kiesecker and Blaustein, 1995; graphic range in North America with reports of abnormal am- Laurance et al., 1996).
    [Show full text]
  • Salamander News
    Salamander News No. 6 June 2014 www.yearofthesalamander.org Salamanders in a World of Pathogens Vanessa Wuerthner and Jason Hoverman, Department of Forestry and Natural Resources, Purdue University Salamander populations around the world are in decline, with about 50% of species threatened globally. Habitat destruction and pollution are major contributors to these declines, but emerging infectious diseases are an increasing concern. Natural systems contain a diversity of pathogens including fungi, viruses, bacteria, and parasitic worms. While most pathogens pose minimal risk to salamander populations, a few have been linked to severe malformations, massive die-off events, or extinctions. Plethodontid salamanders such as this Red-cheeked (Jordan’s) Here, we focus on highly virulent pathogens that have Salamander (Plethodon jordani) appear to be relatively resistant been identified in salamander populations, to increase to infection by the amphibian chytrid fungus (Batrachochytrium awareness of their effects on host pathology and dendrobatidis) due to antimicrobial skin peptides. Photo: Nathan mortality. Haislip The amphibian chytrid fungus, Batrachochytrium dendrobatidis, is the best-known pathogen of salamanders. This fungal pathogen, which thrives in moist habitats, has been detected in amphibian populations across the globe and has been implicated in the decline and extinction of numerous species. Chytridiomycosis, the disease caused by the fungus, was first described in amphibian populations experiencing mass mortality in Australia and Panama in 1998. Recently, another chytrid species, Batrachochytrium salamandrivorans, was discovered in populations of the Fire Salamander (Salamandra salamandra) in the Netherlands. Extensive research efforts over the past decade have helped us understand this pathogen and its impact on amphibian hosts. The fungus has a free-living zoospore stage that seeks out hosts in aquatic Inside: page environments or during direct contact between infected individuals.
    [Show full text]
  • Malformed Frogs in Vermont
    Malformed Frogs in Vermont In the summer of 1996 occurrences of abnormal frogs were reported by the public to the Vermont Department of Environmental Conservation from 12 sites. The twelve sites reported to have abnormal frogs were all located within the Lake Champlain Basin and spanned over 120 miles of Lake Champlain from the northenmost sites close to the Canadian border to the southernmost site near the Poultney River. VT DEC staff surveyed four of the reported locations in 1996 and found abnormal frogs at all four of the sites. All of the abnormalities encountered were with young of the year northern leopard frogs (Rana pipiens). A total of 290 northern leopard frogs were collected at the four sites, 13.1% of the frogs had observable external abnormalities. Abnormality rates ranged from 5 - 23%. In 1997 survey work targeting the northern leopard frog was conducted by VT DEC, USEPA, USFWS, USGS-BRD and Middlebury College. This set the frame work for additional surveys conducted through 2000. During the 1997 survey over 2500 northern leopard frogs were examined from 19 sites representing 13 towns in 5 counties of Vermont. Roughly 8% of the frogs examined had some category of abnormality. Laboratory experiments conducted on normal and abnormal frog samples from the 1997 sites indicated that the abnormalities were not caused by viruses, bacteria, or parasites. Abnormal frogs were found at 17 of the 19 sites surveyed. Categories of abnormalities were primarily missing and partial hind limbs and shortened and missing digits. Systematic field surveys have now been conducted by VT DEC for five consecutive summers (1997- 2002) at a total of 20 sites within the Lake Champlain Basin.
    [Show full text]
  • The Scientific Method and Basic Statistics
    The Scientific Method and Basic Statistics Objectives: Understand the steps in the Scientific Method Be able to describe basic statistical parameters and how they relate to the Normal (Gaussian) Distribution Model Be able to explain how hypotheses are tested; supported or rejected. What Do Scientists Do? •Scientists collect data and develop theories, models, and laws about how nature works. Science searches for natural causes to explain natural phenomenon 1. Purpose of science a. to determine cause and effect b. to gain insight into natural events 2. Science does not include “absolutes” 3. Science provides tentative explanations to explain natural phenomenon 4. Fundamental basis of science: The Principal of Uncertainty “Science cannot prove anything, nor is it a search for the ‘truth’.” 1. Science develops tentative answers for guesses (hypotheses) based on evidence 2. Theory - when supporting evidence is very strong! Science Is a Search for Order in Nature Identify a problem Find out what is known about the problem Ask a question to be investigated Gather data through experiments Propose a scientific hypothesis Science Is a Search for Order in Nature Make testable predictions Keep testing and making observations Accept or reject the hypothesis Scientific theory: well-tested and widely accepted hypothesis Characteristics of Science…and Scientists Curiosity Skepticism Reproducibility Peer review Openness to new ideas Critical thinking Creativity Observation: Nothing happens when I try to turn on my flashlight. Question: Why didn’t the light come on? Are the batteries dead? Hypothesis: Maybe the batteries are dead. Test hypothesis with an experiment: Put in new batteries and try to turn on the flashlight.
    [Show full text]