DOCSLIB.ORG

Protists Directions: Read and Highlight Answering the Questions As You Go

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Protists Directions: Read and Highlight Answering the Questions As You Go Protists Directions: Read and highlight answering the questions as you go. I always refer to myself as the odd ball that isn’t like anyone else (thank goodness huh?). In life terms, that would make me a protist or, more specifically, part of the protista kingdom of organisms. If protists have one thing in common, it’s that they are not other living things‐ they are not bacteria or fungi, they are not plants or animals. And that’s how scientists set about placing them in their own category. Not very creative is it? But where did protists themselves come from? The earliest protists we can recognize in the fossil record date back to about 1.2 billion years ago compared to bacteria which appear about 3.5 billion years ago. We do not know how the various groups of protists are related to one another. We assume they arose from certain groups of bacteria, but when and how they came into being, scientists are still investigating (yeah, somebody has that job ;‐). Protists include many different types of organisms, such as algae, kelp, and paramecium. No one knows how many species there are in total, though estimates range between 65,000 to 200,000. All protists are eukaryotes (cells with a nucleus) and have organelles like mitochondria and chloroplasts. They can be either unicellular or multi‐cellular although most in this group are unicellular. 1. How did scientists figure out which organisms were protists? ______________________________________ ________________________________________________________________________________________ Obtain and Use Energy Just like bacteria, protists eat in a variety of ways. Some protists are photoautotrophs, manufacturing their own energy by photosynthesis (using sunlight). Algae and kelp are great examples of a protist that uses photosynthesis to eat. Other protists are heterotrophs, just like us, getting their energy by eating other organisms (especially the photoautotrophs). There are no chemoautotrophs protists. That type of eater is something only bacteria can be (as far as we know). The photoautotrophs are very similar to plants. They have chloroplasts that are responsible for absorbing the sunlight and turning it into useable energy. As for the heterotrophs, these protists eat by engulfing their food in their cell membrane. The cell membrane surrounds the food and then pinches off a section of membrane to form a hollow space inside the cell. Interestingly, this hollow space, now enclosed by the cell membrane, is called a vacuole. Protists also use vacuoles to store water and waste just like our cells do. Paramecium and many other protists also have a vacuole similar to a lysosome, which drains the cell of waste products and squirts them outside the cell. All protists are aquatic meaning they live in the water. In order to use this energy, many protists can move through the water by means of flagella or cilia. Cilia and flagella are tiny moving hairs. Cilia are like lots of small tiny hairs along the side of a cell while flagella are more like a long hair similar to a tail. 2. How do heterotroph protists get their food? ___________________________________________________ 3. How do protists move through the water? _____________________________________________________ DelliGatti – Protists.docx Reproduction Protists reproduce asexually through binary fission while a few species are capable of sexual reproduction (2 parents). Animal‐like amoebas and plant‐like Euglena reproduce asexually meaning the only have binary fission. In this case, when the parent cell splits in half, there is an exact chromosome copy in each daughter cell. Paramecium (what we are looking for in pond water) can actually reproduce 2 ways. Normally they reproduce using binary fission. If they get stressed, they will find a partner and reproduce sexually. In this case, it requires 2 parents. The offspring will have parts of both parents in its chromosome similar to how both of your parents have given you equal parts of their chromosomes. 4. How is binary fission different than sexual reproduction? _________________________________________ Grow and Develop All protists are different shapes and Sizes. Most are so tiny that they can’t be seen without a microscope. Protists are categorized into three Groups. They are fungus‐like, animal‐like, and plant‐like. It’s funny how scientists define protists as eukaryotic cells that are not animal, plant or fungus, but then they turn around and compare them back to animals, plants, and fungus. Protists are so small that they do not need any special organs to get rid of wastes (no lysosome even though they have a vacuole that does something similar). They rely on diffusion, the movement of materials from an area of high concentration to an area of low concentration, to move gases and waste materials in and out of the cell. Diffusion only works if you’re really small, so most protists are limited to being small single cells. Another reason protists are small is because the cilia or flagella cannot provide enough energy to move a large cell through the water. So if they are too slow, they get eaten while those that are smaller and faster get to make more protists. 5. Name 2 reasons protists are so tiny __________________________________________________________ _______________________________________________________________________________________ Adaptation and Response Protists have adapted over the many years. For example, the cilia and flagella limit size preventing larger protists from growing not to mention those born without an ability to move get eaten. Another interesting improvement comes from the paramecium. When the paramecium is attacked or feels threatened, it unleashes its defense system ‐ a battery of harpoon‐like spears called trichocysts. Most remain attached to the Paramecium, but some are actually thrown a short distance. Under very high magnification these trichocysts appear as long spears, with sharp pointed ends, much like whalers' harpoons. Often, the paramecium will release everything at its disposal, including undigested food, digested waste and waste water. 6. Name two similarities between bacteria and protists. a. b. 7. Name two differences between bacteria and protists. a. b. .
Load more

Recommended publications
  • Antony Van Leeuwenhoek, the Father of Microscope
    Turkish Journal of Biochemistry – Türk Biyokimya Dergisi 2016; 41(1): 58–62 Education Sector Letter to the Editor – 93585 Emine Elif Vatanoğlu-Lutz*, Ahmet Doğan Ataman Medicine in philately: Antony Van Leeuwenhoek, the father of microscope Pullardaki tıp: Antony Van Leeuwenhoek, mikroskobun kaşifi DOI 10.1515/tjb-2016-0010 only one lens to look at blood, insects and many other Received September 16, 2015; accepted December 1, 2015 objects. He was first to describe cells and bacteria, seen through his very small microscopes with, for his time, The origin of the word microscope comes from two Greek extremely good lenses (Figure 1) [3]. words, “uikpos,” small and “okottew,” view. It has been After van Leeuwenhoek’s contribution,there were big known for over 2000 years that glass bends light. In the steps in the world of microscopes. Several technical inno- 2nd century BC, Claudius Ptolemy described a stick appear- vations made microscopes better and easier to handle, ing to bend in a pool of water, and accurately recorded the which led to microscopy becoming more and more popular angles to within half a degree. He then very accurately among scientists. An important discovery was that lenses calculated the refraction constant of water. During the combining two types of glass could reduce the chromatic 1st century,around year 100, glass had been invented and effect, with its disturbing halos resulting from differences the Romans were looking through the glass and testing in refraction of light (Figure 2) [4]. it. They experimented with different shapes of clear glass In 1830, Joseph Jackson Lister reduced the problem and one of their samples was thick in the middle and thin with spherical aberration by showing that several weak on the edges [1].
    [Show full text]
  • 8113-Yasham Neden Var-Nick Lane-Ebru Qilic-2015-318S.Pdf
    KOÇ ÜNiVERSiTESi YAYINLARI: 87 BiYOLOJi Yaşam Neden Var? Nick Lane lngilizceden çeviren: Ebru Kılıç Yayına hazırlayan: Hülya Haripoğlu Düzelti: Elvan Özkaya iç rasarım: Kamuran Ok Kapak rasarımı: James Jones The Vital Question © Nick Lane, 2015 ©Koç Üniversiresi Yayınları, 2015 1. Baskı: lsranbul, Nisan 2016 Bu kitabın yazarı, eserin kendi orijinal yararımı olduğunu ve eserde dile getirilen rüm görüşlerin kendisine air olduğunu, bunlardan dolayı kendisinden başka kimsenin sorumlu rurulamayacağını; eserde üçüncü şahısların haklarını ihlal edebilecek kısımlar olmadığını kabul eder. Baskı: 12.marbaa Sertifika no: 33094 Naro Caddesi 14/1 Seyranrepe Kağırhane/lsranbul +90 212 284 0226 Koç Üniversiresi Yayınları lsriklal Caddesi No:181 Merkez Han Beyoğlu/lsranbul +90 212 393 6000 [email protected] • www.kocuniversirypress.com • www.kocuniversiresiyayinlari.com Koç Universiry Suna Kıraç Library Caraloging-in-Publicarion Dara Lane, Nick, 1967- Yaşam neden var?/ Nick Lane; lngilizceden çeviren Ebru Kılıç; yayına hazırlayan Hülya Haripoğlu. pages; cm. lncludes bibliographical references and index. ISBN 978-605-5250-94-2 ı. Life--Origin--Popular works. 2. Cells. 1. Kılıç, Ebru. il. Haripoğlu, Hülya. 111. Tirle. QH325.L3520 2016 Yaşam Neden Var? NICKLANE lngilizceden Çeviren: Ebru Kılıç ffi1KÜY İçindeki le� Resim Listesi 7 TEŞEKKÜR 11 GiRİŞ 17 Yaşam Neden Olduğu Gibidir? BiRİNCi BÖLÜM 31 Yaşam Nedir? Yaşamın ilk 2 Milyar Yılının Kısa Ta rihi 35 Genler ve Doğal Ortamla ilgili Sorun 39 Biyolojinin Kalbindeki Kara Delik 43 Karmaşıklık Yo lunda Kayıp Adımlar
    [Show full text]
  • PROTISTS Shore and the Waves Are Large, Often the Largest of a Storm Event, and with a Long Period
    (seas), and these waves can mobilize boulders. During this phase of the storm the rapid changes in current direction caused by these large, short-period waves generate high accelerative forces, and it is these forces that ultimately can move even large boulders. Traditionally, most rocky-intertidal ecological stud- ies have been conducted on rocky platforms where the substrate is composed of stable basement rock. Projec- tiles tend to be uncommon in these types of habitats, and damage from projectiles is usually light. Perhaps for this reason the role of projectiles in intertidal ecology has received little attention. Boulder-fi eld intertidal zones are as common as, if not more common than, rock plat- forms. In boulder fi elds, projectiles are abundant, and the evidence of damage due to projectiles is obvious. Here projectiles may be one of the most important defi ning physical forces in the habitat. SEE ALSO THE FOLLOWING ARTICLES Geology, Coastal / Habitat Alteration / Hydrodynamic Forces / Wave Exposure FURTHER READING Carstens. T. 1968. Wave forces on boundaries and submerged bodies. Sarsia FIGURE 6 The intertidal zone on the north side of Cape Blanco, 34: 37–60. Oregon. The large, smooth boulders are made of serpentine, while Dayton, P. K. 1971. Competition, disturbance, and community organi- the surrounding rock from which the intertidal platform is formed zation: the provision and subsequent utilization of space in a rocky is sandstone. The smooth boulders are from a source outside the intertidal community. Ecological Monographs 45: 137–159. intertidal zone and were carried into the intertidal zone by waves. Levin, S. A., and R.
    [Show full text]
  • Protist Phylogeny and the High-Level Classification of Protozoa
    Europ. J. Protistol. 39, 338–348 (2003) © Urban & Fischer Verlag http://www.urbanfischer.de/journals/ejp Protist phylogeny and the high-level classification of Protozoa Thomas Cavalier-Smith Department of Zoology, University of Oxford, South Parks Road, Oxford, OX1 3PS, UK; E-mail: [email protected] Received 1 September 2003; 29 September 2003. Accepted: 29 September 2003 Protist large-scale phylogeny is briefly reviewed and a revised higher classification of the kingdom Pro- tozoa into 11 phyla presented. Complementary gene fusions reveal a fundamental bifurcation among eu- karyotes between two major clades: the ancestrally uniciliate (often unicentriolar) unikonts and the an- cestrally biciliate bikonts, which undergo ciliary transformation by converting a younger anterior cilium into a dissimilar older posterior cilium. Unikonts comprise the ancestrally unikont protozoan phylum Amoebozoa and the opisthokonts (kingdom Animalia, phylum Choanozoa, their sisters or ancestors; and kingdom Fungi). They share a derived triple-gene fusion, absent from bikonts. Bikonts contrastingly share a derived gene fusion between dihydrofolate reductase and thymidylate synthase and include plants and all other protists, comprising the protozoan infrakingdoms Rhizaria [phyla Cercozoa and Re- taria (Radiozoa, Foraminifera)] and Excavata (phyla Loukozoa, Metamonada, Euglenozoa, Percolozoa), plus the kingdom Plantae [Viridaeplantae, Rhodophyta (sisters); Glaucophyta], the chromalveolate clade, and the protozoan phylum Apusozoa (Thecomonadea, Diphylleida). Chromalveolates comprise kingdom Chromista (Cryptista, Heterokonta, Haptophyta) and the protozoan infrakingdom Alveolata [phyla Cilio- phora and Miozoa (= Protalveolata, Dinozoa, Apicomplexa)], which diverged from a common ancestor that enslaved a red alga and evolved novel plastid protein-targeting machinery via the host rough ER and the enslaved algal plasma membrane (periplastid membrane).
    [Show full text]
  • Protists/Fungi Station Lab Information
    Protists/Fungi Station Lab Information 1 Protists Information Background: Perhaps the most strikingly diverse group of organisms on Earth is that of the Protists, Found almost anywhere there is water – from puddles to sediments. Protists rely on water. Somea re marine (salt water), some are freshwater, some are terrestrial (land dwellers) in moist soil and some are parasites which live in the tissues of others. The Protist kingdom is made up of a wide variety of eukaryotic cells. All protist cells have nuclei and other characteristics eukaryotic features. Some protists have more than one nucleus and are called “multinucleated”. Cellular Organization: Protists show a variety in cellular organization: single celled (unicellular), groups of single cells living together in a close and permanent association (colonies or filaments) or many cells = multicellular organization (ex. Seaweed). Obtaining food: There is a variety in how protists get their food. Like plants, many protists are autotrophs, meaning they make their own food through photosynthesis and store it as starch. It is estimated that green protist cells chemically capture and process over a billion tons of carbon in the Earth’s oceans and freshwater ponds every year. Photosynthetic or “green” protists have a multitude of membrane-enclosed bags (chloroplasts) which contain the photosynthetic green pigment called chlorophyll. Many of these organisms’ cell walls are similar to that of plant cells and are made of cellulose. Others are “heterotrophs”. Like animals, they eat other organisms or, like fungi, receiving their nourishment from absorbing nutrient molecules from their surroundings or digest living things. Some are parasitic and feed off of a living host.
    [Show full text]
  • Brown Algae and 4) the Oomycetes (Water Molds)
    Protista Classification Excavata The kingdom Protista (in the five kingdom system) contains mostly unicellular eukaryotes. This taxonomic grouping is polyphyletic and based only Alveolates on cellular structure and life styles not on any molecular evidence. Using molecular biology and detailed comparison of cell structure, scientists are now beginning to see evolutionary SAR Stramenopila history in the protists. The ongoing changes in the protest phylogeny are rapidly changing with each new piece of evidence. The following classification suggests 4 “supergroups” within the Rhizaria original Protista kingdom and the taxonomy is still being worked out. This lab is looking at one current hypothesis shown on the right. Some of the organisms are grouped together because Archaeplastida of very strong support and others are controversial. It is important to focus on the characteristics of each clade which explains why they are grouped together. This lab will only look at the groups that Amoebozoans were once included in the Protista kingdom and the other groups (higher plants, fungi, and animals) will be Unikonta examined in future labs. Opisthokonts Protista Classification Excavata Starting with the four “Supergroups”, we will divide the rest into different levels called clades. A Clade is defined as a group of Alveolates biological taxa (as species) that includes all descendants of one common ancestor. Too simplify this process, we have included a cladogram we will be using throughout the SAR Stramenopila course. We will divide or expand parts of the cladogram to emphasize evolutionary relationships. For the protists, we will divide Rhizaria the supergroups into smaller clades assigning them artificial numbers (clade1, clade2, clade3) to establish a grouping at a specific level.
    [Show full text]
  • Chlorophyceae Incertae Sedis, Viridiplantae), Described from Europe
    Preslia 87: 403–416, 2015 403 A new species Jenufa aeroterrestrica (Chlorophyceae incertae sedis, Viridiplantae), described from Europe Nový druh Jenufa aeroterrestrica (Chlorophyceae incertae sedis, Viridiplantae), popsaný z Evropy KateřinaProcházková,YvonneNěmcová&JiříNeustupa Department of Botany, Faculty of Science, Charles University of Prague, Benátská 2, CZ-128 01 Prague, Czech Republic, e-mail: [email protected] Procházková K., Němcová Y. & Neustupa J. (2015): A new species Jenufa aeroterrestrica (Chlorophyceae incertae sedis, Viridiplantae), described from Europe. – Preslia 87: 403–416. The chlorophycean genus Jenufa includes chlorelloid green microalgae with an irregularly spher- ical cell outline and a parietal perforated chloroplast with numerous lobes. Two species of the genus are known from tropical microhabitats. However, sequences recently obtained from vari- ous temperate subaerial biofilms indicate that members of the Jenufa lineage do not only occur in the tropics. In this paper, we describe and characterize a new species of the genus Jenufa, J. aero- terrestrica, which was identified in five samples of corticolous microalgal biofilms collected in Europe. These strains shared the general morphological and ultrastructural features of the genus Jenufa, but differed in having a larger average cell size and higher numbers of autospores. Phylo- genetic analyses showed that the strains clustered in a sister position to two previously described tropical species, together with previously published European 18S rDNA sequences. This pattern was also supported by the ITS2 rDNA sequences of the genus Jenufa. Our data and previously published sequences indicate that the newly described species J. aeroterrestrica frequently occurs in temperate and sub-Mediterranean European subaerial biofilms, such as those occurring on tree bark or surfaces of stone buildings.
    [Show full text]
  • Protist Review.Pdf
    Protists Termite mound Section 1 Introduction to Protists -!). )DEA Protists form a diverse group of organisms that are subdivided based on their method of obtaining nutrition. Termite colony Section 2 Protozoans— Animal-like Protists -!). )DEA Protozoans are animal-like, heterotrophic protists. Section 3 Algae—Plantlike Protists -!). )DEA Algae are plantlike, autotrophic protists that are the producers for aquatic ecosystems. Section 4 Termites Funguslike Protists SEM Magnification: 17؋ -!). )DEA Funguslike protists obtain their nutrition by absorbing nutrients from dead or decaying organisms. BioFacts • A protist that lives symbiotically Protists in termite gut in the gut of termites helps it LM Magnification: 65؋ digest cellulose found in wood. • The amoeba Amoeba proteus is so small that it can survive in the film of water surrounding particles of soil. • An estimated five million protists can live in one teaspoon of soil. 540 (t)Oliver Meckes/Nicole Ottawa/Photo Researchers, (c)Gerald and Buff Corsi/Visuals Unlimited, (b)Michael Abbey/Photo Researchers , (bkgd)Gerald and Buff Corsi/Visuals Unlimited Start-Up Activities Classify Protists Make this LAUNCH Lab Foldable to help you organize the characteristics of protists. What is a protist? The Kingdom Protista is similar to a drawer or closet in which you keep odds and ends that do not seem to fit any other place. The Kingdom Protista is composed of three groups of organisms that do not fit in any STEP 1 Fold a sheet of notebook paper other kingdom. In this lab, you will observe the three in half vertically. Fold the sheet into thirds. groups of protists. Procedure 1.
    [Show full text]
  • Sanchytriaceae, Fungi Incertae Sedis) Confirms Its Close Relationship to Amoeboradix Sergey Karpov, Andrey Vishnyakov, David Moreira, Purificacion Lopez-Garcia
    The Ultrastructure of Sanchytrium tribonematis (Sanchytriaceae, Fungi incertae sedis) Confirms its Close Relationship to Amoeboradix Sergey Karpov, Andrey Vishnyakov, David Moreira, Purificacion Lopez-Garcia To cite this version: Sergey Karpov, Andrey Vishnyakov, David Moreira, Purificacion Lopez-Garcia. The Ultrastructure of Sanchytrium tribonematis (Sanchytriaceae, Fungi incertae sedis) Confirms its Close Relationship to Amoeboradix. Journal of Eukaryotic Microbiology, Wiley, 2019, 10.1111/jeu.12740. hal-02365842 HAL Id: hal-02365842 https://hal.archives-ouvertes.fr/hal-02365842 Submitted on 15 Nov 2019 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. The Ultrastructure of Sanchytrium tribonematis (Sanchytriaceae, Fungi incertae sedis) Confirms its Close Relationship to Amoeboradix Sergey A. Karpova,b,c , Andrey E. Vishnyakovb, David Moreirac & Purificación López- Garcíac a Zoological Institute, Russian Academy of Sciences, St. Petersburg 199034, Russia b St. Petersburg State University, St. Petersburg 199034, Russia c Unité d’Ecologie, Systématique
    [Show full text]
  • Phylogeny of the Ciliate Family Psilotrichidae (Protista
    Boise State University ScholarWorks Biology Faculty Publications and Presentations Department of Biological Sciences 6-18-2019 Phylogeny of the Ciliate Family Psilotrichidae (Protista, Ciliophora), a Curious and Poorly- Known Taxon, with Notes on Two Algae-Bearing Psilotrichids from Guam, USA Xiaotian Luo Boise State University Jie A. Huang Chinese Academy of Sciences Lifang Li Shandog University Weibo Song Ocean University of China William A. Bourland Boise State University Publication Information Luo, Xiaotian; Huang, Jie A.; Li, Lifang; Song, Weibo; and Bourland, William A. (2019). "Phylogeny of the Ciliate Family Psilotrichidae (Protista, Ciliophora), a Curious and Poorly-Known Taxon, with Notes on Two Algae-Bearing Psilotrichids from Guam, USA". BMC Evolutionary Biology, 19, 125-1 - 125-15. http://dx.doi.org/10.1186/s12862-019-1450-z Luo et al. BMC Evolutionary Biology (2019) 19:125 https://doi.org/10.1186/s12862-019-1450-z RESEARCH ARTICLE Open Access Phylogeny of the ciliate family Psilotrichidae (Protista, Ciliophora), a curious and poorly-known taxon, with notes on two algae-bearing psilotrichids from Guam, USA Xiaotian Luo1,2, Jie A. Huang1, Lifang Li3, Weibo Song4 and William A. Bourland2* Abstract Background: The classification of the family Psilotrichidae, a curious group of ciliated protists with unique morphological and ontogenetic features, is ambiguous and poorly understood particularly due to the lack of molecular data. Hence, the systematic relationship between this group and other taxa in the subclass Hypotrichia remains unresolved. In this paper the morphology and phylogenetics of species from two genera of Psilotrichida are studied to shed new light on the phylogeny and species diversity of this group of ciliates.
    [Show full text]
  • Chp 26 Protistnotes
    Chp. 26 Notes The Protista Kingdom Most protists are unicellular, microscopic organisms, but a few are complex and multicellular. These are the most diverse (different) organisms according to life cycles, since they reproduce asexually and sexually. This kingdom contains ancestral life-forms that gave rise to three kingdoms of multicellular organisms--the fungi, the plants and animals. As we talked about the theory of endosymbiosis, we should now be able to understand that early in the development of our planet, scientist feel that prokaryotic organisms were the only forms of life on our planet. As time went on, these organisms were invaded by parasites which eventually lost their ability to live outside the host cell and became organelles of the host. This brought about the Eukaryotic cells. Protist organisms exibit the most basic characteristics of these eukaryotic cells as well as some complex characteristics involved in organisms within the fungi, plant and animal kingdoms. Several features evolved as did the eukaryotic cell. These characteristics that evolved in protist organisms are; 1) Multicellularity- The prokaryotic bacteria are the only groups of organisms which are soley unicellular. Most protist are unicellular but there quit a few groups of multicellular organisms in this kingdom as well. 2) Sexual Reproduction- All prokaryotic organism asexually reproduced which meant that they reproduced an exact copy of the parent organism unless a mutation occured in the offspring. With protist organisms sexual reproduction came about as a form of necessity due to environmental stresses ( ie. lack of nutrition, temp. change, predation. etc.) Sexual reproduction brings about genetic variation without mutation needing to occur due to there being two parent organisms producing offspring.
    [Show full text]
  • The Planktonic Protist Interactome: Where Do We Stand After a Century of Research?
    The ISME Journal (2020) 14:544–559 https://doi.org/10.1038/s41396-019-0542-5 ARTICLE The planktonic protist interactome: where do we stand after a century of research? 1 1 1 1 Marit F. Markussen Bjorbækmo ● Andreas Evenstad ● Line Lieblein Røsæg ● Anders K. Krabberød ● Ramiro Logares 1,2 Received: 14 May 2019 / Revised: 17 September 2019 / Accepted: 24 September 2019 / Published online: 4 November 2019 © The Author(s) 2019. This article is published with open access Abstract Microbial interactions are crucial for Earth ecosystem function, but our knowledge about them is limited and has so far mainly existed as scattered records. Here, we have surveyed the literature involving planktonic protist interactions and gathered the information in a manually curated Protist Interaction DAtabase (PIDA). In total, we have registered ~2500 ecological interactions from ~500 publications, spanning the last 150 years. All major protistan lineages were involved in interactions as hosts, symbionts (mutualists and commensalists), parasites, predators, and/or prey. Predation was the most common interaction (39% of all records), followed by symbiosis (29%), parasitism (18%), and ‘unresolved interactions’ fi 1234567890();,: 1234567890();,: (14%, where it is uncertain whether the interaction is bene cial or antagonistic). Using bipartite networks, we found that protist predators seem to be ‘multivorous’ while parasite–host and symbiont–host interactions appear to have moderate degrees of specialization. The SAR supergroup (i.e., Stramenopiles, Alveolata, and Rhizaria) heavily dominated PIDA, and comparisons against a global-ocean molecular survey (TARA Oceans) indicated that several SAR lineages, which are abundant and diverse in the marine realm, were underrepresented among the recorded interactions.
    [Show full text]