- •Texts: origin of life. Properties of chemical reactions pre-reading and reading tasks.
- •Origin of life
- •Notes to the text: Aristotle ["xrIs'tq(V)tl]
- •John Tyndall [dZPn tIndl]
- •Comprehension check
- •3. Point out the topic sentence in each paragraph. Language focus Form the derivatives of the words given in the chart below (where possible):
- •Follow-up activities
- •Additional text
- •I. Read and translate the text. Be ready to fulfil the tasks that follow. Properties of chemical reactions
- •Post-reading tasks
- •Grammar exercises
- •Texts: the cell. Cells pre-reading and reading tasks.
- •1. Study the meaning and pronunciation of the following words:
- •2. Make sure you know the following words and word combinations:
- •3. Comment on the headline of the text before reading it. What do you know about the cell? Read the text and point out what information is new for you. The cell
- •Notes to the text:
- •Comprehension check
- •Language focus
- •1. Say it in another way (give synonyms):
- •Follow-up activities
- •Additional text
- •Post-reading tasks
- •Grammar exercises
- •Texts: how the body works. The skin. Seeing. Taste and smell. Hearing. Pre-reading and reading tasks
- •How the body works
- •Comprehension check
- •1. Agree or disagree with the following:
- •2. Answer the questions:
- •Language focus
- •Follow-up activities
- •Additional texts
- •The skin
- •Taste and smell
- •Hearing
- •Imagine that you are making a speech on one of these topics:
- •Grammar exercises
- •Texts: the brain. Pre-reading and reading tasks.
- •1. Practise the pronunciation and study the meaning of the words:
- •The brain
- •Comprehension check
- •1. Express your agreement or disagreement with the following:
- •Language focus.
- •3. Translate the following sentences from Russian into English:
- •Follow-up activities
- •Additional text
- •The brain
- •Post-reading tasks
- •Grammar exercises
- •Texts: the nerves. The nervous system. Pre-reading and reading tasks
- •The nerves
- •Comprehension check
- •Language focus
- •3). Translate the sentences into English using the vocabulary of the unit:
- •Follow-up activities
- •Additional text
- •The nervous system
- •Post-reading tasks
- •Grammar exercises
- •Texts: the skeleton and muscles. Bones and muscles. Pre-reading and reading tasks
- •The skeleton and muscles
- •Comprehension check
- •Language focus
- •Follow-up activities
- •Additional text
- •Bones and muscles
- •Post-reading tasks
- •Grammar exercises
- •Texts: the blood system. Blood. Pre-reading and reading tasks
- •2. Try to guess the meaning of the following words and word combinations:
- •3. Read the text carefully to fulfil the tasks that follow. The blood system
- •Comprehension check
- •Language focus
- •In each box below match the words which are: a) similar or b) opposite in meaning:
- •Follow-up activities
- •Additional text
- •Post-reading tasks
- •Grammar exercises
- •Texts: the digestive system. Nutrition. Pre-reading and reading tasks
- •2. Make sure you know the meaning of these words and word combinations:
- •3. Read the text carefully to fulfil the tasks that follow. The digestive system
- •Comprehension check
- •Language focus
- •Follow-up activities
- •Additional text
- •Nutrition
- •Post-reading tasks
- •Imagine that you are making a speech on the topic “Nutrition”. Grammar exercises
- •Pre-reading and reading tasks
- •Viruses and subviruses
- •Viruses
- •Subviruses
- •Comrehension check
- •Viruses contain
- •Viruses do not
- •Viruses that attack only bacteria are known as … .
- •It is possible that viruses may be moving genetic material from
- •Viruses may prove, in some cases, to be the simplest of
- •3. Think of 5-7 statements that would contradict the contents of the text. Language focus
- •3. Define the following terms:
- •4. Match the first half of a sentence in column a with the appropriate second half in column b:
- •5. Put the parts of the sentences in the right order:
- •Unit 10
- •Text: monera pre-reading and reading tasks
- •1. Make sure you know the following words:
- •2. Read and translate the text. Monera
- •Comprehension check
- •Follow-up activities
- •1. Prepare a dialogue with your partner discussing:
- •Grammar exercises
- •Unit 11
- •Text: protista. Pre-reading and reading tasks
- •1. Make sure you know the following words:
- •2. Read and translate the text. Protista
- •Comprehension check
- •1. Choose the right variant for the multiple-choice statements.
- •1. All protists
- •2. Ask questions revealing the main points of the text.
- •3. Think of 5-7 statements that would contradict the contents of the text. Language focus
- •Follow-up activities
- •1. Prepare dialogues discussing: a) general information about the kingdom Protista; b) primitive protists; c) true algae; d) unicellular algae.
- •2. Prepare a report on the topic under discussion. Grammar exercises
- •Unit 12
- •Text: fungi pre-reading and reading tasks
- •1. Make sure you know the following words and word combinations:
- •Comprehension check
- •7. Many true fungi have mycelia that grow in a close, intimate manner with plant roots, where the plants benefit by receiving … and … while the fungus benefits by receiving nutritious … .
- •8. Lichens involve the close association of a … and a … .
- •9. When the hyphae of a fungus grow around, sometimes in between, and even within living plant root cells, the association is … .
- •2. Questions to think about.
- •3. Think of 5-7 statements that would contradict the contents of the text. Language focus
- •1. Match the words that are: a) similar and b) opposite in meaning:
- •1. Name and describe: a) the major groups of fungi; b) the ways of fungal nutrition.
- •2. Prepare a report on the topic under discussion. Grammar exercises
- •Unit 13
- •Text: plant kingdom: plantae. Pre-reading and reading tasks.
- •Plant kingdom: plantae
- •Comprehension check
- •Language focus
- •Follow-up activities
- •1. Explain the terms: Chlorophyta, Phaeophyta, Rhodophyta.
- •Grammar exercises
- •Unit 14
- •Texts: coniferophyta: conifers. Anthophyta / angiosperms: flowering plants. Pre-reading and reading tasks
- •2. Read and translate the text. Coniferophyta: conifers
- •Anthophyta / angiosperms: flowering plants
- •Comprehension check
- •2. Ask questions revealing the main points of the text.
- •3. Think of 5-7 statements that would contradict the contents of the text. Language focus
- •1. Match the words that are: a) similar and b) opposite in meaning:
- •Follow-up activities
Unit 12
GRAMMAR: PARTICIPLE.
Text: fungi pre-reading and reading tasks
1. Make sure you know the following words and word combinations:
|
ascus (pl. asci) |
['xskqs] ['xskaI] |
аск |
|
basidium |
[bq'sIdIqm] |
базидий |
|
fungus (pl. fungi) |
['fANgqs] ['fANg(a)I] |
гриб |
|
mold |
[mqVld] |
плесень, плесенный гриб |
|
mutual |
['mju:tSVql] |
взаимный |
|
hypha (pl. hyphae) |
['haIfq] ['haIfi:] |
гифа, нить грибницы |
|
lichen |
['laIkqn, 'lItS(q)n] |
лишайник |
|
mycelium |
[maI'si:lIqm] |
грибница |
|
sac fungus |
[sxk] ['fANgqs] |
сумчатый гриб |
|
septum (pl. septa) |
['septqm] ['septq] |
перегородка |
|
slime mold |
[slaIm] [mqVld] |
слизистый гриб |
|
water mold |
['wO:tq] [mqVld] |
водная плесень |
Exercise 2. Read and translate the text.
FUNGI
There is some evidence that the organisms classified as fungi arose from protists along several different evolutionary lines. In fact, depending on the classification, fungi are sometimes placed within the kindgom Protista, or within the kingdom Plantae, or in their own kingdom, Fungi.
Fungi are eukaryotic organisms; most exist in multicellular form, although some go through an amoeba-like stage, and others, such as yeast, exist in a unicellular form. Unlike the photosynthetic algae and plants, fungi do not photosynthesize but absorb food through their cell walls and plasma membranes.
The slime molds are different from most other fungi in that they are mobile during part of their life history. Some slime molds exist as a plasmodium, which is a multinuclear (coenocytic) mass of cytoplasm lacking cell walls. The plasmodium moves about and feeds in an amoeboid manner. The amoeboid mass is a slime mold's diploid phase.
Other slime molds have separate feeding amoebas that occasionally congregate into a pseudoplasmodium that then sprouts asexual fruiting bodies. Because they pass through an amoeba-like stage, slime molds are occasionally classified as protists. Slime molds are usually found growing on such decaying organic matter as rotting logs, leaf litter, or damp soil, where these viscous, glistening masses of slime are usually white or creamy in appearance, though some are yellow or red.
During its vegetative phase, the slime mold plasmodium moves about slowly, phagocytically feeding on organic material. Under certain conditions, the plasmodium stops moving and grows fruiting bodies, from which spores are released that upon germination produce flagellated gametes. The gametes fuse, forming zygotes that lose their flagella and become amoeboid. The diploid nucleus continually undergoes mitotic divisions without any cytokinesis, and the organism develops into a multinuclear plasmodium that usually reaches a total length of five to eight centimeters.
Most fungi secrete digestive enzymes that hydrolyze nearby organic matter into minerals and compounds that can then be absorbed. Chemicals that don’t get absorbed, as well as the fungal waste products, enrich the surrounding area and become available to plants and other nearby organisms.
Fungi obtain their nutrition in any of three ways, or in any combination of these three ways: as saprophytes, living on dead organic matter; as parasites, attacking living plants or animals; and in mycorrhizal associations, in which they have a symbiotic relationship with plants, usually tree or shrubs.
Fungal spores are tiny haploid cells that float through the air, dispersing the fungi to new habitats. They are relatively resistant to high and low temperatures as well as to desiccation, and can survive long periods in an unsuitable habitat. When conditions become right, however, the spores germinate and grow. They absorb food through long, threadlike hyphae. The mass of branching hyphae creates the body of the fungus, called the mycelium. Mycelia grow, spreading throughout their food source. Some hyphae are coenocytic, having many nuclei within the cytoplasm. Others are divided by septa into compartments containing one or more nuclei. The rigid cell walls of the hyphae and fruiting bodies are composed of cellulose, or other polysaccharides, although some are composed of chitin.
The mycelium constitutes the largest part of the fungal body, yet few ever see mycelia because they are usually hidden within the source of food they are eating. Sometimes, however, they can be seen on the forest floor spreading over moist logs and dead leaves. When mycelia break into fragments, fungi can reproduce vegetatively. Each fragment may grow into a new individual fungus. Other methods of fungal reproduction involve the production of spores, which can be formed asexually or sexually. The spores are usually produced on structures that extend above the food source, where they can be blown away and travel to new environments. Slime molds send up spore-bearing fruiting bodies. The mycelia of mildew send up aerial hyphae that form spores. The fruiting bodies that most people are familiar with, those associated with such fungi as mushrooms, are huge compared to the tiny fruiting bodies that cover moldy bread and cheese.
Most fungi are either parasitic or symbiotic. Parasitism occurs when one individual benefits while the other is harmed, and symbiosis is a mutually beneficial relationship between two individuals. By far the majority of fungal species are terrestrial and reproduce both sexually and asexually. Many have mycelia that grow in a close, intimate manner with plant roots. In such a relationship, the plant benefits by receiving nitrogen and phosphorus, while the fungus benefits by receiving nutritious carbohydrates.
The water molds and their relatives include the molds that grow on dead animals in the water. The powdery mildew found growing on Concord grapes is also a member of this group.
Zygomycota represent a group of fungi that, like the Oomycetes, have coeno-cytic hyphae. They also have chitinous cell walls. Although there are hundreds of species in this group, few people recognize any of them.
The Ascomycota, or sac fungi, form another group of fungi that is widespread although just a few species are familiar. Among this group's 30,000 or so species are the yeasts, certain bread molds, and the fungi that produce penicillin, as well as the species involved in making Roquefort and Camembert cheeses.
The yeasts are unicellular, but the Ascomycetes also include many multicellular types that form hyphae with perforated septa, allowing the cytoplasm and organelles such as ribosomes, mitochondria, and nuclei to flow from one cell to another.
Asexual reproduction is common among the Ascomycetes. It occurs whenever the projections known as conidia form and the asexual conidiospores pinch off. The sexual part of the life cycle involves two hyphae growing together so that the two nuclei become housed within the same cell. When these cells, called dikaryons, develop into the fruiting bodies known as asci, which are characteristic of the Ascomycetes, the two nuclei fuse inside each ascus (singular of asci). This is the process of fertilization. Then the diploid nucleus undergoes meiosis, forming four haploid nuclei. These undergo mitosis, forming eight haploid nuclei that become the ascospores. When the ascus ruptures, the ascospores are liberated.
The Basidiomycota, or club fungi, include most of the common mushrooms. Their fruiting bodies are known as mushrooms, basidia, or clubs; they are formed when two hyphae fuse. This is fertilization. A diploid nucleus is formed that undergoes meiosis, forming four haploid nuclei that move along thin extensions created by outgrowths of the cell walls. These nuclei are pushed to the edge of the club, where these basidiospores (spores) easily break off from their delicate stalks and are carried away by the slightest breeze. If they land in a suitable location, the spores germinate and grow hyphae, which form a mycelium that eventually sends up more fruiting bodies.
The imperfect fungi represent about 25,000 fungal species for which sexual reproduction has either been lost or has yet to be observed. Without information about their sexual stages, it has not been possible to identify the characteristic structures that would help specialists classify them appropriately. Accordingly, they have all been lumped together and called imperfect. Members of this group are responsible for ringworm and athlete's foot; both are fungi that infect people without ever sprouting fruiting bodies.
Mycorrhizal associations occur when the hyphae of a fungus grow around, between, and sometimes even into living plant root cells. Such associations have been found to occur in at least 90 percent of all the different plant families. Eighty percent of all the angiosperms (flowering plants) may have such associations. These relationships are symbiotic.
Plants benefit because the mycorrhizae mobilize nutrients by secreting enzymes that help to decompose the litter in the soil. And then, by acting as root hairs, they help to absorb the nutrients, especially nitrogen and phosphorus, by moving these nutrients from the soil into the root tissue. Mycorrhizae also secrete antibiotics that help reduce the plant's susceptibility to infection by pathogens. The mycorrhizae benefit by absorbing the chemicals and carbohydrates that constantly leak through the roots.
Many of the mushrooms seen under trees and shrubs are the fruiting bodies of the fungi that have a mycorrhizal relationship with the roots of the neighboring plants. One often sees certain species of mushrooms associated with certain species of plants because mycorrhizal relationships are often quite specific.
Lichens are symbiotic combinations of organisms living together intimately. The species involved are always a fungus and either a chlorophyte (green algae) or a cyanobacteria (blue-green bacteria). The fungi are always either members of Ascomycetes or Basidiomycetes. Although the fungi involved in lichens are usually not found growing alone, the photosynthetic portion of the lichens sometimes does live on its own. It is clear that the fungus living in a lichen benefits from the organic compounds obtained from the photosynthesizing member of the association. The algae may obtain water and minerals from the fungus, but this part of the interaction isn’t well understood.
Because lichens are so tolerant of drought, heat, and cold temperatures, they are often the most important autotrophs found on recent lava flows, as well as on the stones used to construct buildings and gravestones. Lichens are also associated with dry, exposed soils, such as those in some deserts, and they also commonly occur in cold, exposed regions.
Most lichens reproduce either by fragmentation, when pieces break off and are blown elsewhere, or by spores produced by the fungal part of the lichen. The spores are blown or washed elsewhere, where they may grow and come in contact with an appropriate algal species. This marks the beginning of another lichen.