Devide the text into logical parts

3. 
   1. About three hundred years ago Robert Hooke found the acorn of the oak tree to be made of tiny compartments which he named cells. 2. To prevent the eyes from drying, most land vertebrates have well-developed eyelids which they blink many times each minute to keep the eyeball clear and moist. 3. One of the surprising features of the Arctic is the number of insects to be found there. 4. Dinosaurs were the first animals to fly. 5. Lizards are found to live everywhere in the world except the Arctic regions. 6. Bacteria seem to be nearly everywhere. 7. An organ is a group of tissues working together to do a certain job. 8. Most insects are known to have large compound eyes and often three or more simple eyes situated between the oth­ers. 9. The endocrine secretions have been found to control many of the organic func­tions. 10. Bacteria are known to live on either dead or living materia. 11. When con­ditions are favourable, some insects are known to produce a new generation in less than two weeks. 12. We know Michurin to have crossed not only different varieties of the same plant but different plants, for instance, apples and pears. 13. Dockutchaev believed plants to influence soil development. 14. We found the enzymes to have played an important part in the building of the complex substance from a simple one. 15. Earthworms help to keep soil porous, which allows air to penetrate to the roots of plants. 16. Prolonged irritation seems to cause some cancers. 17. Scientists consider each part of the nervous system to have a definite function. 18. Birds are said to be warm-blooded. 19. Everybody knows the nervous system to consist of many thou­sands of nerve cells or neurons. 20. Many other vitamins are known, but most of them have not yet been proved to be essential in human metabolism.
   
4. 
   1. Proteins to be circulated must be digested into amino acids. 2. Since the functions of nerves in animals have long been known to involve electric phenomena it is not strange that scientists are beginning to look on the electric changes in plant cells as a type of nervous activity. 3. To establish the relationships of these acids two things must be taken into consideration. 4. Among other things Robert Hooke exam­ined thin slices of com obtained from the bark of a tree, and found it to be made up of little boxes which he called cells. 5. Undoubtedly there is a determining factor that causes each branch root to be sent forth from a definite point, but its nature is ob­scure. 6. The specificity of enzymes action is thought to be related to the properties of the enzyme protein. 7. In many instances the sex pattern of plants appears to be influ­enced more readily by environmental factors than does that of animals. 8. Enzymes are known to be present in the chloroplasts. 9. Enzymes are very sensitive to acids and alkalies and might be expected to start reverse activities when changes in acidity occur. 10. Scientists are agreed that life began in the sea, and blood is believed to have originated by sea water being enclosed within the body. 11. Movements of the air are known to increase evaporation from the leaves. 12. The power of bacteria to produce disease is known as virulence. 13. The first thing to be done in this case is to roll the soil after ploughing for firmness to be obtained.
   

1. 
   read and try understand the text without dictionary
   
2. 
   write a list of unnown words and give their transcriptions
   
3. 
   be ready to retell the text in short
   

1. Майер Н.Г. Английский язык для биологов: учебно – методическое пособие. Горно-Алтайск: РИО ГАГУ, 2010г

2. А.С. Бугрова., Е.Н.Вихрова. Английский язык для биологических специальностей. Изд: Высшее профессиональное образование, 2008г

Theme №4. Genetics and the essence of life

The purpose of SIWT:

1. To ensuring fundamental education in the natural-science subjects.

2. To broaden student's outlook and acquaint with professional terms.

3. To encourage the interests of learning foreign language.

GENETICS AND THE ESSENCE OF LIFE

Genetics today is a most brilliant participant in the general revolution wrought in the natural sciences. Its discoveries have led to the emergence of a new concept on the essence of life, and new methods have been evolved for the study and control of heredity, which have greatly affected agricultural production and medicine.

The basic event has been the discovery of the molecular foundations of heredity. It turned out that the rather simple molecules of deoxyribonucleic acid (DNA) carry within them a record of genetic information. This discovery gave rise to a common platform of geneticists, physicists and chemists in analyzing the problems of heredity.

It was found that the genetic information operates within the cell on the principle of guided systems. This allowed in many instances to employ the logic and language of cybernetics in heredity studies.

This discovery upsets the old concept on the omniscient role of protein and showed that the molecules of nucleic acids were responsible for passing on the he­reditary features. Under their influence specific proteins are formed in each cell. The controlling mechanism of the cell is concentrated in its nucleus or, to be more pre­cise, in the chromosomes, which are composed of linear sets of genes. Each gene, which in an elementary unit of heredity, is at the same time a complex microcosm, with a chemical pattern of a separate fragment of the DNA molecule. Thus molecular genetics opened up to man the innermost depths of the organization and functions of life. Like all great discoveries, the development of the chromosome theory of hered­ity, the theory of genes and the theory of mutations (the teaching on forms of change of the genes and chromosomes) have greatly affected life nature made to order. Us­ing these new discoveries, people have evolved new methods of selection of plants, animals and micro-organisms. We can say in all confidence that the nature of the productive forces depends largely on the successes achieved in the microbiological synthesis of proteins, antibiotics, amino-acids, vitamins and other substances. Al­ready today the microbiological industry is based on the use of the so-called radiation and chemical mutants, i.e., the strains of micro-organisms capable of "supersynthesis" of the substances we need. It was found that the energy of radiation or chemical com­pounds, penetrating into the cell, reaches the genes and causes in them various chemical transformations. As a result, a change takes place in the chemical operation of the cell and geneticists find the strains capable of "supersynthesis". In the same way researchers find the changes, which help resist disease, bring about increased photosynthesis sturdiness and other needed features in plants. This has formed the ba­sis for new methods of transforming the nature of plants and some animals.

The problems of radiation and chemical influences are of no little importance for the biology of man himself. Today when the impact of these factors is not yet a men­acing danger, we must carefully weigh up the consequences which may arise if the radiation or chemical background

on earth is noticeably increased. In consequence of the constant process of natu­ral mutations per cent of all babies are born with marked physical or mental deformi­ties. If the background is intensified this level of aggravated heredity will also grow. Soviet scientists have done a lot of research into this problem and are active in the work of the UN Scientific Committee on the Effects of Atomic Radiation which as­sesses the effect radiation has on human heredity and keeps a record of radiation on earth.

A number of major achievements in experimental genetics serve to solve in our time the problem of sharply increasing the output of grain crops and of radically changing all agricultural production in the world. By the end of this century the world population will double. In order to adequately supply its requirements we need to double in the next 30 years production of grain and increase the livestock population 10-fold. That means that we must intensify agricultural production. Experimental ge­netics has evolved a number of new methods above all, of controlling heterosis (the increased vigour and growth capacity exhibited by hybrids from specially selected parents) and experimental polyploidy (controlled increase of chromosomes in a cell) and has discovered excellent means of raising crop yields and productivity of ani­mals.

Hybrid maize, hybrid forms of vegetables and polyploid sugar-beet have already won a place in the world and raised yields by 20—30 per cent. At present revolution­ary changes are anticipated in selection of wheat — the staple food crop. Everywhere in the world and in our country, too, intense, research is underway to evolve a new high-yield, essentially new kind of hydrid wheat. The application of heterosis hybrids has brought about a sharp increase in the productivity of hens, cattle and other stock.

HEALTH OF MAN. Man himself is becoming the object of close study by ge­neticists. At every stage of its history genetics was concerned with one major object in its research. At first the genes theory was worked out in experiments with peas, then the pomace fly was used to establish the chromosome theory. Now that molecu­lar genetics is developing by leaps and bounds, the genetics of bacteria and sub­stances is the main problem. But in its future stage genetics research will apparently concentrate on man himself.

A new science — cytogenetics of man — which has developed in the last 6—7 years has established that disruption of the patterns of chromosomes in the nucleus of man's cells may have a grave and, at times, fatal effect on the development of his per­sonality. It was also discovered that the mutations of genes also have effect. Coupled with medicine, genetics can become a shield against the tragic, hereditary maladies which destroy the human personality and cause terrible grief to families, where de­formed children are bom.

1. 
   Devide the text into logical parts,
   
2. 
   Find the sentences, expressing the main idea of each part
   

3. 
   Entitle the parts
   
4. 
   Be ready to retell the text in short and
   
5. 
   Give a short summary of the text.
   

translation of the text and carring-out all tasks according to the text

1. 
   read and try understand the text without dictionary
   
1. 
   write a list of unnown words and give their transcriptions
   
2. 
   be ready to retell the text in short
   

1. Майер Н.Г. Английский язык для биологов: учебно – методическое пособие. Горно-Алтайск: РИО ГАГУ, 2010г

2. А.С. Бугрова., Е.Н.Вихрова. Английский язык для биологических специальностей. Изд: Высшее профессиональное образование, 2008г

4. 
   The content of SIW
   

Since ancient times anyone familiar with medicinal herbs and poisonous plants has been able to find in the woods the means to cure or to kill. At that time plants were valued for their utility and their medicinal properties, and besides they were worshipped as a gift from the gods.

Amongst the ancient civilized peoples the Egyptians had a strong liking for flowers and shrubs, although they had to grow their plants under a cloudless sky on artificially watered lands.

Many centuries before the Greeks they produced their flowerpictures: the names of herbs with hearing properties were recorded on a long papyrus.

In Ancient Greece one of Aristotle's pupils went beyond the sphere of medicinal and practical questions: he undertook the comparison of plants.

In the Middle Ages voyages of discovery revealed to the naturalists a great abundance of plants and animals hitherto unknown. Now their task was not merely to compare or to describe them but also to classify them systematically according to definite principles. About 1855 the scientist M.G. Schleiden scoffed at those botanists “whose entire wisdom is spent in determining and classifying". This comment came at a time when the botanists had trodden the road of deeper understanding of plant life.

By the end of the 18 century, people bad gradually, in a series of achievements, come to discover why the blossom emits cooler, the purpose of the leaf and the structure of the fruit.

Then there arose for the second time a botany of the unexplored, when in the century researchers with improved microscopes penetrated into the invisible world of cellular structures.

From now the microscope led naturalists deeper and deeper into secret world, from plants without blossoms right down to unicellular bacteria, into the marvels of issues, the growth of new substance and the operation of heredity.

Answer the questions:

1. 
   What does biology study?
   
2. 
   How were plants valued in ancient times?
   
3. 
   Where were the names of healing herbs recorded?
   
4. 
   Who undertook the comparison of plants?
   
5. 
   When did the researchers penetrate into invisible world of secular struc­tures?
   

translation of the text and carring-out all tasks according to the text

1. 
   read and try understand the text without dictionary
   
2. 
   write a list of unnown words and give their transcriptions
   
3. 
   be ready to retell the text in short
   

1. Майер Н.Г. Английский язык для биологов: учебно – методическое пособие. Горно-Алтайск: РИО ГАГУ, 2010г

2. А.С. Бугрова., Е.Н.Вихрова. Английский язык для биологических специальностей. Изд: Высшее профессиональное образование, 2008г

Theme № 2. Animal – Plant differences

The purpose of SIW:

1. To ensuring fundamental education in the natural-science subjects.

2. To broaden student's outlook and acquaint with professional terms.

3. To encourage the interests of learning foreign language.

ANIMAL - PLANT DIFFERENCES

Although you may place organisms without difficulty in either the plant or the animal kingdom, it is essential to know the basic nutritional differences between these two groups.

Plants require sunlight energy to build up their complex organic compounds (starch, for example) from the simplier inorganic foods they absorb. This process is not only dependent on sunlight, but requires the presence of the green pigment chlo­rophyll, and a supply of water and carbon dioxide within the plant, before it can take place. Animals do not carry out such a synthesis; they take in ready-made organic compounds by feeding on other organisms either living or dead. Thus, plants are the only organisms capable of making organic compounds and animals are different on them, either directly or directly for their supply of these substances.

Animals also different from plants in the structure of their cells. Those of ani­mals are bounded by a very thin layer of special protoplasm (a protoplasmic mem­brane), those of plants have a much thicker layer of dead material outside the proto­plasmic membrane. This thick layer (the cell wall is usually made of an organic substance called cellulose. Furthermore, piant cells generally have spaces or vacuoles full of cell sap within their protoplasm. Chlorophyll is not found in animal cells, but is present in small disc-shaped bodies (chloroplasts) in the protoplasm of many plant cells.

The nucleus is a more or less spherical body present in both cell types.

Answer the questions:

1. 
   What do plants require to build up starch?
   
2. 
   Do animals carry out such a complex synthesis'?
   
3. 
   What do animals take in?
   
4. 
   What are animals dependent on?
   
5. 
   Do animals differ from ptants in the structure of their cells?
   
6. 
   Is chlorophyll found in animal cells?
   

translation of the text and carring-out all tasks according to the text

1. 
   to read and to try understand the text without dictionary
   
2. 
   to write a list of unnown words and give their transcriptions
   
3. 
   be ready to retell the text in short
   

1. Майер Н.Г. Английский язык для биологов: учебно – методическое пособие. Горно-Алтайск: РИО ГАГУ, 2010г

2. А.С. Бугрова., Е.Н.Вихрова. Английский язык для биологических специальностей. Изд: Высшее профессиональное образование, 2008г

Theme № 3. General chemistry of the cell

The purpose of SIW:

1. To ensuring fundamental education in the natural-science subjects.

2. To broaden student's outlook and acquaint with professional terms.

3. To encourage the interests of learning foreign language.

GENERAL CHEMISTRY OF THE CELL

All the substances present in protoplasm fall into two great classes: inorganic and organic substances. Inorganic substances make up the bulk of living as well as non-living matter. The rocks, soil, atmosphere and waters of the earth are composed of a wide variety of inorganic materials. And in living matter also the inorganic components are very frequent. This is-due mainly to the high proportion of water in all protoplasm.

Water is the liquid that dissolves, suspends or otherwise disperses other substances present in the cell. The high heat capacity of water plays an important role in the life of organisms generally.

Water participates in many metabolic reactions in all cells. The gases of the air tend to enter all cells and to dissolve in the protoplasm

Nitrogen (N2), oxigen (02) and carbon dioxide (CO) are present in the cell and take part in many metabolic reactions.

Organic compounds occur only in living bodies, or in their products or remains. The element carbon (C) is present in all organic compounds, in other words, organic chemistry is the chemistry of carbon compounds. Carbon has a capacity to form a great variety of compounds. The carbon compounds are continually changing by interaction with each other, but certain kinds are most abundant in the protoplasm. These organic compounds are divided into three main classes - the carbohydrates, the lipids and the proteins.

The most familiar carbohydrate compounds are the sugars starches, glycogens and celluloses. Chemically, all carbohydrates have much in common. They consist of carbon, hydrogen and oxygen. However, their functions in the cell are different. The starches, glycogens and celluloses are important substances, called the polysaccharides all these compounds are derived from glucose. Cellulose has great importance as the chief component of cell wall and of woody materials generally. Starch and glycogen are also important as reserve protoplasmic fuels.

Lipids are important constituents of cell organelles, especial of the cell membrane, mitochondria, microsomes, chromosomes and nucleolus and possibly of the nuclear membrane. The chemical nature of lipids is different. So they are not treated as a single group, but are subdivided into three groups: (I) the true true fats, (2) the phospholipids, and (3) the steroids.

The fats in protoplasm serve mainly as accessory fuels. The fats are mixtures of triglycerides each of which contains a molecule the glycerol associated with three molecules of fatty acids.

There are a number of lipid derivatives the better known of are the vitamins D, E and K.

Proteins are all-important structural components in every cell. Proteins contain carbon, hydrogen, oxigen, nitrogen and sulphur.

Chemically, proteins are the most complicated of all substances. The molecules are huge, consisting of thousands of atoms. Proteins are made of a number of simpler units - the amino acids. The amino acids are liberated as separate molecules when a protein is broken down by hydrolysis. The proportion and arrangement of the amino acids, present in most proteins, varies widely. Just as an almost infinite variety of words can be formed from the 26 letters of alphabet, so a large number of different proteins can be synthesized from the 25 kinds of amino acids.

The most important of all conjugated proteins are the nucleoproteins, not only the DNA proteins, or genic materials, which generally remain inside the nucleus, but also the RNA proteins, which carry on many of their functions in the cytoplasm. Each nucleoprotein represents a gigantic macromolecule formed, by a union between a specific protein and nucleic acid.

The nucleic acids also are very longchained molecules The chain of a nucleic acid consists of a sequence of complex units called nucleotides made up of a pentose sugar, an organic nitrogenous base and phosphoric acid. Although nucleic acids have been long known to be a constant constituen/ of living tissues it is only during the past twenty years that any considerable attention has been paid to their distribution and role in the cell.

Ip addition to the proteins, carbohydrates, lipids, and other previously men­tioned substances, protoplasm always contains smaller amounts of other, usually simpler, organic compounds.

Form of reporting:

translation of the text and carring-out all tasks according to the text

1. 
   read and try understand the text without dictionary
   
2. 
   write a list of unnown words and give their transcriptions
   
3. 
   be ready to retell the text in short
   

1. Майер Н.Г. Английский язык для биологов: учебно – методическое пособие. Горно-Алтайск: РИО ГАГУ, 2010г

2. А.С. Бугрова., Е.Н.Вихрова. Английский язык для биологических специальностей. Изд: Высшее профессиональное образование, 2008г

V. Checking measuring facilities:

1. Which of the following does not help to make up the cytoskeleton?

2. What is the name for an enzyme secreted in an inactive form?

3. What is the name of the process whereby prokaryotes divide?

A: binary fission
B: binary fusion
C: binary collision
D: binary occlusion

4. What is it called when a single zygote divides into 2 embryos, resulting in identical twins?

A: heterozygotic twins
B: monozygotic twins
C: polyzygotic twins
D: homozygotic twins

5. What is the name for the rhythmic movements of the involuntary muscles that move food through the body?

A: catharsis
B: peritonitis
C: peristalsis
D: sepsis

6. What is the name of the enzyme produced in the pancreas that hydrolyzes specific peptide bonds and converts chymotrypsinogen to chymotrypsin?

7. What is the name of the vein that transports glucose and other sugars that are absorbed in digestion to the liver?

8. What is a heterozygous organism?

A: an organism that carries one allele
B: an organism that carries two different alleles
C: an organism that carries no alleles
D: an organism that carries two identical alleles

9. What is the name for the existence of more than one phenotypic forms in a population?

10. What is another name for the evolution of a new species?