The experiment of Beadle and Tatum proved that each enzyme was encoded by one gene. T
7 Some years later mutant Neurospora was used that could not grow unless citrulline was added to the medium. F: “A few years later, to determine the series of chemical reactions by which normal molds synthesize the amino acid arginine, biochemists used mutant Neurospora that couldn’t grow on minimal medium unless arginine was added.”
8 The experimental mutant mold lacked many enzymes. F: “the researchers found that the mutant lacked a single enzyme that catalysed one specific step in arginine synthesis.”
Unit 8
Inheritance
Introduction
Read the following passage and listen to the story about Gregor Mendel’s life. Find six false facts in the story you hear.
An original text in Student’s Book:
Before settling down as a monk in the monastery of St. Thomas in Brünn (now Brno, in the Czech Republic), Gregor Mendel tried his hand at several pursuits, including health care and teaching. To earn his teaching certificate, Mendel attended the University of Vienna for 2 years, where he studied botany and mathematics, among other subjects. This training proved crucial to his later experiments, which were the foundation for the modern science of genetics. At St. Thomas in the mid-1800s, Mendel carried out both his monastic duties and a groundbreaking series of experiments on inheritance in the common edible pea. Although Mendel worked without knowledge of genes or chromosomes, we can more easily follow his experiments after a brief look at some modern genetic concepts.
Six false facts are given in bold:
Before settling down as a monk in the monastery of St. Thomas in Brünn, (now Brno, in the Czech Republic), Gregor Mendel tried his hand at several pursuits, including teaching health care. To earn his medical certificate, Mendel attended the University of Vienna for 2 years, where he studied botany and mathematics only. This training proved very important to his later experiments, which were the foundation for the modern science of genetics. At St. Thomas in the mid-1700s, Mendel carried out both his monastic duties and broke ground in a series of experiments on inheritance in the common edible pea. Although Mendel knew little about genes or chromosomes, we can more easily follow his experiments after a brief look at some modern genetic concepts.
Unit 9
Fungi
Introduction
How do fungi affect humans? Listen to the text and answer the question.
Edible mushrooms are the most obvious fungal contribution to human welfare, but fungi have many other, less visible but more important impacts as well. Many of these impacts are positive, and some fungal benefits extend far beyond mere gastronomic concerns. For example, as decomposers, fungi make an incalculable contribution to ecosystems. The extracellular digestive activities of many fungi liberate nutrients such as carbon, nitrogen, and phosphorus compounds and minerals that can be used by plants. If fungi and bacteria were suddenly to disappear, the consequences would be disastrous. Nutrients would remain locked in the bodies of dead plants and animals, the recycling of nutrients would grind to a halt, soil fertility would rapidly decline, and waste and organic debris would accumulate. In short, ecosystems would collapse.
Although the health of ecosystems depends on the relentless nature of fungal feeding, penetrating fungal filaments can have adverse consequences as well. Parasitic fungi, for instance, cause disease. In humans, such fungi cause a range of diseases such as ringworm and athlete’s foot, which infect the skin; valley fever and histoplasmosis, which infect the lungs; and common vaginal yeast infections. Fungi also cause the majority of plant diseases. The fungi that cause chestnut blight and Dutch elm disease have drastically reduced American chestnut and elm tree populations. Fungal parasites also result in billions of dollars in crop losses annually from diseases such as corn smut.
The fungal impact on agriculture is not entirely negative, however. Fungal parasites that attack insects and other arthropod pests can be an important ally in pest control. Farmers who wish to reduce their dependence on toxic and expensive chemical pesticides are increasingly turning to biological methods of pest control, including the application of “fungal pesticides”. Fungal pathogens are currently used to control a variety of pests, including termites, rice weevils, tent caterpillars, aphids, and citrus mites.
Fungi, of course, also make an important contribution to human nutrition. This contribution goes far beyond the obvious use of wild and cultivated mushrooms. Other fungi, such as the rare and prized truffle, are also consumed directly. Of greater importance, however, are the less visible manifestations of fungal activities. In particular, fungi are responsible for making bread rise, for converting grape juice to wine, for the distinctive flavor of many cheeses, and for the bubbles (and alcohol) in beer. Our diets would certainly be a lot duller without the help we get form fungal partners.
Unit 10
The Evolution of Hormones
Introduction
Now listen to the summary of key concepts concerning the endocrine system of the animal body and get ready to retell it.
Summary of Key Concepts
What are the characteristics of animal hormones?
A hormone is a chemical secreted by cells in one part of the body that is transported in the bloodstream to another part of the body, where it affects the activity of specific target cells. Four types of molecules are known to act as hormones: peptides, amino-acid derivatives, steroids, and prostaglandins.
Most hormones act on their target cells in one of two ways: (1) Peptide hormones and amino-acid derivatives bind to receptors on the surface of target cells and activate intracellular second messengers, such as cyclic AMP. The second messengers then alter the metabolism of the cell. (2) Steroid hormones diffuse through the plasma membranes of the target cells and bind with receptor proteins in the cytoplasm. The hormone-receptor complex travels to the nucleus and promotes the transcription of specific genes. Thyroid hormones also penetrate the plasma membrane but diffuse into the nucleus, where they bind to receptors associated with the chromosomes and influence gene transcription.
Hormone action is commonly regulated through negative feedback, a process in which a hormone causes changes that inhibit further secretion of that hormone.
What are the structures and functions of the mammalian endocrine system?
Hormones are produced by endocrine glands, which are clusters of cells embedded within a network of capillaries. Hormones are secreted into the extracellular fluid and diffuse into the capillaries. The major endocrine glands of the human body are the hypothalamus – pituitary complex, the thyroid and parathyroid glands, the pancreas, the sex organs, and the adrenal glands. Prostaglandins, unlike other hormones, are not secreted by discrete glands but are synthesized and released by many cells of the body. Other endocrine organs include the pineal gland, thymus, kidneys, heart, and the stomach and small intestine.
Unit 11
The Immune Response
Introduction
What are the key characteristics of the immune response? Listen to the text and say whether the following sentences are true or false.
Phagocytic cells, natural killer cells, the inflammatory response, and fever are all nonspecific defenses; their role is to prevent or overcome any microbial invasion of the body. Unfortunately, however, these nonspecific defenses are not impregnable. When they fail to do the job, the body mounts a highly specific immune response directed against the particular organism that has successfully invaded the body.
The essential features of the immune response to infection were recognized more than 2000 years ago by the Greek historian Thucydides. He observed that occasionally someone would contract a disease, recover, and never catch that particular disease again – the person had become immune. With rare exceptions, however, immunity to one disease confers no protection against other diseases. Thus, the immune system attacks one type of microbe, overcomes it, and provides future protection against that microbe but no others. This is why we refer to the immune response as a specific defense against invasion.
The immune system consists of about 2 trillion lymphocytes, a kind of white blood cell. Lymphocytes are distributed throughout the body in the blood and lymph, though many are clustered in specific organs, particularly the thymus, lymph nodes, and spleen. The immune response arises from interactions among the various types of lymphocytes and the molecules that they produce. The theatre of the immune response has a large cast of characters and is difficult to follow without a program. The table below provides a brief overview of the major actors and their roles.
The key actors in the immune response are two types of lymphocytes, called B cells and T cells. Like all white blood cells, B lymphocytes and T lymphocytes arise from precursor cells in the bone marrow. Some of these lymphocyte precursors are released into the bloodstream and come to rest in the thymus, where they complete their differentiation into T (for thymus) cells. In contrast, B cells differentiate in the bone marrow itself. The two cell types play quite different roles in the immune response, but immune responses produced by both B cells and T cells consist of the same three fundamental steps: (1) recognizing the invader, (2) launching a successful attack to overcome the invader, and (3) retaining a memory of the invader to ward off future infections.
1 The Greek physician Thucydides recognized the essential features of the immune response to the infection more than 2000 years ago. F: physician
2 Immunity to one disease always confers no protection against other diseases. F: always
3 We refer to the immune response as a specific defense against invasion. T
4 Lymphocytes are distributed throughout the body in the blood. F: and lymph
5 T cells and B cells play similar roles in the immune response. F: similar
Unit 12
Animal Behaviour
Introduction
I. Listen to the text and determine differences of innate and learned behaviour.
Although all animal behaviour is influenced by both genetic and environmental factors, it can be useful to distinguish between behaviours whose development is not highly dependent on external factor and behaviours that require more extensive environmental stimuli in order to develop behaviours in the first category are sometimes designated as innate and can be performed properly the first time an animal encounters the appropriate stimulus. Innate behaviours include kineses, in which animals orient by varying the speed of essentially random movements, stopping when they encounter favorable conditions. In contrast, taxes are directed movements toward or away from specific stimuli. A fixed action pattern is a complex innate behaviour elicited by a specific stimulus called a releaser. Learning can in some cases modify the releasers for fixed action patterns.
Behaviour that changes in response to input from an animal’s social and physical environment is said to be learned. Learning is especially adaptive in environments that are changing and unpredictable, and learning can modify innate behaviour to make it more appropriate.
Among the diverse array of learning methods are imprinting, habituation, conditioning, trial and error, and insight. Imprinting is a special kind of learning that occurs during a limited sensitive period early in life. This form of simple learning typically involves attachment between parent and offspring or learning the features of a future mate.
Habituation is the decline in response to a harmless stimulus that is repeated frequently. It commonly modifies innate escape responses or defensive responses.
During classical conditioning, an animal learns to make a reflexive response, such as withdrawal or salivation, to a stimulus that did not originally elicit that response. During operant conditioning, an animal learns to make a new response, such as pressing a button, to obtain a reward or to avoid punishment.
Trial-and-error learning can modify innate behaviour or can produce new behaviour as a result of rewards and punishments provided by the environment.
Insight, the most complex form of learning, can be considered a form of mental trial-and-error learning. An animal showing insight makes a new and adaptive response to an unfamiliar situation.
Although the distinction between innate and learned behaviour is conceptually useful, the distinction is not sharp in naturally occurring behaviours. In virtually all behaviours, learning and instinct interact to produce adaptive behaviour. Certain types of learning, such as imprinting, occur instinctively, during a rigidly defined time span. Instinctive responses are typically modified by experience. Learning allows animals to modify these innate responses so that they occur only with appropriate stimuli.
Список литературы
1. Audesirk, Gerald, Audesirk, Teresa. Biology: Life on Earth. Fifth Edition. - University of Colorado at Denver. Prentice Hall, 1999.
2. Lingvo 10. Англо-русский электронный словарь. ABBYY, 2005.
3. Swan, Michael. Practical English Usage. Third Edition. – Oxford University Press, 2005.
4. Биология для поступающих в МГУ. – Изд-во МГУ, 2002.
5. Кемп П., Армс К. Введение в биологию. – Мир, М., 1988.
6. Материалы сайта www.elementy.ru.
7. Новый большой англо-русский словарь. - В 3-х тт. - Под. ред. Ю.Д.Апресяна. - М., 1993.
8. Шахова Н.И. Learn to read science. Курс английского для аспирантов и научных работников. – М., 2005.
Англо-русский словарь
A
acorn желудь
acquire возникать из питательной среды
ACTH адренокортикотропный гормон, гормон коры надпочечников
adapt приспосабливаться
adenosine diphosphate АДФ
adenosine triphosphate АТФ
adrenal medulla мозговое вещество надпочечника, хромаффинная ткань
aeons века
aerobe [¢eərəub] аэроб
affect воздействовать
alert тревога
alga [¢ælgə](pl. algae) водоросли
allele (dominant, recessive) аллель (доминантный, рецессивный)
ameliorate улучшать
anaerobe [¢ænərəub] анаэроб
appropriate подходящий, соответствующий; адекватный
arthropod членистоногое
assault нападение, атака
assemblage скопление; группа
athlete’s foot грибковое заболевание ног, микоз
atrial natriuretic peptide атриальный натрийуретический пептид
autosome аутосома
B
B cell базофильный инсулоцит (В-клетка)
base-pairing rule закон спаривания оснований
basidium (pl. basidia) базидия
beak клюв
become obvious становиться очевидным
biosphere биосфера
blood clotting свертывание крови
bond связь
bone marrow костный мозг
boon благо
breakdown распад
broth бульон; жидкая среда
bug клоп; мелкое насекомое
burrow нора
by-product побочный продукт
C
calcium [¢kælsıəm] кальций
Cambrian period кембрий
сarpel плодолистик
cast отпечаток
catalyst катализатор
catalyze катализировать
catalyzed reaction катализируемая реакция
centriole центриоль
chestnut blight каштановая гниль
chirp чирикать, щебетать
chitin хитин
chlorine хлор
chloroplast хлоропласт
cholecystokinin холецистокинин
chromatophore хроматофор
chromatophorotropic (гормон) меланоцитстимулирующий
cichlid fish цихлида
circulatory кровеносный
citrulline цитруллин
club fungi (basidiomycetes) базидиальные грибы, базидиомицеты
coach тренер, наставник; инструктор
coenzyme коэнзим
coiled скрученный, извитый
colour blindness цветовая слепота
community сообщество
compete
competition for survival and reproduction борьба за выживание и продолжение рода
complex organic molecule сложная органическая молекула
complementarity комплементарность
conditioning соперничать, конкурировать
conduct water from roots to leaves проводить воду от корней к листьям
confer даровать, давать
conquer завоевывать, покорять
conversion of matter and energy превращение веществ и энергии
convert переводить, трансформировать (из одного состояния в другое)
corrugate сморщенный
couple with связывать, ассоциировать
cricket сверчок
crop up неожиданно обнаруживаться; возникать
cross-fertilization перекрёстное оплодотворение
crossing over кроссинговер (перекрёст хромосом)
cyanobacteria [sa¢ıənəbæk¢tıərıə] цианобактерии
cytoplasm [¢saıtəplæzm] цитоплазма
D
decompose разлагаться
deftly ловко, искусно
dehydration synthesis [dı:haı¢dreıò(ə)n] дегидратационный синтез
deoxyribose дезоксирибоза
derive from происходить от
devastate истощать, опустошать, разорять
differential reproduction неравное размножение
differentiate отличаться, видоизменяться, приспосабливаться
diffuse диффундировать
digestive [dı¢dзestıv] tract пищеварительный тракт
dimple желобок, выемка
diploid диплоид
disaccharide [dıs¢əkəraıd] дисахарид
discrete раздельный, неслившийся
dissolve растворять(ся)
distinctively характерно
diverse [daı¢və:s]/ diversity разнообразный/разнообразие
drive the synthesis of ATP from ADP стимулировать синтез АТФ из АДФ
draw attention привлекать внимание
droppings экскременты
ductless не имеющий выводного протока
dung fungus сордария навозная (Sordaria fumicola)
dusting опыление
Dutch elm disease голландская болезнь вязов
dye краситель
E
edible pea горошек обыкновенный
efficient действенный
embedded вставленный, вкопанный, внедренный
emerge появляться; возникать
encode кодировать
encounter столкновение
endergonic reactions эндотермическая реакция
enriched with обогащенный
entropy энтропия
environmental extremes экстремальные условия окружающей среды
enzyme function функция фермента
epinephrine адреналин, эпинефрин
ergot спорынья
erythropoietin эритропоэтин
escape спасаться, избегать
evaporate испаряться
evolution by natural selection эволюция путем естественного отбора
evolutionary transformations эволюционные преобразования
exergonic reactions экзотермическая реакция
exocrine внешнесекреторный
expose открывать
extinction вымирание
F
fascinating удивительный
fertile плодородный
finch вьюрок
fit приспособленный
flow of matter круговорот веществ
flu strain штамм гриппа
follicle фолликул
foothold точка опоры; устойчивое положение
forensic судебный
fossil (remains) ископаемое
fungus (pl. fungi) [¢fΛngəs, ¢fΛndзı] гриб, плесень
fuse объединяться
G
gamete [¢gæmı:t] гамета
gauze марля, кисея
gene locus локус
generate порождать
generation поколение
genetic makeup генетический набор
genotype генотип
genus (pl. genera) род
German shepherd немецкая овчарка
germinate развиваться, прорастать
gill гимениальная пластинка, спороносный слой
give off energy выделять энергию
glucagon гипергликемический гормон поджелудочной железы
glucocorticoids глюкокортикоид
go extinct вымирать
groove углубление, впадина
gull чайка
H
habitat место/среда обитания
habituation привыкание (ослабление реакции при повторении воздействия стимула)
hamster хомяк
haploid гаплоид
hatch вылупляться, выводиться
helium гелий
hemoglobin [hı:məu¢gləubın] гемоглобин
hemorrhage кровоточить
heredity наследственность
heterozygous [het ərəu¢zıgəs] гетерозиготный
hind limbs задние конечности
histocompatibility гистосовместимость
histoplasmosis гистоплазмоз
homicide убийство
homologous nucleotide [¢nju:klıətaıd] гомологичный нуклеотид
homozygous гомозиготный
humanity человечество
hybrid [¢haıbrıd] гибрид
hyphae гифы
I
ignite воспламенять, зажигать
imperfect fungi (deuteromycetes) дейтеромицеты
impregnable неприступный; неуязвимый
incentive стимул
increase rapidly быстро возрастать
individual (n) (зд.) особь
inflammatory воспалительный
initiate начинать, приступать
innate врождённый; природный
insight инсайт
interaction взаимодействие
intruder непрошеный гость
invader захватчик, оккупант
invertebrates беспозвоночные
involve включать
iodine [¢aıəudı:n] йод
J
jar банка
juvenile молодой, юный
K
kinesis кинезис (движение)
L
lack backbone не иметь хорды
lacrimal слезный
leave offspring оставлять потомство
liberate высвобождать
linkage сцепление
living / non-living matter/ objects живая/неживая материя/объекты
lizard ящерица
luteinizing hormone лютеинизирующий гормон
lymphocyte [¢lımfəsaıt] лимфоцит
M
macrophage гистиоцит, макрофаг
maggot личинка насекомого
magnesium магний
maintain the level of pH поддерживать уровень pH
maintain a population поддерживать жизнь популяции
mate спариваться
measles [mi:zlz] корь
meiosis [mı¢əusıs] мейоз
Mendel’s law of segregation закон расщепления Менделя
minced измельченный
mislead вводить в заблуждение
modification изменение
mold [¢məuld] плесень
monosaccharide моносахарид
morel сморчок
mRNA (messenger RNA) иРНК (информационная РНК)
multicellular многоклеточная
mumps свинка
mushroom (v) внезапно и быстро вырасти
mutualistic мутуалистический
mycelium [maı¢sı:lıəm] грибница
mycorrhiza микориза
N
natural population естественная популяция
nematode, roundworm нематода, круглый червь
nutrients питательные вещества
O
observe наблюдать
observer наблюдатель
obtain resources добывать ресурсы
organelle органелла
organic molecule органическая молекула
origin of species происхождение видов
originally изначально
originate появляться, происходить
ovary яичник
overall genetic composition of a population общий генетический состав популяции
oxygen-starved лишенный кислорода
oxytocin окситоцин
ozone layer озоновый слой
P
Paleozoic era палеозой
parathormone гормон околощитовидной железы, паратиреоидный гормон
parental generation родительское поколение
pass on genetic differences передавать генетические отличия
pathway путь
peat bog торфяное болото
perform a (single) function выполнять (общую) функцию
petal [¢petl] лепесток
petrified окаменевший
pest вредитель
phagocytic [¢fægəusaıtık] фагоцитарный
phenotype фенотип
phosphorus фосфор
photosynthetic organism фотосинтезирующий организм
phylum тип
plant resin древесная смола
plasma membrane плазматическая мембрана
plasmid плазмида
pollen пыльца
polymerase полимераза
polysaccharide полисахарид
population популяция
posterior pituitary hormones гормоны задней доли гипофиза
potassium калий
prebiotic до возникновения жизни
Precambrian period докембрий
precursor cell клетка-предшественник
predator хищник
preserve жертва
prickly pear cactus опунция (вид кактуса)
primeval [praı¢mı:v(ə)l] Earth первобытная Земля
primordial первобытный
“primordial soup” «первичный бульон»
proofbreading исправление ошибок (при копировании матрицы)
properties свойства
provide обеспечивать
puffball дождевик
Punnett square method (by R.C.Punnett) метод Пуннетта
R
reach / achieve high concentrations достигать высоких концентраций
reactant molecule молекула-реагент
reduce сокращать
relatively относительно
release высвобождать
releaser пусковой механизм; пусковой раздражитель; стимул, вызывающий осуществление инстинктивного действия
remain constant сохраняться постоянным
remnant остаток
rennin ренин, химозин
replication репликация, ауторепродукция
reproduce воспроизводиться
requisite требуемый
resemble напоминать
reserve заповедник
reside in the cytoplasm находиться в цитоплазме
respiratory distress расстройства внешнего дыхания
retina сетчатка
revamp перестраивать, реконструировать
reveal обнаруживать, показывать
reverse transcriptase обратная транскриптаза (РНК-зависимая ДНК-полимераза)
ringworm обусловленный красным трихофитоном микоз
roam бродить
roan чалый
rock ledge уступ скалы
rudimentary рудиментарные
rust ржавчинный гриб
S
sac fungi (ascomycetes) аскомицеты
scholarship стипендия
scratch ссадина, царапина
seasonal molting сезонная линька
secretin оксикринин, секретин
sediments осадочных породах
self-fertilization самоопыление
sequence последовательность
septum септа, перегородка
set of substances комплекс веществ
severe суровый
sex-linked сцепленный с полом
shallow sea мелкое море
shed сбрасывать (кожу, рога)
shelf fungus (monkey-stool) берёзовый гриб, чага
shell раковина, панцирь
Silurian period силур
single-stranded однонитевой, одноцепочечный (о нуклеиновых кислотах)
smut головнёвый гриб
sodium натрий
soft fruit rot плодовая гниль
sparsely редко, негусто
spawn нереститься
spectator зритель
sperm семя
spleen селезёнка
spontaneously спонтанно
sporangium [spə¢rændзıəm] (pl. sporangia) спорангий
stamen [¢steımen] тычинка
steam пар
straightforward прямолинейный
stud усеивать, усыпать
subcellular structure субклеточная структура
substrate molecule молекула субстрата
subvert разрушать
succumb погибать
sulphur [¢sΛlfə] сера
survival of the fittest выживание наиболее приспособленного
swab off смазывать
swarm кишеть
T
T cell Т-клетка
tadpole головастик
taxis таксис
test cross опытный гибрид
thymine тимин
thyroxine тироксин
tissue ткань
tortoise сухопутная черепаха
trigger инициировать, дать начало
trisomy трисомия
true-breeding разведение гомозигот
turtle морская черепаха
U
undergo a series of reactions проходить через последовательность реакций
unerringly точно, безошибочно
universe вселенная
UV light / radiation ультрафиолетовый свет / излучение
V
valence валентность
variation in traits различия в признаках
vascular васкулярный
vast increase значительное увеличение
vessel сосуд, склянка
via [¢vaıə] посредством
vital жизненный
W
ward off отражать, отвращать (удар, опасность)
waste products отходы
water loss потери воды
waterproof coating водонепроницаемое покрытие
water-soluble водорастворимый
withstand противостоять
woodpecker дятел
worm червь
X
X-ray diffraction дифракция рентгеновских лучей
Y
yeast (baker’s yeast, brewer’s yeast) дрожжи (пекарские, пивные)
yield давать урожай, производить
Z
zygospore ascus (pl. asci [¢æsaı]) зигоспора
zygote fungi (zygomycetes) зигомицеты
Оглавление
Предисловие3
Unit 1. Life and Levels of Organization of Living Matter 6
Grammar: Passive Voice
Unit 2. Biological Molecules 21
Grammar: The Use of Passive Structures
Unit 3. Energy Flow in the Life of a Cell 31
Grammar: Ved[2] Forms
Unit 4. Principles of Evolution 39
Grammar: Ving[3] Forms
Unit 5. The History of Life on Earth 52
Grammar: -Ing and –ed Participles; -ing and –ed Participle Constructions
Unit 6. Biotechnology 61
Grammar: Infinitive
Unit 7. The Double Helix 77
Grammar: Modal Verbs: Can and Could
Unit 8. Inheritance 91
Grammar: Modal Verbs: May and Might
Unit 9. Fungi 108
Grammar: Modal Verbs: Must, Need to, Have to and Be to
Unit 10. The Evolution of Hormones 122
Grammar: Modal Verbs: Should and Ought to
Unit 11. The Immune Response 134
Grammar: Modal Verbs: Shall and Will
Unit 12. Animal Behaviour 145
Grammar: Conditionals
Приложение156
Список литературы 174
Англо-русский словарь175
[1]Упражнение цитируется по учебнику “Learn to Read Science”, ex.8, 9, p. 67.
[2] Ved means ‘past participle’.
[3] Ving means ‘present participle’.