How to ace through EAMCET the easy way

The Engineering, Agriculture and Medical Common Entrance Test (EAMCET) 2014 examination is expected to be held on May 22, 2014 after rescheduling because of the Lok Shabha polls. Applications are available till April 4, 2014. Only candidates belonging to Andhra Pradesh are eligible for EAMCET 2014.

EAMCET, MEDICAL examination will be conducted for a total of 160 marks. 80 marks will be allotted to Biology, 40 for Physics and 40 for Chemistry. 160 Questions will be asked and candidates have to answers them in the duration of 3 hours. Every question carries one mark and have no negative marking.

With exam dates postponed by five days and more than a couple of months now, a quick review of the exam pattern and a few this -n-that will help aspirants get an extra edge.

•  Biology covers fifty percent of the question paper. Hence students have to give priority to Biology. For scoring good ranks students have to earn good marks in Physics, Chemistry and 70 marks out-of 80 in Biology.

• As there are no criteria for compulsorily scoring some minimum marks in any subject, hence students have to work-hard for scoring more marks in the subject in which they have good knowledge.
• The exam has no negative marking system; students can hence apply their luck on questions they aren't sure of
• In EAMCET either one or two questions will be asked from each topic of every subject, hence students have to give equal preference to all topics and sections.
• Easy and less quantity topics should be practiced early. Morphology, Animal physiology, Cell biology, Microbiology,Plant physiology  and Reproduction are the easiest and probable topics in Mathematics.
• Equal preference will be given to the Intermediate first year and second year syllabus. Speed of answering and exactness should be developed.

The marks scored in EAMCET will be given as 75 weight age and marks scored in groups subjects in Intermediate course will be given as 25 percent weight age. Final rank will be prepared by joining the both marks.

Keep calm and prepare! don't discuss unnecessary points with others 

I WISH U ALL THE BEST 

AIPMT 2014: Tips and Tricks to score high

Tips:

• Cover all topics given in syllabus, avoid skipping any topic
• Prepare beginning from Class 11 syllabus before moving on to Class 12. Make sure you are clear on the basic concepts.
• Don't hesitate to clear confusions from Class 11 even though you are in Class 12
• Begin your preparation as soon as possible
• First understand concepts from NCERT books before moving on to others.
• When selecting extra books to study from, aim to focus more on question banks/ sample papers/ previous papers and buy text books for topics you have doubts in or are weak in
• Make sure when you buy question banks/ sample papers/ previous year papers that answers are given. This way you can identify and improve on the sections you went wrong in.
• Create a quick revision sheet for each subject. Add points that are important and that you are likely to forget.
• Follow subject-wise study patterns instead of applying the same studying technique to all subjects for example use flow charts for Biology Processes, a formulae list for Physics numericals and mnemonics for Biology and Chemistry
• Create a fresh study schedule every month based on your success or difficulty with the current study schedule.
• Try to study at least 2 subjects per day and increase to 3 subjects to get into the habit of thinking about all 3 subjects that will appear in the exam
• Study diagrams, even though you won't be asked to draw any diagram based questions may come.
• As AIPMT questions are not necessarily repeated it important to revise all topics carefully
• Give extra attention to Biology 90 questions are based on it. Study Botany and Zoology equally.
• Practice Sample papers and previous year papers within the time limit you will be given at the exam.
• Revise at least twice

Medical colleges in Andhra Pradesh -PROFILES

Medical colleges in Andhra Pradesh

1. Andhra Medical College
2. Deccan College of Medical Sciences, Hyderabad
3. Guntur Medical College
4. Kakatiya Medical College, Warangal
5. Kurnool Medical College
6. Osmania Medical College
7. Rangaraya Medical College,Kakinada
8. S V Medical College,Tirupati
9. Siddhartha Medical College,Vijayawada
10. Gandhi Medical College
11. Narayana Medical College
12. Alluri Sitaram Raju Academy of Medical Sciences,Eluru
13. Chalmeda Anand Rao Instt. Of Med. Sciences,Karimnagar
14. GSL Medical College, Rajahmundry
15. Kamineni Institute of Medical Sciences,Narketpally
16. Katuri Medical College, Guntur
17. Maharajah's Institute of Medical Sciences, Vizianagaram
18. Mamata Medical College, Khammam
19. Mediciti Institute Of Medical Sciences,Ghanpur
20. MNR Medical College,Sangareddy
21. P E S Institute Of Medical Sciences and Research, Kuppam
22. P.S.I. Medical College , Chinoutpalli
23. Prathima Institute Of Medical Sciences,Karimnagar
24. Jorhat Medical College
25. Bhaskar Medical College, Yenkapally
26. Dr. VRK Womem's Medical College, Aziznagar
27. Government Medical College, Anantapur
28. Great Eastern Medical School & Hospital
29. Konaseema Institute of Medical Sciences & Research Foundation, Amalapuram
30. Rajiv Gandhi Institute of Medical Sciences, Srikakulam
31. S V S Medical College, Mehboobnagar
32. Santhiram Medical College, Nandyal
33. Shadan Institute of Medical Sciences,Research Centre and Teaching Hospital, Peerancheru
34. N.R.I academy Of Sciences
35. Vardhman Mahavir Medical College

CHAPTER 7 - SEXUAL REPRODUCTION IN FLOWERING PLANTS

CHAPTER 7 - SEXUAL REPRODUCTION IN FLOWERING PLANTS

FLOWER -  itis the fascinating reproductive organ of angiosperms.
It consist of :-

1. Calyx
2. Corolla
3. Androecium
4. Gynoecium

PRE- FERTILISATION – STRUCTURES AND EVENTS

• —  Hormonal and structural changes are initiated leading to differentiation and development of floral primordium.
• —  Inflorescences are formed which bear floral buds and then flowers.
• —  Androecium and Gynaecium differentiate and develop.

STAMEN
—  Stamen consist of

1. Anther – terminal bilobed structure       
2. Filament – long slender stalk. Proximal end of the filament is attached to the thalamus or

petal.

STRUCTURE OF ANTHER

• —  Anther has two lobes (bilobed). Each lobe consists of two theca. Hence it is dithecous.
• —  Anther is a tetragonal structure which consist of four microsporangia located two in each lobe.
• —  Microsporangium develops into pollen sacs.
• —  Pollen sacs run longitudinally and contain pollen grains.

STRUCTURE OF MICROSPOANGIUM
—  A typical microsporangium appears circular in outline.

It is surrounded by 4 walls.

1. Epidermis          -  protects and help in dehiscence of anther.
2. Endothecium
3. Middle layers
4. Tapetum             - nourishes the developing pollen grain

SPOROGENOUS TISSUE
It is compactly arranged homogenous cells which are present at centre of each microsporangium when the anther is young.

MICROSPOROGENESIS

• —Process of formation of microspores from pollen mother cell through meiosis.
• —The cells of the sporogenous tissue/microspore mother cell (2n) meiotically divide to form microspores which are arranged in a cluster of 4 cells called MICROSPORE TETRAD.
• —When the anther matures and dehydrates, the microspore dissociate from each other and develop into pollen grains
• —Thousands of pollen grains formed inside a microsporangium- released with dehiscence of anther.

POLLEN GRAINS
Pollen grains are male gametophyte - spherical in shape.

STRUCTURE OF POLLEN GRAIN
Pollen grains are made of 2 layered Wall,

1. Exine :- Made of sporopollenin- most resistant organic matter known,
2. Intine :-

                 -Thin and continuous layer
                - Made of cellulose and pectin
  3. Germ pores
                 - apertures on exine where sporopollenin is absent
                 - forms pollen tube.
  4. A plasma membrane surrounds cytoplasm of pollen grain.

MATURE POLLEN
—  A mature pollen consist of 2 cells with nucleus (Vegetative and Generative)

VEGETATIVE CELL

• Bigger
• Abundant food reserve
• Large irregular nucleus
• Responsible for the development of pollen grain

GENERATIVE CELL

• Small
• Involves in syngamy (fuse with an egg)
• Dense cytoplasm and nucleus.

Effect of Pollen on Human:

• Pollen grains cause allergy and bronchial afflictions
• Leading to chronic respiratory disorders like asthma, bronchitis Eg :- Parthenium (carrot grass)

POLLEN PRODUCTS:

• Rich in nutrient.
• Pollen tablets and syrup

              - food supplements
              - claims to increase performance of athletes and race  horse.

Period of viability

• Once shed the pollen grains have to land on the stigma before they lose viability if they have to bring about fertilization.
• Period of viability depends on temperature and humidity. Example:- cereals takes 20 minutes and members of rosaceae, leguminoseae, solanaceae  take months.

• Pollen grains stored by CRYOPRESERVATION.
• Used in crop breeding programmes.

PISTIL, MEGASPORANGIUM AND EMBRYO SAC :

GYNAECIUM - female reproductive part of flower

• —  Gynaecium with 1 pistil – Monocarpellary
• —  Gynaecium with more than 1 pistil – Multicarpellary 
• —  Fused pistil – Syncarpous 
• —  Free pistil – Apocarpous.

PISTIL
Pistil consist of

1. Stigma
2. Style
3. ovary

• ovarian cavity
• placenta

Ovules arise from placenta.

• single ovule – wheat, paddy
• Many ovules - papaya, water melons, etc.

MEGASPORANGIUM (OVULE)

• —  Ovule is a small structure attached to placenta.
• —  Funicle – stalk by which ovule is attached to placenta
• —  Hilum - junction between ovule and funicle 
• —  Integuments - protective envelops
• —  Micropyle - small opening at the tip of ovule into where pollen tube enters
• —  Chalaza - basal part of ovule
• —  Nucellus (2n)-mass of cells enclosed in integuments. Has abundant food reserve.

MEGASPOROGENESIS

• —  Process of formation of megaspores from megaspore mother cells is called MEGASPOROGENESIS.
• —  Megaspore mother cells divide meiotically to form 4 megaspore (haploid)
• —   out of 4, only 1 megaspore is functional and forms gametophyte and the rest degenerate.

 FEMALE GAMETOPHYTE (EMBRYO SAC)

• —  The embryo sac develops from the functional megaspore (n).
• —  MONOSPORIC DEVELOPMENT:- formation of embryo sac from a single megaspore.

FORMATION OF EMRYO SAC

• —  Nucleus of functional megaspore divides mitotically to form 2 nuclei which move to opposite poles forming 2-nucleate embryo sac.
• —  Two more mitotic nuclear division results in 4-nucleate and later 8- nucleate stages of embryo sac.
• —  Then cell wall is laid down leading to organization of female embryo sac.

STRUCTURE OF EMBRYO SAC

• —  Egg apparatus - present at the micropylar end and consist of 2 synergids and 1 egg cell

Synergids have cellular thickenings at micropylar tip called FILIFORM APPARATUS – guides the pollen tube into the synergid

• —  Antipodal - 3 cells present at chalaza end
• —  Polar Nuclei - Large central cell.

POLLINATION

• —  The transfer of pollen grains from anther to stigma of a pistil is called pollination.
• —  Based on the source of pollen, pollination is of  3 types:-

                     - AUTOGAMY
                     - GEITONOGAMY
                     - XENOGAMY

1. AUTOGAMY

• Transfer of pollen grains from anther to stigma of the SAME flower.

REQUIREMENT:-

1. Synchrony in pollen release and stigma receptivity.
2. Closeness of stigma and anther

• Chasmogamous flowers- flowers with exposed anthers and stigma
• Cleistogamous flowers-flowers which do not open at all
• Cleistogamy is disadvantageous because there is no chance of variation.
• Ex:- oxalis ,viola

2. GEITONOGAMY

• —  Transfer of pollen grains from anther to stigma of another flower of the same plant.
• —  Genetically similar
•   Ex:- cucurbits

3. XENOGAMY

• Transfer of pollen grains from anther to stigma of another flower of different plant
• Genetically different pollen grains are brought to the stigma.

Agents of Pollination:
1)      Abiotic agents:
         a)      Wind
         b)      Water
2)      Biotic agents:
          a)      Insects
          b)      Birds
          c)       Bats
          d)      Reptiles
          e)      Mammals

Adaptations in flowers for Pollination

I. Wind Pollination

• pollen  grains :– light, non- sticky, winged
• anther :- well exposed 
• stigma :- large and feathery
• flower :- one ovule, arranged as inflorescence

         Ex : corn cob, cotton, date palm

II. Water Pollination
                   - Bryophytes, Pteridophytes, Algae 

• pollen grains : protected by mucilaginous covering

          Ex : Fresh water plants- Vallisneria, Hydrilla
                 Sea grass- Zostera  

Main features of wind and water pollinated plants
         - produce pollen grains in large no.
         - do not produce nectar

III. Insect Pollination
       - Flowers : large, colourful, fragrant, rich in nectar
       - Pollen grains : sticky
       - Stigma : sticky

Certain rewards to pollinators:

• nectar and (edible) pollen grains as foods
•  provide safe place for laying eggs

Ex : Amorphophallus, Yucca

Outbreeding Devices

Continued self - Pollination – Inbreeding depression

Ways to avoid Self-pollination : 
(i) Pollen release & stigma receptivity – not synchronised
(ii) Stigma and anther – placed at different positions
(iii) Self-incompatibility
(iv) Production of unisexual flowers

       Eg: castor, maize (prevents autogamy)
              papaya (prevents autogamy & geitonogamy) 


Pollen – Pistil Interaction
All events – from deposition of pollen on stigma till the pollen tube enters the ovuleis called     Pollen-pistil interaction.
•        Recognition of compatible pollen
•        Germination of pollen grains
•        Development of Male Gametophyte

Artificial Hybridization

• Crossing diff varieties of species- hybrid individual- with desirable characters of the parent plants
• desired pollen grains for pollination- stigma protected from contamination 
• Emasculation : removal of anther
• Bagging : flower covered- bag made up of butter-prevent contamination of stigma from unwanted pollen

Bagged flower- attains receptivity - mature pollen grains- dusted on the stigma – rebagged - fruits allowed to develop

• Double Fertilisation 
• Syngamy 

       - pollen tube releases male gametes into synergids
       - fusion of 1 of male gametes and egg cell
       - fusion of 2nd male gamete and polar nuclei =Triploid endosperm nucleus- PEN (Triple Fusion)
       - PEN – now called Primary Endosperm Nucleus – Endosperm

Post- fertilization Events        
All events that occur in a flower, after double fertilization is called Post- fertilization events

Major events are : 
   (i)            Development of endosperm
  (ii)             Development of embryo
 (iii)             Maturation of ovule into seed
 (iv)             Maturation of ovary into fruit

Endosperm

†     Two types of endosperm development :
          (i) Free nuclear type (common method)
          (ii) Cellular type
†      Cells of endosperm– store food materials- used for developing embryo
†      Non - Albuminous / Non-Endospermic seeds- endosperm completely utilized - before maturation of seeds. Ex: pea
†      Albuminous / Endospermic seeds- a portion of endosperm remain in mature seeds. Ex: castor

Embryo
†     Embryogeny – early stages of embryo development
†      Zygote   à     Proembryo    à   Mature embyo (heart-shaped)

Embryo consists of:
                 - embryonal axis
                 - cotyledons
                 - plumule
                 - radicle

Monocotyledonous Seed
-          Scutellem = Cotyledon
-           Coleorrhiza: undifferentiated sheath covering radical & root cap
-           Coleoptile: sheath covering plumule  

Seed
-          Fertilized and mature ovule develops into seed.

Seed consists of:
-          cotyledon(s)
-          embryonal axis
-          Seed coat - double layered - formed by integuments     

• Testa (outer coat)
• Tegmen (inner coat)

-          Micropyle: - small o        pening on seed coat, it facilitates entry of H2O & O2 into seeds (for germination)
-          Hilum:- scar on seed coat
-          Seed     - Albuminous / Non-Albuminous
-          Perisperm : remnants of nucellus that is persistent. Ex: Black pepper
-          Dormancy:  state of inactivity

Advantages of Seeds

• To plants

    (i) Seeds - reserve food materials- nourish seedling
    (ii) Seed coat- protection to young embryo
    (iii) Seeds of large no of species –live for several years
    (iv) Seeds - better adaptive strategies- dispersal to new habitats- better survival

• To mankind

      (i) used as food - throughout the year
      (ii) seed - basis of agriculture

Fruit
-          True fruit : - Fruit formed from the ovary
-          Parthenogenesis:  If ovary transform to fruit without fertilization. Ex : Banana
-          Parthenocarpy – induced with gibberellins & auxins without fertilization.
-          False fruit: any part other than ovary- forms the fruit. Ex: Apple 


Apomixis & Polyembryony 
Other modes of reproduction

Apomixis
-          Form of asexual reproduction- mimics sexual reproduction- seed formed without fertilisation
-          Formation of apomictic seeds :
·         diploid cell (formed without meiosis) - develop into embryo without fertilization
·         cells of nucellus (2n) surrounding embryo sac- protrude into embryo sac - develop into embryos. Ex. Citrus and Mango.

Polyembryony 
-          Occurrence of more than one embryo in a seed
-          Often associated with apomixes.  Ex: Citrus, groundnut

CHAPTER 6 -MODES OF REPRODUCTION IN ORGANISMS

CHAPTER 6 - REPRODUCTION IN ORGANISMS

Reproduction

•  Reproduction is the biological process in which an individual gives rise to an offspring similar to itself.

Types of Reproduction:
Based on whether there is one or two organisms taking part in the process of reproduction

• ASEXUAL REPRODUCTON
• SEXUAL REPRODUCTION

Asexual Reproduction:

1. Usually followed by organisms with relatively simpler organizations.
2. Off springs produced by single parent.
3. With/without involvement of gamete formation.
4. Off springs produced are genetically and morphologically similar to each other and to the parent, i.e. they are clones.

Modes of asexual reproduction:

1.Binary fission
Parent cell divides into 2 daughter cells.

E.g.. Amoeba, Paramecium

2.BUDDING
Parent cell divides to form large cell and small cell, called bud, attached to the large cell; the bud gets separated and grows into an adult. E.g., Yeast

• In fungi and algae specialized asexual reproductive units are formed

        Zoospores in many algae and certain aquatic fungi, Conidia (Penicillium), Buds (Hydra), Gemmules (Sponge).

• In higher plants, vegetative propagation is followed using units such as rhizome, sucker, offset, bulb, tuber etc. – known as vegetative propagules.

 
Examples of Vegetative Propagation:

WATER HYACINTH (Terror of Bengal)

• One of the most invasive weeds
• Grows wherever there is standing water
• Drains oxygen from water- leads to death of fishes.
• Introduced in India because of its pretty flowers & shape of leaves
• Vegetative propagation occurs at a phenomenal rate

II SEXUAL REPRODUCTION:

• Involves formation of male and female gamete by two individuals of the opposite sex.
• Offspring produced by fusion of male and female gametes not identical to each other or to the parents.
• All sexually reproducing organisms share a similar pattern of reproduction.

DIFFERENT PHASES IN SEXUAL REPRODUCTION:

1. JUVENILE PHASE
   It is a period of growth and maturity of an organism before it can reproduce sexually.

 2. REPRODUCTIVE PHASE
   Period in which organism is capable of reproducing sexually

• Easily seen in higher plants when they come to flower.
• Some plants flower seasonally & some through out the year
• Few plants exhibit unusual flowering phenomenon

 For e.g.. 1. Bamboo species flower only once in their lifetime. 2. Srobilanthus kunthiana (neelakurinji) found in hilly areas of Kerala, Karnataka & Tamil Nadu flower once in 12 years the latest being in September 2006.

• In animals sexual reproduction is usually seasonal
• In placental mammals there is occurrence of cyclical changes in the activities of ovaries & accessory ducts as well as hormones.

• In non primate mammals like dogs, rats etc these cyclical changes during reproduction is called oestrus cycle – no bleeding occurs.
• In primate mammals like apes & humans, these cycles are called menstrual cycles.

3. SENESCENT PHASE

• It is the end of reproductive phase.
• Old age ultimately leads to death

EVENTS IN SEXUAL REPRODUCTION:

1.       PRE-FERTILIZATION EVENTS:
a)      GAMETOGENESIS

• The gametes are usually haploid
• Gametes called homogametes / isogametes when both have same appearance. 
• When gametes are different, they are called heterogametes; male gamete known as antherozoid /sperm, female is called ovum / egg.
• Bisexual organisms called as homothallic / monoecious whereas unisexual organisms called heterothallic / dioecious.

b)GAMETE TRANSFER

• In most of the organisms, male gametes are motile & female gametes are stationary.
• In algae, bryophytes & pteridophytes water is the medium for gamete transfer.
• Pollination is the method of gamete transfer in higher plants as pollen grains are carriers of male gametes.

2.       SYNGAMY / FERTILIZATION:

• Syngamy results in formation of a diploid zygote.
• In certain animals, female gamete develops into the adult organism without fertilization; such a process is called parthenogenesis - seen in rotifers, lizards turkeys etc.
• Fertilisation may be external or internal

EXTERNAL FERTILIZATION Syngamy occurs outside the body of the organism Large numbers of gametes are released in the surrounding medium. Ex. Bony fishes and Amphibians.

INTERNAL FERTILIZATION Syngamy occurs inside the body of the organism Numbers of ova produced are less, but large numbers of male gametes are released and they travel towards the ovum. Ex. Birds and Mammals.

3.       POST FERTILIZATION:

• Events in sexual reproduction after the formation of zygote
• Zygote – vital link that ensures continuity of species between organisms of one generation and the next.
• Development of zygote depends on 

             - the type of life cycle of the organisms.
             - the environment it is exposed to.

• Zygote develops into embryo.

Embryogenesis involves:
             - cell division to increase the number of cells
             - cell differentiation for the formation of different kinds of tissues

• Based on whether the development of zygote occurs inside or outside the body of the female parent, animals are categorized into oviparous and viviparous.

OVIPAROUS These animals lay eggs. The fertilized eggs have a calcareous shell to protect them from harsh environment.

VIVIPAROUS These animals give birth to young ones Embryo protected inside the mother’s body.

• In flowering plants the zygote formed inside the ovule; zygote develops into embryo after which the ovule becomes the seed and ovary becomes the fruit.