COMPLEMENTARY INHERITANCE AND SUPPLEMENTARY INHERITANCE - PowerPoint PPT Presentation

About This Presentation

Title:

COMPLEMENTARY INHERITANCE AND SUPPLEMENTARY INHERITANCE

Description:

TYPE OF INHERITANCES – PowerPoint PPT presentation

Number of Views:378

Slides: 30

Provided by: thilgar

Category: Concepts & Trends

Tags:

more less

Transcript and Presenter's Notes

Title: COMPLEMENTARY INHERITANCE AND SUPPLEMENTARY INHERITANCE

1
COMPLEMENTARY INHERITANCE SUPPLEMENTARY
INHERITANCE SUBMITED BY,M.THILAKAR,SCHOOL OF
LIFE SCIENCES,BHARAHTHI DASAN UNIVERSITY,TIRUCHI
RAPALLI.INDIA.
2
CELL BASIC UNIT OF LIFE

Cellls are the basic unit of life.
PROKARYTE Less than thousand of mm long and
lacks a complicated system of internal membranes
and membranous organouls.
EUKARYOTE Larger then prokaryotes. Contain
complicated internal membranes.
They contain Cytoplasm, Nuleus, DNA, RNA, etc.,

3
CONT.....

Hall mark of all Eukaryote cells is that their
Hereditary material is contained within a large
Membranes bounded strucuture called nucleus.
Nuclei of Eukaryote cell is provoded a safe haven
for DNA, which is organised into discrete
structure called Cromosomes.
Genes are located in Cromosome.
Consisit of one Double Strand DNA molecule with
an assortment of Proteins.
In Prokarytes Plasmids Circular.

4
Mendelism

Father of Genetics.
1822 1884.
Gardening
Pea plants.
Natural History of Society, Brunn.
Correns,
De vries,
Tshermark _at_ 1900.

5
Pea Plant

Pea plants are Self Fertilizing plants.
Cross ploniation is not difficult.
Artificial Fertilzation is almost success.
Short Life cycles.

6
(No Transcript)
7

Law of Dominance Of the two alleles, one Allele
expresses its Character in F1.
Law of Segregation During Gamete formation, the
Genes of a pair separate in Mieosis and each
gamete receives only one / gamete.
Law of independent Assortment genes for each
pair of character seperate independently from
those of other characters during gamete formation.

8
COMPLEMENTARY INHERITANCE
9
COMPLEMENTARY GENES

Two or More Allelic dominant genes interact with
each another to produce a Character
But one gene cannot produce that character in the
Absence of other.
Action of these Independent genes are
Complementary.
Its a Non allelic gene Interaction.

10
Experiment 1 INERITANCE IN SWEET PEA PLANT

Bateson and Punnet
Flower color in Sweet pea plant, Lathyrus
odoratus.
Two varieties of Flower colors.
1. Red color, 2. White color
Red color due to te Pigment Anthocyanin, from a
colorless substance Chromogen by the action of
Enzyme.

Parents White x White
Ccaa x ccAA
GAMETES Ca x cA
F1 CcAa
Red
F1 x F1
Gametes CA Ca ca ca
Chromogen Enzyme Anthocyanin.
Gene C Chromogen
Gene A Enzyme Ratio 9 7

12
INHERITANCE OF FLOWER COLOR IN SWEET PEA

GAMETES CA Ca Ca Ca
CA CCAA RED CCAa RED CCAa RED CcAa RED
Ca CCAa RED Ccaa WHITE Ccaa RED Ccaa WHITE
cA CcAA RED CcAa RED CcAa WHITE CcAa WHITE
ca CcAa RED Ccaa WHITE Ccaa WHITE Ccaa WHITE
13
RESULTS

F2 GENERATIONS
RED 9 WHITE 7
Ratio 9 7
Two or More Allelic dominant genes interact with
each another to produce a SINGLE Character.
But SINGLE gene cannot produce that character in
the Absence of other.
Action of these Independent genes are
Complementary.

14
Experiment 2 PERICARP COLOR IN GRAINS OF BARELY

Two varieties of Pericarp colors in grains. 1.
Red color, 2. White color.
Red color due to the Pigment Anthocyanin, from
a colorless substance Chromogen by the action of
Enzyme.
If the enzyme absent, Anthocyanin can not be
synthesized in cells.
So anthocyanin needs both of Chromogen and enzyme.

PARENTS WHTIE GRAIN x WHITE GRAIN
ReRejj x rereJJ
GAMETES Rej x reJ
F1 RereJj
Red Grain
F1 x F1
GAMETES ReJ reJ ReJ reJ

16
INHERITANCE OF PERICARP COLOR IN BARELYF2Ratio
9 7
GAMETES ReJ Rej reJ Rej
ReJ ReReJJ RED ReReJj RED RereJj RED RereJj RED
Rej ReReJj RED ReRejj WHITE RereJj RED Rerejj WHITE
reJ RereJJ RED RereJj RED rereJJ WHITE rereJj WHITE
Rej RereJj RED Rerejj WHITE rereJj WHITE rerejj WHITE
17
RESULTS

F2 GENERATIONS
RED 9 WHITE 7
Ratio 9 7
Two or More Allelic dominant genes interact with
each another to produce a SINGLE Character.
But SINGLE gene cannot produce that character in
the Absence of other.
Action of these Independent genes are
Complementary.

18
SUPPLLEMENTARY INHERITANCE
19
SUPPLLEMENTARY GENES

Two independent pairs of dominant genes, which
interact in a such way that each dominant gene
produces its effect whether the other is present
or not.
But even second dominannt gene is added to first,
a new character is expressed.
Non allelic interactions

20
Experiment 1 INERITANCE OF COMBS IN FOWLS

Bateson and Punnet in 1908.
In Fowls, Four types of Combs. 1. Rose, 2.
Pea, 3. Walnut, 4.Single
Rose R, Pea P.
Rrpp Produces Single Comb type.
If R P Walnut.

PARENTS
RED COMB MALE x PEA COMB FEMALE
RRpp x rrPP
GAMETES Rp x Rp
F1 RrPP
WALNUT
F1 X F1
GAMETES RP Rp rP rp

22
INHERITANCE OF COMBS IN FOWLSF2
GAMETES RP Rp rP rp
RP RRPP Walnut RRRp Walnut RrPP Walnut RrPp Walnut
Rp RRpp Walnut RRpp ROSE RrPp Walnut Rrpp ROSE
rP RrPP Walnut RrPp Walnut rrPP PEA rrPp PEA
Rp RrPp Walnut Rrpp ROSE rrPp PEA Rrpp Single
23
RESULTS

F2 GENERATIONS
WALNUT 9 ROSE 3
PEA 3 SINGLE 1
Ratio 9 3 3 1
Two independent pairs of dominant genes interact
in a such way.
Each dominant gene produces its effect whether
the other is present or not.
But even second dominant gene is added to first,
a new character is expressed.

24
Experiment 2Coat color in Mice

Studied by Castle.
3 Types of Mice
1. Agouti, 2. Black, 3. Albino.
Agouti - Dominant to Black and Albino.
Albino - Recessive to Agouti and Balck.
Black - Dominant ot Albino and
Recessive to Agouti.

PARENTS BLACK MALE x ALBINO FEMALE
Bbaa x bbAA
GAMETES Ba x Ba
F1 BbAa
Agouti
F1 x F1
GAMETES BA Ba bA ba

26
INHERITANCE IN COATS OF MICEF2
GAMETES BA Ba bA ba
BA BBAA AGOUTI BBAa AGOUTI BbAA AGOUTI BbAa AGOUTI
Ba BBAa AGOUTI Bbaa BLACK BbAa AGOUTI Bbaa BLACK
bA BbAA AGOUTI BbAa AGOUTI bbAA ALBINO bbAa ALBINO
ba BbAa AGOUTI Bbaa BLACK bbAa ALBINO Bbaa ALBINO
27
RESULTS