SlideShare a Scribd company logo

Inbreeding and outbreeding

β€’Download as PPTX, PDFβ€’
β€’
L
LekshmiJohnson

This powerpoint gives a clear picture on inbreeding and also about outbreeding of higher organisms. This also explains the advantages and disadvantages of the above said topics. the methods of inbreeding and reasons for inbreeding also given in this powerpoint.

Education
1 of 21
DR.N.C.J.PACKIA LEKSHMI NICHE INBREEDING AND OUTBREEDING
INBREEDING Introduction ο‚— Reproduction implies replication ο‚— Biological reproduction always yield reasonable carbon copy of parent unit ο‚— Sexual reproduction practiced by majority of animals, plants and microorganisms ο‚— It produces diversity needed for survival in a world constant change (ie., evolution) ο‚— Sexually reproducing individuals may have individuals which are unisexual or bisexual. ο‚— Bisexuality is common in plants and lower animals. ο‚— Higher animals are unisexual, i.e., separate male and separate female sexes exist. ο‚— Sexual reproduction performs the basic function of providing a great variety of genotypes. ο‚— Great variety of genotype has much higher evolutionary significance ο‚— Living organisms fundamentally following two systems of mating occur: inbreeding and outbreeding
INBREEDING ο‚— The process of mating of individuals which are more closely related than the average of the population to which they belong. ο‚— Production of offspring through matings between related parents ο‚— Biparental: two different individuals are involved ο‚— Leads to deviations from H-W equilibrium by causing a deficit of heterozygotes ο‚— Inbreeding is affected by restrictions in population size or area which brings about the mating between relatives ο‚— Extreme inbreeding – Intragametophytic selfing – mating between gametes produced from the same haploid individual Generation AA Aa Aa 0 P2 2pq q2 1 P2+(pq/2) pq q2 2 P2+(3pq/4) Pq/2 q2+(3pq/4)
ο‚— 100% homozygosity in one generation – eg..some ferns and mosses (fern: Archegonium and anthridium) ο‚— Does not change allele frequency by itself ο‚— It does increase homozygosity but does not bring about a change in overall gene frequencies ο‚— Mating between two heterozygotes as regards two alleles A and a – result in half of the population homozygous for either gene A or a and half of the population heterozygous like the parent but the overall frequencies of A and a remain constant ο‚— Aa X Aa ο‚— 1 AA : 2Aa : 1aa ο‚— It brings about recessive gene to appear in a homozygous state (aa) ο‚— Homozygous recessive are phenotypically differentiated from the dominant
COEFFICIENT OF RELATIONSHIP (R) ο‚— Expression of the amount or degree of any quality possessed by a substance ο‚— Also a degree of physical or chemical change normally occurring in that substance ο‚— Characterizes the percentage of genes held in common by two individuals due to their common ancestory ο‚— Each individual gets only a sample half of his genotype from one of his parent ο‚— The sum (Ζ©) between two individuals through common ancestors is the coefficient of relationship and is represented by R: ο‚— RBC = The coefficient relationship between the full sibs B and C and is calculated as follows: ο‚— I.e., individuals B and C contain 1/2x1/2 = ΒΌ of their genes in common through ancestors D ο‚— i.e., individuals B and C contain 1/2x1/2 = ΒΌ of their genes in common through ancestors E ο‚— the sum of these two, the coefficient of relationship, between the full sibs B and C = ΒΌ+1/4=1/2 = 50 %
INBREEDING COEFFICIENT In diploid organism each gene has two alleles occupy the same locus – called identical genes If they descended from the same gene; such genes are homozygous at the lcous Such homozygosity also caused when two allels in a diploid organism are not descended from the common gene but the alleles of identical origin are brought together through mating between first cousins- such alleles are similar alleles The probability that the two alleles in a zygote are identical by descent is measured by inbreeding coefficient (F) 1. If the parents B and C are full sibs, i.e., B and C parents are 50% related, the inbreeding ccoefficient of individual A can be calculated by the equation FA = Β½ RBC, Where RBC is the coefficient of relationship between the full sib parent (B and C) of A 2. If the common ancestor are not inbred, the inbreeding coefficient is calculated by the equation: F = Ζ©(1/2)n1+n2+1 where n1 is the number of generations from one parent back to the ancestor and n2 is the number of generations form the other parent baCk to the same ancestor
3. In case the common ancestor are inbred, the inbreeding coefficient is calculated as follows F = Ζ©(1/2)n1+n2+1 (1+F ancestor) 4. The coefficient of inbreeding is also calculated by counting the number of arrows connecting the individual through one parent back to the common ancestor and back again to his other parent by the following equation: F = Ζ©(1/2)n1 (1+FA) n = number of arrows which connect the individual through one parent back to the common ancestor and back again to his other parent FA is the inbreeidng coefficient of the common ancestor Eg., the inbreeding coefficient for A in the following arrow diagram can be calculated by following method: B and C are the parents of A. there is only one pathway from B and C and that goes through ancestor E. Ancestor E is inbred, because its parents (G and H) are full sibs and are 50% related. The inbreeding coefficient can be calculated as FE = Β½ RGH (R = the coefficient of relationship between the full sibs G and H)
PANMIXIS – Random mating ο‚— If the breeder assigns no mating restraints upon the selected individuals, their gametes are likely to randomly unite by chance alone ο‚— Wind or insect carry pollen from one plant to another in essentially a random manner ο‚— Even livestock such as sheep and range cattle are usually bred panmicticly ο‚— The males locates females as they came into heat, copulate with and inseminate them without any artificial restrictions as they forage for food over large tracts of grazing lands ο‚— This mating method is most likely to generate the greatest genetic diversity among the progeny
ASSORTATIVE MATING ο‚— In sexually reproducing organism, the most rapid inbreeding system is that between brothers and sisters who share both parents in common – called full sib mating ο‚— Produces inbreeding coefficient of 25% in the first generation – reduced in succeeding generations since some alleles are identical ο‚— Within 10 generations, full sib mating can produce an inbreeding coefficient of 90% ο‚— Other inbreeding systems are half sib mating, parent offspring mating, third cousin mating – called genetic assortative matings ο‚— Parents of each mating type are sorted and mated together on the basis of their genetic relationship. ο‚— Assortative mating is of phenotypic type i.e., the mating between two like phenotypes, two like dominant or two like recessive phenotype ο‚— If it continues for many generations, eliminates the heterozygotes and the resulting will be homozygous dominant or homozygous recessive
DISASSORTATIVE MATING ο‚— Mating of unlike phenotypes and genotypes and tends to maintain heterozygosity ο‚— Mating between homozygous and an heterozygous individual for sex locus ο‚— Also results from dichogamy – producing mature male and female reproductive structures at different times ο‚— Fertilization between plants with different phenotype is favoured
LINE BREEDING ο‚— Special form of inbreeding utilized for the purpose of maintaining a high genetic relationship to a desirable ancestor ο‚— A possesses more than 50% of B’s gene ο‚— D possesses 50% of B’s gene and transmits 25% to C; B also contributes 50% of genes to C-hence C contains 50+25 = 75% B’s genes transmits to C and transmits half of them to A; B also contribute 50% to A – Hence A contains 50+37.5 = 87.5% of B’s gene
GENETIC EFFECTS ο‚— Results genetically in homozygosity ο‚— Produces homozygous stocks of dominant or recessive genes and eliminates heterzygosity ο‚— In each generation, heterozygosity is reduced by 50% and after 10 generation – total elimination of heterozygosity from the inbred line and production of two homozygous or pure lines ο‚— In humans, in happens very slowly
EFFECTS OF INBREEDING ο‚— Occurrence of genetic disorder – due to the development of homogygous recessive Physical and health effects ο‚— Reduced fertility ο‚— Increased genetic disorders ο‚— Fluctuating facial asymmetry ο‚— Lower birth rate ο‚— Higher infant mortality and child mortality ο‚— Smaller adult size ο‚— Loss of immune system function ο‚— Increased cardiovascular risks ο‚— Haemophilia in royal families ο‚— Increases hearing impairment
Reasons for inbreeding ο‚— Royalty, religion and culture, socioeconomic class and geographic isolation and small population ο‚— Religion and culture plays major role – many muslims and hindu societies practices unions of first cousin – advantage – bride’s relationship with her Mother in law and the up keep of the family’s property ο‚— Another incentive to close relative marriages concers brides wealth and dowry ο‚— To keep their property and land ο‚— In royal families – to preserve royal blood lines
APPLICATION OF INBREEDING ο‚— Inbreeding causes homozygosity of deleterious recessive genes which may result in defective phenotype – so in human society, the religious ethics unknowingly and modern social norms consciously have condemned and banned the marriages of brothers and sisters ο‚— Plant and animal breeders also avoid inbreedings in the individuals due to this reason ο‚— Inbreeding results in homozygosity of dominant alleles – it is a best mean of mating among hermaphrodites and self pollinating plant species for several families. ο‚— Animal breeders also use inbreeding to produce best race of horses, dogs, bulls, cattles etc… ο‚— Eg., modern race horse – descendents of three Arabian stallions and mated with several local mares of the slow heavy type – fast runners of F1 was selected and inbred and stallions of F2 appear as beginning point in the pedigrees of almost all modern race horses – called line breeding. ο‚— Merino sheep – fine wool producer – result of 200 yrs of inbreeding
OUTBREEDING ο‚— Mating involves individuals that are more distantly related – outcrossing or outbreeding – negative genetic assortative mating ο‚— Involves crossing individuals belonging to different families or crossing different inbred varieties of plants or crossing different breed of livestock ο‚— Increases heterozygosity and enhances vigour of progeny – i.e., hybrid have superior phenotypic quality but often has poor breeding value ο‚— The two inbred parents homozygous for different genes, if crossed produce F1 progeny – heterozygous ο‚— F1 progeny or hybrid – improved general fitness, resistance to diseases or it may show remarkable growth and vigour ο‚— The superiority of hybrid over parent – heterosis – coined by Shull ο‚— The terms heterosis and hybrid vigour are used as synonyms ο‚— Shull – the developed superiority of the hybrid – hybrid vigour ο‚— Heterosis – mechanism by which this superiority is developed ο‚— According to Whaley – hybrid vigour denotes the manifest effects of heterosis
Cross breeding and mule production ο‚— Mating of individuals from entirely different races or even different species – cross breeding ο‚— Produces sterile hybrids in comparison to normal outbreedings ο‚— Mule – a hybrid of a male donkey (Equus asimus, 2n = 62) and a female horse (Equus caballus, 2n = 64) ο‚— The hybrid from the reciprocal cross (i.e., female donkey or jenny and male horse or stallion) – hinny ο‚— Mule shows hybrid vigour and served mankind ο‚— Sexually sterile and have to produce everytime a new ο‚— Donkey stallions –imported from Europe by Indian army for breeding mules ο‚— Two kinds of mules used by Indian army; ο‚— 1. general service type and ο‚— 2. mountain artillary type – very important as they are firm footed animals that can carry heavy loads on steep himalayan mountain terrain
Manifestation of heterosis ο‚— Heterosis – increase in size and productivity ο‚— Eg.,some crosses of beans certain F1hybrids contain greater number of nodes, leaves and pods than their parents but the gross size of plant remain unaffected ο‚— In some hybrids – the growth rate is increased but there occur no increase in size of mature plant ο‚— Greater resistance to diseases, insect infestation and increased tolerance to erratic climatic condition are some eg of heterosis effect of plants ο‚— Shull - Corn or maize hybrids – diverse parentage – greater hybrid vigour ο‚— Problem is inbred lines are infertile – modified by a method called double cross method (Jones) ο‚— Double cross method – four inbred lines (A.B.C and D) ο‚— Single cross is made between A and B by growing two lines together and removing the tassels from line A – Cannot self fertilize – received only B pollen ο‚— Same method is followed for C and D in another locality ο‚— The yield of single cross hybrid is usually low because inbred parent lacks vigour and produces small cobs ο‚— Plants germinate from single cross seeds – vigorous hybrids with large cobs and many kernels
Genetic basis of heterosis ο‚— Two hypothesis ο‚— Dominance hypothesis of heterosis – holds that increased vigour and size in a hybrid due to combination of favourable growth genes by crossing two inbred races ο‚— Eg., Quinby and Karper – heterosis in sorghum – observed that heterozygote is significantly late in maturity and produces a greater weight of grain than either of the homozygote parents ο‚— Keeble and Pellow – studied two varieties of pea both semi- dwarf, one with thin stem and long internodes and the other with thick stem and short internodes ο‚— The F1 hybrid – taller than either of parents, combining the long internodes of one parent and many nodes of the other ο‚— Over dominance hypothesis of heterosis – proposed by Shull and East independently in 1908 ο‚— Increases with diversity of uniting gametes ο‚— Heterozygote is superior to either homozygous ο‚— Vigour increases in proportion to the amount of heterozygosity
Application of heterosis ο‚— Exploited at commercial scale both in plants and animals ο‚— In plants – applied to crop plants, ornamentals, fruit crops ο‚— More important in vegetatively propogating plants ο‚— In fruit plants and ornamental plants – if heterosis is achieved – may maintained for long ο‚— Sometime intermediate phenotypes are preferred ο‚— General purpose cattle can be produced by crossing beef type with a dairy type – offspring produce an intermediate yield of milk and have a fair meat when slaughtered ο‚— Similar in chicken – egg type with meat type ο‚— Plants – disease resistance
Evolutionary significance of inbreeding and outbreeding ο‚— Both provide raw material to natural of selection ο‚— Inbreeding allows natural selection to operate on successive genes – but not permit the introduction of good mutations from outside ο‚— Outbreeding provides an oppurtunity for the accumulation of good trait of different races in one individual or line ο‚— It expresses good qualities of the races and masked the deleterious recessive alleles ο‚— Both provide new allelic combinations which may be good or bad for the natural selection

Recommended

Inbreeding
InbreedingInbreeding
InbreedingMd. Abu Bakar Siddik
Β 
Hardy weinberg law
Hardy weinberg lawHardy weinberg law
Hardy weinberg lawSrishti Aggrawal
Β 
Pleiotropy
PleiotropyPleiotropy
PleiotropyICHHA PURAK
Β 
heritability its type and estimation of it
heritability its type and estimation of itheritability its type and estimation of it
heritability its type and estimation of itsambhaji yamgar
Β 
Heterosis
Heterosis Heterosis
Heterosis University of Gujrat (Campus Govt.Murray College Sialkot)
Β 
Gene pool
Gene poolGene pool
Gene poolBahauddin Zakariya University lahore
Β 
Inbreeding and inbreeding depression
Inbreeding and inbreeding depressionInbreeding and inbreeding depression
Inbreeding and inbreeding depressionParvati Tamrakar
Β 
Hardy weinberg law
Hardy weinberg lawHardy weinberg law
Hardy weinberg lawKanimoli Mathivathana
Β 

Recommended

Inbreeding
InbreedingInbreeding
InbreedingMd. Abu Bakar Siddik
Β 
Hardy weinberg law
Hardy weinberg lawHardy weinberg law
Hardy weinberg lawSrishti Aggrawal
Β 
Pleiotropy
PleiotropyPleiotropy
PleiotropyICHHA PURAK
Β 
heritability its type and estimation of it
heritability its type and estimation of itheritability its type and estimation of it
heritability its type and estimation of itsambhaji yamgar
Β 
Heterosis
Heterosis Heterosis
Heterosis University of Gujrat (Campus Govt.Murray College Sialkot)
Β 
Gene pool
Gene poolGene pool
Gene poolBahauddin Zakariya University lahore
Β 
Inbreeding and inbreeding depression
Inbreeding and inbreeding depressionInbreeding and inbreeding depression
Inbreeding and inbreeding depressionParvati Tamrakar
Β 
Hardy weinberg law
Hardy weinberg lawHardy weinberg law
Hardy weinberg lawKanimoli Mathivathana
Β 
Cytoplasmic inheritance
Cytoplasmic inheritanceCytoplasmic inheritance
Cytoplasmic inheritanceAashish Patel
Β 
Population genetic ppt
Population genetic pptPopulation genetic ppt
Population genetic pptAhmad Ali
Β 
Presentation on Heritability
Presentation on Heritability Presentation on Heritability
Presentation on HeritabilitySantosh pathak
Β 
Effects of Inbreeding & Inbreeding depression
Effects of Inbreeding & Inbreeding depressionEffects of Inbreeding & Inbreeding depression
Effects of Inbreeding & Inbreeding depressionShizra Imtiaz
Β 
Population genetics
Population geneticsPopulation genetics
Population geneticsIkram Ullah
Β 
Heritability , genetic advance
Heritability , genetic advanceHeritability , genetic advance
Heritability , genetic advancePawan Nagar
Β 
Penetrance and expressivity.pdf
Penetrance and expressivity.pdfPenetrance and expressivity.pdf
Penetrance and expressivity.pdfChZaheer3
Β 
Hardy-Weinberg Law
Hardy-Weinberg LawHardy-Weinberg Law
Hardy-Weinberg LawSyedShaanz
Β 
Genetics: Quantitative Inheritance
Genetics: Quantitative InheritanceGenetics: Quantitative Inheritance
Genetics: Quantitative InheritanceShaina Mavreen Villaroza
Β 
Gene ineractions jb
Gene ineractions jbGene ineractions jb
Gene ineractions jbJayakara Bhandary
Β 
QUANTITATIVE INHERITANCE SMG
QUANTITATIVE INHERITANCE SMGQUANTITATIVE INHERITANCE SMG
QUANTITATIVE INHERITANCE SMGsajigeorge64
Β 
Hardyweinberg law
Hardyweinberg lawHardyweinberg law
Hardyweinberg lawSantosh pathak
Β 
Pleiotropism
PleiotropismPleiotropism
PleiotropismHarshraj Shinde
Β 
Linkage mapping
Linkage mappingLinkage mapping
Linkage mappingSnehaSahu20
Β 
Genotype and Enviornment and their Interaction
Genotype and Enviornment and their InteractionGenotype and Enviornment and their Interaction
Genotype and Enviornment and their InteractionDr. Kaushik Kumar Panigrahi
Β 
Genetic drift
Genetic drift Genetic drift
Genetic drift ShwetA Kumari
Β 
Hardy-Weinberg Equilibrium
Hardy-Weinberg EquilibriumHardy-Weinberg Equilibrium
Hardy-Weinberg EquilibriumVaishnovi Sekar
Β 
Inbreeding cause,effects and technique to reduce inbreeding in hatchery popul...
Inbreeding cause,effects and technique to reduce inbreeding in hatchery popul...Inbreeding cause,effects and technique to reduce inbreeding in hatchery popul...
Inbreeding cause,effects and technique to reduce inbreeding in hatchery popul...Nazmul Haque Syekat, Noakhai Science & Technology University.
Β 
EXTRA CHROMOSOMAL INHERITANCE
EXTRA CHROMOSOMAL INHERITANCEEXTRA CHROMOSOMAL INHERITANCE
EXTRA CHROMOSOMAL INHERITANCEAshish Pratim Mahanta
Β 
Allelic frequency
Allelic frequencyAllelic frequency
Allelic frequencysijiskariah
Β 
Coupling and repulsion human genetics
Coupling and repulsion human geneticsCoupling and repulsion human genetics
Coupling and repulsion human geneticsMangalore University
Β 
LINKAGE
LINKAGELINKAGE
LINKAGENistarini College, Purulia (W.B) India
Β 

More Related Content

What's hot

Cytoplasmic inheritance
Cytoplasmic inheritanceCytoplasmic inheritance
Cytoplasmic inheritanceAashish Patel
Β 
Population genetic ppt
Population genetic pptPopulation genetic ppt
Population genetic pptAhmad Ali
Β 
Presentation on Heritability
Presentation on Heritability Presentation on Heritability
Presentation on HeritabilitySantosh pathak
Β 
Effects of Inbreeding & Inbreeding depression
Effects of Inbreeding & Inbreeding depressionEffects of Inbreeding & Inbreeding depression
Effects of Inbreeding & Inbreeding depressionShizra Imtiaz
Β 
Population genetics
Population geneticsPopulation genetics
Population geneticsIkram Ullah
Β 
Heritability , genetic advance
Heritability , genetic advanceHeritability , genetic advance
Heritability , genetic advancePawan Nagar
Β 
Penetrance and expressivity.pdf
Penetrance and expressivity.pdfPenetrance and expressivity.pdf
Penetrance and expressivity.pdfChZaheer3
Β 
Hardy-Weinberg Law
Hardy-Weinberg LawHardy-Weinberg Law
Hardy-Weinberg LawSyedShaanz
Β 
QUANTITATIVE INHERITANCE SMG
QUANTITATIVE INHERITANCE SMGQUANTITATIVE INHERITANCE SMG
QUANTITATIVE INHERITANCE SMGsajigeorge64
Β 
Hardyweinberg law
Hardyweinberg lawHardyweinberg law
Hardyweinberg lawSantosh pathak
Β 
Linkage mapping
Linkage mappingLinkage mapping
Linkage mappingSnehaSahu20
Β 
Genotype and Enviornment and their Interaction
Genotype and Enviornment and their InteractionGenotype and Enviornment and their Interaction
Genotype and Enviornment and their InteractionDr. Kaushik Kumar Panigrahi
Β 
Genetic drift
Genetic drift Genetic drift
Genetic drift ShwetA Kumari
Β 
Hardy-Weinberg Equilibrium
Hardy-Weinberg EquilibriumHardy-Weinberg Equilibrium
Hardy-Weinberg EquilibriumVaishnovi Sekar
Β 
Allelic frequency
Allelic frequencyAllelic frequency
Allelic frequencysijiskariah
Β 

What's hot (20)

Cytoplasmic inheritance
Cytoplasmic inheritanceCytoplasmic inheritance
Cytoplasmic inheritance
Β 
Population genetic ppt
Population genetic pptPopulation genetic ppt
Population genetic ppt
Β 
Presentation on Heritability
Presentation on Heritability Presentation on Heritability
Presentation on Heritability
Β 
Effects of Inbreeding & Inbreeding depression
Effects of Inbreeding & Inbreeding depressionEffects of Inbreeding & Inbreeding depression
Effects of Inbreeding & Inbreeding depression
Β 
Population genetics
Population geneticsPopulation genetics
Population genetics
Β 
Heritability , genetic advance
Heritability , genetic advanceHeritability , genetic advance
Heritability , genetic advance
Β 
Penetrance and expressivity.pdf
Penetrance and expressivity.pdfPenetrance and expressivity.pdf
Penetrance and expressivity.pdf
Β 
Hardy-Weinberg Law
Hardy-Weinberg LawHardy-Weinberg Law
Hardy-Weinberg Law
Β 
Genetics: Quantitative Inheritance
Genetics: Quantitative InheritanceGenetics: Quantitative Inheritance
Genetics: Quantitative Inheritance
Β 
Gene ineractions jb
Gene ineractions jbGene ineractions jb
Gene ineractions jb
Β 
QUANTITATIVE INHERITANCE SMG
QUANTITATIVE INHERITANCE SMGQUANTITATIVE INHERITANCE SMG
QUANTITATIVE INHERITANCE SMG
Β 
Hardyweinberg law
Hardyweinberg lawHardyweinberg law
Hardyweinberg law
Β 
Pleiotropism
PleiotropismPleiotropism
Pleiotropism
Β 
Linkage mapping
Linkage mappingLinkage mapping
Linkage mapping
Β 
Genotype and Enviornment and their Interaction
Genotype and Enviornment and their InteractionGenotype and Enviornment and their Interaction
Genotype and Enviornment and their Interaction
Β 
Genetic drift
Genetic drift Genetic drift
Genetic drift
Β 
Hardy-Weinberg Equilibrium
Hardy-Weinberg EquilibriumHardy-Weinberg Equilibrium
Hardy-Weinberg Equilibrium
Β 
Inbreeding cause,effects and technique to reduce inbreeding in hatchery popul...
Inbreeding cause,effects and technique to reduce inbreeding in hatchery popul...Inbreeding cause,effects and technique to reduce inbreeding in hatchery popul...
Inbreeding cause,effects and technique to reduce inbreeding in hatchery popul...
Β 
EXTRA CHROMOSOMAL INHERITANCE
EXTRA CHROMOSOMAL INHERITANCEEXTRA CHROMOSOMAL INHERITANCE
EXTRA CHROMOSOMAL INHERITANCE
Β 
Allelic frequency
Allelic frequencyAllelic frequency
Allelic frequency
Β 

Similar to Inbreeding and outbreeding

Coupling and repulsion human genetics
Coupling and repulsion human geneticsCoupling and repulsion human genetics
Coupling and repulsion human geneticsMangalore University
Β 
We have a cross between a heterzygous Aa, Bb with a homozygous rec.pdf
We have a cross between a heterzygous Aa, Bb with a homozygous rec.pdfWe have a cross between a heterzygous Aa, Bb with a homozygous rec.pdf
We have a cross between a heterzygous Aa, Bb with a homozygous rec.pdfaroraenterprisesmbd
Β 
Mating System and Livestock Breeding Policy
Mating System and Livestock Breeding Policy Mating System and Livestock Breeding Policy
Mating System and Livestock Breeding Policy Dr. Jayesh Vyas
Β 
Mating systems (population genetics)
Mating systems (population genetics)Mating systems (population genetics)
Mating systems (population genetics)Ankit R. Chaudhary
Β 
Hardy-Weinberg Law.pptx
Hardy-Weinberg Law.pptxHardy-Weinberg Law.pptx
Hardy-Weinberg Law.pptxVanangamudiK1
Β 
Presentation 02 genetics i
Presentation 02 genetics iPresentation 02 genetics i
Presentation 02 genetics iMa'am Dawn
Β 
17. Heterosis breeding
17. Heterosis breeding17. Heterosis breeding
17. Heterosis breedingNaveen Kumar
Β 
Chapt24 genetics
Chapt24 geneticsChapt24 genetics
Chapt24 geneticsbholmes
Β 
Chapt24 genetics
Chapt24 geneticsChapt24 genetics
Chapt24 geneticsbholmes
Β 
Ap Chap 23 The Evolution Of Populations
Ap Chap 23 The Evolution Of PopulationsAp Chap 23 The Evolution Of Populations
Ap Chap 23 The Evolution Of Populationssmithbio
Β 
linkage and crossing over
linkage and crossing over linkage and crossing over
linkage and crossing overShaliniRoy19
Β 
W-4-MECHANISM.pptx
W-4-MECHANISM.pptxW-4-MECHANISM.pptx
W-4-MECHANISM.pptxLieLanieNavarro
Β 
Explain how recombination increases the amount of genetic variation i.pdf
Explain how recombination increases the amount of genetic variation i.pdfExplain how recombination increases the amount of genetic variation i.pdf
Explain how recombination increases the amount of genetic variation i.pdfarishaenterprises12
Β 

Similar to Inbreeding and outbreeding (20)

Coupling and repulsion human genetics
Coupling and repulsion human geneticsCoupling and repulsion human genetics
Coupling and repulsion human genetics
Β 
LINKAGE
LINKAGELINKAGE
LINKAGE
Β 
We have a cross between a heterzygous Aa, Bb with a homozygous rec.pdf
We have a cross between a heterzygous Aa, Bb with a homozygous rec.pdfWe have a cross between a heterzygous Aa, Bb with a homozygous rec.pdf
We have a cross between a heterzygous Aa, Bb with a homozygous rec.pdf
Β 
Mating System and Livestock Breeding Policy
Mating System and Livestock Breeding Policy Mating System and Livestock Breeding Policy
Mating System and Livestock Breeding Policy
Β 
LINKAGE
LINKAGELINKAGE
LINKAGE
Β 
HereditypptColoradoagsci.ppt
HereditypptColoradoagsci.pptHereditypptColoradoagsci.ppt
HereditypptColoradoagsci.ppt
Β 
Linkage
LinkageLinkage
Linkage
Β 
Mating systems (population genetics)
Mating systems (population genetics)Mating systems (population genetics)
Mating systems (population genetics)
Β 
Genetics
Genetics Genetics
Genetics
Β 
Hardy-Weinberg Law.pptx
Hardy-Weinberg Law.pptxHardy-Weinberg Law.pptx
Hardy-Weinberg Law.pptx
Β 
Presentation 02 genetics i
Presentation 02 genetics iPresentation 02 genetics i
Presentation 02 genetics i
Β 
17. Heterosis breeding
17. Heterosis breeding17. Heterosis breeding
17. Heterosis breeding
Β 
Chapt24 genetics
Chapt24 geneticsChapt24 genetics
Chapt24 genetics
Β 
Chapt24 genetics
Chapt24 geneticsChapt24 genetics
Chapt24 genetics
Β 
Ap Chap 23 The Evolution Of Populations
Ap Chap 23 The Evolution Of PopulationsAp Chap 23 The Evolution Of Populations
Ap Chap 23 The Evolution Of Populations
Β 
linkage and crossing over
linkage and crossing over linkage and crossing over
linkage and crossing over
Β 
Powerpoint heredity
Powerpoint heredityPowerpoint heredity
Powerpoint heredity
Β 
W-4-MECHANISM.pptx
W-4-MECHANISM.pptxW-4-MECHANISM.pptx
W-4-MECHANISM.pptx
Β 
Explain how recombination increases the amount of genetic variation i.pdf
Explain how recombination increases the amount of genetic variation i.pdfExplain how recombination increases the amount of genetic variation i.pdf
Explain how recombination increases the amount of genetic variation i.pdf
Β 
Genetics
Genetics Genetics
Genetics
Β 

More from LekshmiJohnson

Yeast hybrid system
Yeast hybrid systemYeast hybrid system
Yeast hybrid systemLekshmiJohnson
Β 
Properties of carbohydrates
Properties of carbohydratesProperties of carbohydrates
Properties of carbohydratesLekshmiJohnson
Β 
Carbohydrates structure
Carbohydrates structureCarbohydrates structure
Carbohydrates structureLekshmiJohnson
Β 
Giant chromosomes
Giant chromosomesGiant chromosomes
Giant chromosomesLekshmiJohnson
Β 
Nucleic acid hybridization
Nucleic acid hybridizationNucleic acid hybridization
Nucleic acid hybridizationLekshmiJohnson
Β 
Dna of human and great ape
Dna of human and great apeDna of human and great ape
Dna of human and great apeLekshmiJohnson
Β 
Nutritional classification of bacteria
Nutritional classification of bacteriaNutritional classification of bacteria
Nutritional classification of bacteriaLekshmiJohnson
Β 

More from LekshmiJohnson (10)

Yeast hybrid system
Yeast hybrid systemYeast hybrid system
Yeast hybrid system
Β 
Types of pcr
Types of pcrTypes of pcr
Types of pcr
Β 
Proteins
ProteinsProteins
Proteins
Β 
Properties of carbohydrates
Properties of carbohydratesProperties of carbohydrates
Properties of carbohydrates
Β 
Carbohydrates structure
Carbohydrates structureCarbohydrates structure
Carbohydrates structure
Β 
Giant chromosomes
Giant chromosomesGiant chromosomes
Giant chromosomes
Β 
Nucleic acid hybridization
Nucleic acid hybridizationNucleic acid hybridization
Nucleic acid hybridization
Β 
Dna of human and great ape
Dna of human and great apeDna of human and great ape
Dna of human and great ape
Β 
Nutritional classification of bacteria
Nutritional classification of bacteriaNutritional classification of bacteria
Nutritional classification of bacteria
Β 
Sterilization
SterilizationSterilization
Sterilization
Β 

Recently uploaded

Field Attribute Index Feature in Odoo 17
Field Attribute Index Feature in Odoo 17Field Attribute Index Feature in Odoo 17
Field Attribute Index Feature in Odoo 17Celine George
Β 
Crayon Activity Handout For the Crayon A
Crayon Activity Handout For the Crayon ACrayon Activity Handout For the Crayon A
Crayon Activity Handout For the Crayon AUnboundStockton
Β 
MULTIDISCIPLINRY NATURE OF THE ENVIRONMENTAL STUDIES.pptx
MULTIDISCIPLINRY NATURE OF THE ENVIRONMENTAL STUDIES.pptxMULTIDISCIPLINRY NATURE OF THE ENVIRONMENTAL STUDIES.pptx
MULTIDISCIPLINRY NATURE OF THE ENVIRONMENTAL STUDIES.pptxAnupkumar Sharma
Β 
How to do quick user assign in kanban in Odoo 17 ERP
How to do quick user assign in kanban in Odoo 17 ERPHow to do quick user assign in kanban in Odoo 17 ERP
How to do quick user assign in kanban in Odoo 17 ERPCeline George
Β 
Judging the Relevance and worth of ideas part 2.pptx
Judging the Relevance and worth of ideas part 2.pptxJudging the Relevance and worth of ideas part 2.pptx
Judging the Relevance and worth of ideas part 2.pptxSherlyMaeNeri
Β 
Procuring digital preservation CAN be quick and painless with our new dynamic...
Procuring digital preservation CAN be quick and painless with our new dynamic...Procuring digital preservation CAN be quick and painless with our new dynamic...
Procuring digital preservation CAN be quick and painless with our new dynamic...Jisc
Β 
DATA STRUCTURE AND ALGORITHM for beginners
DATA STRUCTURE AND ALGORITHM for beginnersDATA STRUCTURE AND ALGORITHM for beginners
DATA STRUCTURE AND ALGORITHM for beginnersSabitha Banu
Β 
Introduction to AI in Higher Education_draft.pptx
Introduction to AI in Higher Education_draft.pptxIntroduction to AI in Higher Education_draft.pptx
Introduction to AI in Higher Education_draft.pptxpboyjonauth
Β 
ECONOMIC CONTEXT - LONG FORM TV DRAMA - PPT
ECONOMIC CONTEXT - LONG FORM TV DRAMA - PPTECONOMIC CONTEXT - LONG FORM TV DRAMA - PPT
ECONOMIC CONTEXT - LONG FORM TV DRAMA - PPTiammrhaywood
Β 
Hierarchy of management that covers different levels of management
Hierarchy of management that covers different levels of managementHierarchy of management that covers different levels of management
Hierarchy of management that covers different levels of managementmkooblal
Β 
AmericanHighSchoolsprezentacijaoskolama.
AmericanHighSchoolsprezentacijaoskolama.AmericanHighSchoolsprezentacijaoskolama.
AmericanHighSchoolsprezentacijaoskolama.arsicmarija21
Β 
Computed Fields and api Depends in the Odoo 17
Computed Fields and api Depends in the Odoo 17Computed Fields and api Depends in the Odoo 17
Computed Fields and api Depends in the Odoo 17Celine George
Β 
Quarter 4 Peace-education.pptx Catch Up Friday
Quarter 4 Peace-education.pptx Catch Up FridayQuarter 4 Peace-education.pptx Catch Up Friday
Quarter 4 Peace-education.pptx Catch Up FridayMakMakNepo
Β 
AMERICAN LANGUAGE HUB_Level2_Student'sBook_Answerkey.pdf
AMERICAN LANGUAGE HUB_Level2_Student'sBook_Answerkey.pdfAMERICAN LANGUAGE HUB_Level2_Student'sBook_Answerkey.pdf
AMERICAN LANGUAGE HUB_Level2_Student'sBook_Answerkey.pdfphamnguyenenglishnb
Β 
What is Model Inheritance in Odoo 17 ERP
What is Model Inheritance in Odoo 17 ERPWhat is Model Inheritance in Odoo 17 ERP
What is Model Inheritance in Odoo 17 ERPCeline George
Β 
Like-prefer-love -hate+verb+ing & silent letters & citizenship text.pdf
Like-prefer-love -hate+verb+ing & silent letters & citizenship text.pdfLike-prefer-love -hate+verb+ing & silent letters & citizenship text.pdf
Like-prefer-love -hate+verb+ing & silent letters & citizenship text.pdfMr Bounab Samir
Β 

Recently uploaded (20)

Field Attribute Index Feature in Odoo 17
Field Attribute Index Feature in Odoo 17Field Attribute Index Feature in Odoo 17
Field Attribute Index Feature in Odoo 17
Β 
Crayon Activity Handout For the Crayon A
Crayon Activity Handout For the Crayon ACrayon Activity Handout For the Crayon A
Crayon Activity Handout For the Crayon A
Β 
MULTIDISCIPLINRY NATURE OF THE ENVIRONMENTAL STUDIES.pptx
MULTIDISCIPLINRY NATURE OF THE ENVIRONMENTAL STUDIES.pptxMULTIDISCIPLINRY NATURE OF THE ENVIRONMENTAL STUDIES.pptx
MULTIDISCIPLINRY NATURE OF THE ENVIRONMENTAL STUDIES.pptx
Β 
How to do quick user assign in kanban in Odoo 17 ERP
How to do quick user assign in kanban in Odoo 17 ERPHow to do quick user assign in kanban in Odoo 17 ERP
How to do quick user assign in kanban in Odoo 17 ERP
Β 
Judging the Relevance and worth of ideas part 2.pptx
Judging the Relevance and worth of ideas part 2.pptxJudging the Relevance and worth of ideas part 2.pptx
Judging the Relevance and worth of ideas part 2.pptx
Β 
TataKelola dan KamSiber Kecerdasan Buatan v022.pdf
TataKelola dan KamSiber Kecerdasan Buatan v022.pdfTataKelola dan KamSiber Kecerdasan Buatan v022.pdf
TataKelola dan KamSiber Kecerdasan Buatan v022.pdf
Β 
Procuring digital preservation CAN be quick and painless with our new dynamic...
Procuring digital preservation CAN be quick and painless with our new dynamic...Procuring digital preservation CAN be quick and painless with our new dynamic...
Procuring digital preservation CAN be quick and painless with our new dynamic...
Β 
DATA STRUCTURE AND ALGORITHM for beginners
DATA STRUCTURE AND ALGORITHM for beginnersDATA STRUCTURE AND ALGORITHM for beginners
DATA STRUCTURE AND ALGORITHM for beginners
Β 
Introduction to AI in Higher Education_draft.pptx
Introduction to AI in Higher Education_draft.pptxIntroduction to AI in Higher Education_draft.pptx
Introduction to AI in Higher Education_draft.pptx
Β 
Raw materials used in Herbal Cosmetics.pptx
Raw materials used in Herbal Cosmetics.pptxRaw materials used in Herbal Cosmetics.pptx
Raw materials used in Herbal Cosmetics.pptx
Β 
ECONOMIC CONTEXT - LONG FORM TV DRAMA - PPT
ECONOMIC CONTEXT - LONG FORM TV DRAMA - PPTECONOMIC CONTEXT - LONG FORM TV DRAMA - PPT
ECONOMIC CONTEXT - LONG FORM TV DRAMA - PPT
Β 
Hierarchy of management that covers different levels of management
Hierarchy of management that covers different levels of managementHierarchy of management that covers different levels of management
Hierarchy of management that covers different levels of management
Β 
Model Call Girl in Bikash Puri Delhi reach out to us at πŸ”9953056974πŸ”
Model Call Girl in Bikash Puri Delhi reach out to us at πŸ”9953056974πŸ”Model Call Girl in Bikash Puri Delhi reach out to us at πŸ”9953056974πŸ”
Model Call Girl in Bikash Puri Delhi reach out to us at πŸ”9953056974πŸ”
Β 
AmericanHighSchoolsprezentacijaoskolama.
AmericanHighSchoolsprezentacijaoskolama.AmericanHighSchoolsprezentacijaoskolama.
AmericanHighSchoolsprezentacijaoskolama.
Β 
Computed Fields and api Depends in the Odoo 17
Computed Fields and api Depends in the Odoo 17Computed Fields and api Depends in the Odoo 17
Computed Fields and api Depends in the Odoo 17
Β 
Quarter 4 Peace-education.pptx Catch Up Friday
Quarter 4 Peace-education.pptx Catch Up FridayQuarter 4 Peace-education.pptx Catch Up Friday
Quarter 4 Peace-education.pptx Catch Up Friday
Β 
AMERICAN LANGUAGE HUB_Level2_Student'sBook_Answerkey.pdf
AMERICAN LANGUAGE HUB_Level2_Student'sBook_Answerkey.pdfAMERICAN LANGUAGE HUB_Level2_Student'sBook_Answerkey.pdf
AMERICAN LANGUAGE HUB_Level2_Student'sBook_Answerkey.pdf
Β 
What is Model Inheritance in Odoo 17 ERP
What is Model Inheritance in Odoo 17 ERPWhat is Model Inheritance in Odoo 17 ERP
What is Model Inheritance in Odoo 17 ERP
Β 
Like-prefer-love -hate+verb+ing & silent letters & citizenship text.pdf
Like-prefer-love -hate+verb+ing & silent letters & citizenship text.pdfLike-prefer-love -hate+verb+ing & silent letters & citizenship text.pdf
Like-prefer-love -hate+verb+ing & silent letters & citizenship text.pdf
Β 
OS-operating systems- ch04 (Threads) ...
OS-operating systems- ch04 (Threads) ...OS-operating systems- ch04 (Threads) ...
OS-operating systems- ch04 (Threads) ...
Β 

Inbreeding and outbreeding

  • 2. INBREEDING Introduction ο‚— Reproduction implies replication ο‚— Biological reproduction always yield reasonable carbon copy of parent unit ο‚— Sexual reproduction practiced by majority of animals, plants and microorganisms ο‚— It produces diversity needed for survival in a world constant change (ie., evolution) ο‚— Sexually reproducing individuals may have individuals which are unisexual or bisexual. ο‚— Bisexuality is common in plants and lower animals. ο‚— Higher animals are unisexual, i.e., separate male and separate female sexes exist. ο‚— Sexual reproduction performs the basic function of providing a great variety of genotypes. ο‚— Great variety of genotype has much higher evolutionary significance ο‚— Living organisms fundamentally following two systems of mating occur: inbreeding and outbreeding
  • 3. INBREEDING ο‚— The process of mating of individuals which are more closely related than the average of the population to which they belong. ο‚— Production of offspring through matings between related parents ο‚— Biparental: two different individuals are involved ο‚— Leads to deviations from H-W equilibrium by causing a deficit of heterozygotes ο‚— Inbreeding is affected by restrictions in population size or area which brings about the mating between relatives ο‚— Extreme inbreeding – Intragametophytic selfing – mating between gametes produced from the same haploid individual Generation AA Aa Aa 0 P2 2pq q2 1 P2+(pq/2) pq q2 2 P2+(3pq/4) Pq/2 q2+(3pq/4)
  • 4. ο‚— 100% homozygosity in one generation – eg..some ferns and mosses (fern: Archegonium and anthridium) ο‚— Does not change allele frequency by itself ο‚— It does increase homozygosity but does not bring about a change in overall gene frequencies ο‚— Mating between two heterozygotes as regards two alleles A and a – result in half of the population homozygous for either gene A or a and half of the population heterozygous like the parent but the overall frequencies of A and a remain constant ο‚— Aa X Aa ο‚— 1 AA : 2Aa : 1aa ο‚— It brings about recessive gene to appear in a homozygous state (aa) ο‚— Homozygous recessive are phenotypically differentiated from the dominant
  • 5. COEFFICIENT OF RELATIONSHIP (R) ο‚— Expression of the amount or degree of any quality possessed by a substance ο‚— Also a degree of physical or chemical change normally occurring in that substance ο‚— Characterizes the percentage of genes held in common by two individuals due to their common ancestory ο‚— Each individual gets only a sample half of his genotype from one of his parent ο‚— The sum (Ζ©) between two individuals through common ancestors is the coefficient of relationship and is represented by R: ο‚— RBC = The coefficient relationship between the full sibs B and C and is calculated as follows: ο‚— I.e., individuals B and C contain 1/2x1/2 = ΒΌ of their genes in common through ancestors D ο‚— i.e., individuals B and C contain 1/2x1/2 = ΒΌ of their genes in common through ancestors E ο‚— the sum of these two, the coefficient of relationship, between the full sibs B and C = ΒΌ+1/4=1/2 = 50 %
  • 6. INBREEDING COEFFICIENT In diploid organism each gene has two alleles occupy the same locus – called identical genes If they descended from the same gene; such genes are homozygous at the lcous Such homozygosity also caused when two allels in a diploid organism are not descended from the common gene but the alleles of identical origin are brought together through mating between first cousins- such alleles are similar alleles The probability that the two alleles in a zygote are identical by descent is measured by inbreeding coefficient (F) 1. If the parents B and C are full sibs, i.e., B and C parents are 50% related, the inbreeding ccoefficient of individual A can be calculated by the equation FA = Β½ RBC, Where RBC is the coefficient of relationship between the full sib parent (B and C) of A 2. If the common ancestor are not inbred, the inbreeding coefficient is calculated by the equation: F = Ζ©(1/2)n1+n2+1 where n1 is the number of generations from one parent back to the ancestor and n2 is the number of generations form the other parent baCk to the same ancestor
  • 7. 3. In case the common ancestor are inbred, the inbreeding coefficient is calculated as follows F = Ζ©(1/2)n1+n2+1 (1+F ancestor) 4. The coefficient of inbreeding is also calculated by counting the number of arrows connecting the individual through one parent back to the common ancestor and back again to his other parent by the following equation: F = Ζ©(1/2)n1 (1+FA) n = number of arrows which connect the individual through one parent back to the common ancestor and back again to his other parent FA is the inbreeidng coefficient of the common ancestor Eg., the inbreeding coefficient for A in the following arrow diagram can be calculated by following method: B and C are the parents of A. there is only one pathway from B and C and that goes through ancestor E. Ancestor E is inbred, because its parents (G and H) are full sibs and are 50% related. The inbreeding coefficient can be calculated as FE = Β½ RGH (R = the coefficient of relationship between the full sibs G and H)
  • 8. PANMIXIS – Random mating ο‚— If the breeder assigns no mating restraints upon the selected individuals, their gametes are likely to randomly unite by chance alone ο‚— Wind or insect carry pollen from one plant to another in essentially a random manner ο‚— Even livestock such as sheep and range cattle are usually bred panmicticly ο‚— The males locates females as they came into heat, copulate with and inseminate them without any artificial restrictions as they forage for food over large tracts of grazing lands ο‚— This mating method is most likely to generate the greatest genetic diversity among the progeny
  • 9. ASSORTATIVE MATING ο‚— In sexually reproducing organism, the most rapid inbreeding system is that between brothers and sisters who share both parents in common – called full sib mating ο‚— Produces inbreeding coefficient of 25% in the first generation – reduced in succeeding generations since some alleles are identical ο‚— Within 10 generations, full sib mating can produce an inbreeding coefficient of 90% ο‚— Other inbreeding systems are half sib mating, parent offspring mating, third cousin mating – called genetic assortative matings ο‚— Parents of each mating type are sorted and mated together on the basis of their genetic relationship. ο‚— Assortative mating is of phenotypic type i.e., the mating between two like phenotypes, two like dominant or two like recessive phenotype ο‚— If it continues for many generations, eliminates the heterozygotes and the resulting will be homozygous dominant or homozygous recessive
  • 10. DISASSORTATIVE MATING ο‚— Mating of unlike phenotypes and genotypes and tends to maintain heterozygosity ο‚— Mating between homozygous and an heterozygous individual for sex locus ο‚— Also results from dichogamy – producing mature male and female reproductive structures at different times ο‚— Fertilization between plants with different phenotype is favoured
  • 11. LINE BREEDING ο‚— Special form of inbreeding utilized for the purpose of maintaining a high genetic relationship to a desirable ancestor ο‚— A possesses more than 50% of B’s gene ο‚— D possesses 50% of B’s gene and transmits 25% to C; B also contributes 50% of genes to C-hence C contains 50+25 = 75% B’s genes transmits to C and transmits half of them to A; B also contribute 50% to A – Hence A contains 50+37.5 = 87.5% of B’s gene
  • 12. GENETIC EFFECTS ο‚— Results genetically in homozygosity ο‚— Produces homozygous stocks of dominant or recessive genes and eliminates heterzygosity ο‚— In each generation, heterozygosity is reduced by 50% and after 10 generation – total elimination of heterozygosity from the inbred line and production of two homozygous or pure lines ο‚— In humans, in happens very slowly
  • 13. EFFECTS OF INBREEDING ο‚— Occurrence of genetic disorder – due to the development of homogygous recessive Physical and health effects ο‚— Reduced fertility ο‚— Increased genetic disorders ο‚— Fluctuating facial asymmetry ο‚— Lower birth rate ο‚— Higher infant mortality and child mortality ο‚— Smaller adult size ο‚— Loss of immune system function ο‚— Increased cardiovascular risks ο‚— Haemophilia in royal families ο‚— Increases hearing impairment
  • 14. Reasons for inbreeding ο‚— Royalty, religion and culture, socioeconomic class and geographic isolation and small population ο‚— Religion and culture plays major role – many muslims and hindu societies practices unions of first cousin – advantage – bride’s relationship with her Mother in law and the up keep of the family’s property ο‚— Another incentive to close relative marriages concers brides wealth and dowry ο‚— To keep their property and land ο‚— In royal families – to preserve royal blood lines
  • 15. APPLICATION OF INBREEDING ο‚— Inbreeding causes homozygosity of deleterious recessive genes which may result in defective phenotype – so in human society, the religious ethics unknowingly and modern social norms consciously have condemned and banned the marriages of brothers and sisters ο‚— Plant and animal breeders also avoid inbreedings in the individuals due to this reason ο‚— Inbreeding results in homozygosity of dominant alleles – it is a best mean of mating among hermaphrodites and self pollinating plant species for several families. ο‚— Animal breeders also use inbreeding to produce best race of horses, dogs, bulls, cattles etc… ο‚— Eg., modern race horse – descendents of three Arabian stallions and mated with several local mares of the slow heavy type – fast runners of F1 was selected and inbred and stallions of F2 appear as beginning point in the pedigrees of almost all modern race horses – called line breeding. ο‚— Merino sheep – fine wool producer – result of 200 yrs of inbreeding
  • 16. OUTBREEDING ο‚— Mating involves individuals that are more distantly related – outcrossing or outbreeding – negative genetic assortative mating ο‚— Involves crossing individuals belonging to different families or crossing different inbred varieties of plants or crossing different breed of livestock ο‚— Increases heterozygosity and enhances vigour of progeny – i.e., hybrid have superior phenotypic quality but often has poor breeding value ο‚— The two inbred parents homozygous for different genes, if crossed produce F1 progeny – heterozygous ο‚— F1 progeny or hybrid – improved general fitness, resistance to diseases or it may show remarkable growth and vigour ο‚— The superiority of hybrid over parent – heterosis – coined by Shull ο‚— The terms heterosis and hybrid vigour are used as synonyms ο‚— Shull – the developed superiority of the hybrid – hybrid vigour ο‚— Heterosis – mechanism by which this superiority is developed ο‚— According to Whaley – hybrid vigour denotes the manifest effects of heterosis
  • 17. Cross breeding and mule production ο‚— Mating of individuals from entirely different races or even different species – cross breeding ο‚— Produces sterile hybrids in comparison to normal outbreedings ο‚— Mule – a hybrid of a male donkey (Equus asimus, 2n = 62) and a female horse (Equus caballus, 2n = 64) ο‚— The hybrid from the reciprocal cross (i.e., female donkey or jenny and male horse or stallion) – hinny ο‚— Mule shows hybrid vigour and served mankind ο‚— Sexually sterile and have to produce everytime a new ο‚— Donkey stallions –imported from Europe by Indian army for breeding mules ο‚— Two kinds of mules used by Indian army; ο‚— 1. general service type and ο‚— 2. mountain artillary type – very important as they are firm footed animals that can carry heavy loads on steep himalayan mountain terrain
  • 18. Manifestation of heterosis ο‚— Heterosis – increase in size and productivity ο‚— Eg.,some crosses of beans certain F1hybrids contain greater number of nodes, leaves and pods than their parents but the gross size of plant remain unaffected ο‚— In some hybrids – the growth rate is increased but there occur no increase in size of mature plant ο‚— Greater resistance to diseases, insect infestation and increased tolerance to erratic climatic condition are some eg of heterosis effect of plants ο‚— Shull - Corn or maize hybrids – diverse parentage – greater hybrid vigour ο‚— Problem is inbred lines are infertile – modified by a method called double cross method (Jones) ο‚— Double cross method – four inbred lines (A.B.C and D) ο‚— Single cross is made between A and B by growing two lines together and removing the tassels from line A – Cannot self fertilize – received only B pollen ο‚— Same method is followed for C and D in another locality ο‚— The yield of single cross hybrid is usually low because inbred parent lacks vigour and produces small cobs ο‚— Plants germinate from single cross seeds – vigorous hybrids with large cobs and many kernels
  • 19. Genetic basis of heterosis ο‚— Two hypothesis ο‚— Dominance hypothesis of heterosis – holds that increased vigour and size in a hybrid due to combination of favourable growth genes by crossing two inbred races ο‚— Eg., Quinby and Karper – heterosis in sorghum – observed that heterozygote is significantly late in maturity and produces a greater weight of grain than either of the homozygote parents ο‚— Keeble and Pellow – studied two varieties of pea both semi- dwarf, one with thin stem and long internodes and the other with thick stem and short internodes ο‚— The F1 hybrid – taller than either of parents, combining the long internodes of one parent and many nodes of the other ο‚— Over dominance hypothesis of heterosis – proposed by Shull and East independently in 1908 ο‚— Increases with diversity of uniting gametes ο‚— Heterozygote is superior to either homozygous ο‚— Vigour increases in proportion to the amount of heterozygosity
  • 20. Application of heterosis ο‚— Exploited at commercial scale both in plants and animals ο‚— In plants – applied to crop plants, ornamentals, fruit crops ο‚— More important in vegetatively propogating plants ο‚— In fruit plants and ornamental plants – if heterosis is achieved – may maintained for long ο‚— Sometime intermediate phenotypes are preferred ο‚— General purpose cattle can be produced by crossing beef type with a dairy type – offspring produce an intermediate yield of milk and have a fair meat when slaughtered ο‚— Similar in chicken – egg type with meat type ο‚— Plants – disease resistance
  • 21. Evolutionary significance of inbreeding and outbreeding ο‚— Both provide raw material to natural of selection ο‚— Inbreeding allows natural selection to operate on successive genes – but not permit the introduction of good mutations from outside ο‚— Outbreeding provides an oppurtunity for the accumulation of good trait of different races in one individual or line ο‚— It expresses good qualities of the races and masked the deleterious recessive alleles ο‚— Both provide new allelic combinations which may be good or bad for the natural selection