AP Biology 2006-2007 Beyond Mendel’s Laws of Inheritance.

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AP Biology Beyond Mendel’s Laws of Inheritance

AP Biology Extending Mendelian genetics  Mendel worked with a simple system  peas are genetically simple  most traits are controlled by a single gene  each gene has only 2 alleles, 1 of which is completely dominant to the other  The relationship between genotype & phenotype is rarely that simple

AP Biology Incomplete dominance  Heterozygote shows an intermediate, blended phenotype  example:  RR = red flowers  rr = white flowers  Rr = pink flowers  make 50% less color RRRrrr

AP Biology Incomplete dominance true-breeding red flowers true-breeding white flowers X P 100% 100% pink flowers F 1 generation (hybrids) self-pollinate 25% white F 2 generation 25% red 1:2:1 50% pink It’s like flipping 2 pennies!

AP Biology Incomplete dominance CRCR CWCW male / sperm CRCR CWCW female / eggs CRCRCRCR CRCWCRCW CWCWCWCW CRCWCRCW 25% 1:2:1 25% 50% 25% 1:2:1 % genotype % phenotype CRCRCRCR CRCWCRCW CRCWCRCW CWCWCWCW 25% 50% C R C W x C R C W

AP Biology Co-dominance  2 alleles affect the phenotype equally & separately  not blended phenotype  example: ABO blood groups  3 alleles  I A, I B, i  I A & I B alleles are co-dominant to each other  both antigens are produced  both I A & I B are dominant to i allele  produces glycoprotein antigen markers on the surface of red blood cells

AP Biology Genetics of Blood type pheno- type genotype antigen on RBC antibodies in blood donation status AI A I A or I A i type A antigens on surface of RBC anti-B antibodies __ BI B I B or I B i type B antigens on surface of RBC anti-A antibodies __ ABI A I B both type A & type B antigens on surface of RBC no antibodies universal recipient Oi ii i no antigens on surface of RBC anti-A & anti-B antibodies universal donor

AP Biology Blood compatibility  Matching compatible blood groups  critical for blood transfusions  A person produces antibodies against antigens in foreign blood  wrong blood type  donor’s blood has A or B antigen that is foreign to recipient  antibodies in recipient’s blood bind to foreign molecules  cause donated blood cells to clump together  can kill the recipient Karl Landsteiner ( ) 1901 | 1930

AP Biology Blood donation clotting

AP Biology Pleiotropy  Most genes are pleiotropic  one gene affects more than one phenotypic character  wide-ranging effects due to a single gene  dwarfism (achondroplasia)  gigantism (acromegaly)

AP Biology Acromegaly: André the Giant

AP Biology Aa x aa Inheritance pattern of Achondroplasia aa A a Aa A a Aa x Aa Aa aa Aa 50% dwarf:50% normal or 1:1 AA aa Aa 67% dwarf:33% normal or 2:1 Aa 

AP Biology Epistasis B_C_ bbC_ _ _cc How would you know that difference wasn ’ t random chance? Chi-square test!  One gene completely masks another gene  coat color in mice = 2 separate genes  C,c: pigment (C) or no pigment (c)  B,b: more pigment (black=B) or less (brown=b)  cc = albino, no matter B allele  9:3:3:1 becomes 9:3:4

AP Biology Epistasis in Labrador retrievers  2 genes: (E,e) & (B,b)  pigment (E) or no pigment (e)  pigment concentration: black (B) to brown (b) E–B–E–bbeeB–eebb

AP Biology Epistasis in grain color 9/16 purple 7/16 white F 1 generation All purple (AaBb) X Eggs White (aaBB) White (AAbb) F 2 generation A = enzyme 1 + B = enzyme 2  purple color (anthocyanin) AB AbaBab Ab aB ab AABB AABb AaBB AaBb AABb AAbb AaBb Aabb AaBB AaBb aaBB aaBb AaBb Aabb aaBb aabb Sperm 9:7 9:3:3:1

AP Biology Polygenic inheritance  Some phenotypes determined by additive effects of 2 or more genes on a single character  phenotypes on a continuum  human traits  skin color  height  weight  eye color  intelligence  behaviors

AP Biology enzyme Skin color: Albinism Johnny & Edgar Winter albino Africans  However albinism can be inherited as a single gene trait melanin = universal brown color tyrosine melanin albinism

AP Biology OCA1 albinoBianca Knowlton

AP Biology Sex linked traits  Genes are on sex chromosomes  as opposed to autosomal chromosomes  first discovered by T.H. Morgan at Columbia U.  Drosophila breeding  good genetic subject  prolific  2 week generations  4 pairs of chromosomes  XX=female, XY=male 1910 | 1933

AP Biology autosomal chromosomes sex chromosomes Classes of chromosomes

AP Biology Huh! Sex matters?! F 2 generation 100% red-eye female 50% red-eye male 50% white eye male Discovery of sex linkage P X F 1 generation (hybrids) 100% red eye offspring true-breeding white-eye male true-breeding red-eye female

AP Biology RRrr What’s up with Morgan’s flies? x rr R R Rr 100% red eyes Rr x Rr R r RR Rrrr Rr 3 red : 1 white  Doesn’t work that way!

AP Biology  In humans & other mammals, there are 2 sex chromosomes: X & Y  2 X chromosomes  develop as a female: XX  gene redundancy, like autosomal chromosomes  an X & Y chromosome  develop as a male: XY  no redundancy Genetics of Sex XY X X XX XY 50% female : 50% male XX

AP Biology XRXRXRXR XrYXrY What’s up with Morgan’s flies? x XrXr Y XRXR 100% red eyes XRXR XRXrXRXr XRYXRY XRYXRYXRXrXRXr x  XRXrXRXr XRYXRY XRXR Y XRXR XrXr XRXrXRXr XRYXRYXRXRXRXR XrYXrY 100% red females 50% red males; 50% white males BINGO!

AP Biology Genes on sex chromosomes  Y chromosome  few genes other than SRY  sex-determining region  master regulator for maleness  turns on genes for production of male hormones  many effects = pleiotropy!  X chromosome  other genes/traits beyond sex determination  mutations:  hemophilia  Duchenne muscular dystrophy  color-blindness

AP Biology  Sex-linked  usually means “X-linked”  more than 60 diseases traced to genes on X chromosome Human X chromosome

AP Biology Map of Human Y chromosome? < 30 genes on Y chromosome Sex-determining Region Y ( SRY ) Channel Flipping ( FLP ) Catching & Throwing ( BLZ-1) Self confidence ( BLZ-2) note: not linked to ability gene Devotion to sports ( BUD-E) Addiction to death & destruction movies ( SAW-2) Scratching ( ITCH-E) Spitting ( P2E) linked Inability to express affection over phone ( ME-2) Selective hearing loss ( HUH) Total lack of recall for dates ( OOPS) Air guitar ( RIF)

AP Biology Sex-linked traits summary  X-linked  follow the X chromosomes  males get their X from their mother  trait is never passed from father to son  Y-linked  very few genes / traits  trait is only passed from father to son  females cannot inherit trait

AP Biology

Hemophilia Hh x HH XHYXHY XHXhXHXh XHXhXHXh XHXH XhXh XHYXHY Y XHXH sex-linked recessive XHXH Y male / sperm XHXH XhXh female / eggs XHXHXHXH XHXhXHXh XHYXHYXhYXhY XHXHXHXH XHYXHY XHXhXHXh XhYXhY carrierdisease

AP Biology X-inactivation  Female mammals inherit 2 X chromosomes  one X becomes inactivated during embryonic development  condenses into compact object = Barr body  which X becomes Barr body is random  patchwork trait = “mosaic” XHXhXHXh XHXHXhXh

AP Biology X-inactivation & tortoise shell cat  2 different cell lines in cat

AP Biology Male pattern baldness  Sex influenced trait  autosomal trait influenced by sex hormones  age effect as well = onset after 30 years old  dominant in males & recessive in females  B_ = bald in males; bb = bald in females

AP Biology Nature vs. nurture  Phenotype is controlled by both environment & genes Color of Hydrangea flowers is influenced by soil pH Human skin color is influenced by both genetics & environmental conditions Coat color in arctic fox influenced by heat sensitive alleles

AP Biology Any Questions?

AP Biology Mechanisms of Inheritance How do we go from DNA to trait? vs. ?

AP Biology Mechanisms of inheritance  What causes the differences in alleles of a trait?  yellow vs. green color  smooth vs. wrinkled seeds  dark vs. light skin  sickle cell anemia vs. no disease  What causes dominance vs. recessive?

AP Biology Molecular mechanisms of inheritance  Molecular basis of inheritance  genes code for polypeptides  polypeptides are processed into proteins  proteins function as…  enzymes  structural proteins  regulators  hormones  gene activators  gene inhibitors proteinRNADNA trait

AP Biology How does dominance work: enzyme =allele coding for functional enzyme protein =allele coding for non-functional enzyme protein = 100% non-functional enzyme  mutant trait is expressed = 50% functional enzyme  sufficient enzyme present  normal trait is expressed  normal trait is DOMINANT = 100% functional enzyme  normal trait is expressed aaAaAA example: enzyme has incorrect structure at active site carrier homozygous heterozygous dominant recessive

AP Biology How does dominance work: structure =allele coding for functional structural protein =allele coding for non-functional structural protein = 100% non-functional structure  mutant trait is expressed = 50% functional structure  50% proteins malformed  mutant trait is expressed  mutant trait is DOMINANT = 100% functional structure  normal trait is expressed AAAaaa homozygous heterozygous recessive dominant example: malformed channel protein, “stuck open” example: malformed receptor protein, “stuck on”

AP Biology Prevalence of dominance  Because an allele is dominant does not mean…  it is better, or  it is more common Polydactyly dominant allele

AP Biology Polydactyly recessive allele far more common than dominant  only 1 individual out of 500 has more than 5 fingers/toes  so 499 out of 500 people are homozygous recessive (aa) the allele for >5 fingers/toes is DOMINANT & the allele for 5 digits is recessive individuals are born with extra fingers or toes

AP Biology Any Questions?