Bi 3a Bi 2g By Kim Foglia Beyond Mendel’s Laws of Inheritance.

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Bi 3a Bi 2g By Kim Foglia Beyond Mendel’s Laws of Inheritance

 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

 Heterozygote shows an intermediate, blended phenotype  example: ▪ RR = red flowers ▪ rr = white flowers ▪ Rr = pink flowers ▪ make 50% less color RR  RR  WW  RW WWRW

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!

 2 alleles affect the phenotype equally & separately  not blended phenotype  human ABO blood groups  3 alleles ▪ I A, I B, i ▪ I A & I B alleles are co-dominant ▪ glycoprotein antigens on RBC ▪ I A I B = both antigens are produced ▪ i allele recessive to both

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

autosomal chromosomes sex chromosomes

 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 XY X X XX XY 50% female : 50% male XX

 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

 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

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

XRXRXRXR XrYXrY 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!

 Sex-linked  usually means “X-linked”  more than 60 diseases traced to genes on X chromosome

Hh x HH XHYXHY XHXhXHXh XHXhXHXh XHXH XhXh XHYXHY Y XHXH XHXH Y male / sperm XHXH XhXh female / eggs XHXHXHXH XHXhXHXh XHYXHYXhYXhY XHXHXHXH XHYXHY XHXhXHXh XhYXhY carrierdisease