GENETIKA DASAR POKOK BAHASAN 3 Pautan Gen 2
GENETIKA DASAR
POKOK BAHASAN 3 Pautan Gen 2. Pindah Silang 3. Pemetaan Kromosom 1.
HUKUM MENDEL I : “The Law of Segregation of Allelic Genes” atau Hukum Pemisahan Bebas HUKUM MENDEL II : “The law of Independent Assortment of Genes” atau Hukum Pengelompokkan Gen secara Bebas
Pautan Gen (Linkage gene) Deviation From Independent Assortment Ratios Pautan/Berangkai/Linkage gene : Peristiwa beberapa gen bukan alel terdapat pada satu kromosom yang sama
Pautan/Berangkai/Linkage gene : - RANGKAI/PAUTAN SEMPURNA Gen-gen yang terangkai letaknya amat berdekatan, maka selama meiosis gen-gen itu tidak mengalami perubahan letak. Sehingga gen-gen itu bersama-sama menuju ke gamet - RANGKAI/PAUTAN TIDAK SEMPURNA Gen-gen yang terangkai pada satu kromosom letaknya tidak berdekatan satu sama lainnya, sehingga gen-gen itu dapat mengalami perubahan letak yang disebabkan karena ada penukaran segmen dari kromatid-kromatid pada sepasang kromosom homolog
Bateson and Punnett crossed a purple, long snapdragon with one that was red and round The F 1 snapdragon was selfed Observed deviation from a 9: 3: 3: 1 ratio
Phenotype (genotype) Number of individuals Observed Approximate number of individuals Expected (from 9: 3: 3: 1) Purple, long (P_L_) 284 215 Purple, round (P_ll) 21 71 Red, long (pp. L_) 21 71 Red, round (ppll) 55 24 Because the parental genes seemed to assort together more then they were expected, Bateson and Punnett said they were coupled
Creating a Linkage Hypothesis Morgan used Drosophila as an experimental organism to prove linkage
Morgan crossed Drosophila red eye, normal wing (pr+pr+ vg+vg+) and purple eye vestigal wing (prpr vgvg) The F 1 flies were test crossed Observed deviation from the 1: 1: 1: 1 ratio
Coupling Cross Chi-Square Test F 1 Gamete Observed Expected (O-E)2/E pr+ vg+ 1339 709. 75 557. 9 pr+ vg 151 709. 75 439. 9 pr vg+ 154 709. 75 435. 2 pr vg 1195 709. 75 331. 8 Total 2839 X 2=1764. 8
Proof That Linked Genes Exist Morgan hypothesized that alleles of two genes close together may not assort indepentently into gametes Parental arrangements may appear together in gametes
Morgan performed a second cross to prove the hypothesis He crossed red eye, vestigal wing (pr+pr+ vgvg) and purple eye, normal wing flies (prpr vg+vg+) The F 1 flies were testcrossed
pr+pr+ vgvg x prpr vg+vg+ Parent : (red eye, vestigal wing) F 1 : (purple eye, normal wing) pr+pr vgvg+ x testcross
F 1 Gamete Testcross Distribution Gamete Type pr+ vg+ 157 Recombinant pr+ vg 965 Parental pr vg+ 1067 Parental pr vg 146 Recombinant
Repulsion Cross Chi-Square Test F 1 Gamete Observed pr+ vg+ 157 583. 75 312. 0 pr+ vg 965 583. 75 249. 0 pr vg+ 1067 583. 75 483. 3 pr vg 146 583. 75 328. 3 2335 Total Expected (O-E)2/E X 2=1372. 6
Terms Used in Linkage Analysis Coupling – the F 1 configuration where both dominant alleles reside on the same chromosome; also called CIS gen-gen dominan terangkai pada satu kromosom, sedangkan alel resesifnya terangkai pada kromosom homolognya Penulisannya : AB/ab atau AB ab Repulsion - the F 1 configuration where one dominant and one recessive allele reside on the same chromosome; also called TRANS Gen dominan terangkai dengan alel resesifnya pada satu kromosom, sedangkan alel-alel resesifnya terangkai pada kromosom homolognya Penulisannya : Ab/a. B atau Ab a. B
Coupling – the F 1 configuration where both dominant alleles reside on the same chromosome; also called CIS The Development Of The Coupling Chromosome
Repulsion - the F 1 configuration where one dominant and one recessive allele reside on the same chromosome; also called TRANS The Development Of The Repulsion Chromosome
Recombination Occurs Less Frequently Between Closely Linked Genes Physical crossing over is a normal meiosis event Crossing-over pertukaran segmen dari kromatid-kromatid bukan non-sister kromatid dari sepasang kromosom homolog The term used to describe crossing over is recombination Recombination can occur between any two genes on a chromosome The farther apart the two genes the more crossing over
Cross over
A B meiosis I a b a A B A A a a b b B a gamet parental gamet rekombinasi b gamet parental
Faktor-faktor yang mempengaruhi pindah silang 1. 2. 3. 4. 5. 6. TEMPERATUR, temperatur kurang atau melebiji temperatur biasa dapat memperbesar kemungkinan pindah silang UMUR, makin tua suatu individu makin kurang mengalami pindah silang ZAT KIMIA tertentu dapat memperbesar kemungkinan terjadinya pindah silang PENYINARAN SINAR X dapat memperbesar kemungkinan pindah silang JARAK ANTAR GEN YANG TERANGKAI, makin jauh letak satu gen dengan gen lainnya, makin besar kemungkinan pindah silang JENIS KELAMIN, umumnya jantan atau betina dapat mengalami pindah silang. Namun pada ulat sutera betina dan Drosophila jantan tidak pernah terjadi pindah silang
Determining Linkage Distances By definition, one map unit is equal to one percent recombinant gametes or phenotypes In honor of Morgan, one map unit is also called one centimorgan (c. M) 1 mu = 1% = 1 c. M
To determine the distance between two genes, divide the number of recombinant gametes by the total number of gametes Formula : Number of recombinants Total Number x 100%
Coupling Data F 1 Gamete Testcross Distribution Gamete Type pr+ vg+ 1339 Parental pr+ vg 151 Recombinant pr vg+ 154 Recombinant pr vg 1195 Parental pr vg distance = ((151 +154)/2839)*100% = 10. 7 m. u = 10. 7 c. M
Repulsion Data F 1 Gamete Testcross Distribution Gamete Type pr+ vg+ 157 Recombinant pr+ vg 965 Parental pr vg+ 1067 Parental pr vg 146 Recombinant pr vg distance = ((157 + 146)/2335)*100% = 13. 0 c. M
Jarak Gen Coupling : pr vg 10, 7 c. M Repulsion : pr vg 13, 0 c. M
Remember these are estimates; the differences between the two estimates reflect random deviation Neither estimate is incorrect; repeated experimentation would give a more accurate estimate
Deriving Linkage Distance And Gene Order From Three-Point Crosses Analyzing three genes allows us to determine gene order as well as linkage distance Need to create a F 1 and follow deviation from a 1: 1: 1 ratio What are the expected gametes when three linked genes are considered?
Analyzing Three-Point Test Cross Data Genotype ABC abc Ab. C a. BC ABc ab. C Abc a. BC Total Observed 390 374 27 30 5 8 81 85 1000
What are the parental genotypes? What is the gene order? What are the linkage distances?
What are the parental genotypes? The genotypes most frequently found are the parental genotypes ABC and abc are the parental genotypes
What is the gene order? * Menentukan susunan gen dengan memperhatikan Tipe Parental dan Tipe DCO Pada Tipe Parental di-DCO-kan dibandingkan dengan hasil DCO pengamatan The double crossover moves a non-parental allele of the central gene between two parental alleles Gene C is between genes A and B (gene order = A C B)
Analyzing Three-Point Test Cross Data Genotype Observed Type of Gamete ACB acb ACb a. CB Ac. B a. Cb Acb a. CB 390 Parental 374 Parental 27 Single-crossover between genes C and B 30 Single-crossover between genes C and B 5 Double-crossover 8 Double-crossover 81 Single-crossover between genes A and C 85 Single-crossover between genes A and C Total 1000
What are the linkage distances? Linkage distance equals the sum of the appropriate single cross plus all double crosses divided by total number of gametes Formula : Jarak = SCO + DCO x 100% Jumlah Total
*Jarak A - C = ((81+85+5+8)/1000)*100 = 17. 9 c. M *Jarak C - B = ((27+30+5+8)/1000)*100 = 7. 0 c. M A C 17, 9 c. M B 7, 0 c. M
Contoh lain : Genotype v cv+ ct+ v+ cv ct v cv ct+ v+ ct v cv ct v+ ct+ v cv+ ct v+ cv ct+ Observed 580 592 45 40 89 94 3 5 Total 1448
Determine the parental genotypes The most abundant genotypes are v cv+ ct+ and v+ cv ct.
Determine the gene order Allele ct is paired with v and cv+. This is a different pairing than the parental genotype. Therefore gene ct is in the middle.
Genotype Observed v ct+ cv+ 580 Type of Gamete Parental v+ ct cv 592 Parental v ct+ cv 45 Single-crossover between genes ct and cv v+ ct cv+ 40 Single-crossover between genes ct and cv v ct cv 89 Single-crossover between genes v and ct v+ ct+ cv+ 94 Single-crossover between genes v and ct v ct cv+ 3 Double-crossover v+ ct+ cv 5 Double-crossover Total 1448
Determine the linkage distance v-ct = 100*((89+94+3+5)/1448) = 13. 2 c. M ct-cv = 100*((45+40+3+5)/1448 = 6. 4 c. M
Determine the linkage distance v-ct = 100*((89+94+3+5)/1448) = 13. 2 c. M ct-cv = 100*((45+40+3+5)/1448 = 6. 4 c. M
MENGHITUNG JARAK PETA DAN FREKUENSI REKOMBINASI Menghitung jarak antar gen dengan menggunakan percobaan Bateson dan Punnett menggunakan frekuensi rekombinasi dari metode uji silang (testcross)
Parental F 1 PL/PL (Purple, long) x pl/pl (red, round) PL/pl x ppll (purple, long) (red, round) Progeny :
Tipe parental : Purple, long (P_L_) 284 Red, round (ppll) 55 Tipe rekombinan : Purple, round (P_ll) 21 Red, long (pp. L_) Frekuensi rekombinan : rekombinan x 100% tipe parental + tipe rekombinan (21+21) (284+55)+(21+21) x 100% = 11. 02% 21
Jadi jarak gen untuk warna bunga dan gen untuk pollen adalah : P L 11. 02
Rekombinasi dari F 1 x F 1 Data dari Bateson dan Punnett (F 1 x F 1 coupling) F 1 F 2 PL/pl (Purple, long) : Purple, long (P_L_) Purple, round (P_ll) red, long (pp. L_) red, round (ppll) x PL/pl (Purple, long) : : (a 1) (a 2) (a 3) (a 4)
Data dari Bateson dan Punnett (F 1 x F 1 repulsion) F 1 : Pl/p. L (Purple, long) F 2 : Purple, long (P_L_) Purple, round (P_ll) red, long (pp. L_) red, round (ppll) x Pl/p. L (Purple, long) : : (a 1) (a 2) (a 3) (a 4)
Rumus menghitung persentase rekombinasi apabila F 1 heterosigot Z = Hasil kali tipe rekombinan Hasil kali tipe tetua Sehingga apabila F 1 heterosigot dalam keadaan : * Coupling Z = a 2 x a 3 a 1 x a 4 * Repulsion Z = a 1 x a 4 a 2 x a 3
Data dari Bateson dan Punnett (F 1 x F 1 coupling) F 1: PL/pl x PL/pl (Purple, long) F 2 : Purple, long (P_L_) Purple, round (P_ll) red, long (pp. L_) red, round (ppll) : 269 (a 1) : 19 (a 2) : 27 (a 3) : 85 (a 4) Coupling Z = 19 x 27 = 0, 0238 269 x 85 Nilai Z = 0, 0238**
Interference - the reduction in the expected number of crossovers at two adjacent genetic intervals Interferensi – interaksi antar pindah silang Pindah silang pada tempat tertentu mengurangi kemungkinan terjadinya pindah silang pada daerah didekatnya. Pindah silang di daerah I mengurangi terjadinya pindah silang pada daerah II Mengakibatkan frekuensi pindah silang ganda lebih kecil dari yang diharapkan
coefficient of coincidence (c. o. c. ) = ratio of observed to expected double crossovers Koefisien koinsidensi adalah ukuran dari kekuatan interferensi dan merupakan nisbah antara frekuensi pindah silang ganda yang diamati dan frekuensi pindah silang ganda yang diharapkan
Rumus atau KK = Banyaknya pindah silang ganda (DCO) yang sesungguhnya Banyaknya pindah silang ganda (DCO) yang diharapkan Interferensi = 1 - KK
Apabila interferensi sempurna (1, 0) maka tidak ada pindah silang ganda yang dapat diamati Apabila semua pindah silang ganda yang diharapkan dapat diamati maka interferensinya nol (0)
Misalnya diketahui data sebagai berikut: Genotipe gamet Dari F 1 heterosigot V Gl Va v gl va V gl Va v Gl va V gl va v Gl Va V Gl va v gl Va Jumlah individu 235 270 7 4 62 60 40 48 726 Fenotipe normal mengkilat, steril sebagian, pucat mengkilat, steril sebagian pucat steril sebagian mengkilat, pucat
Misalnya : Diketahui peta kromosom : V Gl 18, 3 Va 13, 6 31, 9 SCO-1 (V-Gl) : 18, 3% SCO-2 (Gl-Va) : 13, 6% Pindah silang ganda yang diharapkan = SCO-1 x SCO-2 = 0, 183 x 0, 136 = 0, 025 = 2, 5%
Pindah silang ganda yang sebenarnya : 7+4 = 1, 5% 726 Sehingga Koefisien Koinsidensinya : KK = 1, 5% = 0, 6 2, 5% Jadi Interferensinya : I = 1 -KK = 1 – 0, 6 = 0, 4 = 40%
Calculating Interference Values From The Example v - ct = 0. 132 recombination frequency ct - cv = 0. 064 recombination frequency Expected double crossover frequency equal the product of the two single crossover frequency expected double crossover frequency = 0. 132 x 0. 064 = 0. 0084 Total double crossovers = 1448 x 0. 0084 = 12 Observed double crossovers = 8 c. o. c = 8/12 I for example = 100 x [1 -(8/12)] = 33% Most often I is between 0 and 1 indicating positive interference Occasionally I is greater than 1 indicating negative interference
Creighton and Mc. Clintock's Proof of Chromosomal Exchange During Crossing Over They used corn chromosome 9 markers: c = colorless seed wx = waxy endosperm They created a heterozygote with the following characteristics: repulsion configuration of genetic markers cytological landmarks on both ends of one chromosome They performed a testcross to this stock and analyzed the results.
If crossing over involves exchange of chromosomal material each recombinant chromosome would have on of the cytological landmarks. This is the result they obtained. See the figure below.
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