Unit 6 – Meiosis, Replication, and Protein Synthesis Test on Monday 1/26 Chapters 13, 16, and 17 No chapter notes…reading guides
Meiosis & Sexual Reproduction
Cell division / Asexual reproduction Mitosis produce cells with same information identical daughter cells exact copies clones same amount of DNA same number of chromosomes same genetic information What is Binary Fission? Aaaargh! I’m seeing double!
+ 46 46 92 Okay then….? No! What if we did, then…. Doesn’t work! Why can’t we just do mitosis to reproduce? Why produce sperm and egg and even go through the hassle of dating? No! What if we did, then…. 46 + 46 92 egg sperm zygote Doesn’t work!
Sexual reproduction creates variability Sexual reproduction allows us to maintain both genetic similarity & differences. Jonas Brothers Baldwin brothers Martin & Charlie Sheen, Emilio Estevez any 2 parents will produce a zygote with over 70 trillion (223 x 223) possible diploid combinations
The value of sexual reproduction Sexual reproduction introduces genetic variation genetic recombination independent assortment of chromosomes random alignment of homologous chromosomes in Metaphase 1 crossing over mixing of alleles across homologous chromosomes random fertilization which sperm fertilizes which egg? Driving evolution providing variation for natural selection gametes of offspring do not have same combination of genes as gametes from parents random assortment in humans produces 223 (8,388,608) different combinations in gametes metaphase1
Human female karyotype 46 chromosomes 23 pairs
Human male karyotype 46 chromosomes 23 pairs
Homologous chromosomes Paired chromosomes both chromosomes of a pair carry “matching” genes control same inherited characters homologous = same information single stranded homologous chromosomes diploid 2n 2n = 4 double stranded homologous chromosomes
Meiosis: production of gametes chromosome number must be reduced diploid haploid 2n n humans: 46 23 meiosis reduces chromosome number makes gametes fertilization restores chromosome number haploid diploid n 2n haploid Warning: meiosis evolved from mitosis, so stages & “machinery” are similar but the processes are radically different. Do not confuse the two! diploid
Double division of meiosis DNA replication Meiosis 1 1st division of meiosis separates homologous pairs Meiosis 2 2nd division of meiosis separates sister chromatids
Meiosis 1 1st division of meiosis separates homologous pairs synapsis single stranded Meiosis 1 1st division of meiosis separates homologous pairs 2n = 4 double stranded prophase 1 synapsis 2n = 4 double stranded metaphase 1 tetrad reduction 1n = 2 double stranded telophase 1
Trading pieces of DNA Crossing over during Prophase 1, sister chromatids intertwine homologous pairs swap pieces of chromosome DNA breaks & re-attaches prophase 1 Chiasma synapsis tetrad
What does this division look like? Meiosis 2 2nd division of meiosis separates sister chromatids 1n = 2 double stranded prophase 2 What does this division look like? 1n = 2 double stranded metaphase 2 1n = 2 single stranded telophase 2 4
Steps of meiosis Meiosis 1 Meiosis 2 interphase prophase 1 metaphase 1 anaphase 1 telophase 1 Meiosis 2 prophase 2 metaphase 2 anaphase 2 telophase 2 1st division of meiosis separates homologous pairs (2n 1n) “reduction division” 2nd division of meiosis separates sister chromatids (1n 1n) * just like mitosis *
Mitosis vs. Meiosis Mitosis Meiosis 1 division daughter cells genetically identical to parent cell produces 2 cells 2n 2n produces cells for growth & repair no crossing over Meiosis 2 divisions daughter cells genetically different from parent produces 4 cells 2n 1n produces gametes crossing over
Putting it all together… meiosis fertilization mitosis + development gametes 46 23 46 23 46 46 46 46 46 23 meiosis 46 46 egg 46 46 23 zygote fertilization mitosis sperm development
Sex Increases Variation! Metaphase I – there is a 50/50 chance of lining up so that “mom’s” pair or “dad’s” pair winds up in either of the cells produced (2 possibilities for each of the 23 tetrads 223 = 8,388,608 possible combinations per gamete Reproduction – possible combinations is equal to the possible number of combinations for each gamete, multiplied by each other (223) (223) = 70,368,744,177,664 possible combinations per offspring
Sperm production Spermatogenesis continuous & prolific process Epididymis Testis germ cell (diploid) Coiled seminiferous tubules primary spermatocyte (diploid) MEIOSIS I secondary spermatocytes (haploid) MEIOSIS II Vas deferens spermatids (haploid) spermatozoa Spermatogenesis continuous & prolific process each ejaculation = 100-600 million sperm Cross-section of seminiferous tubule
Egg production: Oogenesis Begins in the ovaries of the female fetus before birth Pauses during first meiotic division Final development occurs in the ovaries of the adult female Each month one egg matures as cued by hormones Completes the first meiotic division and starts the second meiotic division Last bit of meiosis is finalized at time of fertilization
Oogenesis MEIOSIS I MEIOSIS II primary follicles germinal cell first polar body second polar body ovum (haploid) secondary oocyte primary (diploid) germinal cell primary follicles mature follicle with secondary oocyte ruptured follicle (ovulation) corpus luteum developing follicle fertilization fallopian tube after fertilization
sperm vs. egg production Similarities Both produce haploid cells by meiosis Both take place in the gonads both are controlled by hormones Differences Spermatogenesis produces 4 sperm each time while oogenesis produces only 1 egg Formation of mature sperm continually occurs while eggs only mature once a month (on average) Sperm formation never stops, egg formation ends at menopause Sperm can be released at anytime while eggs are released only once a month
Differences across kingdoms Not all organisms use haploid & diploid stages in same way which one is dominant (2n or n) differs but still alternate between haploid & diploid must for sexual reproduction
Cheesy/Bizarre Meiosis Video www.youtube.com/watch?v=iCL6d0OwKt8