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CHROMOSOMES © The Human Genome Project: Biocomputing Admin Ed Yung Chromosomes in eukaryotes and prokaryotes are different PROKARYOTES EUKARYOTES single chromosome plus plasmids many chromosomes circular chromosome linear chromosomes made only of DNA made of chromatin, a nucleoprotein (DNA coiled around histone proteins) found in cytoplasm found in a nucleus copies its chromosome and divides copies chromosomes, then the immediately afterwards cell grows, then goes through mitosis to organise chromosomes in two equal groups © 2007 Paul Billiet ODWS Chromosomes in eukaryotes Found in the nucleus Condensed and visible during cell division At the beginning of mitosis they can be seen to consist of two threads (sister chromatids) joined by a centromere The sister chromatids are identical copies During mitosis the sister chromatids separate and are placed into two nuclei © 2007 Paul Billiet ODWS Image believed to be in the Public Domain Numbers of chromosomes Constant for each cell in the body (except sex cells which only have half sets). Constant throughout the life of an individual (you don’t lose or gain chromosomes) Constant for all members of a species © 2007 Paul Billiet ODWS Mouse Maize Image believed to be in the Public Domain © A. Lane Rayburn Organism Human Chromosome numbers 46 Chimpanzee 48 House Mouse 40 Maize 20 © 2007 Paul Billiet ODWS Human chromosomes Image believed to be in the Public Domain The chromosomes of a human female © 2007 Paul Billiet ODWS Image believed to be in the Public Domain Identifying chromosomes Chromosomes can be identified by: Their size Their shape (the position of the centromere) NB Chromosomes are flexible Banding patterns produced by specific stains (Giemsa) Chromosomes are analysed by organising them into a KARYOTYPE © 2007 Paul Billiet ODWS © Biologyreference.com Female Male Images believed to be in the Public Domain Down’s syndrome Image believed to be in the Public Domain Development and chromosomes Differences in chromosomes are associated with difference in the way we grow. The karyotypes of males and females are not the same Females have two large X chromosomes Males have a large X and a small Y chromosome The X and the Y chromosomes are called sex chromosomes The sex chromosomes are placed at the end of the karyotype Unusual growth can be associated with chromosome abnormalities e.g. People who develop Down’s syndrome have trisomy 21 © 2007 Paul Billiet ODWS Chromosomal abnormalities Trysomy-21 Down’s syndrome Trysomy-18 Edward’s syndrome Images believed to be in the Public Domain Therefore genetic information is found on our chromosomes © 2007 Paul Billiet ODWS Chromosomes and cell division Multicellular organisms copy their chromosomes before cell division. Interphase They must grow to a mature size. The nucleus divides, distributing the chromosomes into two equal groups (mitosis). The cytoplasm then divides (cytokinesis) each part taking a nucleus. © 2007 Paul Billiet ODWS Image believed to be in the Public Domain The cell cycle Cytokinesis Division of the cytoplasm M G0 Some cells may stay in this stage for over a year G1 First growth phase. Varies in length G2 Second growth phase S Copying of chromosomes G1 + S + G2 = INTERPHASE © 2007 Paul Billiet ODWS The cell cycles in different cells Cell type Bean root tip Cell cycle / hours 19.3 Mouse fibroblast 22 Chinese hamster fibroblast Mouse small intestine epithelium 11 Mouse oesophagus epithelium © 2007 Paul Billiet ODWS 17 181 Chromosomes and reproduction Chromosomes come in pairs One of the pair is maternal the other is paternal When parents make sex cells the number of chromosomes must be halved One of each type of chromosome is taken © 2007 Paul Billiet ODWS Meiosis and fertilisation Mother Father 23 pairs of chromosomes 23 pairs of chromosomes Meiosis Sex cells 23 unpaired chromosomes 23 unpaired chromosomes 23 unpaired chromosomes Fertilisation 23 pairs of chromosomes Child © 2007 Paul Billiet ODWS Images believed to be in the Public Domain 23 unpaired chromosomes Meiosis A special type of cell division Used to make sex cells Meiosis halves the numbers of chromosomes Meiosis picks one chromosome from each pair at random and places them in a sex cell. This results in enormous variation amongst the sex cells. © 2007 Paul Billiet ODWS The inheritance of gender Is it going to be a boy or a girl? © University of New Mexico The inheritance of gender Mother Father XX XY Meiosis Sex cells X Fertilisation X X X Y X XX XY X XX XY Y Possible children Chance of a girl 50% Chance of a boy 50% © 2007 Paul Billiet ODWS Sex chromosomes The sex of many animals is determined by genes but on chromosomes called sex chromosomes The other chromosomes are called autosomes One sex is homogametic The other sex is heterogametic © 2007 Paul Billiet ODWS Sex determination in different animals HOMOGAMETIC SEX HETEROGAMETIC SEX SEX DETERMINATION Female XX Male XY Presence of Ychromosome = maleness (mammals and fish) Presence of second Xchromosome = femaleness (Drosophila, the fruit fly) Male ZZ Female ZW Female XX Male Xo © 2007 Paul Billiet ODWS Birds, amphibians, reptiles, butterflies, moths. Grasshoppers A prokaryotic chromosome consists of a single molecule of DNA in the form of a closed loop. The chromosome is described as circular. A prokaryotic cell has only one chromosome. A eukaryotic chromosome is linear, not circular, in other words it has two ends, like a sausage. Each chromosome contains one molecule of DNA for the first half or so of interphase, then the DNA replicates, and the two DNA molecules remain together (as sister-chromatids) in the same chromosome for the rest of interphase. This does not happen in prokaryotic cells. Eukaryotic cells have more than one chromosome. A further difference: prokaryotic chromosomes consist only of a naked DNA molecule, but eukaryotic chromosomes also contain many molecules of proteins (mostly histones). The DNA is wound around these proteins. Bacterial Chromosome Structure Prokaryotic cells (bacteria) contain their chromosome as circular DNA. Usually the entire genome is a single circle, but often there are extra circles called plasmids. The DNA is packaged by DNA-binding proteins. The bacterial DNA is packaged in loops back and forth. The bundled DNA is called the nucleoid. It concentrates the DNA in part of the cell, but it is not separated by a nuclear membrane (as in eukaryotes.) The DNA does form loops back and forth to a protein core, attached to the cell wall.