1. Changes to the number of chromosomes
1. Changes to the number of chromosomes

... one of the resulting cells will have one chromosome too many, the other cell one chromosome less than normal. (See Fig 16.1 p 109 Torrance ‘New Higher Biology’). This results in the formation of abnormal gametes. Often these gametes will be unable to form viable embryos because the organism cannot c ...
Cellular Reproduction - Genomic DNA
Cellular Reproduction - Genomic DNA

... example, hair color is a characteristic with traits that are blonde, brown, or black. Each copy of a homologous pair of chromosomes originates from a dierent parent; therefore, the genes themselves are not identical. The variation of individuals within a species is due to the specic combination of ...
13-3 Cell Transformation
13-3 Cell Transformation

...  Bacterial plasmids can be used to transform plant cells.  Agrobacterium tumefaciens  Type of bacteria that inserts a plasmid into plant cells and grows tumors.  The tumor-producing gene can be removed and replaced with recombinant DNA.  If transformation is successful the recombinant DNA is in ...
Document
Document

... Eukaryotic cells that go through the process of mitosis make EXACT copies of themselves (one skin cell divides to form two identical skin cells, etc.) Sex cells (sperm and egg cells) are different from all other cells in the body because they have half as many chromosomes Human body cells have 46 ch ...
01 - edl.io
01 - edl.io

... _____ 4. The repeated sequence of growth and division during the life of a cell is called a. the cell cycle. c. mitosis. b. the life cycle. d. cytokinesis. _____ 5. The first three phases of the life cycle of a cell are called a. anaphase. c. the first gap phase. b. interphase. d. the synthesis phas ...
Meiosis
Meiosis

... Hereditary information is contained in genes, located in the chromosomes of each cell. An inherited trait of an individual can be determined by one or by many genes, and a single gene can influence more than one trait. A human cell contains many thousands of different genes in its nucleus. Each orga ...
AG-ASB-02.421-11.1P Genetics
AG-ASB-02.421-11.1P Genetics

... • Considered the “Father of Heredity” • He conducted plant breeding experiments in their monastery garden. • In 1865 he made his work public, units of inheritance. ...
Can You Divide - Cell Reproduction Notes
Can You Divide - Cell Reproduction Notes

... from a severed body part (ex: starfish) ...
Genetics
Genetics

... • Considered the “Father of Heredity” • He conducted plant breeding experiments in their monastery garden. • In 1865 he made his work public, units of inheritance. ...
Inheritance: Mitosis and Meiosis
Inheritance: Mitosis and Meiosis

... Even though chromosomes are inherited, they are not the same due to genetic diversity, which occurs during meiosis. Crossing-over of the non-sister chromatids of homologous chromosomes in Prophase I, and independent assortment of homologous chromosomes in Metaphase I allow for genetic diversity. Lo ...
Genetics - Tomball FFA
Genetics - Tomball FFA

... every cell is the genetic information “blueprint” to construct the individual. It is the Deoxyribonucleic acid (DNA) Function of DNA ...
S1-1-07: What role do gametes play in reproduction?
S1-1-07: What role do gametes play in reproduction?

... d) During the first stage of meiosis, what happens to the number of chromosomes? e) In the first stage, do chromosomes line up in homologous pairs or as single chromosomes? f) After the second stage of meiosis, how many chromosomes are present? g) What is a “gamete?” h) What type of cell is produced ...
CH 11 Human Inheritance / Pedigrees Notes
CH 11 Human Inheritance / Pedigrees Notes

... protective caps at the end of chromosomes that consist of  DNA associated with proteins ...
Ch 16 Genetics Review
Ch 16 Genetics Review

... and slowly duplicate the chromosomes for another mitotic division. Since this is meiosis, there is a very short interphase and division begins again. The DNA is not doubled ...
Cell Reproduction (continued)
Cell Reproduction (continued)

... • Meiosis is very similar to mitosis EXCEPT: – Meiosis consists of 2 division cycles – Meiosis starts with pairs of homologous chromosomes (or a tetrad of chromatids) – You end up with 4 daughter cells (sperm or egg) – Each daughter cell is genetically different – Each daughter cell is haploid (n), ...
A substance formed by the chemical joining of two or more elements
A substance formed by the chemical joining of two or more elements

... to make proteins translation ...
Students Mitosis 2011.ppt
Students Mitosis 2011.ppt

... » Nucleus well-defined ˃ DNA loosely packed in long chromatin fibers ...
Chapter 15
Chapter 15

... Explain the chromosomal theory of inheritance and its discovery Explain why sex-linked diseases are more common in human males than females Distinguish between sex-linked genes and linked genes Explain how meiosis accounts for recombinant phenotypes Explain how linkage maps are constructed Explain h ...
Meiosis simulation
Meiosis simulation

... Recall that chromosomes are composed of DNA and contain the genetic blueprint for an organism. Each species has its own unique set of chromosomes, and all individuals in a particular species typically have the same number of chromosomes. Humans have 46 chromosomes. The domestic dog has 78 chromosome ...
Biology Term 1 Revision tracker
Biology Term 1 Revision tracker

... Explain how nearly all human cells come to have 2 copies of each chromosome and what they are called The cell’s nucleus contains chromosomes made from long DNA molecules. Each cell has 2 copies of these chromosomes, meaning that body cells have 46 chromosomes in total, arranged into 23 pairs. The on ...
Chapter 8 Sample Questions: MITOSIS (there is another set for
Chapter 8 Sample Questions: MITOSIS (there is another set for

... 6. It is difficult to observe individual chromosomes with a light microscope during interphase because _____. A. they leave the nucleus and are dispersed to other parts of the cell B. the DNA has not been replicated yet C. they are uncoiled as long, diffuse, thin strands D. the spindle must move the ...
Genetics Notes
Genetics Notes

... chromosomes do not move apart in Meiosis I or sister chromatids do not separate during Meiosis II leaves one cell with too few chromosomes and one cell with too many. monosomy – only one of a particular type of chromosome (2n -1) trisomy – having three of a particular type of chromosome (2n + 1) pol ...
Human Chromosomes Section 14–2
Human Chromosomes Section 14–2

... human chromosomes. It also describes genetic disorders that are sex-linked, as well as disorders caused by nondisjunction. ...
Chromosomes and Cell Reproduction
Chromosomes and Cell Reproduction

... Segment of DNA that codes for a protein or RNA molecule ...
chromosomes
chromosomes

... comes from the mother (called a maternal chromosome) and one comes from the father (paternal chromsosome).  Homologous chromosomes are similar but not identical. Each carries the same genes in the same order, but the alleles (alternative form of a gene) for each trait may not be the same.  Excepti ...

Chromosome



A chromosome (chromo- + -some) is a packaged and organized structure containing most of the DNA of a living organism. It is not usually found on its own, but rather is complexed with many structural proteins called histones as well as associated transcription (copying of genetic sequences) factors and several other macromolecules. Two ""sister"" chromatids (half a chromosome) join together at a protein junction called a centromere. Chromosomes are normally visible under a light microscope only when the cell is undergoing mitosis. Even then, the full chromosome containing both joined sister chromatids becomes visible only during a sequence of mitosis known as metaphase (when chromosomes align together, attached to the mitotic spindle and prepare to divide). This DNA and its associated proteins and macromolecules is collectively known as chromatin, which is further packaged along with its associated molecules into a discrete structure called a nucleosome. Chromatin is present in most cells, with a few exceptions - erythrocytes for example. Occurring only in the nucleus of eukaryotic cells, chromatin composes the vast majority of all DNA, except for a small amount inherited maternally which is found in mitochondria. In prokaryotic cells, chromatin occurs free-floating in cytoplasm, as these cells lack organelles and a defined nucleus. The main information-carrying macromolecule is a single piece of coiled double-stranded DNA, containing many genes, regulatory elements and other noncoding DNA. The DNA-bound macromolecules are proteins, which serve to package the DNA and control its functions. Chromosomes vary widely between different organisms. Some species such as certain bacteria also contain plasmids or other extrachromosomal DNA. These are circular structures in the cytoplasm which contain cellular DNA and play a role in horizontal gene transfer.Compaction of the duplicated chromosomes during cell division (mitosis or meiosis) results either in a four-arm structure (pictured to the right) if the centromere is located in the middle of the chromosome or a two-arm structure if the centromere is located near one of the ends. Chromosomal recombination during meiosis and subsequent sexual reproduction plays a vital role in genetic diversity. If these structures are manipulated incorrectly, through processes known as chromosomal instability and translocation, the cell may undergo mitotic catastrophe and die, or it may unexpectedly evade apoptosis leading to the progression of cancer.In prokaryotes (see nucleoids) and viruses, the DNA is often densely packed and organized. In the case of archaea by homologs to eukaryotic histones, in the case of bacteria by histone-like proteins. Small circular genomes called plasmids are often found in bacteria and also in mitochondria and chloroplasts, reflecting their bacterial origins.