3.1 Genes Essential idea: Every living organism inherits a blueprint for life from its parents. Genes and hence genetic information is inherited from parents, but the combination of genes inherited from parents by each offspring will be different. In sexual reproduction each parent can only pass on 50% of there genes as the other 50% comes from the second parent. http://publicationsnigms.nih.gov/insidethecell/images/ch4_meiosissex.jpg

A gene is a heritable factor that controls or influences a specific characteristic, consisting of a length of DNA occupying a particular position on a chromosome (locus) http://learn.genetics.utah.edu/content/molecules/gene/

A gene is a heritable factor that controls or influences a specific characteristic, consisting of a length of DNA occupying a particular position on a chromosome (locus) Alleles of a gene are found at the same locus, but have a different DNA base sequence. The sequence tends to be very similar, differing only by a few bases. As shown later on [3.1.A1] a mutation causing a change to a single base can have a large impact on the structure and function of the protein synthesised. http://learn.genetics.utah.edu/content/molecules/gene/

3.1.A2 Comparison of the number of genes in humans with other species. Humans see themselves as being more complex and evolved than other species. Therefore you might well expect to see a larger number of genes in humans than in other organisms. Plant Mammal Bird Insect It is not just plants such as the grapevine that have large numbers of genes; water fleas are an animal example of an organism with more genes than humans. Bacterium Virus When analysing an organisms’ complexity, what other than the count of an organisms’ genes needs to be considered? https://www.sciencenews.org/sites/default/files/storyone_backstory_2.gif

http://learn.genetics.utah.edu/content/chromosomes/intro/ DNA Supercoiling: https://youtu.be/AF2wwMReTf8

3.1.U6 The genome is the whole of the genetic information of an organism. AND 3.1.U7 The entire base sequence of human genes was sequenced in the Human Genome Project. http://web.ornl.gov/sci/techresources/Human_Genome/index.shtml The Human Genome* Project (HGP) was an international 13-year effort, 1990 to 2003. Primary goals were to discover the complete set of human genes and make them accessible for further biological study, and determine the complete sequence of DNA bases in the human genome. http://www.ncbi.nlm.nih.gov/genome/guide/human/ *The genome is the entire genetic material of an organism. It consists of DNA (or RNA in RNA viruses) and includes both the genes and the non-coding sequences. https://www.dnalc.org/view/15477-The-public-Human-Genome-Project-mapping-the-genome-sequencing-and-reassembly-3D-animation-.html

Nature of Science: Developments in scientific research follow improvements in technology - gene sequencers are used for the sequencing of genes. (1.8) http://web.ornl.gov/sci/techresources/Human_Genome/index.shtml “The first methods for sequencing DNA were developed in the mid-1970s. At that time, scientists could sequence only a few base pairs per year, not nearly enough to sequence a single gene, much less the entire human genome. By the time the HGP began in 1990, only a few laboratories had managed to sequence a mere 100,000 bases, and the cost of sequencing remained very high. Since then, technological improvements and automation have increased speed and lowered cost to the point where individual genes can be sequenced routinely, and some labs can sequence well over 100 million bases per year.” (https://www.genome.gov/10001177) Key advances in technology: Biotechnology techniques such as PCR are used to prepare samples: the DNA needs to be copied to prepare a sufficiently large pure samples to sequence Computers automate the sequencing process Fluorescent labeling techniques enable all four nucleotides to be analysed together Lasers are used to fluoresce the dye markers Digital camera technology reads the dye markers Computers are used to assemble the base sequence

3.1.A1 The causes of sickle cell anemia, including a base substitution mutation, a change to the base sequence of mRNA transcribed from it and a change to the sequence of a polypeptide in haemoglobin.

Base substitution

What the difference?

3.1.U5 New alleles are formed by mutation. Learn.Genetics: What Is Mutation? http://learn.genetics.utah.edu/content/variation/mutation/

Substitution

Sickle cell disease

https://youtu.be/1fN7rOwDyMQ

For each chosen species retrieve the base sequence: 3.1.S1 Use of a database to determine differences in the base sequence of a gene in two species. One use of aligning base sequences is to determine the differences between species: this can be used to help determine evolutionary relationships. http://www.ncbi.nlm.nih.gov/genbank GenBank Your task is to analyse the differences between three or more species (the skill asks for two species, but the online Clustal tool works better with a minimum of three). For each chosen species retrieve the base sequence: Go to GenBank website http://www.ncbi.nlm.nih.gov/genbank Select ‘Gene’ from the search bar Enter the name of a gene (e.g. AMY1A for salivary amylase 1A or COX1 for cytochrome oxidase 1) AND the organism (use the binomial) and press ‘Search’ n.b. if you are comparing species the gene chosen needs to be the same for each species Select the ‘Name/Gene ID’ to get a detailed view Scroll down to the ‘Genomic regions, transcripts, and products’ section and click on ‘FASTA’ Copy the entire sequence from ‘>’ onwards Save the sequence – you will need to align with the other species next http://bitesizebio.s3.amazonaws.com/wp-content/uploads/2012/10/header-image-copy18.jpg

To align the sequences: Go to the Clustal Omega website http://www.ebi.ac.uk/Tools/msa/clustalo/ In STEP 1 Select ‘DNA’ under ‘a set of’ Paste the chosen sequences into the box (each sequence must start on a new line) Press ‘Submit’ (and wait – depending on the size of the sequences you may have to wait for a couple of minutes) http://www.ebi.ac.uk/Tools/msa/clustalo/ Analysis: ‘Alignments’ allows you to visually check the results – this is easier if the chosen gene has a short base sequence Under ‘Results Summary’ use the ‘Percent Identity Matrix’ to quantify the overall similarity (0 = no similarity, 100 = identical) Under ‘Phylogenic Tree’ chose the ‘Real’ option for the Phylogram to get a visual representation of how similar the species are (based on the chosen gene). http://bitesizebio.s3.amazonaws.com/wp-content/uploads/2012/10/header-image-copy18.jpg