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Genetics lessons in Bayswater

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1 genetics teacher in Bayswater

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Biology · Microbiology · Genetics
In the IGCSE and CIE (Cambridge International Education)curricula, Genetics is a part of Biology under the broader topics of inheritance and variation. It is covered in both IGCSE Biologyand AS/A Level Biology. Below is a breakdown of what you can expect in each: IGCSE Biology (Cambridge - 0610/0970) The topic of genetics is introduced under the following key areas: 1. Variation and Inheritance - Genetic variation: Understanding differences caused by genetic and environmental factors. - Inheritance: - Definition of key terms: genes, alleles, dominant, recessive, homozygous, heterozygous, phenotype, genotype. - Monohybrid inheritance (using Punnett squares to predict offspring ratios). - Concepts of dominant and recessive traits. - Structure of DNA: - Basic structure of DNA (double helix) and its role in carrying genetic information. - Mutations: - Causes (e.g., radiation, chemicals) and effects of mutations on organisms. 2. Selective Breeding and Genetic Engineering (basic concepts): - Selective breeding in animals and plants to produce desired traits. - Introduction to genetic modification (GM), though details are limited in IGCSE. --- CIE AS and A Level Biology (9700) At the A Level, genetics is covered in greater depth. Key concepts include: 1. DNA and Protein Synthesis: - Structure of DNA, RNA, and nucleotides. - Transcription, translation, and protein synthesis. - Genetic code and its universal nature. 2. Cell Division: - Mitosis and meiosis. - Significance of meiosis in genetic variation (crossing over, independent assortment). 3. Inheritance: - Mendelian genetics: monohybrid and dihybrid crosses. - Codominance and multiple alleles. - Sex-linked inheritance (e.g., haemophilia, color blindness). - Pedigree analysis. 4. Gene Technology: - Recombinant DNA technology (genetic modification and cloning). - Applications of genetic engineering in medicine and agriculture. 5. Mutations: - Gene mutations and their effects. - Chromosomal abnormalities. 6. Variation and Selection: - Natural selection and evolution. - Role of genetic variation in populations. --- Summary - At the IGCSE level, genetics focuses on basic concepts of inheritance, variation, DNA structure, and simple Punnett square problems. - At the AS/A Level, the depth increases significantly, introducing advanced topics like meiosis, protein synthesis, genetic engineering, and natural selection.
Genetics
Trusted teacher: With the Genetics course, an undergraduate student will be exposed to a clear, comprehensive, and balanced introduction to genetics and genomics. The material deals with transmission genetics and molecular genetics, as fully integrated subjects, and provides an understanding of the basic processes of gene transmission, mutation, expression, and regulation. Upon successful completion of the course, students must be able to: Common outcomes: a - Solve genetic problems of several types. b - Write and State genetic principles in their own words and recognize the key terms of genetics in context. c - Be able to think like a geneticist at the elementary level of being able to formulate genetic hypotheses, work out their consequences, and test the results against observed data. d - Gain some sense of the social and historical context in which genetics and genomics has developed and is continuing to develop. e - Develop critical thinking and analytical skills. Specific Outcomes: 1.1 - Analyze a pedigree, determine the mode of inheritance and genotypes, and predict offspring ratios. 1.2 - Inspect data from 3-point mapping crosses. 1.3 - Test the goodness-of-fit of experimental data to theoretical predictions using the chi-squared test. 2.1 – Discover and discuss the basic processes of gene transmission, mutation and expression. 2.2 - Assess the principal experimental methods that geneticists use in their studies, and consider the advantages and limitations of these approaches. 2.3 - Investigate the modes of gene expression regulation. 3.1 – Examine the role of every component of eukaryotic and prokaryotic chromosomes. 3.2 – Predict and evaluate the consequences of genomic rearrangements. 3.3 – Analyze genome organization and the parameters affecting DNA renaturation. 4.1 – Consider the different mechanisms of genetic exchanges. 4.2 – Practice how transformation, transduction and conjugation can be used in gene With the Molecular Biology course, the student will acquire knowledge in the field of modern molecular biology as it covers the molecular mechanisms of gene expression and regulation, the fundamental aspects of recombinant DNA technology, the protein structure and function, the signaling pathways that control gene activity, the regulation of the eukaryotic cell cycle, the Cell birth lineage and death, and Cancer. Course Learning Outcomes: Upon successful completion of the course, students must be able to: Common outcomes: a - Identify and discuss several molecular mechanisms underlying cellular functions. b – Solve molecular problems of several types. c - Develop critical thinking and analytical skills in molecular biology research. d – Develop scientific communication. Specific Outcomes: 1.1- Inspect and contrast the genetic engineering methods that molecular biologists use in their studies in order to determine gene function, and discriminate the advantages and limitations of these approaches. 1.2- Analyze and evaluate the applications of recombinant DNA technology. 2.1- Practice a genome-wide analysis of gene structure and expression. 2.2- Identify the transcriptional and post transcriptional gene expression regulation. 2.3- Acquire knowledge about the histone code and dissect how chromatin remodeling plays an important role in the determination of gene expression pattern. 2.4- Investigate how the post translational modifications participate in regulating gene function. 3.1- Consider biology at new levels of complexity, such as large multiprotein signaling complexes in cells. 3.2- Interpret how signaling pathways control gene activity. 4.1- Examine the molecular aspects underlying the activation of the origins of replication and the occurrence of the early and late mitotic events.
Genetics · Molecular biology
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Only reviews of students are published and they are guaranteed by Apprentus. Rated 4.7 out of 5 based on 16 reviews.

Tutor in English Language/Literature and Biology for High School and University Students (Yeongdong)
Karl
Mr. Karl is amazing, my son really struggles with biology and mr. Karl helped him very good. Mr. Karl explained him all matters in an excellent way with a lot of patience. His teaching is very clear and he is able to explain complicated topics in a way it’s understandable. I really recommend Karl!!
Review by SAMIRA
Learn basic to advanced chemistry, biochemistry, organic chemistry (Coventry)
Aditya
Adi is good at explaining concepts to let student understand. He’s helpful and asks for student’s feedback to check-in progress. Impressive !
Review by FM
learn how to keep your soul and body healthy with very easy yoga steps. (Rohtak)
Prachi
Prachi is wonderful. She takes her time for you and has a lot of experience, so she can catche you at you level and help you make progress.
Review by OMER