Recessive Trait

Genetics 101: Recessive traits

Order: Reorder
Duration: 10:54
Updated: 26 May 2013

Basic genetics info on recessive traits.

http://wn.com/Genetics_101_Recessive_traits

RECESSIVE AND DOMINANT CHARACTERISTICS.m4v

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Duration: 3:10
Updated: 05 Jul 2013

http://wn.com/RECESSIVE_AND_DOMINANT_CHARACTERISTICSm4v

Dominant and Recessive traits

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Duration: 4:07
Updated: 26 Jul 2013

How dominant and recessive alleles (genotype) interact to produce a trait (phenotype)

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What are Punnett Squares

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Duration: 5:07
Updated: 28 Jul 2013

Learn how traits are passed from generation to generation. Punnett Squares help predict the genes passed to offspring. Dominant and recessive genes combined ...

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Biology #7 A - Dominant and Recessive Genes.wmv

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Duration: 4:51
Updated: 10 Jun 2013

Genes are passed on from parent to offspring using dominant and recessive genes. This lesson explains the difference between dominant and recessive genes and...

http://wn.com/Biology_7_A_Dominant_and_Recessive_Geneswmv

Heredity: Crash Course Biology #9

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Duration: 10:18
Updated: 18 Aug 2013

Hank and his brother John discuss heredity via the gross example of relative ear wax moistness. Like CrashCourse on Facebook! http://www.facebook.com/YouTube...

http://wn.com/Heredity_Crash_Course_Biology_9

How Mendel's pea plants helped us understand genetics - Hortensia Jiménez Díaz

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Duration: 3:07
Updated: 18 Aug 2013

View full lesson: http://ed.ted.com/lessons/how-mendel-s-pea-plants-helped-us-understand-genetics-hortensia-jimenez-diaz Each father and mother pass down tra...

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Dominant Traits

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Duration: 1:32
Updated: 21 May 2013

A few examples of dominant traits in genetics - created at http://animoto.com.

http://wn.com/Dominant_Traits

Hardy-Weinberg #3 - dominant & recessive traits.m4v

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Duration: 7:59
Updated: 22 Jan 2013

In this video we will work through a problem that provides information on how the trait is inherited (i.e. dominant vs. recessive). Knowing that the populati...

http://wn.com/Hardy-Weinberg_3_dominant_recessive_traitsm4v

Autosomal Recessive Dz and Probability

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Duration: 5:59
Updated: 10 Jun 2013

These videos are designed for medical students studying for the USMLE step 1. Feel free to comment and suggest what you would like to see in the future, and ...

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Electric Blue Jack Dempsey (Rare Recessive trait)

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Duration: 0:34
Updated: 11 Apr 2013

Electric Blue verson of the Jack dempsey, I got the one in the background from maidenhead aquatics. You cannot breed EBJD to EBJD, as the fry are too weak.

http://wn.com/Electric_Blue_Jack_Dempsey_Rare_Recessive_trait

The Story of Fido's Physical Traits

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Duration: 4:29
Updated: 08 Aug 2013

Appearance only reveals part of your dog's ancestry -- the rest is revealed when you take a closer look at his/her DNA. This illustrative video provides info...

http://wn.com/The_Story_of_Fido's_Physical_Traits

Dominant vs. Recessive

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Duration: 1:39
Updated: 25 May 2013

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Introduction to Heredity

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Duration: 17:27
Updated: 20 Aug 2013

Learn more: http://www.khanacademy.org/video?v=eEUvRrhmcxM Heredity and Classical Genetics. Dominant and recessive traits. Heterozygous and homozygous genoty...

http://wn.com/Introduction_to_Heredity

Genetics problems 5 recessive epistasis

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Duration: 10:23
Updated: 01 Oct 2013

For more information, log on to- http://shomusbiology.weebly.com/ Download the study materials here- http://shomusbiology.weebly.com/bio-materials.html Genetics (from Ancient Greek γενετικός genetikos, "genitive" and that from γένεσις genesis, "origin"),[1][2][3] a discipline of biology, is the science of genes, heredity, and variation in living organisms.[4][5] Genetics concerns the process of trait inheritance from parents to offspring, including the molecular structure and function of genes, gene behavior in the context of a cell or organism (e.g. dominance and epigenetics), gene distribution, and variation and change in populations (such as through Genome-Wide Association Studies). Given that genes are universal to living organisms, genetics can be applied to the study of all living systems; including bacteria, plants, animals, and humans. The observation that living things inherit traits from their parents has been used since prehistoric times to improve crop plants and animals through selective breeding[citation needed]. The modern science of genetics, seeking to understand this process, began with the work of Gregor Mendel in the mid-19th century.[6] Mendel observed that organisms inherit traits by way of discrete 'units of inheritance.' This term, still used today, is a somewhat ambiguous definition of a gene. A more modern working definition of a gene is a portion (or sequence) of DNA that codes for a known cellular function. This portion of DNA is variable, it may be small or large, have a few subregions or many subregions. The word 'Gene' refers to portions of DNA that are required for a single cellular process or single function, more than the word refers to a single tangible item. A quick idiom that is often used (but not always true) is 'one gene, one protein' meaning a singular gene codes for a singular protein type in a cell. Another analogy is that a 'gene' is like a 'sentence' and 'letters' are like 'nucleotides.' A series of nucleotides can be put together without forming a gene (non-coding regions of DNA), like a string of letters can be put together without forming a sentence (babble). Nonetheless, all sentences must have letters, like all genes must have a nucleotides. The sequence of nucleotides in a gene is read and translated by a cell to produce a chain of amino acids which in turn spontaneously fold into proteins. The order of amino acids in a protein corresponds to the order of nucleotides in the gene. This relationship between nucleotide sequence and amino acid sequence is known as the genetic code. The amino acids in a protein determine how it folds into its unique three-dimensional shape; a structure that is ultimately responsible for the proteins function. Proteins carry out many of the functions needed for cells to live. A change to the DNA in a gene can change a protein's amino acid sequence, thereby changing its shape and function, rendering the protein ineffective or even malignant (see: sickle cell anemia). When a gene change occurs, it is referred to as a mutation. Although genetics plays a large role in the appearance and behavior of organisms, it is a combination of genetics with the organisms' experiences (aka. environment) that determines the ultimate outcome. Genes may be activated or inactivated, which is determined by a cell's or organism's environment, intracellularly and/or extracellularly. For example, while genes play a role in determining an organism's size, the nutrition and health it experiences after inception also have a large effect.

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What is outcome of crossing homozygous recessive with heterozygous?

Order: Reorder
Duration: 4:31
Updated: 25 Dec 2013

Heterozygous vs. Homozygous Loci and Dominant vs. Recessive Genes When an individual has two identical genes at a locus, it is said to be homozygous (a zygote is a germ cell, e.g. an egg or sperm, and homozygous means the two have the same gene at the same locus). Individuals with different genes at a locus are heterozygous at that locus. For example, individuals that are AA are homozygous, and those that are Aa are heterozygous. In a heterozygous locus, one of the genes might be dominant, which means that the trait it codes for will be seen and the trait coded for by the other gene (the recessive gene) will not be epxressed. For example, suppose A is dominant and a is recessive. That means whenever an organism has an A at the locus - either AA, Aa, or aA - the attribute coded by A is in effect. The only way the attribute coded by a is seen is if the organism is aa.

http://wn.com/What_is_outcome_of_crossing_homozygous_recessive_with_heterozygous?

Genetics part 7 epistasis (dominant, recessive, double dominant etc.)

Order: Reorder
Duration: 18:32
Updated: 30 Sep 2013

For more information, log on to- http://shomusbiology.weebly.com/ Download the study materials here- http://shomusbiology.weebly.com/bio-materials.html In genetics, epistasis is a phenomenon in which the expression of one gene depends on the presence of one or more 'modifier genes'. A gene whose phenotype is expressed is called epistatic, while one whose phenotype is altered or suppressed is called hypostatic. If two epistatic genes A and B are mutated, and each mutation by itself produces a unique phenotype but the two mutations together show the same phenotype as the gene A mutation, then gene A is epistatic to gene B. Epistasis can be contrasted with dominance, which is an interaction between alleles at the same gene locus. Epistasis is often studied in relation to Quantitative Trait Loci (QTL) and polygenic inheritance. In general, the expression of any one allele depends in a complicated way on many other alleles; but, because of the way that the science of population genetics was developed, evolutionary scientists tend to think of epistasis as the exception to the rule. In the first models of natural selection devised in the early 20th century, each gene was considered to make its own characteristic contribution to fitness, against an average background of other genes. Some introductory college courses still teach population genetics this way. Epistasis and genetic interaction refer to different aspects of the same phenomenon. The term epistasis is widely used in population genetics and refers especially to the statistical properties of the phenomenon, and does not necessarily imply biochemical interaction between gene products. However, in general epistasis is used to denote the departure from 'independence' of the effects of different genetic loci. Confusion often arises due to the varied interpretation of 'independence' between different branches of biology.[1] Examples of tightly linked genes having epistatic effects on fitness are found in supergenes and the human major histocompatibility complex genes. The effect can occur directly at the genomic level, where one gene could code for a protein preventing transcription of the other gene. Alternatively, the effect can occur at the phenotypic level. For example, the gene causing albinism would hide the gene controlling color of a person's hair. In another example, a gene coding for a widow's peak would be hidden by a gene causing baldness. Fitness epistasis (where the affected trait is fitness) is one cause of linkage disequilibrium between loci that are not necessarily physically close to each other. Studying genetic interactions can reveal gene function, the nature of the mutations, functional redundancy, and protein interactions. Because protein complexes are responsible for most biological functions, genetic interactions are a powerful tool.

http://wn.com/Genetics_part_7_epistasis_dominant,_recessive,_double_dominant_etc

Punnett Square Charting Dominant and Recessive Traits

Order: Reorder
Duration: 1:59
Updated: 04 Nov 2013

http://wn.com/Punnett_Square_Charting_Dominant_and_Recessive_Traits

Sex linked inheritance

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Duration: 7:52
Updated: 24 May 2013

Inheritance involving genes that are on the X chromosome in animals (focus on sex-linked recessive traits)

http://wn.com/Sex_linked_inheritance

Sex-Linked Traits

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Duration: 14:19
Updated: 16 Aug 2013

Learn more: http://www.khanacademy.org/video?v=-ROhfKyxgCo Chromosomal basis for gender. Sex-linked traits.

http://wn.com/Sex-Linked_Traits

Recessive vs DOMINANT Genes

Order: Reorder
Duration: 9:06
Updated: 16 Aug 2013

Understanding DNA final informing people about genes that are recessive and dominant. I do not own the copyrights to the song.

http://wn.com/Recessive_vs_DOMINANT_Genes

List all the genotypes possible

Order: Reorder
Duration: 8:16
Updated: 22 Dec 2013

The Law of Segregation states that alleles segregate randomly into gametes When gametes are formed, each allele of one parent segregates randomly into the gametes, such that half of the parent's gametes carry each allele. KEY POINTS Each gamete acquires one of the two alleles as chromosomes separate into different gametes during meiosis. Heterozygotes, which posess one dominant and one recessive allele, can receive each allele from either parent and will look identical to homozygous dominant individuals; the Law of Segregation supports Mendel's observed 3:1 phenotypic ratio. Mendel proposed the Law of Segregation after observing that pea plants with two different traits produced offspring that all expressed the dominant trait, but the following generation expressed the dominant and recessive traits in a 3:1 ratio. TERMS law of segregation a diploid individual possesses a pair of alleles for any particular trait and each parent passes one of these randomly to its offspring. qual Segregation of Alleles Observing that true-breeding pea plants with contrasting traits gave rise to F1 generations that all expressed the dominant trait and F2 generations that expressed the dominant and recessive traits in a 3:1 ratio, Mendel proposed the law of segregation. The law of segregation states that each individual that is a diploid has a pair of alleles (copy) for a particular trait. Each parent passes an allele at random to their offspring resulting in a diploid organism (Figure 1). The allele that contains the dominant trait determines the phenotype of the offspring. In essence, the law states that copies of genes separate or segregate so that each gamete receives only one allele. For the F2 generation of a monohybrid cross, the following three possible combinations of genotypes could result: homozygous dominant, heterozygous, or homozygous recessive. Because heterozygotes could arise from two different pathways (receiving one dominant and one recessive allele from either parent), and because heterozygotes and homozygous dominant individuals are phenotypically identical, the law supports Mendel's observed 3:1 phenotypic ratio. The equal segregation of alleles is the reason we can apply the Punnett square to accurately predict the offspring of parents with known genotypes. The physical basis of Mendel's law of segregation is the first division of meiosis in which the homologous chromosomes with their different versions of each gene are segregated into daughter nuclei. The behavior of homologous chromosomes during meiosis can account for the segregation of the alleles at each genetic locus to different gametes. As chromosomes separate into different gametes during meiosis, the two different alleles for a particular gene also segregate so that each gamete acquires one of the two alleles. In Mendel's experiments, the segregation and the independent assortment during meiosis in the F1 generation give rise to the F2 phenotypic ratios observed by Mendel. The role of the meiotic segregation of chromosomes in sexual reproduction was not understood by the scientific community during Mendel's lifetime.

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How to solve problems and find genotype/phenotype as result of the cross?

Order: Reorder
Duration: 9:47
Updated: 26 Dec 2013

1. Genetic Crosses 2. Think About It... How can an offspring have a certain trait if neither of its parents displayed that trait? How many alleles does an offspring get from each parent? 3. Law of Segregation Each parent passes on ONE of two alleles to its offspring. LAW OF SEGREGATION: Each pair of alleles is segregated, or separated, during the formation of gametes. 4. Meiosis Aa A a A a Chromosomes double A A a a 5. Law of Independent Assortment Alleles for different characteristics are distributed to different gametes independently. 6. Example A In rabbits, brown fur (B) is dominant to white fur (b). If a rabbit is heterozygous for fur color, what gametes could be created? 7. Example B A rabbit is homozygous recessive for fur. What color is it? What percentage of its gametes would have the allele for brown fur? 8. Punnett Squares Chart that shows possible combinations when egg and sperm combine 9. Punnett Squares Draw a square as shown. Each box represents a possible combination of alleles in the offspring. 10. Punnett Squares Determine which alleles will be in the sex cells of each parent. Write the egg and sperm possibilities along the top and side. 11. Punnett Squares Copy the alleles into the boxes below and across from them. Calculate percentage of offspring with each phenotype. 12. Punnett Squares Your problems must display the following: Original cross Punnett Square Resulting phenotypes (# or percentage) Phenotype ratio 13. Example I In pot-bellied pigs, grey fur (G) is dominant to pink fur (g). A homozygous dominant male pig mates with a pink female pig. Predict the possible F 1 offspring. 14. Example II A man heterozygous for a cleft chin, a dominant trait, mates with a woman with no cleft chin. What percentage of their children will have a cleft chin? 15. Example III Pollen from a rose bush with red flowers, a dominant trait, was crossed to a second bush with red flowers. (White is the recessive trait.) If the first plant was homozygous and the second plant was heterozygous, predict the possibilities of their offspring. 16. Example IV In parrots, green feathers are dominant over red feathers. Two heterozygous birds are crossed. What are the possible genotypes of the F 1 generation? 17. F 1 Crosses A common cross involves crossing two individuals with opposing traits, one homozygous dominant and one homozygous recessive, the crossing their F 1 offspring to analyze the F 2 generation. 18. Example V Cross a homozygous dominant and homozygous recessive parrot, then cross two of the F 1 offspring. What is the ratio of dominant and recessive offspring in the F 2 ? G = green G = red 19. A Common Ratio Any time a homozygous dominant individual is crossed with a homozygous recessive individual, the F 2 generation will have a 3:1 ratio of dominant traits to recessive traits. 20. Pea Plant Experiments Experiment 1: Plant Height Mendel crossed a short plant with a tall plant. All offspring were tall. Crossing two of the offspring resulted in 787 tall plants and 277 short plants -- HOW??? 21. Pea Plant Experiments Experiment 2: Seed Color Mendel crossed a yellow-seed plant with a green-seed plant. All offspring had yellow seeds. Crossing two of the offspring resulted in 6,022 yellow-seed plants and 2001 green-seed plants -- HOW??? 22. Monohybrid Crosses The crosses we have been completing are called "monohybrid crosses" because they deal with only one trait. 23. Other Types of Inheritance 24. Types of Inheritance Dominant-Recessive Multiple Alleles Codominance Incomplete Dominance 25. Multiple Alleles Characteristics are determined by more than two alleles Example: human blood types (A, B, AB, O) 26. Incomplete Dominance Heterozygous individuals have a phenotype in-between the dominant and recessive phenotypes 27. Incomplete Dominance Carnations can be red, white, or pink R R = red R' R' = white R R' = pink 28. Example VI Cross a red carnation with a white carnation. What is the phenotype ratio? 29. Example VII Cross two F 1 carnations from the previous cross. What is the phenotype ratio of the F 2 generation? 30. Example VIII Chinchillas are fuzzy, South American rodents. Two alleles control their fur color: F, which represents black, and f, which represents white. Heterozygous chinchillas are grey. Cross a grey chinchilla male with a white female. Give the possible offspring colors and ratio. 31. Example VIII 32. Codominance Heterozygous individuals display both phenotypes Examples: Human blood type AB Roan horses = red and white fur Calico cats = orange and black fur 33. Example IX A roan mare, heterozygous for coat color, is crossed with a red stallion. Describe their offspring. (R codes for red while R' codes for white.) 34. Example X A calico cat has the genotype BB'. What is the ratio of F 2 offspring if a pure-breeding black cat (BB) is crossed with a pure-breeding orange cat (B'B'), and then their offspring are crossed?

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