In this video, we're going to begin our introduction to Punnett squares. And so a Punnett square is really just a diagram. It's a very specific diagram that is going to show the possible genotypes and phenotypes of offspring for a specific trait. Now as we'll see moving forward in our course, Punnett squares are going to represent both meiosis or gametogenesis, as well as fertilization or gametofusion. Now again, Punnett squares show the possibilities that offspring will inherit a specific trait. And we'll get to talk more about how to use Punnett squares in our next video. But down below, what we have is this really interesting image which is showing you a pea plant over here that's saying, "Hey, wanna make baby peas with me?" to this other pea plant over here. And notice that this other pea plant is saying, "Only if one of them will be green." Let's check the Punnett square. And so notice here is the Punnett square in this pea plant's hand, and again, you can use Punnett squares to determine the possibilities that the offspring will inherit specific traits. And so, again, we'll be able to talk about how to use a Punnett square in our next video. So I'll see you all there.
- 1. Introduction to Biology2h 40m
- 2. Chemistry3h 40m
- 3. Water1h 26m
- 4. Biomolecules2h 23m
- 5. Cell Components2h 26m
- 6. The Membrane2h 31m
- 7. Energy and Metabolism2h 0m
- 8. Respiration2h 40m
- 9. Photosynthesis2h 49m
- 10. Cell Signaling59m
- 11. Cell Division2h 47m
- 12. Meiosis2h 0m
- 13. Mendelian Genetics4h 41m
- Introduction to Mendel's Experiments7m
- Genotype vs. Phenotype17m
- Punnett Squares13m
- Mendel's Experiments26m
- Mendel's Laws18m
- Monohybrid Crosses16m
- Test Crosses14m
- Dihybrid Crosses20m
- Punnett Square Probability26m
- Incomplete Dominance vs. Codominance20m
- Epistasis7m
- Non-Mendelian Genetics12m
- Pedigrees6m
- Autosomal Inheritance21m
- Sex-Linked Inheritance43m
- X-Inactivation9m
- 14. DNA Synthesis2h 27m
- 15. Gene Expression3h 20m
- 16. Regulation of Expression3h 31m
- Introduction to Regulation of Gene Expression13m
- Prokaryotic Gene Regulation via Operons27m
- The Lac Operon21m
- Glucose's Impact on Lac Operon25m
- The Trp Operon20m
- Review of the Lac Operon & Trp Operon11m
- Introduction to Eukaryotic Gene Regulation9m
- Eukaryotic Chromatin Modifications16m
- Eukaryotic Transcriptional Control22m
- Eukaryotic Post-Transcriptional Regulation28m
- Eukaryotic Post-Translational Regulation13m
- 17. Viruses37m
- 18. Biotechnology2h 58m
- 19. Genomics17m
- 20. Development1h 5m
- 21. Evolution3h 1m
- 22. Evolution of Populations3h 52m
- 23. Speciation1h 37m
- 24. History of Life on Earth2h 6m
- 25. Phylogeny40m
- 26. Prokaryotes4h 59m
- 27. Protists1h 6m
- 28. Plants1h 22m
- 29. Fungi36m
- 30. Overview of Animals34m
- 31. Invertebrates1h 2m
- 32. Vertebrates50m
- 33. Plant Anatomy1h 3m
- 34. Vascular Plant Transport2m
- 35. Soil37m
- 36. Plant Reproduction47m
- 37. Plant Sensation and Response1h 9m
- 38. Animal Form and Function1h 19m
- 39. Digestive System10m
- 40. Circulatory System1h 57m
- 41. Immune System1h 12m
- 42. Osmoregulation and Excretion50m
- 43. Endocrine System4m
- 44. Animal Reproduction2m
- 45. Nervous System55m
- 46. Sensory Systems46m
- 47. Muscle Systems23m
- 48. Ecology3h 11m
- Introduction to Ecology20m
- Biogeography14m
- Earth's Climate Patterns50m
- Introduction to Terrestrial Biomes10m
- Terrestrial Biomes: Near Equator13m
- Terrestrial Biomes: Temperate Regions10m
- Terrestrial Biomes: Northern Regions15m
- Introduction to Aquatic Biomes27m
- Freshwater Aquatic Biomes14m
- Marine Aquatic Biomes13m
- 49. Animal Behavior28m
- 50. Population Ecology3h 41m
- Introduction to Population Ecology28m
- Population Sampling Methods23m
- Life History12m
- Population Demography17m
- Factors Limiting Population Growth14m
- Introduction to Population Growth Models22m
- Linear Population Growth6m
- Exponential Population Growth29m
- Logistic Population Growth32m
- r/K Selection10m
- The Human Population22m
- 51. Community Ecology2h 46m
- Introduction to Community Ecology2m
- Introduction to Community Interactions9m
- Community Interactions: Competition (-/-)38m
- Community Interactions: Exploitation (+/-)23m
- Community Interactions: Mutualism (+/+) & Commensalism (+/0)9m
- Community Structure35m
- Community Dynamics26m
- Geographic Impact on Communities21m
- 52. Ecosystems2h 36m
- 53. Conservation Biology24m
Punnett Squares - Online Tutor, Practice Problems & Exam Prep
A Punnett square is a diagram used to predict the genotypes and phenotypes of offspring from specific parental traits. The process involves three steps: drawing the square, aligning parental alleles, and filling in the squares to represent fertilization. Analyzing the results reveals the possible genotypes, such as heterozygous combinations, and their corresponding phenotypes. For example, a cross between a homozygous dominant and a homozygous recessive pea plant results in all offspring displaying the dominant phenotype. Understanding this tool is essential for studying inheritance patterns and genetic probabilities.
Punnett Squares
Video transcript
How to Use Punnett Squares
Video transcript
In this video, we're going to talk about how to use Punnett squares, which it turns out that it is a 3-step process to using Punnett squares. Now we're going to be making a Punnett square for these 2 pea plant individuals from our last lesson video. This pea plant over here, which is homozygous dominant because it has 2 dominant alleles or 2 uppercase Ys, and this pea plant over here which is homozygous recessive because it has 2 recessive alleles or 2 lowercase Ys. And so we'll be able to create a Punnett Square for these two organisms. And so in the very first step of creating a Punnett square, step number 1, of course, you have to draw the square itself, which is going to be a square, with 4 squares within it. But then after you draw the square, you are going to simply align the alleles of the parent gametes on the top and the left side of the square. And this is going to represent the process of meiosis, and recall meiosis is gamete formation. And so notice in step number 1, again, all we're going to do is align the gametes of the parent on the top and the side. And so notice that parent number 1 up above here, is, homozygous dominant, it has 2 capital Ys. So when it undergoes meiosis, each of the gametes can only have a capital Y, one capital Y. And for this parent number 2 over here, which is homozygous recessive to lowercase Ys, each of its gametes can only have one lowercase Y, which I'll draw with a lowercase cursive here to distinguish it easier from the capital Y. And so that's it for step number 1, align the alleles of the parent gametes on the top and left side of the square representing meiosis, gamete formation. And then in step number 2 of using the Punnett square, all we need to do is actually just fill in the Punnett square itself. And this process is going to represent fertilization or the fusion of the gametes. And so, when we take a look at the square this first square over here at the top left, this one's going to represent the fusion of this gamete with this gamete up here at the top. And so what we need to do is, bring down those, fill in these gametes. So this capital Y here is gonna go in this position and this lowercase Y here will go in this position. And that represents again the fusion of these 2 gametes right here in this box. So that represents fertilization. But then what if this gamete fuses with this gamete over here? Well, then we need to fill in, this box right here. So that would be bringing down this capital Y to this position and bringing across this lowercase Y over to this position over here, And so we would get this combination. And then of course this box down here represents the fusion of this gamete with this gamete here at the top. And once again you just bring down the capital Y here to this position, and you bring across the lowercase Y here to this position. And then, this last box over here represents the fusion of this gamete with this gamete here at the top. And so again, all you need to do is take the capital Y here and bring it all the way down, and bring the lowercase Y here and bring it all the way across. And so now what you can see is that we've completely filled in each of these 4 squares within our Punnett square. So we've completely filled in our Punnett square and we've completely finished step number 2, which again represents fertilization or the fusion of gametes. And so step number 3 here is really just to analyze the results, or in other words, analyze the possible genotypes and phenotypes of the offspring. And so when you take a look at step number 3 over here, analyze the results, of each of these squares, what you'll notice is that each of these 4 squares is showing a heterozygous genotype, 1 dominant allele and one recessive allele. And so, recall that the dominant allele, the capital Y, is going to dominate over the recessive allele. So that means that the capital Y, the yellow allele, is going to dominate, and each of these squares here represents a heterozygous yellow offspring. And so what we can say by analyzing the results is that there are 4 possibilities for yellow phenotypes in the offspring, and there are 0 possibilities for green phenotypes in the offspring. Again, to get a green phenotype, one of these squares would have to have 2 lowercase Ys, but that is not the case here. And so what's important to note is that each of these squares that you see here represents an equally probable genotype and phenotype that one single offspring can inherit. So these represent the possibilities. And so, later in our course, we'll be able to talk more about calculating probabilities when it comes to Punnett squares. But what's really important to note is that each fertilization event producing an offspring is going to be independent of each other. And so one fertilization event will not impact another fertilization event. And so that's exactly what we mean by independent. One fertilization event does not impact another fertilization event, which technically means that for each fertilization, for each offspring, this Punnett square would need to be reconsidered and redone essentially. And, again, we'll get to talk more about probabilities as they apply to Punnett squares later in our course. But for now, this here concludes our lesson on how to use Punnett squares, and we'll be able to apply these concepts as we move forward in our course. So I'll see you all in our next video.
Mendel found that green pea pod color (y) was recessive to yellow pea pod color (Y). For the cross Yy × yy, what percentage of offspring are expected to be yellow?
A female dog with black fur (Ff) mates with a male dog that also has black fur (Ff). Determine the possible genotypes and phenotypes of their puppies using a Punnett Square. Black fur (F) is dominant to grey fur (f).
a) # of possible Genotypes:
FF: ________
Ff: ________
ff: _________
b) % of possible Phenotypes:
Black fur: __________
Grey fur: ___________
A female dog with black fur (Ff) mates with a male dog that also has black fur (Ff). Determine the possible genotypes and phenotypes of their puppies using a Punnett Square. Black fur (F) is dominant to grey fur (f).
a) # of possible Genotypes:
FF: ________
Ff: ________
ff: _________
b) % of possible Phenotypes:
Black fur: __________
Grey fur: ___________
Problem Transcript
Do you want more practice?
More setsHere’s what students ask on this topic:
What is a Punnett square and how is it used in genetics?
A Punnett square is a diagram used in genetics to predict the possible genotypes and phenotypes of offspring from specific parental traits. It involves three steps: drawing the square, aligning the parental alleles on the top and left side, and filling in the squares to represent fertilization. This process helps visualize how alleles from each parent combine and the resulting genetic makeup of the offspring. For example, crossing a homozygous dominant (YY) with a homozygous recessive (yy) results in all heterozygous (Yy) offspring, displaying the dominant phenotype. Understanding Punnett squares is crucial for grasping genetic inheritance and probability in offspring traits.
How do you create a Punnett square for a monohybrid cross?
To create a Punnett square for a monohybrid cross, follow these steps: 1) Draw a square divided into four smaller squares. 2) Align the alleles of the parent gametes on the top and left side of the square. For example, if one parent is homozygous dominant (YY) and the other is homozygous recessive (yy), place 'Y' and 'Y' on the top and 'y' and 'y' on the side. 3) Fill in the squares by combining the alleles from the top and side. This represents fertilization. The resulting squares will show the possible genotypes of the offspring. In this case, all squares will be 'Yy', indicating heterozygous offspring with the dominant phenotype.
What are the steps involved in using a Punnett square?
Using a Punnett square involves three main steps: 1) Draw the square, which is a larger square divided into four smaller squares. 2) Align the alleles of the parent gametes on the top and left side of the square. This step represents meiosis, where gametes are formed. 3) Fill in the squares by combining the alleles from the top and side, representing fertilization. This step shows the possible genotypes of the offspring. Finally, analyze the results to determine the possible phenotypes. For example, a cross between homozygous dominant (YY) and homozygous recessive (yy) results in all heterozygous (Yy) offspring, displaying the dominant phenotype.
How do you interpret the results of a Punnett square?
Interpreting the results of a Punnett square involves analyzing the genotypes and phenotypes of the offspring. Each square within the Punnett square represents an equally probable genotype. For example, if you cross a homozygous dominant (YY) with a homozygous recessive (yy), all four squares will show 'Yy', indicating heterozygous offspring. The dominant allele (Y) will mask the recessive allele (y), resulting in the dominant phenotype. Therefore, all offspring will display the dominant trait. This analysis helps predict the likelihood of specific traits appearing in the offspring, which is crucial for understanding genetic inheritance and probability.
What is the significance of independent fertilization events in Punnett squares?
Independent fertilization events in Punnett squares mean that each fertilization event is separate and does not affect the outcome of another. This concept is crucial because it ensures that the probabilities calculated using Punnett squares are accurate for each offspring. For example, if a Punnett square predicts a 75% chance of a dominant phenotype and a 25% chance of a recessive phenotype, these probabilities apply to each offspring independently. This independence is essential for understanding genetic inheritance and accurately predicting the distribution of traits in a population.