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Practice Questions for Science Class 10th "Heridity"

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Multiple Choice Questions (MCQs):

  1. Who is known as the father of genetics?
    • A) Charles Darwin
    • B) Gregor Mendel
    • C) Louis Pasteur
    • D) Thomas Morgan
  2. Mendel studied the inheritance patterns in which plant?
    • A) Pea plant
    • B) Sunflower
    • C) Rice
    • D) Potato
  3. The term 'genetics' was coined by:
    • A) William Bateson
    • B) Gregor Mendel
    • C) Charles Darwin
    • D) Hugo de Vries
  4. The physical expression of a gene is known as:
    • A) Genotype
    • B) Phenotype
    • C) Allele
    • D) Trait
  5. If a plant has the genotype Tt, it is:
    • A) Homozygous dominant
    • B) Homozygous recessive
    • C) Heterozygous
    • D) None of the above
  6. Which of these is not a Mendelian law?
    • A) Law of Segregation
    • B) Law of Independent Assortment
    • C) Law of Dominance
    • D) Law of Natural Selection
  7. When both alleles of a gene pair are different, the individual is:
    • A) Homozygous
    • B) Heterozygous
    • C) Purebred
    • D) Hybrid
  8. The condition where two different alleles for a trait are expressed simultaneously is called:
    • A) Dominance
    • B) Recessiveness
    • C) Co-dominance
    • D) Incomplete dominance
  9. Which of these is an example of a sex-linked trait?
    • A) Eye color
    • B) Height
    • C) Hemophilia
    • D) Blood group
  10. In humans, the sex chromosomes are:
    • A) XX or YY
    • B) XX or XY
    • C) XO or YO
    • D) XX or XO
  11. The gene responsible for a particular characteristic is called:
    • A) Chromosome
    • B) Trait
    • C) Allele
    • D) Genome
  12. If both parents are carriers for a recessive trait, what is the probability of their child expressing that trait?
    • A) 0%
    • B) 25%
    • C) 50%
    • D) 100%
  13. What does the Punnett square help predict?
    • A) Weather patterns
    • B) Genetic outcomes
    • C) Economic trends
    • D) Population growth
  14. The genetic makeup of an organism is its:
    • A) Phenotype
    • B) Genotype
    • C) Karyotype
    • D) Pedigree
  15. A trait that is passed from fathers to sons only is likely:
    • A) Autosomal
    • B) Sex-linked
    • C) Recessive
    • D) Dominant
  16. Which of Mendel's laws explains why traits can skip generations?
    • A) Law of Segregation
    • B) Law of Independent Assortment
    • C) Law of Dominance
    • D) None of the above
  17. The genetic condition where a person has an extra chromosome is called:
    • A) Mutation
    • B) Aneuploidy
    • C) Polyploidy
    • D) Hybridization
  18. In pea plants, if yellow seed color (Y) is dominant over green (y), what would be the genotype of a plant with green seeds?
    • A) YY
    • B) Yy
    • C) yy
    • D) YY or Yy
  19. The study of heredity and the variation of inherited characteristics is called:
    • A) Physiology
    • B) Pathology
    • C) Genetics
    • D) Zoology
  20. An organism that has two different alleles for a particular gene is:
    • A) Homozygous
    • B) Heterozygous
    • C) Diploid
    • D) Haploid

 

Short Answer Questions:

  1. Define the term 'allele'.
  2. Explain the difference between genotype and phenotype.
  3. What is meant by 'dominant' and 'recessive' traits?
  4. How did Mendel ensure that his experiments were not influenced by environmental factors?
  5. Describe Mendel's Law of Segregation.
  6. What is co-dominance? Give an example.
  7. Why are pea plants considered ideal for genetic experiments?
  8. What does the term 'incomplete dominance' mean, and can you provide an example?
  9. Explain how sex determination works in humans.
  10. What are sex-linked traits? How do they differ from autosomal traits?
  11. How can you use a Punnett square to predict the offspring of a cross between two heterozygous parents?
  12. Discuss the role of genes in determining traits.
  13. How does the Law of Independent Assortment work? Provide an example.
  14. What is a genetic disorder? Give two examples.
  15. Explain the concept of 'carrier' in genetics.
  16. Why might a trait skip a generation?
  17. What is a pedigree chart, and what is it used for in genetics?
  18. Describe the difference between a mutation and a variation.
  19. How does genetic variation contribute to evolution?
  20. What is the significance of the F1 and F2 generations in Mendel's experiments?

 

Long Answer Questions:

  1. Describe Mendel's experiments with pea plants and how they led to the formulation of his laws of inheritance.
  2. Explain the process of genetic inheritance with the help of a Punnett square, using an example of a monohybrid cross.
  3. Discuss the role of DNA in heredity. How does DNA lead to the expression of traits?
  4. What are the differences between Mendelian and non-Mendelian inheritance patterns? Provide examples for each.
  5. Explain how genetic counseling could help families with a history of genetic disorders.
  6. Discuss the ethical considerations of genetic testing and engineering.
  7. How do genetic mutations affect heredity? Include examples of both beneficial and harmful mutations.
  8. Describe the process of meiosis and explain how it contributes to genetic diversity.
  9. What is gene interaction, and how does it affect the expression of traits? Use examples to explain.
  10. Explain the concept of polygenic inheritance. How does it differ from Mendelian inheritance?
  11. Discuss the impact of environmental factors on gene expression, giving specific examples.
  12. How does the study of heredity help in understanding human diseases? Give examples.
  13. Describe the inheritance of blood groups in humans. How does it exemplify co-dominance?
  14. What is the Human Genome Project, and what are its implications for genetics and medicine?
  15. Discuss the role of genetic drift and gene flow in changing allele frequencies in populations.
  16. Explain how genetic recombination during meiosis leads to greater genetic diversity.
  17. What are the implications of cloning for the study of heredity? Discuss both positive and negative aspects.
  18. How does the Hardy-Weinberg principle relate to the study of heredity and evolution?
  19. Describe the genetic basis of natural selection. How does it lead to evolutionary changes?
  20. Explain the concept of epigenetics and how it might influence heredity without changing the DNA sequence.

 

Application-Based Questions:

If a red-flowered (R) pea plant is crossed with a white-flowered (r) pea plant, and all the offspring (F1) are red, what can you conclude about the inheritance pattern?

  1. In humans, brown eyes (B) are dominant over blue eyes (b). If two heterozygous parents (Bb) have children, what are the possible eye colors of their offspring?
  2. A woman with type AB blood has a child with a man with type O blood. What blood types are possible for their child?
  3. In snapdragons, red flowers crossed with white flowers produce all pink flowers. Explain this result in terms of inheritance.
  4. If a man with normal vision (X^Y) and a woman who is a carrier for color blindness (X^cX) have children, what are the chances of their son being color blind?
  5. A couple has four children, two with blue eyes and two with brown eyes. If brown eyes are dominant (B) over blue (b), what are the possible genotypes of the parents?
  6. Predict the outcome of a dihybrid cross between pea plants that are heterozygous for both seed color (Yy) and seed shape (Rr).
  7. A family pedigree shows hemophilia only in males. Explain how this pattern is consistent with sex-linked inheritance.
  8. How would you use a test cross to determine if a plant with a dominant phenotype is homozygous or heterozygous?
  9. If you cross a homozygous tall (TT) pea plant with a heterozygous tall (Tt) plant, what would be the expected phenotypic ratio in the F1 generation?

 

Critical Thinking Questions:

  1. Why might some genetic traits not follow Mendel's laws strictly?
  2. Discuss how understanding genetics has changed the approach to breeding in agriculture.
  3. How does the concept of 'heritability' differ from inheritance?
  4. What are the implications of genetic diversity for conservation biology?
  5. How might advances in genetic technology change our approach to treating genetic diseases?
  6. Discuss the potential societal impacts of genetic screening for traits like intelligence or athletic ability.
  7. How does the environment interact with genetic predispositions to affect an organism's traits?
  8. What are the challenges in predicting genetic outcomes in humans compared to plants like peas?
  9. Explain why identical twins might not be completely identical in terms of traits and health.
  10. How can the study of heredity help in the fight against antibiotic resistance?

 

Answers

Multiple Choice Questions (MCQs):

  1. B) Gregor Mendel - Gregor Mendel is known as the father of genetics due to his pioneering work on pea plants.
  2. A) Pea plant - Mendel conducted his experiments on garden pea plants.
  3. A) William Bateson - William Bateson coined the term 'genetics' to describe the study of heredity and variation.
  4. B) Phenotype - Phenotype refers to the physical expression or characteristics of an organism due to its genetic makeup.
  5. C) Heterozygous - Tt represents a heterozygous genotype where one allele is dominant (T) and one is recessive (t).
  6. D) Law of Natural Selection - This is not one of Mendel's laws; it's part of Darwin's theory of evolution.
  7. B) Heterozygous - An individual with two different alleles for a gene pair is heterozygous.
  8. C) Co-dominance - In co-dominance, both alleles are expressed equally in the phenotype.
  9. C) Hemophilia - Hemophilia is an example of a sex-linked trait, usually carried on the X chromosome.
  10. B) XX or XY - In humans, females are XX, and males are XY.
  11. C) Allele - An allele is one of two or more versions of a gene.
  12. B) 25% - For two carriers (Aa and Aa), there's a 1 in 4 chance (25%) of an offspring expressing the recessive trait (aa).
  13. B) Genetic outcomes - A Punnett square predicts the possible genotypes of offspring from given parental genotypes.
  14. B) Genotype - The genetic makeup or the combination of alleles for a given gene or set of genes is the genotype.
  15. B) Sex-linked - Traits passed from fathers to sons only are usually X-linked recessive traits.
  16. A) Law of Segregation - This law explains that traits can skip generations due to the separation of alleles during gamete formation.
  17. B) Aneuploidy - An extra chromosome results in aneuploidy, like in Down syndrome (trisomy 21).
  18. C) yy - Green seeds in pea plants are a recessive trait, so the genotype must be yy.
  19. C) Genetics - Genetics is the study of heredity and the variation of inherited characteristics.
  20. B) Heterozygous - An organism with two different alleles for a gene is heterozygous.

 

Short Answer Questions:

  1. Allele: An allele is one of two or more alternative forms of a gene at a given locus on a chromosome.
  2. Genotype vs. Phenotype: Genotype is the genetic constitution of an organism, while phenotype is the observable physical or biochemical characteristics which result from the genotype and environmental influences.
  3. Dominant vs. Recessive Traits: Dominant traits mask the expression of recessive traits in heterozygous individuals. Recessive traits are only expressed if both alleles are recessive.
  4. Mendel's Control: Mendel controlled variables like cross-pollination, used purebred lines for experiments, and tracked traits over generations to minimize environmental influence.
  5. Law of Segregation: This law states that during gamete formation, the two alleles for each gene segregate so that each gamete carries only one allele.
  6. Co-dominance: Both alleles contribute to the phenotype, e.g., in human blood groups, AB type where both A and B antigens are expressed.
  7. Pea Plants: They have easily distinguishable traits, can self-pollinate or be cross-pollinated, and have a short generation time.
  8. Incomplete Dominance: Neither allele is completely dominant, leading to a blend of traits, e.g., red and white flowers producing pink in snapdragons.
  9. Sex Determination: Humans have 23 pairs of chromosomes, one pair being sex chromosomes. XX results in female, XY in male.
  10. Sex-linked Traits: Traits on sex chromosomes, often X-linked. They differ from autosomal traits which are on non-sex chromosomes, showing different inheritance patterns.
  11. Punnett Square: For two heterozygous parents (e.g., Bb x Bb), a Punnett square shows 25% BB, 50% Bb, and 25% bb, predicting phenotypes.
  12. Role of Genes: Genes carry instructions for traits; variations in genes lead to variation in traits.
  13. Law of Independent Assortment: Genes for different traits segregate independently of one another during gamete formation, e.g., seed color and shape in peas.
  14. Genetic Disorder: Abnormalities due to genetic mutations. Examples include cystic fibrosis and Down syndrome.
  15. Carrier: An individual with one copy of a recessive allele for a disorder, showing no symptoms but can pass the allele to offspring.
  16. Trait Skipping: Due to recessive traits not being expressed unless both alleles are present, or through sex-linked inheritance.
  17. Pedigree Chart: A diagram showing the occurrence and appearance of phenotypes of a particular gene or organism and its ancestors over multiple generations.
  18. Mutation vs. Variation: Mutation is a change in DNA sequence, while variation refers to differences within populations, including from mutations.
  19. Genetic Variation and Evolution: Variation provides raw material for natural selection, leading to evolution by favoring traits that enhance survival and reproduction.
  20. F1 and F2 Generations: F1 (first filial) shows immediate results of crossbreeding, while F2 (second filial) reveals the segregation of alleles, confirming Mendel's laws.

 

Long Answer Questions:

  1. Mendel's Experiments:
  • Mendel crossbred pea plants, tracking traits like seed color, shape, etc., across generations. His observations led to three laws: Segregation, Independent Assortment, and Dominance.
  1. Genetic Inheritance with Punnett Square:
  • Example: Monohybrid cross of tall (T) and short (t) pea plants (Tt x Tt). The Punnett square shows 3:1 ratio of tall to short in F2, demonstrating Mendelian ratios.
  1. Role of DNA in Heredity:
  • DNA carries genetic information; genes on DNA code for proteins that define traits. Transcription and translation convert DNA's code into functional proteins.
  1. Mendelian vs. Non-Mendelian:
  • Mendelian: Traits follow Mendel's laws, e.g., pea plant colors.
  • Non-Mendelian: Includes co-dominance (ABO blood groups), incomplete dominance (flower color blending), and polygenic traits (skin color).
  1. Genetic Counseling:
  • Helps families understand genetic risks, inheritance patterns, and options for testing, prevention, or management of genetic disorders.
  1. Ethical Considerations:
  • Issues include privacy, consent, potential for discrimination, and the moral implications of altering human genetics or selecting for certain traits.
  1. Genetic Mutations:
  • Beneficial: Mutations can lead to adaptations, like sickle cell trait offering malaria resistance.
  • Harmful: Mutations can cause diseases like cystic fibrosis.
  1. Meiosis and Diversity:
  • Meiosis involves crossing over, independent assortment, and random segregation of chromosomes, increasing genetic variation in gametes.
  1. Gene Interaction:
  • When genes at different loci interact to produce a phenotype, e.g., epistasis where one gene masks the expression of another.
  1. Polygenic Inheritance:
  • Traits controlled by multiple genes, like height or skin color, contrast with Mendelian traits controlled by single genes, showing a range of phenotypes.
  1. Environmental Impact on Gene Expression:
  • Example: Diet affecting gene expression in obesity, or sunlight influencing skin pigmentation through vitamin D synthesis.
  1. Heredity and Human Disease:
  • Understanding inheritance helps in diagnosing, predicting, and potentially preventing genetic diseases like Huntington's or BRCA-related cancers.
  1. Blood Group Inheritance:
  • A, B, O blood groups show co-dominance (A and B are co-dominant over O), with phenotypes determined by combinations of these alleles.
  1. Human Genome Project:
  • Aimed to sequence all human DNA; implications include identifying disease-causing genes, personalized medicine, and understanding human evolution.
  1. Genetic Drift and Gene Flow:
  • Genetic drift randomly changes allele frequencies, while gene flow introduces new alleles into populations, both impacting genetic diversity.
  1. Genetic Recombination:
  • During meiosis, recombination shuffles genes, ensuring offspring are genetically diverse, promoting adaptability.
  1. Cloning and Heredity:
  • Cloning can produce organisms with identical genes, useful for research but raises ethical issues about genetic diversity and identity.
  1. Hardy-Weinberg Principle:
  • Describes allele frequency in a non-evolving population, providing a baseline to detect evolutionary changes.
  1. Genetic Basis of Natural Selection:
  • Selection favors certain alleles, leading to changes in population genetics over time, driving evolution.
  1. Epigenetics:
  • Changes in gene expression without altering DNA sequence, influenced by environment, like methylation patterns affecting gene activity.

 

Application-Based Questions:

  1. Red and White Flowers: If all F1 are red, red is likely dominant. The cross was probably RR x rr, with R being dominant.
  2. Eye Color: Possible eye colors are brown (BB or Bb) or blue (bb), with a 3:1 ratio of brown to blue.
  3. Blood Types: Child can only be A or B, as O is recessive and cannot mask A or B.
  4. Snapdragon Flowers: This shows incomplete dominance, where the heterozygous phenotype is intermediate.
  5. Color Blindness: There's a 50% chance for a son to be color blind (X^cY).
  6. Eye Color of Children: Parents could be Bb (one brown, one blue gene each), producing the observed ratio.
  7. Dihybrid Cross: With YyRr x YyRr, expect a 9:3:3:1 phenotypic ratio for yellow round, yellow wrinkled, green round, and green wrinkled seeds.
  8. Hemophilia and Pedigree: Hemophilia's X-linked nature means it only appears in males if inherited from a carrier mother.
  9. Test Cross: Cross the dominant phenotype with a homozygous recessive; if any offspring show the recessive trait, the parent was heterozygous.
  10. Tall Cross: All F1 would be phenotypically tall (TT or Tt), but genotypically, you'd get 50% TT and 50% Tt.

 

Critical Thinking Questions:

  1. Non-Mendelian Inheritance: Traits might show incomplete dominance, co-dominance, or be polygenic, not fitting Mendel's strict laws.
  2. Breeding in Agriculture: Genetics allows for selective breeding for desired traits, increasing yield, resistance, or nutritional content.
  3. Heritability vs. Inheritance: Heritability measures how much of the variation in a trait is due to genetics, while inheritance refers
  4. Genetic Diversity and Conservation: Genetic diversity ensures species resilience, adaptability, and survival. Conservation biology uses this knowledge to manage populations, prevent inbreeding, and maintain ecosystem health.
  5. Genetic Technology and Disease Treatment: Advancements like gene therapy, CRISPR, and genetic screening can lead to personalized medicine, targeting genetic disorders at their molecular level, potentially offering cures or significant symptom management.
  6. Societal Impact of Genetic Screening: Screening for non-disease traits could lead to ethical issues like eugenics, discrimination, or social stratification. It might also affect employment, insurance, and personal identity.
  7. Environment and Genetic Predispositions: Environmental factors can activate or silence genes (epigenetics), influencing phenotype. For example, diet affects obesity genes, or sunlight impacts vitamin D synthesis, altering gene expression.
  8. Predicting Human Genetic Outcomes: Human genetics is complex with multiple genes, environmental interactions, and ethical constraints on experiments, making predictions less straightforward than in plants like peas.
  9. Identical Twins: Despite sharing DNA, environmental factors, epigenetics, and even minor genetic differences from mutations can lead to phenotypic differences in traits or health outcomes.
  10. Heredity and Antibiotic Resistance: Understanding how resistance genes are inherited and spread can guide strategies to limit resistance development, like reducing antibiotic use and improving infection control practices.

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