Answer: Trait B (60%) likely arose earlier than trait A (10%). In asexual reproduction, traits are passed from parent to offspring with minor variations. A trait that has been present longer will have had more time to spread through the population, resulting in a higher percentage. Since trait B is present in 60% of the population compared to trait A's 10%, it has had more generations to accumulate and spread.

Answer: Variations promote survival in several ways:

• Environmental adaptation: Different variations help individuals adapt to changing environmental conditions
• Natural selection: Beneficial variations increase survival chances in specific environments
• Species survival: If the environment changes drastically, at least some individuals with suitable variations will survive
• Example: In a heat wave, bacteria with heat-resistant variations will survive better than those without

Without variations, if environmental conditions change, the entire species might become extinct.

Answer:

Mendel's experiments demonstrated dominant and recessive traits through his monohybrid cross:

• F1 Generation observation: When he crossed tall pea plants (TT) with short pea plants (tt), ALL F1 offspring were tall, not medium-height
• This showed that tallness dominated over shortness
• F2 Generation observation: When F1 plants (Tt) were self-pollinated, the F2 generation had both tall and short plants in a 3:1 ratio
• The reappearance of short plants proved the shortness trait was present but hidden in F1

Conclusion:

• Dominant trait (T): Expressed even when present in single copy (Tt shows tall)
• Recessive trait (t): Expressed only when both copies are present (tt shows short)

Answer:

Mendel's dihybrid cross proved independent inheritance:

• Cross performed: Round, Yellow seeds (RRYY) × Wrinkled, Green seeds (rryy)
• F1 Result: All plants had Round, Yellow seeds (RrYy)
• F2 Result: Four types of offspring appeared:
  • Round, Yellow (9)
  • Round, Green (3) - NEW combination
  • Wrinkled, Yellow (3) - NEW combination
  • Wrinkled, Green (1)

Significance of new combinations: The appearance of Round-Green and Wrinkled-Yellow (which were not present in parents) proves that:

• Seed shape and seed color traits separated and recombined independently
• The two traits are controlled by genes on different chromosomes
• Inheritance of one trait does not affect inheritance of another

Answer:

No, this information is NOT enough to determine which trait is dominant.

Reason:

• The daughter has blood group O, which she must have inherited from both parents
• The mother (blood group O) can only give O allele
• The father (blood group A) must have given an O allele to the daughter
• This means the father's genotype could be:
  • AO (heterozygous) - has both A and O alleles
  • If A is dominant, genotype AO shows blood group A
  • If O is dominant, genotype AO should show blood group O, but father shows A

What we can conclude:

• Blood group A appears to be dominant because the father with AO genotype shows blood group A phenotype
• However, to be completely certain, we would need to see results from multiple families or do more crosses

Actually, A IS dominant over O, but the single case doesn't provide conclusive proof - we need larger sample sizes for scientific certainty.

Answer:

In human beings, sex is determined genetically by sex chromosomes:

Chromosome composition:

• Humans have 23 pairs of chromosomes (46 total)
• 22 pairs are autosomes (same in males and females)
• 1 pair consists of sex chromosomes

Parent	Sex Chromosomes	Gametes Produced
Mother (Female)	XX	All carry X chromosome
Father (Male)	XY	50% carry X, 50% carry Y

Mechanism:

• All children inherit one X chromosome from mother
• Children inherit either X or Y from father
• If child gets X from father → Girl (XX)
• If child gets Y from father → Boy (XY)

Conclusion: The father's chromosome determines the sex of the child, with a 50:50 probability of boy or girl.

Answer: (c) TtWW

Explanation:

• Given information:
  • Tall parent with violet flowers crossed with short parent with white flowers
  • All progeny have violet flowers (W is dominant)
  • About half progeny are short (ratio is approximately 1:1 for height)
• Analysis for height:
  • Short parent genotype: tt
  • Half offspring are short means 1:1 ratio
  • This happens when one parent is heterozygous (Tt)
  • Tt × tt → 50% Tt (tall), 50% tt (short)
• Analysis for flower color:
  • Short parent genotype: ww
  • All offspring have violet flowers
  • This means tall parent must be WW (homozygous)
  • WW × ww → All Ww (violet)

Therefore, tall parent genotype = TtWW

Answer: No, we cannot determine dominance from this information alone.

Reason:

• The observation only shows that light eye color runs in families - it's inherited
• This pattern would occur whether light eye color is dominant OR recessive
• If light is recessive:
  • Parents with light eyes (ll) can only produce children with light eyes (ll)
  • This fits the observation
• If light is dominant:
  • Parents with light eyes (LL or Ll) would mostly produce children with light eyes
  • This also fits the observation

What we need to determine dominance:

• We need to study families where parents have DIFFERENT eye colors
• If dark × light consistently produces dark children, dark is dominant
• If dark × light consistently produces light children, light is dominant
• We need F2 generation data to see phenotypic ratios

Note: In reality, dark eye color is dominant over light eye color in humans.

Answer: Project Plan to Determine Dominant Coat Color in Dogs

Objective: To identify which coat color is dominant in dogs (e.g., black vs. brown)

Method:

1. Select Purebred Parents:
   • Choose purebred black dogs (BB)
   • Choose purebred brown dogs (bb)
   • Ensure they are from pure lines for at least 3 generations
2. Cross Breeding (F1 Generation):
   • Breed black dogs with brown dogs
   • Observe the coat color of all F1 puppies
   • All F1 puppies will show the dominant color
   • If all puppies are black → Black is dominant
   • If all puppies are brown → Brown is dominant
3. F2 Generation (Confirmation):
   • Breed F1 dogs with each other (Bb × Bb)
   • Observe coat colors in F2 generation
   • Expected ratio: 3 dominant color : 1 recessive color
   • This 3:1 ratio confirms which trait is dominant
4. Data Collection:
   • Record number of puppies of each color in both generations
   • Calculate percentages
   • Use large sample sizes (minimum 50-100 puppies) for accuracy
5. Test Cross (Additional confirmation):
   • Breed F1 dogs (Bb) with recessive parent (bb)
   • Expected ratio: 1 dominant : 1 recessive (50:50)

Expected Results:

Cross	Result if Black is Dominant
BB × bb	All Black (Bb)
Bb × Bb	3 Black : 1 Brown
Bb × bb	1 Black : 1 Brown

Precautions:

• Ensure purebred parents
• Maintain proper records
• Use large sample sizes
• Consider environmental factors that might affect coat color

Answer:

Equal genetic contribution from both parents is ensured through the following mechanism:

1. Diploid Body Cells:

• All body cells are diploid (2n)
• They contain two sets of chromosomes - one from each parent
• In humans: 23 pairs = 46 chromosomes total

2. Meiosis - Formation of Gametes:

• Reproductive cells undergo meiosis (reduction division)
• During meiosis, chromosome number is reduced to half
• Gametes (sperm and egg) are haploid (n)
• Each gamete contains only one set of chromosomes
• In humans: gametes have 23 chromosomes (not 23 pairs)

3. Process:

• Male parent: Produces sperm cells (n) through meiosis
• Female parent: Produces egg cells (n) through meiosis
• Each gamete receives:
  • One chromosome from each pair
  • This can be either maternal or paternal origin

4. Fertilization:

• One sperm (n) fuses with one egg (n)
• The resulting zygote is diploid (2n)
• n (from father) + n (from mother) = 2n (in child)

Conclusion:

• The reduction of chromosome number during meiosis and restoration during fertilization ensures equal genetic contribution
• This maintains chromosome number constant across generations
• Child receives exactly 50% DNA from each parent