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This chapter on "Heredity" explores the mechanisms by which traits and characteristics are inherited from one generation to the next. It delves into the concepts of genetic variation, inheritance, and the principles that govern these processes, as laid out by Gregor Mendel. The chapter also discusses how these inherited traits can lead to diversity within a species and the role of heredity in evolution. The chapter is crucial for understanding the basic principles of genetics and the biological processes that underlie inheritance.Overview: Heredity | Science Class 10

Accumulation of Variation of Reproduction

  • If one bacterium divides, and then the resultant two bacteria divide again, the four individual bacteria generated would be very similar. There would be only very minor differences between them.
  •  However, if sexual reproduction is involved, even greater diversity will be generated. 
  • In sexual reproduction, the parental generation provides information for basic body design for the next generation, which is accompanied by small changes.
  • Different variations would provide different advantages to different individuals.
  • The selection of variants by environmental factors forms the basis for the evolutionary process.

Overview: Heredity | Science Class 10

Heredity

The transfer of traits from one generation to the next is termed heredity.  Both parents contribute an equal amount of genetic material to the child i.e., for each trait, there will be a maternal and a paternal chromosome.

Overview: Heredity | Science Class 10

Inherited traits 

  • The traits that are inherited from the parents are called inherited characters. These traits always get transferred to the next generation but depending on the dominance or recessiveness, they may or may not be expressed.

Genes 

  • Gene is the functional unit of heredity.
  • Every gene controls one or several particular characteristic features in living organisms.

Rules for Inheritance of Traits: Mendel's Contributions

  • Gregor Johann Mendel, through consistent studies on Garden Pea, arrived at laws of inheritance.
  • He used plants that were pure breeding for a trait and considered contrasting characters like - tall and short plant size, round and wrinkled seeds, white and violet flowers etc. for his studies.
    Overview: Heredity | Science Class 10

Dominant Gene 

The traits that express themselves in an organism in every possible combination and can be seen are called Dominant traits. In Mendel’s experiment, we see that the tall trait in pea plants tends to express more than the short trait. Therefore, the tall trait of the plant is said to be dominant over the short trait.

Recessive Gene 

A trait which is not expressed in the presence of a dominant gene is known as recessive. So, a recessive character/trait is present in an organism but cannot be seen if a dominant gene exists.

Monohybrid Cross

  • In his experiments, he crossed plants with contrasting characters, studied the progeny of first-generation (F1and second-generation (F2and calculated ratios of plants with contrasting characters that were an original parental type or different.
  • For example, he crossed a pure tall pea plant with a dwarf pea plant. He found that in the first generation (F1) all the plants produced were tall. This led Mendel to propose that two copies of factors (now we know them as genes) that control a trait are present in each sexually reproducing organism
  • But when plants of F1 were crossed to get the second generation, he found that 3/4 of plants were tall while 1/4  were short.
  • Mendel concluded that an offspring might receives half its genetic material from either parent and if we represent tallness as 'T’ and dwarfness as ‘t’ then -
    Tall parent can be represented as TT and dwarf parent can be represented as tt. This is genotypic representation of pure plants for their respective traits. Hence, both the chromosomes are same making the organism homozygous for that trait.
  • When progeny of F1 were self-pollinated the resultant progeny F2 showed a ratio of 3 :1, i.e., three tall and one dwarf pea plant.
    Overview: Heredity | Science Class 10

Dihybrid Cross

  • A single copy of 'T' is enough to make the plant tall while both copies of T for the plant to be dwarf.
  • The trait which is expressed in F1 i.e., in heterozygous condition, is called dominant the one which remains hidden is termed recessive. The F1 generation is the result of cross between two pure individuals for contrasting characters. Hence, it will have one chromosome from either parent (Ex: Tt), making it heterozygous.
  • Similarly, when two pairs of contrasting characters were studied simultaneously, it was found that two traits are inherited independent of each other.
  • For example, a plant with round seeds of yellow colour (RRYY) was crossed with a plant with wrinkled seeds of green colour (rryy).
  • In F1 generation, all plants produced resembled the dominant parent.
  • However, on selfing F1 x F1 to get F2 progeny, the result showed that the two traits i.e., round/wrinkled seeds and yellow/green colour were inherited independently.
  • It also shows that new combinations of traits are formed in F2.
    Overview: Heredity | Science Class 10This shows that the two traits are inherited independently of each other.

Expression of genes 

  • Genes control the expression of a trait or a character in an organism. 
  • Genes produces proteins. 
  • The proteins act as enzymes which can directly control a character or help in the formation of a hormone which can control the expression of a particular character or the proteins become a part of various structural components.

Sex Determination

  • Humans have 23 pairs of chromosomes.
  •  Out of these 23 pairs, 22 pairs are Autosomes and only one pair is the ‘Sex Chromosome’, which actively takes part in the process of sex determination.
  • Male has one X and one Y (XY) sex chromosome. 
  • Female has both X (XX) sex chromosome 
  • All children will inherit an X chromosome from their mother, despite whether they are a boy or girl. Thus, the sex of the children will be determined by the type of chromosome inherited from their father. 
  • Overview: Heredity | Science Class 10A child who inherits Y chromosome will be a boy and who inherits X chromosome will be a girl.
The document Overview: Heredity | Science Class 10 is a part of the Class 10 Course Science Class 10.
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FAQs on Overview: Heredity - Science Class 10

1. What is the significance of Mendel's contributions to the understanding of heredity?
Ans.Mendel's contributions are significant as he established the foundational principles of inheritance through his experiments with pea plants. He formulated the laws of segregation and independent assortment, which explain how traits are passed from parents to offspring. His work laid the groundwork for the field of genetics.
2. How does a dihybrid cross differ from a monohybrid cross in genetics?
Ans.A dihybrid cross involves the examination of two different traits, while a monohybrid cross focuses on a single trait. In a dihybrid cross, the inheritance patterns of two traits are analyzed simultaneously, allowing for the observation of how alleles assort independently.
3. What are the basic rules for inheritance of traits as proposed by Mendel?
Ans.Mendel proposed several key rules for inheritance, including the Law of Segregation, which states that allele pairs separate during gamete formation, and the Law of Independent Assortment, which indicates that the inheritance of one trait does not influence the inheritance of another trait.
4. How is sex determination achieved in humans?
Ans.Sex determination in humans is achieved through the presence of sex chromosomes. Females have two X chromosomes (XX), while males have one X and one Y chromosome (XY). The combination of these chromosomes from the parents determines the sex of the offspring.
5. What is the role of variation in reproduction?
Ans.Variation in reproduction is essential for the evolution and adaptation of species. It introduces genetic diversity, which allows populations to adapt to changing environments and increases the chances of survival by providing a broader range of traits that may be beneficial under different circumstances.
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