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Hello. In this lecture, we will focus on the genetic significance of mitosis and meiosis. The lecture is part of Module 1, Animal Genetics. 

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The creation of this presentation was supported by the ERASMUS+ KA2 grant within the project ISAGREED, Innovations in the Content and Structure of Study Programs in the Field of Animal Genetic and Food Resources Management Using Digitalization.

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Gregor Mendel was the first to recognize that processes related to his elements during gamete formation are closely related to heredity.

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He knew nothing about chromosomes in his time; their existence was described only towards the end of his life by Flemming.

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It was not until after 1900 that the connection between Mendel's discrete units - elements and their location on chromosomes during cell division - was demonstrated.

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The chromosomal theory of heredity was formulated in the 20s and 30s of the 20th century. 

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The linking of Mendel's discrete units - elements with their location on chromosomes became an integral part of scientists' understanding of heredity at the beginning of the 20th century.

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To better understand, we will show how chromosomes behave and what happens to them during the cell cycle. Diploid organisms always have 

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two copies of the same chromosome - one inherited from the mother and the other from the father. They form a homologous pair of chromosomes.

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A cell that grows normally, undergoes metabolism, and has one DNA molecule in each chromosome is formed by a single chromatid. 

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In the image on the left, we have a gene located on the homologous pair of chromosomes, in which it is heterozygous, Aa. Once the cell decides

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to divide, it enters the S phase (synthetic phase), where, from a genetic point of view, DNA replication and chromosome duplication take place.

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However, the number of chromosomes does not change, but within each chromosome, two chromatids appear, which are connected and form one chromosome.

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These chromatids are identical, carry the same genetic information, and are called sister chromatids. We can see them in the image 

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on the right. Such two-chromatid chromosomes enter cell division, whether mitosis or meiosis, through the G2 phase. This is essential 

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for understanding the connection between the inheritance of genes located on chromosomes and the behavior of chromosomes during subsequent divisions.

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This schematic representation simplifies the process. In the G0 and G1 phase, the chromosomes are one-chromatid. Each chromosome is formed by one DNA.

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The total DNA content is 2c (c as content) and the number of chromosomes is 2n (diploid state). The DNA content is the same as the number of chromatids.

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In the S phase and G2 phase, after DNA replication, the number of chromosomes remains the same, 2n, but the amount of DNA and therefore the number of chromatids is 4c.

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These two-chromatid chromosomes subsequently enter cell division - mitosis or meiosis.

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What is the genetic perspective on chromosome behavior during mitosis? We will observe two pairs of chromosomes when an individual is a dihybrid Aa Bb.

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Each gene is on a different chromosome pair - gene A is on the green chromosomes, gene B is on the red chromosomes. 

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In the initial cell in the G1 phase, we see a state of 2n and 2c (in our case, a total of 4 chromosomes and 4 chromatids) because the chromosomes are one-chromatid.

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After chromosome duplication, DNA replication occurs, resulting in two-chromatid chromosomes and a state of 2n and 4c (we have 4 chromosomes, but 8 chromatids).

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This cell then enters mitotic division. Mitosis consists of 4 phases.

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In prophase, chromosomes shorten because they condense and thicken to form a compact mass visible in the optical microscope.

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In metaphase, chromosomes align in the equatorial plane and attach to microtubules of the dividing spindle from both sides of the cell's poles.

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We still have a state of 4c, 2n. Because the microtubules of the dividing spindle are attached to the centromere of each specific chromosome from both 

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poles, chromatid separation or segregation of the original chromosome occurs in anaphase, resulting in the formation of two chromosomes with 

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only one chromatid from one chromosome. Thus, the situation is 2c and 2n to one pole of the cell and also 2c and 2n to the other pole.

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After telophase and cytokinesis, we can see two new cells that are genetically identical to each other and to the original mother cell.

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By evenly segregating chromatids, the genetic information is accurately reproduced from one generation of cells to the next.

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This is the main significance of mitosis. This is how our somatic cells divide.

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Meiosis consists of two separate divisions. Before the first meiosis, DNA replication occurs in the S phase. 

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Thus, the cell is again transformed from a state of 2n and 2c to a cell with 2n and 4c. And this cell enters meiosis I.

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Meiosis I is genetically the most important because it involves the main processes related to Mendelian principles of inheritance.

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In prophase I, chromosome condensation occurs as in mitosis. The main difference between mitosis and meiosis I is that pairs of homologous chromosomes 

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are close to each other and form bivalents (2 chromosomes together) or tetrads (4 chromatids together). And because they are close 

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to each other, crossing over can occur. This process will be presented in the lecture on gene linkage. Importantly, they are close to each other,

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so in metaphase, I put them in the equatorial plane of the cell. When we observe two pairs of homologous chromosomes, then there are two possible ways 

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of their arrangement, with a probability of 50 to 50%. In either the right or left cell, microtubules of the dividing spindle connect ONLY to each chromosome from one side.

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This is another fundamental difference between mitosis and meiosis. In our case, in metaphase I, two combinations of chromosome pair arrangements can occur.

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Either one or the other. This state explains Mendel's principle of independent assortment, which Mendel observed in the F2 generation in a dihybrid cross.

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Further, either the right or left cell then enters the next phase of meiosis I, anaphase I. Here, segregation occurs, 

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but due to the attachment of microtubules of the dividing spindle from each pole of the cell only to one chromosome from the pair, the entire chromosomes segregate.

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As a result, haploid cells 1n and 2c are formed at the end of meiosis I because they segregated entire two-chromatid chromosomes.

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This process also explains Mendel's principle of segregation, which he discovered in the analysis of a monohybrid cross. 

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These cells are not yet mature gametes, so they must enter meiosis II. Haploid cells, 1n and 2c, formed by meiosis I,

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pass through prophase II and enter metaphase II, where the chromosomes again align in the equatorial plane. Microtubules of the dividing 

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spindle extend from both sides towards each chromosome. In anaphase II, segregation of sister chromatids occurs. 

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This process is the same as in mitosis. By segregating chromatids in anaphase II, we obtain two new cells at the end of meiosis II,

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which are still haploid 1n but each chromosome carries only 1 DNA in one chromatid, i.e., they are 1c. This is the final product. 

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Haploid cells, 1n and 1c, when fused in fertilization, create a zygote with a 2n and 2c number of chromosomes and DNA.

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So what is the genetic significance of meiosis?


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Meiosis is a process that reduces genetic information by half, so that offspring formed through sexual reproduction have the same amount 

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of genetic material as their parents. Additionally, due to the free combination of chromosomal pairs in metaphase I, 

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diverse gametes are formed in terms of gene combinations. Because these two genes are on different chromosomal pairs, 

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they can freely combine and segregate independently during anaphase I. This creates variability in gametes, and in our case,

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when thousands of dihybrid Aa Bb cells enter meiosis, four types of gametes AB, Ab, aB, and ab are formed in a 1:1:1:1 ratio.

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When we summarize both types of division, the genetic significance of mitosis and meiosis is clear. During mitosis, genetic information

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is transferred from one diploid cell to two new diploid cells, but they are genetically identical. This mainly concerns somatic cells of multicellular organisms.

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On the other hand, the genetic significance of meiosis lies in the fact that due to free combination and segregation,

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 non-identical haploid cells, gametes, are formed, which have great genetic variability.

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Thank you for your attention.