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Mendel’s Law of segregation states than when an organism produces gametes, its two alleles for a trait separate and go into different gametes (sex cells). In this way when gametes from two parents join to produce a new organism, the offspring receives one allele from each parent.
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Mendel’s Law of segregation states than when an organism produces gametes, its two alleles for a trait separate and go into different gametes (sex cells). In this way when gametes from two parents join to produce a new organism, the offspring receives one allele from each parent. A diagram called a Punnett square is useful for finding the results of a simple genetic cross.The parents alleles are written across the top and side of the square. Combining these alleles gives the possible genotypes of the offspring, as shown below. SC.L.16.1 Mendel’s Laws of Segregation and independent assortment to analyze patterns of inheritance.
R: Dominant allele produces round seeds r: Recessive allele produces wrinkled seeds Homozygous (pure) two alleles with the same genetic information RR or rr Heterozygous (hybrid) two alleles with different information Rr Two round seeded plant produced a wrinkled seeded plant because the plant received two recessive alleles for wrinkled seed.
Mendel’s Law of independent assortment states that when gametes are formed, the genes for different traits are inherited separately. In metaphase I, the homologous chromosomes line up along the center of the cell in a random fashion Law of Independent Assortment
SC.L.16.3 describe the basic process of dna replication and how it relates to the transmission and conservation of the genetic information
DNA Animation DNA replication begins at specific point in the DNA molecule called the origin of replication site. The enzyme HELICASE unwinds, and separates a portion of the DNA molecule Single strand binding proteins react with and stabilize the separated, single stranded sections of the DNA molecule. An enzyme called primase assembles an RNA primer at the origin of Replication site. The RNA primer consists of a short sequence of nucleotides complementary to a small, initial section of DNA strand being prepared for replication. DNA polymerase adds DNA nucleotides to the RNA primer and thus begin the process of constructing a new complementary strand of DNA. Later the RNA primer is enzymatic ally removed and replaced with an appropriate sequence of DNA nucleotides. Because the two complementary strands of the DNA molecule are oriented in opposite direction, and the DNA polymerase can accommodate replication in only one direction, two different mechanisms for copying the strands of DNA are employed.
One strand is replicated continuously towards the unwinding, separating portion of the original DNA molecule; while the other strand is replicated discontinuously in the opposite direction with the formation of a series of short DNA segments called Okazaki fragments. Each Okazaki fragment requires a separate RNA primer. As the Okazaki fragments are synthesized, the RNA primer is enzymatic ally removed and replaced with the appropriate sequences o DNA nucleotides. The individual Okazaki fragments are then bonded together into a continuous complementary strand by a DNA ligase, which seals the gaps between the segments. DNA replication results in two identical daughter molecules each consisting of one old (original) strand and one newly-synthesized strand. SUMMARY Separation by Helicase RNA primer binds to template DNA polymerase brings DNA nucleotides DNA ligase seals the gaps between the Okazaki fragments.
An individual’s traits such as hair color and eye color, are determined by proteins. Proteins are made up of chains of amino acids. DNA codes for 20 amino acids. How these amino acids combine determines the shape and purpose of the proteins they form. PROTEIN SYNTHESIS ANIMATION 1 PROTEIN SYNTHESIS ANIMATION 2 The information in an organism DNA is used to make proteins. If two of the base pairs are switched a mutation occurs and a different protein is made. protein Synthesis
Continuation…. II II I I I I II II
Both are forms of cell division. Both begging with diploid cells. Both occur within the nucleus of the cell. Both go through the same steps known as Prophase, Metaphase, Anaphase and Telophase. Both have in common cytokines is (The cytoplasm divides) Similarities between mitosis and meiosis
Mendel’s Law of segregation states than when an organism produces gametes, its two alleles for a trait separate and go into different gametes (sex cells). In this way when gametes from two parents join to produce a new organism, the offspring receives one allele from each parent. A diagram called a Punnett square is useful for finding the results of a simple genetic cross.The parents alleles are written across the top and side of the square. Combining these alleles gives the possible genotypes of the offspring, as shown below. SC.16.1 Mendel’s Laws of Segregation and independent assortment to analyze patterns of inheritance.
R: Dominant allele produces round seeds r: Recessive allele produces wrinkled seeds Homozygous (pure) two alleles with the same genetic information RR or rr Heterozygous (hybrid) two alleles with different information Rr Two round seeded plant produced a wrinkled seeded plant because the plant received two recessive alleles for wrinkled seed.
Mendel’s Law of independent assortment states that when gametes are formed, the genes for different traits are inherited separately. In metaphase I, the homologous chromosomes line up along the center of the cell in a random fashion Law of Independent Assortment