Five mitotic divisions are required to form 32 cells from a single cell.
How many generations are required to produce 32 cells?
5 successive generations of mitosis must occur to produce 32 cells.
How many mitotic divisions and number of generations respectively are required to form 32 cells from a cell?
For a single cell to produce 32 cells, 31 mitotic divisions are required. From the first cell, 2 cells are produced (1 mitotic division). Then these 2 cells are divided into 4 cells (2 mitotic division). Then from these 4 cells, by mitosis, 8 cells are produced (4 mitotic division).
How many times a cell will have to divide Mitotically?
Complete answer: The cell will have to divide 7 times mitotically, to form 128 cells. The number of times a cell will have to divide mitotically is calculated by the formula 2n, where n is the number of times the cell is dividing.
How many number of generations are required to produce 32 cells from the two cells by mitotic division?
1-2-4-8-16-32-64-128 so total 7 generation req. Since Mitosis is an equational division process and it produces two daughter cells from the single parent cells. Clearly, the formula (2)^n would answer the number of cells produced, where n would be the number of divisions.
How many generations are required to produce 256 cells?
Every mitotic division will lead to the formation of twice the number of mother cells, hence to form 256 cells from a root tip cell, 8 generations of mitotic divisions must occur (28=256 cells).
How many generations of mitosis are required to produce 64 cells from one cell?
How many mitotic division and generation respectively are required to form 64 cells from a cell? 1 6,6.
How many mitotic divisions are needed for 100 cells?
Number of generations (n) of mitosis for producing ‘x’ cells is 2^n. First formula is used when the question is saying “Find the number of mitotic divisions required to produce say 100 cells” so for example, to produce 100 cells, 100-1 = 99 mitosis are required.
How many mitotic divisions are needed for a single cell?
Mitosis is an equational division where after division each cell produces two daughter cells, therefore after 7 divisions one cell will give 128 cells in case of mitosis.
How many times mitotic divisions are needed for a single cell to make 128 cells?
Hence 7 mitotic divisions cell needed for a single cell to make 128 cells.
How many cells will be produced if a cell divides mitotically 6 times?
12 cells can be formed if cell divide by 6 times through mitosis process.
How many times a cell will have to divide mitotically to form 256 cells?
Mitotic cells division is equational division where a mother cell divides to form 2 daughter cells. So to produce 256 cells from a single cell, 8 mitotic divisions will occur which can be represented as 1→2→4→8→16→64→128→256.
How many times a cell can divide?
The Hayflick Limit is a concept that helps to explain the mechanisms behind cellular aging. The concept states that a normal human cell can only replicate and divide forty to sixty times before it cannot divide anymore, and will break down by programmed cell death or apoptosis.
How many meiotic divisions are necessary for formation of 80 sperms?
Answer: The number of ‘meiotic divisions’ that are necessary for the production of 80 sperms is 20. Explanation: During the process of spermatogenesis, the haploid sperms are produced by the meiotic division that occurs.
How many meiotic divisions are required to produce?
The meiotic division is involved in the formation of the two types of gametes in an organism, one male gamete, and the other female gamete. The formation of the male gamete requires only one meiotic division which results in four male gametes while the formation of four female gametes requires four meiotic divisions.
How many Meiosiss are needed for 50 seeds?
Thus, in order to produce 50 mature ovules, 50 megaspore mother cells will undergo 50 meiotic divisions, one meiosis per megaspore mother cell. This takes the requirement of 50 (in megaspore mother cells) + 13 (in microspore mother cells), i.e., 63 meiotic divisions.