because we need to develop and growth. without cell division, we remain single-celled and we won't grow.
In multicellular organisms, cell division is also required for repair of damaged tissues and for reproduction. It ensures that an organism can continue to grow and develop, as well as maintain its structure and function.
Yes, multicellular organisms grow by increasing the number of cells through cell division and cell growth. Growth in multicellular organisms also involves the increase in overall size and development of different tissues and organs.
cell specialization
The main purpose of cell division in multicellular organisms is growth, repair, and maintenance of tissues. Cell division allows for the production of new cells to replace damaged or worn-out cells, as well as to facilitate growth and development of the organism.
Cell division has three purposes for the organism. The are responsible for the reproduction, growth and maintenance of both single celled and multicellular organisms.
Cell division in multicellular organisms is essential for growth, development, and repair of tissues. It allows the organism to replace old or damaged cells, produce new cells for growth, and maintain a balance between cell loss and cell renewal. Additionally, cell division is necessary for reproduction and passing genetic information to offspring.
Multicellular organisms grow through cell division. A multicellular organism's growth and development start with one cell, which then divides into two cells. The division will continue, with each division increasing by a factor of two.
Multicellular organisms grow through cell division. A multicellular organism's growth and development start with one cell, which then divides into two cells. The division will continue, with each division increasing by a factor of two.
before cell division happens after the old tissues have to be renewed or repaired.
cells in a multicellular organism have the ability to specialize in certain functions for the overall success of the organism. some genes will be expressed in some cells while other genes in other cells. this creates the difference between skin cells versus liver or blood cells. a unicellular organism must cover all the functions of an entire organism and all the necessary genes must be expressed plus all the functions of created and breaking down compounds necessary for growth, development and producing offspring.
Asexual cell division in multicellular organisms is known as mitosis. During mitosis, a parent cell divides into two identical daughter cells, each with the same number of chromosomes as the parent cell. Mitosis is important for growth, development, and replacing damaged or old cells in multicellular organisms.
In multicellular organisms, cell division is also required for repair of damaged tissues and for reproduction. It ensures that an organism can continue to grow and develop, as well as maintain its structure and function.
Yes, multicellular organisms grow by increasing the number of cells through cell division and cell growth. Growth in multicellular organisms also involves the increase in overall size and development of different tissues and organs.
Cell division is the process that plays a key role in the growth and repair of tissue in multicellular organisms. When cells divide, they can increase in number to promote tissue growth or help replace damaged or dead cells during tissue repair.
The main distinction between unicellular and multicellular is the number of cells. Unicellular organisms survive on a single cell while multicellular means that they need a number of cells to survive.
Cell division is called mitosis. It occurs in eukaryotes, or multicellular organisms. It has different stages to ensure that it gets done correctly.
In unicellular organisms, cell division is a form of asexual reproduction, allowing the organism to reproduce offspring. In multicellular organisms, cell division is used for growth, repair, and maintenance of tissues and organs. It plays a crucial role in development, allowing for the formation of complex organisms from a single fertilized egg.