What Is a Multicellular Organism Definition Structure Types and Functions
The cell is the smallest structural and functional unit of an organism. In Latin, the “cella” means the “small room”. The cell is known as the “building blocks of life” and the study of cells is called cytology or cell biology or cellular biology. The cells are made of cytoplasm that consists of nucleic acids and proteins. The dimensions of the cells are about one to 100 micrometres. It was discovered by Robert Hooke in 1665. There are two types of cells, they are prokaryotic and eukaryotic cells. The prokaryotic cells are unicellular organisms that lack a nucleus. The eukaryotic cells are single-celled organisms or multicellular organisms. These eukaryotic cells evolved from a community of prokaryotic cells. The multicellular organisms are formed in various ways such as cell division or by assembling single cells.
The macroscopic multicellular organisms evolved around the world about 600 million years ago. Maoyan Zhu at the Chinese Academy of Sciences located in Nanjing, along with his colleagues has reported that they discovered the well-preserved fossils found in northern China, where the length of these organisms is about 30cm long.
What is a Multicellular Organism?
An organism that consists of two or more cells is called multicellular organisms. All the species of plants, animals, fungi, red algae, green algae, and brown algae are multicellular organisms.
One of the hypotheses that tell about the origin of the multicellular organism is the aggregation of cells that have specific functions into a slug-like mass known as grex combined forms multicellular organisms.
The second hypothesis is that a primitive cell has become a coenocyte by the process of nuclear division. A membrane has been formed around each of these nuclei that resulted in the formation of a number of cells.
The third hypothesis is that a unicellular organism has divided to form two daughter cells in which at a particular stage the daughter cells fail to divide further and these cells develop into a specialized tissue performing different functions. This mainly happens in plant and animal embryos.
The multicellular organisms found at first were simple, didn't have bone, other body parts, or shell and they were not preserved in the fossil records. Now we got to know what a multicellular organism is. Now let us see the evolutionary history of these organisms.
Evolutionary History:
The first evidence obtained for these organisms is from cyanobacteria that lived 3.5 billion years ago.
Loss of multicellularity has occurred in some of the groups of organisms. Fungi are unicellular organisms, but according to early diverging fungi are unicellular organisms. This has also happened in red algae.
The long-living multicellular organisms often face the challenge of cancer. This occurs only when the cells lack the capability of growth in their normal development. Cancer in multicellular organisms led to the loss of multicellularity. As per some researchers, the plant galls are considered tumours, but some researchers argue that the plant bodies do not get affected by cancer.
In some of the multicellular organisms, the separation of the sterile somatic cells and the germ cells has occurred.
Some of the Theories Suggest How Multicellular Cells Evolved:
Symbiotic Theory: Due to the symbiosis of different single-celled organisms that perform different roles the first multicellular organism has formed. But these organisms were dependent on each other; this further led to the incorporation of genomes to form a multicellular organism.
Cellularization Theory: It states that a unicellular organism that has numerous nuclei has developed the partitions by covering each of the nuclei with a membrane. This simple presence of multi nuclei was not sufficient to support the hypothesis.
Colonial Theory: It states that the symbiosis of organisms that belong to the same species has led to the formation of multicellular organisms. It is assumed the land is evolved and the multicellularity has occurred by joining or separating the cells, in some cases the multicellularity occurs when the cells fail to divide further. The main advantage of this theory is that this process of multicellularity has been found in 16 different phyla.
Oxygen Availability Hypothesis: The availability of oxygen on the earth acts as a limiting factor for the formation of multicellular organisms. This hypothesis defines the relationship between the availability of oxygen and the emergence of life.
Snowball Earth Hypothesis: It is a geological event in which the entire Earth has been covered with ice and snow. This theory suggests that the Cryogenian period acts as the catalyst to the formation of complex multicellular life.
Predation Hypothesis: This theory states that in order to get protection from the predators the single-celled organisms have evolved to form multicellular.
Characteristics of Multicellular Organisms
The Characteristics of the Multicellular Organisms are as Follows:
These are complex organisms that are made up of more than one cell.
These organisms are visible to the naked eye.
They are made up of different organs and the organ systems where each of these performs various functions.
They contain membrane-bound organelles as they belong to the eukaryotes.
The size of an organism increases with an increase in the number of cells in the body.
The division of labour takes place in between the cells.
Conclusion
We have learnt what is multicellular, characteristics, and history of these organisms. By this, we got to know that they have the advantages to increase their size without any limitations. Even though the individual cells die they have the capability of living for a longer lifespan. The complexity can be increased by the differentiation of the cells in an organism.
FAQs on Multicellular Organism and Its Biological Organization
1. What is a multicellular organism?
A multicellular organism is a living organism made up of many cells that work together to perform specific functions. Unlike unicellular organisms, these organisms have:
- Specialized cells with different structures and roles
- Organized levels such as tissues, organs, and organ systems
- Division of labor among cells for efficiency
Examples of multicellular organisms include humans, animals, plants, and most fungi.
2. How are multicellular organisms different from unicellular organisms?
The main difference is that multicellular organisms are made of many cells, while unicellular organisms consist of only one cell. Key differences include:
- Cell number: Many cells vs. single cell
- Specialization: Multicellular organisms have specialized cells; unicellular organisms do not
- Complexity: Presence of tissues and organs in multicellular life
- Examples: Humans (multicellular) vs. Amoeba (unicellular)
3. What are examples of multicellular organisms?
Examples of multicellular organisms include organisms composed of many specialized cells organized into tissues and organs. Common examples are:
- Humans and other animals
- Flowering plants such as sunflower and mango
- Fungi like mushrooms
- Most algae (except some unicellular forms)
These organisms show cellular specialization and structural complexity.
4. How do cells in a multicellular organism become specialized?
Cells in a multicellular organism become specialized through a process called cell differentiation. During differentiation:
- All cells start from a single zygote
- Different genes are turned on or off
- Cells develop specific structures and functions
For example, some cells become nerve cells for communication, while others become muscle cells for movement.
5. What are the levels of organization in multicellular organisms?
The levels of organization in multicellular organisms progress from simple to complex structures. These levels are:
- Cell – basic structural and functional unit
- Tissue – group of similar cells performing a function
- Organ – structure made of different tissues
- Organ system – group of organs working together
- Organism – complete living individual
This hierarchy increases efficiency and specialization in complex life forms.
6. Why are multicellular organisms considered more complex?
Multicellular organisms are considered more complex because they have specialized cells organized into tissues and organ systems. Their complexity is due to:
- Division of labor among cells
- Presence of multiple organ systems
- Advanced communication through chemical and electrical signals
This organization allows them to perform sophisticated functions like digestion, circulation, and reproduction.
7. How do multicellular organisms grow?
Multicellular organisms grow primarily by increasing their number of cells through mitosis. Growth involves:
- Repeated cell division
- Increase in cell size
- Cell differentiation for specialized roles
In plants, growth occurs at specific regions called meristems, while in animals it occurs throughout the body during development.
8. Do multicellular organisms reproduce sexually or asexually?
Most multicellular organisms reproduce sexually, but some can also reproduce asexually. The two main modes are:
- Sexual reproduction – involves fusion of male and female gametes, producing genetic variation
- Asexual reproduction – involves one parent, such as budding in Hydra or vegetative propagation in plants
Sexual reproduction is more common in complex animals and plants.
9. What are the advantages of multicellularity?
The main advantages of multicellularity include specialization, increased size, and improved survival. Key benefits are:
- Division of labor among cells
- Ability to develop complex organ systems
- Better adaptation to environments
- Longer lifespan compared to many unicellular organisms
These features enhance efficiency and evolutionary success.
10. How do cells in multicellular organisms communicate with each other?
Cells in multicellular organisms communicate through chemical and direct signaling mechanisms. Major methods include:
- Hormones carried in blood for long-distance signaling
- Neurotransmitters in the nervous system
- Direct cell-to-cell contact via gap junctions (animals) or plasmodesmata (plants)
This communication maintains coordination, homeostasis, and proper functioning of the organism.
