All questions of Biological Classification for ACT Exam

The first major break from the Linnean model came from Thomas Whittaker. In 1969 Whittaker proposed a "five kingdom" system in which three kingdoms were added to the animals and plants: Monera (bacteria), Protista, and Fungi.

Explanation:

Archaebacteria are microorganisms that belong to the domain Archaea. They are prokaryotic organisms, meaning they lack a true nucleus and other membrane-bound organelles that are common in eukaryotic cells. Archaebacteria are known to survive in extreme environmental conditions that would be lethal for most other organisms. This is due to several factors, but the most important one is their rigid cell wall.

Rigid Cell Wall:

Archaebacteria have a unique cell wall composition that is different from that found in other bacteria. Their cell walls are made up of a complex polysaccharide called pseudomurein, which is more resistant to heat, acids, and other harsh environmental conditions than the peptidoglycan found in other bacterial cell walls. This rigid cell wall provides the archaebacteria with a protective barrier that helps them to withstand extreme temperatures, pH levels, and pressures.

Other Factors:

Apart from the rigid cell wall, there are several other factors that contribute to the ability of archaebacteria to survive in extreme environments. These include:

1. Unique metabolic pathways: Archaebacteria have evolved unique metabolic pathways that allow them to extract energy and nutrients from the environment in which they live. These pathways allow them to survive in environments that would be toxic to other organisms.

2. Resistance to radiation: Some archaebacteria are known to be resistant to high levels of radiation, which allows them to survive in environments such as hot springs and deep-sea hydrothermal vents.

3. Adaptability: Archaebacteria are highly adaptable and can adjust their metabolism and other cellular processes in response to changes in their environment. This allows them to survive and thrive in a wide range of conditions.

Conclusion:

In conclusion, archaebacteria can survive in extreme conditions because of their unique cell wall composition, as well as other factors such as their metabolic pathways, radiation resistance, and adaptability. Their ability to survive in extreme environments makes them important models for studying the origin and evolution of life on Earth.

Monera are unicellular and prokaryotic , fungi are multicellular and eukaryotic then bacteria is taken under Monera . and protista are unicellular eukaryotic..

Aids is due to deficiency of T helper cells or T lymphocytes.

• Mushrooms are the commonly known form of Basidiomycetes, called bracket fungi or puffballs.
• They grow in soil, on logs and tree stumps and in living plant bodies as parasites, e.g., rusts and smuts.

**Introduction:**
Prokaryotes are a group of organisms that lack a membrane-bound nucleus and other membrane-bound organelles. They are unicellular organisms that include bacteria and archaea. Prokaryotes have a cell wall that provides structural support and protection. However, there is one group of prokaryotes that is wall-less, known as Mycoplasma.

**Mycoplasma:**
Mycoplasma is a genus of bacteria that belong to the class Mollicutes. They are unique among prokaryotes because they lack a cell wall. Instead, they have a flexible cell membrane that gives them a pleomorphic (varying in shape) appearance. This absence of a cell wall makes Mycoplasma highly adaptable, allowing them to colonize a wide range of environments, including the human body.

**Bacteria:**
Bacteria are prokaryotic microorganisms that have a cell wall made up of peptidoglycan. The cell wall provides shape, protection, and structural support to the bacteria. It helps them withstand changes in osmotic pressure and prevents them from bursting. The cell wall also plays a role in bacterial pathogenesis, as it can interact with the host immune system.

**Cyanobacteria:**
Cyanobacteria, also known as blue-green algae, are a group of photosynthetic prokaryotes. They have a cell wall that contains peptidoglycan and other complex polysaccharides. The cell wall provides them with structural support and protection. Cyanobacteria are capable of oxygenic photosynthesis and are responsible for the production of a significant amount of the Earth's oxygen.

**Slime molds:**
Slime molds are not prokaryotes but rather a type of eukaryotic organism. They belong to the kingdom Protista and are known for their unique life cycle. Slime molds can exist as free-living single-celled amoeboid organisms or as a multicellular mass called a plasmodium. They do not possess a cell wall like prokaryotes or most other eukaryotes.

**Conclusion:**
Among the options given, Mycoplasma is the only wall-less prokaryote. Bacteria and cyanobacteria have cell walls, while slime molds are not prokaryotes. Mycoplasma's lack of a cell wall gives it unique characteristics and allows it to thrive in various environments.

Asexual Reproduction in Fungi by Conidiophores:

Asexual reproduction is a type of reproduction in which offspring arise from a single organism, and inherit the genes of that parent only. Fungi reproduce both sexually and asexually. Asexual reproduction in fungi takes place through conidiophores.

Conidiophores:

Conidiophores are specialized structures that produce conidia or conidiospores. These are asexually produced spores that develop on the surface of the conidiophore. Conidiophores are produced by many different types of fungi, including both molds and yeasts.

How Conidiophores work:

Conidiophores are produced by the mycelium of the fungus. They are typically found in clusters, and can grow to be several millimeters in length. The conidiophore is composed of several cells, including a basal cell, a stalk cell, and a terminal cell. The terminal cell is where the conidia are produced.

The conidia are formed by a process called conidiation. This process involves the development of a small bud on the surface of the terminal cell. As the bud grows, it becomes surrounded by a protective layer of cells, which eventually break apart to release the conidiospore.

Advantages of Asexual Reproduction:

Asexual reproduction has several advantages for fungi. First, it allows for rapid reproduction, since no mating is required. This is particularly important in environments where conditions are favorable for growth, but may not be stable over a long period of time.

Second, asexual reproduction allows for the production of large numbers of offspring that are genetically identical to the parent. This can be advantageous in environments where the parent organism is well adapted to the local conditions, since the offspring will also be well adapted.

Third, asexual reproduction allows for the spread of fungi over long distances, since the conidia can be carried by wind or other means.

Conclusion:

In conclusion, the asexual reproduction in fungi takes place by conidiophores. These specialized structures produce conidia or conidiospores, which are asexually produced spores that develop on the surface of the conidiophore. This type of reproduction has several advantages for fungi, including rapid reproduction, large numbers of offspring, and the ability to spread over long distances.

Virus means VENOM or POISONOUS FLUID.(11th ncert page no 26.3rd line)

Blue green algae

Thermoacidophiles are the bacteria that survives in hot springs because of branched chain lipids in the cell membranes
the primitive prokaryotes responsible for the production of biogas from the dung of ruminant animals include the methanogens
halophiles are the bacteria that can live in the saline habitats

Binary fission ("division in half") is a kind of asexual reproduction. It is the most common form of reproduction in prokaryotes such as bacteria. It occurs in some single-celled Eukaryotes like the Amoeba and the Paramoecium. In binary fission DNA replication and segregation occur simultaneously.

HIV attack and destroy T4 - lymphocytes also known as CD4 cells, are white blood cells that fight infection and play an important role in your immune system. If too many CD4 cells are lost, your immune system will have trouble fighting off infections. Even a minor infection such as cold can be much more severe because the body has difficulty responding to new infections.

Tobacco mosaic virus (TMV) is a positive-sense single stranded RNA virus, genus tobamovirus that infects a wide range of plants, especially tobacco and other members of the family Solanaceae. The infection causes characteristic patterns, such as "mosaic"-like mottling and discoloration on the leaves (hence the name).

Unicellular vs Multicellular

Unicellular organisms are those that are composed of a single cell, while multicellular organisms are those that are made up of multiple cells.

Algae

Algae are a diverse group of aquatic organisms that can be found in a variety of environments, from freshwater to saltwater. They can be either unicellular or multicellular, depending on the species.

Plantae

Plants, which belong to the kingdom Plantae, are multicellular organisms that are capable of photosynthesis. They are made up of a variety of specialized cells that work together to carry out the functions necessary for growth and survival.

Protozoa

Protozoa are a group of unicellular eukaryotic organisms that are found in a variety of environments, including water, soil, and the digestive tracts of animals. They are capable of a wide range of metabolic activities, including photosynthesis, and are an important part of many ecosystems.

Animalia

Animals, which belong to the kingdom Animalia, are multicellular organisms that are capable of movement and are characterized by a wide range of specialized tissues and organs. They are found in a variety of environments, from the depths of the ocean to the highest mountains.

Why is the answer A?

The answer to this question is A because algae can be either unicellular or multicellular. Some species of algae, such as Chlamydomonas, are unicellular, while others, such as kelp, are multicellular. Therefore, it is not possible to make a clear distinction between unicellular and multicellular when it comes to algae.

Arranging organisms on the basis of their shared similar or derived characters that differ from ancestral characters, will produce a phylogenetic tree called cladogram. Depending upon the type of system of classification, organisms are classified into two kingdoms or three kingdoms, four kingdoms, five kingdoms and now into six kingdoms.

Conidia is a sexual spores in ascomycetes which are produced exogenously on conidiophores :)

Coenocytic means sharing of common cytoplasm. This term is commonly used to describe a type of cell or organism that does not have distinct cell boundaries or compartments. Instead, coenocytic cells contain multiple nuclei within a single, continuous cytoplasmic mass.

Explanation:
Coenocytic cells are typically found in fungi, algae, and some types of plants. In these organisms, individual cells may fuse together during development to form a single, multinucleate cell. This single cell may then develop into a larger structure or organism, such as a fungus or alga.

Some key characteristics of coenocytic cells include:

- Lack of cell walls: Coenocytic cells do not have distinct cell walls separating them from neighboring cells. Instead, they are connected by a network of cytoplasmic strands.
- Multiple nuclei: Because coenocytic cells contain multiple nuclei within a single cytoplasmic mass, they are often referred to as multinucleate.
- Large size: Without the constraints of cell walls, coenocytic cells can grow to very large sizes. Some fungi, for example, can form structures that are many meters in length.

Overall, the term "coenocytic" refers to a unique type of cell organization that is characterized by the sharing of cytoplasmic material between multiple nuclei.

A capsid is the protein shell of a virus. It consists of several oligomeric structural subunits made of protein called protomers. The observable 3-dimensional morphological subunits, which may or may not correspond to individual proteins, are called capsomeres. The capsid encloses the genetic material of the virus.

Rhizopus belongs to Phycomycetes :)

A B C all are incorrect...
The question should be which is correct.so the answer should be D.
because if we go by this question 3 answers will be correct.

Non motile spore in phycomycetes is aplanospores

DNA and RNA are the genetic materials out of which DNA universally serves as the carrier of hereditary information from one generation to another in all the organisms except viruses. Among viruses, some carry DNA (either single or double stranded) as hereditary material while some have RNA (either single or double stranded) as hereditary material. But they never have both DNA and RNA. Bacteriophages are DNA viruses thus they resemble fungi in having DNA as herditary material.

Viruses

A virus is a microscopic infectious agent that replicates only inside the living cells of an organism. Viruses are not living organisms as they cannot reproduce or carry out metabolic activities outside a host cell.

Incorrect statement:

C) Viruses can perform all of their metabolic activities except reproduction when outside a living host.

Explanation:

Viruses are not capable of performing any metabolic activities outside a living host cell. They cannot carry out functions such as respiration, digestion, or synthesis of proteins or nucleic acids. The only function they can carry out outside a host cell is attaching to and infecting a host cell.

Correct statements:

A) Viruses are acellular.
B) Viruses are smaller than bacterium.
D) Viruses are non-living organisms.

Explanation:

A) Viruses are acellular, which means they do not have a cellular structure and do not contain any organelles such as mitochondria, ribosomes, or nucleus.

B) Viruses are smaller than bacteria. Bacteria are typically between 0.5 and 5 micrometers in size, while viruses are usually between 20 and 300 nanometers in size.

D) Viruses are non-living organisms as they do not have the properties of living organisms such as metabolism, growth, or reproduction outside a host cell. They cannot maintain homeostasis, respond to stimuli or evolve.

Cyanobacteria and Heterocysts

Cyanobacteria, also known as blue-green algae, are a group of prokaryotic organisms that are found in various aquatic and terrestrial environments. They are photosynthetic and use sunlight to produce energy and organic compounds.

Heterocysts are specialized cells that some cyanobacteria have. They are able to fix atmospheric nitrogen into a form that can be used by the cell. Heterocysts are important for cyanobacteria because, unlike other organisms, they cannot take up nitrogen from the soil. Therefore, they need to be able to produce their own nitrogen.

The incorrect statement about cyanobacteria is option B, which states that they lack heterocysts. In fact, some cyanobacteria do have heterocysts, which are specialized cells that are able to fix atmospheric nitrogen. However, not all cyanobacteria have heterocysts.

Therefore, the correct statement about cyanobacteria is:
- They are photoautotrophs, meaning they use sunlight to produce energy and organic compounds.
- They often form blooms in polluted water bodies, which can be harmful to other organisms in the ecosystem.
- They have chlorophyll A similar to green plants, which allows them to capture sunlight for photosynthesis.
- Some cyanobacteria have heterocysts, specialized cells that are able to fix atmospheric nitrogen.

Extreme Saline Conditions and Organisms

Extreme saline conditions refer to environments that have high levels of salt concentration, such as salt pans, salt lakes, and salt marshes. These environments pose significant challenges for most organisms due to the osmotic stress caused by the high salt concentration. However, some organisms have adapted to these extreme conditions and can thrive in saline habitats. One group of organisms that is well-suited to extreme saline conditions is the Archaebacteria.

Archaebacteria and Extreme Saline Conditions

Archaebacteria, also known as Archaea, are a group of single-celled microorganisms that are distinct from both eubacteria and eukaryotes. They are known for their ability to inhabit extreme environments, including high-temperature areas, acidic environments, and saline habitats. Archaebacteria that can be found in extreme saline conditions belong to the halophile category.

Adaptations of Halophilic Archaebacteria

Halophilic Archaebacteria have several adaptations that allow them to survive in extreme saline conditions:

1. Compatible Solutes: Halophiles produce or accumulate compatible solutes, such as potassium ions, amino acids, and polyols, to balance the osmotic pressure and prevent water loss. These compatible solutes help maintain the cell's internal water content and protect essential cellular structures.

2. Pigments: Some halophiles produce pigments, such as bacteriorhodopsin, which are involved in energy generation through photosynthesis or light-driven ion pumps. These pigments enable halophiles to utilize light as an additional energy source in saline environments.

3. Cell Membrane Adaptations: The cell membranes of halophiles have unique lipid compositions that help maintain membrane integrity and function in high salt concentrations. These adaptations include increased levels of branched-chain fatty acids and ether-linked lipids.

4. Enzyme Adaptations: Halophilic enzymes have adapted to function in high salt concentrations by having a higher number of acidic amino acids on their surfaces. This allows the enzymes to maintain their structural stability and activity in saline environments.

Conclusion

In conclusion, among the organisms listed, only the Archaebacteria (option B) can be found in extreme saline conditions. Archaebacteria, specifically the halophilic group, have evolved various adaptations to survive in high salt environments, including the production of compatible solutes, unique cell membrane compositions, and specialized enzymes. These adaptations allow halophiles to maintain cellular homeostasis, protect essential cellular structures, and utilize light as an additional energy source.

On the basis of their energy source, organisms are classified as organotrophic and lithotrophs. Most prokaryotes and all non-phototrophic eukaryotes use organic compounds as their energy source and thus, are referred to as organotrophs. They oxidise organic compounds during cellular respiration and the produced oxygen as a byproduct. But some Cyanobacteria and Archaea use inorganic compounds as an electron donor in electron transport chain and are referred to as lithotrophs, none of the eukaryotes falls in this category. Virus act as non-living outside the cell. It becomes active when it enters the host cell and derives the cellular protein from the host.

Because it requires host macheinary for living state