Answer: A -endomorphs
Endomorphs usually have a shorter build and they gain fat very easily. Thus endomorphs are short and stout. They have very heavy arms. They have strong muscles in the upper leg.
Answer:
The correct answer is option A, Endomorphs
Explanation:
There are three body types in human beings and the characteristics features of all three body types is as follows:
1. Ectomorph - Skinny appearance, Small chest, joints, bones and buttocks, Less body fat (without exercising), long limbs and Gains weight (build muscles) with difficulty
2. Mesomosph - Heavy body, Strong build, Gains muscles and fat easily, have Athletic body of rectangular shape
3. Endomorph – Soft and round body, short limbs, Gains muscles and fat easily
Thus considering the features of all three body types, it is clear that Endomorphs are short and stout
Answer:
The correct answer in this case is the first option archaea.
Explanation:
Hello!
Let's solve this!
Within the domains, that of Bacteria and that of Arqueas are very similar, since both group prokaryotic unicellular organisms. One of the differences is that one of the domains has organisms with a cell wall with peptidoglycan and the other domain does not.
The domain, and the correct answer in this case is the first option archaea
Archaea, also known as archaebacteria, are unicellular prokaryotes that do not contain peptidoglycan in their cell walls. They differ from Eubacteria, which do contain peptidoglycan. Eukarya, on the other hand, contains all eukaryotic cells.
The domain that is composed of unicellular prokaryotes that have cell walls that do not contain peptidoglycan is
Archaea (or archaebacteria). Unlike Eubacteria, the other major group of prokaryotes, the cell walls of Archaea do not contain peptidoglycan. Each of these domains, Archaea, Eubacteria, and Eukarya, represent a major category of life. It's worth noting that Eukarya contains all organisms with eukaryotic cells, including humans, animals, plants, and fungi.
Archaebacteria are known for surviving in extreme environments, such as hot springs or salt lakes.
#SPJ6
Answer:
The correct answer is- Synthesis(S) phase
Explanation:
Interphase is the phase where cells spend most of their time. It is known as the resting phase and contains 3 stages called G1, S, and G2 phase. In G1 phase cells grow in size and produce those enzymes which are required for DNA replication.
In the synthesis phase, the DNA is replicated and gets doubled. This event is very important in the cell cycle because it allows each cell produced after cell division to take an equal amount of genetic material which is identical. Therefore in the cell cycle DNA replication occurs in the synthesis phase.
Answer: lots of words >_>
Explanation:
The osmolarity of a liquid solution can change after a red blood cell is added due to processes involving changes in concentration. Here is a step-by-step explanation of these processes:
1. When a red blood cell is added to a liquid solution, it will attempt to reach equilibrium with its surroundings. Red blood cells are surrounded by a semipermeable membrane that allows certain substances to pass through while restricting others.
2. If the concentration of solutes (such as ions or molecules) in the liquid solution is higher than that inside the red blood cell, water will move from an area of lower solute concentration (inside the cell) to an area of higher solute concentration (the solution) through osmosis.
3. This movement of water from inside the red blood cell to the solution will cause the cell to shrink, leading to a decrease in the osmolarity of the solution. The solute concentration in the solution increases as water leaves the cell.
4. On the other hand, if the concentration of solutes in the liquid solution is lower than that inside the red blood cell, water will move from the solution into the cell, causing it to swell. This leads to an increase in the osmolarity of the solution since the solute concentration decreases as water enters the cell.
5. The extent of the change in osmolarity depends on the initial concentrations of solutes in the solution and inside the red blood cell. If the concentrations are similar, there may be little to no change in osmolarity.
In summary, when a red blood cell is added to a liquid solution, the osmolarity of the solution can change due to the movement of water through osmosis. Water moves from areas of lower solute concentration to higher solute concentration, resulting in either the shrinking or swelling of the red blood cell and a corresponding change in the concentration of solutes in the solution.
hope this helps :D