Homologous chromosomes are two similar chromosomes that an individual inherits from their parents. They contain identical gene segments in the same locations, determining specific characteristics or traits. For an example, different gene sequences in these chromosomes determine a trait like human blood type.
Two similar chromosomes you inherit from your parents are called homologous chromosomes. These matched pairs of chromosomes within a diploid organism are the same length and have specific nucleotide segments, called genes, at the same location. These genes, which are found on the homologous chromosomes, determine specific characteristics by coding for specific proteins, also known as traits.
One chromosome of a homologous pair is inherited from each parent. For instance, human blood type, a certain trait, is determined by three possible gene sequences (A, B, O) that can be found on these chromosomes.
#SPJ6
a lipid bilayer
b. semi-permeable
c. lack of compartmentalization
d embedded proteins
Answer:
lipidbilayer
Explanation:
phagocytes
complement
antibodies
An antibody is a protein that reacts against an antigen in an organism it would be the best to use as a model for the pill’s function.
They are used by the immune system to recognize and block viruses, bacteria, parasites or fungi.
Each type of antibody defends the body against a specific class of antigen and is made up of basic structural units that have four chains: two light and two heavy.
Therefore, we can conclude that an antibody is a protein that reacts against an antigen in an organism it would be the best to use as a model for the pill’s function.
Learn more about antibodies here: brainly.com/question/22543460
Answer:
antibodies
Explanation:
just took the test and got 100%
binary fission
conjugation
spore formation
chlorine
sulfur
Phosphorus is a key component of the energy molecule ATP.
ATP stands for adenosine triphosphate, and it is a molecule that carries energy within cells.
The energy is stored in the phosphate bonds of ATP, and when these bonds are broken, energy is released for cellular processes such as muscle contractions, protein synthesis, and nerve impulses. The phosphorus atom is what makes the phosphate bond in ATP so high in energy, and this is what allows ATP to be such an effective energy carrier within cells.
The phosphate groups are linked by high-energy bonds, and when these bonds are broken, energy is released that can be used for various cellular processes.
The breakdown of ATP into ADP (adenosine diphosphate) and inorganic phosphate releases energy, while the formation of ATP from ADP and phosphate requires energy. The energy stored in ATP is used for various cellular processes such as muscle contraction, protein synthesis, and active transport across cell membranes.
Learn more about ATP at:
#SPJ7
D- All of the above I think