You will need to look up what you see on the transparency and compare it to a drawing of a cell. Obviously we can not see this transparency and therefore can not help.
Endocytosis is a process which allows a cell to engulf molecules in their entirety and surround those molecules in a membrane. Transport is when small molecules can actively transport through a cellular membrane and come out again.
The epidermis on the palms of your hands and soles of your feet has thicker layers of skin cells compared to other parts of the body. This serves to provide extra protection and withstand the friction and pressure these areas experience. In contrast, the epidermis shown in the transparency may have a thinner layer of skin cells due to its location on a different part of the body.
The diagram illustrates a cell membrane with molecules that can freely pass across it. These molecules likely include water, oxygen, and carbon dioxide, which can diffuse across the lipid bilayer. The unequal distribution of molecules inside and outside the cell creates a concentration gradient that drives passive transport.
A plasmid in cloning serves as a vector to carry the foreign DNA fragment and introduce it into a host cell for replication. It provides a replication origin, antibiotic resistance gene, and a cloning site for inserting the DNA of interest.
Passive transport shown in the transparency is diffusion, where molecules move from areas of high concentration to low concentration without the need for energy input.
You will need to look up what you see on the transparency and compare it to a drawing of a cell. Obviously we can not see this transparency and therefore can not help.
Endocytosis is a process which allows a cell to engulf molecules in their entirety and surround those molecules in a membrane. Transport is when small molecules can actively transport through a cellular membrane and come out again.
penis
Facilitated diffusion because carrier proteins are being used.
A linear equation is y = mx + c where m is the gradient and c is the y-intercept. Linear equations are always graphically shown as a straight line, regardless of the gradient or the y-intercept.
A solute pump is typically needed for the active transport of substances against their concentration gradient. This process requires energy, often in the form of ATP. If the substance in question is an ion or a small molecule that must move from an area of lower concentration to higher concentration across the membrane, it would require a solute pump for transport. Examples include sodium (Na+) or potassium (K+) ions.
because the bacteriophage is set to do so
You would need 6 hydrogen atoms to react with the 3 nitrogen atoms shown in the transparency. This is based on the stoichiometric ratio of 2 moles of hydrogen to 1 mole of nitrogen in the formation of ammonia (NH3).
All the muscles shown in the transparency are likely to be skeletal muscles, which are responsible for voluntary movements of the body. They are striated in appearance due to their organized structure of muscle fibers and are attached to bones via tendons. Additionally, these muscles are controlled by the somatic nervous system, allowing for precise movement and coordination.
The sodium-potassium pump is an essential membrane protein that actively transports sodium ions (Na⁺) out of the cell and potassium ions (K⁺) into the cell, both against their concentration gradients. This process requires energy in the form of ATP, as it involves moving ions from areas of lower concentration to areas of higher concentration. By maintaining the appropriate concentrations of these ions, the pump plays a crucial role in cell functions such as maintaining membrane potential and regulating cell volume.
For a molecule or substance to diffuse from the outside of a structure to the inside, there must be a concentration gradient, with a higher concentration outside than inside. Additionally, the structure should have permeable membranes or openings that allow the molecule to pass through. Factors such as temperature, which increases molecular movement, and the size or charge of the molecule relative to the membrane's properties also play a crucial role in facilitating diffusion.