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Biological Processes

Have you ever wondered how you stay alive? How do you know when to eat? How does your body digests food? Well, there are natural processes that occur in our bodies daily. 

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Biological Processes

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Have you ever wondered how you stay alive? How do you know when to eat? How does your body digests food? Well, there are natural processes that occur in our bodies daily.

A big part of your daily processes may include waking up to your alarm clock, showering, brushing your teeth, eating breakfast, and putting on your clothes for the day. All these steps help you be confident and achieve the best.

Similarly, our Cells have biological processes to help them stay alive and function properly.

  • We will cover biological processes and their examples in humans, Plants, and microbes.
  • We will also discuss how these processes are related to the carbon cycle.

The Meaning of Biological Processes

Each organism can regulate its biological processes, such as growth, nutrition, and breathing patterns. In biology, the method of intaking necessary nutrients from food is called assimilation. We "assimilate" our food through physical (chewing) or chemical (Proteins such as Enzymes and stomach acids) means.

Biological processes are processes that take place in a living organism that are essential and influence how an organism interacts with its surroundings. All living organisms share many biological processes. These natural processes allow us to reproduce, move around, and react to our environment.

Proteins are organic compounds that perform significant roles in the body, such as speeding up reactions (Enzymes), helping the Immune System function (Antibodies), hormone protection, and even serving as energy for the Cells.

Autotrophs, like Plants, "assimilate" their nutrients through Photosynthesis or other inorganic resources. Photosynthesis is a biological process by which Plants use light energy to convert carbon dioxide and water into glucose. Glucose is a simple sugar or carbohydrate that consumers or Heterotrophs can use for chemical energy.

Heterotrophs, like us humans, "assimilate" our nutrients through cellular Respiration. Cellular respiration is the process by which glucose is converted into ATP. ATP, or adenosine phosphate, is an organic compound that gives cells a usable form of energy.

Organic compounds are chemical compounds comprised of carbons bonded to elements, such as hydrogen, oxygen, and nitrogen. Carbon is vital to life because it can quickly form bonds with many other elements, allowing it to be the building block of Macromolecules.

Macromolecules are giant molecules that are formed when smaller molecules bond together.

Biological Processes - Examples

There are many examples of biological processes all around us. Many of these processes occur both inside and outside of your body. Homeostasis, organization, metabolism, Response to Stimuli, Reproduction, and interaction between organisms are all examples of biological processes. Let’s look at two processes you may already be familiar with.

Homeostasis is how our bodies regulate the internal environment to maintain a constant state. This depends on a Negative Feedback loop that triggers a response when our internal environment goes through too much change. One tangible example of this regulation would be sweating. When the core temperature of our bodies rises too high, a signal is sent to your sweat glands to activate. When the sweat evaporates, our skin, and the Blood flowing through it, are cooled and bring down the body's temperature.

Another example of homeostasis would be our bodies' maintenance of Blood glucose levels. Insulin and glucagon are the controllers of our Blood glucose level. After eating, our body produces insulin which will lower Blood glucose levels. When we haven’t eaten for a while, our body produces glucagon, which raises Blood glucose levels. Diabetes is a disease that occurs when this feedback loop is broken in the form of poor Insulin secretion, causing blood glucose levels to spike.

The last example we’ll cover is Reproduction. Every living organism on this planet results from the reproductive process, whether it be sexual or asexual reproduction. Asexual reproduction is when an organism makes a clone or a very similar version of itself without sexual reproduction with another organism. Sexual reproduction occurs when two compatible organisms unite and create a fertilized zygote. This zygote is the offspring of the parents and will carry the genetic material of both parent organisms.

Microbial Biological Processes

Microbial biological processes are processes that microbes need to survive or stay alive. Aerobic bacteria need oxygen to survive, while anaerobic bacteria that do not. There are also facultative anaerobe bacteria that would ideally prefer to grow in the presence of oxygen but don’t require it to survive.

Bacteria can also be grouped by how they obtain nutrients:

Heterotrophs are consumers that receive energy from breaking down complex organic compounds. Examples of heterotrophic bacteria include decomposers and bacteria that rely on aerobic or anaerobic Respiration and fermentation.

Decomposers, or detritivores, are organisms, such as Fungi and bacteria, that break down dead organisms.

Autotrophs are producers that make their energy or nutrients from inorganic sources. Examples of autotrophs are photoautotrophs, which receive their nutrients from light energy, and chemoautotrophs, which receive nutrients from the oxidation of inorganic compounds.

We'll cover photoautotrophs in more detail in the section called "biological processes in plants." As for chemoautotrophs, some of the most important examples are nitrogen-fixing bacteria, which are bacteria involved in the nitrogen cycle.

Nitrogen is essential for living organisms, as it's in the structures of proteins and nucleic acids, such as DNA. DNA, or deoxyribonucleic acid, is the genetic material of living organisms. Nitrogen is also essential as it's considered a limiting nutrient.

Limiting nutrients are nutrients necessary for growth and development of living organisms that are in low supply in the environment. This means that the lack of these limiting nutrients, such as nitrogen, can prevent or limit further growth in ecosystems.

Bacteria play crucial roles in the nitrogen cycle because, even though other living organisms need it, they cannot convert nitrogen gas, or \((N_2\)), into a form that is useful to us.

The stages of the nitrogen cycle are illustrated in Figure 1:

  1. Nitrogen fixation: nitrogen gas or atmospheric nitrogen \((N_2\)) is transformed into ammonia \((NH_3)\) by nitrogen-fixing bacteria such as Rhizobium. Ammonia is a usable form of nitrogen that is fixed in the soil or aquatic environments usually.

  2. Nitrification: During nitrification, ammonia is transformed into nitrite \((NO_{2}^-\)) and then nitrate \((NO_{3}^-\)) by soil bacteria such as Nitrosomonas. This is because ammonia is toxic to plants and other organisms.

  3. Assimilation: During assimilation, plants, fungi, and specific bacteria assimilate or take in mainly nitrate \((NO_{3}^-\)) from the soil. They can sometimes also take in ammonium \((NH_{4}^+)\). Animals get nitrogen into their bodies by consuming organisms such as plants, making them heterotrophs.

  4. Ammonification: Ammonification is the process by which decomposers break down dead organisms such as plants and animals. This process results in ammonium \((NH_{4}^+)\) and ammonia \((NH_3)\).

  5. Denitrification: During denitrification, nitrate and nitrite are usually converted into nitrogen gas or \((N_2\)). This allows nitrogen to return to the atmosphere. Hence making the process of acquiring nitrogen a cycle.

Biological Processes Nitrogen Cycle Study SmarterFigure 1: Nitrogen cycle illustrated. Wikimedia, EPA.

Biological Processes - The Carbon Cycle

The nitrogen cycle isn't the only important cycle necessary for our survival. Another biological cycle that's vital is the carbon cycle.

The carbon cycle is the process by which carbon compounds are circulated and exchanged by our atmosphere and earth.

The carbon cycle is essential as it controls the earth's temperature, makes up vital macromolecules like Carbohydrates, and involves crucial biological processes, such as Photosynthesis and cellular respiration.

The carbon cycle can control the earth's temperature through greenhouse gases.

Greenhouse gases are gases in the earth's atmosphere that trap heat, much like the glass windows in a greenhouse.

Carbon dioxide \((CO_2)\) is a significant greenhouse gas, and carbon burning produces it. Without greenhouse gases, our earth would lack warmth and be frozen.

The stages of the carbon cycle are:

  1. Plants take in carbon in the atmosphere through photosynthesis. We will go over photosynthesis in the next section.

  2. Animals consume the plants causing the carbon to move from plants to Animals.

  3. When plants and animals die, they decompose, causing carbon to be let back into the atmosphere. Living organisms can also release carbon into the atmosphere through cellular respiration.

  4. Carbon not released into the atmosphere becomes fossil fuels. This is why carbon gets released into the atmosphere when fossil fuels are burnt. The excessive burning of fossil fuels for energy has resulted in global warming.

  5. The ocean absorbs carbon from the atmosphere, acting as a carbon sink. This causes the carbon to dissolve in the water.

  6. Carbon can also be released into the ocean by weathering rocks. Carbon is usually removed from ocean water when limestone settles on the ocean floor. The limestone comes from marine animal shells and bones. This carbon can be released into the atmosphere usually once the limestone melts.

Figure 2 shows how the carbon cycle works and how much carbon is exchanged. The carbon flux or amounts of carbon exchanged are usually measured in units of gigatons per year or GtC/yr.

Biological Processes Carbon Cycle Study Smarter

Figure 2: Carbon cycle illustrated. Wikimedia, NASA.

Biological Processes in Plants

Plants have their own set of biological processes and some of which they also share with us. Some primary procedures are growth and development, photosynthesis, respiration, and Transpiration.

Photosynthesis is the process by which plants absorb light energy from the sun and convert it to chemical energy through cellular respiration.

Photosynthesis is a crucial process, as it releases oxygen as a byproduct. Around 50% to 80% of the world's oxygen, which we breathe, comes from oceanic phytoplankton and marine plants. Although land plants also produce oxygen; for instance, rainforests make around 28% of the world's oxygen.

The green plants not located in water are called land plants or embryophytes. They are terrestrial plants and the plants we think about when we think of plants. Angiosperms, or flowering plants, are the most common land plants. They consist of plants like roses, orchids, daisies, etc.

Marine plants and phytoplankton are distributed over a larger surface area than land plants simply because the ocean covers around 70% of our surface on earth compared to land.

Plants are essential because they provide energy and oxygen to consumers like us. This means that their survival is essential to us. For plants to flourish, they need to be able to grow and develop.

The general process for growth and development in plants is embryogenesis, Seed Germination, the vegetative stage, the reproductive stage, and the ripening stages.

Embryogenesis is the step that occurs right after fertilization and results in a plant embryo or young plant.

All seeds contain embryos located inside them, and a hard covering called a seed coat protects them.

Seed Germination deals with seed sprouting and occurs when there are favorable light, heat, and water conditions.

  • The vegetative stage involves the growth of stems, leaves, and roots. During the vegetative stage, plants also undergo photosynthesis to obtain resources to be ready for the next step.

  • The reproductive stage occurs when the plant matures and is prepared to make flowers and fruits.

  • The flowering stage is when plants are usually pollinated.

  • Ripening is the stage in which vegetables or fruits grow or ripen. They produce these fruits, so animals can eat them and distribute its seed so that the cycle can start over again.

  • Transpiration is the process by which water travels through a plant and evaporates from stems, flowers, and leaves.

Biological Processes - Key takeaways

  • Biological processes are essential processes in a living organism that influence how an organism can interact with its surroundings.
  • Biological processes are essential because organisms like us need them to survive. All of us living organisms share many biological processes.
  • These natural processes allow us to reproduce, move around, and react to our environment.
  • Many of the biological processes occur both inside and outside of your body. Homeostasis, organization, metabolism, and interaction between organisms are all examples of biological processes.
  • Biological processes can also be found in all living organisms, including microbes and Fungi.

References

  1. https://www.sciencedirect.com/topics/earth-and-planetary-sciences/biological-process
  2. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6773238/
  3. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6515536/
  4. https://www.sciencedirect.com/topics/earth-and-planetary-sciences/nitrogen-cycle
  5. https://scied.ucar.edu/learning-zone/earth-system/biogeochemical-cycles

Frequently Asked Questions about Biological Processes

Biological processes are processes that take place in a living organism that are essential and influence how an organism can interact with its surroundings. 


Some critical biological processes are reproduction, metabolism, organization, and homeostasis.

Microbial biological processes are processes that microbes need to survive or stay alive.  

Two of the most important biological processes in the carbon cycle are photosynthesis and cellular respiration. This is because they are the primary processes involved in recycling carbon. 

Plants have their own set of biological processes and some of which they also share with us. Some primary procedures are growth and development, photosynthesis, respiration, and transpiration.

Final Biological Processes Quiz

Biological Processes Quiz - Teste dein Wissen

Question

Describe the components of an amino acid.

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Answer

An amino acid is a group of organic molecules with an amino group (-NH2), a carboxyl group (-COOH), and a side chain (called R group) unique to every amino acid. Each amino acid molecule has a central carbon C atom to which the amino and carboxyl groups are attached. 

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Question

Amino acids are the building blocks of ___.

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Answer

proteins

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Question

What does metabolism mean?

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Answer

Metabolism refers to the chemical reactions that take place in living organisms to provide energy for life-sustaining processes and to synthesize new organic materials. 

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Question

What is amino acid metabolism?

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Answer

Amino acid metabolism refers to the sum of all chemical reactions in which amino acid is broken down and synthesized for vital processes in the body.     

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Question

Amino acids that are not synthesized in the body are called __.

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Answer

essential amino acids

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Amino acids that are not needed in our diet are called __.

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Answer

non-essential amino acids

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Question

Do plants need to take in amino acids like humans do? Why or why not?

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Answer

Unlike humans, plants can synthesize all 20 amino acids themselves.

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Cellular ____ are constantly being partially drained and refilled as the body synthesizes and degrades proteins. 

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Answer

amino acid pools

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The replacement of older proteins as they degrade within the cell is referred to as ___

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protein turnover

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Once proteins have been broken down, free amino acids combine with the _____ amino acids produced in the liver and those recycled from the body’s own proteins, forming the amino acid pool.

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non-essential

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In what ways are free amino acids used by the body?

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Answer

They can be used in synthesizing protein and other nitrogen-containing compounds like nucleotide bases, neurotransmitters, and hormones. The carbon skeletons of amino acids can also be oxidized then utilized as an energy source or used for glucose synthesis during hypoglycemia.


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Question

The nitrogen in amino acid carbon skeletons that were oxidized for energy or converted to glucose are then excreted in the urine in the form of ___.

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Answer

urea

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Question

Are excess proteins and amino acids stored in the human body? Why or why not? 

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Answer

Unlike fats and carbohydrates, there is no dedicated storage of proteins and amino acids in the human body. If not used for biological processes, excess amino acids in the body are typically degraded and the nitrogen expelled as urea. However, the body can conserve protein when in a state of nutrient deficiency or withdrawal. 

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Amino acid metabolism often begins with a ____ reaction.

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transamination

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Amino acids can be classified as either ____ based on the pathways involved in their degradation.

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glucogenic or ketogenic

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______ are those whose carbon skeletons are converted into pyruvate, succinyl-CoA, 2-oxoglutarate, fumarate, and oxaloacetate which are intermediates in the glycolysis pathway.

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Answer

Glucogenic amino acids

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____ are those whose carbon skeletons are converted into acetyl-CoA or acetoacetate which are used to produce fatty acids or ketone bodies.

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Ketogenic amino acids

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____ are special types of proteins that catalyze or accelerate biochemical reactions.

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Answer

Enzymes

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A chain of enzymes can catalyze a series of reactions called ____ to synthesize or breakdown complex biological molecules. 

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pathways

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What are amino acid disorders?

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Amino Acid Disorders (AAs) are diseases that hinder the degradation of some amino acids due to dysfunctional enzymes. 

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What are biological processes?

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Biological processes are processes that take place in a living organism that are essential and influence how an organism can interact with its surroundings. 

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Why are biological processes essential?

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Answer

Biological processes are essential because organisms like us need them to survive. All of us living organisms share many biological processes. These natural processes allow us to

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Question

What is assimilation and why is it important?

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Answer

The method of intaking necessary nutrients from food is called assimilation in biology.

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Why is carbon essential to life? 

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Answer

Carbon is vital to life because it can quickly form bonds with many other elements allowing it to be building blocks for macromolecules. 

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What are examples of biological processes in humans?

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Answer

homeostasis

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What are examples of microbial biological processes?

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nitrogen fixation

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How can carbon be released into the atmosphere? 

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When plants and animals die, they decompose, causing carbon to be let back into the atmosphere. 

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How can carbon be absorbed from the atmosphere?

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Answer

Photosynthesis

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What is the carbon cycle?

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The carbon cycle is the process by which carbon compounds are circulated and exchanged by our atmosphere and earth. 


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Why is nitrogen important?

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Nitrogen is essential for living organisms as it's in structures of proteins and nucleic acids such as DNA.

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Why are plants and their biological processes important?

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Photosynthesis is the process by which plants absorb light energy from the sun and convert it to chemical energy through cellular respiration. 

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What is the process of growth and development in plants?

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Growth and development are important biological processes in plants.

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What are some important biological processes in plants?

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growth and development

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What are some critical biological processes in plants but not humans?

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cellular respiration

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What is the correct order of the nitrogen cycle?

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Answer

Nitrogen fixation, nitrification, assimilation, ammonification, and denitrification.

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Question

What type of transport is the sodium-glucose pump?

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symporter

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What type of transporter is the sodium-potassium pump?

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antiporter

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What's the difference between a sodium-potassium pump and a sodium-glucose pump?

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The sodium-potassium pump is an antiporter, and the sodium-glucose pump is a symporter.

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What drives the sodium-glucose process?

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The difference in energy gradient resulting from sodium wanting to enter the cell drives the glucose into the cell with it.

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What's the difference between primary and secondary active transport?

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Answer

Secondary active transport couples or pairs the transport proteins to the movement of ions or charged molecules down their concentration or electrochemical gradient to another molecule moving against its concentration or electrochemical gradient. 

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What is active transport?

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Active transport is a type of process that requires energy from our cells. This energy comes in the form of ATP or adenosine phosphate. 

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What are examples of passive transport?

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osmosis

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What are examples of active transport?

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sodium-potassium pump

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Why are transport proteins necessary?

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Transport proteins are necessary because the cell membrane is semipermeable.

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What are the types of primary active transports?

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P-type ATPase

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Why is the sodium-potassium pump important?

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The sodium-potassium pump is integral to our bodies as it drives nerve impulses.

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What type of transport is the sodium-glucose pump, and why?

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The sodium-glucose pump is a secondary active transport because it couples the movement of sodium down its concentration gradient with the movement of glucose, which, unlike sodium, is going against its concentration gradient.

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What is the electrochemical gradient, and how does it work?

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The electrochemical gradient is a gradient that consists of a chemical and electrical aspect.

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What's the difference between channel and carrier proteins?

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Channel proteins are transport proteins that do the same thing as carrier proteins, except they diffuse molecules faster because they don't have to change shape. 

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Why do molecules need help from transport proteins?

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Molecules that need help from transport proteins do so because they are either polar or charged, too big to diffuse through the cell or both. This occurs because of the cell membrane's arrangement. 


Show question

Test your knowledge with multiple choice flashcards

Amino acids are the building blocks of ___.

Amino acids that are not synthesized in the body are called __.

Amino acids that are not needed in our diet are called __.

Next

Flashcards in Biological Processes125

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Describe the components of an amino acid.

An amino acid is a group of organic molecules with an amino group (-NH2), a carboxyl group (-COOH), and a side chain (called R group) unique to every amino acid. Each amino acid molecule has a central carbon C atom to which the amino and carboxyl groups are attached. 

Amino acids are the building blocks of ___.

proteins

What does metabolism mean?

Metabolism refers to the chemical reactions that take place in living organisms to provide energy for life-sustaining processes and to synthesize new organic materials. 

What is amino acid metabolism?

Amino acid metabolism refers to the sum of all chemical reactions in which amino acid is broken down and synthesized for vital processes in the body.     

Amino acids that are not synthesized in the body are called __.

essential amino acids

Amino acids that are not needed in our diet are called __.

non-essential amino acids

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