Structure and functions of living organisms(biology)
Cards (68)
- Cell structure:
- Organelles are specialised subcellular structures found within living cells
- Cells are the basic structural unit of a living organism
- Tissues are groups of cells with similar structures, working together to perform the same function
- Organs are groups of tissues working together to perform specific functions
- Organ systems are groups of organs with similar functions, working together to perform body functions
- An example of an organ system is the respiratory system, containing the lungs (organ), made up of epithelial tissue consisting of epithelial cells
- Subcellular structures found in plant and animal cells:
- Nucleus:
- Contains the genetic material that codes for a particular protein
- Enclosed in a nuclear membrane
- Cytoplasm:
- Liquid substance where chemical reactions occur
- Contains enzymes that speed up the rate of reaction
- Cell membrane:
- Contains receptor molecules to identify and control what enters and leaves the cell
- Mitochondria:
- Where aerobic respiration reactions occur, providing energy for the cell
- Ribosomes:
- Where protein synthesis occurs and found on the rough endoplasmic reticulum
- Subcellular structures found only in plants:
- Chloroplasts:
- Where photosynthesis takes place, providing food for the plant
- Contains chlorophyll pigment that harvests light for photosynthesis
- Permanent vacuole:
- Contains cell sap and improves cell rigidity
- Cell wall:
- Made from cellulose and provides strength to the cell
- Specialised cells:
- Specialised cells develop certain characteristics to perform specific functions
- Cells specialise through differentiation, gaining new sub-cellular structures for their role
- Stem cells can differentiate once early on or throughout their life
- Examples of specialised cells in animals:
- Sperm cells, Nerve cells, Muscle cells
- Examples of specialised cells in plants:
- Root hair cells, Xylem cells, Phloem cells
- Stem cells in medicine:
- Characteristics: undifferentiated cells that can divide to produce different cells
- Types: Embryonic stem cells, Adult stem cells, Meristems in plants
- Uses: development, growth, repair
- Potential applications in treating diseases and conditions
- Biological molecules:
- Carbohydrates: made of carbon, oxygen, and hydrogen, break down into simple sugars
- Proteins: made of carbon, oxygen, hydrogen, sulfur, nitrogen, and phosphorous, break down into amino acids
- Lipids: fats and oils made of carbon, oxygen, and hydrogen, break down into 3 fatty acids and a glycerol molecule
- Enzymes:
- Enzymes are biological catalysts, protein molecules with a specific active site
- Lock and Key Hypothesis explains enzyme-substrate interaction
- Factors affecting enzyme activity: temperature and pH
- Practical investigations on enzyme activity with changes in temperature and pH
- Practical on investigating food samples for glucose, starch, protein, and fat:
- Tests for glucose, starch, protein, and fat with specific procedures and indicators
- To investigate the effect of pH on the reaction time of amylase breaking down starch:
- Mix 3 cm3 of amylase solution, 2 cm3 of starch solution, and 1 cm3 of pH solution in a test tube
- Place the test tube in a water beaker above a Bunsen Burn to maintain a constant temperature
- Every 10 seconds, place a drop of the solution into iodine solution wells
- The solution should turn blue-black when starch is present
- Record the time taken for the solution to turn orange
- Repeat the experiment with different pH solutions
- Record results on a graph of pH (x-axis) and time taken for the reaction (y-axis)
- The optimum pH for amylase is where the reaction is completed the fastest, likely around pH 7.0
- Diffusion:
- Spreading of particles from an area of higher concentration to lower concentration
- Passive process, no energy required
- Small molecules like oxygen, glucose, amino acids, and water can diffuse, but larger molecules like starch and proteins cannot
- Examples of diffusion in living organisms:
- Single-celled organisms use diffusion due to a large surface area to volume ratio
- Multicellular organisms have adaptations for molecule transport, like alveoli in lungs, villi in intestines, and root hair cells in plants
- Factors affecting diffusion rate:
- Concentration gradient: Greater difference leads to faster diffusion
- Temperature: Higher temperature increases particle movement and collisions, speeding up diffusion
- Surface area to volume ratio: Greater surface area allows faster diffusion
- Distance: Longer distance increases diffusion time
- Osmosis:
- Movement of water from a less concentrated to a more concentrated solution through a partially permeable membrane
- Passive process, no energy required
- Examples of osmosis in living organisms:
- Animals and plants experience osmosis effects based on external solution concentration
- Osmosis in animals can cause bursting or shriveling of cells
- Osmosis in plants affects turgor pressure and cell health
- Active transport:
- Movement of particles from lower to higher concentration, against the gradient
- Requires energy from respiration, hence called active
- Examples of active transport in living organisms:
- Root hair cells uptake water and mineral ions from soil
- Gut absorbs substances like glucose and amino acids into the bloodstream
- Leaf structures:
- Waxy cuticle reduces water loss
- Palisade mesophyll contains chloroplasts for photosynthesis
- Spongy mesophyll has air spaces for gas exchange
- Guard cells regulate stomata opening
- Stomata allow gas exchange and water loss
- Mineral ions:
- Magnesium is essential for chlorophyll production
- Nitrate is needed for amino acid synthesis
- Nutrition in humans:
- Balanced diet includes carbohydrates, proteins, lipids, dietary fiber, vitamins, minerals, and water
- Factors affecting energy requirements:
- Age impacts energy needs
- Nutrients and their sources:
- Iron: found in red meat, needed for haemoglobin, deficiency can cause anaemia
- Water: found in water, juice, milk, needed for cell reactions to take place
- Factors affecting energy requirements:
- Age:
- Energy requirements generally increase as we approach adulthood
- Energy needs of adults decrease as they age
- Activity levels:
- More activity requires more energy for movement
- Pregnancy:
- Energy requirements increase to support growth of the foetus
- Energy needs increase due to the extra mass of the baby
- Human alimentary canal:
- Mouth:
- Mechanical digestion: teeth break up large food pieces into smaller pieces with larger surface area to volume ratio (food bolus)
- Chemical digestion: amylase breaks down starch into glucose
- Salivary glands produce saliva to lubricate the food bolus for easy swallowing
- Oesophagus:
- Tube from the mouth to the stomach
- Food bolus moves down due to peristalsis created by circular and longitudinal muscles
- Pancreas:
- Produces carbohydrase, protease, and lipase enzymes
- Secretes enzymes into the stomach and small intestine
- Stomach:
- Gastric juice is released when food is detected
- Gastric juice contains pepsin (enzyme breaking down proteins) and hydrochloric acid
- Peristalsis occurs in the stomach
- Digested food is called chyme
- Small intestine:
- Duodenum:
- First part of the small intestine
- Carbohydrases, proteases, and lipases digest food here
- Bile is released into the duodenum to neutralize stomach acid and emulsify fats
- Ileum:
- Lined with villi for absorption of digested molecules into blood
- Large intestine:
- Water absorption to produce faeces
- Faeces stored in the rectum and removed through the anus
- Digestive enzymes:
- Carbohydrates (starch): broken down by carbohydrases
- Proteins: broken down by proteases
- Lipids: broken down by lipases
- Respiration:
- Occurs in every cell to supply ATP
- Aerobic respiration uses oxygen and yields more energy
- Anaerobic respiration occurs without enough oxygen and yields less energy
- Structure of thorax:
- Ribs: bone 'cage' surrounding lungs for protection
- Intercostal muscles: control inhalation and exhalation
- Diaphragm: changes pressure for breathing
- Trachea: windpipe for air entry to lungs
- Alveoli: tiny air sacs for gas exchange
- Ventilation process:
- Inhalation: intercostal muscles contract, ribcage moves up, diaphragm contracts downwards, pressure decreases, air moves in
- Exhalation: intercostal muscles relax, ribcage moves down, diaphragm relaxes upwards, pressure increases, air moves out
- Alveoli adaptations:
- Thin cell walls for shorter diffusion distance
- Folded to increase surface area
- Large network of capillaries for efficient gas exchange
- Transport:
- Diffusion is the passive movement of particles from higher to lower concentration
- Single-celled organisms rely on diffusion due to high surface area to volume ratio
- Multicellular organisms have adaptations for efficient transport
- Transport in plants:
- Phloem adaptations for translocation of sucrose and amino acids
- Elongated cells with sieve plates for movement of food substances
- Companion cells have many mitochondria to provide energy for the cells
- Food substances can be moved in both directions (translocation) within plants
- Water travels up xylem from the roots into the leaves to replace lost water due to transpiration
- Xylem adaptations:
- Lignin is deposited causing cells to die and become hollow, forming a continuous tube for water and mineral ions
- Water molecules are attracted to each other by hydrogen bonding, creating a continuous column of water
- Lignin strengthens the plant to withstand water pressure
- Lignin contains bordered pits for water and mineral entry