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Nutrition Strategies: Autotrophic, Human Digestion & Respiratory Systems

December 19, 2023 765 0

Approaches to Satisfying the Universal Need for Energy in Organisms

All living organisms share a common need for energy and materials, but they fulfill these requirements in diverse ways. Energy is obtained from external sources, and food serves as a crucial source for this purpose.

Diverse Nutritional Pathways: The Contrasts Between Autotrophs and Heterotrophs in Energy Acquisition

  • Autotrophs, such as green plants and certain bacteria, use simple food materials like carbon dioxide and water obtained from inorganic sources. 
    • In contrast, heterotrophs, including animals and fungi, rely on complex substances for their energy needs
    • These complex substances must be broken down into simpler ones for utilization in the body’s maintenance and growth. 
  • Enzymes, acting as biocatalysts, facilitate this breakdown process. 
  • The survival of heterotrophs is directly or indirectly dependent on the activities of autotrophs.

Autotrophic Nutrition Through the Lens of Photosynthesis and Carbohydrate Storage

  • Autotrophs, such as green plants and some bacteria, use photosynthesis to fulfill their carbon and energy requirements.
  • Carbohydrates not immediately used are stored as starch for future energy needs.

The steps of photosynthesis need not occur immediately in sequence. For example, desert plants take up carbon dioxide at night and prepare an intermediate, which is then acted upon by the energy absorbed by chlorophyll during the day.

Photosynthesis and the Vital Role of Chloroplasts in Carbohydrate Synthesis

  • The process involves the absorption of light energy by chlorophyll.
  • Light energy is converted to chemical energy, leading to the splitting of water molecules into hydrogen and oxygen.

Cross-section of a leaf

  • Carbon dioxide is subsequently reduced to form carbohydrates.
  • Chloroplasts, which contain chlorophyll, play a crucial role in photosynthesis.

6CO2 + 12H2ChlorophyllSunlight C6H12O6 + 6O2 + 6H2O

  • If you carefully observe a cross-section of a leaf under the microscope, you will notice that some cells contain green dots. 
  • These green dots are cell organelles called chloroplasts which contain chlorophyll.

The Role of Stomata in Carbon Dioxide Uptake and Gaseous Exchange in Photosynthesis

  • Stomata, small pores located on leaves, facilitate gaseous exchange during photosynthesis. 
  • The exchange of gases also occurs on stems, roots, and leaves.
  • Control of stomatal pores is governed by guard cells, which swell to open and shrink to close.
  • Pores close when the plant does not require carbon dioxide.
Open and closed stomatal pore
(a) Open and (b) closed stomatal pore

Raw Materials for Autotrophs

  • The water necessary for photosynthesis is absorbed by roots from the soil.
  • Essential elements such as nitrogen, phosphorus, iron, and magnesium are taken up from the soil.
  • Nitrogen, a critical component for protein synthesis, is obtained in the form of inorganic nitrates or nitrites, or as organic compounds produced by bacteria.

Nutritional Strategies: Adaptations, Variances, and Specializations in the Heterotrophic World

  • Organisms adapt their nutritional strategies based on the type and availability of food, as well as the method of obtaining it. 
  • The distinction between stationary (e.g., grass) and mobile (e.g., deer) food sources leads to variations in how organisms access and process their nutrition. 
  • The nutritive apparatus differs between species, exemplified by variations between a cow and a lion. 
  • Various strategies exist for taking in and utilizing food; some organisms break down food externally for absorption, like fungi such as bread molds and yeast, while others internally process whole material. 
  • The ability to take in and break down substances relies on an organism’s body design and functioning. 
  • Additionally, certain organisms adopt a parasitic nutritive strategy, obtaining nutrition from plants or animals without causing harm, seen in examples like cuscuta (amar-bel), ticks, lice, leeches, and tape-worms. 
  • This diversity highlights the adaptability of organisms to their environments in the realm of nutrition.
Nutrition in Amoeba
Nutrition in Amoeba

From Single Cells to Specialized Organs, Exploring the Evolution of Nutritional Processes in Organisms

  • Organisms employ diverse methods to obtain nutrition, and their digestive systems vary accordingly. 
  • In single-celled organisms, such as Amoeba, the entire surface may serve for food intake. 
  • As organisms become more complex, specialized parts emerge to carry out distinct functions. 
  • For instance, Amoeba utilizes temporary extensions of the cell surface to form a food-vacuole, where complex substances are broken down into simpler ones. 
  • The nutrients then diffuse into the cytoplasm, while undigested material is expelled from the cell surface. 
  • In Paramoecium, another unicellular organism, a specific spot on the cell is designated for food intake. 
  • Cilia, covering the cell surface, facilitate the movement of food to this spot, showcasing the adaptability of organisms in their nutritional strategies.

Nutrition in Human Beings

Journey of Sustenance: The Alimentary Canal and the Intricacies of Food Processing

  • The alimentary canal, a lengthy tube from the mouth to the anus, is specialized into various regions for distinct functions. 
  • Food undergoes processing to create small, uniform particles, initiated by crushing with teeth. 
  • Saliva, containing the enzyme salivary amylase, breaks down complex starch into simple sugar.
Human Alimentary Canal
Human Alimentary Canal

 

Peristaltic Movements and Gastric Digestion

  • Peristaltic movements, rhythmic contractions along the digestive tube, propel the food forward. 
  • The food travels from the mouth through the esophagus to the stomach. 
  • In the stomach, gastric glands release hydrochloric acid, pepsin, and mucus
  • Hydrochloric acid aids pepsin in protein digestion, and mucus protects the stomach lining.

Stomach to Small Intestine Transition

  • The sphincter muscle regulates the release of food from the stomach into the small intestine. 
  • The small intestine, characterized by extensive coiling, varies in length among animals based on their diets. 
  • Herbivores have longer intestines for cellulose digestion, while carnivores like tigers have shorter ones.

Small Intestine’s Role in Carbohydrate, Protein, and Fat Digestion, Enhanced by Liver, Pancreas, and Villi Collaboration

  • The small intestine: It is the primary site for complete digestion of carbohydrates, proteins, and fats
  • Secretions from the liver and pancreas neutralize acidic stomach contents. 
  • Bile from the liver emulsifies fats, facilitating enzyme action. 
  • The pancreas secretes digestive enzymes like trypsin and lipase
  • Villi: Present in the small intestine, increases the absorption surface, supplying absorbed nutrients to the entire body.

Dental caries

Dental caries or tooth decay causes gradual softening of enamel and dentine. It begins when bacteria acting on sugars produce acids that softens or demineralises the enamel. Masses of bacterial cells together with food particles stick to the teeth to form dental plaque. Saliva cannot reach the tooth surface to neutralise the acid as plaque covers the teeth. Brushing the teeth after eating removes the plaque before the bacteria produce acids. If untreated, microorganisms may invade the pulp, causing inflammation and infection.

Large Intestine and Waste Elimination

  • Unabsorbed food moves to the large intestine, where water absorption occurs
  • Waste material is expelled through the anus, regulated by the anal sphincter.

Human Respiratory System

  • The human respiratory system facilitates oxygen intake and carbon dioxide release
  • Nostrils filter and moisten incoming air, which passes through the throat into the lungs. 
  • Rings of cartilage prevent the collapse of air passages. 
  • The lungs consist of alveoli (singular–alveolus), where gases exchange occurs with blood vessels.

The Human Respiratory Mechanism and the Intricacies of Gas Exchange in the Alveoli

  • In humans, breathing expands the chest cavity, drawing air into the lungs and filling alveoli. 
  • During the breathing cycle, a residual volume of air ensures sufficient time for gas exchange. 
  • Hemoglobin in red blood cells serves as the respiratory pigment, aiding oxygen transport
  • Carbon dioxide, more soluble in water, is mainly transported in dissolved form in the blood.
Human respiratory system
Human respiratory system

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UDAAN PRELIMS WALLAH
Comprehensive coverage with a concise format
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Designed as per recent trends of Prelims questions
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