Microbial Nutrition - Microbiology & Chemistry Program PDF
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Uploaded by AdroitSnake
Ain Shams University
Dr. Abeer A. Rushdy
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Summary
This document provides a detailed overview of microbial physiology, focusing on the nutrition and uptake of nutrients, covering topics like cell structure, growth factors, and molecular composition. The document describes the required chemical elements and nutritional categories for microbes, highlighting transport mechanisms such as diffusion and active transport.
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##### Microbial Physiology BOT 432 ![](media/image3.png) ##### What is microbial physiology? - An understanding of cell structure, growth factors, metabolism, and - Introduces the inter-relatedness of microbiology, and biochemistry, in the context of a functioning microbial cell - The...
##### Microbial Physiology BOT 432 ![](media/image3.png) ##### What is microbial physiology? - An understanding of cell structure, growth factors, metabolism, and - Introduces the inter-relatedness of microbiology, and biochemistry, in the context of a functioning microbial cell - The study of the mechanical, physical, and biochemical functions of ![](media/image1.jpeg)![](media/image12.png) Growth of any organism ====================== - ### Available source of chemicals to use as nutrients - **Uptake of nutrients** - ### Suitable physical environment 4 ![](media/image20.png)![](media/image12.png) ### Expected Learning Outcomes - - **Differentiate between organic and inorganic nutrients.** - - **Describe the main categories of nutritional types (patterns)among organisms.** - - **Distinguish between the energy and carbon sources for the four nutritional classes of microorganisms**. - - **Discuss diffusion and passive transport systems.** - **Describe the features of active transport and differentiate among its mechanisms.** ![](media/image1.jpeg)![](media/image12.png) The Nutrition ============= #### Process by which chemical substances called nutrients are acquired from the environment and used in cellular activities such as metabolism and growth ![](media/image1.jpeg)![](media/image12.png) ![](media/image32.png) ##### ![](media/image34.png)Microorganisms require ##### nutrients ![](media/image37.png) - **Carbon = C** - **Hydrogen = H** - **Oxygen = O** - **Nitrogen = N** - **Phosphorus = P** - **Sulfur = S** - **Potasium = K** - **Calcium = Ca** - **Magnesium = Mg** - **Iron = Fe** ![](media/image3.png) - **Manganese = Mn** - **Zinc = Zn** - **Cobalt = Co** - **Molybdenum = Mo** - **Nickel = Ni** - **Copper = Cu [ ]** ![](media/image1.jpeg)![](media/image12.png) #### Determined in the laboratory. ![](media/image1.jpeg)![](media/image12.png) ##### Chemical Analysis of Cell Contents ###### List is a brief summary of some nutritional patterns in the intestinal bacterium **Escherichia coli**. - **Water content** is the highest of all components (**70%**). - About **97%** of the dry cell weight is composed of **organic compounds** - **Proteins** are the most prevalent organic compound. - Chemical **elements** are needed in the overall scheme of cell growth, but most of them are available to the cell as **compounds** and not as pure elements. ![](media/image56.png) ##### ![](media/image57.jpeg)The source of nutrients is extremely varied ![](media/image69.png) - ![](media/image80.png) ![](media/image81.png) ![](media/image84.png) - Nutritionally dependent on other life forms, Because organic carbon usually originates from organisms. - Among the common organic molecules that can satisfy this requirement are **proteins**, **carbohydrates**, **lipids**, and **nucleic acids**. In most cases, **these nutrients provide several other elements** as well. - Not all heterotrophs can use the same organic carbon sources. - Some organic nutrients already exist in a form that is **simple enough for absorption** (for example, monosaccharides and amino acids), but many larger molecules **must be digested** by the cell before absorption. ![](media/image1.jpeg) - ![](media/image91.png)Organisms harvest the energy of **light** are called - Organisms obtain energy by metabolizing **chemical compounds** (oxidized organic or inorganic) are called **Chemotrophs** - Organisms can use reduced inorganic compounds as electron donors are called **Lithotrophs** - Chemolithotrophs and Photolithotrophs - Organisms can use organic compounds as electron donors are called **Organotrophs** - Chemoorganotrophs and Photoorganotrophs. ![](media/image1.jpeg)![](media/image6.png) ![](media/image110.png) ![](media/image1.jpeg) ![](media/image1.jpeg)![](media/image116.png) 1. ### Amino acids - Required for the synthesis of proteins 2. ### Purines and pyrimidines - Required for synthesis of nucleic acids (DNA and RNA) 3. ### Vitamins - #### Needed as coenzymes and functional groups of certain enzymes ![](media/image118.png) - ###### **E.coli** does not require any growth factors (need med. contain only glucose and 6 different inorganic salts) - **Neisseria** require at least 40 additional ingredients, including 7 ###### -i.e have complex nutrient requirements - **Enterococcus faecalis** needs 8 different vitamins for growth. ###### Many microorganisms are able to synthesize large quantities of vitamins needed for human use. - **Vitamin C** produced by **Corynebacterium** - **Vitamin B12** by **Streptomyces, Pseudomonas** - **Vitamin D** by **Saccharomyces** - **β-carotene** by **Dunaliella** (genus of algae) - **Riboflavin (B2)** by **Clostridium, Candida** ![](media/image12.png) ![](media/image148.png) +-----------------------+-----------------------+-----------------------+ | **Photoautotroph** | | - | | | | | | (Photolithotroph) | | | | | | | | ***Primary | | | | producers*** | | | +=======================+=======================+=======================+ | **Photoheterotroph** | | - | | | | | | (Photoorganotroph) | | | +-----------------------+-----------------------+-----------------------+ | **Chemoautotroph** | | - - - - - | | | | | | **(**Chemolithotroph* | | | | *)** | | | | | | | | ***Primary producers | | | | in inhospitable | | | | environments*** | | | +-----------------------+-----------------------+-----------------------+ | **Chemoheterotroph | | | | (**Chemoorganotroph** | | | | )** | | | +-----------------------+-----------------------+-----------------------+ Photoautotroph Photoheterotroph Chemoautotroph - **Saprobes : are free-living microorganisms** that feed primarily on organic detritus from dead organisms - **Parasites derive nutrients from the cells or** tissues of a host. Light \+ H2O Light ![](media/image151.jpeg) ![](media/image1.jpeg)![](media/image6.png) - **Grow on dead organic remains of plants or animals. They decompose and decay organic remains into simpler compounds with the help of a variety of enzymes ([decomposers])** ##### - Parasites ![](media/image190.jpeg) - ##### - Symbionts - - ![](media/image194.jpeg)**Symbionts, which live in close association with a host, often depend on organic compounds from their host for their energy and carbon sources for survival.** ![](media/image199.jpeg) - **Parasites** grow **in or on the body** of a host, which they **harm** to some degree. - **Parasites** can damage tissues (disease) or even cause death; - **Parasites** range from viruses to helminth worms, - **Parasites** can live 27 Species usually belongs in **only one** of the nutritional classes ![](media/image223.png) ![](media/image1.jpeg) - **Taken into the cell (**required nutrients) Transport **waste materials** - **Out of the cell** (into the environment). - - Cell wall (bacteria, algae, and fungi) is usually only a **partial, nonselective barrier (**organisms with **cell walls-**bacteria, algae, and fungi) ![](media/image229.png) 1. ### Passive transport (di - **Osmosis (water)** ##### Diffusion - **Diffusion (small molecules)** ### Active transport - \ Simple diffusion - **Facilitated diffusion** ![](media/image233.jpeg) ![](media/image1.jpeg) - Means that the cell does not expend extra **energy** for - Follows physical laws - 2nd law of thermodynamics (not unique to living systems)- - The **inherent energy** of the molecules moving down a gradient does the work of transport ![](media/image240.jpeg)![](media/image242.png) ![](media/image243.png) ##### ![](media/image249.png) Diffusion - ![](media/image251.jpeg)**Diffusion** is a driving force in cell activities - Its effects are greatly controlled by ![](media/image252.png) - Small molecules can pass **through** the cell membrane by a process called **diffusion** - Diffusion across a membrane does **not require energy** - The difference in the concentration of molecules across a membrane is called a **concentration gradient.** - Diffusion always occurs **down a concentration gradient** (from an area where it is more concentrated to an area where it is less concentrated) - ###### Diffusion **continues** until the concentration of the molecules is the same on both sides of a membrane ![](media/image253.png) ![](media/image256.png) - The **rate of diffusion** depends on temperature, surface area, size of particles & type of molecules diffusing - Molecules **diffuse faster** at higher temperatures than at lower temperatures- called "**Thermal movement**" - Smaller molecules **diffuse faster than** larger molecules - Diffusion is driven by the **kinetic energy** of the molecules. - **Kinetic energy** keeps molecules in constant motion causing the molecules to move randomly away from each other in a liquid or a gas ![](media/image242.png) ![](media/image1.jpeg) ![](media/image1.jpeg) ### ![](media/image12.png)Adaptations to Osmotic Variations in the Environment - **Bacteria** & **Algae** have a **cell wall** protects them from bursting even as the cytoplasmic membrane becomes **turgid** from pressure. - The **amoeba** has no cell wall to protect it, so it must expend - **Halobacteria** living in the Great Salt Lake and the Dead Sea - **Absorb salt** to make their cells isotonic with the environment; - Thus, they have a physiological need for a high salt concentration in their habitats ![](media/image1.jpeg)![](media/image6.png) Simple Diffusion {#simple-diffusion-1} ---------------- (through phospholipid bilayer) ![](media/image1.jpeg)![](media/image6.png) These molecules can diffuse right through the membrane\'s **lipid** ![](media/image282.jpeg) ![](media/image283.png) Facilitated Diffusion --------------------- ![](media/image275.png) ![](media/image3.png) Facilitated Diffusion --------------------- - ![](media/image292.png)Diffusion across selectively permeable membranes **by** various types of proteins , sometimes called , which are embedded in the **plasma membrane**. - While there are hundreds of different proteins throughout the cell, only two types are found associated with facilitated diffusion: **channel proteins** and **carrier proteins.** ![](media/image1.jpeg) ![](media/image295.jpeg)![](media/image296.jpeg)Facilitated Diffusion --------------------------------------------------------------------- 1. **Channel proteins** provide hydrophilic passageways, typically are used to transport **ions** in and out of the cell through "**porins**" ion channels 2. **Carrier proteins** transport molecules by changing their shape to move a specific molecule across the membrane. ie. **glucose, amino acids, nucleotides** ![](media/image1.jpeg) ### ![](media/image6.png)Active transport - Live in habitats characterized by **very dilute nutrient** sources - Exist under relatively **nutrient-starved conditions** ![](media/image304.png) rate faster than by diffusion alone ![](media/image15.png)Presence of specific membrane proteins (- ![](media/image1.jpeg)![](media/image6.png) ![](media/image312.jpeg) pes o**Mi**f**cro**T**bia**r**l** a**Ph**n**ysi**s**olo**p**gy**o**--** r**Mi**t**crobiology & Chemistry program -- Prof Abeer A. Rushdy** 45 ![](media/image313.png) - ### Active transport systems - ##### Carrier-mediated active transport - **Group translocation system** - ##### ATP-binding cassette transporters (ABC transporters) - **Cotransport system** ![](media/image1.jpeg) - ![](media/image315.png)Specific membrane proteins that bind both ATP and the molecules to be transported. - Release of energy from the ATP drives the movement of - This can occur in either direction. ![](media/image1.jpeg) - ![](media/image324.png)A molecule is transported into the cell while being **chemically modified**. - **Couples** the transport of a nutrient with its conversion to a substance that is immediately useful inside the cell***.*** - Used primarily for the transport of sugars. ![](media/image328.png)![](media/image331.png) - ##### Important examples of active transport systems. - **Observed in Bacteria, Archaea, and eukaryotes** ![](media/image332.jpeg) - ![](media/image333.png)The **target solute** binds to **a soluble cassette protein** - Then interact with the **membrane transport proteins** to move the solute molecule inside the cell. - The cytoplasmic **ATP-hydrolyzing protein** supplies the energy for the transport event. ![](media/image336.jpeg)**soluble cassette protein** ![](media/image337.jpeg) ![](media/image3.png) - If the two molecules are transported in the same direction it is called **symport** - ![](media/image342.jpeg)If the two molecules are transported in opposite directions it is called **antiport** ![](media/image343.png) ### ![](media/image344.jpeg)Cytosis - #### Endocytosis ![](media/image347.png) - Exocytosis ![](media/image1.jpeg)![](media/image12.png) - Some cells can transport large molecules, particles, liquids, or even other cells **across the cell membrane**. - Because the cell usually **expends energy** to carry out this movement, it is also a form of **active transport**. - The substances transported do not pass physically through the membrane but are carried into the cell by **endocytosis.** ![](media/image354.png) #### ![](media/image357.png)Bulk transport - First the cell encloses the substance in its membrane, simultaneously - **Amoebas and certain white blood cells** ingest whole cells or large solid matter by a type of endocytosis called **phagocytosis** "cellular eating"**.** - **Liquids, such as oils or molecules** in solution, enter the cell