Microbial Cell Structure and Function PDF

Summary

This document is an overview of microbial cell structure and function, focusing on eucaryotes and fungal cells. It covers the features of fungal hyphae, types of hyphae, fungal cell structure, components of fungal cell walls, and the general structure and function of the cell membrane. The document also discusses the composition and activities of the cytoplasm and different types of organelles.

Full Transcript

 Septa
Septa occur at generally regular intervals along a
length of a hypha
Perforations allow cytoplasm to flow from one
cell to another

When a cell is damaged, a Woronin body or
coagulated cytoplasm serves a plug to prevent loss of
cytoplasm

Coenocytic fungi are more susceptible to cellular
damage
Membrane-Bound Organelles of Eucaryotic Cells

Nucleus

Rough Endoplasmic Reticulum (RER)

Smooth Endoplasmic Reticulum (SER)

Golgi Apparatus

Vacuoles

Mitochondria
The Cell Wall and Glycocalyx
(Capsule and S-layers)
When present, cell wall is chemically simpler than
procaryotic cell wall and lacks peptidoglycan.

Fungi: Chitin (polysaccharide)

Yeasts: Glucan and mannan (polysaccharides)
 The wall structure directly affects wall function
and interactions with the environment including
immune recognition by plants and animals.

Fibrous and gel-like carbohydrate polymers form a
tensile and robust core scaffold to which a variety of
proteins and other superficial components are added
that together make strong, but flexible, and
chemically diverse cell walls.
In most fungal species the inner cell wall consists of
a core of covalently attached branched β-(1,3) glucan
and chitin.

β-(1,3) Glucan and chitin form intrachain hydrogen
bonds and can assemble into fibrous microfibrils.
The outer layers of fungi vary much more than the
inner skeletal layer.
The inner walls of many fungal spores
and so-called black yeasts contain
complex amorphous (non-crystalline solid)
polymerized phenolic compounds called
melanins, which also add protection—
particularly from oxidants and some
exoenzymes.
 o Chitin - straight chain polymers of β-1,4-linked N-
acetylglucosamine residues;

Chitosan is de-acetylated chitin

o Glucan - polymers of β-1,3-linked glucose residues with
short β-1,6-linked side chains

o Cellulose - β-1,4-linked glucans

o Matrix polymers

- Glucouronic acids

- Mannoproteins - mannose attached to protein
This general arrangement places the structural

elements of the cell wall close to the membrane to

provide mechanical support, and places the gel-like or

hydrophobic polymers to the outside where they can

protect the load-bearing elements from degradative

enzymes in the environment or act as adhesins to

anchor the cell to substrata.
In A. fumigatus, the branched β-(1,3)(1,6) glucan is covalently bound to a
linear β-(1,3)(1,4) glucan with a [3Glcβ1-4Glcβ1] repeating unit.
The Cell Membrane
Similar to procaryotic cell membranes, but:
- Have different membrane proteins
- Contain carbohydrates that are important for
cell-cell recognition and serve as sites for
bacterial attachment.
- Contain sterols which increase resistance to
osmotic lysis.
The peripheral proteins (extrinsic) are partially
embedded on one side of the membrane,
whereas integral (transmembrane- intrinsic)
proteins extend from one side through the
membrane to the other side.

Glycolipids, also a component of membranes,
project into the extracellular space. Functionally,
these may protect, insulate, and serve as receptor-
binding sites.

The lipid and protein compositions of membranes
vary from cell type to cell type as well as within
the various intracellular compartments that are
defined by intracellular membranes.
The functions of membrane proteins differ
depending on their composition and location
in the plasma membrane. They can:
= Provide structural support
= Transport molecules across the membrane
= Act as enzyme regulators to control
chemical reactions
 Cytoplasmic Organelles
Plasma membrane - phospholipid bilayer

Involved in uptake of nutrients

Differs in that it contains ergosterol

- Site of action for certain antifungal drugs

- Oomycota contain plant-like sterols
Ergosterol is the major sterol found in the
membranes of fungi, in contrast to the cholesterol
found in the membranes of animals and
phytosterols in plants.
Hopanoid (sterol-like) is found in bacterial
membrane.
- Affects the cell membrane's fluidity and serves
signaling.
 Cholesterol

phytosterol
hopanoid
bb
Movement across eucaryotic
cell membranes:
Simple diffusion,
facilitated diffusion,
osmosis, and
active transport.
Group translocation does not occur.
The Cytoplasm:
- Many enzymes are sequestered in organelles.

- Contains the cytoskeleton: A complex network of thread
and tube-like structures, which provides support, shape, and
movement.

1. Microfilaments: Smallest fibers – Actin
Actin filaments (microfilaments)

2. Intermediate filaments: Medium sized fibers
Anchor organelles (nucleus) and hold cytoskeleton in place.
Abundant in cells with high mechanical stress.

3. Microtubules: Largest fibers - made of tubulin proteins.
Work in cell division, moving chromosomes
Flagella and ciliary movement.
Flagella
- Projections used for locomotion.
- Enclosed by plasma membrane and contain
cytoplasm.
- Consist of 9 pairs of microtubules in a ring,
with 2 single microtubules in center of ring (9
+ 2).

Flagella: Long whip-like projections.
Eucaryotic flagella move in wavelike
manner, unlike procaryotic flagella.
The Nucleus
Structure
Envelope: Double nuclear membrane.
Large nuclear pores
DNA (genetic material) is combined with histones and exists
in two forms:
Chromatin (Loose, threadlike DNA. Most of cell life)
Chromosomes (Tightly packaged DNA. Found only during
cell division)
Nucleolus: Dense region where ribosomes are made
Unique features of fungal nucleus
Membrane remains intact during mitosis
Functions
- House and protect cell’s genetic information (DNA).
- Ribosome synthesis
- The nucleus and the mitochondria represent unique
membrane enclosed organelles given that both are composed
of two lipid bilayers.

The nuclear membrane is most often referred to as the
nucleolemma and is composed of closely associated inner and
outer lipid bilayers. The space between the inner and outer
nuclear membranes is referred to as the perinuclear space.

The inner and outer nuclear membranes are also connected at
thousands of locations via multiprotein complexes that
generate pores in the nuclear membrane called nuclear pore
complexes.

The nuclear pores are through which RNA and proteins are
transported.
Ribosomes
- The site of protein synthesis (translation).
- Found in all eucaryotic and procaryotic cells.
- Made up of protein and ribosomal RNA (rRNA).
- May be found free in the cytoplasm or associated with
the rough endoplasmic reticulum (RER).
- Eucaryotic ribosomes (80S) are larger and more dense
than procaryotic ribosomes (70S).
- Eucaryotic ribosomes have two subunits:
Small subunit: 40S
Large subunit: 60S
- Mitochondria and chloroplasts have 70S ribosomes that
are similar to procaryotic ribosomes.
The Endoplasmic Reticulum (ER)

“Network within the cell”

ER is continuous with plasma membrane and outer
nucleus membrane.

Two types of ER:
Rough Endoplasmic Reticulum (RER)
Smooth Endoplasmic Reticulum (SER)
Rough Endoplasmic Reticulum (RER)

- Flat, interconnected, rough membrane sacs
- ―Rough‖: Outer walls are covered with ribosomes.
Ribosomes: Protein making ―machines‖.
May exist free in cytoplasm or attached to ER.

RER Functions:
- Synthesis and modification of proteins.
- Synthesis of cell and organelle membranes.
- Packaging, and transport of proteins that are
secreted from the cell.