Chapter 1 - Structure of Prokaryotic Cells PDF

Summary

This document describes the structure of prokaryotic cells, focusing on learning objectives for characterizing these cells and differentiating between Gram-positive and Gram-negative bacteria. It also provides an introduction to microbiology, classification, and naming conventions.

Full Transcript

**Chapter 1: Structure of prokaryotic cells**

+-----------------------------------------------------------------------+
| **[Learning Objectives]** |
| |
| By the end of this section, you should be able to: |
| |
| a. Characterise the structure of prokaryotic cells. |
| |
| b. Differentiate between Gram positive and Gram negative bacterial |
| cells. |
+-----------------------------------------------------------------------+

**Introduction**

Microbiology is the study of tiny organisms that cannot be seen with the
unaided eye. In other words, they are microscopic and can only be viewed
when magnified by a microscope. These organisms are collectively known
as microorganisms or microbes.

The unaided human eye cannot visualise things that are smaller than 1
mm. To provide a quick size comparison, Figure 1 shows the relative
sizes of some objects.

The microbes normally encountered in the study of microbiology tend to
fall within the micrometer (µm) dimensions (Figure 1), with viruses
being the smallest microbes.

Three groups of micro-organisms will be of focus in this module:
bacteria, fungi and viruses. Viruses are not living organisms but they
are considered a type of microbe as they are microscopic and can cause
infections and disease. They are small particles that exist at a level
of complexity between large molecules and cells. Viruses are in fact
simpler than cells; they are in fact composed essentially of a protein
covering that wraps around a small amount of nucleic acid (DNA or RNA).
Despite their simple make-up, viruses have the ability to invade host
cells and can inflict serious damage and death.

Thus, microbes are found everywhere. Some are harmful, but most are
beneficial. Their presence and biological activities contribute
tremendously to the well-being of living things and their environment.

**\
**

**Classification of Microbes (INFO)**

Living organisms can be systematically organised using many different
classification systems. Classification is an orderly arrangement of
organisms into groups that indicate their evolutionary relationships and
history.

The main taxa (or groups) in a classification scheme begin with
**domain** (which is a giant, all-inclusive category based on a unique
cell type), and ends with **species**, the smallest and most specific
taxon (pl. taxa). All the members of a domain share only one or few
general characteristics, whereas members of a species - essentially the
same kind of organism, share many characteristics. The order of taxa
between the top and bottom levels is (in descending order): domain,
kingdom, phylum (or division), class, order, family, genus and species.

Using molecular methods, Carl Woese and George Fox have classified
living organisms into three domains. The members of Domain Bacteria have
prokaryotic cells and are what people think of as traditional bacterial
species. Members of the Domain Archaea also possesses prokaryotic cells,
but these cells are so distinct from those found in the Bacteria that
they are placed in their own domain. Most members of this domain are
characterised by their ability to live in extreme environments (E.g.
deserts, volcanoes, the Antarctic etc.) or produce novel metabolic
by-products (E.g. methane). Biologists have estimated that these two
domains together account for at least half of the total mass of life
forms on earth. This is largely due to their versatility and
adaptability to a variety of habitats.

The Domain Eukarya contains all of the organisms that display an
eukaryotic cell structure, and includes Kingdom Fungi, Kingdom Protista,
Kingdom Animalia and Kingdom Plantae. These are more commonly known as
fungi, protists, animals and plants, respectively.

**Binomial Naming of Organisms**

Scientists use a two-name (binomial) system to name all organisms on
Earth. This system describes the *genus* and *species* of the organism.
For example, Humans are scientifically named *Homo sapiens*. The first
word is the **genus** name and the second is the **species** name.

[There are four rules that must be applied when naming an
organism]:

1. The genus name is always written first, followed by the species
name.

2. The genus name is always capitalized, the species name is not.

3. Both names must be underlined separately; alternatively, they are
not underlined but written in italics.

4. The genus name may be represented by its first letter, but this is
not applicable to the species name.


Here is an example:

**Binomial name of organism** **Abbreviation** **Remarks**
------------------------------- ------------------ --------------------------------------------------------------------------------------------------------------------------------------------------------------------------
*Escherichia coli* *E. coli* Some strains can cause severe food poisoning
*Staphylococcus aureus* *S. aureus* Can cause skin infections when it enters open wounds
*Bacillus cereus* *B. cereus* Can cause 'Fried Rice Syndrome'. This is classically contracted from consumption of fried rice that have been sitting at room temperature for hours (such as at buffets)

**Cell structure**

A cell is the basic unit of all living organisms that is capable of
independent existence. Cells are highly complex and organised. They
contain DNA to construct cellular structures, run cellular activities
and reproduce. Cells also carry out basic cellular functions that are
essential for survival and growth.

There are two basic cell types, **prokaryotic** and **eukaryotic**. They
can be distinguished by their size and types of cellular structures
possessed. Note that all prokaryotes are microbes while only some
eukaryotes are microbes.

A prokaryotic cell is usually smaller than a eukaryotic cell. It does
not have any membrane-bound genetic material and structures while a
eukaryotic cell has its genetic material enclosed by the nuclear
membrane (forming the nucleus) and many membranous structures. The
genetic material possessed by prokaryotic cells is usually a double
stranded circular chromosome while that of eukaryotic cells are
typically found in more than 1 paired chromosomes. A eukaryotic cell
also has very complex internal structure and possesses many structures
lacking in prokaryotic cells. Some examples are listed below in Table 1.

Table 1: Comparison of some prokaryotic and eukaryotic cellular
structures

**Structures** **Eukaryotic cell (eg. fungi)** **Prokaryotic cell (eg. bacteria)**
------------------------------------------------------------------ ------------------------------------------------------------ -------------------------------------------------------------------------
Nucleus/nuclear region Nucleus (linear chromosomes are bound by nuclear membrane) Nucleoid (single, circular chromosome is not bound by nuclear membrane)
Ribosomes Many, larger Less, smaller
Cell membrane, cytoplasm Yes Yes
Membrane-bound organelles (eg. ER, mitochondria, lysosomes etc.) Yes No

Two generalised cells (bacterial and fungal cell) can be used to
understand more about cellular structures, and their corresponding
functions. Refer to Figures 2-3.


Being prokaryotic cells, bacterial cells are have a much less complex
structure than fungal cells (which are eukaryotic). Table 2 shows a
brief comparison of cell structures.

Table 2: Comparison of cellular structures within bacterial and fungal
cells

\*note: while fungi are generally non-motile, but some classes of fungi
do produce motile spores.

**Bacterial structure**

Bacteria are unicellular prokaryotes. They reproduce by binary fission
(will be covered in greater detail in Chapter 2). Bacteria are
relatively small, with sizes ranging from 0.5-1.0 µm in diameter. Their
small size gives them a large surface area to volume ratio, enabling
large surfaces of the bacteria cell to be in contact with the
environment. A bacterial cell is made up of several generalised
structures (Figure 4).


Figure 4: Bacterial structures

(Ref: K. P. Talaro. Foundations in Microbiology. 5^th^ Edition. 2005.
McGraw-Hill, Inc. USA. pp 88.)

This flowchart summarises the general structural plan of a typical
bacterial cell:

**\
**

**External structures**

Very often, bacteria may have surface structures (called **appendages**)
arising from their surfaces. These can be divided into two groups: those
that provide motility (E.g. flagella and axial filaments); and those
that provide attachment sites (E.g. fimbriae) or channels (E.g. pili).

**Fimbria** (pl. fimbriae) and **Pilus** (pl. pili); refer to Figure 5.

- - -


**Flagella** (sing. flagellum)

They are long, thin, rounded structure that rotates 360^o^ (Figure 6).
This is in contrast to the flagella of eukaryotic cells which undulate
back and forth. Flagella confer cell motility (allows bacterial cells to
swim freely in aquatic habitats) and are made from flagellin protein.

All spirilla, about half of the bacilli and a small number of cocci are
flagellated (bear flagella). Flagella vary in number and arrangement on
a cell as shown below.

Figure 6: Different types of flagellar arrangements (or flagellation)

Motile bacteria may be propelled by one or more flagella per cell as
shown above. On the other hand, eukaryotic cells may be able to move
either with the help of flagella (eg. human sperm cells) or **cilia**
(eg. protists such as *Paramecium* or *Euglena*).

The ability to move is one piece of information used in the laboratory
identification of various groups of bacteria. Special stains must be
used to see flagella arrangement because they are usually to minute to
be seen with a light microscope. One way to detect for bacterial
motility is to stab a tiny mass of cells into a test-tube of semi-solid
agar medium. Rapidly spreading growth is indicative of cell motility.
You will be performing this experiment in the lab.

Motile cells have the ability to respond to environmental signals such
as chemicals. This is known as **chemotaxis**. Positive chemotaxis is
the movement of a cell towards a favourable chemical stimulus (E.g. a
food source); whereas negative chemotaxis is the movement away from a
repellent (E.g. potentially harmful compound).

A few pathogenic (disease-causing) bacteria use their flagella to invade
the surface of mucous membranes during infections. *Helicobacter
pylori*, the agent of stomach ulcers, bores through the stomach lining,
and *Vibrio cholerae*, the cause of cholera, penetrates the small
intestine with the help of flagella.

**Glycocalyx**

The bacterial cell surface is often subjected to severe environmental
conditions. Some (not all!) bacterial cells can secrete some
extracellular material as a form of protection. The **glycocalyx**
(Figure 7) develops as a coating of macromolecules to protect the cell
and in some cases, help it to adhere to its environment. Glycocalyces
differ in thickness, organisation and composition.

Some bacteria are covered with a loose shield called a **slime layer**
that protects them from dehydration and loss of nutrients, as well as
serving in adhesion. Other bacteria produce **capsules** that are
attached tightly to the bacterial cells and have a more defined shape.
Capsules are composed of repeating polysaccharide units of protein,
carbohydrate or both. Capsules have a thick, gummy consistency that
gives a sticky (mucoid) appearance to the colonies of encapsulated
bacteria. Capsules prevents host cells from mounting an immune response
because bacteria with capsules can resist engulfment and destruction by
white blood cells.

Cell envelope and
glycocalyces

Figure 7: Two types of glycocalyces (sing. = glycocalyx)

(Source: Chess, B. Talaro's Foundations in Microbiology. 11^th^ Edition.
2021. McGraw-Hill, Inc. USA. pp 98.)

**Cell envelope (consists of cell membrane & cell wall)**

Most bacteria have an extensive cell envelope (making up a tenth to up
to half of the cell volume) comprising of three layers stacked on top of
each other. Each of these layers performs a distinct function, but
together they act as single protective unit.

**Cell wall**

- Surrounds the cell membrane

- Strong and semi-rigid casing that provides structural support and
maintains cell shape

- Protects cell against changes in osmotic pressure

- Many bacteria have porous cell walls so the cell walls are not as
important as cell membranes in regulating the entry of material into
and out of cells

- Primarily made up of **peptidoglycan** (Figure 8)


Figure 8: Structure of peptidoglycan, also known as murein, is a polymer
consisting of sugars (glycan) and amino acids (peptido) that forms a
mesh-like layer external to the cell membrane. The sugar portion
consists of alternating residues of β, 14 linked NAG
(N-acetylglucosamine) and NAM (N-acetylmuramic acid). NAM molecules from
neighbouring glycan chains are held together by branches of four amino
acids (called peptide cross links).

The bacterial cell wall surrounds the entire bacterium, holding the cell
together and offering protection. It also maintains osmotic pressure,
meaning it lets in just the right amount of water, sugars, amino acids
and other ions that the cell needs. This prevents the cell from lysis
(bursting).

Bacteria are grouped based on differences in their cell wall structures
as seen after Gram staining has been performed (Figure 9).


Figure 9: Gram staining procedure. Upon completion, Gram positive cells
would appear dark purple (or blue), while Gram negative cells would
appear red (or pink).

Ref: Talaro & Chess. Foundations in Microbiology. 10^th^ Edition. 2018.
McGraw-Hill, Inc. USA.

The peptidoglycan layer of Gram positive bacteria can be up to 30 sheets
of glycan chains thick. On the other hand, that of Gram negative
bacteria is only one or two sheets thick (Figure 10).

Gram positive bacterial cell walls have a thick peptidoglycan layer
(Table 3) which retains Gram Stain crystal violet. There is a thin
(almost negligible) periplasmic space in between cell wall and cell
membrane. There may also be additional molecules, teichoic acid and
lipoteichoic acid to add rigidity to the cell wall and are also
essential for survival/ virulence of bacterial pathogens (allows them to
attach to host tissues to cause illness when released into bloodstream).

Gram negative bacterial cell walls have a much thinner peptidoglycan
layer that does not retain Gram Stain crystal violet well. The
peptidoglycan layer is surrounded by an additional layer (called the
'outer membrane') consisting of lipopolysaccharide and phospholipid.
This additional layer protects the cells from antibiotics and enzymes.
They also have a thick periplasmic space between the cell wall and cell
membrane.

cow95289\_04\_14

Figure 10: Cell wall structural comparison of Gram positive and Gram
negative bacteria

(Ref: Talaro & Chess. Foundations in Microbiology. 10^th^ Edition. 2018.
McGraw-Hill, Inc. USA. pp 101.)

Table 3: Key differences between the cell walls of Gram positive and
Gram negative bacteria

(Fill in the blanks using clues given during your lecture)

+-----------------------+-----------------------+-----------------------+
| Characteristics | Gram positive | Gram negative |
| | bacteria | bacteria |
+=======================+=======================+=======================+
| Thickness of | Thick; 60% of CW; | Thin; 10-20% of CW; |
| peptidoglycan layer | 20-80 nm | 8-11 nm |
+-----------------------+-----------------------+-----------------------+
| Outer membrane | Absent | Present (together |
| | | with the periplasmic |
| | | space, protects |
| | | against antibiotics & |
| | | enzymes) |
+-----------------------+-----------------------+-----------------------+
| Chemical composition | Peptidoglycan | Lipopolysaccharides |
| | | (LPS) |
| | Teichoic acid | |
| | | Lipoprotein |
| | Lipoteichoic acid | |
| | | Peptidoglycan |
| | Mycolic acid & | |
| | polysaccharides\* | Porin proteins |
+-----------------------+-----------------------+-----------------------+
| Periplasmic space | Thin | Thick |
+-----------------------+-----------------------+-----------------------+
| Permeability to | More penetrable | Less penetrable |
| molecules | | |
+-----------------------+-----------------------+-----------------------+

\*only in acid-fast bacteria (E.g. *Mycobacterium* species)

Porins are channel proteins that allow the passage of useful, small,
hydrophilic molecules (nutrients) across the outer membrane, but they
prevent the passage of larger, harmful substances like bile salts
(commonly present in the human intestine). This protects the bacteria
and allows them to live in our dastrointestinal tract..

**Cell membrane**

While the glycocalyx (if present) and cell wall can bar the passage of
large molecules, it is the cell membrane that acts as a barrier between
the inside and outside of the cell. Here are its key features:

- Selectively-permeable, flexible thin sheet that surrounds the
cytoplasm

- Comprises of a bilayer of phospholipids (30-40%) and proteins
(60-70%). The membranes of Archaea which contain unique, branched
hydrocarbons, rather than fatty acids

- Most important function of cell membrane is to regulate transport --
the passage of nutrients into the cell and discharge of wastes

- As bacterial cells do not have any membrane-bound organelles, the
cell membrane provides a site for energy reactions, nutrient
processing and synthesis

**Cytoplasm**

The site for many of the cell's biochemical and synthetic activities. It
is mostly made up of water (70-80%), which serves as a solvent for
nutrients (E.g. sugars, amino acids, salts etc.). The cytoplasm holds
larger structures such as the chromosome, ribosomes, granules, plasmids
etc.

**Nucleoid**

By definition, bacteria do not have a true nucleus. Their DNA is not
enclosed by a nuclear membrane but is instead condensed in a central
area of the cell called the **nucleoid** (or **nuclear region**).

Bacterial DNA occurs in the form of a single, circular strand. Arranged
along its length are genes that carry information required for bacterial
growth and reproduction.

Although the bacterial chromosome contains all the essential information
for bacterial survival, many bacteria contain additional genetic
elements called **plasmid**. These are small pieces of circular DNA that
exist independently within the cytoplasm. At times, they may be
integrated with the nucleoid. During bacterial reproduction, plasmids
are duplicated and passed on to the offspring. Plasmids are not
essential for growth or metabolism, but can carry genes that confer
protective traits like antibiotic resistance or toxin production. Some
yeasts (eukaryotes) may also have plasmids. Plasmids are an important
component of genetic engineering techniques because they are readily
manipulated in the lab for the purpose of transferring genes into
bacterial cells.

**Ribosomes**

Each bacterial cell contains tens of thousands of **ribosomes**. They
are the sites of protein synthesis. Ribosomes are made from protein
[and] ribosomal RNA. Each ribosome consists of a large
subunit and a small subunit. In the cytoplasm, ribosomes can occus in
chains (polysomes) or they can be attached to the cell membrane.

Ribosomes can be characterised in the lab by Svedberg (S) units. This
rates the molecular sizes of various cellular structures when they are
spun down using a lab centrifuge. Heavier, more compact structures
sediment faster and are given a higher S rating. Prokaryotic ribosomes
are fewer and smaller (70S), whereas eukaryotic ribosomes are more
plentiful and larger (80S).

Being prokaryotic cells, bacteria do not possess any membrane-bound
organelles like mitochondria, smooth- and rough- ER, Golgi apparatus
etc.

**Endospores**

Some bacteria have a two-phase life cycle: a vegetative cell
(metabolically active, growing organism) and an **endospore** (inert,
dormant body). During adverse environmental conditions, (E.g. nutrient
depletion, dehydration etc.), these bacteria are induced to produce
endospores through a process known as **sporulation** (Figure 11). Each
cell can only produce one endospore. Endospores are very difficult to
kill as they able to withstand extremes of heat, drying, freezing,
radiation and the chemicals that would readily kill ordinary cells.

Figure 11: Formation of bacterial endospore ('spore') during
environmental stress; and spore germination when favourable conditions
return.

Once conditions become favourable, each endospore will undergo
**germination** to form a new vegetative cell, thus enabling the
bacteria to survive. Once initiated, germination can occur as soon as 90
minutes later. The stimulus is usually water, and a specific germination
agent (E.g. an amino acid or an inorganic salt).

To date, two rod-shaped, Gram positive bacterial genera are known to
have the ability to produce endospores: *Clostridium* and *Bacillus*. In
the laboratory, endospore staining is carried out using malachite green
to stain the endospore, and safranin as a counterstain.

**[Bacterial morphology (shape) ]**

Bacterial cells function as independent, single-celled (unicellular)
organisms. They exhibit considerable variety in shape, size and colonial
arrangement. It is most convenient to describe most bacteria by one of
three general morphologies as designated by the shape of the cell wall
(Table 4).

If the cell is spherical, the bacterium is described as a **coccus**
(pl. cocci). Cocci are often perfect spheres, but they can also appear
slightly oval or bean-shaped. A cell that is cylindrical is termed a
rod, or **bacillus** (pl. bacilli). There is also a bacterial genus
named *Bacillus* whereby cells are all rod-shaped. When a rod-shaped
cell is slightly elongated, it is termed a **coccobacillus** or
short-rod (length not exceeding 2 µm). If it is gently curved or
comma-shaped, it is termed a **vibrio**.

Bacteria that have a spiral-shaped cylinder are called **spirillum**
(pl. spirilla). They consist of a rigid helix, twisted 1-20 times along
its axis (like a corkscrew) and may have one to several flagella
attached at one end of the cell. Another spirally-shaped cell that was
mentioned earlier is the **spirochete**. This is a more flexible form
that resembles a spring as it has 3-70 helical turns. Spirochetes move
with the help of between 2-100 periplasmic flagella (also called axial
filaments).

Table 4: Common bacterial morphologies

+-----------------------+-----------------------+-----------------------+
| Morphology | Description | Example (no need to |
| | | memorise) |
+=======================+=======================+=======================+
| Bacillus | Rod-shaped cells | *Bacillus* species |
| | whose dimensions vary | are about 2 µm in |
| ![Bacteria | according to species. | width and up to 7 µm |
| shapes](media/image17 | The term *Bacillus* | in length; while |
|.jpeg) | is a genus name while | *Escherichia coli* |
| | the term bacillus | cells are typically 1 |
| | also describes a | µm in width and 2-3 |
| | shape. | µm in length. |
+-----------------------+-----------------------+-----------------------+
| Coccus | Describes any | |
| | bacterium that has a | |
| File:Arrangement of | spherical shape. | |
| cocci bacteria.svg | Sometimes, they can | |
| | occur as groups of | |
| ![File:Arrangement of | cells and the | |
| cocci | patterns they arrange | |
| bacteria.svg](media/i | themselves in are | |
| mage18.png) | given names. | |
| | | |
| File:Arrangement of | | |
| cocci bacteria.svg | | |
| | | |
| ![File:Arrangement of | | |
| cocci | | |
| bacteria.svg](media/i | | |
| mage18.png) | | |
| | | |
| File:Arrangement of | | |
| cocci bacteria.svg | | |
| | | |
| ![http://eglobalmed.c | | |
| om/tbook/27713-h\_fil | | |
| es/fig83.jpg](media/i | | |
| mage19.jpeg) | | |
+-----------------------+-----------------------+-----------------------+
| | Diplococci are | *Neisseria |
| | arranged in 2-cell | gonorrhoeae* is an |
| | pairs of small cocci, | example and it is the |
| | usually joined along | causative agent for |
| | their longest axis | gonorrhoea. |
| | and with adjacent | |
| | sides flattened. | |
+-----------------------+-----------------------+-----------------------+
| | Bacteria that are | |
| | typically arranged in | |
| | clusters of 4 cells. | |
+-----------------------+-----------------------+-----------------------+
| | Bacteria in the | |
| | *Sarcina* genus | |
| | typically form a | |
| | cuboidal arrangement | |
| | of 8-64 cells. | |
+-----------------------+-----------------------+-----------------------+
| | Bacteria in the | *Streptococcus |
| | *Streptococcus* genus | pyogenes*, which can |
| | are arranged in | cause sore throats |
| | chains. They divide | and also skin and |
| | in one plane only and | soft tissue |
| | the degree of | infections is an |
| | adhesion between | example. The cells |
| | cells is not very | are about 1-2 µm in |
| | strong, thus the | diameter. |
| | chains are easily | |
| | broken. | |
+-----------------------+-----------------------+-----------------------+
| | Those found in | *Staphylococcus |
| | irregular clusters of | aureus* is often |
| | cells (like grapes) | found as part of the |
| | are called | normal flora of skin |
| | staphylococci. Cell | and nostrils, but can |
| | division takes place | also give rise to |
| | in a number of planes | skin infections when |
| | with a high degree of | there are open |
| | cell adhesion. | wounds. Cells are |
| | | typically 1 µm or |
| | | less in diameter. |
+-----------------------+-----------------------+-----------------------+
| Coccobacillus | A shape that is | *Escherichia coli* is |
| | intermediate between | a Gram negative |
| Bacteria shapes | cocci (spherical) and | coccobacillus |
| | bacilli (rod-shaped). | commonly found in |
| | Thus, they are very | human intestines. |
| | short rods and are | Some strains are |
| | often mistaken for | responsible for food |
| | cocci. | poisoning, urinary |
| | | tract infection etc. |
+-----------------------+-----------------------+-----------------------+
| Vibrio | Rigid, curved cells | *Vibrio cholerae* |
| | | (causative agent of |
| ![Bacteria | | cholera) has a |
| shapes](media/image17 | | typical diameter of |
|.jpeg) | | 0.5 µm and a length |
| | | of 2 µm. |
+-----------------------+-----------------------+-----------------------+
| Spirillum | Cells are made up of | *Helicobacter pylori* |
| | rigid spirals with | (implicated in |
| Bacteria shapes | 1-20 helical turns. | gastric ulcer |
| | They resemble | formation). |
| | corkscrews | Dimensions are |
| | | typically 0.5 µm in |
| | | diameter with |
| | | variable length up to |
| | | 60 µm. |
+-----------------------+-----------------------+-----------------------+
| Spirochete | Thin, flexibly-coiled | *Treponema pallidum* |
| | cells with between | (causative agent of |
| ![Bacteria | 3-70 helical turns | syphilis) is an |
| shapes](media/image17 | and resemble a spring | example. Typical |
|.jpeg) | | diameter is 0.5 µm by |
| | | 5-500 µm length. |
+-----------------------+-----------------------+-----------------------+

**[Bacterial arrangement ]**

Bacteria also exhibit different cell arrangements (distinctive grouping
of cells), depending on the division pattern and how the cells remain
attached after division (Table 5). At times, individual cells may remain
attached to others after cell division, thereby appearing in groups or
clusters of cells. This is known as bacterial arrangement (or style of
grouping). Thus, the main factors influencing bacterial arrangement are
its pattern of cell division and how the cells remain attached
afterward.

The greatest variety in arrangement occurs among the spherically-shaped
(**cocci**) bacteria (Figure 12). They may exist as singles, in pairs
(**diplococci**), in **tetrads** (groups of four), in irregular clusters
(**staphylococci**) or in chains of a few to hundreds of cells
(**streptococci**). An even more complex grouping of a cubical packet of
8, 16 or more cells is called a **sarcina** (pl. sarcinae).

These different coccal groupings is the result of cell division of a
coccus in a single plane, in two perpendicular planes, or in several
intersecting planes (after division, daughter cells remaining attached).

Rod-shaped (**bacilli**) cells are less varied because they only divide
in the transverse plane (perpendicular to long axis). Thus, they can be
arranged as single cells, as a pair of cells with ends attached
(**diplobacilli**), or as a chain of several cells (**streptobacilli**)
(Figure 13).


Table 5: Bacterial morphologies and arrangements

**Morphology** **Division without separation produces:** **Prefix** **Cell numbers** **Arrangement** **Morphology + Arrangement**
---------------- ------------------------------------------- ------------ ------------------ ----------------- ------------------------------
Coccus Single cells NA 1 Single Coccus
Cells in pairs Diplo- 2 Pair Diplococci
Cells in chains Strepto- Variable Chain Streptococci
Four cells in a cube Tetrad 4 Tetrad Tetrads
Cells in a cube Sarcina 8-64 Sarcina Sarcina (plural: sarcinae)
Irregular cluster Staphylo- Variable Cluster Staphylococi
Bacillus Single cells NA 1 Single Bacillus
Cells in pairs Diplo- 2 Pair Diplobacilli
Cells in chains Strepto- Variable Chain Streptobacilli
Spirillum Single cells NA 1 Single Spirillum

Here are some ways in which bacteria may be described:

+-----------------------+-----------------------+-----------------------+
| **Bacterium** | **Description 1** | **or Description 2** |
+=======================+=======================+=======================+
| | Morphology: coccus | staphylococcus |
| | | |
| | Arrangement: cluster | |
+-----------------------+-----------------------+-----------------------+
| ![](media/image23.png | Morphology: bacillus | Streptobacillus |
| ) | (or rod) | |
| | | |
| | Arrangement: chain | |
+-----------------------+-----------------------+-----------------------+
| | Morphology: | Coccobacillus |
| | coccobacillus (or | |
| | short rod\*) | |
| | | |
| | Arrangement: single | |
+-----------------------+-----------------------+-----------------------+

\*Less than 2 μm in length