Lecture 2: Aspects of the Microbial Genome PDF

Summary

This document provides information on aspects of microbial genomes, including anatomy and structure. It covers the difference between prokaryotic and eukaryotic genomes, including features such as genome size, coding regions, and non-coding regions.

Full Transcript

**3**

**ASPECTS OF THE MICROBIAL GENOME**

- **Anatomy of microbial and eukaryotic genomes**

Biologists recognize that the living world comprises two types of
organism ([Figure
2.1](https://www.ncbi.nlm.nih.gov/books/NBK21120/figure/A5469/?report=objectonly)):

1. As mentioned before, prokaryotes have smaller genome compared with
that of eukaryotes (Figure 26). Genome size is measured
in [nucleotide](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5567/) pairs
of [DNA](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5084/) per [haploid](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5264/) [genome](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5222/),
that is, per single copy of the genome. (The cells of sexually
reproducing organisms such as ourselves are
generally [diploid](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5077/):
they contain two copies of the genome, one inherited from the
mother, the other from the father.) Closely related organisms can
vary widely in the quantity of DNA in their genomes, even though
they contain similar numbers of functionally distinct genes.

**Figure 26: Comparison of the length of genomes from different
organisms.**

2. Eucaryotes not only have more genes than procaryotes; they also have
vastly
more [DNA](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5084/) that
does not code
for [protein](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5688/) or
for any other functional
product [molecule](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5486/).
The
human [genome](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5222/) contains
a 1000 times as
many [nucleotide](https://www.ncbi.nlm.nih.gov/books/n/mboc4/A4754/def-item/A5567/) pairs
as the genome of a typical bacterium, 20 times as many genes, and
about 10,000 times as much noncoding DNA (\~98.5% of the genome for
a human is noncoding, as opposed to 11% of the genome for the
bacterium E. coli).

Genome regions could be:

- **Untranscribed region**: "non-coding regions" does not transcribed
as the regions of promoter and Silencers. Promoters provide binding
sites for the protein machinery that carries out transcription.
**Promoters** are typically found just ahead of the gene on the DNA
strand. **Silencers** provide binding sites for proteins that
repress transcription. Like enhancers, silencers can be found before
or after the gene they control and can be some distance away on the
DNA strand.

- **Transcribed non-coding region**: genes do not give proteins. Like
rRNA and tRNA genes.

- **Protein-coding regions**: Genes give protein. Check figure 27

![Non-coding RNAs: Junk or Critical Regulators in Health and
Disease? \| Biology \| MIT OpenCourseWare](media/image2.jpeg)

**Figure 27: Different regions in the genome of different types of
organisms.**

**Write your observation on this figure (27):**

3. Prokaryotic genomes are very different from eukaryotic ones.\
For example,
the *[E](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10200/).
coli* K12 genome is just
**4639 [kb](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10259/)
(Check table 2 to know the units for genome length)**, two-fifths
the size of the yeast genome, and has only **4405** genes. The
physical organization of the genome is also different in eukaryotes
and prokaryotes. The traditional view has been that an entire
prokaryotic genome is contained in **a single
circular [DNA](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9330/) molecule**.
As well as this single 'chromosome', prokaryotes may also have
additional genes on independent smaller, circular or linear DNA
molecules
**called [plasmid](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9784/)s
(Fig. 28)**.\
Genes carried by plasmids are useful, coding for properties such as
antibiotic resistance or the ability to utilize complex compounds
such as toluene as a carbon source, but plasmids appear to be
dispensable - a prokaryote can **exist quite effectively without
them**.\
We now know that this traditional view of the prokaryotic genome has
been biased by the extensive research on *E. coli*, which has been
accompanied by the mistaken assumption that *E. coli* is a typical
prokaryote. In fact, prokaryotes display a considerable diversity in
genome organization, some having a **unipartite genome**, like *E.
coli,* but others being more complex. *Borrelia burgdorferi* B31,
for example, has a linear chromosome of 911 kb, carrying 853 genes,
accompanied by 17 or 18 linear and circular molecules, which
together contribute another 533 kb and at least 430 genes.
**Multipartite genomes** are now known in many other bacteria and
archaea.

**Table 2: Units to express DNA length**

Biomedical Data

**Which unit is suitable for human genome and a gene??**

![Figure 2.3. Plasmids are small circular DNA molecules that are found
inside some prokaryotic cells.](media/image4.jpeg)

**Figure 28: Nucleoids and plasmids of Bacteria.**

4. Prokaryotic genomes are even **more compact** than those of yeast
and other lower eukaryotes. We can see this fact illustrated
in Figure 29, which shows a
50-[kb](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10259/) segment
of the *E. coli* K12 genome **[compared to other organisms same
fragment]**. It is immediately obvious that there are
more genes and less space between them, with 43 genes taking up
85.9% of the segment. Some genes have virtually no space between
them: *thrA* and *thrB*, for example, are separated by a single
nucleotide, and *thrC* begins at the nucleotide immediately
following the last nucleotide of *thrB*. These three genes are an
example of
an [operon](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9735/),
a group of genes involved in a single biochemical pathway (in this
case, synthesis of the amino acid threonine) and expressed in
conjunction with one another. Operons have been used as model
systems for understanding how gene expression is regulated. Check
figure 30 to know the genes organization in both prokaryotes and
eukaryotes.

Figure 2.2. Comparison of the genomes of humans, yeast, fruit flies,
maize and Escherichia coli.

### **Figure 29: Comparison of the genomes of humans, yeast, fruit flies, maize and *Escherichia coli.* ([A](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10140/)) is the 50-[kb](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10259/) segment of the human β [T](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10347/)-cell receptor locus shown. This is compared with 50-kb segments from the genomes of (B) *Saccharomyces* *cerevisiae* (chromosome III; redrawn; ([C](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10162/)) *Drosophila melanogaster* ; ([D](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10178/)) maize and ([E](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10200/)) *E. coli* K12. See the text for more details.**

![A white sign with text and colorful arrows Description automatically
generated with medium confidence](media/image6.png)

**Figure 30: Operon organization in prokaryotes**

5. In general, **prokaryotic genes are shorter than their eukaryotic
counterparts**, the average length of a bacterial gene being about
**two-thirds** that of a eukaryotic gene, even after the introns
have been removed from the latter. Bacterial genes appear to be
slightly longer than archaeal ones.

6. There are **no introns (Figure 31)** in the genes present in this
segment of
the *[E](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10200/).
coli* genome. In fact, *E. coli* has no discontinuous genes at all,
and it is generally believed that this type of gene structure is
virtually **absent in prokaryotes**, the few exceptions occurring
mainly among the archaea.

Contrasting the Regulation of Gene Expression in Prokaryotic &
Eukaryotic Organisms Practice \| Biology Practice Problems \|
Study.com

**Figure 31: eukaryotic and prokaryotic genes and operon structure
in prokaryotes**

7. The second feature is the **infrequency of repetitive sequences**.
Most prokaryotic genomes do not have anything equivalent to the
high-copy-number genome-wide repeat families found in eukaryotic
genomes. They do, however, possess certain sequences that might be
repeated elsewhere in the genome, examples being the [insertion
sequences](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9558/) IS1
and IS186 that can be seen in the
50-[kb](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10259/) segment
shown in Figure 27.

8. **Insertion sequence**

[A](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10140/) short
transposable element found in bacteria as indicated in figure 32.

![A diagram of a gene sequence Description automatically
generated](media/image8.png)

**Figure 32: The insertion sequence (transposons) of bacteria**

- #### **Complications on the E. coli theme**

1. In recent years it has become clear that the straightforward view of
prokaryotic genome anatomy developed from studies
of *[E](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10200/).
coli* is an over-simplification. Although the majority of bacterial
and archaeal chromosomes are indeed circular, an increasing number
of linear ones are being found. The first of these was found in
for *Borrelia burgdorferi* and  *Streptomyces*.

2. [A](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10140/) second
complication concerns the precise status of plasmids with regard to
the prokaryotic genome. A plasmid is a small piece
of [DNA](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9330/),
often, but not always circular, that coexists with the main
chromosome in a bacterial cell. Some types of plasmid are able to
integrate into the main genome, but others are thought to be
permanently independent. Plasmids carry genes that are not usually
present in the main chromosome, but in many cases these genes are
non-essential to the bacterium, coding for characteristics such as
antibiotic resistance, which the bacterium does not need if the
environmental conditions are amenable Table 3. As well as this
apparent dispensability, many plasmids are able to transfer from one
cell to another, and the same plasmids are sometimes found in
bacteria that belong to different species. These various features of
plasmids suggest that they are independent entities and that in most
cases the plasmid content of a prokaryotic cell should not be
included in the definition of its genome.

### **Table 3: features of typical plasmids**

**Type of plasmid** **[Gene](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9448/) functions** **Examples**
--------------------- ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Resistance Antibiotic resistance Rbk of *Escherichia coli* and other bacteria
Fertility [Conjugation](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9260/) and [DNA](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9330/) transfer between bacteria [F](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10213/) of *[E](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10200/). coli*
Killer Synthesis of toxins that kill other bacteria [Col](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10170/) of *[E](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10200/). coli*, for colicin production
Degradative Enzymes for metabolism of unusual molecules [TOL](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10359/) of *Pseudomonas putida*, for toluene metabilism
Virulence Pathogenicity [Ti](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10353/) of *Agrobacterium tumefaciens*, conferring the ability to cause crown gall disease on dicotyledonous plants

With a bacterium such
as *[E](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10200/).
coli* K12, which has a
4.6-[Mb](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10271/) chromosome
and can harbor various combinations of plasmids, none of which is more
than a
few [kb](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10259/) in
size and all of which are dispensable, it is acceptable to define the
main chromosome as the 'genome'. With other prokaryotes it is not so
easy Table 4. *Vibrio cholerae*, the pathogenic bacterium that causes
cholera, has two
circular [DNA](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9330/) molecules,
one of 2.96 Mb and the other of 1.07 Mb, with 71% of the organism\'s
3885 genes on the larger of these ([Heidelberg *et al.*,
2000](https://www.ncbi.nlm.nih.gov/books/NBK21120/)). It would appear
obvious that these two DNA molecules together constitute
the *Vibrio* genome, but closer examination reveals that most of the
genes for the central cellular activities such as genome expression and
energy generation, as well as the genes that confer pathogenicity, are
located on the larger molecule. The smaller molecule contains many
essential genes but also has certain features that are considered
characteristic of plasmids, notably
an [integron](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9565/),
a set of genes and other DNA sequences that enable plasmids to capture
genes from bacteriophages and other plasmids. It therefore appears
possible that the smaller genome is a 'megaplasmid' that was acquired by
the ancestor to *Vibrio* at some period in the bacterium\'s evolutionary
past. *Deinococcus radiodurans* R1, whose genome is of particular
interest because it contains many genes that help this bacterium resist
the harmful effects of radiation, is constructed on similar lines, with
essential genes distributed among two circular chromosomes and two
plasmids ([White *et al.*,
1999](https://www.ncbi.nlm.nih.gov/books/NBK21120/)). However,
the *Vibrio* and *Deinococcus* genomes are relatively non-complex
compared with *Borrelia burgdorferi* B31, whose linear chromosome of 911
kb, carrying 853 genes, is accompanied by 17 or 18 linear and circular
plasmids which together contribute another 533 kb and at least 430 genes
([Fraser *et al.*, 1997](https://www.ncbi.nlm.nih.gov/books/NBK21120/)).

### **Table 4: Examples of genome organization in prokaryotes**

**[Genome](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9469/) organization**
------------------------------------------------------------------------------------------------- ----------------------------------------------------------------------------------------- --------------------------------------------------------------------------------------- ---------------------
**Species** **[DNA](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9330/) molecules** **Size ([Mb](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10271/))** **Number of genes**
*Escherichia coli* [K](https://www.ncbi.nlm.nih.gov/books/n/genomes/A10138/def-item/A10258/)-12 One circular molecule 4.639 4397
*Vibrio cholerae* El Tor N16961 **Two circular molecules**
 Main chromosome 2.961 2770
 Megaplasmid 1.073 1115
*Deinococcus radiodurans* R1 **Four circular molecules**
 [Chromosome](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9225/) 1 2.649 2633
 [Chromosome](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9225/) 2 0.412 369
 Megaplasmid 0.177 145
 [Plasmid](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9784/) 0.046 40
*Borrelia burgdorferi* B31 **Three circular molecules, 11 linear molecules**
 Linear chromosome 0.911 853
 Circular plasmid cp9 0.009 12
 Circular plasmid cp26 0.026 29
 Circular plasmid cp32\* 0.032 Not known
 Linear plasmid lp17 0.017 25
 Linear plasmid lp25 0.024 32
 Linear plasmid lp28-1 0.027 32
 Linear plasmid lp28-2 0.030 34
 Linear plasmid lp28-3 0.029 41
 Linear plasmid lp28-4 0.027 43
 Linear plasmid lp36 0.037 54
 Linear plasmid lp38 0.039 52
 Linear plasmid lp54 0.054 76
 Linear plasmid lp56 0.056 Not known

Although the functions of most of these genes are unknown, those that
have been identified include several that would not normally be
considered dispensable, such as genes for membrane proteins and purine
biosynthesis. The implication is that at least some of
the *Borrelia* plasmids are essential components of the genome, leading
to the possibility that some prokaryotes have highly multipartite
genomes, comprising a number of separate DNA molecules, more akin to
what we see in the eukaryotic nucleus rather than the 'typical'
prokaryotic arrangement. This interpretation of the *Borrelia* genome is
still controversial, and is complicated by the fact that the related
bacterium *Treponema pallidum*, whose genome is a single circular DNA
molecule of 1138 kb containing 1041 genes ([Fraser *et al.*,
1998](https://www.ncbi.nlm.nih.gov/books/NBK21120/)), does not contain
any of the genes present on the *Borrelia* plasmids.

3. The final complication regarding the physical structures of
prokaryotic genomes concerns differences between the packaging
systems for bacterial and
archaeal [DNA](https://www.ncbi.nlm.nih.gov/books/n/genomes/A9089/def-item/A9330/) molecules.
One reason why the archaea are looked upon as a distinct group of
organisms, different from the bacteria, is that archaea do not
possess packaging proteins such as HU but instead have proteins that
are much more similar to histones. Currently we have no information
on the structure of the archaeal nucleoid, but the assumption is
that these histone-like proteins play a central role in DNA
packaging.

**Compare between pro and eu-karyotic genomes**

*li*.