Molecular Genetics Lecture 4 PDF

Summary

This lecture covers the classification of genes based on various criteria such as function, inheritance, and expression patterns. It also explores gene evolution, highlighting the role of mutations and gene duplication in the diversification of genes. The lecture also delves into the importance of homologous genes for understanding evolutionary relationships.

Full Transcript

Molecular
Genetics
Lecture 4
Prof. Amr M.
Mowafy

1
- Gene classification based on purpose of study

- Gene evolutions
Some Genes Evolve Rapidly; Others Are Highly Conserved

New Genes Are Generated from Preexisting Genes

Gene Duplications Give Rise to Families of Related Genes Within a Single Cell

The Function of a Gene Can Often Be Deduced from Its Sequence

More Than 200 Gene Families Are Common to All Three Primary Branches of the Tree of Life

2
Gene classification based on purpose of study

3
Genes can be classified in various ways based on different
criteria. Here are a few common ways in which genes are
classified:

1.Function: Genes can be classified based on their function,
such as structural genes that code for proteins, regulatory
genes that control gene expression, and non-coding genes that
do not code for proteins but have other regulatory functions,
and pseudogenes (non-functional copies of genes).
2.Inheritance: Genes can be classified based on their
inheritance patterns, such as autosomal genes located on
autosomes (non-sex chromosomes) or sex-linked genes located
on sex chromosomes.

4
3. Expression: Genes can be classified based on their
expression patterns, such as housekeeping genes that are
expressed constitutively in all cell types, tissue-specific genes
that are expressed only in specific tissues, or inducible genes
that are expressed in response to specific stimuli.
4. Evolutionary Conservation: Genes can be classified
based on their evolutionary conservation across species, such
as orthologs (genes in different species that evolved from a
common ancestor) and paralogs (genes that arise from gene
duplication within a species).
5. Location: Genes can be classified based on their genomic
location, such as genes located on different chromosomes or
genes clustered together in the same genomic region (gene
families).
6. Role in Disease: Genes can be classified based on their 5
GENE EVOLUTION

6
Some Genes Evolve Rapidly; Others Are Highly
Conserved

Both in the storage and in the copying of genetic information,
random accidents and errors occur, altering the nucleotide sequence
—that is, creating mutations. Therefore, when a cell divides, its two
daughters are often not quite identical to one another or to their
parent.
- On rare occasions, the error may represent a change for the better;
- more probably, it will cause no significant difference in the cell's
prospects;
- and in many cases, the error will cause serious damage—for
example, by disrupting the coding sequence for a key protein.
7
Changes due to mistakes of the first type will tend to be
perpetuated, because the altered cell has an increased likelihood
of reproducing itself.
Changes due to mistakes of the second type—selectively
neutral changes—may be perpetuated or not: in the competition
for limited resources, it is a matter of chance whether the altered
cell or its cousins will succeed.
But changes that cause serious damage lead nowhere: the cell
that suffers them dies, leaving no progeny. Through endless
repetition of this cycle of error and trial—
of mutation and natural selection—organisms evolve: their
genetic specifications change, giving them new ways to exploit
the environment more effectively, to survive in competition with
others, and to reproduce successfully. 8
Clearly, some parts of the genome change more easily than others in
the course of evolution. A segment of DNA that does not code for
protein and has no significant regulatory role is free to change at a
rate limited only by the frequency of random errors. In contrast,
a gene that codes for a highly optimized essential protein or RNA
molecule cannot alter so easily: when mistakes occur, the faulty
cells are almost always eliminated. Genes of this latter sort are
therefore highly conserved. Through 3.5 billion years or more of
evolutionary history, many features of the genome have changed
beyond all recognition; but the most highly conserved genes remain
perfectly recognizable in all living species.

9
These latter genes are the ones that must be
examined if we wish to trace family relationships
between the most distantly related organisms in the
tree of life. The studies that led to the classification of
the living world into the three domains of bacteria,
archaea, and eucaryotes were based chiefly on
analysis of one of the ribosomal RNA subunits—the so-
called 16S RNA, which is about 1500 nucleotides long.
Because the process of translation is fundamental to
all living cells, this component of the ribosome has
been well conserved since early in the history of life
on Earth (Figure 1-22).

10
Figure 1-22Genetic information conserved since the beginnings of life
A part of the gene for the smaller of the two main RNA components of the ribosome is shown.
Corresponding segments of nucleotide sequence from an archaean (Methanococcus jannaschii), a
eubacterium (Escherichia coli) and a eucaryote (Homo sapiens) are aligned in parallel. Sites where the
nucleotides are identical between species are indicated by a vertical line; the human sequence is repeated at
the bottom of the alignment so that all three two-way comparisons can be seen. A dot halfway along the E.
coli sequence denotes a site where a nucleotide has been either deleted from the eubacterial lineage in the
course of evolution, or inserted in the other two lineages. Note that the sequences from these three organisms,
representative of the three domains of the living world, all differ from one another to a roughly similar
degree, while still retaining unmistakable similarities.

11
 New Genes Are Generated from Preexisting Genes

The raw material of evolution is the DNA sequence that already exists: there
is no natural mechanism for making long stretches of new random sequence.
In this sense, no gene is ever entirely new. Innovation can, however, occur in
several ways (Figure 1-23):

Intragenic mutation: an existing gene can be modified by mutations in its
DNA sequence.
Gene duplication: an existing gene can be duplicated so as to create a pair
of closely related genes within a single cell.

12
 Segment shuffling: two or more existing genes can be broken and
rejoined to make a hybrid gene consisting of DNA segments that
originally belonged to separate genes.

Horizontal (intercellular) transfer: a piece of DNA can be
transferred from the genome of one cell to that of another—even to
that of another species. This process is in contrast with the
usual vertical transfer of genetic information from parent to
progeny.

13
Four modes of genetic innovation
and their effects on the DNA
sequence of an organism.

14
Each of these types of change leaves a characteristic
trace in the DNA sequence of the organism, providing
clear evidence that all four processes have occurred.

15
Gene Duplications Give Rise to Families of Related Genes Within a Single
Cell
A cell must duplicate its entire genome each time it divides into two
daughter cells. However, accidents occasionally result in the
duplication of just part of the genome, with retention of original and
duplicate segments in a single cell. Once a gene has been duplicated
in this way, one of the two gene copies is free to mutate and become
specialized to perform a different function within the same cell.
Repeated rounds of this process of duplication and divergence, over
many millions of years, have enabled one gene to give rise to a
whole family of genes within a single genome. Analysis of the
DNA sequence of procaryotic genomes reveals many examples of
such gene families: in Bacillus subtilis, for example, 47% of
the genes have one or more obvious relatives (Figure 1-24).
16
When genes duplicate and diverge in this way, the individuals of one
species become endowed with multiple variants of a primordial gene.
This evolutionary process has to be distinguished from the genetic
divergence that occurs when one species of organism splits into two
separate lines of descent at a branch point in the family tree—when the
human line of descent became separate from that of chimpanzees, for
example. There, the genes gradually become different in the course of
evolution, but they are likely to continue to have corresponding functions
in the two sister species. Genes that are related in this way—that
is, genes in two separate species that derive from the same
ancestral gene in the last common ancestor of those two species—are
said to be orthologs. Related genes that have resulted from
a gene duplication event within a single genome—and are likely to have
diverged in their function—are said to be paralogs. Genes that are
related by descent in either way are called homologs, a general term used
to cover both types of relationship 17
Paralogous genes and orthologous genes: two types
of gene homology based on different evolutionary pathways. (A)
and (B) The most basic possibilities. (C) A more complex
pattern of events that can occur.

18
 The Function of a Gene Can Often Be Deduced from Its
Sequence

Family relationships among genes are important not just for their historical
interest, but because they lead to a spectacular simplification in the task of
deciphering gene functions. Once the sequence of a newly discovered genehas
been determined, it is now possible, by tapping a few keys on a computer, to
search the entire database of known gene sequences for genes related to it. In
many cases, the function of one or more of these homologs will have been
already determined experimentally, and thus, since gene sequence
determines gene function, one can frequently make a good guess at the
function of the new gene: it is likely to be similar to that of the already-known
homologs.

19
In this way, it becomes possible to decipher a great deal of
the biology of an organism simply by analyzing the DNA
sequence of its genome and using the information we
already have about the functions of genes in other
organisms that have been more intensively
studied. Mycobacterium tuberculosis, the eubacterium that
causes tuberculosis, is extremely difficult to study
experimentally in the laboratory and provides an example of
the power of comparative genomics. DNA sequencing has
revealed that this organism has a genome of 4,411,529
nucleotide pairs, containing approximately 4000 genes.
20
Of these genes, 40% were immediately recognizable (when the genome was
sequenced, in 1998) as homologs of known genes in other species, and could
be tentatively assigned a function on that basis. Another 44% showed some
informative similarity to other known genes—for example, containing a
conserved protein domain within a longer amino acid sequence. Only 16% of
the 4000 genes were totally unfamiliar. As we saw also for Bacillus
subtilis(see Figure 1-24), about half the genes have sequences closely similar
to those of other genes in the M. tuberculosis genome, showing that they must
have arisen through relatively recent gene duplications. Compared with other
bacteria, M. tuberculosis contains an exceptionally large number
of genescoding for enzymes involved in the synthesis and degradation of lipid
(fatty) molecules. This presumably reflects this bacterium's production of an
unusual outer coat that is rich in these substances; the coat, and the enzymes
that produce it, may explain how M. tuberculosis escapes destruction by the
immune system of tuberculosis patients.
21
More Than 200 Gene Families Are Common to All Three Primary
Branches of the Tree of Life

Given the complete genome sequences of representative organisms from all
three domains—archaea, eubacteria, and eucaryotes—one can search
systematically for homologies that span this enormous evolutionary divide. In
this way we can begin to take stock of the common inheritance of all living
things. Because of all these vagaries of the evolutionary process, it seems that
only a small proportion of ancestral gene families have been universally retained
in a recognizable form. Thus, out of 2264 protein-coding gene families recently
defined by comparing the genomes of 18 bacteria, 6 archaeans and 1 eucaryote
(yeast), only 76 are truly ubiquitous (that is, represented in all the genomes
analyzed). The great majority of these universal families include components of
the translation and transcription systems.
22
A better—though still crude—idea of the latter can be obtained by
tallying the gene families that have representatives in multiple, but not
necessarily all, species from all three major kingdoms. Such an
analysis reveals 239 ancient conserved families. With a single
exception, these families can be assigned a function (at least in terms
of general biochemical activity, but usually with more precision), with
the largest number of shared gene families being involved in
translation and ribosome production and in amino acid metabolism
and transport (Table 1-2).

23
24
MOLECULAR BIOLOGY OF THE CELL
https://www.ncbi.nlm.nih.gov/books/NBK26866/

25