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[交流] gene 8 word 文档形式 chapter1 1.1-1.4

GENE EIGHT
GENES is continuously updated on the web site, www.ergito.com with revisions posted weekly. This allows readers to check for revised sections and relate them to the printed book. The web site can be viewed as either sections from the book or as a slide show of the figures from the book. Some of the figures shown are animated and there are references hyperlinked to the original sources. Other features of the web site include a glossary, sophisticated searches, and ancillary material such as the essays in the Great Experiments and Structures Series. To subscribe to this site, please visit www.ergito.com.
Genes are DNA
1.1 Introduction
The hereditary nature of every living organism is defined by its genome, which consists of a long sequence of nucleic acid that provides the information needed to construct the organism. We use the term "information" because the genome does not itself perform any active role in building the organism; rather it is the sequence of the individual subunits (bases) of the nucleic acid that determines hereditary features. By a complex series of interactions, this sequence is used to produce all the proteins of the organism in the appropriate time and place. The proteins either form part of the structure of the organism, or have the capacity to build the structures or to perform the metabolic reactions necessary for life.
The genome contains the complete set of hereditary information for any organism. Physically the genome may be divided into a number of different nucleic acid molecules. Functionally it may be divided into genes. Each gene is a sequence within the nucleic acid that represents a single protein. Each of the discrete nucleic acid molecules comprising the genome may contain a large number of genes. Genomes for living organisms may contain as few as <500 genes (for a mycoplasma, a type of bacterium) to as many as >40,000 for Man. In this chapter, we analyze the properties of the gene in terms of its basic molecular construction. Figure 1.1 summarizes the stages in the transition from the historical concept of the gene to the modern definition of the genome.
The basic behavior of the gene was defined by Mendel more than a century ago. Summarized in his two laws, the gene was recognized as a "particulate factor" that passes unchanged from parent to progeny. A gene may exist in alternative forms. These forms are called alleles. In diploid organisms, which have two sets of chromosomes, onecopy of each chromosome is inherited from each parent. This is the same behavior that is displayed by genes. One of the two copies of each gene is the paternal allele (inherited from the father), the other is the maternal allele (inherited from the mother). The equivalence led to the discovery that chromosomes in fact carry the genes.
Each chromosome consists of a linear array of genes. Each gene resides at a particular location on the chromosome. This is more formally called a genetic locus. We can then define the alleles of this gene as the different forms that are found at this locus. The key to understanding the organization of genes into chromosomes
was the discovery of genetic linkage. This describes the observation that alleles on the same chromosome tend to remain together in the progeny instead of assorting independently as predicted by Mendel's laws. Once the unit of recombination (reassortment) was introduced as the measure of linkage, the construction of genetic maps became possible. On the genetic maps of higher organisms established during the first half of this century, the genes are arranged like beads on a string. They occur in a fixed order, and genetic recombination involves transfer of corresponding portions of the string between homologous chromosomes. The gene is to all intents and purposes a mysterious object (the bead), whose relationship to its surroundings (the string) is unclear. The resolution of the recombination map of a higher eukaryote is restricted by the small number of progeny that can be obtained from each mating. Recombination occurs so infrequently between nearby points that it is rarely observed between different mutations in the same gene. By moving to a microbial system in which a very large number of progeny can be obtained from each genetic cross, it became possible to demonstrate that recombination occurs within genes. It follows the same rules that were previously deduced for recombination between genes. Mutations within a gene can be arranged into a linear order, showing that the gene itself has the same linear construction as the array of genes on a chromosome. So the genetic map is linear within as well as between loci: it consists of an unbroken sequence within which the genes reside. This conclusion leads naturally into the modern view that the genetic material of a chromosome consists of an uninterrupted length of DNA representing many genes. A genome consists of the entire set of chromosomes for any particular organism. It therefore comprises a series of DNA molecules (one for each chromosome), each of which contains many genes. The ultimate definition of a genome is to determine the sequence of the DNA of each chromosome. The first definition of the gene as a functional unit followed from the discovery that individual genes are responsible for the production of specific proteins. The difference in chemical nature between the DNA of the gene and its protein product led to the concept that a gene codes for a protein. This in turn led to the discovery of the complex apparatus that allows the DNA sequence of gene to generate the amino acid sequence of a protein.
Understanding the process by which a gene is expressed allows us to make a more rigorous definition of its nature. Figure 1.2 shows the basic theme of this book. A gene is a sequence of DNA that produces another nucleic acid, RNA. The DNA has two strands of nucleic acid, and the RNA has only one strand. The sequence of the RNA is determined by the sequence of the DNA (in fact, it is identical to one of the DNA strands). In many, but not in all cases, the RNA is in turn used to direct production of a protein. Thus a gene is a sequence of DNA that codes for
an RNA; in protein-coding genes, the RNA in turn codes for a protein. From the demonstration that a gene consists of DNA, and that a chromosome consists of a long stretch of DNA representing many genes, we move to the overall organization of the genome in terms of its DNA sequence. In 2 The interrupted gene we take up in more detail the organization of the gene and its representation in proteins. In 3 The content of the genome we consider the total number of genes, and in 4
Clusters and repeats we discuss other components of the genome and the maintenance of its organization.
1.2 DNA is the genetic material of bacteria
The idea that genetic material is nucleic acid had its roots in the discovery of transformation in 1928. The bacterium Pneumococcus kills mice by causing pneumonia. The virulence of the bacterium is determined by its capsular polysaccharide. This is a component of the surface that allows the bacterium to escape destruction by the host. Several types (I, II, III) of Pneumococcus have different capsular polysaccharides. They have a smooth (S) appearance. Each of the smooth Pneumococcal types can give rise to variants that fail to produce the capsular polysaccharide. These bacteria have a rough (R) surface (consisting of the material
that was beneath the capsular polysaccharide). They are avirulent. They do not kill the mice, because the absence of the polysaccharide allows the animal to destroy the bacteria. When smooth bacteria are killed by heat treatment, they losetheir ability to harm the animal. But inactive heat-killed S bacteria and the ineffectual variant R bacteria together have a quite different effect from either bacterium by itself. Figure 1.3shows that when they are jointly injected into an animal, the mouse dies as the result of a Pneumococcal infection. Virulent S bacteria can be recovered from the mouse postmortem. In this experiment, the dead S bacteria were of type III. The live R bacteria had been derived from type II. The virulent bacteria recovered from the mixed infection had the smooth coat of type III. So some property of the dead type III S bacteria can transform the live R bacteria so that they make the type III capsular polysaccharide, and as a result become virulent.
Figure 1.4 shows the identification of the component of the dead bacteria responsible for transformation. This was called the transforming principle. It was purified by developing a cell-free system, in which extracts of the dead S bacteria could be added to the live R bacteria before injection into the animal. Purification of the transforming principle in 1944 showed that it is deoxyribonucleic acid (DNA).
1.3 DNA is the genetic material of viruses
Having shown that DNA is the genetic material of bacteria, the next step was to demonstrate that DNA provides the genetic material in a quite different system. Phage T2 is a virus that infects the
DNA is the genetic material of bacteria SECTION 1.2
Key Concepts
; * Phage infection proved that DNA is the genetic material of :
• viruses. When the DNA and protein components of bacteriophages i
; are labeled with different radioactive isotopes, only the DNA is :
transmitted to the progeny phages produced by infecting bacteria. •
Key Concepts
I * Bacterial transformation provided the first proof that DNA is the :
: genetic material. Genetic properties can be transferred from one •
: bacterial strain to another by extracting DNA from the first strain :
: and adding it to the second strain. •
bacterium E. coli. When phage particles are added to bacteria, they adsorb to the outside surface, some material enters the bacterium, and then -20 minutes later each bacterium bursts open (lyses) to release a large number of progeny phage.
Figure 1.5 illustrates the results of an experiment in 1952 in which bacteria were infected with T2 phages that had been radioactively labeled either in their DNA component (with 32P) or in their protein component (with 35S). The infected bacteria were agitated in a blender, and two fractions were separated by centrifugation. One contained the
empty phage coats that were released from the surface of the bacteria. The other fraction consisted of the infected bacteria themselves. Most of the 32P label was present in the infected bacteria. The progeny phage particles produced by the infection contained ~30% ofthe original 32P label. The progeny received very little—less than 1%—of the protein contained in the original phage population. The phage coats consist of protein and therefore carried the 35S radioactive label. This experiment therefore showed directly that only the DNA of the parent phages enters the bacteria and then becomes part of the progeny phages, exactly the pattern of inheritance expected of genetic material. A phage (virus) reproduces by commandeering the machinery of an infected host cell to manufacture more copies of itself. The phage possesses genetic material whose behavior is analogous to that of cellular genomes: its traits are faithfully reproduced, and they are subject to the conclusion that the genetic material is BNA, wriemeir part of me
genome of a cell or virus. 1.4 DNA is the genetic material of animal cells
When DNA is added to populations of single eukaryotic cells growing in culture, the nucleic acid enters the cells, and in some of them results in the production of new proteins. When a purified DNA is used, its incorporation leads to the production of a particular protein. Figure 1.6 depicts one of the standard systems.
Although for historical reasons these experiments are described as transfection when performed with eukaryotic cells, they are a direct counterpart to bacterial transformation. The DNA that is introduced into the recipient cell becomes part of its genetic material, and is inherited in the same way as any other part. Its expression confers a new trait upon the cells (synthesis of thymidine kinase in the example of the figure). At first, these experiments were successful only with individual cells adapted to grow in a culture medium. Since then, however, DNA has been introduced into mouse eggs by microinjection; and it may become a stable part of the genetic material of the mouse (see 18.18 Genes can be injected into animal eggs).
Such experiments show directly not only that DNA is the genetic material in eukaryotes, but also that it can be transferred between different species and yet remain functional. The genetic material of all known organisms and many viruses is
DNA. However, some viruses use an alternative type of nucleic acid, ribonucleic acid (RNA), as the genetic material. The general principle of the nature of the genetic material, then, is that it is always nucleic acid; in fact, it is DNA except in the RNA viruses.
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gene 8 word 文档形式 chapter1 1.5-1.9

1.5 Polynucleotide chains have nitrogenous
bases linked to a sugar-phosphate backbone
The basic building block of nucleic acids is the nucleotide. This has three components:
• a nitrogenous base;
• a sugar;
• and a phosphate.
The nitrogenous base is a purine or pyrimidine ring. The base is linked to position 1 on a pentose sugar by a glycosidic bond from Ni of pyrimidines or N9 of purines. To avoid ambiguity between the numbering systems of the heterocyclic rings and the sugar, positions on the pentose are given a prime (')•
Nucleic acids are named for the type of sugar; DNA has 2'-deoxyribose, whereas RNA has ribose. The difference is that the sugar in RNA has an OH group at the 2' position of the pentose ring. The sugar can be linked by its 5' or 3' position to a phosphate group. A nucleic acid consists of a long chain of nucleotides. Figure 1.7 shows that the backbone of the polynucleotide chain consists of an alternating series of pentose (sugar) and phosphate residues. This is constructed by linking the 5' position of one pentose ring to the 3' position of the next pentose ring via a phosphate group. So the sugar-phosphate backbone is said to consist of 5'-3' phosphodiester linkages. The nitrogenous bases "stick out" from the backbone.
Each nucleic acid contains 4 types of base. The same two purines, adenine and guanine, are present in both DNA and RNA. The two pyrimidines in DNA are cytosine and thymine; in RNA uracil is found instead of thymine. The only difference between uracil and thymine is the presence of a methyl substituent at position C5. The bases are usually referred to by their initial letters. DNA contains A, G, C, T, while RNA contains A, G, C, U.
The terminal nucleotide at one end of the chain has a free 5' group; the terminal nucleotide at the other end has a free 3' group. It is conventional to write nucleic acid sequences in the 5'—>3' direction—that is, from the 5' terminus at the left to the 3' terminus at the right.
1.6 DNA is a double helix
The observation that the bases are present in different amounts in the DNAs of different species led to the concept that the sequence of bases is the form in which genetic information is carried. By the 1950s, the concept of genetic information was common: the twin problems it posed were working out the structure of the nucleic acid, and explaining how a sequence of bases in DNA could represent the sequence
of amino acids in a protein. Three notions converged in the construction of the double helix model for DNA by Watson and Crick in 1953:
• X-ray diffraction data showed that DNA has the form of a regular helix, making a complete turn every 34 A (3.4 nm), with a diameter of ~20 A (2 nm). Since the distance between adjacent nucleotides is 3.4 A, there must be 10 nucleotides per turn.
• The density of DNA suggests that the helix must contain two polynucleotide chains. The constant diameter of the helix can be explained if the bases in each chain face inward and are restricted so that a purine is always opposite a pyrimidine, avoiding partnerships of purine-purine (too wide) or pyrimidine-pyrimidine (too
narrow).
• Irrespective of the absolute amounts of each base, the proportion of G is always the same as the proportion of C in DNA, and the proportion of A is always the same as that of T. So the composition of any DNA can be described by the proportion of its bases that is G + C. This ranges from 26% to 74% for different species.
Watson and Crick proposed that the two polynucleotide chains in the double helix associate by hydrogen bonding between the nitrogenous bases. G can hydrogen bond specifically only with C, while A can bond specifically only with T. These reactions are described as base pairing, and the paired bases (G with C, or A with T) are said to be complementary. The model proposed that the two polynucleotide chains run in opposite directions (antiparallel), as illustrated in Figure 1.8. Looking along the helix, one strand runs in the 5'—>3' direction, while its partner runs 3'—»5'.
The sugar-phosphate backbone is on the outside and carries negative charges on the phosphate groups. When DNA is in solution in vitro, the charges are neutralized by the binding of metal ions, typically by Na+. In the cell, positively charged proteins provide some of the neutralizing force. These proteins play an important role in determining the organization of DNA in the cell.
The bases lie on the inside. They are flat structures, lying in pairs perpendicular to the axis of the helix. Consider the double helix in terms of a spiral staircase: the base pairs form the treads, as illustrated schematically in Figure 1.9. Proceeding along the helix, bases are stacked above one another, in a sense like a pile of plates.
Each base pair is rotated ~36° around the axis of the helix relative to the next base pair. So ~10 base pairs make a complete turn of 360°. The twisting of the two strands around one another forms a double helix with a minor groove (~12 A across) and a major groove (~22 A across), as can be seen from the scale model of Figure 1.10. The double helix is right-handed; the turns run clockwise looking along the helical axis. These features represent the accepted model for what is known as the B-formofDNA. It is important to realize that the B-form represents an average, not a precisely specified structure. DNA structure can change locally. If it has more base pairs per turn it is said to be overwound; if it has fewer base pairs per turn it is underwound. Local winding can be affected by the overall conformation of the DNA double helix in space or by the binding of proteins to specific sites.
1.7 DNA replication is semiconservative
It is crucial that the genetic material is reproduced accurately. Because the two polynucleotide strands are joined only by hydrogen bonds, they are able to separate without requiring breakage of covalent bonds. The specificity of base pairing suggests that each of the separated parental strands could act as a template strand for the synthesis of a complementary daughter strand. Figure 1.11 shows the principle that a new daughter strand is assembled on each parental strand.  The sequence of the daughter strand is dictated by the parental strand; an A in the parental strand causes a T to be placed in the daughter strand, a parental G directs incorporation of a daughter C, and so on. The top part of the figure shows a parental (unreplicated) duplex that consists of the original two parental strands. The lower part shows the two daughter duplexes that are being produced by complementary base pairing. Each of the daughter duplexes is identical in sequence with the original parent, and contains one parental strand and one newly synthesized strand. The structure of DNA carries the information needed to perpetuate its sequence.
The consequences of this mode of replication are illustrated in Figure 1.12. The parental duplex is replicated to form two daughter duplexes, each of which consists of one parental strand and one (newly synthesized) daughter strand. The unit conserved from one generation to the next is one of the two individual strands comprising the parental duplex. This behavior is called semiconservative replication. The figure illustrates a prediction of this model. If the parental DNA "heavy,, density label because the organism has been grown in medium containing a suitable isotope (such as 15N), its strands can be distinguished from those that are synthesized when the organism is transferred to a medium containing normal "light" isotopes. The parental DNA consists of a duplex of two heavy strands (red). After one generation of growth in light medium, the duplex DNA is "hybrid" in density—it consists of one heavy parental strand (red) and one light daughter strand (blue). After a second generation, the two strands of each hybrid duplex have separated; each gains a light partner, so that now half of the duplex DNA remains hybrid while half is entirely light (both strands are blue). The individual strands of these duplexes are entirely heavy or entirely light. This pattern was confirmed experimentally in the Meselson- Stahl experiment of 1958, which followed the semiconservative replication of DNA through three generations of growth of E. coll. When DNA was. extracted from bacteria and its density measured by centrifugation, the DNA formed bands corresponding to its density— heavy for parental, hybrid for the first generation, and half hybrid and half light in the second generation.
1.8 DNA strands separate at the replication fork
Key Concepts
• Replication of DNA is undertaken by a complex of enzymes that separate the parental strands and synthesize the daughter strands.
• The replication fork is the point at which the parental strands are separated.
• The enzymes that synthesize DNA are called DNA polymerases; the enzymes that synthesize RNA are RNA polymerases.
• Nucleases are enzymes that degrade nucleic acids; they include DNAases and RNAases, and can be divided into endonucleases and exonucleases.
Replication requires the two strands of the parental duplex to separate.
However, the disruption of structure is only transient and is reversed as the daughter duplex is formed. Only a small stretch of the duplex DNA is separated into single strands at any moment. The helical structure of a molecule of DNA engaged in replication is illustrated in Figure 1.13. The nonreplicated region consists of the parental duplex, opening into the replicated region where the two daughter duplexes have formed. The double helical structure is disrupted at the junction between the two regions, which is called the replication fork. Replication involves movement of the replication fork along the parental DNA, so there is a continuous unwinding of the parental strands and rewinding into daughter duplexes.The synthesis of nucleic acids is catalyzed by specific enzymes, which recognize the template and undertake the task of catalyzing the addition of subunits to the polynucleotide chain that is being synthesized. The enzymes are named according to the type of chain that is synthesized:
DNA polymerases synthesize DNA, and RNA polymerases synthesize RNA.
Degradation of nucleic acids also requires specific enzymes: deoxyribonucleases (DNAases) degrade DNA, and ribonucleases (RNAases) degrade RNA. The nucleases fall into the general classes of exonucleases and endonucleases: Endonucleases cut individual bonds within RNA or DNA molecules, generating discrete fragments. Some DNAases cleave both strands of a duplex DNA at the target site, while others cleave only one of the two strands. Endonucleases are involved in cutting reactions, as shown in Figure 1.14.
Exonucleases remove residues one at a time from the end of the molecule, generating mononucleotides. They always function on a single nucleic acid strand, and each exonuclease proceeds in a specific direction, that is, starting at either a 5' or at a 3' end and proceeding toward  the other end. They are involved in trimming reactions, as shown in Figure 1.15.
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gene 8 word 文档形式 chapter1 1.9

1.9 Nucleic acids hybridize by base pairing
Key Concepts
• Heating causes the two strands of a DNA duplex to separate.
• The Tm is the midpoint of the temperature range for denaturation.
• Complementary single strands can renature when the temperature is reduced.
• Denaturation and renaturation/hybridization can occur with DNA-DNA, DNA-RNA, or RNA-RNA combinations, and can be intermolecular or intramolecular.
• The ability of two single-stranded nucleic acid preparations to hybridize is a measure of their complementarity. Acrucial property of the double helix is the ability to separate the two strands without disrupting covalent bonds. This makes it possible for the strands to separate and reform under physiological conditions at the (very rapid) rates needed to sustain genetic functions. The specificity of the process is determined by complementary base pairing. The concept of base pairing is central to all processes involving nucleic acids. Disruption of the base pairs is a crucial aspect of the function of a double-stranded molecule, while the ability to form base pairs is essential for the activity of a single-stranded nucleic acid. Figure
1.16 shows that base pairing enables complementary single-stranded nucleic acids to form a duplex structure.
• An intramolecular duplex region can form by base pairing between two complementary sequences that are part of a single-stranded molecule.
• A single-stranded molecule may base pair with an independent, complementary single-stranded molecule to form an intermolecular duplex.
Formation of duplex regions from single-stranded nucleic acids is most important for RNA, but single-stranded DNA also exists (in the form of viral genomes). Base pairing between independent complementary single strands is not restricted to DNA-DNA or RNA-RNA, but can also occur between a DNA molecule and an RNA molecule. The lack of covalent links between complementary strands makes it possible to manipulate DNA in vitro. The noncovalent forces that stabilize the double helix are disrupted by heating or by exposure to low salt concentration. The two strands of a double helix separate entirely when all the hydrogen bonds between them are broken.
The process of strand separation is called denaturation or (more colloquially) melting. ("Denaturation" is also used to describe loss of authentic protein structure; it is a general term implying that the natural conformation of a macromolecule has been converted to some other form.) Denaturation of DNA occurs over a narrow temperature range and results in striking changes in many of its physical properties. The midpoint of the temperature range over which the strands of DNA separate is called the melting temperature (Tm). It depends on the proportion of GC base pairs. Because each G-C base pair has three hydrogen bonds, it is more stable than an A-T base pair, which has only two hydrogen bonds. The more G-C base pairs are contained in a DNA, the greater the energy that is needed to separate the two strands. In solution under  physiological conditions, a DNA that is 40% G-C—a value typical of  mammalian genomes—denatures with a Tm of about 87°C. So duplex  DNA is stable at the temperature prevailing in the cell.  The denaturation of DNA is reversible under appropriate conditions.  The ability of the two separated complementary strands to reform into a  double helix is called renaturation. Renaturation depends on specific  base pairing between the complementary strands. Figure 1.17 shows  that the reaction takes place in two stages. First, single strands of DNA  in the solution encounter one another by chance; if their sequences are  complementary, the two strands base pair to generate a short doublehelical  region. Then the region of base pairing extends along the molecule  by a zipper-like effect to form a lengthy duplex molecule.  Renaturation of the double helix restores the original properties that  were lost when the DNA was denatured.  Renaturation describes the reaction between two complementary sequences  that were separated by denaturation. However, the technique  can be extended to allow any two complementary nucleic acid sequences  to react with each other to form a duplex structure. This is  sometimes called annealing, but the reaction is more generally described  as hybridization whenever nucleic acids of different sources are  involved, as in the case when one preparation consists of DNA and the  other consists of RNA. The ability of two nucleic acid preparations to  hybridize constitutes a precise test for their complementarity since only  complementary sequences can form a duplex structure.  The principle of the hybridization reaction is to expose two singlestranded  nucleic acid preparations to each other and then to measure the  amount of double-stranded material that forms. Figure 1.18 illustrates a  procedure in which a DNA preparation is denatured and the single  strands are adsorbed to a filter. Then a second denatured DNA (or  RNA) preparation is added. The filter is treated so that the second  preparation can adsorb to it only if it is able to base pair with the DNA  that was originally adsorbed. Usually the second preparation is radioactively  labeled, so that the reaction can be measured as the amount of radioactive  label retained by the filter.  The extent of hybridization between two single-stranded nucleic  acids is determined by their complementarity. Two sequences need not  be perfectly complementary to hybridize. If they are closely related but  not identical, an imperfect duplex is formed in which base pairing is interrupted  at positions where the two single strands do not correspond.
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gene 8 word 文档形式 chapter1 1.10-1.13

1.10 Mutations change the sequence of DNA
Key Concepts
* All mutations consist of changes in the sequence of DNA.
• Mutations may occur spontaneously or may be induced by mutagens.
Mutations provide decisive evidence that DNA is the genetic material.  When a change in the sequence of DNA causes an alteration  in the sequence of a protein, we may conclude that the DNA codes  for that protein. Furthermore, a change in the phenotype of the organism  may allow us to identify the function of the protein. The existence  of many mutations in a gene may allow many variant forms of a protein  to be compared, and a detailed analysis can be used to identify regions  of the protein responsible for individual enzymatic or other functions.  All organisms suffer a certain number of mutations as the result of  normal cellular operations or random interactions with the environment.  These are called spontaneous mutations; the rate at which they  occur is characteristic for any particular organism and is sometimes  called the background level. Mutations are rare events, and of course  those that damage a gene are selected against during evolution. It is  therefore difficult to obtain large numbers of spontaneous mutants to  study from natural populations.  The occurrence of mutations can be increased by treatment with certain  compounds. These are called mutagens, and the changes they cause  are referred to as induced mutations. Most mutagens act directly by virtue  of an ability either to modify a particular base of DNA or to become incorporated  into the nucleic acid. The effectiveness of a mutagen is judged  by how much it increases the rate of mutation above background. By  using mutagens, it becomes possible to induce many changes in any gene.  Spontaneous mutations that inactivate gene function occur in bacteriophages  and bacteria at a relatively constant rate of 3-4 x 1(T3 per genome  per generation. Given the large variation in genome sizes between bacteriophages  and bacteria, this corresponds to wide differences in the mutation  rate per base pair. This suggests that the overall rate of mutation has  been subject to selective forces that have balanced the deleterious effects  of most mutations against the advantageous effects of some mutations.  This conclusion is strengthened by the observation that an archaeal microbe  that lives under harsh conditions of high temperature and acidity  (which are expected to damage DNA) does not show an elevated mutation  rate, but in fact has an overall mutation rate just below the average range.  Figure 1.19 shows that in bacteria, the mutation rate corresponds to  ~1(T6 events per locus per generation or to an average rate of change  per base pair of 10~9-10~10 per generation. The rate at individual base  pairs varies very widely, over a 10,000 fold range. We have no accurate  measurement of the rate of mutation in eukaryotes, although usually it  is thought to be somewhat similar to that of bacteria on a per-locus pergeneration  basis. We do not know what proportion of the spontaneous  events results from point mutations.  1.11 Mutations may affect single base pairs or
longer sequences
Key Concepts
• A point mutation changes a single base pair.
• Point mutations can be caused by the chemical conversion of one base into another or by mistakes that occur during replication.
• A transition replaces a G-C base pair with an A-T base pair or vice-versa.
• A transversion replaces a purine with a pyrimidine, such as
changing A-T to T-A.
• Insertions are the most common type of mutation, and result from
the movement of transposable elements.
• Chemical modification of DNA directly changes one base into a different base.
• A malfunction during the replication of DNA causes the wrong base to be inserted into a polynucleotide chain during DNA synthesis. Point mutations can be divided into two types, depending on the nature of the change when one base is substituted for another:
• The most common class is the transition, comprising the substitution of one pyrimidine by the other, or of one purine by the other. This replaces a GC pai* with an AT pair or vice versa.
• The less common class is the transversion, in which a purine is replaced by a pyrimidine or vice versa, so that an AT pair becomes a T A or C G pair.
The effects of nitrous acid provide a classic example of a transition caused by the chemical conversion of one base into another. Figure 1.20 shows that nitrous acid performs an oxidative deamination that  converts cytosine into uracil. In the replication cycle following the transition,  the U pairs with an A, instead of with the G with which the original  C would have paired. So the CG pair is replaced by a TA pair  when the A pairs with the T in the next replication cycle. (Nitrous acid  also deaminates adenine, causing the reverse transition from AT to  GC.)  Transitions are also caused by base mispairing, when unusual partners  pair in defiance of the usual restriction to Watson-Crick pairs.  Base mispairing usually occurs as an aberration resulting from the incorporation  into DNA of an abnormal base that has ambiguous pairing  properties. Figure 1.21 shows the example of bromouracil (BrdU), an  analog of thymine that contains a bromine atom in place of the methyl  group of thymine. BrdU is incorporated into DNA in place of thymine.  But it has ambiguous pairing properties, because the presence of the  bromine atom allows a shift to occur in which the base changes structure  from a keto ( O) form to an enol (-OH) form. The enol form can  base pair with guanine, which leads to substitution of the original AT  pair by a GC pair.  The mistaken pairing can occur either during the original incorporation  of the base or in a subsequent replication cycle. The transition  is induced with a certain probability in each replication cycle, so the  incorporation of BrdU has continuing effects on the sequence of  DNA.  Point mutations were thought for a long time to be the principal  means of change in individual genes. However, we now know that insertions  of stretches of additional material are quite frequent. The  source of the inserted material lies with transposable elements, sequences  of DNA with the ability to move from one site to another (see  16 Transposons and 17 Retroviruses and retroposons). An insertion  usually abolishes the activity of a gene. Where such insertions have occurred,  deletions of part or all of the inserted material, and sometimes  of the adjacent regions, may subsequently occur.  A significant difference between point mutations and the insertions/  deletions is that the frequency of point mutation can be increased  by mutagens, whereas the occurrence of changes caused by transposable  elements is not affected. However, insertions and deletions can  also occur by other mechanisms—for example, involving mistakes  made during replication or recombination—although probably these are  less common. And a class of mutagens called the acridines introduce  (very small) insertions and deletions.  1.12 The effects of mutations can be reversed
Key Concepts
• Forward mutations inactivate a gene, and back mutations (or revertants) reverse their effects.
• Insertions can revert by deletion of the inserted material, but deletions cannot revert.
• Suppression occurs when a mutation in a second gene bypasses the effect of mutation in the first gene.
Figure 1.22 shows that the isolation of revertants is an important"  characteristic that distinguishes point mutations and insertions  from deletions:  • A point mutation can revert by restoring the original sequence or by  gaining a compensatory mutation elsewhere in the gene.  • An insertion of additional material can revert by deletion of the  inserted material.  • A deletion of part of a gene cannot revert.  Mutations that inactivate a gene are called forward mutations. Their  effects are reversed by back mutations, which are of two types.  An exact reversal of the original mutation is called true reversion.  So if an AT pair has been replaced by a GC pair, another mutation to  restore the AT pair will exactly regenerate the wild-type sequence.  Alternatively, another mutation may occur elsewhere in the gene,  and its effects compensate for the first mutation. This is called secondsite  reversion. For example, one amino acid change in a protein may  abolish gene function, but a second alteration may compensate for the  first and restore protein activity.  A forward mutation results from any change that inactivates a gene,  whereas a back mutation must restore function to a protein damaged by  a particular forward mutation. So the demands for back mutation are  much more specific than those for forward mutation. The rate of back  mutation is correspondingly lower than that of forward mutation, typically  by a factor of ~\ 0.  Mutations can also occur in other genes to circumvent the effects of  mutation in the original gene. This effect is called suppression. A locus  in which a mutation suppresses the effect of a mutation in another locus  is called a suppressor.  
1.13 Mutations are concentrated at hotspots
Key Concepts
' The frequency of mutation at any particular base pair is  determined by statistical fluctuation, except for hotspots, where  the frequency is increased by at least an order of magnitude.  So far we have dealt with mutations in terms of individual changes  in the sequence of DNA that influence the activity of the genetic  unit in which they occur. When we consider mutations in terms of the  inactivation of the gene, most genes within a species show more or  less similar rates of mutation relative to their size. This suggests that  the gene can be regarded as a target for mutation, and that damage to  any part of it can abolish its function. As a result, susceptibility to mutation  is roughly proportional to the size of the gene. But consider the  sites of mutation within the sequence of DNA; are all base pairs in a  gene equally susceptible or are some more likely to be mutated than  others?  What happens when we isolate a large number of independent mutations  in the same gene? Many mutants are obtained. Each is the result of  an individual mutational event. Then the site of each mutation is determined.  Most mutations will lie at different sites, but some will lie at the  same position. Two independently isolated mutations at the same site  may constitute exactly the same change in DNA (in which case the  same mutational event has happened on more than one occasion), or  they may constitute different changes (three different point mutations  are possible at each base pair).  The histogram of Figure 1.23 shows the frequency with which mutations  are found at each base pair in the lad gene of E. coli. The statistical  probability that more than one mutation occurs at a particular site  is given by random-hit kinetics (as seen in the Poisson distribution). So
some sites will gain one, two, or three mutations, while others will not
gain any. But some sites gain far more than the number of mutations expected
from a random distribution; they may have 10x or even 100x
more mutations than predicted by random hits. These sites are called
hotspots. Spontaneous mutations may occur at hotspots; and different
mutagens may have different hotspots.
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