Biochemistry, 4th Edition P34 docx

Hydrogen bonding between purine and pyrimidine bases is fundamental to the biological functions of nucleic acids, as in the formation of the double-helix structure of DNA see Section 10.

The Properties of Pyrimidines and Purines Can Be Traced to Their

Electron-Rich Nature

The aromaticity of the pyrimidine and purine ring systems and the electron-rich

nature of their carbonyl and ring nitrogen substituents endow them with the

ca-pacity to undergo keto–enol tautomeric shifts That is, pyrimidines and purines

ex-ist as tautomeric pairs, as shown in Figure 10.6 for uracil and Figure 10.7 for

gua-nine The keto tautomers of uracil, thymine, and guanine vastly predominate at

neutral pH In other words, pKavalues for ring nitrogen atoms 1 and 3 in uracil

(Figure 10.6) are greater than 8 (the pKavalue for N-3 is 9.5) In contrast, the enol

form of cytosine predominates at pH 7 and the pKavalue for N-3 in this pyrimidine

is 4.5 Similarly, for guanine (Figure 10.7), the pKavalue is 9.4 for N-1 and less than

5 for N-3 These pKavalues specify whether protons are associated with the various

ring nitrogens at neutral pH As such, they are important in determining whether

these nitrogens serve as H-bond donors or acceptors Hydrogen bonding between

purine and pyrimidine bases is fundamental to the biological functions of nucleic

acids, as in the formation of the double-helix structure of DNA (see Section 10.5)

The important functional groups participating in H-bond formation are the amino

groups of cytosine, adenine, and guanine; the ring nitrogens at position 3 of

pyrim-idines and position 1 of purines; and the strongly electronegative oxygen atoms

at-tached at position 4 of uracil and thymine, position 2 of cytosine, and position 6 of

guanine (see Figure 10.17)

Another property of pyrimidines and purines is their strong absorbance of

ul-traviolet (UV) light, which is also a consequence of the aromaticity of their

hete-rocyclic ring structures Figure 10.8 shows characteristic absorption spectra of

Adenine (6-amino purine)

N N

NH2

Guanine (2-amino-6-oxy purine)

N N H

N

H2N

N N H N

H O

FIGURE 10.4 The common purine bases—adenine and guanine—in the tautomeric forms predominant at pH 7.

Hypoxanthine

N H N

H O

Xanthine

N H N H

H O O

Uric acid

N H N H

H O

H

O O

FIGURE 10.5 Other naturally occurring purine derivatives—hypoxanthine, xanthine, and uric acid.

O

Keto

N N H

Enol

N N

OH

H2N

N N H

N N H

H2N

FIGURE 10.7 The tautomerization of the purine guanine.

O

Keto

N N H

H O

Enol

N N HO OH

FIGURE 10.6 The keto–enol tautomerization of uracil.

294 Chapter 10 Nucleotides and Nucleic Acids

several of the common bases of nucleic acids—adenine, uracil, cytosine, and guanine—in their nucleotide forms: AMP, UMP, CMP, and GMP (see Section 10.3) This property is particularly useful in quantitative and qualitative analysis of nu-cleotides and nucleic acids

Nucleosidesare compounds formed when a base is linked to a sugar The sugars of

nu-cleosides are pentoses (five-carbon sugars, see Chapter 7) Ribonunu-cleosides contain

the pentose D-ribose, whereas 2-deoxy-D-ribose is found in deoxyribonucleosides.

In both instances, the pentose is in the five-membered ring form furanose:

D-ribofuranose for ribonucleosides and 2-deoxy-D-ribofuranose for deoxyribonucleo-sides (Figure 10.9) In nucleodeoxyribonucleo-sides, these ribofuranose atoms are numbered as 1, 2, 3, and so on to distinguish them from the ring atoms of the nitrogenous bases The

base is linked to the sugar via a glycosidic bond Glycosidic bonds in nucleosides (and

nucleotides, see following discussion) are always of the -configuration Nucleosides

are named by adding the ending -idine to the root name of a pyrimidine or -osine to the

root name of a purine The common nucleosides are thus cytidine, uridine, thymidine,

220

0

0.2

0.4

0.6

0.8

1.0

pH 7

pH 2

Wavelength, nm

pH 7

pH 1

0 0.2 0.4 0.6 0.8 1.0

0 0.2 0.4 0.6 0.8 1.0

0 0.2 0.4 0.6 0.8 1.0

FIGURE 10.8 The UV absorption spectra of the common

ribonucleotides.

HUMAN BIOCHEMISTRY

Adenosine: A Nucleoside with Physiological Activity

For the most part, nucleosides have no biological role other than

to serve as component parts of nucleotides Adenosine is a rare

exception In mammals, adenosine functions as an autacoid, or

“local hormone,” and as a neuromodulator This nucleoside

cir-culates in the bloodstream, acting locally on specific cells to

influence such diverse physiological phenomena as blood vessel

dilation, smooth muscle contraction, neuronal discharge,

neuro-transmitter release, and metabolism of fat For example, when

muscles work hard, they release adenosine, causing the

sur-rounding blood vessels to dilate, which in turn increases the flow

of blood and its delivery of O2and nutrients to the muscles In a

different autacoid role, adenosine acts in regulating heartbeat

The natural rhythm of the heart is controlled by a pacemaker, the

sinoatrial node, which cyclically sends a wave of electrical

excita-tion to the heart muscles By blocking the flow of electrical

cur-rent, adenosine slows the heart rate Supraventricular tachycardia is

a heart condition characterized by a rapid heartbeat Intravenous

injection of adenosine causes a momentary interruption of the

rapid cycle of contraction and restores a normal heart rate

Adenosine is licensed and marketed as Adenocard to treat

supraventricular tachycardia

In addition, adenosine is implicated in sleep regulation

Dur-ing periods of extended wakefulness, extracellular adenosine

lev-els rise as a result of metabolic activity in the brain, and this in-crease promotes sleepiness During sleep, adenosine levels fall Caffeine promotes wakefulness by blocking the interaction of ex-tracellular adenosine with its neuronal receptors.*

*Porrka-Heiskanen, T., et al., 1997 Adenosine: A mediator of the

sleep-inducing effects of prolonged wakefulness Science 276:1265–1268; and

Vaugeois, J-M., 2002 Signal transduction: Positive feedback from coffee.

Nature 418:734–736.

H3 C

H3C

H3 C O

N N

N

Caffeine

O

N

䊱 Caffeine is an alkaloid, a term used to define naturally occurring nitrogenous molecules that have pharmacological effects Alkaloids are classified according to their metabolic precursors, so caffeine is a purine alkaloid.

H O

C

H

H

H2COH

D -Ribose

1

3

4

5

O

OH OH

-D -Ribofuranose

Furanose form of D-Ribose

C

H2COH

D -2-Deoxyribose

1 2

5

O

-D -2-Deoxyribofuranose

Furanose form of D-2-Deoxyribose

OH H

5

3 2

H

H

H

H

3 4

2

1 4

5

2 3

FIGURE 10.9 Furanose structures—ribose and deoxyribose.

NH2

N

N

O

HOCH2

OH OH

Cytidine

O

N

N O HOCH2

OH OH

Uridine

O

N N O

HOCH2

OH OH

Adenosine

N N

N N O

HOCH2

OH OH

Guanosine

N

NH2

N N O

HOCH2

H

OH OH

Inosine, a less common nucleoside

N N

O

O

O H

Hypoxanthine FIGURE 10.10 The common ribonucleosides—cytidine,

uridine, adenosine, and guanosine—and the less-common inosine (Purine nucleosides and nucleotides usually adopt the anti conformation, where the purine ring is not above the ribose, as it would be in the syn conformation Pyrimidines are always anti, never syn, because the 2-O atom of pyrimidines sterically hinders the ring from a position above the ribose.)

adenosine, and guanosine (Figure 10.10) Nucleosides are more water soluble than the

free bases, because of the hydrophilicity of the pentose

A nucleotide results when phosphoric acid is esterified to a sugar OOH group of

a nucleoside The nucleoside ribose ring has three OOH groups available for

esterification, at C-2, C-3, and C-5 (although 2-deoxyribose has only two) The

vast majority of monomeric nucleotides in the cell are ribonucleotides having

5-phosphate groups Figure 10.11 shows the structures of the common four

ribo-nucleotides, whose formal names are adenosine 5ⴕ-monophosphate, guanosine

5 ⴕ-monophosphate, cytidine 5ⴕ-monophosphate, and uridine 5ⴕ-monophosphate.

These compounds are more often referred to by their abbreviations: 5ⴕ-AMP,

5 ⴕ-GMP, 5ⴕ-CMP, and 5ⴕ-UMP, or even more simply as AMP, GMP, CMP,

and UMP Because the pKavalue for the first dissociation of a proton from the

phosphoric acid moiety is 1.0 or less, the nucleotides have acidic properties This

acidity is implicit in the other names by which these substances are known—

adenylic acid, guanylic acid, cytidylic acid,and uridylic acid The pKavalue for

the second dissociation, pK2, is about 6.0, so at neutral pH or above, the net

charge on a nucleoside monophosphate is 2 Nucleic acids, which are polymers

of nucleoside monophosphates, derive their name from the acidity of these

phos-phate groups

296 Chapter 10 Nucleotides and Nucleic Acids

Cyclic Nucleotides Are Cyclic Phosphodiesters

Nucleoside monophosphates in which the phosphoric acid is esterified to two of the

available ribose hydroxyl groups (Figure 10.12) are found in all cells Forming two such ester linkages with one phosphate results in a cyclic phosphodiester structure

3 ⴕ,5ⴕ-cyclic AMP, often abbreviated cAMP, and its guanine analog 3ⴕ,5ⴕ-cyclic GMP,

or cGMP, are important regulators of cellular metabolism (see Parts 3 and 4). Nucleoside Diphosphates and Triphosphates Are Nucleotides with Two or Three Phosphate Groups

Additional phosphate groups can be linked to the phosphoryl group of a nucleotide through the formation of phosphoric anhydride linkages, as shown

in Figure 10.13 Addition of a second phosphate to AMP creates adenosine

5 ⴕ-diphosphate, or ADP, and adding a third yields adenosine 5ⴕ-triphosphate, or ATP. The respective phosphate groups are designated by the Greek letters ,

, and , starting with the -phosphate as the one linked directly to the pentose.

The abbreviations GTP, CTP, and UTP represent the other corresponding

nucle-oside 5-triphosphates Like the nuclenucle-oside 5-monophosphates, the nuclenucle-oside 5-diphosphates and 5-triphosphates all occur in the free state in the cell, as do their deoxyribonucleoside phosphate counterparts, represented as dAMP, dADP, and dATP; dGMP, dGDP, and dGTP; dCMP, dCDP, and dCTP; dUMP, dUDP, and dUTP; and dTMP, dTDP, and dTTP

NDPs and NTPs Are Polyprotic Acids

Nucleoside 5 ⴕ-diphosphates (NDPs) and nucleoside 5ⴕ-triphosphates (NTPs) are

relatively strong polyprotic acids in that they dissociate three and four protons,

re-spectively, from their phosphoric acid groups The resulting phosphate anions on NDPs and NTPs form stable complexes with divalent cations such as Mg2and Ca2 Because Mg2is present at high concentrations (as much as 40 mM) intracellularly,

NDPs and NTPs occur primarily as Mg2complexes in the cell

A phosphoester bond

P –O

NH2 N N O

OCH2

OH OH

Adenosine 5'-monophosphate (or AMP or adenylic acid)

N

N

–O

N O

OCH2

OH OH

Guanosine 5'-monophosphate (or GMP or guanylic acid)

N

N –O

H

NH2

P –O

N

N O OCH2

OH OH

Uridine 5'-monophosphate (or UMP or uridylic acid)

–O P

–O

N

N O

OH OH

Cytidine 5'-monophosphate (or CMP or cytidylic acid)

–O

H

O 5'

5' 5'

5' OCH2

NH2

O

P –O –O

NH2 N N O

HOCH2

A nucleoside 3'-monophosphate

3'-AMP

N N

O 3'

O

O

O

O

O

FIGURE 10.11 Structures of the four common ribonucleotides—AMP, GMP, CMP, and UMP Also shown is the nucleotide 3 -AMP.

N N O

C

3',5'-Cyclic AMP

N N

5'

NH2

3'

O

P

O

N N O

H

OH

3',5'-Cyclic GMP

N N

3'

O

H

NH2 O

–O

H

P

H

H

C

O

5' H

H

O

–O

FIGURE 10.12 The cyclic nucleotides cAMP and cGMP.

Nucleoside 5 ⴕ-Triphosphates Are Carriers of Chemical Energy

Nucleoside 5-triphosphates are indispensable agents in metabolism because the

phosphoric anhydride bonds they possess are a prime source of chemical energy to

do biological work

Virtually all of the biochemical reactions of nucleotides involve either phosphate

or pyrophosphate group transfer: the release of a phosphoryl group from an NTP to

give an NDP, the release of a pyrophosphoryl group to give an NMP unit, or the

ac-ceptance of a phosphoryl group by an NMP or an NDP to give an NDP or an NTP

(Figure 10.14) The pentose and the base are not directly involved in this chemistry.

A “division of labor” directs ATP to serve as the primary nucleotide in central

path-ways of energy metabolism, whereas GTP is used to drive protein synthesis Thus,

the various nucleotides are channeled in appropriate metabolic directions through

specific recognition of the base of the nucleotide The bases of nucleotides never

participate directly in the covalent bond chemistry that goes on

Nucleic acids are polynucleotides: linear polymers of nucleotides linked 3 to 5 by

phosphodiester bridges (Figure 10.15) They are formed as 5-nucleoside

mono-phosphates are successively added to the 3-OH group of the preceding nucleotide,

a process that gives the polymer a directional sense Polymers of ribonucleotides are

named ribonucleic acid, or RNA Deoxyribonucleotide polymers are called

deoxy-ribonucleic acid, or DNA Because C-1 and C-4 in deoxyribonucleotides are

in-volved in furanose ring formation and because there is no 2-OH, only the 3- and

5-hydroxyl groups are available for internucleotide phosphodiester bonds In the

case of DNA, a polynucleotide chain may contain hundreds of millions of

nu-cleotide units The convention in all notations of nucleic acid structure is to read the

polynu-cleotide chain from the 5-end of the polymer to the 3-end Note that this reading direction

actually passes through each phosphodiester from 3 to 5 (Figure 10.15) A

repeti-tious uniformity exists in the covalent backbone of polynucleotides

–O

NH2

N N O

OCH2

OH OH

AMP (adenosine 5'-monophosphate)

N

N

H O

5'

A phosphoric anhydride

–O

Phosphate (P i ) +

–O

NH2

N N O

OCH2

H

OH OH

ADP (adenosine 5'-diphosphate)

N N

5'

–O –O

O

+

–O

NH2

N N O

OCH2

OH OH

ADP

N N

5'

–O

–O

Phosphate +

–O

H O

–O

NH2

N N O

OCH2

OH OH

ATP (adenosine 5'-triphosphate)

N N

5'

–O

+

–O

FIGURE 10.13 Formation of ADP and ATP by the successive addition of phosphate groups via phosphoric

anhydride linkages Note that the reaction is a dehydration synthesis reaction.

298 Chapter 10 Nucleotides and Nucleic Acids

Uracil

P –O O

NH2 N N O

OCH2

N

N 5'

O

etc.

3'

P –O

NH 2 N N O OCH2

5' O

3'

O

P –O

NH2

N N O

OCH 2

N

N 5'

O

3'

P –O

N N O OCH2

5' O

3'

O

H

H

etc.

Adenine

Cytosine

Guanine

Ribonucleic acid (RNA)

Adenine

P –O

N O OCH2

O

5' O

etc.

3'

P –O

O OCH2

O

5' O

3'

P –O

O OCH 2

O

5' O

3'

P –O

O OCH2

O

5' O

3'

etc.

Thymine

Guanine

Cytosine

Deoxyribonucleic acid (DNA)

H

O

H3C

NH 2

N N N

NH2 N

N N

N

NH2

O

O

O

O

N

FIGURE 10.15 3 , 5-phosphodiester bridges link

nucleo-tides together to form polynucleotide chains The

5 -ends of the chains are at the top; the 3-ends are at

the bottom.

PHOSPHORYL GROUP TRANSFER:

OCH2 O

O P O–

O

O–

O

Base

OH HO

NTP

O

O–

O

Base

OH HO

O P O– O–

NDP

PYROPHOSPHORYL GROUP TRANSFER:

OCH2 O

O P O–

O

O–

O

Base

OH HO

NTP

O

O–

O

Base

OH HO

O P O– O–

NMP

NUCLEOTIDYL GROUP TRANSFER:

OCH2 O

O P O–

O

O–

O

Base

OH HO

NTP

O

O–

O P O–

O– OCH2

P O

Base

OH HO

O R

R–NMP

FIGURE 10.14 Phosphoryl,

pyrophos-phoryl, and nucleotidyl group transfer,

the major biochemical reactions of

nucleotides.

The Base Sequence of a Nucleic Acid Is Its Distinctive Characteristic

The only significant variation that commonly occurs in the chemical structure of

nu-cleic acids is the nature of the base at each nucleotide position These bases are not

part of the sugar–phosphate backbone but instead serve as distinctive side chains,

much like the R groups of amino acids along a polypeptide backbone They give the

polymer its unique identity A simple notation for nucleic acid structures is merely to

list the order of bases in the polynucleotide using single capital letters—A, G, C, and

U (or T) Occasionally, a lowercase “p” is written between each successive base to

indi-cate the phosphodiester bridge, as in GpApCpGpUpA

To distinguish between RNA and DNA sequences, DNA sequences may be

pre-ceded by a lowercase “d” to denote deoxy, as in d-GACGTA From a simple string of

letters such as this, any biochemistry student should be able to draw the unique

chemical structure of, for example, a pentanucleotide, even though it may contain

more than 200 atoms

The two major classes of nucleic acids are DNA and RNA DNA has only one

bio-logical role, but it is the more central one The information to make all the

func-tional macromolecules of the cell (even DNA itself) is preserved in DNA and

ac-cessed through transcription of the information into RNA copies Coincident with

DNA’s singular purpose, simple life forms such as viruses or bacteria usually contain

only a single DNA molecule (or “chromosome”) Such DNA molecules must be

quite large in order to embrace enough information for making the

macromole-cules necessary to maintain a living cell The Escherichia coli chromosome has a

mo-lecular mass of 2.9 109D and contains more than 9 million nucleotides

Eukary-otic cells have many chromosomes, and DNA is found principally in two copies in

the diploid chromosomes of the nucleus DNA is also found in mitochondria and

in chloroplasts, where it encodes some of the proteins and RNAs unique to these

organelles

In contrast, RNA occurs in multiple copies and various forms Cells typically

con-tain about eight times as much RNA as DNA RNA has a number of important

bio-logical functions, its central one being information transfer from DNA to protein

RNA molecules playing this role are categorized into several major types:

messen-ger RNA, ribosomal RNA, transfer RNA, and small nuclear RNA Another type,

small RNAs (RNA 21 to 28 nucleotides in length), consists of important players in

gene regulation Beyond various roles in information transfer, RNA participates in

a number of metabolic functions, including the processing and modification of

tRNA, rRNA, and mRNA and several maintenance or “housekeeping” functions,

such as preservation of telomeres

With these basic definitions in mind, let’s now briefly consider the chemical and

structural nature of DNA and the various RNAs Chapter 11 elaborates on methods

to determine the primary structure of nucleic acids by sequencing methods and

dis-cusses the secondary and tertiary structures of DNA and RNA Part IV, Information

Transfer, includes a detailed treatment of the dynamic role of nucleic acids in the

molecular biology of the cell

The Fundamental Structure of DNA Is a Double Helix

The DNA isolated from different cells and viruses characteristically consists of two

polynucleotide strands wound together to form a long, slender, helical molecule,

the DNA double helix The strands run in opposite directions; that is, they are

antiparallel The two strands are held together in the double helical structure

through interchain hydrogen bonds (Figure 10.16) These H bonds pair the bases of

nucleotides in one chain to complementary bases in the other, a phenomenon

called base pairing.

Telomeres are specialized sequences at the ends

of chromosomes

300 Chapter 10 Nucleotides and Nucleic Acids

Erwin Chargaff’s Analysis of the Base Composition of Different DNAs Provided a Key Clue to DNA Structure A clue to the chemical basis of base pairing in DNA came from the analysis of the base composition of various DNAs by Erwin Chargaff in the late 1940s His data showed that the four bases commonly found in DNA (A, C, G, and T) do not occur in equimolar amounts and that the relative amounts of each vary from species to species (Table 10.1) Nevertheless, Chargaff noted that certain pairs of bases, namely, adenine and thymine, and guanine and cytosine, are always found in a 1⬊1 ra-tio and that the number of pyrimidine residues always equals the number of purine

residues These findings are known as Chargaff’s rules: [A]ⴝ [T]; [C] ⴝ [G]; [pyrim-idines] ⴝ [purines].

5' 3'

5' 3'

5'

5'

5'

5'

5'

3'

3'

3'

3'

3'

5'

5'

5'

5'

5'

3'

3'

3'

3'

3'

T A

G C

A T

C G

T A

3'

5'

Segment of unwound double helix illustrating the antiparallel orientation

of the complementary strands

5'

3'

P

P

P

P

P

P

P

P

P

P

P

P

FIGURE 10.16 The antiparallel nature of the DNA double

helix.

Source: After Chargaff, E., 1951 Structure and function of nucleic acids as cell constituents Federation Proceedings

TABLE 10.1 Molar Ratios Leading to the Formulation of Chargaff’s Rules

Watson and Crick’s Postulate of the DNA Double Helix Became the Icon of DNA

Structure James Watson and Francis Crick, working in the Cavendish Laboratory

at Cambridge University in 1953, took advantage of Chargaff’s results and the data

obtained by Rosalind Franklin and Maurice Wilkins in X-ray diffraction studies on

the structure of DNA to conclude that DNA was a complementary double helix Two

strands of deoxyribonucleic acid (sometimes referred to as the Watson strand and

the Crick strand) are held together by the bonding interactions between unique base

pairs, always consisting of a purine in one strand and a pyrimidine in the other Base

pairing is very specific: If the purine is adenine, the pyrimidine must be thymine

Similarly, guanine pairs only with cytosine (Figure 10.17) Thus, if an A occurs in

one strand of the helix, T must occupy the complementary position in the

oppos-ing strand Likewise, a G in one dictates a C in the other Because of this exclusive

pairing of A only with T and G only with C, these pairs are taken as the standard or

accepted law, and the A⬊T and G⬊C base pairs are often referred to as canonical As

Watson recognized from testing various combinations of bases using structurally

ac-curate models, the A⬊T pair and the G⬊C pair form spatially equivalent units

(Fig-ure 10.17) The backbone-to-backbone distance of an A⬊T pair is 1.11 nm, virtually

identical to the 1.08 nm chain separation in G⬊C base pairs

Base pairing in the DNA molecule not only conforms to Chargaff results and

Wat-son and Crick’s rules but also has a profound property relating to heredity: The sequence

of bases in one strand has a complementary relationship to the sequence of bases in the other strand.

That is, the information contained in the sequence of one strand is conserved in the

sequence of the other Therefore, separation of the two strands and faithful replication

of each, through a process in which base pairing specifies the nucleotide sequence in

the newly synthesized strand, leads to two progeny molecules identical in every respect

to the parental double helix (Figure 10.18) Elucidation of the double helical structure

of DNA represented one of the most significant events in the history of science This

discovery more than any other marked the beginning of molecular biology Indeed,

upon solving the structure of DNA, Crick proclaimed in The Eagle, a pub just across

from the Cavendish lab, “We have discovered the secret of life!”

The Information in DNA Is Encoded in Digital Form In this digital age, we are

accustomed to electronic information encoded in the form of extremely long arrays of

just two digits: ones (1s) and zeros (0s) DNA uses four digits to encode biological

in-formation: A, C, G, and T A significant feature of the DNA double helix is that

virtu-ally any base sequence (encoded information) is possible: Other than the base-pairing

rules, no structural constraints operate to limit the potential sequence of bases in DNA

DNA contains two kinds of information:

1 The base sequences of genes that encode the amino acid sequences of proteins

and the nucleotide sequences of functional RNA molecules such as rRNA and

tRNA (see following discussion)

2 The gene regulatory networks that control the expression of protein-encoding

(and functional RNA-encoding) genes (see Chapter 29)

Thymine

C

C C

N

C

N

C

O

O

H

H

H

H

H H

C C

C

N

C

N

N

H

H

N

C

N

H

50°

To chain

To chain

1.11 nm

0.28 nm

0.30 nm

Adenine

51°

N N

H

N

O

H H

N

O

H

N

N

H

N

H

0.29 nm

0.30 nm

0.29 nm

1.08 nm

To chain

To chain

H

C C

C C

C 1 '

C C

C C

C

C 1 '

FIGURE 10.17 The Watson–Crick base pairs A ⬊T and G⬊C.

Emerging progeny DNA

G C

A

A T G C

A

A

G C

G C

G

A T

A T G C

A T

T G C

A T

A T

G C

A T

A T

G C

New

Parental DNA

FIGURE 10.18Replication of DNA gives identical progeny molecules because base pairing is the mechanism that determines the nucleotide sequence of each newly syn-thesized strand.

302 Chapter 10 Nucleotides and Nucleic Acids

DNA Is in the Form of Enormously Long, Threadlike Molecules Because of the double helical nature of DNA molecules, their size can be represented in terms of

the numbers of paired nucleotides (or base pairs) they contain For example, the

E coli chromosome consists of 4.64 106base pairs (abbreviated bp) or 4.64 103

kilobase pairs (kbp) DNA is a threadlike molecule The diameter of the DNA dou-ble helix is only 2 nm, but the length of the DNA molecule forming the

E coli chromosome is over 1.6 106nm (1.6 mm) The long dimension of an E coli

cell is only 2000 nm (0.002 mm), so its chromosome must be highly folded Because

of their long, threadlike nature, DNA molecules are easily sheared into shorter fragments during isolation procedures, and it is difficult to obtain intact chromo-somes even from the simple cells of prokaryotes

DNA in Cells Occurs in the Form of Chromosomes DNA occurs in various forms

in different cells The single chromosome of prokaryotic cells (Figure 10.19) is typ-ically a circular DNA molecule Proteins are associated with prokaryotic DNA, but unlike eukaryotic chromosomes, prokaryotic chromosomes are not uniformly orga-nized into ordered nucleoprotein arrays The DNA molecules of eukaryotic cells, each of which defines a chromosome, are linear and richly adorned with proteins

A class of arginine- and lysine-rich basic proteins called histones interact ionically with the anionic phosphate groups in the DNA backbone to form nucleosomes,

structures in which the DNA double helix is wound around a protein “core” com-posed of pairs of four different histone polypeptides (see Section 11.5 in Chapter

11) Chromosomes also contain a varying mixture of other proteins, so-called

non-FIGURE 10.19 If the cell walls of bacteria such as

Escherichia coli are partially digested and the cells are

then osmotically shocked by dilution with water, the

contents of the cells are extruded to the exterior In

electron micrographs, the most obvious extruded

com-ponent is the bacterial chromosome, shown here

sur-rounding the cell.

A DEEPER LOOK

Do the Properties of DNA Invite Practical Applications?

The molecular recognition between one DNA strand and its

com-plementary partner not only leads to formation of a

double-stranded DNA, but it also creates a molecule with mechanical

properties distinctly different from single-stranded DNA DNA

double helices are relatively rigid rods Single-stranded DNA

mol-ecules are flexible strands These features are of interest to

nano-technology,the new branch of applied science that aims to

ma-nipulate matter at the molecular, or nanometer, level for practical

purposes Nanotechnology seeks to create nanodevices, nanoscale

devices with simple machinelike qualities

DNA chains have been used to construct nanomachines

capa-ble of simple movements such as rotation or pincerlike motions,

and more elaborate DNA-based devices can even act as motors

that walk along DNA tracks To illustrate the principles, consider

the DNA “tweezers” composed of three DNA strands (Q [red

strand], S1, and S2) with regions of partial sequence

complemen-tarity The 40-nucleotide Q strand is hybridized with two

differ-ent 42-nucleotide-long DNA strands, S1 (blue/purple) and S2

(green/purple) Terminal segments of S1 and S2 are designed to

be complementary to 18-nucleotide stretches at the opposite ends

of Q Base pairing between Q , S1, and S2 forms a V-shaped

supramolecular structure, the tweezers, in an open conformation

(1) Both S1 and S2 have 24-nucleotide-long ends that remain

un-paired The DNA tweezers can be driven into a closed

confor-mation by the “fuel,” a 56-nucleotide DNA strand (F) that has

24 bases complementary to the unpaired region of S1 and 24 bases

complementary to the unpaired region of S2 Hybridization of the

“fuel” to the unpaired segments of S1 and S2 (blue and green,

re-spectively) closes the “tweezers” (2) The F strand has eight

un-paired nucleotides remaining at its end; this region is called the

“toehold.” The “toehold” serves as the hybridization site for a fifth

DNA strand, the R or “removal” strand R is complementary to F

along its length Hybridization of the end of R to the

complemen-tary eight-base “toehold” region of F results in the unzipping of F

from S2 and then S1 as it zips up with R Removal of F returns the DNA tweezers to the open conformation (1) The F⬊R duplex is the “waste” generated by the operation of the DNA nanomachine Thus, this DNA tweezers nanomachine consumes “fuel” and gen-erates “waste,” as many common machines do

F

F

F R

F : R duplex (“waste”) R

R

S1

S2

Q

Closed

(2)

(1)

Open

“toehold”

F (“fuel”)

䊱 DNA tweezers—a simple DNA nanomachine (Adapted from Yurke, B.,

Turberfield, A J., Mills, A P., Jr., Simmel, F C., and Neumann, J L 2000 A DNA-fuelled

molecular machine made of DNA Nature 406:605–608, as discussed in an article in the

whimsically named nanoscience journal Small by Simmel, F C., and Dittmer W U., 2006.

DNA nanodevices Small 1:284–299).