BIOTECH Biochemistry Notes PDF

Summary

These notes cover the physical and chemical properties of water, including weak interactions in aqueous systems, ionization, buffering, and water as a reactant. The significance of hydrogen bonds and their influence on biomolecules in the aquatic environment are also addressed.

Full Transcript

I believe that as the methods of structural chemistry are further applied
to physiological problems, it will be found that the significance of the
hydrogen bond for physiology is greater than that of any other single
structural feature.
2
—Linus Pauling, The Nature of the Chemical Bond, 1939

Water

2.1 Weak Interactions in Aqueous Systems 43 perature and favor the extreme ordering of molecules
that is typical of crystalline water (ice). Polar biomole-
2.2 Ionization of Water,Weak Acids, and Weak Bases 54 cules dissolve readily in water because they can replace
2.3 Buffering against pH Changes in Biological Systems 59 water-water interactions with more energetically favor-
able water-solute interactions. In contrast, nonpolar
2.4 Water as a Reactant 65 biomolecules interfere with water-water interactions
but are unable to form water-solute interactions—
2.5 The Fitness of the Aqueous Environment for Living consequently, nonpolar molecules are poorly soluble in
Organisms 65 water. In aqueous solutions, nonpolar molecules tend to
cluster together. Hydrogen bonds and ionic, hydropho-
bic (Greek, “water-fearing”), and van der Waals interac-

W ater is the most abundant substance in living
systems, making up 70% or more of the weight
of most organisms. The first living organisms on
Earth doubtless arose in an aqueous environment, and
the course of evolution has been shaped by the proper-
tions are individually weak, but collectively they have a
very significant influence on the three-dimensional
structures of proteins, nucleic acids, polysaccharides,
and membrane lipids.
ties of the aqueous medium in which life began.
This chapter begins with descriptions of the physical
Hydrogen Bonding Gives Water Its Unusual Properties
and chemical properties of water, to which all aspects of Water has a higher melting point, boiling point, and
cell structure and function are adapted. The attractive heat of vaporization than most other common solvents
forces between water molecules and the slight tendency of (Table 2–1). These unusual properties are a conse-
water to ionize are of crucial importance to the structure quence of attractions between adjacent water molecules
and function of biomolecules. We review the topic of ion- that give liquid water great internal cohesion. A look at
ization in terms of equilibrium constants, pH, and titration the electron structure of the H2O molecule reveals the
curves, and consider how aqueous solutions of weak acids cause of these intermolecular attractions.
or bases and their salts act as buffers against pH changes in Each hydrogen atom of a water molecule shares an
biological systems. The water molecule and its ionization electron pair with the central oxygen atom. The geome-
products, H and OH, profoundly influence the structure, try of the molecule is dictated by the shapes of the outer
self-assembly, and properties of all cellular components, in- electron orbitals of the oxygen atom, which are similar
cluding proteins, nucleic acids, and lipids. The noncovalent to the sp3 bonding orbitals of carbon (see Fig. 1–14).
interactions responsible for the strength and specificity of These orbitals describe a rough tetrahedron, with a hy-
“recognition” among biomolecules are decisively influ- drogen atom at each of two corners and unshared elec-
enced by the solvent properties of water, including its abil- tron pairs at the other two corners (Fig. 2–1a). The
ity to form hydrogen bonds with itself and with solutes. H—O—H bond angle is 104.5, slightly less than the
109.5 of a perfect tetrahedron because of crowding by
the nonbonding orbitals of the oxygen atom.
2.1 Weak Interactions in Aqueous Systems The oxygen nucleus attracts electrons more strongly
Hydrogen bonds between water molecules provide the than does the hydrogen nucleus (a proton); that is, oxy-
cohesive forces that make water a liquid at room tem- gen is more electronegative. This means that the shared

43
 44 Water

TABLE 2–1 Melting Point, Boiling Point, and Heat of Vaporization of Some Common Solvents
Melting point (C) Boiling point (C) Heat of vaporization (J/g)*

Water 0 100 2,260
Methanol (CH3OH) 98 65 1,100
Ethanol (CH3CH2OH) 117 78 854
Propanol (CH3CH2CH2OH) 127 97 687
Butanol (CH3(CH2)2CH2OH) 90 117 590
Acetone (CH3COCH3) 95 56 523
Hexane (CH3(CH2)4CH3) 98 69 423
Benzene (C6H6) 6 80 394
Butane (CH3(CH2)2CH3) 135 0.5 381
Chloroform (CHCl3) 63 61 247

*The heat energy required to convert 1.0 g of a liquid at its boiling point and at atmospheric pressure into its gaseous state at the same temperature.
It is a direct measure of the energy required to overcome attractive forces between molecules in the liquid phase.

electrons are more often in the vicinity of the oxygen quired to break a bond) of about 23 kJ/mol, compared
atom than of the hydrogen. The result of this unequal with 470 kJ/mol for the covalent O—H bond in water or
electron sharing is two electric dipoles in the water mol- 348 kJ/mol for a covalent C—C bond. The hydrogen bond
ecule, one along each of the H—O bonds; each hydrogen is about 10% covalent, due to overlaps in the bonding or-
bears a partial positive charge (), and the oxygen bitals, and about 90% electrostatic. At room tempera-
atom bears a partial negative charge equal in magnitude ture, the thermal energy of an aqueous solution (the
to the sum of the two partial positives (2). As a result, kinetic energy of motion of the individual atoms and
there is an electrostatic attraction between the oxygen molecules) is of the same order of magnitude as that re-
atom of one water molecule and the hydrogen of another quired to break hydrogen bonds. When water is heated,
(Fig. 2–1b), called a hydrogen bond. Throughout this the increase in temperature reflects the faster motion of
book, we represent hydrogen bonds with three parallel individual water molecules. At any given time, most of
blue lines, as in Figure 2–1b. the molecules in liquid water are hydrogen bonded, but
Hydrogen bonds are relatively weak. Those in liquid the lifetime of each hydrogen bond is just 1 to 20 pi-
water have a bond dissociation energy (the energy re- coseconds (1 ps  1012 s); when one hydrogen bond
breaks, another hydrogen bond forms, with the same
partner or a new one, within 0.1 ps. The apt phrase “flick-
 104.5  ering clusters” has been applied to the short-lived groups
of water molecules interlinked by hydrogen bonds in
liquid water. The sum of all the hydrogen bonds between
H2O molecules confers great internal cohesion on liquid

 Hydrogen bond water. Extended networks of hydrogen-bonded water
H 0.177 nm molecules also form bridges between solutes (proteins
 and nucleic acids, for example) that allow the larger
molecules to interact with each other over distances of
Covalent bond
O
 0.0965 nm several nanometers without physically touching.
The nearly tetrahedral arrangement of the orbitals
 H 
 about the oxygen atom (Fig. 2–1a) allows each water

molecule to form hydrogen bonds with as many as four
(a) (b) neighboring water molecules. In liquid water at room
FIGURE 2–1 Structure of the water molecule. (a) The dipolar nature of temperature and atmospheric pressure, however, water
the H2O molecule is shown in a ball-and-stick model; the dashed lines molecules are disorganized and in continuous motion, so
represent the nonbonding orbitals. There is a nearly tetrahedral that each molecule forms hydrogen bonds with an aver-
arrangement of the outer-shell electron pairs around the oxygen atom; age of only 3.4 other molecules. In ice, on the other hand,
the two hydrogen atoms have localized partial positive charges () each water molecule is fixed in space and forms hydro-
and the oxygen atom has a partial negative charge (). (b) Two H2O gen bonds with a full complement of four other water
molecules joined by a hydrogen bond (designated here, and through- molecules to yield a regular lattice structure (Fig. 2–2).
out this book, by three blue lines) between the oxygen atom of the up- Breaking a sufficient proportion of hydrogen bonds to
per molecule and a hydrogen atom of the lower one. Hydrogen bonds destabilize the crystal lattice of ice requires much thermal
are longer and weaker than covalent O—H bonds. energy, which accounts for the relatively high melting
 2.1 Weak Interactions in Aqueous Systems 45

A A
C E CJ
Hydrogen E J J D D D D D J D
acceptor O N O O O N

Hydrogen H H H H H H

O O

O O

O O

O

O

O
donor
O O O N N N
D G D G D G

FIGURE 2–3 Common hydrogen bonds in biological systems. The hy-
drogen acceptor is usually oxygen or nitrogen; the hydrogen donor is
another electronegative atom.

to carbon atoms do not participate in hydrogen bond-
ing, because carbon is only slightly more electronega-
tive than hydrogen and thus the C—H bond is only very
weakly polar. The distinction explains why butanol
(CH3(CH2)2CH2OH) has a relatively high boiling point
of 117 C, whereas butane (CH3(CH2)2CH3) has a boil-
ing point of only 0.5 C. Butanol has a polar hydroxyl
group and thus can form intermolecular hydrogen
bonds. Uncharged but polar biomolecules such as sug-
ars dissolve readily in water because of the stabilizing
FIGURE 2–2 Hydrogen bonding in ice. In ice, each water molecule effect of hydrogen bonds between the hydroxyl groups
forms four hydrogen bonds, the maximum possible for a water mole- or carbonyl oxygen of the sugar and the polar water
cule, creating a regular crystal lattice. By contrast, in liquid water at molecules. Alcohols, aldehydes, ketones, and com-
room temperature and atmospheric pressure, each water molecule pounds containing N—H bonds all form hydrogen
hydrogen-bonds with an average of 3.4 other water molecules. This bonds with water molecules (Fig. 2–4) and tend to be
crystal lattice structure makes ice less dense than liquid water, and thus soluble in water.
ice floats on liquid water.
Between the Between the Between peptide
point of water (Table 2–1). When ice melts or water hydroxyl group carbonyl group groups in
evaporates, heat is taken up by the system: of an alcohol of a ketone polypeptides
and water and water
H2O 1solid2 S H2O 1liquid2 ¢H  5.9 kJ/mol R
R R2 G
G A C
H2O (liquid) S H2O (gas) ¢H  44.0 kJ/mol O H
G D HH
A 1ECJ NO C
R J
During melting or evaporation, the entropy of the H O
O
aqueous system increases as more highly ordered arrays
of water molecules relax into the less orderly hydrogen- E OH H
A H
H H A
bonded arrays in liquid water or into the wholly disor- EO HENH
H C C
dered gaseous state. At room temperature, both the A B
melting of ice and the evaporation of water occur spon- R O
taneously; the tendency of the water molecules to asso-
ciate through hydrogen bonds is outweighed by the Between
complementary
energetic push toward randomness. Recall that the free- bases of DNA
energy change (G) must have a negative value for a
process to occur spontaneously: G  H  T S, H
A
where G represents the driving force, H the enthalpy R
H E N ECH3
C
change from making and breaking bonds, and S the N C
A A Thymine
change in randomness. Because H is positive for melt-
ing and evaporation, it is clearly the increase in entropy KCH EC N
O N O
(S) that makes G negative and drives these changes. A
H H
A
Water Forms Hydrogen Bonds with Polar Solutes H N
H E N E NH
C C
Hydrogen bonds are not unique to water. They readily B A Adenine
N C
form between an electronegative atom (the hydrogen H K H
C N
acceptor, usually oxygen or nitrogen) and a hydrogen i l
NOCH
atom covalently bonded to another electronegative E
R
atom (the hydrogen donor) in the same or another mol-
ecule (Fig. 2–3). Hydrogen atoms covalently bonded FIGURE 2–4 Some biologically important hydrogen bonds.
 46 Water

R trast, nonpolar solvents such as chloroform and benzene
A R
O A are poor solvents for polar biomolecules but easily dis-
A O solve those that are hydrophobic—nonpolar molecules
H Strong A
H Weaker such as lipids and waxes.
hydrogen bond
G KO G KO hydrogen bond Water dissolves salts such as NaCl by hydrating and
OP
OP
D D stabilizing the Na and Cl ions, weakening the electro-
static interactions between them and thus counteract-
FIGURE 2–5 Directionality of the hydrogen bond. The attraction be- ing their tendency to associate in a crystalline lattice
tween the partial electric charges (see Fig. 2–1) is greatest when the three (Fig. 2–6). The same factors apply to charged biomole-
atoms involved in the bond (in this case O, H, and O) lie in a straight line. cules, compounds with functional groups such as
When the hydrogen-bonded moieties are structurally constrained (when ionized carboxylic acids (—COO), protonated amines
they are parts of a single protein molecule, for example), this ideal geom- (—NH 3 ), and phosphate esters or anhydrides. Water
etry may not be possible and the resulting hydrogen bond is weaker. readily dissolves such compounds by replacing solute-
solute hydrogen bonds with solute-water hydrogen
Hydrogen bonds are strongest when the bonded bonds, thus screening the electrostatic interactions be-
molecules are oriented to maximize electrostatic inter- tween solute molecules.
action, which occurs when the hydrogen atom and the Water is effective in screening the electrostatic in-
two atoms that share it are in a straight line—that is, teractions between dissolved ions because it has a high
when the acceptor atom is in line with the covalent bond dielectric constant, a physical property that reflects the
between the donor atom and H (Fig. 2–5), putting the number of dipoles in a solvent. The strength, or force
positive charge of the hydrogen ion directly between the (F ), of ionic interactions in a solution depends on the
two partial negative charges. Hydrogen bonds are thus magnitude of the charges (Q), the distance between the
highly directional and capable of holding two hydrogen- charged groups (r), and the dielectric constant ( ,
bonded molecules or groups in a specific geometric which is dimensionless) of the solvent in which the in-
arrangement. As we shall see later, this property of teractions occur:
hydrogen bonds confers very precise three-dimensional Q1Q2
structures on protein and nucleic acid molecules, which F
er2
have many intramolecular hydrogen bonds.
For water at 25 C, is 78.5, and for the very nonpolar
solvent benzene, is 4.6. Thus, ionic interactions be-
Water Interacts Electrostatically with Charged Solutes tween dissolved ions are much stronger in less polar en-
Water is a polar solvent. It readily dissolves most bio- vironments. The dependence on r 2 is such that ionic
molecules, which are generally charged or polar com- attractions or repulsions operate only over short
pounds (Table 2–2); compounds that dissolve easily in distances—in the range of 10 to 40 nm (depending on
water are hydrophilic (Greek, “water-loving”). In con- the electrolyte concentration) when the solvent is water.

TABLE 2–2 Some Examples of Polar, Nonpolar, and Amphipathic Biomolecules (Shown as Ionic Forms at pH 7)
Polar Nonpolar O
Glucose CH2OH Typical wax
CH3(CH2)7 CH CH (CH2)6 CH2 C
O
H OH O
H
CH3 (CH2)7 CH CH (CH2)7 CH2
OH H H
HO

H OH
Amphipathic
NH
GNH3
Glycine 3 CH2 COO Phenylalanine
CH2 CH COOJ
Aspartate NH
3

OOC CH2 CH COO
Phosphatidylcholine O
Lactate CH3 CH COO CH3(CH2)15CH2 C O CH2
OH CH3(CH2)15CH2 C O CH O GN(CH3)3
O CH2 O P O CH2 CH2
Glycerol OH
OJ
HOCH2 CH CH2OH
Polar groups Nonpolar groups
 2.1 Weak Interactions in Aqueous Systems 47

FIGURE 2–6 Water as solvent. Water dissolves many
crystalline salts by hydrating their component ions. The
Hydrated NaCl crystal lattice is disrupted as water molecules
H2O Cl– Cl– ion
cluster about the Cl and Na ions. The ionic charges
Cl– Na+ – are partially neutralized, and the electrostatic attrac-
– tions necessary for lattice formation are weakened.

+
– Note the nonrandom
– – orientation of the

+
+

water molecules
– –

– –
+

+
Na+ Hydrated
– – Na+ ion
– –

Entropy Increases as Crystalline Substances Dissolve crease in entropy when they enter solution combine to
  make them very poorly soluble in water (Table 2–3).
As a salt such as NaCl dissolves, the Na and Cl ions
leaving the crystal lattice acquire far greater freedom of Some organisms have water-soluble “carrier proteins”
motion (Fig. 2–6). The resulting increase in entropy (hemoglobin and myoglobin, for example) that facili-
(randomness) of the system is largely responsible for tate the transport of O2. Carbon dioxide forms carbonic
the ease of dissolving salts such as NaCl in water. In acid (H2CO3) in aqueous solution and is transported as
thermodynamic terms, formation of the solution occurs the HCO 3 (bicarbonate) ion, either free—bicarbonate
with a favorable free-energy change: G  H  T S, is very soluble in water (100 g/L at 25 C)—or bound
where H has a small positive value and T S a large to hemoglobin. Three other gases, NH3, NO, and H2S,
positive value; thus G is negative. also have biological roles in some organisms; these
gases are polar, dissolve readily in water, and ionize in
Nonpolar Gases Are Poorly Soluble in Water aqueous solution.

The molecules of the biologically important gases CO2, Nonpolar Compounds Force Energetically Unfavorable
O2, and N2 are nonpolar. In O2 and N2, electrons are
Changes in the Structure of Water
shared equally by both atoms. In CO2, each CUO bond
is polar, but the two dipoles are oppositely directed and When water is mixed with benzene or hexane, two
cancel each other (Table 2–3). The movement of mole- phases form; neither liquid is soluble in the other. Non-
cules from the disordered gas phase into aqueous solu- polar compounds such as benzene and hexane are
tion constrains their motion and the motion of water hydrophobic—they are unable to undergo energeti-
molecules and therefore represents a decrease in en- cally favorable interactions with water molecules, and
tropy. The nonpolar nature of these gases and the de- they interfere with the hydrogen bonding among water

TABLE 2–3 Solubilities of Some Gases in Water
Solubility
Gas Structure* Polarity in water (g/L)†
Nitrogen NqN Nonpolar 0.018 (40 C)
Oxygen OPO Nonpolar 0.035 (50 C)
Carbon dioxide   Nonpolar 0.97 (45 C)
OPCP O
Ammonia H H Polar 900 (10 C)
A H
G D
N 

Hydrogen sulfide H
G D
H Polar 1,860 (40 C)
S 

*The arrows represent electric dipoles; there is a partial negative charge () at the head of the arrow, a partial positive charge (; not
shown here) at the tail.
†
Note that polar molecules dissolve far better even at low temperatures than do nonpolar molecules at relatively high temperatures.
 48 Water

molecules. All molecules or ions in aqueous solution in- Amphipathic compounds contain regions that are
terfere with the hydrogen bonding of some water mole- polar (or charged) and regions that are nonpolar
cules in their immediate vicinity, but polar or charged (Table 2–2). When an amphipathic compound is mixed
solutes (such as NaCl) compensate for lost water-water with water, the polar, hydrophilic region interacts favor-
hydrogen bonds by forming new solute-water interac- ably with the solvent and tends to dissolve, but the non-
tions. The net change in enthalpy (H) for dissolving polar, hydrophobic region tends to avoid contact with
these solutes is generally small. Hydrophobic solutes, the water (Fig. 2–7a). The nonpolar regions of the
however, offer no such compensation, and their addition molecules cluster together to present the smallest
to water may therefore result in a small gain of enthalpy; hydrophobic area to the aqueous solvent, and the polar
the breaking of hydrogen bonds between water mole- regions are arranged to maximize their interaction with
cules takes up energy from the system, requiring the the solvent (Fig. 2–7b). These stable structures of am-
input of energy from the surroundings. In addition to phipathic compounds in water, called micelles, may
requiring this input of energy, dissolving hydrophobic contain hundreds or thousands of molecules. The forces
compounds in water produces a measurable decrease in
entropy. Water molecules in the immediate vicinity of a
nonpolar solute are constrained in their possible orien-
tations as they form a highly ordered cagelike shell
around each solute molecule. These water molecules Dispersion of
are not as highly oriented as those in clathrates, crys- lipids in H2O
talline compounds of nonpolar solutes and water, but Each lipid
the effect is the same in both cases: the ordering of water molecule forces
molecules reduces entropy. The number of ordered surrounding H2O
molecules to become
water molecules, and therefore the magnitude of the en- highly ordered.
tropy decrease, is proportional to the surface area of the
hydrophobic solute enclosed within the cage of water
molecules. The free-energy change for dissolving a non-
polar solute in water is thus unfavorable: G  H 
T S, where H has a positive value, S has a negative
value, and G is positive.

Hydrophilic
O – “head group”
O
H

C
H O
H C H

Clusters of lipid
molecules
Only lipid portions
at the edge of
the cluster force the
ordering of water.
Fewer H2O molecules
are ordered, and
Hydrophobic entropy is increased.
alkyl group

“Flickering clusters” of H2O
molecules in bulk phase

Highly ordered H2O molecules form Micelles
“cages” around the hydrophobic alkyl chains All hydrophobic
groups are
(a) sequestered from
water; ordered
FIGURE 2–7 Amphipathic compounds in aqueous solution. (a) Long- shell of H2O
chain fatty acids have very hydrophobic alkyl chains, each of which is molecules is
surrounded by a layer of highly ordered water molecules. (b) By clus- minimized, and
entropy is further
tering together in micelles, the fatty acid molecules expose the small- increased.
est possible hydrophobic surface area to the water, and fewer water
molecules are required in the shell of ordered water. The energy gained
by freeing immobilized water molecules stabilizes the micelle. (b)
 2.1 Weak Interactions in Aqueous Systems 49

that hold the nonpolar regions of the molecules together portant determinants of structure in biological mem-
are called hydrophobic interactions. The strength of branes. Hydrophobic interactions between nonpolar
hydrophobic interactions is not due to any intrinsic at- amino acids also stabilize the three-dimensional struc-
traction between nonpolar moieties. Rather, it results tures of proteins.
from the system’s achieving greatest thermodynamic Hydrogen bonding between water and polar solutes
stability by minimizing the number of ordered water also causes an ordering of water molecules, but the en-
molecules required to surround hydrophobic portions of ergetic effect is less significant than with nonpolar
the solute molecules. solutes. Part of the driving force for binding of a polar
Many biomolecules are amphipathic; proteins, pig- substrate (reactant) to the complementary polar sur-
ments, certain vitamins, and the sterols and phospho- face of an enzyme is the entropy increase as the enzyme
lipids of membranes all have both polar and nonpolar displaces ordered water from the substrate, and as the
surface regions. Structures composed of these mole- substrate displaces ordered water from the enzyme sur-
cules are stabilized by hydrophobic interactions among face (Fig. 2–8).
the nonpolar regions. Hydrophobic interactions among
lipids, and between lipids and proteins, are the most im- van der Waals Interactions Are Weak
Interatomic Attractions
Ordered water
interacting with When two uncharged atoms are brought very close to-
substrate and enzyme gether, their surrounding electron clouds influence each
other. Random variations in the positions of the elec-
trons around one nucleus may create a transient electric
dipole, which induces a transient, opposite electric di-
Substrate pole in the nearby atom. The two dipoles weakly attract
each other, bringing the two nuclei closer. These weak
attractions are called van der Waals interactions
(also known as London forces). As the two nuclei
Enzyme draw closer together, their electron clouds begin to
repel each other. At the point where the net attraction is
maximal, the nuclei are said to be in van der Waals con-
tact. Each atom has a characteristic van der Waals
radius, a measure of how close that atom will allow
another to approach (Table 2–4). In the “space-filling”
molecular models shown throughout this book, the
atoms are depicted in sizes proportional to their van der
Waals radii.

van der Waals Radii and Covalent
TABLE 2–4
Disordered water (Single-Bond) Radii of Some Elements
displaced by
enzyme-substrate van der Waals Covalent radius for
interaction Element radius (nm) single bond (nm)
H 0.11 0.030
O 0.15 0.066
N 0.15 0.070
C 0.17 0.077
S 0.18 0.104
P 0.19 0.110
I 0.21 0.133
Enzyme-substrate interaction
stabilized by hydrogen-bonding,
ionic, and hydrophobic interactions Sources: For van der Waals radii, Chauvin, R. (1992) Explicit periodic trend of van der
Waals radii. J. Phys. Chem. 96, 9194–9197. For covalent radii, Pauling, L. (1960)
FIGURE 2–8 Release of ordered water favors formation of an enzyme- Nature of the Chemical Bond, 3rd edn, Cornell University Press, Ithaca, NY.
Note: van der Waals radii describe the space-filling dimensions of atoms. When two
substrate complex. While separate, both enzyme and substrate force atoms are joined covalently, the atomic radii at the point of bonding are less than the
neighboring water molecules into an ordered shell. Binding of sub- van der Waals radii, because the joined atoms are pulled together by the shared elec-
strate to enzyme releases some of the ordered water, and the resulting tron pair. The distance between nuclei in a van der Waals interaction or a covalent bond
is about equal to the sum of the van der Waals or covalent radii, respectively, for the two
increase in entropy provides a thermodynamic push toward formation atoms. Thus the length of a carbon-carbon single bond is about 0.077 nm  0.077 nm 
of the enzyme-substrate complex (see p. 192). 0.154 nm.
 50 Water

Weak Interactions Are Crucial to Macromolecular one or more ionic interactions, as well as hydrophobic
Structure and Function and van der Waals interactions. The formation of each of
these weak bonds contributes to a net decrease in the
The noncovalent interactions we have described— free energy of the system. We can calculate the stability
hydrogen bonds and ionic, hydrophobic, and van der Waals of a noncovalent interaction, such as that of a small mol-
interactions (Table 2–5)—are much weaker than covalent ecule hydrogen-bonded to its macromolecular partner,
bonds. An input of about 350 kJ of energy is required to from the binding energy. Stability, as measured by the
break a mole (6  1023) of C—C single bonds, and about equilibrium constant (see below) of the binding reac-
410 kJ to break a mole of C—H bonds, but as little as 4 kJ tion, varies exponentially with binding energy. The dis-
is sufficient to disrupt a mole of typical van der Waals in- sociation of two biomolecules (such as an enzyme and
teractions. Hydrophobic interactions are also much weaker its bound substrate) that are associated noncovalently
than covalent bonds, although they are substantially through multiple weak interactions requires all these in-
strengthened by a highly polar solvent (a concentrated salt teractions to be disrupted at the same time. Because the
solution, for example). Ionic interactions and hydrogen interactions fluctuate randomly, such simultaneous dis-
bonds are variable in strength, depending on the polarity of ruptions are very unlikely. The molecular stability be-
the solvent and the alignment of the hydrogen-bonded stowed by 5 or 20 weak interactions is therefore much
atoms, but they are always significantly weaker than cova- greater than would be expected intuitively from a
lent bonds. In aqueous solvent at 25 C, the available ther- simple summation of small binding energies.
mal energy can be of the same order of magnitude as the Macromolecules such as proteins, DNA, and RNA
strength of these weak interactions, and the interaction be- contain so many sites of potential hydrogen bonding or
tween solute and solvent (water) molecules is nearly ionic, van der Waals, or hydrophobic interactions that the
as favorable as solute-solute interactions. Consequently, cumulative effect of the many small binding forces can
hydrogen bonds and ionic, hydrophobic, and van der Waals be enormous. For macromolecules, the most stable (that
interactions are continually forming and breaking. is, the native) structure is usually that in which weak
Although these four types of interactions are indi- interactions are maximized. The folding of a single
vidually weak relative to covalent bonds, the cumulative polypeptide or polynucleotide chain into its three-
effect of many such interactions can be very significant. dimensional shape is determined by this principle. The
For example, the noncovalent binding of an enzyme to binding of an antigen to a specific antibody depends on
its substrate may involve several hydrogen bonds and the cumulative effects of many weak interactions. As
noted earlier, the energy released when an enzyme binds
noncovalently to its substrate is the main source of the
enzyme’s catalytic power. The binding of a hormone or a
Four Types of Noncovalent (“Weak”) neurotransmitter to its cellular receptor protein is the
TABLE 2–5 Interactions among Biomolecules in result of multiple weak interactions. One consequence of
Aqueous Solvent the large size of enzymes and receptors (relative to their
Hydrogen bonds
substrates or ligands) is that their extensive surfaces
G provide many opportunities for weak interactions. At the
Between neutral groups D CP
O HO OO molecular level, the complementarity between interact-
ing biomolecules reflects the complementarity and weak
G interactions between polar, charged, and hydrophobic
Between peptide bonds D CP G
O HON groups on the surfaces of the molecules.
D When the structure of a protein such as hemoglobin
(Fig. 2–9) is determined by x-ray crystallography
Ionic interactions O
Attraction B (see Box 4–5, p. 132), water molecules are often found
ONH3 O O CO to be bound so tightly that they are part of the crystal
Repulsion structure; the same is true for water in crystals of RNA
ONH3 H3N O or DNA. These bound water molecules, which can also
be detected in aqueous solutions by nuclear magnetic
resonance, have distinctly different properties from
those of the “bulk” water of the solvent. They are, for ex-
water
Hydrophobic CH3 CH3
ample, not osmotically active (see below). For many
G D proteins, tightly bound water molecules are essential to
interactions CH
A their function. In a reaction central to the process of
CH2 photosynthesis, for example, light drives protons across
A
CH2 a biological membrane as electrons flow through a series
A of electron-carrying proteins (see Fig. 19–60). One of
van der Waals interactions Any two atoms in these proteins, cytochrome f, has a chain of five bound
close proximity water molecules (Fig. 2–10) that may provide a path
for protons to move through the membrane by a process
 2.1 Weak Interactions in Aqueous Systems 51

Solutes Affect the Colligative Properties of
Aqueous Solutions
Solutes of all kinds alter certain physical properties
of the solvent, water: its vapor pressure, boiling
point, melting point (freezing point), and osmotic
pressure. These are called colligative properties
(colligative meaning “tied together”), because the ef-
fect of solutes on all four properties has the same ba-
(a) (b)
sis: the concentration of water is lower in solutions
FIGURE 2–9 Water binding in hemoglobin. (PDB ID 1A3N) The crystal than in pure water. The effect of solute concentration
structure of hemoglobin, shown (a) with bound water molecules (red on the colligative properties of water is independent
spheres) and (b) without the water molecules. The water molecules are of the chemical properties of the solute; it depends
so firmly bound to the protein that they affect the x-ray diffraction pat- only on the number of solute particles (molecules,
tern as though they were fixed parts of the crystal. The two  subunits
ions) in a given amount of water. A compound such
of hemoglobin are shown in gray, the two  subunits in blue. Each sub-
as NaCl, which dissociates in solution, has an effect
unit has a bound heme group (red stick structure), visible only in the
on osmotic pressure, for example, that is twice that
 subunits in this view. The structure and function of hemoglobin are
of an equal number of moles of a nondissociating
discussed in detail in Chapter 5.
solute such as glucose.
Water molecules tend to move from a region of
higher water concentration to one of lower water con-
known as “proton hopping” (described below). Another centration, in accordance with the tendency in nature
such light-driven proton pump, bacteriorhodopsin, al- for a system to become disordered. When two different
most certainly uses a chain of precisely oriented bound aqueous solutions are separated by a semipermeable
water molecules in the transmembrane movement of membrane (one that allows the passage of water but not
protons (see Fig. 19–67). solute molecules), water molecules diffusing from the
region of higher water concentration to the region of
lower water concentration produce osmotic pressure
(Fig. 2–11). This pressure, , measured as the force
Val60
Pro231 Gln59
H H O –
O Heme
N H
propionate
water O Force ()
H Pure Nonpermeant resists osmosis
O H
water solute dissolved
N O Asn232 in water
Asn168
H
HN
Piston
O
H
Arg156 O
h
153
Asn H
HN O NH2
N H
H Gln158
O N
N
Ala27
Fe

H N H (a) (b) (c)

HO C C Semipermeable
H membrane
O
FIGURE 2–11 Osmosis and the measurement of osmotic pressure.
FIGURE 2–10 Water chain in cytochrome f. Water is bound in a proton (a) The initial state. The tube contains an aqueous solution, the beaker
channel of the membrane protein cytochrome f, which is part of contains pure water, and the semipermeable membrane allows the pas-
the energy-trapping machinery of photosynthesis in chloroplasts (see sage of water but not solute. Water flows from the beaker into the tube
Fig. 19–64). Five water molecules are hydrogen-bonded to each other to equalize its concentration across the membrane. (b) The final state.
and to functional groups of the protein: the peptide backbone atoms of Water has moved into the solution of the nonpermeant compound, di-
valine, proline, arginine, and alanine residues, and the side chains of luting it and raising the column of water within the tube. At equilibrium,
three asparagine and two glutamine residues. The protein has a bound the force of gravity operating on the solution in the tube exactly balances
heme (see Fig. 5–1), its iron ion facilitating electron flow during pho- the tendency of water to move into the tube, where its concentration is
tosynthesis. Electron flow is coupled to the movement of protons lower. (c) Osmotic pressure () is measured as the force that must be ap-
across the membrane, which probably involves “proton hopping” (see plied to return the solution in the tube to the level of that in the beaker.
Fig. 2–13) through this chain of bound water molecules. This force is proportional to the height, h, of the column in (b).
 54 Water

SUMMARY 2.1 Weak Interactions in reaction. We therefore turn now to a brief discussion of
the ionization of water and of weak acids and bases dis-
Aqueous Systems solved in water.
The very different electronegativities of H and O
make water a highly polar molecule, capable of Pure Water Is Slightly Ionized
forming hydrogen bonds with itself and with solutes.
Hydrogen bonds are fleeting, primarily electrostatic, Water molecules have a slight tendency to undergo re-
and weaker than covalent bonds. Water is a good versible ionization to yield a hydrogen ion (a proton)
solvent for polar (hydrophilic) solutes, with which it and a hydroxide ion, giving the equilibrium
forms hydrogen bonds, and for charged solutes, H2O Δ H   OH  (2–1)
with which it interacts electrostatically.
Although we commonly show the dissociation product
Nonpolar (hydrophobic) compounds dissolve of water as H, free protons do not exist in solution; hy-
poorly in water; they cannot hydrogen-bond with drogen ions formed in water are immediately hydrated
the solvent, and their presence forces an to hydronium ions (H3O). Hydrogen bonding be-
energetically unfavorable ordering of water tween water molecules makes the hydration of dissoci-
molecules at their hydrophobic surfaces. To ating protons virtually instantaneous:
minimize the surface exposed to water, nonpolar
÷
compounds such as lipids form aggregates H O H O H O H  OH
(micelles) in which the hydrophobic moieties are H H H
sequestered in the interior, associating through
hydrophobic interactions, and only the more polar The ionization of water can be measured by its elec-
moieties interact with water. trical conductivity; pure water carries electrical current
as H3O migrates toward the cathode and OH toward
Weak, noncovalent interactions, in large numbers, the anode. The movement of hydronium and hydroxide
decisively influence the folding of macromolecules ions in the electric field is extremely fast compared with
such as proteins and nucleic acids. The most stable that of other ions such as Na, K, and Cl. This high
macromolecular conformations are those in which ionic mobility results from the kind of “proton hopping”
hydrogen bonding is maximized within the molecule shown in Figure 2–13. No individual proton moves very
and between the molecule and the solvent, and in far through the bulk solution, but a series of proton hops
which hydrophobic moieties cluster in the interior
of the molecule away from the aqueous solvent.
The physical properties of aqueous solutions are Hydronium ion gives up a proton
strongly influenced by the concentrations of H H
Proton hop
solutes. When two aqueous compartments are O+
separated by a semipermeable membrane (such as H
the plasma membrane separating a cell from its O
H H
surroundings), water moves across that membrane H O
H
to equalize the osmolarity in the two compart- H O
H
ments. This tendency for water to move across a
semipermeable membrane is the osmotic pressure. H O

H
2.2 Ionization of Water,Weak Acids, and O H
Weak Bases H
H
Although many of the solvent properties of water can be O
explained in terms of the uncharged H2O molecule, the
H
small degree of ionization of water to hydrogen ions
(H) and hydroxide ions (OH) must also be taken into O H

account. Like all reversible reactions, the ionization of H
water can be described by an equilibrium constant. Water accepts proton and
When weak acids are dissolved in water, they contribute becomes a hydronium ion
H by ionizing; weak bases consume H by becoming FIGURE 2–13 Proton hopping. Short “hops” of protons between a series
protonated. These processes are also governed by equi- of hydrogen-bonded water molecules result in an extremely rapid net
librium constants. The total hydrogen ion concentration movement of a proton over a long distance. As a hydronium ion (upper
from all sources is experimentally measurable and is ex- left) gives up a proton, a water molecule some distance away (lower right)
pressed as the pH of the solution. To predict the state of acquires one, becoming a hydronium ion. Proton hopping is much faster
ionization of solutes in water, we must take into account than true diffusion and explains the remarkably high ionic mobility of H
the relevant equilibrium constants for each ionization ions compared with other monovalent cations such as Na and K.
 2.2 Ionization of Water, Weak Acids, and Weak Bases 55

between hydrogen-bonded water molecules causes the weight: (1,000 g/L)/(18.015 g/mol)—and is essentially
net movement of a proton over a long distance in a re- constant in relation to the very low concentrations of H
markably short time. As a result of the high ionic mo- and OH, namely, 1  107 M. Accordingly, we can sub-
bility of H (and of OH, which also moves rapidly by stitute 55.5 M in the equilibrium constant expression
proton hopping, but in the opposite direction), acid- (Eqn 2–3) to yield
base reactions in aqueous solutions are exceptionally
fast. As noted above, proton hopping very likely also [H  ][OH  ]
Keq 
plays a role in biological proton-transfer reactions [55.5 M]
(Fig. 2–10; see also Fig. 19–67).
Because reversible ionization is crucial to the role of On rearranging, this becomes
water in cellular function, we must have a means of ex-
(55.5 M) (Keq)  [H  ] [OH  ]  Kw (2–4)
pressing the extent of ionization of water in quantitative
terms. A brief review of some properties of reversible where Kw designates the product (55.5 M)(Keq), the ion
chemical reactions shows how this can be done. product of water at 25 C.
The position of equilibrium of any chemical reaction The value for Keq, determined by electrical-
is given by its equilibrium constant, Keq (sometimes conductivity measurements of pure water, is 1.8 
expressed simply as K ). For the generalized reaction 1016 M at 25 C. Substituting this value for Keq in
AB Δ CD (2–2) Equation 2–4 gives the value of the ion product of water:
an equilibrium constant can be defined in terms of the Kw  [H  ][OH  ]  (55.5 M) (1.8  1016 M)
concentrations of reactants (A and B) and products (C
and D) at equilibrium:  1.0  1014 M2

[C]eq[D]eq Thus the product [H][OH] in aqueous solutions at
Keq  25 C always equals 1  1014 M2. When there are ex-
[A]eq[B]eq
actly equal concentrations of H and OH, as in pure
Strictly speaking, the concentration terms should be the water, the solution is said to be at neutral pH. At this
activities, or effective concentrations in nonideal solu- pH, the concentration of H and OH can be calculated
tions, of each species. Except in very accurate work, from the ion product of water as follows:
however, the equilibrium constant may be approximated
by measuring the concentrations at equilibrium. For rea- Kw  [H][OH]  [H]2  [OH]2
sons beyond the scope of this discussion, equilibrium con-
stants are dimensionless. Nonetheless, we have generally Solving for [H] gives
retained the concentration units (M) in the equilibrium ex-
pressions used in this book to remind you that molarity is [H]  2Kw  21  10 14 M2
the unit of concentration used in calculating Keq. [H]  [OH  ]  107 M
The equilibrium constant is fixed and characteristic
for any given chemical reaction at a specified tempera- As the ion product of water is constant, whenever [H]
ture. It defines the composition of the final equilibrium is greater than 1  107 M, [OH] must be less than 1 
mixture, regardless of the starting amounts of reactants 107 M, and vice versa. When [H] is very high, as in a
and products. Conversely, we can calculate the equilib- solution of hydrochloric acid, [OH] must be very low.
rium constant for a given reaction at a given tempera- From the ion product of water we can calculate [H] if
ture if the equilibrium concentrations of all its reactants we know [OH], and vice versa.
and products are known. As we showed in Chapter 1
(p. 24), the standard free-energy change (G) is di-
rectly related to ln Keq. WORKED EXAMPLE 2–3 Calculation of [H]
What is the concentration of H in a solution of 0.1 M
The Ionization of Water Is Expressed by NaOH?
an Equilibrium Constant Solution: We begin with the equation for the ion product
The degree of ionization of water at equilibrium (Eqn 2–1) of water:
is small; at 25 C only about two of every 109 molecules in
Kw  [H][OH]
pure water are ionized at any instant. The equilibrium
constant for the reversible ionization of water is With [OH]  0.1 M, solving for [H] gives
[H  ][OH  ]
Keq  (2–3) Kw 1  1014 M2 1014 M2
[H2O] [H]    
[OH ] 0.1 M 101 M
In pure water at 25 C, the concentration of water is
 1013 M
55.5 M—grams of H2O in 1 L divided by its gram molecular
JWCL281_c11_359-385.qxd 6/3/10 10:35 AM Page 359

Sugars and
Polysaccharides
CHAPTER 11
1 Monosaccharides weight. Polysaccharides such as starch in plants and glyco-
A. Classification gen in animals serve as important nutritional reservoirs.
B. Configurations and Conformations The elucidation of the structures and functions of carbo-
C. Sugar Derivatives hydrates has lagged well behind those of proteins and nu-
2 Polysaccharides cleic acids. This can be attributed to several factors. Carbo-
A. Carbohydrate Analysis hydrate compounds are often heterogeneous, both in size
B. Disaccharides and in composition, which greatly complicates their physi-
C. Structural Polysaccharides: Cellulose and Chitin cal and chemical characterization. They are not subject to
D. Storage Polysaccharides: Starch and Glycogen the types of genetic analysis that have been invaluable in
E. Glycosaminoglycans the study of proteins and nucleic acids because saccharide
3 Glycoproteins sequences are not genetically specified but are built up
A. Proteoglycans through the sequential actions of specific enzymes (Section
B. Bacterial Cell Walls 23-3B). Furthermore, it has been difficult to establish as-
C. Glycoprotein Structure and Function says for the biological activities of polysaccharides because
D. Glycomics of their largely passive roles. Nevertheless, it is abundantly
clear that carbohydrates are essential elements in many, if
not most, biological processes.
Carbohydrates or saccharides (Greek: sakcharon, sugar) In this chapter, we explore the structures, chemistry,
are essential components of all living organisms and are, in and, to a limited extent, the functions of carbohydrates,
fact, the most abundant class of biological molecules. The alone and in association with proteins. Glycolipid struc-
name carbohydrate, which literally means “carbon hy- tures are considered in Section 12-1D. The biosynthesis of
drate,” stems from their chemical composition, which is complex carbohydrates is discussed in Section 23-3.
roughly (C ⴢ H2O)n, where n ⱖ 3. The basic units of carbo-
hydrates are known as monosaccharides. Many of these
compounds are synthesized from simpler substances in a 1 MONOSACCHARIDES
process named gluconeogenesis (Section 23-1). Others
(and ultimately nearly all biological molecules) are the Monosaccharides or simple sugars are aldehyde or ketone
products of photosynthesis (Section 24-3), the light-powered derivatives of straight-chain polyhydroxy alcohols contain-
combination of CO2 and H2O through which plants and ing at least three carbon atoms. Such substances, for exam-
certain bacteria form “carbon hydrates.” The metabolic ple, D-glucose and D-ribulose, cannot be hydrolyzed to
breakdown of monosaccharides (Chapters 17 and 21) form simpler saccharides.
provides much of the energy used to power biological O H
processes. Monosaccharides are also principal components 1
C
of nucleic acids (Section 5-1A), as well as important ele-
2 1
ments of complex lipids (Section 12-1D). H C OH CH2OH
Oligosaccharides consist of a few covalently linked HO
3
C H
2
C O
monosaccharide units. They are often associated with pro- 4 3
teins (glycoproteins) and lipids (glycolipids) in which they H C OH H C OH
have both structural and regulatory functions (glycopro- 5 4
H C OH H C OH
teins and glycolipids are collectively called glycoconju- 6 5
gates). Polysaccharides consist of many covalently linked CH2OH CH2OH
monosaccharide units and have molecular masses ranging D-Glucose D-Ribulose
well into the millions of daltons. They have indispensable
structural functions in all types of organisms but are most In this section, the structures of the monosaccharides and
conspicuous in plants because cellulose, their principal some of their biologically important derivatives are dis-
structural material, comprises up to 80% of their dry cussed.

359
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360 Chapter 11. Sugars and Polysaccharides

A. Classification Fischer elucidated these configurations for the aldohexoses in
1896.According to the Fischer convention (Section 4-2B), D
Monosaccharides are classified according to the chemical
sugars have the same absolute configuration at the asymmet-
nature of their carbonyl group and the number of their C
ric center farthest removed from their carbonyl group as does
atoms. If the carbonyl group is an aldehyde, as in glucose,
D-glyceraldehyde. The L sugars, in accordance with this con-
the sugar is an aldose. If the carbonyl group is a ketone, as
vention, are mirror images of their D counterparts, as is
in ribulose, the sugar is a ketose. The smallest monosaccha-
shown below in Fischer projection for glucose.
rides, those with three carbon atoms, are trioses. Those
with four, five, six, seven, etc., C atoms are, respectively, tet- O H O H
roses, pentoses, hexoses, heptoses, etc. These terms may be C C
combined so that, for example, glucose is an aldohexose,
whereas ribulose is a ketopentose. H C OH HO C H
Examination of D-glucose’s molecular formula indicates HO C H H C OH
that all but two of its six C atoms¬C1 and C6¬are chiral
H C OH HO C H
centers, so that D-glucose is one of 24 ⫽ 16 stereoisomers
that comprise all possible aldohexoses. In general, n-carbon H C OH HO C H
aldoses have 2n⫺2 stereoisomers. The stereochemistry and
CH2OH CH2OH
names of the D-aldoses are presented in Fig. 11-1. Emil
D-Glucose L-Glucose

CHO

HCOH Aldotriose

CH2OH
D-Glyceraldehyde

CHO CHO

HCOH HOCH
Aldotetroses
HCOH HCOH

CH2OH CH2OH
D-Erythrose D-Threose

CHO CHO CHO CHO

HCOH HOCH HCOH HOCH

HCOH HCOH HOCH HOCH Aldopentoses

HCOH HCOH HCOH HCOH

CH2OH CH2OH CH2OH CH2OH
D-Ribose (Rib) D-Arabinose (Ara) D-Xylose (Xyl) D-Lyxose (Lyx)

CHO CHO CHO CHO CHO CHO CHO CHO

HCOH HOCH HCOH HOCH HCOH HOCH HCOH HOCH

HCOH HCOH HOCH HOCH HCOH HCOH HOCH HOCH Aldohexoses
HCOH HCOH HCOH HCOH HOCH HOCH HOCH HOCH

HCOH HCOH HCOH HCOH HCOH HCOH HCOH HCOH

CH2OH CH2OH CH2OH CH2OH CH2OH CH2OH CH2OH CH2OH
D-Allose D-Altrose D-Glucose D-Mannose D-Gulose D-Idose D-Galactose D-Talose
(Glc) (Man) (Gal)

Figure 11-1 The stereochemical relationships, shown in distinguishes the members of each pair. The L- counterparts of
Fischer projection, among the D-aldoses with three to six carbon these 15 sugars are their mirror images. The biologically most
atoms. The arrows indicate stereochemical relationships (not common aldoses are boxed.
biosynthetic reactions). The configuration about C2 (red)
JWCL281_c11_359-385.qxd 6/3/10 10:35 AM Page 361

Section 11-1. Monosaccharides 361

Sugars that differ only by the configuration about one C function at C2 are the most common form (Fig. 11-2). Note
atom are known as epimers of one another. Thus D-glucose that some of these ketoses are named by the insertion of
and D-mannose are epimers with respect to C2, whereas -ul- before the suffix -ose in the name of the corresponding
D-glucose and D-galactose are epimers with respect to C4 aldose; thus D-xylulose is the ketose corresponding to the
(Fig. 11-1). However, D-mannose and D-galactose are not aldose D-xylose. Dihydroxyacetone, D-fructose, D-ribulose,
epimers of each other because they differ in configuration and D-xylulose are the biologically most prominent
about two of their C atoms. ketoses.
D-Glucose is the only aldose that commonly occurs in na-
ture as a monosaccharide. However, it and several other
B. Configurations and Conformations
monosaccharides including D-glyceraldehyde, D-ribose,
D-mannose, and D-galactose are important components of Alcohols react with the carbonyl groups of aldehydes and
larger biological molecules. L Sugars are biologically much ketones to form hemiacetals and hemiketals, respectively
less abundant than D sugars. (Fig. 11-3). The hydroxyl and either the aldehyde or the ke-
The position of their carbonyl group gives ketoses one tone functions of monosaccharides can likewise react in-
less asymmetric center than their isomeric aldoses (e.g., tramolecularly to form cyclic hemiacetals and hemiketals
compare D-fructose and D-glucose). n-Carbon ketoses (Fig. 11-4). The configurations of the substituents to each
therefore have 2n⫺3 stereoisomers. Those with their ketone carbon atom of these sugar rings are conveniently repre-
sented by their Haworth projection formulas.
A sugar with a six-membered ring is known as a pyra-
nose in analogy with pyran, the simplest compound con-
taining such a ring. Similarly, sugars with five-membered
CH2OH rings are designated furanoses in analogy with furan.
C O
O O
CH2OH
Dihydroxyacetone

Pyran Furan

CH2OH The cyclic forms of glucose and fructose with six- and five-
C O membered rings are therefore known as glucopyranose
and fructofuranose, respectively.
HCOH

CH2OH a. Cyclic Sugars Have Two Anomeric Forms
D-Erythrulose
The Greek letters preceding the names in Fig. 11-4 still
need to be explained. The cyclization of a monosaccharide
renders the former carbonyl carbon asymmetric. The re-
CH2OH CH2OH sulting pair of diastereomers are known as anomers and
the hemiacetal or hemiketal carbon is referred to as the
C O C O
anomeric carbon. In the ␣ anomer, the OH substituent to
HCOH HOCH the anomeric carbon is on the