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27 Biochemistry of Fruits 543
is converted to lactate-by-lactate dehydrogenase using NADH
as the reducing factor, and generating NAD. Accumulation
of lactate in the cytosol could cause acidification, and un-
der these low pH conditions, lactate dehydrogenase is in-
hibited. The formation of acetaldehyde by the decarboxyla-
tion of pyruvate is stimulated by the activation of pyruvate
decarboxylase under low pH conditions in the cytosol. It is
also likely that the increase in concentration of pyruvate in the
cytoplasm may stimulate pyruvate decarboxylase directly. Ac-
etaldehyde is reduced to ethanol by alcohol dehydrogenase using
NADH as the reducing power. Thus, acetaldehyde and ethanol
are common volatile components observed in the headspace of
fruits indicative of the occurrence of anaerobic respiration. Cy-
tosolic acidification is a condition that stimulates deteriorative
reactions. By removing lactate through efflux and converting
pyruvate to ethanol, cytosolic acidification can be avoided.
Anaerobic respiration plays a significant role in the respira-
tion of citrus fruits. During early stages of growth, respiratory
activity predominantly occurs in the skin tissue. Oxygen up-
take by the skin tissue was much higher than the juice vesicles
(Purvis 1985). With advancing maturity, a decline in aerobic res-
piration and an increase in anaerobic respiration was observed
in Hamlin orange skin (Bruemmer 1989). In parallel with this,
the levels of ethanol and acetaldehyde increased. As well, a de-
crease in the organic acid substrates pyruvate and oxaloacetate
was detectable in Hamlin orange juice. An increase in the activ-
ity levels of pyruvate decarboxylase, alcohol dehydrogenase and
malic enzyme was noticed in parallel with the decline in pyru-
vate and accumulation of ethanol. In apple fruits, malic acid is
converted to pyruvate by the action of NADP-malic enzyme,
and pyruvate subsequently converted to ethanol by the action of
pyruvate decarboxylase and alcohol dehydrogenase. The alco-
hol dehydrogenase in apple can use NADPH as a cofactor, and
NADP is regenerated during ethanol production, thus driving
malate utilisation. Ethanol is either released as a volatile or can
be used for the biosynthesis of ethyl esters of volatiles.
Pentose Phosphate Pathway
Oxidative PPP is a key metabolic pathway that provides re-
ducing power (NADPH) for biosynthetic reactions as well as
carbon precursors for the biosynthesis of amino acids, nucleic
acids, secondary plant products and so on. The PPP shares many
of the sugar phosphate intermediates with the glycolytic path-
way (Fig. 27.4). The PPP is characterised by the interconversion
of sugar phosphates with three (glyceraldehyde-3-phosphate),
four (erythrose-4-phosphate), five (ribulose-, ribose-, xylulose-
phosphates), six (glucose-6-phosphate, fructose-6-phosphate)
and seven (sedoheptulose-7-phosphate) carbon long chains.
The PPP involves the oxidation of glucose-6-phosphate,
and the sugar phosphate intermediates formed are recycled.
The first two reactions of PPP are oxidative reactions medi-
ated by the enzymes glucose-6-phosphate dehydrogenase and
6-phosphogluconate dehydrogenase (Fig. 27.4). In the first step,
glucose-6-phosphate is converted to 6-phosphogluconate by the
removal of two hydrogen atoms by NADP to form NADPH.
In the next step, 6-phosphogluconate, a six-carbon sugar acid
phosphate, is converted to ribulose-5-phosphate, a five-carbon
sugar phosphate. This reaction involves the removal of a car-
bon dioxide molecule along with the formation of NADPH.
Ribulose-5-phosphate undergoes several metabolic conversions
to yield fructose-6-phosphate. Fructose-6-phosphate can then be
converted back to glucose-6-phosphate by the enzyme glucose-
6-phosphate isomerase and the cycle repeated. Thus, six com-
plete turns of the cycle can result in the complete oxidation of a
glucose molecule.
Despite the differences in the reaction sequences, the gly-
colytic pathway and the PPP intermediates can interact with one
another and share common intermediates. Intermediates of both
the pathways are localised in plastids, as well as the cytoplasm,
and intermediates can be transferred across the plastid mem-
brane into the cytoplasm and back into the chloroplast. Glucose-
6-phosphate dehydrogenase is localised both in the chloroplast
and cytoplasm. Cytosolic glucose-6-phosphate dehydrogenase
activity is strongly inhibited by NADPH. Thus, the ratio of
NADP to NADPH could be the regulatory control point for
the enzyme function. The chloroplast-localised enzyme is regu-
lated differently through oxidation and reduction, and related to
the photosynthetic process. 6-Phosphogluconate dehydrogenase
exists as distinct cytosol- and plastid-localised isozymes.
The PPP is a key metabolic pathway related to biosyn-
thetic reactions, antioxidant enzyme function and general
stress tolerance of the fruits. Ribose-5-phosphate is used in
the biosynthesis of nucleic acids and erythrose-4- phosphate
is channelled into phenyl propanoid pathway leading to the
biosynthesis of the amino acids phenylalanine and tryptophan.
Phenylalanine is the metabolic starting point for the biosynthe-
sis of flavonoids and anthocyanins in fruits. Glyceraldehyde-
3-phosphate and pyruvate serve as the precursors for the iso-
prenoid pathway localised in the chloroplast. Accumulation of
sugars in fruits during ripening has been related to the function
of PPP. In mangoes, an increase in the levels of pentose sugars
observed during ripening has been related to increased activity
of PPP. Increases in glucose-6-phosphate dehydrogenase and
6-phosphogluconate dehydrogenase activities were observed
during ripening of mango.
NADPH is a key component required for the proper function-
ing of the antioxidant enzyme system (Fig. 27.4). During growth,
stress conditions, fruit ripening and senescence, free radicals are
generated within the cell. Activated forms of oxygen, such as
superoxide, hydroxyl and peroxy radicals, can attack enzymes,
proteins, nucleic acids and lipids, causing structural and func-
tional alterations of these molecules. Under most conditions,
these are deleterious changes, which are nullified by the action of
antioxidants and antioxidant enzymes. Simple antioxidants such
as ascorbate and vitamin E can scavenge the free radicals and
protect the tissue. Anthocyanins and other polyphenols may
also serve as simple antioxidants. In addition, the antioxidant
enzyme system involves the integrated function of several en-
zymes. The key antioxidant enzymes are superoxide dismutase
(SOD), catalase, ascorbate peroxidase and peroxidase. SOD con-
verts superoxide into hydrogen peroxide. Hydrogen peroxide is
immediately acted upon by catalase, generating water. Hydro-
gen peroxide can also be removed by the action of peroxidases.