Handbook of Plant and Crop Physiology

(Steven Felgate) #1

  1. Total Soluble-N Content of Plants


Soluble N compounds that should be in an ethanol extract of plant tissues include NO 3 , NH 4 , amides,
amino acids, amine, amino sugars, peptide, alkaloids, nucleotide, chlorophyll, and even some fats. Be-
cause only the NH 4 form of N was used in this investigation,^15 N from^15 NH 4 exposure should not be
found in the NO 3 form in the plant tissues in this study.
The total soluble-^15 N concentration of the plant tissues increased with NaCl concentration at 0.8
MPa osmotic potential after 24 hr exposure to^15 NH 4 at the vegetative growth stage, then declined at 1.2
MPa (Table 6). At the reproductive growth stage, total soluble-^15 N increased in a similar manner but did
not decline at the highest salinity level. Thus, the decrease in protein-^15 N at the 1.2 MPa salinity level
did not result from a shortage of soluble-^15 N compounds. The rates of^15 N incorporation into the total sol-
uble-^15 N fraction as indicated by the slope of the regression of the^15 N tissue concentration versus time
(Table 7) followed the same pattern as described before for the 24-hr uptake time. Accumulation of sol-
uble-N compounds in plants under stress conditions has also been reported by several other investigators
for various plant species [43,49,53–61,65,66,69,70,72–76,79,81–86,89–96,101,102,153].
The amounts of soluble-^15 N reflect both concentrations in the tissue and dry-matter production
(Table 1). Significantly less total soluble-^15 N was found after 24 hr with 1.2 MPa salinity at the vege-
tative growth stage. With the 0.8 MPa salinity, a larger amount of total soluble-^15 N was observed than
with other treatments. At the reproductive stage, the amounts of total soluble-^15 N were equal at the high
and low levels of salinity, with the intermediate salinity levels resulting in higher quantities of total solu-
ble-^15 N in the plant parts.
Although the rate of^15 NH 4 absorption was severely curtailed by high salinity at both growth stages
[62], growth was not restricted by decreased total soluble-N concentration. However, impairment of sol-
uble-N utilization at high salinity was reflected in a severe decrease in the protein concentration of plants.
It is not clear whether this lower protein concentration was a cause of reduced growth. Growth was re-
duced at the lower salinity levels without a reduction in the protein concentration.
The ratio of protein-N to non–protein-N (soluble-N) is further evidence for the decrease in the pro-
tein-N content of the NaCl-treated plants. A substantial decrease in the ratio of protein-^15 N to non–pro-
tein-^15 N was observed for the plants subjected to a high level of NaCl (1.2 MPa osmotic potential) com-
pared with the controls at both stages of growth (Table 6). At both stages of growth, the values for the
0.8 MPa osmotic potential of the NaCl-treated plants were significantly lower than the controls.



  1. Ammonium Plus Amide-N Content of Plants


At both stages of growth, significantly higher concentrations of ammonium plus amide-^15 N accumu-
lated in the shoots of the plants subjected to NaCl stress compared with the controls (Table 6). The con-
centration of ammonium plus amide-^15 N increased with increasing salinity to a maximum at 0.8 MPa
osmotic potential. Because the absorption rate of^15 NH 4 did not change appreciably at these salinity
levels, this increased accumulation of ammonium plus amide-N must have resulted from a reduced rate
of utilization; however, reduced growth is another possible consideration. The concentrations of am-
monium plus amide-N at the 1.2 MPa stress were lower than at the 0.8 MPa osmotic potential.
These values reflect markedly reduced absorption rates at the 1.2 MPa stress [62]. The rate of^15 N
utilization also decreased, allowing a higher^15 N concentration than commensurate with absorption rate.
Slopes for regressions of ammonium plus amide-^15 N and time of uptake for each salinity level (Table
7) indicate a rate of accumulation pattern similar to the concentrations indicated for the 24 hr exposure
time (Table 6).



  1. Free Amino-N Content of Plants


Free amino acids would be expected to constitute the major portion of the total ethanol soluble-N com-
pounds from plant tissues. In this study, the amino-N and ammonium plus amide-N accounted for 30 to
55% of the total soluble-N. The ninhydrin release method for free amino-N determination was used in this
investigation. This method, however, can result in poor recoveries of a number of amino acids [168]. In
Kennedy’s [168] investigation, recoveries varied from 2 to 60% for 12 amino acids with complete re-
covery of 14 others. In the present study, the apparent low recovery of amino-^15 N from cotton tissues by
the ninhydrin release method is consistent with the results of Kennedy [168] when all aspects of the
methodology are considered. Even with the low recovery, however, the relative effects of NaCl salinity
on amino acid formation and utilization should be valid.


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