Maize Genetics Cooperation Newsletter vol 87 2013
DNIPROPETROVSK, UKRAINE
L-proline
amount in callus tissues of Lancaster maize inbred lines under chloride load
Derkach KV*, Abraimova OE*, Dzubetskij BV*, Cherchel VJu*, Sitalo MJu**, Konoschuk JuV**, Satarova TM*
*Agricultural Steppe Zone Institute of
the National Academy of Agrarian Sciences of Ukraine, 14 Dzerzhynskyi str.,
Dnipropetrovsk, Ukraine, 49600
**Ukrainian State University of Chemical Technology, 8
Gagarin av., Dnipropetrovsk, Ukraine, 49005
Salinity of soil and soil waters are actual problems of land
utilization. Chloride salinity is the most common kind, in Ukraine it is
dominated by sulphate and carbonate forms. Chloride salinity has a
super-negative effect on the maize plant. Growth inhibition is observed already at 0.1% salt contents in soil, but
the salt level of 0.3-0.4% provokes the wilting and plant death. Numerous
metabolic cell abnormalities occur under the salt influence: inhibition of
enzyme activities, photosynthesis, protein synthesis, disorders of respiratory
processes [Dolgyh Ju. I., dis. phD: 384, 2005].
Protective
plant response to the negative effect of abiotic factors is being induced by a
lot of cell systems. One of the responses to the stress factors (salinity,
drought and low temperatures) is the accumulation of free L-proline in the
cells. The precursor of proline synthesis is glutamate or ornithine. Under the
stress proline content increases due to the regulation of two opposite
processes – the intensification of its biosynthesis and the inhibition of
its catabolism.
Proline is
an organic compound of low molecular weight which lightly resolves in water and
forms colloidal polymer structures. Free proline and proline in the protein
molecules are the required components of any plant cell. This aminoacid is a
component of the antioxidant protective system, it stabilizes the subcellular
structures and macromolecules, regulates redox potential, participates in the
modification of functions of mitochondria. Proline is a part of the signal
transmission systems those control gene expression in response to stress [Anjum
S. A. et al., Afr. J. Agric. Res. 6 (9): 2026-2032, 2011].
Ions Na+
and Cl- from the nutrient medium overcome the cell wall and enter
the cell through anionic and cationic channels, penetrate through protein hydrate
coverage and affect the noncovalent bonds that maintain the structure of the
protein molecules. Proline does not penetrate through hydrate coverage and does
not enter into direct contact with the proteins, but creates obstacles for the
hydrate coverage destruction and the protein denaturation by ions [Alyohina N.
D. et al., Physiology of plant: 636, 2006].
Proline is
an important cell osmoprotector. On the one hand it protects proteins from
denaturation and forwards their native conformation, interacting with them
during stress. On the other hand, it helps to achieve the osmotic balance of
cytosol with vacuoles and other cell organelles.
The
subject of our work includes the determination of proline amount in maize
callus tissues under chloride load and after its removal, the characterization
of influence of sodium chloride on the regeneration potential of callus tissues.
Research
material was represented by 5 inbreds of maize commercially valuable
Lancaster germplasm (DK633/266, DK633/325, DK236, DK3070, DK6080) and 1 inbred
of Polish germplasm (PLS61). Primary explants for induction of callus tissues
were immature embryos, 1.5 mm in length. Callus tissue was initiated within 30
days on N6 medium (Chu Ch.-Ch. et al., Sci. Sinica 18: 659 – 668, 1975) modified with 690 mg/l L-proline, 100 mg/l inositol,
100 mg/l casein hydrolyzate, 1 mg/l 2,4-D, 0.1 mg/l abscisic acid and two
levels of sucrose - 30 g/l or 60 g/l. Chloride load in vitro was simulated by
adding into the medium for subcultivation sodium chloride in concentrations of
6, 30 and 60 g/l. The content of L-proline was determined for 330-day
stabilized maize callus tissues obtained in two different ways. In the first
version the callus tissue was subcultivated on the N6 medium with 0 (control),
6, 30 or 60 g/l sodium chloride for 300 days right after the induction period.
In the second version the callus tissue was subcultivated on the N6 medium with
0 (control), 6, 30 and 60 g/l sodium chloride during 210 days right after the
induction period and maintained during the following 90 days on hormone free
regeneration medium MS (Murashige T. A. et al., Physiol. Plant 15: 473 – 497, 1962) without sodium chloride.
Determination of the proline amount was performed by a
modified method [Bates L. S. et al., Plant soil 39: 205-207, 1963]. Callus
tissue sample (approximately 1 g) was poured by boiling distilled water (10 ml)
and placed for 10 minutes in a boiling water bath. 2 ml of glacial acetic acid
and 2 ml of ninhidryn reagent was placed into the clean test tube. Then 2 ml of
extract was flowed to the same test tube. Samples were incubated for 1 hour in
a boiling water bath and then rapidly cooled in ice. 10 ml of toluene for
extraction of the proline was added to the obtained samples. The mixture was
separated in a separatoring funnel. The color intensity of proline fraction was
measured spectrophotometrically at the wavelength of 520 nm. Proline amount was
calculated according to calibration curve constructed with crystalline proline.
For the determination of proline amount the average sample from pieces of 3-5
typical calli was composed. Proline content was evaluated in 1 g of callus
tissue. Data processing was carried out according to [Atramentova N. O. et al.,
Statistic methods in biology: 288, 2007]. Data in tables are presented as 
, where
– the average value of the
index, m – the error of average
value, t0,05 – Student criterion for significance level of 0.05.
Proline content
in the maize callus tissues under the sodium chloride in the medium for
subcultivation was raised compared to control and was being increased simultaneously
with the increasing of sodium chloride concentration (Table 1). Proline content
in control depended on genotype and fluctuated between 483.16 - 1,509.23 mg
proline/g callus tissue. In general for induction medium applying 30 g/l
sucrose the level of proline in callus tissues was not lower, but sometimes
higher than for 60 g/l sucrose as without sodium chloride, so under its effect.
Table
1
Content of
L-proline in maize calllus tissues under chloride load
|
Sucrose
content in the medium for callus induction, g/l |
Sodium
chloride content in the medium
for callus subcultivation, g/l |
L-proline
content in callus tissues, mg L-proline/g callus
tissue |
|
DK633/266 |
||
|
60 |
0 |
483,16 � 17,13 |
|
60 |
6 |
764,98 � 18,45 |
|
60 |
30 |
1790,87 � 19,88 |
|
60 |
60 |
2633,71 � 19,24 |
|
DK633/325 |
||
|
60 |
0 |
1431,33 � 41,62 |
|
60 |
6 |
2573,36 � 39,40 |
|
60 |
30 |
2698,25 � 44,30 |
|
60 |
60 |
3621,32 � 43,63 |
|
DK236 |
||
|
30 |
0 |
1509,23 � 22,20 |
|
30 |
30 |
2100,29 � 16,40 |
|
30 |
60 |
4059,92 � 27,69 |
Ninety
days after the removal of chloride load the divergences of proline content
for the callus tissues having been cultivated on different levels of sodium
chloride have decreased (Table 2). Tested for inbred DK3070 levels of proline
after removal of chloride load in callus tissues obtained on callusogenic
medium with 30 g/l sucrose were higher then with 60 g/l sucrose. Regenerants
were recovered only for inbred PLS61 on the medium for subcultivation with 6 g/l sodium chloride. Proline amount in callus
tissues of PLS61 after the removal of chloride load was rather high compared to
nonregenerable inbred DK3070.
Table
2
Content of L-proline in
maize callus tissues after removal of chloride load
|
Sucrose
content in the medium for callus induction, g/l |
Sodium
chloride content in the medium for callus
subcultivation, g/l |
L-proline
content in callus tissues, mg L-proline/g callus
tissue |
|
DK3070 |
||
|
30 |
0 |
250,18 � 14,97 |
|
30 |
6 |
319,72 � 18,17 |
|
30 |
30 |
390,46 � 34,21 |
|
30 |
60 |
627,00 � 44,58 |
|
60 |
0 |
192,57 � 13,69 |
|
60 |
6 |
272,75 � 23,90 |
|
60 |
30 |
259,11 � 12,39 |
|
60 |
60 |
334,94 � 38,22 |
|
DK6080 |
||
|
30 |
30 |
1833,14 � 54,71 |
|
30 |
60 |
5529,57 � 53,06 |
|
PLS61 |
||
|
60 |
6 |
2082,63 � 21,25 |
|
60 |
30 |
2257,69 � 46,52 |
|
60 |
60 |
2304,97 � 40,18 |
The
experimental data allow concluding that the response of maize callus tissues to chloride load
leads to the accumulation of proline. The content of proline in callus tissues
depended on the concentration of sodium chloride in the nutrient medium and
increases with its magnification. Concentrations of sodium chloride in the
nutrient medium of 30 and 60 g/l completely suppress regenerative potential of
maize callus tissues, while 6 g/l sodium chloride permits the plant
regeneration of certain genotypes.
Please Note: Notes submitted to the Maize Genetics
Cooperation Newsletter may be cited only with consent of authors.