The influence of abscisic acid on different polysomal populations in embryonal tissue during pea seeds germination

The influence of abscisic acid (ABA) on the processes of formation of different polysomal populations, their structures and stability in embryonal tissue during pea seeds germination was studied. The contents of total ribosomal fraction increased in all samples up to 72 h of germination and then decreased. The contents of polysomal population (FP, MBP, CBP and CMBP) extracted from the embryonal tissue after 72 hrs of germination of pea seeds were then quantified. It turned out that in examined tissue of control sample, fraction of free polysomes (FP) was the most abounded. This population of polysomes in sprouts decreased after ABA treatment. FP content decreased even more when the higher ABA concentration was applied during germination. Similar changes were observed in the fraction of membrane-bound polysomes (MBP). Quite different tendencies were found, however, in forming population of the cytoskeleton-membrane-bound polysomes (CMBP). The CMBP population content in embryonal tissue increased in a dosage dependent manner with increasing concentration of ABA applied during seed germination. This indicates the important role of CMBP fraction in synthesis of specific proteins in embryos in the time when processes of seeds germination are retarded by ABA. In the final part we examined the stability of polysomes isolated from sprouts of germinating seeds in water and sprouts isolated from seeds treated with ABA (100 μM) during germination. Total polysomes isolated from embryonal tissue of germinating seeds treated with ABA showed much higher resistance to exogenous ribonuclease digestion than total polysomes of control sample. The obtained results suggest that ABA influence on different polysomal population formation also controls their stability.     

Significant role for polysomes associated with the cytoskeleton in the control of protein synthesis during germination of triticale caryopses in the presence of abscisic acid

The influence of abscisic acid (ABA) on the process of polysome formation and synthesis of newly-formed proteins by different polysome populations was studied. Triticale caryopses were germinated in water or various ABA concentrations for 48 hrs, and afterwards they were transferred to a solution of ¹⁴C-amino acids and germinated for an additional 30 min. Embryos were separated from caryopses, and four polysome populations were isolated: the FP (free polysomes), MBP (membrane-bound polysomes), CBP (cytoskeleton-bound polysomes) and CMBP (cytoskeleton-membrane-bound polysomes). ABA retarded both the process of polysome formation and their activity in forming new proteins in vivo in all studied fractions. Participation of polysomes in total ribosomal materials (sub-units, monosomes and polysomes) of each polysome population in the control sample was as follows: FP — 77; MBP — 72; CBP — 70 and CMBP — 66 %, whereas in sample treated by ABA (100 μM) it was accordingly: 17; 23; 27 and 28%. The largest population made up FP (in control sample 69%), participation of MBP was always lower and ranged from about 19 to 30 %. Participation of polysome populations bound with the cytoskeleton CBP and CMBP, both in control sample as well as in samples treated with 1 and 10 μM ABA solution, was only a few per cent. It should be noted that when the ABA concentration was higher (100 μM) (process of germination was strongly inhibited), participation of those two populations (CBP and CMBP) was much increased in embryos, respectively to about 18 and 20 %. In both the control group and in embryonal tissue treated with ABA increasing incorporation of radioactive precursors to newly-formed proteins in vivo in fractions of polysomes isolated by following buffers: C (FP), C + PTE (MBP), C + Tris (CBP) and buf. U (CMBP) was observed. It should be noted, that the biggest incorporation of ¹⁴C-amino acids into nascent polypeptide chains was found in the last polysome population (CMBP). In the sample treated with ABA (100 μM) the activity of this fraction (CMBP) in forming new proteins is several times, and in the case of FP dozens of times, more intense. Increased participation of CBP and CMBP in embryos of triticale caryopses treated with ABA (100 μM) and the largest incorporation of ¹⁴C-amino acids into nascent polypeptide chains synthesised by CMBP, may indicate the important role of proteins formed by polysomes associated with cytoskeleton in inhibition of germination and seedling growth by ABA.     

Possible involvement of the cytoskeleton in the regulation of barley caryopsis dormancy and germination

This study was conducted on barley cv. Ars. caryopses collected at full ripeness and divided into two batches. From one batch (dormant caryopses) polysomes were isolated from embryos immediately after harvesting and after two days of germination. From the other batch (non-dormant caryopses) the same was done after eight months storage in a dry state. A low ionic strength cytoskeleton-stabilizing buffer was used for the isolation of polysomes. Four different fractions of polysomes were examined: free polysomes (FP), membrane-bound polysomes (MBP), cytoskeleton-bound polysomes (CBP) and cytoskeleton-membrane-bound polysomes (CMBP). In germs grown from non-dormant caryopses, the first two fractions (FP + MBP) made up about 78 % of the total ribosomal material, whereas in embryos of dormant, imbibed caryopses, two last fractions (CBP + CMBP) made up about 71 %. The percentage of polysomes after 48 hours of imbibition of dormant caryopses in the FP, MBP and CBP was only about 13 % (i.e., 87 % monosomes), whereas a greater proportion (19.4 %) was found in the CMBP. The highest incorporation of ³H-uridine and ¹⁴C-amino acids (after 48 hours of germination and 0.5, 3 and 6 hrs incubation with precursors) took place in trhc CMBP both in dormant and non-dormant caryopses The major amount of the two polysome fractions associated with the cytoskeleton (CBP and CMBP) and the higher activity of CMBP in protein synthesis in embryos of dormant, imbibed triticale caryopses may indicate a significant role for polysomes associated with the cytoskeleton in the control of protein synthesis in dormant and germinating caryopses.     

Effect of osmotic stress on the formation of a population of polysomes and their stability in pea (<Emphasis Type="Italic">Pisum sativum</Emphasis> L.) seeds

Plants growing under natural conditions are constantly exposed to various stress factors, which can restrain their productivity and limit yields. This paper deals with the effect of long- and short-term osmotic stress followed by recovery on the formation of polysomes and their stability during germination of pea (Pisum sativum L.) seeds. By isolating polysomes, it is possible to obtain an index which evidences the ability of tissues to synthesize proteins. Changes in the distribution of polysomes often precede measurable changes in amounts of proteins. Under osmotic stress, the dominant population of polysomes was the population of free polysomes (FP). The share of membrane-bound polysomes (MBP) and cytoskeleton-bound polysomes (CBP) and cytoskeleton-membrane-bound polysomes (CMBP) in the total fraction of ribosomes increased under intensive (−1.0 and −1.5 MPa) osmotic stress. These results can suggest that the bound forms of polysomes play an important role in the synthesis of stress proteins. In addition, the stability of polysomes isolated from pea early seedlings growing under unstressed control and osmotic stress conditions was tested. It turned out that polysomes formed under osmotic stress conditions (especially the CMBP) were more resistant to the activity of exogenous ribonucleases than the polysomes in the control samples. Under stress conditions it is highly likely that ribosomes become more densely packed on mRNA thus making it more resistant to ribonuclease. This is just one of the many mechanisms regulating stability of mRNA.     

Formation and stability of polysomes and polysomal populations in roots of germinating seeds of soybean (Glycine max L.) under cold,osmotic and combined cold and osmotic stress conditions

Abiotic stress factors such as extreme temperatures or osmotic stress are among the major causes of inferior crop yields. In response to a stress, plants have evolved various defense mechanisms. In our study, we have demonstrated how cold stress, osmotic stress and a combination of both stresses retard the growth of roots and inhibit the process of ribosomes binding into polysomes. The tested stresses also limited the ability of root tissues to synthesize proteins. At the same time, most of the analyzed samples were found to contain elevated shares of the fractions of cytoskeleton-bound polysomes (CBP, CMBP) in the total population of polysomes. Using a polysome-based degradation system, it was shown that polysomes formed under stress conditions were much more resistant to the effect of exogenous ribonuclease than the control ones. The highest tolerance to digestion was demonstrated by the cytoskeleton-bound (CBP) and cytoskeleton-membrane bound polysomes (CMBP). The increasing share of CBP and their stability in roots of seeds germinating under stress conditions can be a target for physiological regulation. It seems that modifications in the stability and percentages of particular polysomal populations play an important role in the adaptation of plants to stress conditions, which may indicate that these forms of polysomes, i.e., cytoskeleton-bound ones, are involved (via selective translation) in the synthesis of stress proteins in soybean roots.     

Exogenous abscisic acid increases stability of polysomes in embryos of triticale caryopses during germination

Some posttranslational processes that occur in embryos of germinating triticale caryopses treated with different concentrations of abscisic acid (ABA) were examined. ABA increased the ratio of cytoskeleton-bound polysomes in the total population of polysomes and depressed the share of free and membrane-bound polysomes. Using exogenous RNase, stability of the total polysomal population as well as each polysomal fraction was investigated. The total extractable polysomes isolated from embryonic tissues of germinating triticale caryopses treated with ABA were more stable than the polysomes isolated from the control sample caryopses. The contribution of the polysomes that were not digested by RNase was increased by higher concentrations of ABA applied during germination. At high concentrations of ABA (50, 100 μM), the quantitative contribution of polysomes in the total ribosomal fraction was almost 100% of the amount of polysomes before digestion and the modifications observed consisted mainly of the shift of the so-called heavy polysomes towards light polysomes, containing a few ribosomes. Within each polysomal population, cytoskeleton-bound polysomes (CBP and CMBP) were the most stable, which may imply that the bonds between polysomes and these protein filaments, created in all eukaryotic cells increased their stability. It is assumed that mRNAs are stabilised or destabilised by interaction of proteins with their various sequences. A plant hormone may depress or elevate the quantities of these proteins, thus regulating the stability of different mRNAs. The results confirm the multi-faceted mechanism of ABA-induced response, where one of the constituents is the effect of ABA on the stability of mRNAs molecules. The co-ordinated regulation of mRNAs synthesis and their stability provide plants with improved adaptability.     

Water-deficit-induced changes in cytoskeleton-bound and other polysomal populations in embryonic tissue during triticale caryopsis germination

We studied the influence of water-deficit stress on the process of formation of different polysomal populations, their abundance and stability in embryonic tissue during triticale caryopsis germination. Osmotic stress retarded the ability of seeds to germinate and decreased the content of the total ribosomal fraction in embryos. In control samples, the fraction of free polysomes was the most abundant and this population of polysomes decreased sharply in osmotic stress conditions. Water-deficit stress applied during germination profoundly changed the proportions between different polysome populations in the total ribosomal fraction of embryonic tissue. The predominant population in these conditions was the cytoskeleton-bound fraction. This may indicate an important role for cytoskeleton-bound polysomes in the synthesis of stress-induced proteins. We hypothesize that there must be an active mechanism of translational control that permits specific proteins to be synthesized despite a reduction in total protein synthesis.     

Importance of cytomatrix-bound polysomes to synthesis of lysine-containing proteins in triticale germs under ABA treatment

The influence of exogenous abscisic acid (ABA) on the content of free polysomes (FP), membrane-bound polysomes (MBP), cytoskeleton-bound polysomes (CBP) and cytomatrix-bound polysomes (CMBP) in triticale germs as well as in vitro protein synthesis by these four polysomal fractions were studied. During translation, proteins were biotinylated for chemiluminescence detection. We have found that ABA changed both the content of FP, MBP, CMP and CMBP in germ tissue, and their subsequent translation activity. At 100 μM ABA, the content of FP and MBP was over fourfold lower compared to the control, whereas the amounts of CBP and CMBP were about two- and threefold higher, respectively. Moreover, the estimation of the share of polysomes in each ribosomal fraction (sub-units, monosomes, polysomes) showed that, at 100 μM ABA, cytomatrix-bound polysomes, which constituted 90% of polysomes, were the predominant class in ABA-treated germs while membrane-bound polysomes, which made up 82% of polysomes, dominated in the control. A high level of CMBP in ABA-treated tissues may indicate that this class of polysomes participates in ABA-induced synthesis of proteins. In turn, the inhibition of MBP under ABA-treatment is probably due to the delayed protein synthesis which takes place on these polysomes. We identified two lysine-containing proteins synthesized on both of the above classes of polysomes, whose synthesis was altered due to ABA application. Synthesis of a 47 kDa protein on MBP was inhibited, while synthesis of a 79 kDa protein on CMBP is strongly enhanced by ABA influence. The importance of these findings is discussed.     

Changes in Polysomes and RNA in Developing Seeds of Chickpea (Cicer arietinum L.)

In the present investigation changes in polyribosomes and RNAs in the developing seeds of chickpea (Cicer arietinum L.) have been studied. The total polysome yield was higher in the early stages of development and declined at the later stages. The maximum level of polyribosomes was obtained at 18 days after flowering and a drastic decrease was noticed at maturity. The total RNA yield correlated with the polysomal yield. Northern hybridization with a heterologous probe (pea legumin cDNA) gave distinct hybridization with the mRNA coding for legumin proteins at different stages of seed development. Hybridization showed a direct relation between mRNA levels and seed weight accumulation.     

Polysome formation and incorporation of new ribosomes into polysomes during germination of the embryonic axis of maize

Isolated axes of Zea mays L. cvs CiV₂ and CUZCO were imbibed for different periods of time, and free polysomes were extracted and analysed by centrifugation in a sucrose gradient. The amount of rRNA per axis was determined at different moments of germination. Polysome reassembly was practically completed by 8 h and 54% of the preformed ribosomes were found in the polysome fraction. An increase in the proportion of large polysomes was also observed during this period of germination. During the following period, the polysome content and the distribution of the various classes of polysomes remained unchanged.
The time of appearance of newly synthesized ribosomes into the polysomes was investigated using axes germinated in the presence of [³H]-uridine. Centrifugal analysis of EDTA-dissociated polysomes and gel electrophoretic analysis of polysomal RNA showed that new ribosomes appeared into polysomes a few hours after completion of the initial polysome assembly. When released into the cytoplasm, the new ribosomes were preferentially incorporated into polysomes rather than stored as free ribosomes.     

Influence of Plant Root Exudates, Germ Tube Orientation and Passive Conidia Transport on Biological Control of Fusarium Wilt by Strains of Nonpathogenic Fusarium oxysporum

In earlier studies, biological control of Fusarium wilt of cucumber induced by Fusarium oxysporum f. sp. cucumerinum was demonstrated using nonpathogenic strains C5 and C14 of Fusarium oxysporum. Strain C14 induced resistance and competed for infection sites whether roots were wounded or intact, whereas strain C5 required wounds to achieve biocontrol. In the current work, additional attributes involved in enhanced resistance by nonpathogenic biocontrol agents strains to Fusarium wilt of cucumber and pea were further investigated. In pre-penetration assays, pathogenic formae specials exhibited a significantly higher percentage of spore germination in 4-day-old root exudates of cucumber and pea than nonpathogens. Also, strain C5 exhibited the lowest significant reduction in spore germination in contrast to strain C14 or control. One-day-old cucumber roots injected with strain C14 resulted in significant reduction in germ tube orientation towards the root surface, 48–96 h after inoculation with F. o. cucumerinum spores, whereas strain C5 induced significantly lower spore orientation of the pathogen and only at 72 and 96 h after inoculation. In post-penetration tests, passive transport of microconidia of pathogenic and nonpathogens in stems from base to apex were examined when severed plant roots were immersed in spore suspension. In repeated trials, strain C5, F. o. cucumerinum and F. o. pisi were consistently isolated from stem tissues of both cucumber and pea at increasing heights over a 17 days incubation period. Strain C14 however, was recovered at a maximum translocation distance of 4.6 cm at day 6 and later height of isolation significantly declined thereafter to 1.2 cm at day 17. In pea stem, the decline was even less. Significant induction of resistance to challenge inoculation by the pathogen in cucumber occurred 72 and 96 h after pre-inoculation with biocontrol agents. Nonetheless, strain C14 induced protection as early as 48 h and the maximum resistance was reached at 96 h. The presented data confirm the previous findings that attributes important for nonpathogenic fusaria to induce resistant are: rapid spore germination and orientation in response to root exudate; active root penetration and passive conidia transport in stem to initiate defence reaction without pathogenicity and enough lag period between induction and challenge inoculation. Strain C14 possesses all these qualifications and hence its ability to enhance host resistance is superior than strain C5.     

Polysomes, Messenger RNA, and Growth in Soybean Stems during Development and Water Deficit

The polysome status and populations of polysomal mRNA were examined in different regions of dark-grown soybean (Glycine max [L.] Merr.) stems that contained either dividing, elongating, or mature (nongrowing) cells. There was a developmental gradient of polysome content in which the dividing tissue had the highest levels and the mature tissue the lowest. A few hours after transplanting the seedlings to vermiculite having low water content (water potential Ψ_w = −0.29 megapascals), stem growth rate decreased to 30% of well-watered controls and the polysome content decreased most in the dividing and elongating tissues. After 24 to 36 hours, stem growth and polysome content recovered gradually. In vitro translation products of polysomal mRNA from dividing, elongating or mature tissue were examined on two-dimensional gels. In well-watered controls, each of the stem regions was enriched in a small subset of the polysomal mRNA population, probably because of developmentally regulated gene expression. Exposing plants to low Ψ_w for 24 hours induced a change in the relative abundance of a small number of polysomal mRNAs in the elongating and mature tissues, but not in the dividing tissue. After 24 to 72 hours at low Ψ_w, the changes in polysomal mRNA population were reversed in the elongating tissue. The data indicate that changes in stem growth at low water potential are associated with changes in polysome status and polysomal mRNA in the elongating tissue.     

Regulation of protein synthesis in Tetrahymena: isolation and characterization of polysomes by gel filtration and precipitation at pH 5.3.

The fraction of ribosomes loaded on polysomes is about 95% in logarithmically growing Tetrahymena thermophila, and about 4% in starved cells. Cytoplasmic extracts from cells in these two physiological states were used to develop column chromatographic methods for the purification of polysomes. Bio-Gel A 1.5 m was found to separate total cytoplasmic ribosomes from many soluble proteins, including RNAse, with no detectable change in the polysome size distribution. Polysomes can be separated from monosomes and non-polysomal mRNA by chromatography on Bio-Gel A 15 m without size selection. These methods can easily be adapted to large scale preparations of polysomes, even from cells where a small fraction of the ribosomes is on polysomes. A method is described for reversible precipitation of polysomes and monosomes from dilute solutions at pH 5.3 which greatly facilitates polysome isolation. Hybridization of 3H-labeled polyU to RNA isolated from column fractions has been used to demonstrate that purification of EDTA released polysomal mRNA can be performed using the column chromatography procedures described here. These methods have been employed to demonstrate that most of the cytoplasmic mRNA in log-phase Tetrahymena is loaded onto polysomes while most of the mRNA is starved cells exists in a non-polysomal form.     

Import of proteins into mitochondria. Translatable mRNAs for imported mitochondrial proteins are present in free as well as mitochondria-bound cytoplasmic polysomes

In order to assess the role of different polysomal populations in mitochondrial protein import, yeast spheroplasts were treated with cycloheximide to prevent polysome "run-off" and fractionated into free polysomes, polysomes bound to the mitochondrial outer surface, and polysomes bound to the endoplasmic reticulum. These polysomes were analyzed for translatable mRNAs coding for 8 cytosolic and 12 imported mitochondrial proteins. The mitochondrial proteins included 7 proteins of the inner membrane, 2 proteins of the matrix, 2 proteins of the intermembrane space, and 1 protein of the outer membrane. Of the mRNAs for imported mitochondrial proteins, 8 were enriched in mitochondria-bound polysomes, 3 were enriched in free polysomes, and 1 was enriched in neither. All mRNAs for cytosolic proteins were enriched in free polysomes. Polysomes bound to the endoplasmic reticulum lacked significant levels of translatable mRNAs for either cytosolic or mitochondrial proteins. Even though mRNAs for imported mitochondrial proteins were enriched in mitochondria-bound polysomes, these polysomes represented only 12-18% of the total cytoplasmic polysomes. As a consequence, none of the translatable mRNAs for imported mitochondrial proteins tested was predominantly associated with mitochondria-bound polysomes. While mitochondria-bound polysomes may contribute to mitochondrial protein import, they do not appear to be obligatory for this process.     

The effect of insulin on proteins associated with free,cytoskeletal-bound and membrane-bound polysome populations.

It is known that insulin treatment increases the rate of protein synthesis in many cells and tissues and that it causes changes in the distribution of ribosomes between free (FP), cytoskeletal-bound (CBP) and membrane-bound polysome (MBP) populations. This paper concerns an analysis of the pattern of proteins in high-salt extracts of FP, CBP and MBP isolated from Krebs II ascites and MPC-11 cells. A combined detergent/salt extraction procedure was used to isolate the three fractions of polysomes from control cells and from cells following short-term stimulation with insulin. There were differences in the protein patterns in the individual fractions and changes occurred after insulin stimulation.     

Wounding of Aged Pea Epicotyls Enhances the Reinitiating Ability of Isolated Ribosomes

Total ribosomes (monosomes plus polysomes) isolated from woundedpea epicotyls are more efficient at supporting protein synthesisin a wheat germ S₃₀ system (containing wheat ribosomes) thanare total ribosomes from aged (control) pea tissue. This increasedefficiency is seen when enriched large polysomes, almost devoidof monosomes, are used to program a wheat germ S₃₀₀ system,from which the wheat germ ribosomes have been removed. Reactionsprimed by enriched polysomes from wounded tissue, but not agedtissue, continue for at least 30 min, suggesting that reinitiationis occurring during the reaction, albeit in the initial absenceof monosomes from wheat or pea. Wheat germ ribosomes, but notmonosomes from either aged or wounded pea tissue, are able totranslate pea poly(A) RNA and globin mRNA. Aurintricarboxylicacid reduces protein synthesis in a rather indiscriminate manner,whereas, pactamycin seems to have an inhibitory effect specificfor initiation, and it is much more effective on wounded thanon control tissue polysomes. We interpret these results to implythat polysomal ribosomes from wounded tissue are more efficientat initiation than are polysomal ribosomes from control tissueor than non-polysomal ribosomes (monosomes) from either tissue. (Received May 7, 1985; Accepted July 4, 1985)     

Cell-free Synthesis of Pea Seed Proteins

Both polysomes and polysomal RNA, isolated from cotyledons of ripening pea (Pisum sativum) seeds and supplemented respectively with wheat germ S-100 and S-30 fractions, were used to program the cell-free synthesis of polypeptides. The relationship of these polypeptide products to seed storage proteins has been investigated. When fractionated on sucrose density gradients the translation products did not coincide with native storage proteins, nor were they exactly coincident with the subunits of storage proteins on dissociating gels. Treatment with antiserum prepared against storage proteins precipitated only a very small proportion of these products. Nonetheless, tryptic peptide mapping showed that a significant proportion (up to 65%) of the in vitro products from cell-free systems were related to the storage proteins. Alternative interpretations of these results are that either the translatable mRNAs for storage proteins make up a small proportion of the total template isolated from pea cotyledon polysomes, or that storage protein polypeptides are made in significant amounts in vitro but lack major antigenic determinants which in vivo may be acquired during chain completion or post-translational modification.     

Specificity of factors isolated from free polysomes and microsomes on in vitro protein synthesis in plasmacytoma cells

A simple procedure for measuring chain initiation in complete in vitro systems is described. The capacity of free and membrane-bound polysomes prepared by a detergent technique or by nitrogen cavitation to incorporate radioactive amino acids into proteins was compared with the capacity of these polysomes to initiate polypeptide chains.The extent of amino acid incorporation by polysomes prepared by either of these methods did not differ significantly. However, chain initiation determined by measuring the incorporation of radioactive subunits into polysomes showed that polysomes prepared by the detergent technique were less effective than polysomes made by nitrogen cavitation in chain initiation.Crude initiation factors, prepared by washing either free polysomes or microsomes with 0.5 M KCl, stimulated chain initiation and amino acid incorporation by both types of polysomes. Free polysomes were stimulated almost to the same extent by factors isolated from free polysomes or microsomes. Membrane-bound polysomes on the other hand showed a specific requirement for microsomal factors.The extent of stimulation by crude polysomal factors was dependent on the concentration of high speed supernatant in the assay system.     

Isolation and in vitro translation of polysomes from mature rye leaves

Cytoplasmic polysomes have been prepared from mature leaves of winter rye (Secale cereale L. cv Puma). This is the first time a method has been developed for isolation of highly polymerized polysomes from mature leaves. The degree of intactness of isolated plant polysomes has been determined by two independent but complementary methods: size class distribution by sucrose gradient centrifugation and in vitro translation. The polymerization of isolated polysomes was estimated by the ratio of the proportion of large polysomes to the proportion of small polysomes obtained from the profiles. Our results show that the composition of the optimal polysome isolation buffer for mature rye leaves is different from that reported for young tobacco and pea leaves. Polysomes were translated in vitro with the S-105 wheat germ fraction. The degree of polysome polymerization has a significant effect on their in vitro translation since both the incorporation of amino acid and the presence of high molecular weight polypeptides are proportional to the large polysomes/small polysomes ratio. This study emphasizes the need to evaluate isolation conditions carefully before proceeding with polysome studies in any particular tissue or in tissues under different physiological status.