Isoperoxidases as markers of the wound-induced differentiation pattern in potato tuber

Isoperoxidases induced by wounding in potato tuber tissue were separated by starch gel electrophoresis and found to be distributed in a highly specific spatial pattern. This pattern of molecular differentiation correlates well with the pattern of cell differentiation associated with wound healing. Although wound induced isoperoxidases were found to vary between three varieties of potato, they were distributed in the same spatial pattern. The combination of isozymes extracted from various parts of a potato plant was specific for each of nine organs and tissues, and all combinations were different from the isozymes from wounded tuber tissue. Isoperoxidases can thus be considered as highly specific molecular markers of cell differentiation.     

Kinetics and localization of wound-induced DNA biosynthesis in potato tuber

Tuber wounding induces a cascade of biological responses that are involved in processes required to heal and protect surviving plant tissues. Little is known about the coordination of these processes, including essential wound-induced DNA synthesis, yet they play critical roles in maintaining marketability of the harvested crop and tubers cut for seed. A sensitive “Click-iT EdU Assay” employing incorporation of the thymidine analog, 5-ethynyl-2′-deoxyuridine (EdU), in conjunction with 4′,6-diamindino-2-phenylindole (DAPI) counter labeling, was employed to objectively identify and determine the time course and spatial distribution of tuber nuclei that were wound-induced to enter S-phase of the cell cycle. Both labeling procedures are rapid and sensitive in situ. Following wounding, EdU incorporation (indicating DNA synthesis) was not detectable until after 12 h, rapidly reached a maximum at about 18 h and then declined to near zero at 48 h. About 28% of the nuclei were EdU labeled at 18 h reflecting the proportion of cells in S-phase of the cell cycle. During the ∼30 h in which induced cells were progressing through S-phase, de novo DNA synthesis extended 7–8 cell layers below the wound surface. Cessation of nuclear DNA synthesis occurred about 4 d prior to completion of wound closing layer formation. Initiation of wound periderm development followed at 7 d, i.e. about 5 d after cessation of nuclear DNA biosynthesis; at this time the phellogen developed and meristematic activity was detected via the production of new phellem cells. Collectively, these results provide new insight into the coordination of wound-induced nucleic acid synthesis with associated tuber wound-healing processes.     

Studies on enzymes involved in DNA synthesis and thymine nucleotide formation in potato tuber slices

Activity changes of several enzymes involved in DNA synthesiswere investigated in potato tuber tissue in which DNA synthesiswas induced by slicing. Nucleoside phosphotransferase activityincreased only slightly during aging of the tissue discs. Thymidinemonophosphate (TMP) kinase activity increased about 36% afteraging for 24 hr. Protein synthesis in an early stage of agingwas necessary for the activity increase. A 2.7-fold increasewas observed in DNA polymerase activity after aging for 36 hr.The activity increase was due to continuous synthesis of enzymeprotein. In vivo examination of TMP synthetase suggests thatits activity does not necessarily increase before full developmentof DNA synthesis. It was concluded that among the enzymes examined,TMP kinase activity may increase shortly after slicing to supporta massive supply of thymidine triphosphate and the increasedactivity of DNA polymerase may contribute to the active synthesisof DNA in aged discs. (Received February 18, 1977; )     

Synthesis of nucleic acids and protein in tuber buds of Solanum tuberosum during dormancy and early sprouting

Autoradiographic studies have demonstrated the continuous synthesis of protein, RNA and DNA in potato ( Solanum tuberosum L. cv. King Edward) tuber buds from the time of tuber harvest throughout dormancy. Breaking of dormancy is associated with a rise in all activities. A first rise occurs just prior to (or coincident with) a general increase in cell volume. A second rise accompanies the elongation and outgrowth of the bud. The continuous metabolic activity during dormancy in the absence of cell growth is discussed.     

Enhancement of polyribosome formation and RNA synthesis of gibberellic Acid in wounded potato tuber tissue

As part of a more detailed study on plant tumorigenesis, the action of gibberellic acid (GA₃) in wounded potato tuber tissues as a model system has been evaluated. GA₃ stimulates total RNA synthesis in wounded tissues, the optimal concentration being 0.1 micromolar. The responsiveness of the tissue toward the hormone develops with time after wounding. Whereas freshly wounded tissue does not respond at all to the hormone, it becomes competent after about 6 hours, the competence being maximal after 1 day of wound healing.     

Wound healing in potato tuber tissue: phosphon inhibition of developmental processes requiring protein synthesis

Several aspects of wound healing in tuber tissue of potato (Solanum tuberosum var. Kennebec), known to require protein synthesis, are inhibited by 2,4-dichlorobenzyltributylphosphonium chloride (Phosphon D). Cell division was completely blocked by 60 mum Phosphon and markedly reduced by concentrations as low as 3 mum. When applied at the time of wounding, 0.25mm Phosphon completely prevented the wound-induced respiratory increase. Application at 15 hours after wounding arrested respiration at the rate present at that time. The same concentrations of Phosphon inhibited auxin-induced cell expansion of the tissue, protein synthesis as measured by the incorporation of leucine-(14)C into the trichloroacetic acid-insoluble fraction of tissue disks, and the appearance of wound-induced peroxidase isozymes. None of these inhibitory effects of Phosphon could be prevented or reversed by the application of gibberellic acid. All wound-induced processes inhibited by Phosphon are also inhibited by cycloheximide. It is suggested that inhibitory effects of Phosphon on wound healing in potato and on other developmental processes in excised plant tissues which cannot be reversed by gibberellin are due to interference with protein synthesis.     

Induction of deoxyribonucleic Acid synthesis in potato tuber slices: role of protein synthesis

Timing of protein synthesis which is a prerequisite to DNA synthesis induced in potato tuber tissue (Solanum tuberosum L.) by cut injury has been studied using cycloheximide. The induction of DNA synthesis which was measured by incorporation of ³H-thymidine was completely inhibited when the inhibitor was applied to the tuber discs immediately after slicing. When the application of cycloheximide was delayed for 6 hours or more after slicing, DNA synthesis was observed but its rate was reduced to 20% of control. The inhibitory effect of cycloheximide, however, rapidly decreased when the inhibitor was applied at 6 or less hours immediately prior to determination of DNA synthesis. The effect of cycloheximide on the incorporation of ¹⁴C-leucine suggests that the change in the effect of cycloheximide on the induction of DNA synthesis is not due to incomplete inhibition of protein synthesis. Cycloheximide did not have significant effects on either uptake or phosphorylation of ³H-thymidine in the discs. Inhibition of both protein and DNA synthesis by cycloheximide was reversed by washing and further incubation of the discs. Almost no qualitative difference was detected by buoyant density analysis between DNA formed under inhibition of protein synthesis of the later stage and DNA synthesized under normal conditions. These results suggest that DNA synthesis induced in potato tuber tissue by cut injury requires continuous synthesis of new protein molecules in a characteristically programmed sequence.     

Über den Einfluss hypotonischen Milieus auf den Stoffwechsel dereprimierter pflanzlicher Gewebe

During investigations of their metabolism fragments of plant tissue are most commonly incubated in watery solutions in order to replace the conditions within the intact organ approximately. — This paper reports experiments performed to investigate the influence of a hypotonic medium on several parameters of importance in cell metabolism (protein synthesis, enzymatic activity, concentrations of metabolic intermediates, respiration and cell division). — It could be shown that protein synthesis is severely inhibited in hypotonically exposed potato tuber discs. As a consequence the activities of two dehydrogenases of the pentose phosphate shunt (glucose-6-phosphate- and 6-phosphogluconate-dehydrogenase) are very low as compared with tissue in air. Since the activated pentose shunt evidently contributes to the respiratory reaction after derepression of the tissue, lowered activities of these dehydrogenases must consequently result in lower respiratory activity. This is actually realized in washed tissue. Likewise the mitotic activity is inhibited to a considerable extent. — The destruction of permeability barriers within the cell as a consequence of slicing causes leakage of a variety of metabolites such as glucose, glucose-6-phosphate, fructose-6-phosphate and pyruvate. Thus leaching of metabolic active substances is certainly one of the causal factors in the complex reaction of tissue slices exposed to a hypotonic medium, although such important parameters as changed gas conditions and the various effects of altered hydration of cell cytoplasm must be considered.     

Tuber on a chip: differential gene expression during potato tuber development

Potato tuber development has proven to be a valuable model system for studying underground sink organ formation. Research on this topic has led to the identification of many genes involved in this complex process and has aided in the unravelling of the mechanisms underlying starch synthesis. However, less attention has been paid to the biochemical pathways of other important metabolites or to the changing metabolic fluxes occurring during potato tuber development. In this paper, we describe the construction of a potato complementary DNA (cDNA) microarray specifically designed for genes involved in processes related to tuber development and tuber quality traits. We present expression profiles of 1315 cDNAs during tuber development where the predominant profiles were strong up- and down-regulation. Gene expression profiles showing transient increases or decreases were less abundantly represented and followed more moderate changes, mainly during tuber initiation. In addition to the confirmation of gene expression patterns during tuber development, many novel differentially expressed genes were identified and are considered as candidate genes for direct involvement in potato tuber development. A detailed analysis of starch metabolism genes provided a unique overview of expression changes during tuber development. Characteristic expression profiles were often clearly different between gene family members. A link between differential gene expression during tuber development and potato tissue specificity is described. This dataset provides a firm basis for the identification of key regulatory genes in a number of metabolic pathways that may provide researchers with new tools to achieve breeding goals for use in industrial applications.     

Changes in the location of polyphenol oxidase in potato (Solanum tuberosum L.) tuber during cell death in response to impact injury: comparison with wound tissue

In order to elucidate the nature of the response of potato to impact injury at the biochemical level, changes in the location of the enzyme responsible for the discoloration, polyphenol oxidase, were determined using immunogold location with an antibody specific for potato tuber polyphenol oxidase. Tissue printing revealed that the enzyme was distributed throughout the tuber. Following impact injury, both tissue printing and quantitative electron microscopy indicated that there was no increase in the level of the enzyme although there was subcellular redistribution of polyphenol oxidase. This redistribution was first apparent at 12 h after impact, as determined by the use of confocal immunolocation, and coincided with loss of membrane integrity. These changes were examined in parallel with a number of stress-related parameters in both impact and wound responses. Wounding was accompanied by active gene expression and protein synthesis, leading to metabolic activity and tissue repair. In contrast, the bruising response was characterised by a limited active response and vital-staining methods indicated that after 16 h the tissue undergoes cell death. Received: 4 June 1998 / Accepted: 18 September 1998     

Time course and spatial distribution of phenylalanine ammonia-lyase and peroxidase activity in wounded potato tuber tissue

The time course and spatial distribution of wound-induced activities of phenylalanine ammonia-lyase and peroxidase were determined to establish correlations between molecular and cellular aspects of the wound-induced pattern of cell differentiation in potato (Solanum tuberosum L.) tissue. A high correlation between peroxidase activity and suberization was observed. Peroxidase activity increased for several days after wounding. Peroxidase content of suberizing cells was more than 10 times higher than that of the immediately adjacent dividing cells. Suberizing and dividing cells contained different isoperoxidases. Neither time course nor spatial distribution of the wound-induced activity of phenylalanine ammonia-lyase was directly correlated with the wound-induced pattern of cell differentiation.     

Acclimatization and subsequent gas exchange, water relations, survival and growth of microcultured apple plantlets after transplanting them in soil

Wounded tuber tissue of potato ( Solanum tuberosum L. cv. Gloria) exposed to the monoterpene S-carvone did show neither suberization nor cambium layer formation, whereas these processes started after 2–4 days in control tissue. Suberized tissue was clearly visible 24 days after the start of the S-carvone treatment, when the concentrations of S-carvone and its bioconversion products in the tissue were almost zero and cambium layer formation had not yet started. The inhibition of wound healing coincided with a lack of induction of 3-hydroxy-3-methylglutaryl coenzyme A reductase (HMGR, EC 1.1.1.34). The wounded potato tissue used as control, showed a transient induction of HMGR activity.
In S-carvone treated tissue, the activities of GR (glutathione reductase, EC 1.6.4.2) and AP (ascorbate peroxidase, EC 1.11.1.11) were induced, and the level of glutathione increased four- to five-fold.     

Enhancement of DNA polymerase activity in potato tuber slices

DNA polymerase was extracted from potato (Solanum tuberosumL.) tuber discs and the temporal correlation of its activitychange to DNA synthesis in vivo was examined during aging ofthe discs. Most of the DNA polymerase was recovered as a boundform in the 18,000?g precipitate. Reaction with the bound-formenzyme was dependent on the presence of four deoxynucleosidetriphosphates, Mg²⁺, and a template. "Activated" DNA and heat-denaturedDNA, but not native DNA, were utilized as templates. The polymeraseactivity was sensitive to SH reagents. Fresh discs, which donot synthesize DNA in vivo, contained a significant amount ofDNA polymerase and its activity increased linearly with timeuntil 48 hr after slicing and became four times that of freshdiscs after 72 hr, whereas the activity of DNA synthesis invivo increased with time and decreased after reaching a maximumat 30 hr. Cycloheximide inhibited the enhancement of polymeraseactivity. DNA polymerase from aged and fresh discs had identicalrequirements for deoxynucleotides and a template in their reactions,sensitivity to SH reagent, and affinity to thymidine triphosphate. (Received February 18, 1977; )     

Enniatin Production by Fusarium Strains and Its Effect on Potato Tuber Tissue

Several Fusarium strains produce the cyclohexadepsipeptide enniatin, a host-nonspecific phytotoxin. Enniatins are synthesized by the 347-kDa multifunctional enzyme enniatin synthetase. In the present study, 36 Fusarium strains derived from a wide range of host plants were characterized with respect to enniatin production in different media. Thirteen of these strains produced enniatins on one or more of these media. To determine whether enniatin production affected virulence, an assay on potato tuber tissue was performed. Seven enniatin-producing and 16 nonproducing strains induced necrosis of potato tuber tissue, so that enniatin synthesis is not essential for the infection of potato tuber tissue. The application of a mixture of enniatins to slices of potato tuber, however, caused necrosis of the tissue. Therefore, enniatin production by the enniatin-synthesizing strains may affect their pathogenicity. The enniatin synthetase gene (esyn1) of Fusarium scirpi ETH 1536 was used as a probe to determine if similar sequences were present in the strains examined. In Southern blot analyses, DNA sequences hybridizing with the esyn1 probe were present in all but two of the strains examined. In some cases, enniatin-nonproducing strains had the same hybridization pattern as enniatin producers.     

The effect of injury and infection by Gibberella zeae on the polyacrylamide gel electrophoretic pattern of soluble proteins in potato tuber tissue

Polyacrylamide gel electrophoretic patterns of soluble proteinsfrom intact potato tubers and from wounded tuber tissue wereidentical. The patterns from diseased tissue showed some minordifferences not before 3–4 days after inoculation. Itis concluded that primarily proteins of minor fractions areinvolved in protein synthesis after wounding or infection. (Received March 22, 1969; )     

Effect of ethylene on DNA synthesis in potato tuber discs

The effect of ethylene on DNA synthesis in potato tuber discsinduced by cutting was examined. Continuous presence of ethylenein the ambient atmosphere of the slices lowered the rate ofinduced DNA synthesis by about 50%, but did not alter the timecourse pattern of development of DNA synthesis. RNA and proteinsyntheses were not affected. The inhibitory effect on DNA synthesiswas observed at as low as 0.01 µl/liter and was due tothe specific action of ethylene, not to a non-specific actionof gaseous hydrocarbons. Ethylene also decreased the numberof cells which could synthesize DNA. The results of ethylenetreatment of various durations at various times after cuttingindicate that a process prerequisite for DNA synthesis and susceptibleto ethylene action starts at about 6 hr after cutting and continuesfor only a limited period. (Received July 5, 1976; )     

Tissue reparation of the liver after thermo- and cryosurgical lesions: comparative cell analytical investigation

Histological and cell kinetic studies were performed on the liver of rats after local thermocoagulation. The dynamics of the wound healing were compared with those after in situ freezing (cryonecrosis) of the liver. The postoperative time ranged from 12 hr to 30 days. In the histological slides the morphological changes and the percentages of cells in the granulation tissue as well as in the autoradiograms were determined.The morphologic consequences of cryolesions in the liver are characterized by a shorter duration of the leukocytic reaction, stronger activities of macrophages, and a relatively prominent fibroblast-fibrocyte involvement. The dynamic process of the wound healing after cryonecrosis leads to a small fibrous scar 3–4 weeks postoperatively.After thermonecrosis, the leukocytic reaction is prolonged, the resorptive activity of the granulation tissue is lower but still visible 4 weeks after the injury, and the thermonecrotic carbonized material is not yet resorbed.Therefore, it can be stated that thermosurgically induced tissue lesions exhibit a delayed wound healing in comparison to other physical injuries, especially cryosurgical processes.     

Light-induced transformation of amyloplasts into chloroplasts in potato tubers

The transformation of amyloplast into chloroplasts in potato (Solanum tuberosum L.) tuber tissue can be induced by light. Excised potato tuber discs illuminated with white light of 3000 lux began to synthesize chlorophyll after a lag period of 1 day, and continued to synthesize chlorophyll for 3 weeks. In this paper we present evidence, based on ultracentrifugal sedimentation and immunoprecipitation, that the light-mediated synthesis of Ribulose-1,5-bisphosphate carboxylase began 1 day after illumination with white light. When illuminated the chloroplasts isolated from light-grown potato tuber tissue incorporated [³⁵S]methionine into polypeptides, one of which has been identified as the large subunit of Ribulose-1,5-bisphosphate carboxylase. These chloroplasts are functional as determined by O₂ evolution in the Hill reaction.     

Kinetics of Viral Deoxyribonucleic Acid, Protein, and Infectious Particle Production and Alterations in Host Macromolecular Syntheses in Equine Abortion (Herpes) Virus-infected Cells

Infection of exponential-phase suspension cultures of mouse fibroblast cells (L-M) with equine abortion virus (EAV) resulted in inhibition of cell growth and marked alterations in host metabolic processes. The synthesis of deoxyribonucleic acid (DNA) and ribonucleic acid was inhibited within 4 hr after infection and was suppressed by more than 90% by the time of maximal virus replication (14 to 18 hr). The overall rate of protein synthesis, however, was similar in uninfected and virus-producing cells as determined by measurements of net protein and isotope incorporation. The time course of viral DNA and protein synthesis and assembly into mature virus was determined with the inhibitors 5-fluorodeoxyuridine (FUdR) and cycloheximide, respectively. Thus, viral DNA synthesis was essentially completed at 14 hr, and viral protein and infectious virus synthesis was completed at 18 hr. Although the number of plaque-forming units (PFU) produced by FUdR-treated cells (10(3) to 10(4) PFU/ml) was at least 3 logs less than that produced by untreated cells, the yield of physical particles (as determined by electron microscopy) was approximately the same at 30 hr after infection. Besides being relatively non-infective, the particles produced in FUdR-treated cells appeared morphologically incomplete as they contained little or no nucleoid material.