Development of seed coat-imposed dormancy during seed maturation in Cynoglossum officinale

The relationship between seed phenolics and appearance of seed coat–imposed dormancy during seed development in Cynoglossum officinale L. was studied. Up to 24 days after anthesis, seeds failed to germinate upon imbibition in Petri dishes at 25°C. At 44 days after anthesis, seeds were fully germinable; removal of seed coats did not improve their germination or O₂ uptake. At 72 days after anthesis, mature seeds at the base of the cyme did not germinate unless their coats were removed. Removal of seed coat also stimulated O₂ uptake at this harvest date. The methanol-soluble phenolic content of the seeds increased during the early stages of seed development, in both the seed coat and the embryo. As seed development continued, the methanol-soluble phenolic content of the embryo stabilized, but that of the seed coat declined. This decline was associated with an increase in the thioglycolic acid–soluble phenolics, presumably lignins, in the seed coat. These results suggest that polymerization of methanol–soluble phenolics into lignins in the seed coat during later stages of seed development renders the seed coat of C. officinale impermeable to 03, and thus keeps the seed dormant.     

Permeability of seed coats to water as related to drying conditions and metabolism of phenolics

The seed coat of Pisum elatius is normally impermeable to water. When seeds are dried in the absence of oxygen their coats are totally permeable to water. Structural differences are observed between permeable and impermeable seed coats. In the genus Pisum, species with normally impermeable seed coats have a high content of phenolics and of catechol oxidase, while seed coats of P. sativum contain very little catechol oxidase and have a very low content of phenolics. Such differences are not noted in the cotyledons. We hypothesized that during dehydration of seeds, oxidation of phenolic compounds in seed coats through catalysis of catechol oxidase in presence of O₂ might render the seed coats impermeable to water.     

Seed development in the rare cold desert sand dune shrub Eremosparton songoricum and a comparison with other papilionoid legumes

No study has yet been carried out on seed development in a cold desert sand dune papilionoid legume. Thus, our primary aims were to (i) monitor seed development in the cold desert sand dune species Eremosparton songoricum from the time of pollination to seed maturity, and (ii) compare seed development in this species with that in other species of papilionoid legumes. Fruit and seed size, mass and seed moisture content, and seed imbibition, germination, desiccation tolerance and water retention during development (pollination to seed maturity) were monitored in the papilionaceous shrub E. songoricum in the Gurbantunggut Desert of northwest China. The duration of seed development was 40 days. Seeds reached physiological maturity 28 days after pollination (DAP), at which time 58% of them germinated and they had developed desiccation tolerance. Seeds became impermeable 36–40 DAP, when their moisture content was about 10%. The final stage of maturation drying occurred via loss of water through the hilum. The developmental stages and their timing (DAP) in seeds of E. songoricum are generally similar to those reported for other papilionaceous legumes with a water‐impermeable seed coat (physical dormancy). In general, the developmental features of seeds with water‐impermeable coats at maturity do not appear to be specific to habitat or phylogeny.     

Changes in Catechol Oxidase and Permeability to Water in Seed Coats of Pisum elatius during Seed Development and Maturation

In the developing seed coat of Pisum elatius, o-dihydroxyphenols are present in appreciable amounts at all stages of development. However, catechol oxidase activity rises sharply during the later stages of development, shows a further abrupt rise during dehydration of the seed coat, and then decreases. It is suggested that a tanning reaction is induced by the contact of enzyme with its substrate while cell membranes are ruptured, and that this reaction renders the seed coats impermeable. The entire chain of events does not occur in Pisum sativum which has permeable seed coats.     

Changes in phenolic acids and abscisic acid in sugar pine seed coats during stratification

The phenolic acids and abscisic acid (ABA) of sugar pine ( Pinus lambertiana Dougl.) seeds coats, separated by high-pressure liquid chromatography, were analyzed during 90 days stratification of the seeds. Although levels of seed coat phenolic acids and ABA declined significantly during, stratification, this decrease did not appear to be responsible for the loss of dormancy due to stratification. Lack of improved germination following washing, cracking, or removal of the seed coats, plus additional evidence, did not support a significant role for the seed coat in the dormancy of sugar pine seeds.     

Crypsis hypothesis as an explanation for evolution of impermeable coats in seeds is anecdotal

Impermeable seed/fruit coat, i.e. physical dormancy (PY) occurring in seeds of many genera of 19 angiosperm plant families has been traditionally viewed as a form of dormancy that regulates germination timing. However, this view was recently challenged by an alternative explanation claiming that the impermeable seed coat evolved as a coping mechanism to escape predators, i.e. crypsis hypothesis. Here, I wish to call for more careful attention on crypsis as an evolutionary factor because (1) information of volatile compounds is not known in PY families except Fabaceace; (2) impermeability is not induced until the moisture content of the seeds drops below species-specific threshold suggesting that drying determines development of impermeable seed coats; (3) the crypsis hypothesis does not explain the year-to-year or between site variations in proportions of impermeable seeds produced by plants; and (4) dry seeds of species from non-PY families also do not emit volatile compounds, and do not develop impermeable seed coats. For these reasons, it appears crypsis might be an exaptation, i.e., a trait that performs a function for which it was not originally evolved. Based on the available evidence, it is suggested that climate drying might have resulted in evolution of impermeable seed coats.     

Cracks in the palisade cuticle of soybean seed coats correlate with their permeability to water

BACKGROUND AND AIMS: Soybean (Glycine max) is among the many legumes that are well known for 'hardseededness'. This feature can be beneficial for long-term seed survival, but is undesirable for the food processing industry. There is substantial disagreement concerning the mechanisms and related structures that control the permeability properties of soybean seed coats. In this work, the structural component that controls water entry into the seed is identified. METHODS: Six soybean cultivars were tested for their seed coat permeabilities to water. To identify the structural feature(s) that may contribute to the determination of these permeabilities, fluorescent tracer dyes, and light and electron microscopic techniques were used. KEY RESULTS: The cultivar 'Tachanagaha' has the most permeable seed coat, 'OX 951' the least permeable seed coat, and the permeabilities of the rest ('Harovinton', 'Williams', 'Clark L 67-3469', and 'Harosoy 63') are intermediate. All seeds have surface deposits, depressions, a light line, and a cuticle about 0.2 microm thick overlaying the palisade layer. In permeable cultivars the cuticle tends to break, whereas in impermeable seeds of 'OX 951' it remains intact. In the case of permeable seed coats, the majority of the cracks are from 1 to 5 micro m wide and from 20 to 200 micro m long, and occur more frequently on the dorsal side than in other regions of the seed coat, a position that correlates with the site of initial water uptake. CONCLUSIONS: The cuticle of the palisade layer is the key factor that determines the permeability property of a soybean seed coat. The cuticle of a permeable seed coat is mechanically weak and develops small cracks through which water can pass. The cuticle of an impermeable seed coat is mechanically strong and does not crack under normal circumstances.     

Involvement of AtLAC15 in lignin synthesis in seeds and in root elongation of Arabidopsis

Laccase, EC 1.10.3.2 or p-diphenol:dioxygen oxidoreductase, has been proposed to be involved in lignin synthesis in plants based on its in vitro enzymatic activity and a close correlation with the lignification process in plants. Despite many years of research, genetic evidence for the role of laccase in lignin synthesis is still missing. By screening mutants available for the annotated laccase gene family in Arabidopsis, we identified two mutants for a single laccase gene, AtLAC15 (At5g48100) with a pale brown or yellow seed coat which resembled the transparent testa (tt) mutant phenotype. A chemical component analysis revealed that the mutant seeds had nearly a 30% decrease in extractable lignin content and a 59% increase in soluble proanthocyanidin or condensed tannin compared with wild-type seeds. In an in vitro enzyme assay, the developing mutant seeds showed a significant reduction in polymerization activity of coniferyl alcohol in the absence of H₂O₂. Among the dimers formed in the in vitro assay using developing wild-type seeds, 23% of the linkages were β-O-4 which resembles the major linkages formed in native lignin. The evidence strongly supports that AtLAC15 is involved in lignin synthesis in plants. To our knowledge, this is the first genetic evidence for the role of laccase in lignin synthesis. Changes in seed coat permeability, seed germination and root elongation were also observed in the mutant.Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at .     

A soybean cell wall protein is affected by seed color genotype.

The dominant I gene inhibits accumulation of anthocyanin pigments in epidermal cells of the soybean seed coat. We compared saline-soluble proteins extracted from developing seed coats and identified a 35-kilodalton protein that was abundant in Richland (genotype I/I, yellow) and much reduced in an isogenic mutant line T157 (genotype i/i, imperfect black seed coats). We purified the 35-kilodalton protein by a novel procedure using chromatography on insoluble polyvinylpolypyrrolidone. The 35-kilodalton protein was composed primarily of proline, hydroxyproline, valine, tyrosine, and lysine. Three criteria (N-terminal amino acid sequence, amino acid composition, and sequence of a cDNA) proved that the seed coat 35-kilodalton protein was PRP1, a member of a proline-rich gene family expressed in hypocotyls and other soybean tissues. The levels of soluble PRP1 polypeptides and PRP1 mRNA were reduced in young seed coats with the recessive i/i genotype. These data demonstrated an unexpected and novel correlation between an anthocyanin gene and the quantitative levels of a specific, developmentally regulated cell wall protein. In contrast, PRP2, a closely related cell wall protein, was synthesized later in seed coat development and was not affected by the genotype of the I locus.     

Immobilisation of soybean seed coat peroxidase on its natural support for phenol removal from wastewater

Soybean seed coat peroxidase (SBP; EC 1.11.1.7) was immobilised on its natural support, soybean seed coats, anticipating its use in phenol removal. Periodate and glutaraldehyde chemistries were assayed. Periodate failed to immobilise any SBP, whereas glutaraldehyde was effective. The optimum concentration of glutaraldehyde was found to be 1%. Immobilisation shifted the optimum pH for phenol removal from 4.0 to 6.0. Treated seed coat retained its activity over a 4-week period, and reusability assays showed that treated seed coats could be reused once for phenol removal. Polyethylene glycol (PEG) increased the stability of phenol degradation activity. In addition, the phenolic polymer was adsorbed on to seed coats, thus making removal of the polymeric product easier.     

Immobilisation of soybean seed coat peroxidase on its natural support for phenol removal from wastewater

Soybean seed coat peroxidase (SBP; EC 1.11.1.7) was immobilised on its natural support, soybean seed coats, anticipating its use in phenol removal. Periodate and glutaraldehyde chemistries were assayed. Periodate failed to immobilise any SBP, whereas glutaraldehyde was effective. The optimum concentration of glutaraldehyde was found to be 1%. Immobilisation shifted the optimum pH for phenol removal from 4.0 to 6.0. Treated seed coat retained its activity over a 4-week period, and reusability assays showed that treated seed coats could be reused once for phenol removal. Polyethylene glycol (PEG) increased the stability of phenol degradation activity. In addition, the phenolic polymer was adsorbed on to seed coats, thus making removal of the polymeric product easier.     

Chalcone synthase mRNA and activity are reduced in yellow soybean seed coats with dominant I alleles.

The seed of all wild Glycine accessions have black or brown pigments because of the homozygous recessive i allele in combination with alleles at the R and T loci. In contrast, nearly all commercial soybean (Glycine max) varieties are yellow due to the presence of a dominant allele of the I locus (either I or i) that inhibits pigmentation in the seed coats. Spontaneous mutations to the recessive i allele occur in these varieties and result in pigmented seed coats. We have isolated a clone for a soybean dihydroflavonol reductase (DFR) gene using polymerase chain reaction. We examined expression of DFR and two other genes of the flavonoid pathway during soybean seed coat development in a series of near-isogenic isolines that vary in pigmentation as specified by combinations of alleles of the I, R, and T loci. The expression of phenylalanine ammonia-lyase and DFR mRNAs was similar in all of the gene combinations at each stage of seed coat development. In contrast, chalcone synthase (CHS) mRNA was barely detectable at all stages of development in seed coats that carry the dominant I allele that results in yellow seed coats. CHS activity in yellow seed coats (I) was also 7- to 10-fold less than in the pigmented seed coats that have the homozygous recessive i allele. It appears that the dominant I allele results in reduction of CHS mRNA, leading to reduction of CHS activity as the basis for inhibition of anthocyanin and proanthocyanin synthesis in soybean seed coats. A further connection between CHS and the I locus is indicated by the occurrence of multiple restriction site polymorphisms in genomic DNA blots of the CHS gene family in near-isogenic lines containing alleles of the I locus.     

Histochemical and biochemical approaches to the study of phenolic compounds and peroxidases in needles of Norway spruce (Picea abies)

The three youngest age-classes of needles of Norway spruce ( Picea abies ) were collected from four sites in the Krusne Hory Mountains (Czech Republic) characterized by different levels of damage caused by environmental pollution. Histochemical methods did not reveal any differences in localization of phenolics among the needles. Mesophyll cells close to the epidermis of needles and cells around resin ducts and substomatal cavities often accumulated higher amounts of phenolics than the rest of the mesophyll cells, but this was independent of age and damage. Needles of different age- and damage-class did not show any marked changes in general lignification pattern. However, a lower intensity of histochemical detection of lignin was observed in needles from the most damaged site. This finding was confirmed by chemical analysis using thioglycolic acid. Generally, the amount of lignin in mesophyll cells was lower in damaged trees than in healthy ones. Using the Folin–Ciocalteau method, no significant differences in the total content of phenolics were observed in the needles, although HPLC revealed marked alterations in the forms of seven phenolic acids. Concentrations of conjugated forms of phenolic acids (esters and glycosides) were higher in damaged needles (255.9 μg g⁻¹ f. wt) than in healthy needles (189.8 μg g⁻¹ f. wt). By contrast, content of esterified phenolic acids incorporated into cell walls was higher in needles from healthy trees (101.1 μg g⁻¹ f. wt) than in damaged needles (78.3 μg g⁻¹ f. wt). Marked differences were also observed in the activity of soluble peroxidases, although the activity of ionically bound forms was approximately the same in healthy and damaged needles. The total amounts of chlorophylls and carotenoids decreased as environmental damage increased.     

Soybean Seed Coat Peroxidase (A Comparison of High-Activity and Low-Activity Genotypes)

Peroxidase activity in the seed coats of soybean (Glycine max [L.] Merr.) is controlled by the Ep locus. We compared peroxidase activity in cell-free extracts from seed coat, root, and leaf tissues of three EpEp cultivars (Harosoy 63, Harovinton, and Coles) to three epep cultivars (Steele, Marathon, and Raiden). Extracts from the seed coats of EpEp cultivars were 100-fold higher in specific activity than those from epep cultivars, but there was no difference in specific activity in crude root or leaf extracts. Isoelectric focusing of root tissue extracts and staining for peroxidase activity showed that EpEp cultivars had a root peroxidase of identical isoelectric point to the seed coat peroxidase, whereas roots of the epep types were lacking that peroxidase, indicating that the Ep locus may also affect expression in the root. In seed coat extracts, peroxidase was the most abundant soluble protein in EpEp cultivars, whereas this enzyme was present only in trace amounts in epep genotypes, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Histochemical localization of peroxidase activity in seed coats of EpEp cultivars shows that the enzyme occurs predominately in the cytoplasm of hourglass cells of the subepidermis. No obvious difference in the gross or microscopic structure of the seed coat was observed to be associated with the Ep locus. These results suggest that soybean seed coat peroxidase may be involved in processes other than seed coat biosynthesis.     

Patterns and kinetics of water uptake by soybean seeds

Soybean [Glycine max (L.) Merr.] plants produce some seeds (called stone or impermeable seeds) that do not take up water for long periods of time. The present investigation confirmed that the stone seed trait is a feature of the seed coat: isolated embryos from both stone and permeable seeds took up water equally quickly. A whole, permeable seed typically imbibed water initially through its dorsal side, forming wrinkles in the seed coat and delivering water to the underlying cotyledons. Later, some lateral movement of water through the coat occurred, presumably through the air spaces of the osteosclereid layer. Imbibition by seeds was a two-phase process, the first dominated by hydration of the seed coat and the second by hydration of the cotyledons, which was rate-limited by the coat. When hydrated, coats of stone seeds were permeable to water but their hydraulic conductivity, as measured with a pressure probe, was smaller than that of coats from permeable seeds by a factor of five. Hydrated coats of both permeable and stone seeds showed weak osmometer properties.     

Apoplastic Peroxidases and Lignification in Needles of Norway Spruce (Picea abies L.)

The objective of the present study was to investigate the correlation of soluble apoplastic peroxidase activity with lignification in needles of field-grown Norway spruce (Picea abies L.) trees. Apoplastic peroxidases (EC 1.11.1.7) were obtained by vacuum infiltration of needles. The lignin content of isolated cell walls was determined by the acetyl bromide method. Accumulation of lignin and seasonal variations of apoplastic peroxidase activities were studied in the first year of needle development. The major phase of lignification started after bud break and was terminated about 4 weeks later. This phase correlated with a transient increase in apoplastic guaiacol and coniferyl alcohol peroxidase activity. NADH oxidase activity, which is thought to sustain peroxidase activity by production of H2O2, peaked sharply after bud break and decreased during the lignification period. Histochemical localization of peroxidase with guaiacol indicated that high activities were present in lignifying cell walls. In mature needles, lignin was localized in walls of most needle tissues including mesophyll cells, and corresponded to 80 to 130 [mu]mol lignin monomers/g needle dry weight. Isoelectric focusing of apoplastic washing fluids and activity staining with guaiacol showed the presence of strongly alkaline peroxidases (isoelectric point [greater than or equal to] 9) in all developmental stages investigated. New isozymes with isoelectric points of 7.1 and 8.1 appeared during the major phase of lignification. These isozymes disappeared after lignification was terminated. A strong increase in peroxidase activity in autumn was associated with the appearance of acidic peroxidases (isoelectric point [less than or equal to] 3). These results suggest that soluble alkaline apoplastic peroxidases participate in lignin formation. Soluble acidic apoplastic peroxidases were apparently unrelated to developmentally regulated lignification in spruce needles.