Involvement of cytokinins in the germination of chick-pea seeds

Eight cytokinins detected in germinated chick-pea (Cicer arietinum L. var. Castellana) seeds were first present in the embryonic axes but appeared in the cotyledons after 12h of germination. The cytokinins detected in the cotyledons originate in the embryonic axes, but no passage of these substances from the cotyledons to the axes was detected, except when the seeds were treated with red light.It is concluded that the role played by the embryonic axis in mobilizating the main reserves of the cotyledons is mainly effected through these cytokinins. Both natural and synthetic cytokinins exert an important regulatory role in the hydrolysis of reserve proteins and calcium could be involved as an intermediate.Abbreviations BA benzyladenine - cot. cotyledon - (diH)Z dihydrozeatin - (diH)ZR dihydrozeatin riboside - GZR glycosyl zeatin riboside - 2iP 277-1 - iPA 277-2 riboside - Kin kinetin - Z zeatin - ZG zeatin glucoside - ZR zeatin riboside     

Cotyledon cells of Vigna mungo seedlings use at least two distinct autophagic machineries for degradation of starch granules and cellular components

alpha-Amylase is expressed in cotyledons of germinated Vigna mungo seeds and is responsible for the degradation of starch that is stored in the starch granule (SG). Immunocytochemical analysis of the cotyledon cells with anti-alpha-amylase antibody showed that alpha-amylase is transported to protein storage vacuole (PSV) and lytic vacuole (LV), which is converted from PSV by hydrolysis of storage proteins. To observe the insertion/degradation processes of SG into/in the inside of vacuoles, ultrastructural analyses of the cotyledon cells were conducted. The results revealed that SG is inserted into LV through autophagic function of LV and subsequently degraded by vacuolar alpha-amylase. The autophagy for SG was structurally similar to micropexophagy detected in yeast cells. In addition to the autophagic process for SG, autophagosome-mediated autophagy for cytoplasm and mitochondria was detected in the cotyledon cells. When the embryo axes were removed from seeds and the detached cotyledons were incubated, the autophagosome-mediated autophagy was observed, but the autophagic process for the degradation of SG was not detected, suggesting that these two autophagic processes were mediated by different cellular mechanisms. The two distinct autophagic processes were thought to be involved in the breakdown of SG and cell components in the cells of germinated cotyledon.     

Influence of the Embryonic Axis on Protein Hydrolysis in Cotyledons of Cucurbita maxima

Four-day time course studies of the hydrolysis of cotyledonal storage protein were conducted on intact seeds, seed cotyledons detached from their embryonic axes and on detached cotyledon pairs germinated in the presence of three excised embryonic axes of Cucurbita maxima Duch., cv. Chicago Worted Hubbard. Detached cotyledons germinated alone showed little hydrolysis of the storage protein. However, the amount of protein hydrolysis of the detached cotyledon pairs germinated in the presence of three excised embryonic axes was comparable to the amount hydrolyzed in the cotyledons of intact germinating seeds. Visual growth differences among these treatments were also evident. The size and yellow color intensity of the fourth day treatments were shown to increase in the following order: detached cotyledon pairs alone, intact seedlings, detached cotyledon pairs in the presence of three excised axes. The growth of the hypocotyl and radical was also modified by removal of the cotyledons. These findings suggest that storage protein degradation and cotyledonal growth are controled by the axis. They also indicate that the cotyledons have some influence on the growth of the axes. Time-course studies were made on the hydrolysis of storage protein in the cotyledons of squash and on the distribution of the hydrolytic products during the germination of light- and dark-grown plants. The storage protein was not hydrolyzed during the first 24 hours. It was hydrolyzed at a uniform rate from 1 to 5 days and at a slightly decreased rate from 5 to 7 days. Most of the hydrolytic products were transported to the axial tissue. Proteinase activity in the cotyledons rapidly increased during germination to a maximum level at 2 to 3 days. This was followed by a decline to about the initial value after 7 days.     

Gibberellin-responsive elements in the promoter of a barley high-pI alpha-amylase gene.

Deletion analysis has previously shown that the major gibberellic acid (GA)- and abscisic acid (ABA)-responsive elements in the promoter of a high-pI alpha-amylase gene of barley are located downstream of -174 (Jacobsen and Close, 1991). We have used transient expression assays in barley aleurone protoplasts to identify sequences between -174 and +53 that confer GA and ABA responsiveness on expression of a beta-glucuronidase reporter gene. Using alpha-amylase promoter fragments and synthetic oligonucleotides fused to minimal promoters, we have shown that the hormone-responsive region is located between -174 and -108. A single copy of this region fused to a minimal alpha-amylase promoter (-41) conferred both GA- and ABA-responsive expression on the reporter gene comparable to the positive control, Am(-174)IGN. Multiple copies of this region were able to activate even greater levels of expression. Site-directed mutagenesis was used to determine the functional importance of the conserved motifs (-169pyrimidine box, -143TAACAAA box, and -124TATCCAC box) and nonconserved intervening sequences within the region between -174 and -108. Our results showed that both the TAACAAA and TATCCAC boxes play an important role in GA-regulated expression. We propose that the TAACAAA box is a gibberellin response element, that the TATCCAC box acts cooperatively with the TAACAAA box to give a high level of GA-regulated expression, and that together these motifs form important components of a gibberellin response complex in high-pI alpha-amylase genes. The TAACAAA box also appears to be the site of action of ABA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Promoter elements required for developmental expression of the maize Adh1 gene in transgenic rice.

To define the regions of the maize alcohol dehydrogenase 1 (Adh1) promoter that confer tissue-specific expression, a series of 5' promoter deletions and substitution mutations were linked to the Escherichia coli beta-glucuronidase A (uidA) reporter gene and introduced into rice plants. A region between -140 and -99 not only conferred anaerobically inducible expression in the roots of transgenic plants but was also required for expression in the root cap, embryo, and in endosperm under aerobic conditions. GC-rich (GC-1, GC-2, and GC-3) or GT-rich (GT-1 and GT-2) sequence motifs in this region were necessary for expression in these tissues, as they were in anaerobic expression. Expression in the root cap under aerobic conditions required all the GC- and GT-rich motifs. The GT-1, GC-1, GC-2, and GC-3 motifs, and to a lesser extent the GT-2 motif, were also required for anaerobic responsiveness in rice roots. All elements except the GC-3 motif were needed for endosperm-specific expression. The GC-2 motif and perhaps the GT-1 motif appeared to be the only elements required for high-level expression in the embryos of rice seeds. Promoter regions important for shoot-, embryo-, and pollen-specific expression were proximal to -99, and nucleotides required for shoot-specific expression occurred between positions -72 and -43. Pollen-specific expression required a sequence element outside the promoter region, between +54 and +106 of the untranslated leader, as well as a silencer element in the promoter between -72 and -43.     

Isolation and functional characterization of two novel seed-specific promoters from sunflower (Helianthus annuus L.)

The promoter region of two sunflower (Helianthus annuus L. HA89 genotype) seed specifically expressed genes, coding for an oleate desaturase (HaFAD2-1) and a lipid transfer protein (HaAP10), were cloned and in silico characterized. The isolated fragments are 867 and 964 bp long, respectively, and contain several seed-specific motifs, such as AACA motif, ACGT element, E-Boxes, SEF binding sites and GCN4 motif. Functional analysis of these promoters in transgenic Arabidopsis plants was investigated after fusing them with the β-glucuronidase (GUS) reporter gene. None of the promoters triggered GUS activity in any vegetative tissue, with the exception of early seedling cotyledons. HaFAD2-1 and HaAP10 promoters were tested along seed development from globular stage to mature seeds. GUS staining was restricted to embryonic tissue and quantitative fluorometric assays showed high activity values at the later stages of development. In this work we demonstrate that HaFAD2-1 promoter is as strong as 35S promoter even though it is a tissue-specific promoter and its activity derived just from the embryo, thus confirming that it can be considered a strong highly specific seed promoter useful for biotechnology applications.     

Spatially regulated genes expressed during seed germination and postgerminative development are activated during embryogeny

Summary We investigated the control of genes expressed primarily during seed germination and postgerminative development in Brassica napus L. We identified cloned mRNA sequences which became prevalent within 1 day after the start of imbibition and were at low or undetectable levels in immature embryos, dry seeds, and leaves. Most postgermination-abundant mRNAs accumulated primarily, though not exclusively, in different parts of the seedling. Of the 14 cloned mRNAs, 8 were prevalent in cotyledons, 2 were abundant in seedling axes, and 4 were approximately equally distributed in both parts. We showed that although these mRNAs reached maximal levels in seedlings, the spatially regulated mRNAs were also detected at distinct embryonic stages; mRNAs prevalent in seedling axes accumulated primarily during early embryogenesis while cotyledon-abundant mRNA concentration increased during late embryogeny. We conclude that the temporal and spatial regulation of gene expression in seedlings reflects similarities and differences in the physiological functions of cotyledons and axes. Furthermore, the regulated expression of cotyledon-abundant genes during late embryogeny suggests that the mRNAs and possibly proteins may accumulate in preparation for subsequent seedling growth. Similarities in the accumulation of cotyledon-abundant mRNAs may indicate coordinate regulation of this gene set.Abbreviations DAF days after flowering - DAI days after the start of imbibition - HAI hours after the start of imbibition - kb kilobase(pairs)     

Stored mRNA in cotyledons of Vigna unguiculata seeds: nucleotide sequence of cloned cDNA for a stored mRNA and induction of its synthesis by precocious germination

By differential hybridization screening, we previously selected a class of cDNA clones from a gt10 cDNA library that was constructed from the total poly(A)⁺ RNA of mature cowpea cotyledons (Plant Cell Physiol 31: 39–44, 1990). pSAS10, a clone of this class, hybridized with a cDNA probe complementary to poly(A)⁺ RNA from cotyledons collected 1 day after the onset of imbibition (DAI), but not with the cDNA probe from cotyledons at development stage II (13 to 15 days after flowering, DAF). pSAS10 mRNA was detectable only in cotyledons at development stage III (17 to 19 DAF) or later, and its level began to decline when seeds germinated. We have suggested that pSAS10 mRNA is likely to belong to the class of stored mRNA or the mRNA that is formed at the late stage of seed maturation, is conserved in quiescent seeds and becomes functional at the early stage of germination. We determined the nucleotide sequence of pSAS10 cDNA consisting of 459 bp and an approximately 36 bp poly(A) tract, and deduced the amino acid sequence of its product, a 10-kDa cysteine-rich polypeptide. Synthesis of pSAS10 mRNA was induced just before germination began, not only in mature seeds but also in immature seeds even at stages I (9 to 11 DAF) and II (13 to 15 DAF) if they were placed under conditions suitable for germination.     

Changes in soluble carbohydrates and related enzymes induced by low temperature during early developmental stages of quinoa (Chenopodium quinoa) seedlings

Low temperature represents one of the principal limitations in species distribution and crop productivity. Responses to chilling include the accumulation of simple carbohydrates and changes in enzymes involved in their metabolism. Soluble carbohydrate levels and invertase, sucrose synthase (SS), sucrose-6-phosphate synthase (SPS) and alpha-amylase activities were analysed in cotyledons and embryonic axes of quinoa seedlings grown at 5 degrees C and 25 degrees C in the dark. Significant differences in enzyme activities and carbohydrate levels were observed. Sucrose content in cotyledons was found to be similar in both treatments, while in embryonic axes there were differences. Invertase activity was the most sensitive to temperature in both organs; however, SS and SPS activities appear to be less stress-sensitive. Results suggest that 1) metabolism in germinating perispermic seeds would be different from endospermic seeds, 2) sucrose futile cycles would be operating in cotyledons, but not in embryonic axes of quinoa seedlings under our experimental conditions, 3) low temperature might induce different regulatory mechanisms on invertase, SS and SPS enzymes in both cotyledons and embryonic axes of quinoa seedlings, and 4) low temperature rather than water uptake would be mainly responsible for the changes observed in carbohydrate and related enzyme activities.     

Molecular cloning and characterization of Vigna mungo processing enzyme 1 (VmPE-1), an asparaginyl endopeptidase possibly involved in post-translational processing of a vacuolar cysteine endopeptidase (SH-EP)

Asparaginyl endopeptidase is a cysteine endopeptidase that has strict substrate specificity toward the carboxy side of asparagine residues. Vigna mungo processing enzyme 1, termed VmPE-1, occurs in the cotyledons of germinated seeds of V. mungo, and is possibly involved in the post-translational processing of a vacuolar cysteine endopeptidase, designated SH-EP, which degrades seed storage protein. VmPE-1 also showed a substrate specificity to asparagine residues, and its enzymatic activity was inhibited by NEM but not E-64. In addition, purified VmPE-1 had a potential to process the recombinant SH-EP precursor to its intermediate in vitro. cDNA clones for VmPE-1 and its homologue, named VmPE-1A, were identified and sequenced, and their expressions in the cotyledons of V. mungo seedlings and other organs were investigated. VmPE-1 mRNA and SH-EP mRNA were expressed in germinated seeds at the same stage of germination although the enzymatic activity of VmPE-1 rose prior to that of SH-EP. The level of VmPE-1A mRNA continued increasing as germination proceeded. In roots, stems and leaves of fully grown plants, and in hypocotyls, VmPE-1 and VmPE-1A were little expressed. We discuss possible functions of VmPE-1 and VmPE-1A in the cotyledons of germinated seeds.     

Investigation of the endosperm-specific sucrose synthase promoter from rice using transient expression of reporter genes in guar seed tissue

We report the investigation of an endosperm-specific promoter from the rsus3 gene from rice (Oryza sativa). The promoter was characterized by deletion analysis and transient expression in guar (Cyamopsis tetragonoloba) seed-tissue. Transient expression was monitored by histochemical GUS assay, and quantitative dual reporter assays comprising firefly luciferase as a test reporter, and Renilla luciferase and GUS as reference reporters. These revealed high expression levels of the reporter genes directed by the rsus3 promoter in guar endosperm. Specificity for this tissue in seeds was apparent from a virtual absence of reporter activity in guar cotyledons. Removal of a putative intron region only slightly raised the expression level, whereas duplication of the minimal promoter region, in a tandem-repeat rsus3 promoter construct, retained endosperm specificity in guar, and displayed three times the reporter activity observed with the single copy construct.     

The families of papain- and legumain-like cysteine proteinases from embryonic axes and cotyledons of Vicia seeds: developmental patterns,intracellular localization and functions in globulin proteolysis

Families of papain- and legumain-like cysteine proteinases (CPR) were found in Vicia seeds. cDNAs and antibodies were used to follow organ specificity and the developmental course of CPR-specific mRNAs and polypeptides. Four papain-like cysteine proteinases (CPR1, CPR2, proteinase A and CPR4) from vetch seeds (Vicia sativa L.) were analysed. CPR2 and its mRNA were already found in dry embryonic axes. CPR1 was only detected there during early germination. Both CPR1 and CPR2 strongly increased later during germination. In cotyledons, both CPR1 and CPR2 were only observed one to two days later than in the axis. Proteinase A was not found in axes. In cotyledons it could only be detected several days after seeds had germinated. CPR4 mRNA and polypeptide were already present in embryonic axes and cotyledons during seed maturation and decreased in both organs during germination. Purified CPR1, CPR2 and proteinase A exhibited partially different patterns of globulin degradation products in vitro. Although the cDNA-deduced amino acid sequence of the precursor of proteinase A has an N-terminal signal peptide, the enzyme was not found in vacuoles whereas the other papain-like CPRs showed vacuolar localization. Four different legumain-like cysteine proteinases (VsPB2, proteinase B, VnPB1 and VnPB2) of Vicia species were analysed. Proteinase B and VnPB1 mRNAs were detected in cotyledons and seedling organs after seeds had germinated. Proteinase B degraded globulins isolated from mature vetch seeds in vitro. VsPB2 and proteinase B are localized to protein bodies of maturing seeds and seedlings, respectively, of V. sativa. Like VsPB2 from V. sativa, also VnPB2 of V. narbonensis corresponds to vacuolar processing enzymes (VPE). Based on these results different functions in molecular maturation and mobilization of storage proteins could be attributed to the various members of the CPR families.