George J. Wullems

Characterization of a pollen-specific cDNA clone from Nicotiana tabacum expressed during microgametogenesis and germination

This report describes the isolation and characterization of a cDNA clone representing a gene specifically expressed in pollen. A cDNA library was constructed against mRNA from mature pollen of Nicotiana tabacum. It was screened differentially against cDNA from mRNA of leaf and of pollen. One clone, NTPc303, was further characterized. On northern blot this clone hybridizes to a transcript 2100 nucleotides in length. NTPc303 is abundant in pollen. Expression of the corresponding gene is restricted to pollen, because no other generative or vegetative tissue contains transcripts hybridizing to NTPc303. Expression of NTP303 is evolutionarily conserved: homologous transcripts are present in pollen from various plant species. The first NTP303 transcripts are detectable on northern blot at the early bi-nucleate stage and accumulate until the pollen has reached maturity. During germination and pollen tube growth in vitro new NTP303 transcripts appear. This transcription has been proved by northern blots as well as by pulse labelling experiments. Nucleotide sequence analysis revealed that NTPc303 has an open reading frame coding for a predicted protein of 62 kDa. This protein shares homology to ascorbate oxidase and other members of the blue copper oxidase family. A possible function for this clone during pollen germination is discussed.

Stage related expression of mRNAs during pollen development in lily and tobacco.

Homogeneous populations of developing microspores and pollen from anthers of lily (Lilium longiflorum Thumb.) and tobacco (Nicotiana tabacum L.) show a continuous production of biomass, reaching a maximum in young pollen. The rate of RNA synthesis was 460 fg · h−1 in young binucleate cells, 138 fg · h−1 in late binucleate cells and 56 fg · h−1 in microspores. The mRNA population in developing pollen can be separated into three groups. In the first group, certain types of mRNAs are present at a constant level during all stages of development. A second group is characteristic of young pollen and increases quantitatively until anthesis. A third group is seen transiently; to this belong mRNAs present only before mitosis or at a distinct cell stage after mitosis. Some of the translation products of this latter group of mRNAs showed similarities between lily and tobacco on two-dimensional gels in respect of molecular weight and isolectric point, indicating that those mRNAs and proteins play a role in the regulation of pollen development.

The 5′-Untranslated Region of the ntp303 Gene Strongly Enhances Translation during Pollen Tube Growth, But Not during Pollen Maturation

Transcripts of the ntp303 gene accumulate abundantly throughout pollen development, whereas the protein only accumulates to detectable levels after pollen germination. In an attempt to explain the divergence in the accumulation profiles of the mRNA and the protein, we investigated the role of the untranslated regions (UTRs) in enhancing ntp303 translation during the transition from developing to germinating pollen. Luciferase reporter gene fusion constructs containing the ntp3035′-UTR gave rise to luciferase activity that was up to 60-fold higher during pollen tube growth than that of constructs containing different 5′-UTRs. No apparent differences in the luciferase activity of these constructs were observed during pollen development. Thentp303 5′-UTR-mediated increase in luciferase activity was not significantly influenced by coding region or 3′-UTR sequences. Furthermore, enhanced luciferase activity directed by thentp303 5′-UTR occurred predominantly at the post-transcriptional level. A series of 5′-UTR deletion constructs was created to identify putative regulatory sequences required for the high level of translation during pollen tube growth. Two predicted stem loop structures (H-I and H-II) caused a complete inhibition of the enhanced translation after their total or partial deletion. A (GAA)8repeat within the H-I stem loop structure was demonstrated to be important for the modulation of translation efficiency. The H-II stem loop structure was found to be essential for the determination of mRNA stability.

Thiophene accumulation in relation to morphology in roots of Tagetes patula : Effects of auxin and transformation by Agrobacterium.

Roots of marigold (Tagetes patula L.) accumulate thiophenes, heterocyclic sulfurous compounds with strong biocidal activity. In detached roots cultured in vitro, the thiophene content was 5 μmol·(g fresh weight)-1 which is 25-times higher than in roots attached to the plant. In roots derived from tissues transformed by Agrobacterium tumefaciens and A. rhizogenes, the morphology and thiophene content varied with the bacterial strain used. Transformation stimulated the elongation of the root tips and the formation of lateral roots but lowered the thiophene level to 20–50% relative to the concentration in untransformed detached roots. A negative correlation was found between the number of laterals in a root system and the thiophene content. Extensive branching and a decrease in thiophene accumulation was evoked in untransformed roots by indole-3-acetic acid (1–10 μmol·l-1) added to the medium. Within the roots, the highest thiophene concentrations were found in the tips. The results indicate that auxin directly or indirectly plays a role in the regulation of the thiophene level in root tips.

Analysis of microspore-specific promoters in transgenic tobacco

In order to modify the early stages of pollen development in a transgenic context microspore-specific promoters are required. We tested two putatively microspore-specific promoters, the Bp4 promoter from rapeseed and the NTM19 promoter from tobacco. Expression of the gus and barnase reporter genes under the control of these two promoters was studied in transgenic tobacco. Contrary to expectations, the Bp4 promoter became active only after the first pollen mitosis, and not in the microspores. The NTM19 promoter turned out to be highly microspore-specific and directed very high levels of gus expression to the unicellular microspores. The NTM19-barnase transgene caused cell-autonomous death at the mid-unicellular microspore stage, whereas Bp4-barnase induced cell ablation of early to mid-bicellular pollen. Both promoter-barnase transgenes did not affect the sporophyte and were inherited through the female germline. These results show that both the NTM19 and Bp4 promoters are expressed only in the male germline, and that the NTM19 promoter is an excellent tool to direct high levels of transgene expression exclusively to the microspores. This may have important biotechnological applications.

Metabolism of 1-naphthaleneacetic acid in explants of tobacco: Evidence for release of free hormone from conjugates

Abstract1-Naphthaleneacetic acid (1-NAA), required for in vitro flower bud formation, was taken up by pedicel explants of tobacco (Nicotiana tabacum L.) in large amounts and rapidly metabolized into various conjugates. These conjugates have been tentatively identified in four thin-layer Chromatographic systems using authentic standards as references. The major metabolite formed during the first hours of culture comigrated with 1-NAA-glucoside (1-NAGlu). From the 6th hour on, most 1-NAA had been converted into a yet unidentified metabolite. 1-NAglu was an intermediate in the formation of this metabolite. After 24 h, 1-NAA-aspartate (1-NAAsp) became the second major metabolite. The increase in 1-NAAsp formation was induced by 1-NAA. The inactive analog 2-naphthaleneacetic acid (2-NAA) was metabolized similar to 1-NAA, but was unable to increase the formation of the aspartate conjugate. When explants were fed labeled 1-NAGlu, 1-NAAsp or the major unidentified metabolite, radioactivity became associated with free 1-NAA and all major conjugates, indicating interconversion of conjugates and breakdown to free 1-NAA. A regulatory role of conjugation in maintaining a particular level of free 1-NAA in the tissue is proposed herein.

Isolation and characterization of a microspore-specific gene from tobacco

The characterization of a gene with a unique microspore-specific expression pattern is reported. Isolated microspores from tobacco were used to synthesize a cDNA library. Clones that did not hybridize to leaf cDNA were further characterized by northern analysis. One clone proved to be a microspore-specific cDNA, representing a transcript of 650 nt. The corresponding gene, NTM19 (Nicotiana tabacum microspore-specific), was isolated and its sequence analysed. The gene encodes a protein of 10.8 kDa with a pI of 6.92 and a putative signal sequence at the N-terminus. A localization study revealed a unique spatial and temporal distribution. The transcript was only detected in the unicellular microspore. No hybridization signals were observed in other pollen developmental stages, nor in the surrounding anther tissues or other vegetative tissues of the plant. Therefore it can be concluded that NTM19 is a gene with a highly microspore-specific character according to both localization and stage of expression. Southern blot analysis demonstrated the presence of a small gene family. The occurrence of TNM19 was investigated in a range of closely and distantly related species and was found to be present in other solanaceous species, including the ancestors of tobacco and in a monocot species.

The pollen-specific gene Ntp303 encodes a 69-kDa glycoprotein associated with the vegetative membranes and the cell wall

Abstract The pollen-specific gene Ntp303 belongs to the class of late pollen specific genes. It is first transcribed directly after pollen mitosis. Biochemical properties, appearance and precise location of the NTP303 protein during pollen development and pollen tube growth were studied by amino-acid micro-sequencing, protein gel blotting and immuno-localization. Antisera were raised against recombinant proteins, encoded by sequences of the pollen-specific Ntp303 gene. The antibodies specifically recognized a 69-kDa glycoprotein. Electron-microscopic immuno-localization of the protein revealed the presence of high concentrations of the NTP303 protein at the vegetative plasma membranes that surround the vegetative cell, the generative cell and the sperm cells of pollen and pollen tubes. The generative plasma membranes of the generative cell and the sperm cells were negative. NTP303 protein was also present in the cell walls and in callose plugs. With this method it was shown that the NTP303 protein was already present in mid-bicellular pollen, after the first, asymmetrical pollen mitosis. Possible functions for the NTP303 protein are discussed in relation to its properties and its association with the vegetative plasma membranes.

Molecular analysis of a pistil-specific gene expressed in the stigma and stylar cortex of Solanum tuberosum

A gene, sts14, coding for a highly expressed mRNA in pistils of Solanum tuberosum, was isolated. Northern blot and in situ analyses demonstrated that the gene was expressed throughout pistil development in both the stylar cortex and the stigma. The deduced STS14 protein displays similarity to the pathogenesis-related PR-1 proteins. A possible function for protection or guidance of the pollen tubes through the pistil is discussed.

Regulation of anthraquinone biosynthesis in cell cultures ofMorinda citrifolia

Cell cultures of Morinda citrifolia L. are capable of accumulating substantial amounts of anthraquinones. Chorismate formed by the shikimate pathway is an important precursor of these secondary metabolites. Isochorismate synthase (EC 5.4.99.6), the enzyme that channels chorismate into the direction of the anthraquinones, is involved in the regulation of anthraquinone biosynthesis. Other enzymes of the shikimate pathway such as deoxy-D-arabino-heptulosonate 7-phosphate synthase (EC 4.1.2.15) and chorismate mutase (EC 5.4.99.5) do not play a regulatory role in the process. The accumulation of anthraquinones is correlated with isochorismate synthase activity under a variety of conditions, which indicates that under most circumstances the concentration of the branchpoint metabolite chorismate is not a rate-limiting factor. Anthraquinone biosynthesis in Morinda is strongly inhibited by 2,4-D, but much less by NAA. Both auxins inhibit the activity of isochorismate synthase proportionally to the concomitant reduction in the amount of anthraquinone accumulated. However, the correlation between enzyme activity and rate of biosynthesis is less clear when the activity of the enzyme is very high. In this case, a limiting concentration of precursor may determine the extent of anthraquinone accumulation. Partial inhibition of chorismate biosynthesis by glyphosate leads to less anthraquinone accumulation, but also to a reduction in ICS activity. The complexity of the interference of glyphosate with anthraquinone biosynthesis is illustrated by the effect of the inhibitor in cell cultures of the related species Rubia tinctorum L. in these cells, glyphosate leads to an increase in anthraquinone content and a concomitant rise in ICS activity. All data indicate that the main point of regulation in anthraquinone biosynthesis is located at the entrance of the specific secondary route.