Pollen-specific Promoter Research Articles

Expression of foreign aquaporin genes in lily pollen protoplasts

Aquaporins facilitate water flux across biomembranes in cells and are involved in various physiological phenomena in several plant tissues. Generally, the water-flux activity of exogenously expressed aquaporins is measured in Xenopus laevis oocytes or yeast. However, heterogeneous systems are not likely to be optimal for plant aquaporin analysis. Thus, we created a new experimental system for functional analysis of plant aquaporins using lily (Lilium longiflorum) pollen protoplasts. Large protoplasts with uniform diameters of approximately 95 mm were isolated from lily pollen grains. No plasma membrane intrinsic protein (PIP) aquaporin was detected in lily pollen. For ectopic expression of PIPs in the lily pollen protoplasts, we constructed plasmids in which Arabidopsis AtPIP1;1 or AtPIP2;1 was under the control of a strong pollen-specific promoter (maize Zm13). The PCR-amplified DNA fragments were transformed into the pollen protoplasts by electroporation. Between 45 and 60% of protoplasts were successfully transformed. The protoplasts expressing AtPIP2;1 significantly increased in volume in a hypotonic solution (350 mM mannitol), compared with the vector control. In contrast, the changes in volume of the protoplasts expressing AtPIP1;1 were similar to that of the vector control. This result suggests that PIP2 induces higher water-flux activity in plant cells, whereas PIP1 does not. Thus, we propose the lily pollen protoplast as a simple and useful experimental system to analyze the function of plant aquaporins.

Structural and functional characterization of a pollen-specific promoter NTPp13 in tobacco

A novel 407 bp nucleotide sequence NTPp13 was isolated from tobacco (Nicotiana tabacum L.) by PCR, its structure and function were characterized. The NTPp13 sequence was highly homologous with the pollen-specific expression promoter Zm13 from maize (Zea mays L.) and contained some key motifs which controlled pollen-specific expression. The NTPp13 was fused to the beta-glucuronidase (GUS) reporter gene and transferred into tobacco. Analysis of the transgenic plants revealed that this putative promoter fragment was sufficient to direct GUS expression specifically in the anther, exactly in the pollen and pollen tube, and that GUS activity reached the maximum at the stage of pollen grain began to separate. Further study showed that the expression of NTPp13 sequence at pollen was stable at the range of temperature measured. These data suggested that the NTPp13 sequence was likely the essential element of promoter region of an unknown pollen-specific gene from tobacco.

Isolation and heterologous transformation analysis of a pollen-specific promoter from wheat (Triticum aestivum L.)

The promoter of a pollen-specific gene TaPSG719 was isolated from wheat (Triticum aestivum L.) by inverse-PCR (IPCR). Sequence analysis revealed that the promoter contains two cis-acting elements (AGAAA and GTGA) known to confer anther/pollen-specific gene expression which suggests that the promoter of TaPSG719 gene is a pollen-specific one. To ascertain the regulatory function of TaPSG719 promoter, two deleted fragments (-1,776 to -1 bp and -1,019 to -1 bp) were fused to the beta-glucuronidase (GUS) gene and transformed into tobacco plants. Similar GUS expression patterns were observed in all transformed plants and its activity was detected exclusively in pollen. No GUS activity in any other floral or vegetative tissue was observed. The results confirm that TaPSG719 promoter is pollen-specific and active during the middle stages of pollen development till anther matured, and it can drive pollen-specific gene expression across the species.

Analysis of the tip-to-base gradient of CaM in pollen tube pulsant growth using in vivo CaM–GFP system

Ca(2+)-CaM signaling is involved in pollen tube development. However, the distribution and function of CaM and the downstream components of Ca(2+)-CaM signal in pollen tube development still need more exploration. Here we obtained the CaM-GFP fusion protein transgenic line of Nicotiana tobacum SRI, which allowed us to monitor CaM distribution pattern in vivo and provided a useful tool to observe CaM response to various exogenous stimulations and afforded solid evidences of the essential functions of CaM in pollen tube growth. CaM-GFP fusion gene was constructed under the control of Lat52-7 pollen-specific promoter and transformed into Nicotiana tobacum SRI. High level of CaM-GFP fluorescence was detected at the germinal pores and the tip-to-base gradient of fluorescence was observed in developing pollen tubes. The distribution of CaM at apical dome had close relationship with the pulsant growth mode of pollen tubes: when CaM aggregated at the apical dome, pollen tubes stepped into growth state; When CaM showed non-polarized distribution, pollen tubes stopped growing. In addition, after affording exogenous Ca(2+), calmidazolium (antagonism of CaM) or Brefeldin A (an inhibitor of membrane trafficking), CaM turned to a uniform distribution at the apical dome and pollen tube growth was held back. Taken together, our results showed that CaM played a vital role in pollen tube elongation and growth rate, and the oscillation of tip-to-base gradient of CaM was required for the normal pulsant growth of pollen tube.

Visualization of Plastids in Pollen Grains: Involvement of FtsZ1 in Pollen Plastid Division

Visualizing organelles in living cells is a powerful method to analyze their intrinsic mechanisms. Easy observation of chlorophyll facilitates the study of the underlying mechanisms in chloroplasts, but not in other plastid types. Here, we constructed a transgenic plant enabling visualization of plastids in pollen grains. Combination of a plastid-targeted fluorescent protein with a pollen-specific promoter allowed us to observe the precise number, size and morphology of plastids in pollen grains of the wild type and the ftsZ1 mutant, whose responsible gene plays a central role in chloroplast division. The transgenic material presented in this work is useful for studying the division mechanism of pollen plastids.

The legwd mutant uncovers the role of starch phosphorylation in pollen development and germination in tomato

Starches extracted from most plant species are phosphorylated. alpha-Glucan water dikinase (GWD) is a key enzyme that controls the phosphate content of starch. In the absence of its activity starch degradation is impaired, leading to a starch excess phenotype in Arabidopsis and in potato leaves, and to reduced cold sweetening in potato tubers. Here, we characterized a transposon insertion (legwd::Ds) in the tomato GWD (LeGWD) gene that caused male gametophytic lethality. The mutant pollen had a starch excess phenotype that was associated with a reduction in pollen germination. SEM and TEM analyses indicated mild shrinking of the pollen grains and the accumulation of large starch granules inside the plastids. The level of soluble sugars was reduced by 1.8-fold in mutant pollen grains. Overall, the transmission of the mutant allele was only 0.4% in the male, whereas it was normal in the female. Additional mutant alleles, obtained through transposon excision, showed the same phenotypes as legwd::Ds. Moreover, pollen germination could be restored, and the starch excess phenotype could be abolished in lines expressing the potato GWD homolog (StGWD) under a pollen-specific promoter. In these lines, where fertility was restored, homozygous plants for legwd::Ds were isolated, and showed the starch excess phenotype in the leaves. Overall, our results demonstrate the importance of starch phosphorylation and breakdown for pollen germination, and open up the prospect for analyzing the role of starch metabolism in leaves and fruits.

Functional characterization of the pollen-specific SBgLR promoter from potato (Solanum tuberosum L.)

SBgLR (Solanum tuberosum genomic lysine-rich) gene was isolated from a potato genomic library using SB401 (S. berthaultii 401) cDNA as probe. RT-PCR analysis of SBgLR gene expression profile and microscopic analysis of green fluorescent protein (GFP) expression in tobacco plants transformed with SBgLR promoter-GFP reporters indicate that SBgLR is a pollen-specific gene. A series of 5'deletions of SBgLR promoter were fused to the beta-glucuronidase (GUS) gene and stably introduced into tobacco plants. Histochemical and quantitative assays of GUS expression in transgenic plants allowed us to localize an enhancer of SBgLR promoter to the region -345 to -269 relative to the translation start site. This 76 bp (-345 to -269) fragment enhanced GUS expression in leaves, stems and roots when fused to -90/+6 CaMV 35S minimal promoter. Deletion analysis showed that a cis-element, which can repress gene expression in root hairs, was located in the region -345 to -311. Further study indicated that the -269 to -9 region was sufficient to confer pollen-specific expression of GFP when fused to CaMV 35S enhancer.

Overexpression of Zm401, an mRNA-like RNA, has distinct effects on pollen development in maize

We previously identified a 0.7 Kb cDNA fragment of Zm401, a novel pollen-specific gene in maize (Zea mays). However, little information is known about the function of Zm401 in pollen development. The full-length of Zm401 cDNA was amplified by 5′ RACE and 3′ RACE and both sequence analysis and in vitro translation of Zm401 showed that it belonged to an mRNA-like non-coding gene. To analyze its possible biological roles in pollen development, the Zm401 cDNA was overexpressed in transgenic maize under the control of a pollen specific promoter Zm13 or a CaMV 35S promoter. RT-PCR and RNA gel blot analysis indicated that the expression level of Zm401 in leaves and anthers of transgenic plants was much higher than that of non-transformants. Compared with the non-transformed maize, transgenic maize showed distinct phenotypes, such as abnormal tassels and degenerate anthers. The histological observation showed that the development of pollen grains and anthers in transgenic plants were abnormal. These abnormalities include delayed degradation of tapetum, asynchronous fusion of pollen sacs, and aborted pollen grain development. Furthermore, the pollen viability in six transgenic plants ranged from 1.24% to 6.63%. The reduced pollen viability cosegregated with the transgene in a selfed progeny. These results suggest that Zm401 is involved in the regulation of pollen development. This article demonstrated Zm401, as a non-coding RNA, plays an essential role in pollen development.

Developmental defects and seedling lethality in apyrase AtAPY1 and AtAPY2 double knockout mutants

Previously it was shown that the Arabidopsis apyrase genes AtAPY1 and AtAPY2 are crucial for male fertility because mutant pollen (apy1-1; apy2-1) with T-DNA insertions in both genes could not germinate (Steinebrunner et al. (2003) Plant Physiol. 131: 1638-1647). In this study, pollen germination was restored and apyrase T-DNA double knockouts (DKO) apy1-1/apy1-1; apy2-1/apy2-1 were generated by complementation with AtAPY2 under the control of a pollen-specific promoter. The DKO phenotype displayed developmental defects including the lack of functional root and shoot meristems. In cotyledons, morphogenetic and patterning abnormalities were apparent, e.g., unlobed pavement cells and stomatal clusters. Another set of lines was created which carried either AtAPY1 or AtAPY2 under a dexamethasone-(DEX)-inducible promoter as an additional transgene to the pollen-specific gene construct. Application of DEX did not reverse the DKO phenotype to wild-type, but some inducible lines exhibited less severe defects even in the absence of the inducer, probably due to some background expression. However, even these DKO mutants were seedling-lethal and shared other defects regarding cell division, cell expansion and stomatal patterning. Taken together, the defects in the DKO mutants demonstrate that AtAPY1 and AtAPY2 are essential for normal plant development.

MIKC* MADS-Protein Complexes Bind Motifs Enriched in the Proximal Region of Late Pollen-Specific Arabidopsis Promoters

The genome of Arabidopsis (Arabidopsis thaliana) encodes over 100 MADS-domain transcription factors, categorized into five phylogenetic subgroups. Most research efforts have focused on just one of these subgroups (MIKC(c)), whereas the other four remain largely unexplored. Here, we report on five members of the so-called Mdelta or Arabidopsis MIKC* (AtMIKC*) subgroup, which are predominantly expressed during the late stages of pollen development. Very few MADS-box genes function in mature pollen, and from this perspective, the AtMIKC* genes are therefore highly exceptional. We found that the AtMIKC* proteins are able to form multiple heterodimeric complexes in planta, and that these protein complexes exhibit a for the MADS-family unusual and high DNA binding specificity in vitro. Compared to their occurrence in promoters genome wide, AtMIKC* binding sites are strongly overrepresented in the proximal region of late pollen-specific promoters. By combining our experimental data with in silico genomics and pollen transcriptomics approaches, we identified a considerable number of putative direct target genes of the AtMIKC* transcription factor complexes in pollen, many of which have known or proposed functions in pollen tube growth. The expression of several of these predicted targets is altered in mutant pollen in which all AtMIKC* complexes are affected, and in vitro germination of this mutant pollen is severely impaired. Our data therefore suggest that the AtMIKC* protein complexes play an essential role in transcriptional regulation during late pollen development.

Characterisation of transgenic oilseed rape expressing pea lectin in anthers for improved resistance to pollen beetle

In order to evaluate pea lectin as a resistance factor against the pollen beetle (Meligethes aeneus), transgenic oilseed rape (Brassica napus) has been produced wherein the pea lectin gene expression is driven by a pollen-specific promoter. The aim of the present study was to identify and characterise non-segregating transgenic and non-transgenic lines to be compared in various future tests for benefits and risks associated with such transgenic crop plants. Three doubled haploid (DH) populations (1436, 1440 and 1451) expected to include lectin-producing lines and two DH populations (1443 and 1449) expected to be free of lectin were produced. All five populations originated from different transformation events in the cultivar Westar. The relative amounts of DNA from the marker gene cassette were quantified by conventional as well as real-time PCR analyses and lectin concentrations were estimated by western blot analysis. Two populations with high lectin concentrations, 1436 and 1451, contained higher amounts of the marker DNA and thus more lectin gene copies as compared with 1440 which had lower concentrations of the lectin. As expected all DH lines from 1443 and 1449 were free of lectin. Maximum pea lectin concentration obtained corresponded to 3% of total soluble protein in the anthers. There were significant differences between the populations with respect to bud and flowering stage phenology as well as seed yields, but the differences were not related to their transgenic status. All in all there were 171 lines tested for phenology and transgenic status, out of which 89 with similar phenology were subjected to tests for lectin concentration and seed yield, and 20 of these lines were retested in the next generation. Finally two lines with high lectin concentrations and one with an intermediate level along with two matching non-transgenic lines were selected for future benefit/risk experiments.

Ectopic expression of a maize pollen specific gene, zm401, results in aberrant anther development in tobacco

Our previous study shows that the maize zm401 cDNA is specifically expressed in maize pollens. This evidence suggests that zm401 likely functions in pollen growth and/or development. To confirm its possible involvement in pollen development, the full length cDNA of zm40l was ectopically expressed in tobacco plants under the control of a pollen specific promoter ZM13 (from maize). RT-PCR amplification demonstrated that the ZM13-driven zm401 gene was spatially expressed in tobacco pollens. It was found that all transgenic tobacco plants expressing zm401 showed various levels of sterility, ranging from abortive flower development to male sterility. Further analyses on anther development of transgenic plants indicated multiple abnormalities in the late stages of anther development. These abnormalities include lagged degradation of the tapetum and connective tissue, failed deposition of fibrous bands in endothecium cells, and aborted pollen grain development. These results strongly suggest that zm401 plays an essential role in anther development. However the exact functions of zm401 is still unclear, and further analysis of zm401 is required to determine the exact mechanism involved in anther development.

The F-box protein AhSLF-S2 controls the pollen function of S-RNase-based self-incompatibility.

Recently, we have provided evidence that the polymorphic self-incompatibility (S) locus-encoded F-box (SLF) protein AhSLF-S(2) plays a role in mediating a selective S-RNase destruction during the self-incompatible response in Antirrhinum hispanicum. To investigate its role further, we first transformed a transformation-competent artificial chromosome clone (TAC26) containing both AhSLF-S(2) and AhS(2)-RNase into a self-incompatible (SI) line of Petunia hybrida. Molecular analyses showed that both genes are correctly expressed in pollen and pistil in four independent transgenic lines of petunia. Pollination tests indicated that all four lines became self-compatible because of the specific loss of the pollen function of SI. This alteration was transmitted stably into the T1 progeny. We then transformed AhSLF-S(2) cDNA under the control of a tomato (Lycopersicon esculentum) pollen-specific promoter LAT52 into the self-incompatible petunia line. Molecular studies revealed that AhSLF-S(2) is specifically expressed in pollen of five independent transgenic plants. Pollination tests showed that they also had lost the pollen function of SI. Importantly, expression of endogenous SLF or SLF-like genes was not altered in these transgenic plants. These results phenocopy a well-known phenomenon called competitive interaction whereby the presence of two different pollen S alleles within pollen leads to the breakdown of the pollen function of SI in several solanaceaous species. Furthermore, we demonstrated that AhSLF-S(2) physically interacts with PhS(3)-RNase from the P. hybrida line used for transformation. Together with the recent demonstration of PiSLF as the pollen determinant in P. inflata, these results provide direct evidence that the polymorphic SLF including AhSLF-S(2) controls the pollen function of S-RNase-based self-incompatibility.

The roles of calmodulin polar distribution during pollen hydration and germination

Polarity patterning of pollen germination is a vital process for angiosperm fertilization. In our study a new method was employed to investigate the real-time distribution of calmodulin (CaM) in living pollen grains and pollen tubes. The CaM–GFP fusion gene was constructed under the control of the pollen-specific promoter LAT52-7 and transformed into Nicotiana tabacum L. Through confocal laser scanning microscopy, high levels of CaM were observed to accumulate in the three germinal apertures, and a tip–base gradient of CaM was detected in elongating pollen tubes. During pollen-grain hydration and germination, one of the three germinal apertures aggregated a much higher level of CaM than the other two. In addition, CaM showed a directional migration from the cytoplasm to this germinal aperture, where the pollen tube would emerge. Interestingly, CaM was not detected in the reproductive nucleus of either pollen grains or pollen tubes. Our findings indicated that the directional migration of CaM existed during pollen hydration and germination, and this movement may play a crucial role in the normal polarity establishment of pollen germination.Key words: calmodulin, polarity, pollen grain, Nicotiana tabacum.

A Model System to Study the Environment-Dependent Expression of the Bet v 1a Gene Encoding the Major Birch Pollen Allergen

Background: The major birch pollen allergen Bet v 1 (or Bet v 1a) is one of the main causes of seasonal type I allergies. Various environmental factors such as light, temperature and air pollution may influence the activity of the Bet v 1a gene. The creation of a model system to evaluate the role of environmental factors affecting the Bet v 1a gene expression would be highly desirable. We suggest the use of transgenic tobacco plants carrying a Bet v 1a promoter-reporter gene fusion as such a system. Methods: The promoter of the Bet v 1a gene was isolated with the use of the Universal Genome Walker kit (BD Biosciences Clontech, USA). Web Software was used to search for putative cis-regulatory elements within the promoter. Transgenic tobacco plants harboring the promoter-β-glucuronidase (GUS) reporter gene fusion were obtained via Agrobacterium tumefaciens-mediated transformation. Promoter activity was examined with histochemical and quantitative assays. Results: Structural analysis predicted elements responsible for pollen-specific, light-, stress- and hormone-mediated induction within the Bet v 1a promoter. The evaluation of GUS activity in transgenic tobacco plants showed that the Bet v 1a promoter is pollen-specific. Moreover, the Bet v 1a promoter is considered to be the strongest isolated pollen-specific promoter reported to date. It was shown that temperature and abscisic acid positively regulate the activity of the Bet v 1a promoter during pollen development, providing evidence for environment-dependent regulation of the Bet v 1a gene. Conclusions: A model system to study the effect of environmental factors on the expression of the Bet v 1a gene encoding the major birch allergen in pollen was generated. Additionally, we suggest that this system could be used to search for factors that inhibit the activity of the gene in pollen in order to reduce the potential allergenicity of birch trees.

Geminating pollen has tubular vacuoles, displays highly dynamic vacuole biogenesis, and requires VACUOLESS1 for proper function.

Vacuoles perform multiple functions in plants, and VCL1 (VACUOLESS1) is essential for biogenesis with loss of expression in the vcl1 mutant leading to lethality. Vacuole biogenesis plays a prominent role in gametophytes, yet is poorly understood. Given the importance of VCL1, we asked if it contributes to vacuole biogenesis during pollen germination. To address this question, it was essential to first understand the dynamics of vacuoles. A tonoplast marker, delta-TIP::GFP, under a pollen-specific promoter permitted the examination of vacuole morphology in germinating pollen of Arabidopsis. Our results demonstrate that germination involves a complex, yet definable, progression of vacuole biogenesis. Pollen vacuoles are extremely dynamic with remarkable features such as elongated (tubular) vacuoles and highly mobile cytoplasmic invaginations. Surprisingly, vcl1 did not adversely impact vacuole morphology in pollen germinated in vitro. To focus further on VCL1 in pollen, reciprocal backcrosses demonstrated reduced transmission of vcl1 through male gametophytes, indicating that vcl1 was expressive after germination. Interestingly, vcl1 affected the fertility of female gametophytes that undergo similarly complex vacuole biogenesis. Our results indicate that vcl1 is lethal in the sporophyte but is not fully expressive in the gametophytes. They also point to the complexity of pollen vacuoles and suggest that the mechanism of vacuole biogenesis in pollen may differ from that in other plant tissues.

Pea lectin expressed transgenically in oilseed rape reduces growth rate of pollen beetle larvae.

In several studies plant lectins have shown promise as transgenic resistance factors against various insect pests. We have here shown that pea seed lectin is a potential candidate for use against pollen beetle, a serious pest of Brassica oilseeds. In feeding assays where pollen beetle larvae were fed oilseed rape anthers soaked in a 1% solution of pea lectin there was a reduction in survival of 84% compared to larvae on control treatment and the weight of surviving larvae was reduced by 79%. When a 10% solution of pea lectin was used all larvae were dead after 4 days of testing. To further evaluate the potential use of pea lectin, transgenic plants of oilseed rape (Brassica napus cv. Westar) were produced in which the pea lectin gene under control of the pollen-specific promoter Sta44-4 was introduced. In 11 out of 20 tested plants of the T0-generation there was a significant reduction in larval weight, which ranged up to 46% compared to the control. A small but significant reduction in larval survival rate was also observed. In the T2-generation significant weight reductions, with a maximum of 32%, were obtained in 10 out of 33 comparisons between transgenic plants and their controls. Pea lectin concentrations in anthers of transgenic T2-plants ranged up to 1.5% of total soluble protein. There was a negative correlation between lectin concentration and larval growth. Plants from test groups with significant differences in larval weights had a significantly higher mean pea lectin concentration, 0.64% compared to 0.15% for plants from test groups without effect on larval weight. These results support the conclusion that pea lectin is a promising resistance factor for use in Brassica oilseeds against pollen beetles.

Comparison of Bt maize hybrids with their non‐transgenic counterparts and commercial varieties for resistance to European corn borer and for agronomic traits

AbstractThe European corn borer (ECB), Ostrinia nubilalis (Hübner), is a major pest of maize (Zea mays L.) in Central Europe. In order to compare transgenic Bt maize hybrids with their non‐transgenic counterparts and commercial hybrids, field trials and a laboratory bioassay were conducted. The field experiments were performed at four locations with natural and manual infestation of ECB larvae in 1998 and 1999. Transgenic Bt hybrids showed significantly lower means than their corresponding non‐transgenic counterparts and commercial hybrids for all resistance traits (damage rating of stalks, number of larvae per plant, and percentage of damaged plants or ears under infestation). Bt hybrids containing the CryIA(b) gene under the control of green tissue and pollen‐specific promoters (event 176) showed a significantly higher percentage of damaged ears than Bt hybrids carrying the CryIA(b) gene under the control of a constitutive promoter (Mon810). Bt and non‐Bt hybrids showed no significant differences for all agronomic traits, except for plant height under insecticide protection and grain yield reduction under infestation, whereas Bt hybrids had significantly lower means than their non‐transgenic counterparts and other commercial hybrids. All resistance traits were significantly correlated with grain yield reduction. The laboratory bioassay confirmed the level of antibiosis of Bt hybrids against neonate ECB larvae. Bt hybrids showed the highest level of ECB resistance and therefore are an attractive method of preventing ECB damage within an integrated pest‐management system.

Reduction in Allergenicity of Grass Pollen by Genetic Engineering

Background: Hay fever and allergic asthma triggered by grass pollen allergens affect ∼20% of the population in cool temperate climates. Ryegrass is the dominant source of allergens due to its prodigious airborne pollen production. Lol p 5 or group 5 is among the most important and widespread grass pollen allergen because it reacts with IgE antibodies of more than 90% of grass pollen-allergic patients, contains most of the grass pollen-specific IgE epitopes and elicits strong biological responses. Significant efforts have been made in developing diagnostic and therapeutic reagents for designing new and more effective immunotherapeutic strategies for treatment of allergic diseases. An alternative approach to this problem could be to reduce the amount of allergen content in the source plant. Methods: High velocity microprojectile bombardment was used to genetically engineer ryegrass. Antisense construct targeted to one of major allergen, Lol p 5, was introduced. The expression of antisense RNA was regulated by a pollen-specific promoter. Pollen was analysed for IgE reactivity. Results: Analysis of proteins with allergen-specific monoclonal and polyclonal antibodies did not detect Lol p 5 in the transgenic pollen. The transgenic pollen showed remarkably reduced allergenicity as reflected by low IgE binding capacity of pollen extract as compared to control pollen. The transgenic ryegrass plants in which Lol p 5 gene expression is perturbed showed normal fertile pollen development. Conclusions: Our studies showed that it is possible to selectively ‘switch off’ allergen production in pollen of ryegrass demonstrating feasibility of genetic engineering of plants for reduced allergenicity.

Analyses of the Genomic Sequence and Promoter Activity of a Gene for a Protein Similar to Tat Binding Protein Isolated from Brassica rapa.

We have previously isolated a cDNA clone, which is similar in sequence to the Tat binding protein (TBP) of human immunodeficiency virus 1, from the anthers of Brassica rapa and designated it BrTBP. In the present study we isolated a genomic clone of BrTBP from B. rapa and found several sequence motifs conserved in various pollen-expressed genes. The 1.7-kb promoter region of BrTBP was fused to the GUS gene and introduced into tobacco and Arabidopsis thaliana. GUS expression was observed exclusively in mature pollen after anthesis in transgenic tobacco, while it was observed in tricellular pollen starting two days before anthesis in A. thaliana. Such expression patterns at the late stage of pollen development have not been reported in other pollen-specific promoters. These results indicate that the BrTBP promoter region used in this study has a unique activation pattern in tobacco and A. thaliana.