M.E.L. Schreuder

Physiological characterization of a high-pigment mutant of tomato.

Abstract— A high‐pigment (hp) mutant, which shows exaggerated phytochrome responses and three other genotypes of Lycopersicon esculenrum Mill. cv. Ailsa Craig: the aurea (au) mutant deficient in the bulk light‐labile phytochrome (PI) pool, the au, hp double mutant, and their isogenic wild type, were used in this study. Measurements of phytochrome destruction in red light (R) revealed that the exaggerated responses of the hp mutant are not caused by a higher absolute phytochrome level or a reduced rate of phytochrome destruction. Fluence‐response relationships for anthocyanin synthesis after a blue‐light pretreatment were studied to test if the hp mutant conveys hypersensitivity to the far‐red light (FR)‐absorbing form of phytochrome (Pfr), i.e. the threshold of Pfr required to initiate the response is lower. The response range for the hp mutant and wild type was identical, although the former exhibited a 6‐fold larger response. Moreover, the kinetics of anthocyanin accumulation in continuous R were similar in the wild‐type and hp‐mutant seedlings, despite the latter accumulating 9‐fold more anthocyanin. Since the properties of phytochrome are the same, the hp mutation appears to affect the state of responsiveness amplification, i.e. the same amount of Pfr leads to a higher response in the hp mutant. We therefore propose that the hp mutation is associated with an amplification step in the phytochrome transduction chain. Escape experiments showed that the anthocyanin synthesis after different light pretreatments terminated with a R pulse was still 50% FR reversible after 4–6 h darkness, indicating that the Pfr pool regulating this response must be relatively stable. However, fluence‐rate response relationships for anthocyanin synthesis and hypocotyl growth induced by a 24‐h irradiation with 451, 539, 649, 693, 704 and 729 nm light showed no or a severely reduced response in the au and au, hp mutants, suggesting the importance of PI in these responses. We therefore propose that the capacity for anthocyanin synthesis (state of responsiveness amplification) could be established by PI, while the anthocyanin synthesis is actually photoregulated via a stable Pfr pool. The Hp gene product is proposed to be an inhibitor of the state of responsiveness amplification for responses controlled by this relatively stable Pfr species.

Phytochrome control of anthocyanin biosynthesis in tomato seedlings : Analysis using photomorphogenic mutants

Anthocyanin biosynthesis has been studied in hypocotyls and whole seedlings of tomato (Lycoperskon esculentum Mill.) wild types (WTs) and photomorphogenic mutants. In white light (WL)/dark (D) cycles the fri1 mutant, deficient in phytochrome A (phyA), shows an enhancement of anthocyanin accumulation, whereas the tri1 mutant, deficient in phytochrome Bl (phyBl) has a WT level of anthocyanin. Under pulses of red light (R) or R followed by far‐red light (FR) given every 4 h, phyA is responsible for the non‐R/FR reversible response, whereas phyBl is partially responsible for the R/FR reversible response. From R and blue light (B) pretreatment studies, B is most effective in increasing phytochrome responsiveness, whereas under R itself it appears to be dependent on the presence of phyBl. Anthocyanin biosynthesis during a 24 h period of monochromatic irradiation at different flu‐ence rates of 4 day‐old D‐grown seedlings has been studied. At 660 nm the fluence rate‐response relationships for induction of anthocyanin in the WT are similar, yet complex, showing a low fluence rate response (LFRR) and a fluence rate‐dependent high irradiance response (HIR). The high‐pigment‐1 (hp‐1) mutant exhibits a strong amplification of both the LFRR and HIR. The fri1 mutant lacks the LFRR while retaining a normal HIR. In contrast, a transgenic tomato line overexpressing the oat PHYA3 gene shows a dramatic amplification of the LFRR. The tri1 mutant, retains the LFRR but lacks the HIR, whereas the fri1, tri1 double mutant lacks both components. Only an LFRR is seen at 729 nm in WT; however, an appreciable HIR is observed at 704 nm, which is retained in the tri1 mutant and is absent in the fri1 mutant, indicating the labile phyA pool regulates this response component.

Identification of the Gene Encoding the α1,3-Mannosyltransferase (ALG3) in Arabidopsis and Characterization of Downstream N-Glycan Processing

Glycosyltransferases are involved in the biosynthesis of lipid-linked N-glycans. Here, we identify and characterize a mannosyltransferase gene from Arabidopsis thaliana, which is the functional homolog of the ALG3 (Dol-P-Man:Man5GlcNAc2-PP-Dol α1,3-mannosyl transferase) gene in yeast. The At ALG3 protein can complement a Δalg3 yeast mutant and is localized to the endoplasmic reticulum in yeast and in plants. A homozygous T-DNA insertion mutant, alg3-2, was identified in Arabidopsis with residual levels of wild-type ALG3, derived from incidental splicing of the 11th intron carrying the T-DNAs. N-glycan analysis of alg3-2 and alg3-2 in the complex-glycan-less mutant background, which lacks N-acetylglucosaminyl-transferase I activity, reveals that when ALG3 activity is strongly reduced, almost all N-glycans transferred to proteins are aberrant, indicating that the Arabidopsis oligosaccharide transferase complex is remarkably substrate tolerant. In alg3-2 plants, the aberrant glycans on glycoproteins are recognized by endogenous mannosidase I and N-acetylglucosaminyltransferase I and efficiently processed into complex-type glycans. Although no high-mannose-type glycoproteins are detected in alg3-2 plants, these plants do not show a growth phenotype under normal growth conditions. However, the glycosylation abnormalities result in activation of marker genes diagnostic of the unfolded protein response.

Physiological characterization of exaggerated photoresponse mutants of tomato.

Summary Four monogenic mutants in tomato (Lycopersicon esculentum Mill.), i.e. three recessive mutations, high-pigment-1 (hp-1), high-pigment-2 (hp-2), and atroviolacea (atv), and one dominant mutation, Intense pigmentation (Ip), were used in this study. These mutants all show exaggerated photoresponses during deetiolation and seedlings having shorter hypocotyls and higher anthocyanin levels. The hp-1 and hp-2 have higher chlorophyll levels in immature fruit, giving them a dark green colour. Spectrophotometrical and immunological analyses of phytochrome A and phytochrome B revealed no differences between the mutants and the wild types (WTs), suggesting that the mutants are not photoreceptor mutants. Both hp-1 and hp-2 accumulate high levels of anthocyanin in continuous blue (B) and red (R) broad-band light. In contrast, atv has a WT level of anthocyanin in B and an exaggerated response in R. The Ip mutant has the opposite response: a WT level of anthocyanin in R and an exaggerated response in B. In B and R pretreat-ment studies, all mutants show an enhanced R/far-red light (FR)-reversible response compared with WT, but the Ip mutant shows a preferentially enhanced response in B. The hp-1 mutant exhibits a strong amplification of both the low fluence rate response and high irradiance response components of anthocyanin biosynthesis in red light. The atv mutant shows the strongest amplification of the HIR component. The Ip mutant exhibits an exaggerated anthocyanin response in B. All four mutants exhibit a normal elongation response to supplementary FR during the daily photoperiod.

Characterization of the gene encoding the apoprotein of phytochrome B2 in tomato, and identification of molecular lesions in two mutant alleles

Abstract The structure of the gene encoding the apoprotein of tomato phytochrome B2 (PHYB2) has been determined from genomic and cDNA sequences. The coding region is organized into four exons, like almost every other angiosperm phytochrome (phy). The deduced phyB2 apoprotein (PHYB2) consists of 1121 amino acids, with 82, 74 and 70% identity to tomato PHYB1, Arabidopsis PHYB, and Arabidopsis PHYD, respectively. In order to facilitate the identification of new mutants, we constructed a double mutant that is deficient in phyA and phyB1. When grown in white light, this mutant becomes only slightly taller than wild type and is similar in phenotype to the monogenic phyB1-deficient mutant. This double mutant has been used as the parent line for mutagenesis with γ radiation. Several recessive mutants with long hypocotyls and reduced anthocyanin content were selected under white light and screened for mutations in PHYB2, PHYE and PHYF. Two of the triple-mutant lines, designated 55H and 70F, had elongated hypocotyls and fruit trusses, and pale immature fruits. Both belong to the same complementation group and both were found to have defects in PHYB2. Line 70F was found by Northern analysis to have a slightly larger PHYB2 transcript. Part or all of the intron between the second and third exons was found to be retained following RT-PCR of PHYB2 mRNA from line 70F. Three base substitutions were detected near the donor splice site for this intron, including a change from the consensus /GT to /GA at the 5′ end of this intron. In every case, the C-terminal 164 amino acids of PHYB2 were replaced by 59 nonsense amino acids followed by a stop codon. Sequencing of PHYB2 from 55H revealed a single-nucleotide deletion near the end of the third exon, resulting in one incorrect codon followed immediately by a stop codon. The predicted mutant apoprotein in 55H is 90 residues shorter than wild-type PHYB2.

Characterization of the single-chain Fv-Fc antibody MBP10 produced in Arabidopsis alg3 mutant seeds

ER resident glycoproteins, including ectopically expressed recombinant glycoproteins, carry so-called high-mannose type N-glycans, which can be at different stages of processing. The presence of heterogeneous high-mannose type glycans on ER-retained therapeutic proteins is undesirable for specific therapeutic applications. Previously, we described an Arabidopsisalg3-2 glycosylation mutant in which aberrant Man5GlcNAc2 mannose type N-glycans are transferred to proteins. Here we show that the alg3-2 mutation reduces the N-glycan heterogeneity on ER resident glycoproteins in seeds. We compared the properties of a scFv-Fc, with a KDEL ER retention tag (MBP10) that was expressed in seeds of wild type and alg3-2 plants. N-glycans on these antibodies from mutant seeds were predominantly of the intermediate Man5GlcNAc2 compared to Man8GlcNAc2 and Man7GlcNAc2 isoforms on MBP10 from wild-type seeds. The presence of aberrant N-glycans on MBP10 did not seem to affect MBP10 dimerisation nor binding of MBP10 to its antigen. In alg3-2 the fraction of underglycosylated MBP10 protein forms was higher than in wild type. Interestingly, the expression of MBP10 resulted also in underglycosylation of other, endogenous glycoproteins.

Low-Phosphate Induction of Plastidal Stromules Is Dependent on Strigolactones But Not on the Canonical Strigolactone Signaling Component MAX2

Induction of stromule formation in plastids is dependent on strigolactones, but not on the strigolactone signaling component MAX2. Stromules are highly dynamic protrusions of the plastids in plants. Several factors, such as drought and light conditions, influence the stromule frequency (SF) in a positive or negative way. A relatively recently discovered class of plant hormones are the strigolactones; strigolactones inhibit branching of the shoots and promote beneficial interactions between roots and arbuscular mycorrhizal fungi. Here, we investigate the link between the formation of stromules and strigolactones. This research shows a strong link between strigolactones and the formation of stromules: SF correlates with strigolactone levels in the wild type and strigolactone mutants (max2-1 max3-9), and SF is stimulated by strigolactone GR24 and reduced by strigolactone inhibitor D2.

Differential effects of human and plant N-acetylglucosaminyltransferase I (GnTI) in plants

In plants and animals, the first step in complex type N-glycan formation on glycoproteins is catalyzed by N-acetylglucosaminyltransferase I (GnTI). We show that the cgl1-1 mutant of Arabidopsis, which lacks GnTI activity, is fully complemented by YFP-labeled plant AtGnTI, but only partially complemented by YFP-labeled human HuGnTI and that this is due to post-transcriptional events. In contrast to AtGnTI-YFP, only low levels of HuGnTI-YFP protein was detected in transgenic plants. In protoplast co-transfection experiments all GnTI-YFP fusion proteins co-localized with a Golgi marker protein, but only limited co-localization of AtGnTI and HuGnTI in the same plant protoplast. The partial alternative targeting of HuGnTI in plant protoplasts was alleviated by exchanging the membrane-anchor domain with that of AtGnTI, but in stably transformed cgl1-1 plants this chimeric GnTI still did not lead to full complementation of the cgl1-1 phenotype. Combined, the results indicate that activity of HuGnTI in plants is limited by a combination of reduced protein stability, alternative protein targeting and possibly to some extend to lower enzymatic performance of the catalytic domain in the plant biochemical environment.

Functional intron-derived miRNAs and host-gene expression in plants

BackgroundRecently, putative pre-miRNAs locations have been identified in the introns of plant genes, raising the question whether such genes can show a dual functionality by having both correct maturation of the host gene pre-mRNA and maturation of the miRNAs from the intron. Here, we demonstrated that such dual functionality is indeed possible, using as host gene the firefly luciferase gene with intron (ffgLUC), and different artificial intronic miRNAs (aimiRNA) placed within the intron of ffgLUC.ResultsThe miRNAs were based on the structure of the natural miR319a. Luciferase (LUC) activity in planta was used to evaluate a correct splicing of the ffgLUC mRNA. Different target sequences were inserted into the aimiRNA to monitor efficiency of silencing of different target mRNAs. After adjusting the insertion cloning strategy, the ffgLUCaimiR-319a gene showed dual functionality with correct splicing of ffgLUC and efficient silencing of TEOSINTE BRANCHED1/CYCLOIDEA/PROLIFERATING CELL FACTOR1 transcription factor genes targeted in-trans by aimiR-319a or targeting the transgene ffLUC in-cis by an aimiR-LUC. Silencing of endogenous target genes by aimiRNA or amiRNA is efficient both in transient assays and stable transformants. A behave as strong phenotype the PHYTOCHROME B (PHYB) gene was also targeted by ffgLUCaimiR-PHYB. The lack of silencing of the PHYB target was most likely due to an insensitive target site within the PHYB mRNA which can potentially form a double stranded stem structure.ConclusionThe combination of an overexpression construct with an artificial intronic microRNA allows for a simultaneous dual function in plants. The concept therefore adds new options to engineering of plant traits that require multiple gene manipulations.