Krzysztof Jaworski

The involvement of cyclic GMP in the photoperiodic flower induction of Pharbitis nil

The involvement of cGMP in the regulation of the flowering of Pharbitis nil was investigated through exogenous applications of cGMP and chemicals that are able to change the cGMP level and analyses of endogenous cGMP level. Exogenous applications of cGMP and 8-pCPT-cGMP (a cyclic GMP non hydrolyzed analog) to P. nil plants, which were exposed to a 12-h-long subinductive night, significantly increased flowering response. NS-2028 (guanylyl cyclase inhibitor) inhibited flowering when that compound was applied during a 16-h-long inductive night, whereas SNP (guanylyl cyclase activator) increased the flowering when plants were subjected to a 12-h-long subinductive night. The inhibitors of cyclic nucleotides phosphodiesterase (isobutyl-methylxanthine and dipyridamole), which increase the cytosolic cGMP level, promoted the flowering and allowed the length of the dark period necessary for induction of flowering to be reduced. The endogenous cGMP level was also measured after the treatment of P. nil seedlings with those chemicals. Results have clearly shown that compounds that were used in physiological experiments modulated endogenous cGMP level. There was a significant difference in the cyclic GMP level between 16-h-long night conditions and a long night with a night-break. During a long inductive night the oscillation of cGMP was observed with four main peaks in 4, 7, 11, 14 h, whereas a 10 min flash of red light in the middle of the night was able to modify these rhythmical changes in the second half of the long night. These results have shown that there are oscillations in the concentration of cGMP in the night and the biosynthesis and/or deactivation of cGMP is affected by light treatment and therefore it may be involved in the regulation of photoinduction processes in cotyledons. From these combined results, we propose a hypothesis that cGMP is involved in the control of photoperiodic flower induction in Pharbitis nil.

Calreticulin expression and localization in plant cells during pollen-pistil interactions.

In this report, the distributions of calreticulin (CRT) and its transcripts in Haemanthus pollen, pollen tubes, and somatic cells of the hollow pistil were studied. Immunoblot analysis of protein extracts from mature anthers, dry and germinated pollen, growing pollen tubes, and unpollinated/pollinated pistils revealed a strong expression of CRT. Both in vitro and in situ studies confirmed the presence of CRT mRNA and protein in pollen/pollen tubes and somatic cells of the pistil transmitting tract. The co-localization of these molecules in ER of these cells suggests that the rough ER is a site of CRT translation. In the pistil, accumulation of the protein in pollen tubes, transmitting tract epidermis (tte), and micropylar cells of the ovule (mc) was correlated with the increased level of exchangeable calcium. Therefore, CRT as a Ca2+-binding/buffering protein, may be involved in mechanism of regulation calcium homeostasis in these cells. The functional role of the protein in pollen–pistil interactions, apart from its postulated function in cellular Ca2+ homeostasis, is discussed.

Biochemical evidence for a calcium-dependent protein kinase from Pharbitis nil and its involvement in photoperiodic flower induction

A soluble Ca(2+)-dependent protein kinase (CDPK) was isolated from seedlings of the short-day plant Pharbitis nil and purified to homogeneity. Activity of Pharbitis nil CDPK (PnCDPK) was strictly dependent on the presence of Ca(2+) (K(0,5)=4,9 microM). The enzyme was autophosphorylated on serine and threonine residues and phosphorylated a wide diversity of substrates only on serine residues. Histone III-S and syntide-2 were the best phosphate acceptors (K(m) for histone III-S=0,178 mg ml(-1)). Polyclonal antibodies directed to a regulatory region of the soybean CDPK recognized 54 and 62 kDa polypeptides from Pharbitis nil. However, only 54 kDa protein was able to catalyse autophosphorylation and phosphorylation of substrates in a Ca(2+)-dependent manner. CDPK autophosphorylation was high in 5-day-old Pharbitis nil seedlings grown under non-inductive continuous white light and was reduced to one-half of its original when plants were grown in the long inductive night. Also, the pattern of proteins phosphorylation has changed. After 16-h-long inductive night phosphorylation of endogenous target (specific band of 82 kDa) increased in the presence of calcium ions. It may suggest that Ca(2+)-dependent protein kinase is involved in this process and it is dependent on light/dark conditions.

Biochemical evidence for a cGMP-regulated protein kinase in Pharbitis nil.

It is known that the level of cGMP is modulated in response to a number of stimuli in plant cells but intracellular events distal to cGMP metabolism are not clear. Cyclic GMP-dependent protein kinase (Pk-G) is a major effector of cGMP action in animals and yeasts. We wanted to determine whether such kinase is present in plant cells. A soluble protein kinase was isolated from seedlings of Pharbitis nil and purified following purification methods including anion-exchange and affinity-chromatography. The enzyme consists of a single polypeptide of M(r) 70 kDa as determined by SDS-PAGE. From conventional modulators only cyclic GMP, when applied in low concentration, was able to accelerate the enzyme activity in the presence of histones. The enzyme autophosphorylated on serine and threonine residues and phosphorylated some substrates only on serine residues. Mixture of histones and histones H2B, H3 were the best phosphate acceptors. The process of autophosphorylation was accelerated by a low concentration of cGMP and reduced by high concentration of this second messenger. Antibodies raised against catalytic domain of animals Pk-G I alpha and beta cross-reacted with protein kinase from Pharbitis nil tissue. These data, taken together, demonstrate the presence of functional enzyme, which activity is regulated by cGMP and allow to classify this protein kinase as a member of the second messenger regulated group of enzymes.

The calcium-dependent protein kinase (PnCDPK1) is involved in Pharbitis nil flowering

Signaling pathways, and specifically the signaling pathway of calcium, have been widely implicated in the regulation of a variety of signals in plants. Calcium-dependent protein kinases (CDPKs) are essential sensor-transducers of calcium signaling pathways, the functional characterization of which is of great interest because they play important roles during growth and in response to a wide range of environmental and developmental stimuli. Here, we report the first evidence of transient and specific elevation of PnCDPK1 transcript level and enzyme activity following conversion of a leaf bud to a flower bud, as well as participation of PnCDPK1 in evocation and flower morphogenesis in Pharbitis nil. Fluorescence microscopy immunolocalization and biochemical analysis confirmed the presence of CDPK in shoot apexes. The protein level was low in leaves, vegetative apexes and increased significantly in apexes after a flowering long-induction night. In the vegetative apex, a very weak PnCDPK1 protein signal was accumulated prominently in the zone of the ground meristem and in external layers of tissues of the cortex. After the dark treatment, the signal in cells of the ground meristem was still present, but a significantly stronger signal appeared in epidermal cells, cortex tissue, and leaf primordium. At the onset of flower meristem development, the PnCDPK1 level diverged significantly. PnCDPK1 mRNA, protein level and enzyme activity were very low at the beginning of flower bud development and gradually increased in later stages, reaching the highest level in a fully open flower. Analysis of flower organs revealed that PnCDPK1 was accumulated mainly in petals and sepals rather than in pistils and stamens. Our results clearly indicate that PnCDPK1 is developmentally regulated and may be an important component in the signal transduction pathways for flower morphogenesis. Findings from this research are important for further dissecting mechanisms of flowering and functions of CDPKs in flowering plants.

The Involvement of Cyclic ADPR in Photoperiodic Flower Induction of Pharbitis nil

Cyclic adenosine diphosphate ribose (cADPR) is a potent endogenous calcium-mobilizing agent synthesized from NAD+ by ADP-ribosyl cyclases described for several animal cells. Pharmacological studies suggest that cADPR is an endogenous modulator of Ca2+-induced Ca2+ release channels. There is also information about the sub-micromolar concentration of cADPR in plant cells. Whether cADPR can act as a Ca2+-mobilizing intracellular messenger in plant tissue is an unresolved question. Despite the obvious importance of monitoring cADPR cellular levels under various physiological conditions in plants, its measurement has been technically difficult and requires specialized reagents. In the present study a widely applicable sensitivity assay for cADPR is described. We show that Pharbitis nil tissue from cotyledons contains a certain cADPR level. To explain the possible roles of this second messenger in photoperiodic flower induction, some physiological experiments were also performed. The exogenous applications of cADPR to Pharbitis nil plants, which were exposed to a 12-h-long subinductive night, significantly increased flowering response. Nevertheless 8-Br-cADPR inhibited flowering when these compounds were applied during a 16-h-long inductive night. The effect of ruthenium red, a calcium channel blocker and ryanodine, a calcium channel stimulator, on the photoperiodic induction of flowering was also studied. Ruthenium red, when applied before and during an inductive 16-h dark period, slightly inhibited flowering, whereas ryanodine, when applied before and during a 12-h long subinductive night, stimulated flower bud formation. We also confirmed evidence that Ca2+ ions are involved in the photoperiodic induction of flowering. Thus, the obtained results may suggest the involvement of cyclic ADPR-activated Ca2+ mobilization in the photoperiodic flower induction process in Pharbitis nil.

Effect of light on soluble guanylyl cyclase activity in Pharbitis nil seedlings

Cyclic GMP acts as a chemical switch in plant cells to modulate cellular reactions. However, its metabolism has not been extensively explored and is still poorly understood. Previous experiments suggest that an endogenous cGMP system could participate in the mechanism of phytochrome controlled photoperiodic flower induction in Pharbitis nil. In order to gain further information on the role of cGMP, we have begun to study the enzyme of cGMP synthesis. In this article, the presence of the enzyme with guanylyl cyclase (GC) activity in soluble protein fractions of P. nil is reported. A large portion of the enzymatic activity is present in the cotyledons, where enzyme activity amounted to 0.45 pmol cGMP/min/mg protein. The enzyme exhibited a K(m) 0.5mM for GTP. A plot of 1/v versus 1/[GTP] was linear and V(max) was 0.74 pmol cGMP/min/mg protein. It was shown that the anti-sGC antibody recognise a 40 kDa protein. Moreover, the NO-donor, sodium nitroprusside (SNP) and YC-1, as a NO-independent stimulator, enhanced enzyme activity. The NS 2028 (a potent GC inhibitor) treatments provoked a 3-fold reduction of the enzyme activity in comparison to the untreated fractions. Furthermore, the influence of light on GC activity was analysed. It was noted that cGMP level increased in cool white light, and darkness inhibited enzyme activity. Exposure to blue light acts to stimulate cGMP formation, whereas in red light a rapid decrease in GC activity was observed that returned to the high level when far-red light was applied after the red light treatment. The results presented in this work strongly argue that an enzyme with guanylyl cyclase activity is present in P. nil organs and its activity is controlled by light via the photoreceptors-dependent pathways.

Molecular cloning and characterization of a novel adenylyl cyclase gene, HpAC1, involved in stress signaling in Hippeastrum x hybridum

Adenylyl cyclases (ACs) are enzymes that generate cyclic AMP, which is involved in different physiological and developmental processes in a number of organisms. Here, we report the cloning and characterization of a new plant adenylyl cyclases (AC) gene, designated HpAC1, from Hippeastrum x hybridum. This gene encodes a protein of 206 amino acids with a calculated molecular mass of 23 kD and an isoelectric point of 5.07. The predicted amino acid sequence contains all the typical features of and shows high identity with putative plant ACs. The purified, recombinant HpAC1 is able to convert ATP to cAMP. The complementation test that was performed to analyze the ability of HpAC1 to compensate for the AC deficiency in the Escherichia coli SP850 strain revealed that HpAC1 functions as an adenylyl cyclase and produces cyclic AMP. Moreover, it was shown that the transcript level of HpAC1 and cyclic AMP concentration changed during certain stress conditions. Both mechanical damage and Phoma narcissi infection lead to two sharp increases in HpAC1 mRNA levels during a 72-h test cycle. Changes in intracellular cAMP level were also observed. These results may indicate the participation of a cAMP-dependent pathway both in rapid and systemic reactions induced after disruption of symplast and apoplast continuity.

Production and purification of polyclonal antibodies to Pisum and Avena labile phytochrome which cross-react with phyA from Pharbitis nil

Little work was done so far with phytochrome from Pharbitis nil. Purification of phyA from this plant has been exceptionally difficult. Labile phytochrome was presented in too small amount to obtain either absorption spectra or enough protein to produce antibodies. Monoclonal antibodies mAP5, MAC 50, 52, 198 recognized Pharbitis nil labile phytochrome poorly, so it was necessary to develop independently an antiserum against labile phytochrome. The antiserum was prepared against proteolytically undegraded phytochrome obtained from etiolated Avena and Pisum seedlings using conventional methods. The antiserum to phytochrome from each of the above mentioned plants was prepared by injecting purified phytochrome into rabbits. The newly produced polyclonal antibodies to phyA from Avena and Pisum were used to characterize phytochrome from etiolated seedlings of Pharbitis nil. The cross reaction was tested by immunobloting. Both kinds of PAbs recognised phyA from Pharbitis nil, however IgG against the labile phytochrome from Pisum gave stronger reaction. The recognized peptide had the molecular weight of about 120-kDa.

Activation of hypoxia-inducible factor-1α in rat brain after perinatal anoxia: role of body temperature

Abstract Transcriptional hypoxia-inducible factor-1α (HIF-1α) plays the fundamental role in adaptive processes in response to hypoxia. Specific HIF-1α target genes are involved in glycolysis, erythropoiesis and angiogenesis to promote survival. In our previous study we have demonstrated that naturally low body temperature of newborn rats protects them against damage due to perinatal hypoxia. Therefore, our experiments aimed at checking the effects of body temperature during simulated perinatal anoxia on subsequent changes of expression of HIF-1α and its specific target genes such as vascular endothelial growth factor (VEGF) and erythropoietin (EPO) in the rat brain. Two-day old Wistar rats were divided into three temperature groups: normothermic −33 °C, hyperthermic −37 °C and extremely hyperthermic −39 °C. The temperature was controlled 15 min before start and continued during 10 min of anoxia as well as for 2 h post-anoxia. HIF-1α was analysed by Western blot and immunofluorescence and mRNA levels of HIF-1α and its downstream genes (VEGF, EPO) were quantified by qRT-PCR. Thermal conditions during neonatal anoxia affected the hippocampal and neocortical level of HIF-1α protein. Physiological body temperature of newborn rats led to prominent accumulation of cerebral HIF-1α protein and significant upregulation of VEGF and EPO mRNA. In contrast, anoxia-induced HIF-1α activation at elevated body temperatures was less pronounced. Since HIF-1α and EPO have recently been regarded as promising therapeutical targets against brain lesions due to hypoxia/ischemia, presented data imply that in order to achieve a full effect of neuroprotection, the thermal conditions during and after the insult should be taken into consideration.