[PECULIARITIES OF ANESTHESIA DURING COCHLEAR IMPLANTATION IN PEDIATRICS.]

THE AIM: analysis of the use of laryngeal mask in anesthesia for cochlear implantation. MATERIALS AND METHODS: 10 patients aged from 1 year to 5 years were operated on according to the classical method KI with the use of laryngeal masks. As anesthesia was performed a balanced multimodal anesthesia by Sevoflurane and Fentanyl. RESULTS: The use of laryngeal masks in all 10 cases have gave the possible to avoid the use of muscle relaxants and to clear the threshold of detection of acoustic reflexes ofstapes musclestendon, and to reduce time of surgical intervention. A short time surgery provided rapid awakening of the patient, absence of nausea and vomiting in the early postoperative period. CONCLUSION: use of laryngeal mask airway is reduces the time of surgery, minimize the patient's trauma, reduce input anesthetic drugs and get good results intraoperative audiological testing.

Broad-range antagonistic rhizobacteria Pseudomonas fluorescens and Serratia plymuthica suppress Agrobacterium crown gall tumours on tomato plants.

AIM: To examine the biocontrol activity of broad-range antagonists Serratia plymuthica IC1270, Pseudomonas fluorescens Q8r1-96 and P. fluorescens B-4117 against tumourigenic strains of Agrobacterium tumefaciens and A. vitis. METHODS AND RESULTS: Under greenhouse conditions, the antagonists, applied via root soak prior to injecting Agrobacterium strains into the wounded stems, significantly suppressed tumour development on tomato seedlings. A derivative of P. fluorescens Q8r1-96 tagged with a gfp reporter, as well as P. fluorescens B-4117 and S. plymuthica IC1270 marked with rifampicin resistance, stably persisted in tomato tissues for at least 1 month. Mutants of P. fluorescens Q8r1-96 and S. plymuthica IC1270 deficient in 2,4-diacetylphloroglucinol or pyrrolnitrin production, respectively, also proficiently suppressed the tumour development, indicating that these antibiotics are not responsible for the observed biocontrol effect on crown gall disease. The volatile organic compounds (VOCs) produced by the tested P. fluorescens and S. plymuthica strains inhibited the growth of A. tumefaciens and A. vitis strains in vitro. Solid-phase microextraction-gas chromatography-mass spectrometry analysis revealed dimethyl disulfide (DMDS) as the major headspace volatile produced by S. plymuthica IC1270; it strongly suppressed Agrobacterium growth in vitro and was emitted by tomato plants treated with S. plymuthica IC1270. 1-Undecene was the main volatile emitted by the examined P. fluorescens strains, with other volatiles, including DMDS, being detected in only relatively low quantities. CONCLUSIONS: S. plymuthica IC1270, P. fluorescens B-4117 and P. fluorescens Q8r1-96 can be used as novel biocontrol agents of pathogenic Agrobacterium. VOCs, and specifically DMDS, might be involved in the suppression of oncogenicity in tomato plants. However, the role of specific volatiles in the biocontrol activity remains to be elucidated. SIGNIFICANCE AND IMPACT OF THE STUDY: The advantage of applying these antagonists lies in their multiple activities against a number of plant pathogens, including Agrobacterium.

Development-specific association of amyloplasts with microtubules in scale cells of Narcissus tazetta.

Narcissus tazetta is one of the major geophyte crops worldwide, but little is known about its cell biology. The narcissus storage organ was studied by monitoring scale cell biology during the growth stage and dormancy, and it was found that amyloplasts gradually increased in size and reached a maximum at dormancy. In parallel, microtubules changed their organisation: during the growth phase (February to March) they were oblique; during April and May, microtubules formed a network with round "holes"; by late June and the beginning of July, when dormancy started, they were organised in parallel arrays. The holes formed in the microtubule array corresponded to amyloplasts. A closer look showed that during a short time window, while the plants were preparing for dormancy, the microtubules surrounded the amyloplasts. In vitro reconfirmation of this phenomenon was obtained when fluorescent bovine brain microtubules enwrapped isolated amyloplasts that had been purified between April and July but not those purified between January and March. Interestingly, protease treatment of amyloplasts did not completely prevent binding of microtubules, which suggests the existence of a protease-resistant factor that docks microtubules to the outer membrane of amyloplasts.

The Evergreen gene is essential for flower initiation in carnation.

One of the leading cut-flower crops in the world, the greenhouse carnation (Dianthus caryophyllus), has been subjected to intense breeding efforts for the past few hundred years. As an ornamental crop, flowering and flower architecture are major breeding targets that are constantly in demand. In an ongoing breeding program aimed at improving these characteristics, two mutants heterozygous for a mutation in a gene termed evergreen (e) were identified. In these mutants, spike-like clusters of bracteoles subtend each flower. Genetic analysis of the mutants confirmed the semidominant nature of this nuclear mutation and that the two original mutants were allelic at the evergreen locus. In homozygous mutant plants, a more severe phenotype was observed. Flower formation was completely blocked and spikelike clusters of bracteoles did not subtend any flowers. Morphological characterization of mutant plants revealed that vegetative growth and inflorescence structure are not affected by the mutant allele. In plants heterozygous for the evergreen mutation, fertility, petal and pistil length, calyx diameter, and stamen number were not affected. However, flowers from these heterozygous plants had a reduced number of petals, suggesting an intriguing link between evergreen and the double flower (d) gene that determines petal number in carnation. The control by evergreen of bracteole formation, floral meristem initiation, and petal number in carnation is discussed in comparison to the recessive leafy (lfy) and floricaula (flo) mutants of Arabidopsis and Antirrhinum, respectively.

Molecular mechanisms underlying carotenogenesis in the chromoplast: multilevel regulation of carotenoid-associated genes

In nature, carotenoid function and mode of action are highly determined by the neighboring protein and lipid molecules. Therefore an understanding of the proteins' involvement in carotenoid sequestration would be of great help in elucidating carotenoid function in vivo. Based on a study of the expression of chromoplast-specific carotenoid-associated genes from cucumber corolla (CHRC and CHRD), a working model is presented wherein two major regulatory factors control carotenoid sequestration within the chromoplasts: (i) floral tissue-specific transcriptional regulators of chromoplasto- genesis; and (ii) post-transcriptional regulators related to the amount/type of sequestered carotenoids. This model is supported by the major role transcriptional regulation was found to play in the temporal and spatial expression of the CHRC gene, and by the fact that phytohormones such as gibberellic acid (GA3), abscisic acid and ethylene also acted as transcriptional regulators of CHRC expression. The primary response to GA3 was localized within the CHRC promoter to a 290 bp fragment. Furthermore, we demonstrated strong down-regulation of CHRC expression at post-transcriptional and translational/post-translational levels resulting from inhibition of carotenoid biosynthesis, thus revealing a close link between carotenoid biosynthetic and sequestration machineries.

Carotenoid sequestration in plants: the role of carotenoid-associated proteins.

In plants, carotenoid accumulation and sequestration take place within chloroplasts and chromoplasts. In the chloroplast, practically all carotenoids are associated with chlorophyll-binding proteins, whereas chromoplasts have developed a unique mechanism to sequester carotenoids within specific lipoprotein structures. Recent research into the existence of a group of homologous genes that encode carotenoid-associated proteins that aid in the generation of carotenoid-lipoprotein structures in chromoplasts, offers a new framework for elucidating the carotenoid sequestration mechanism.

Genetic engineering for cut-flower improvement.

The application of modern biotechnological approaches to cut flowers has clearly become instrumental and rewarding for the floriculture industry. In recent years, several gene-transfer procedures have been developed for some of the major commercial cut flowers. Using Agrobactrium or microprojectile bombardment, several basic protocols are now available. However, despite the great progress and interest in gene transfer to these crops, their transformation is routine in only a limited number of laboratories, and its application is still considered to be an "art form". This review summarizes the reported gene-transfer procedures for the main cut-flower crops, with an emphasis on the unique factors of each method and the recent progress in introducing new traits of horticultural interest into these species.

CHRC, encoding a chromoplast-specific carotenoid-associated protein, is an early gibberellic acid-responsive gene.

CHRC, a corolla-specific carotenoid-associated protein, is a major component of carotenoid-lipoprotein complexes in Cucumis sativus chromoplasts. Using an in vitro flower bud culture system that mimics in vivo flower development, CHRC mRNA levels in corollas were shown to be specifically up-regulated by gibberellic acid. The response to gibberellic acid was very rapid (within 20 min) and insensitive to protein synthesis inhibition by cycloheximide. Abscisic acid, known to antagonize gibberellin in many developmental systems, strongly down-regulated CHRC mRNA levels. The gibberellin synthesis inhibitor paclobutrazol exhibited a similar negative effect on CHRC expression. Inclusion of exogenous gibberellic acid into the in vitro bud culture system with the paclobutrazol not only prevented the CHRC mRNA down-regulation, it up-regulated transcript accumulation to the level of gibberellic acid-treated corollas. CHRC mRNA accumulation in response to gibberellic acid displayed a dose-dependent increase up to 10(-4) M gibberellic acid. The up-regulation could be detected with as little as 10(-7) M gibberellic acid. Based on these data, we suggest that CHRC is the first structural gene identified to date whose expression is regulated by gibberellic acid in a primary fashion. The critical role of the rapid response of CHRC to gibberellic acid in aiding carotenoid sequestration while preserving chromoplast structural organization is discussed.

Isolation and regulation of accumulation of a minor chromoplast-specific protein from cucumber corollas.

The differentiation of chloroplasts to chromoplasts in cucumber (Cucumis sativus L.) corollas parallels flower development. Chromoplast biogenesis involves chlorophyll degradation, carotenoid accumulation, and the appearance of a new set of proteins. To study factors involved in chromoplast biogenesis in floral tissues, a minor (in abundance) protein of about 14 kD, CHRD (chromoplast protein D), was isolated from cucumber corolla chromoplasts. Immunological characterization revealed that the protein is chromoplast-specific and that its steady-state level in corollas increases in parallel to flower development. The protein was not detected in cucumber leaves or fruits. Immunological analysis of corollas and fruits from variety of other plants also did not reveal cross-reactivity with the CHRD protein antisera. Using an in vitro bud culture system, we analyzed the effect of phytohormones on CHRD expression. Gibberellic acid rapidly enhanced, whereas paclobutrazol down-regulated, the steady-state level of CHRD. Ethylene also down-regulated the protein's steady-state level. It is suggested that hormonal control of chromoplastogenesis is tightly regulated at the tissue/organ level and that mainly developmental signals control carotenoid accumulation in nonphotosynthetic tissues.

Adventitious shoot regeneration from leaf explants of Gypsophila paniculata L.

Adventitious shoots were successfully regenerated from leaf explants of Gypsophila paniculata L. The efficiency of shoot regeneration for cv. Arbel was tested on 18 media based on Murashige and Skoog basal medium containing different concentrations of thidiazuron or 6-benzylaminopurine in combination with naphthaleneacetic acid. Both explant age and that of the cuttings used as leaf donors affected the regeneration efficiency. The highest efficiency of adventitious shoot regeneration was obtained with the oldest leaves originating from the youngest cutting analyzed; on thidiazuron-containing medium, shoots regenerated on average from 67% of the leaves, with an average of seven shoots per explant. This regeneration procedure was suitable for all six commercial cultivars studied. Regenerated shoots elongated, rooted and successfully acclimatized to the greenhouse where they were grown to flowering.

Molecular cloning of a carotenoid-associated protein from Cucumis sativus corollas: homologous genes involved in carotenoid sequestration in chromoplasts.

Chromoplasts are carotenoid-accumulating plastids found in the corollas and fruits of many higher plants. In most cases, the pigment in these plastids is accumulated with the aid of carotenoid-associated proteins located within unique structures. This paper reports the isolation and characterization of the cDNA (CHRC) from Cucumis sativus corollas which encodes the chromoplast-specific carotenoid-associated protein CHRC. The transit peptide cleavage site was determined and, using a chloroplast uptake system, it is shown that CHRC can be post-translationally targeted to these plastids where it is peripherally associated with thylakoids. Analysis of CHRC transcript level in Cucumis sativus revealed its temporal and tissue-specific regulation: the transcript was detected only in corollas, where its level increased in parallel to flower development, peaking just before anthesis. CHRC shares significant homology (59%) with the gene coding for fibrillin-a protein in Capsicum annuum red fruits whose function is essentially identical to that of CHRC. A CHRC fragment including the potential active site of the protein was used as a probe in Northern blot analyses of floral and fruit tissues from various plants containing chromoplasts of different types: CHRC homologs of similar sizes were revealed in all cases. The existence of a group of homologous genes coding for chromoplast-specific proteins which aid in the sequestration of carotenoids within specific structures is proposed.

Highly efficient transformation and regeneration of aspen plants through shoot-bud formation in root culture.

The natural capacity of aspen (Populus tremula L.) roots for direct shoot-bud regeneration was harnessed to establish a highly efficient transformation and regeneration procedure that does not require a pre-selection stage on antibiotics. Aspen stem segments were transformed using wildtype Agrobacterium rhizogenes (LBA9402) with the binary p35SGUSINT plasmid carrying the genes coding for ß-glucuronidase (GUS) and neomycin phosphotransferase II. High levels of transient GUS expression were found in the basal cut surface of 87% of the segments, and 98% of these formed well-developed adventitious roots. Proliferating root cultures were established in liquid culture, and GUS expression was found in 75% of the roots. Shoot-bud regeneration in root cultures was very high: 99% of the roots yielded shoot-buds (4.3 buds per root), of which 91% expressed GUS. Southern blot analysis and polymerase chain reaction confirmed the transgenic nature of the plants expressing GUS. Kanamycin resistance of transformants was tested with respect to callus growth and bud regeneration. Callus from transgenic plants exhibited a high growth rate in the presence of up to 100 µg/µl kanamycin, and bud regeneration from transformed roots occurred in the presence of up to 30 µg/µl kanamycin. Callus and buds from control (non-transformed) plants failed to proliferate or regenerate, respectively, in the presence of kanamycin at concentrations above 10 µg/µl. Ninety-four independent clones from different transformation events were established, of which 52 were phenotypically true-to-type.

Agrobacterium rhizogenes-mediated DNA transfer inPinus halepensis Mill.

Agrobacterium rhizogenes strain LBA9402 was used to transformPinus halepensis embryos, seedlings and shoots. Mature embryos exhibited susceptibility to the agrobacterium as monitored by ß-glucurortidase (GUS) expression, with more than 85% showing considerable transient GUS expression in the radicle. GUS expression was also observed in cotyledons, but at a lower rate of about 24% of the embryos (1-5 spots/embryo). Stable transformation was evidenced by the regeneration of GUS-expressing roots and calli from infectedP. halepensis seedlings. Inoculum injections into intact seedling hypocotyls induced callus and root formation at the wound sites in 64% of the seedlings. Dipping seedling cuttings in a bacterial suspension resulted in adventitious root formation in 7I% of the seedling cuttings, all of which expressed GUS activity. Adventitious shoots, that were induced on 2.5-year-old seedlings by pruning and spraying with 6-benzylaminopurine, were infected by injecting of bacterial suspension into their basal side. Two months later, adventitious roots and root primordia regenerated in 74% and 40% of 2- and 5-month-old shoots, respectively. Non-transformed shoots, either without or with auxin application, failed to form roots. Polymerase chain reaction and Southern blot analyses confirmed theuidA-transgenic nature of the root and callus, as well as the presence ofrolC androlB genes in roots from infectedP. halepensis seedlings.

Chromoplast Biogenesis in Cucumis sativus Corollas (Rapid Effect of Gibberellin A3 on the Accumulation of a Chromoplast-Specific Carotenoid-Associated Protein).

The development of cucumber (Cucumis sativus L.) corollas is accompanied by the accumulation of chromoplasts. In mature corollas, chromoplasts, but no chloroplasts, were detected by electron microscopy. Chlorophyll was also undetectable in corollas at anthesis. The contents of carotenoids and a carotenoid-associated, chromoplast-specific, 35-kD protein in corollas increased in parallel with flower development, peaking concomitantly at anthesis. The involvement of phytohormones and light in the regulation of their expression was studied. When gibberellin A3 (GA3) was added to an in vitro bud culture system, accumulation of both carotenoids and the 35-kD protein was markedly enhanced. The specific up-regulation of the 35-kD protein was very rapid: after only 2 h of culture, increased levels were detected in GA3-treated versus untreated corollas. During this period, corolla fresh weight and total protein and carotenoid contents remained unchanged. Inclusion of abscisic acid in the culture medium counteracted the effect of GA3. Accumulation of the 35-kD protein was also enhanced when flower buds on plants were sprayed with GA3 or etiolated.

Isolation and Characterization of a Chromoplast-Specific Carotenoid-Associated Protein from Cucumis sativus Corollas.

The differentiation of chloroplasts to chromoplasts in corollas of cucumber (Cucumis sativus) is subject to developmental control. To study factors involved in the chloroplast-chromoplast conversion, a chromoplast-specific protein of 35 kD was isolated, and polyclonal antibodies were prepared against it. This protein was found to be a principal component of the carotenoid-protein complex resolved from chromoplast membranes by nondenaturing gel electrophoresis. Immunological studies revealed that expression of this protein is regulated in a temporal and tissue-specific manner. Its steady-state level increased in parallel with flower development and carotenoid accumulation, peaking in mature flowers and then rapidly decreasing to very low levels. The protein was not detectable in cucumber leaves or fruits. To ascertain whether an organ-specific system regulates the chloroplast-chromoplast conversion and to enable future molecular studies of factors involved in this regulation, an in vitro bud culture system was established. Patterns of expression of the 35-kD protein and carotenoids in corollas of detached buds were similar to those in intact buds.

Expression of plant genes in transfected mammalian cells: accumulation of recombinant preLHCIIb proteins within cytoplasmic inclusion bodies.

Transfection of the monkey COS-7 cells with an expression vector bearing the Lemma gibba LHCIIb AB30 or AB19 genes led to the synthesis of the LHCIIb polypeptide precursors (preLHCIIb). This was inferred mainly from Western blot analysis which has revealed the appearance of a single immunoprecipitation band following the use of three different preparations of anti-LHCIIb antibodies. Synthesis of the precursor polypeptides, not the mature processed LHCIIb protein, was evident from the molecular weight of the newly synthesized protein, inferred from its position in the gel. Expression of the AB30 and AB19 genes was also evident from the appearance of specific transcripts only in transfected cells. Immunofluorescence observations revealed the appearance of distinct fluorescent spots in about 1-2% of the transfected cells. The same was observed following immunogold staining and electron microscopy studies, which revealed a specific association of gold particles with amorphous structures only in transfected cells. The preLHCIIb synthesized by transfected COS-7 cells was insoluble in a variety of detergents and could be solubilized only by 8 M urea or 0.1 N NaOH. These properties are characteristic of proteins accumulating within inclusion bodies of prokaryotes.

Correlation of some published amino acid sequences for photosystem I polypeptides to a 17 kDa LHCI pigment-protein and to subunits III and IV of the core complex.

Photosystem I (PSI) in barley consists of at least 11 polypeptides of which three have apparent sizes of 15-19 kDa. Two of these polypeptides (subunits III and IV) are constituents of the core complex (CCI), the third is a component of the light-harvesting complex (LHCI). After fractionation of PSI into its CCI and LHCI components, each of the polypeptides has been isolated and its N-terminal region sequenced. We conclude that the gene sequence published for subunit IV of spinach [(1988) FEBS Lett. 237, 108-112] is not that of subunit IV but rather that of the 17 kDA LHCIc pigment protein. We confirm that the published sequence for subunit III [(1988) Curr. Genet. 14, 511-518] is indeed that of subunit III; seemingly conflicting identifications, based on apparent sizes on SDS-PAGE, of which polypeptides are subunits III and IV are probably explained by subunit III's electrophoretic migration rate being dependent on the solvent.

Light-harvesting pigment-proteins of photosystem I in maize. Subunit composition and biogenesis.

Three different pigment-binding proteins of the light-harvesting complex (LHC I) of maize photosystem I (PS I) have been isolated. Absorption and fluorescence excitation spectral analyses showed that each pigment-protein can transfer absorbed energy from its carotenoid and/or chlorophyll b components to chlorophyll alpha. Their apoproteins with apparent sizes of 24 (LHC Ia), 21 (LHC Ib), and 17 (LHC Ic) kDa have been purified to homogeneity. Differences in their pigment and amino acid compositions and in their reactions with antibodies demonstrate that the two smaller pigment-proteins are not proteolytically derived from the largest one. LHC Ib's apoprotein is particularly enriched in cysteine residues. None of the three apoproteins cross-reacted with antibodies raised against the major light-harvesting chlorophyll a/b-protein of photosystem II (LHC IIb) or against the PS I core complex (CC I) subunits. Studies of the biogenesis of PS I during greening of etiolated plants showed that all of the CC I subunits accumulated to a detectable level prior to the appearance of the 17-kDa subunit of LHC I, the accumulation of which preceded those of the 24- and 21-kDa subunits of LHC I. In addition, subunit VI of CC I is shown to be differentially expressed in mesophyll and bundle sheath cells; a slightly larger form of it accumulates in mesophyll than in bundle sheath thylakoids during plastid development.

Expression of the Major Light-Harvesting Chlorophyll a/b-Protein and Its Import into Thylakoids of Mesophyll and Bundle Sheath Chloroplasts of Maize.

Distribution of the major light-harvesting chlorophyll a/b-protein (LHCII) and its mRNA within bundle sheath and mesophyll cells of maize (Zea mays L.) was studied using in situ immunolocalization and hybridization, respectively. In situ hybridization with specific LHCII RNA probes from maize and Lemna gibba definitively shows the presence of high levels of mRNA for LHCII in both bundle sheath cells and mesophyll cells. In situ immuno-localization studies, using an LHCII monoclonal antibody, demonstrate the presence of LHCII polypeptides in chloroplasts of both cell types. The polypeptide composition of LHCII and the amount of LHCII in bundle sheath cells are different from those in mesophyll cells. Both mesophyll and bundle sheath chloroplasts can take up, import and process the in vitro transcribed and translated LHCII precursor protein from L. gibba. Although bundle sheath chloroplasts incorporate LHCII into the pigmented light-harvesting complex, the efficiency is lower than that in mesophyll chloroplasts.