Molecular characterization of glyoxalase-I from a higher plant; upregulation by stress

A cDNA, GLX1, encoding glyoxalase-I was isolated by differential screening of salt-induced genes in tomato. Glyoxalases-I and -II are ubiquitous enzymes whose functions are not clearly understood. They may serve to detoxify methylglyoxal produced from triosephosphates in all cells. The protein encoded by GLX1 shared 49.4% and 58.5% identity with glyoxalase-I isolated from bacteria and human, respectively. Furthermore, yeast cells expressing GLX1 showed a glyoxalase-I specific activity 20-fold higher than non-transformed cells. Both GLX1 mRNA and glyoxalase-I polypeptide levels increased 2- to 3-fold in roots, stems and leaves of plants treated with either NaCl, mannitol, or abscisic acid. Immunohistochemical localization indicated that glyoxalase-I was expressed in all cell types, with preferential accumulation in phloem sieve elements. This expression pattern was not appreciably altered by salt-stress. We suggest that the increased expression of glyoxalase-I may be linked to a higher demand for ATP generation and to enhanced glycolysis in salt-stressed plants.

Differential accumulation of S-adenosylmethionine synthetase transcripts in response to salt stress

NaCl stress causes the accumulation of several mRNAs in tomato seedlings. An upregulated cDNA clone, SAM1, was found to encode a S-adenosyl-L-methionine synthetase enzyme (AdoMet synthetase). Expression of the cDNA SAM1 in a yeast mutant lacking functional SAM genes resulted in high AdoMet synthetase activity and AdoMet accumulation. We show that tomato plants contain at least four SAM isogenes. Clones corresponding to isogenes SAM2 and SAM3 have also been isolated and sequenced. They encode predicted polypeptides 95% and 92% identical, respectively, to the SAM1-encoded AdoMet Synthetase. RNA hybridization analysis showed a differential response of SAM genes to salt and other stress treatments. SAM1 and SAM3 mRNAs accumulated in the root in response to NaCl, mannitol or ABA treatments. SAM1 mRNA accumulated also in leaf tissue. These increases of mRNA level were apparent as soon as 8 h after the initiation of the salt treatment and were maintained for at least 3 days. A possible role for AdoMet synthetases in the adaptation to salt stress is discussed.

The protein phosphatase calcineurin is essential for NaCl tolerance of Saccharomyces cerevisiae

NaCl-sensitive yeast mutants were isolated to identify genes essential for NaCl tolerance. Complementation of a mutant highly sensitive to Na+ and Li+ led to the isolation of the CNB1 gene. This gene encodes the regulatory subunit (CNB) of the Ca2+/calmodulin-dependent protein phosphatase calcineurin. Cells deficient in CNB accumulated Li+ due to reduced expression of ENA1, a gene encoding a P-type ATPase involved in Na+ and Li+ efflux. In addition, the K+ transport system of cnb1 delta cells was not converted to the high affinity state that facilitates better discrimination of K+ over Na+. Thus the cnb1 delta strain resembled a trk1 mutant. These results indicate that adaptation to NaCl stress in Saccharomyces cerevisiae requires a signal transduction pathway involving Ca2+ and protein phosphorylation-dephosphorylation. In this pathway, calcineurin would coordinate gene expression and activity of ion transporters to facilitate ion homeostasis.

Immunocytolocalization of Plasma Membrane H-ATPase

The localization of plasma membrane H(+)-ATPase has been studied at the optical microscope level utilizing frozen and paraffin sections of Avena sativa and Pisum sativum, specific anti-ATPase polyclonal antibody, and second antibody coupled to alkaline phosphatase. In leaves and stems the ATPase is concentrated at the phloem, supporting the notion that it generates the driving force for phloem loading. In roots the ATPase is concentrated at both the periphery (rootcap and epidermis) and at the central cylinder, including endodermis and vascular cells. This supports a ;two-pump' mechanism for ion absorption, involving active uptake at the epidermis, symplast transport across the cortex, and active efflux at the xylem. The low ATPase content of root meristem and elongation zone may explain the observed transorgan H(+) currents, which leave nongrowing parts and enter growing tips.

Structure of a plasma membrane H+-ATPase gene from the plant Arabidopsis thaliana

Physiological and biochemical studies have suggested that the plant plasma membrane H+-ATPase controls many important aspects of plant physiology, including growth, development, nutrient transport, and stomata movements. We have started the genetic analysis of this enzyme by isolating both genomic and cDNA clones of an H+-ATPase gene from Arabidopsis thaliana. The cloned gene is interrupted by 15 introns, and there is partial conservation of exon boundaries with respect to animal (Na+/K+)- and Ca2+-ATPases. In general, the relationship between exons and the predicted secondary and transmembrane structure of different ATPases with phosphorylated intermediate support a somewhat degenerate correspondence between exons and structural modules. The predicted amino acid sequence of the plant H+-ATPase is more closely related to fungal and protozoan H+-ATPases than to bacterial K+-ATPases or to animal (Na+/K+)-, (H+/K+)-, and Ca2+-ATPases. There is evidence for the existence of at least three isoforms of the plant H+-ATPase gene. These results open the way for a molecular approach to the structure and function of the plant proton pump.

Biochemical characterization of two cloned resistance determinants encoding a paromomycin acetyltransferase and a paromomycin phosphotransferase from Streptomyces rimosus forma paromomycinus

The mechanism conferring resistance to paromomycin in Streptomyces rimosus forma paromomycinus, the producing organism, was studied at the level of both protein synthesis and drug-inactivating enzymes. Ribosomes prepared from this organism grown in either production or nonproduction medium were fully sensitive to paromomycin. A paromomycin acetyltransferase and a paromomycin phosphotransferase, both characteristic of the producer, were highly purified from extracts prepared from two Streptomyces lividans transformants harboring the relevant genes inserted in pIJ702-derived plasmids. In vitro, paromomycin was inactivated by either activity. In vivo, however, S. lividans clones containing the gene for either enzyme inserted in the low-copy-number plasmid pIJ41 were resistant to only low levels of paromomycin. In contrast, an S. lividans transformant containing both genes inserted in the same pIJ41-derived plasmid displayed high levels of resistance to paromomycin. These results indicate that both genes are required to determine the high levels of resistance to this drug in the producing organism. Paromomycin is doubly modified by the enzymes. However, whereas acetylparomomycin was a poorer substrate than paromomycin for the phosphotransferase, phosphorylparomomycin was modified more actively than was the intact drug by the acetyltransferase. These findings are discussed in terms of both a permeability barrier to paromomycin and the possible role(s) of the two enzymes in the biosynthetic pathway of this antibiotic.

Similar short elements in the 5' regions of the STA2 and SGA genes from Saccharomyces cerevisiae

The 5' region of the SGA and STA2 genes, encoding the intra- and extracellular glucoamylases, respectively, from Saccharomyces cerevisiae have been sequenced. In addition, the transcription initiation sites have been determined. Four distinct short elements (named I to IV) were found in both genes. Element III has the consensus sequence PuCATTTAPiG with a bilateral symmetry around the central T, and is present in both genes as a direct repeat. This motive seems responsible for the coregulation of STA2 and SGA by the repressor STA10 gene of S. cerevisiae.

Purification and characterization of a hygromycin B phosphotransferase from Streptomyces hygroscopicus

A hygromycin B phosphotransferase activity from Streptomyces hygroscopicus has been highly purified by ammonium sulphate fractionation followed by affinity column chromatography through Sepharose-6B-hygromycin-B. The combined active fractions showed a single protein band (41 kDa) when subjected to polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. When gel electrophoresis was performed under non-denaturing conditions, the single protein band promoted in situ phosphorylation of hygromycin B, indicating that this protein corresponded to the purified hygromycin B phosphotransferase. The enzyme has been purified 236-fold and approximate Km values of 0.56 microM for hygromycin B and ATP, respectively, were deduced.

Virilization of a female infant due to an adrenal tumor

We report here the case of a 22-month-old girl with virilization due to a potentially malignant adrenal tumor. She presented with clitoromegaly and growth of pubic hair, first noticed at birth. The clinical picture, hormonal profile, and pathologic findings are described. The practical aspects of the differential diagnosis and treatment are illustrated.

Cloning of the STA2 and SGA genes encoding glucoamylases in yeasts and regulation of their expression by the STA10 gene of Saccharomyces cerevisiae

The Saccharomyces STA2 and SGA genes, encoding the extracellular and intracellular sporulation-specific glucoamylase respectively, have been cloned and their transcription and regulation studied. The STA2 gene differs from the SGA gene in that it contains an extra piece of DNA, which encodes the domain for exportation of the extracellular glucoamylase. The STA2 gene produces a single 2.85 kb transcript. Transcription of the SGA gene is initiated from two different sites, yielding two transcripts of 1.95 and 2.40 kb. Transcription of both STA2 and SGA genes is repressed by the STA10 gene of Saccharomyces cerevisiae.

Biochemical basis of resistance to hygromycin B in Streptomyces hygroscopicus--the producing organism

Hygromycin B, an aminocyclitol antibiotic that strongly inhibits both 70S and 80S ribosomes, is synthesized by Streptomyces hygroscopicus. Ribosomes from this Gram-positive mycelial bacterium are inhibited in vitro by the antibiotic. In contrast, the streptomycete is highly resistant to the drug in vivo since it possesses hygromycin B phosphotransferase activity. This enzyme has been shown by gel filtration to have a molecular weight of 42000, and to modify its antibiotic substrate to produce 7"-O-phosphoryl-hygromycin B which totally lacks biological activity both in vivo and in vitro.