Unadapted and adapted to starvation Acholeplasma laidlawii cells induce different responses of Oryza sativa, as determined by proteome analysis

For the first time, we studied the phytopathogenicity toward Oryza sativa L. of unadapted and adapted to unfavorable environment (starvation) cells of Acholeplasma laidlawii PG8--ubiquitous mycoplasma found in the soil, waste waters, tissues of the highest eukaryotes and being the basic contaminant of cell cultures and a causative agent of phytomycoplasmoses. The features of morphology, ultrastructural organization and proteomes of unadapted and adapted cells of the mycoplasma and infected plants were presented. Using 2D-DIGE and MS, 43 proteins of O. sativa L. that were differentially expressed in the leaves of plants cultivated in media with A. laidlawii PG8 were identified. The qualitative and quantitative responses of the plant proteome toward adapted and unadapted mycoplasma cells differed. That may be explained by differences in the virulence of the corresponding bacterial cells. Using 2D-DIGE and MS, 82 proteins that were differentially expressed in adapted and unadapted mycoplasma cells were detected. In adapted cells of the mycoplasma, in comparison with unadapted ones, a significant increase in the expression of PNPase--a global regulator of virulence in phytopathogenic bacteria occurred; there was also decreased expression of 40 proteins including 14 involved in bacterial virulence and the expression of 31 proteins including 5 involved in virulence was not detected. We propose that differences in the phytopathogenicity of adapted and unadapted A. laidlawii PG8 cells may be related to features of their proteomes and membrane vesicles.     

DNA base changes induced following in vivo exposure of unadapted, adapted or ada- Escherichia coli to N-methyl-N'-nitro-N-nitrosoguanidine

The adaptive response is one of the major repair pathways in Escherichia coli that removes DNA alkylation damage. To investigate the role of the adaptive response in mutagenesis, the E. coli gpt forward mutation assay system was used to determine the mutation spectrum of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) in MNNG-adapted and unadapted GP120 (wild-type) and unadapted PJ5 (ada-5) cells. We observed that 34/37 mutations in the unadapted GP120 cells, 38/40 mutations in the adapted GP120 cells, and 10/10 mutations in the PJ5 cells were GC----AT transitions. The remaining 3/37 mutations in the unadapted GP120 cells were large insertions. The remaining 2/40 mutations in the adapted GP120 cells were transversions with one a GC----CG and the other an AT----CG. A surrounding sequence specificity of mutagenesis was observed for the GC----AT transitions in both the unadapted (GP120 and PJ5) and adapted (GP120) cells, with 70% of the unadapted PJ5, 68% of the unadapted GP120, and 61% of the adapted GP120 mutations occurring at the middle G of the sequence 5'--GG(A or T)--3'. Both strains also displayed a statistically significant preference for mutagenesis at guanine bases in the non-transcribed strand. The overall distribution of mutated sites in the gpt gene in adapted and unadapted cells was similar, although the rate of mutations at certain sites appeared different. These minor differences could result from either non-uniform repair of alkylation damage at different sites on the DNA, or altered processing of the alkylated bases to mutations in the adapted state.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enhanced H Transport Capacity and ATP Hydrolysis Activity of the Tonoplast H-ATPase after NaCl Adaptation

Tonoplast enriched membrane vesicle fractions were isolated from unadapted and NaCl (428 millimolar) adapted tobacco cells (Nicotiana tabacum L. var Wisconsin 38). Polypeptides from the tonoplast enriched vesicle fractions were separated by SDS-PAGE and analyzed by Western blots using polyclonal antibodies to the 70 kilodalton subunit of the red beet tonoplast H⁺-ATPase. These antibodies cross-reacted exclusively to a tobacco polypeptide of an apparent molecular weight of 69 kilodaltons. The antibodies inhibited ATP-dependent, NO₃⁻ sensitive H⁺ transport into vesicles in tonoplast enriched membrane fractions from both unadapted and NaCl adapted cells. The relative H⁺ transport capacity per unit of 69 kilodalton subunit of the tonoplast ATPase of vesicles from NaCl adapted cells was fourfold greater than that observed for vesicles from unadapted cells. The increase in specific H⁺ transport capacity after adaptation was also observed for ATP hydrolysis.     

Induction of the heat shock regulon of Escherichia coli markedly increases production of bacterial viruses at high temperatures.

Production of bacteriophages T2, T4, and T6 at 42.8 to 44 degrees C was increased from 8- to 260-fold by adapting the Escherichia coli host (grown at 30 degrees C) to growth at the high temperature for 8 min before infection; this increase was abolished if the host htpR (rpoH) gene was inactive. Others have shown that the htpR protein increases or activates the synthesis of at least 17 E. coli heat shock proteins upon raising the growth temperature above a certain level. At 43.8 to 44 degrees C in T4-infected, unadapted cells, the rates of RNA, DNA, and protein synthesis were about 100, 70, and 70%, respectively, of those in T4-infected, adapted cells. Production of the major processed capsid protein, gp23, was reduced significantly more than that of most other T4 proteins in unadapted cells relative to adapted cells. Only 4.6% of the T4 DNA made in unadapted cells was resistant to micrococcal nuclease, versus 50% in adapted cells. Thus, defective maturation of T4 heads appears to explain the failure of phage production in unadapted cells. Overproduction of the heat shock protein GroEL from plasmids restored T4 production in unadapted cells to about 50% of that seen in adapted cells. T4-infected, adapted E. coli B at around 44 degrees C exhibited a partial tryptophan deficiency; this correlated with reduced uptake of uracil that is probably caused by partial induction of stringency. Production of bacteriophage T7 at 44 degrees C was increased two- to fourfold by adapting the host to 44 degrees C before infection; evidence against involvement of the htpR (rpoH) gene is presented. This work and recent work with bacteriophage lambda (C. Waghorne and C.R. Fuerst, Virology 141:51-64, 1985) appear to represent the first demonstrations for any virus that expression of the heat shock regulon of a host is necessary for virus production at high temperature.     

Changes in pectin structure and localization during the growth of unadapted and NaCl-adapted tobacco cells

Tobacco cells adapted to grow in high concentrations of NaCl exhibit a drastically altered growth physiology that results in cells whose fully expanded volume is only one-fifth to one-eighth those of unadapted cells. Comparison between NaCl-adapted and unadapted tobacco cells provides an opportunity to evaluate current concepts of the structural and mechanical determinants of cell wall expansion. Both biochemical studies of pectic polymers and the ultrastructural localization of pectic epitopes at three specific phases of cell culture, maximal cell division, maximal elongation, and stationary phase are reported here. One-half of the galactosyluronic acid units in wall polymers of NaCl-adapted cells are esterified throughout the culture period, while wall polymers of unadapted cells show a rise in esterified polygalacturonic acid from 50 to 80% during elongation and then a decrease to 70% at stationary phase. Methyl esters account for only a proportion of the total esterified polygalacturonic acid at any stage in both unadapted and NaCl-adapted cell walls. Using monoclonal antibodies, we show differences in the localization of relatively methyl-esterified and unesterified pectic epitopes at different stages of growth and corroborate the chemical determinations. Fourier transform infrared (FTIR) microspectroscopy of representative walls of both NaCl-adapted and unadapted cells confirms, at the single cell wall level, that results obtained from chemical analysis of bulk samples are applicable to the entire cell population. FTIR microspectroscopy also reveals an increase in wall protein in the walls of adapted cells. Images obtained by the fast-freeze, deep-etch, rotary-shadowed replica technique show clearly different cell wall architectures in NaCl-adapted compared with unadapted cells; walls of elongating unadapted cells contain long, thin fibres that show a net orientation with respect to the long axis of the cell, whereas walls of adapted cells have thicker, flatter bundles of fibres with no clear net orientation. Polarized FTIR microspectroscopy indicates that, in unadapted tobacco cells during elongation, pectin molecules may be oriented within the wall in a similar manner to cellulose. Possible ways in which pectin structure and conformation may affect the behaviour of the cellulose-xyloglucan network are discussed.     

Long-term Adaptation to Fatty Acids by the Phytoflagellate, Polytoma uvella

SUMMARY. The adaptation to fatty acids by Polytoma depends upon two mechanisms: 1. The induced synthesis of fatty acid oxidase which precedes growth. 2. A long-term physiological adaptation spanning several cell generations which results in an increase of the initial rate of growth.
Analysis of the long-term adaptation shows that the adaptation does not result from the selection of fast-growing mutants. The generation time on butyrate of unadapted cells is initially ca. 24 hours and it is reduced to ca. 10 hours after the second subculture in butyrate medium. Adaptation to butyrate results in a simultaneous adaptation to caproate.     

Molecular Cloning of Osmotin and Regulation of Its Expression by ABA and Adaptation to Low Water Potential

In response to adaptation to NaCl, cultured tobacco cells (Nicotiana tabacum L. cv Wisconsin 38) synthesize a major 26 kilodalton protein which has been named osmotin due to its induction by low water potentials. To help characterize the expression of osmotin in adapted cells, a cDNA clone for osmotin has been isolated. Abscisic acid induces messenger RNA encoding osmotin. Levels of this mRNA in adapted cells are approximately 15-fold higher than in unadapted cells. Message for osmotin is present at constant levels through the growth cycle of adapted cells, while in unadapted cells, the level decreases during exponential phase of growth and increases again when the cells approach stationary phase. While abscisic acid induces the message for osmotin, a low water potential environment appears to be required for accumulation of the protein. An osmotic shock to unadapted cells does not increase the amount of message or protein present most likely because this treatment does not induce immediately the accumulation of abscisic acid. The increased expression of osmotin in adapted cells is not correlated with an increase in osmotin gene copy number. Osmotin is homologous to a 24 kilodalton NaCl-induced protein in tomato, as well as thaumatin, maize α-amylase/trypsin inhibitor and a tobacco mosaic virus-induced pathogenesis-related protein.     

Enrichment of vitronectin- and fibronectin-like proteins in NaCl-adapted plant cells and evidence for their involvement in plasma membrane–cell wall adhesion

Cells of tobacco adapted to grow in high concentrations of NaCl develop tight zones of adhesion between the plasma membrane and cell wall, revealed by concave plasmolysis in osmotic solutions. Unadapted cells exhibit mostly convex plasmolysis and exhibit little or no adhesive character. Wall-less protoplasts isolated from the adapted cells retain the complementary adhesive character and adhere tightly to each other, whereas protoplasts from unadapted cells do not. The hexapeptide gly- arg-gly-asp -ser-pro, in which the arg-gly-asp represents the integrin-binding domain of several animal extracellular matrix proteins, specifically blocks adhesion of the protoplasts. A control hexapeptide, gly-arg-gly-glu-ser-pro, is ineffective in blocking adhesion. Tobacco proteins immunologically related to human vitronectin were found in cell walls and membranes of unadapted and NaCl-adapted cells, but the total extractable vitronectin-like protein was enriched in the adapted cells. Tobacco proteins immunologically related to human fibronectin were found in membranes and cell walls of NaCl-adapted cells but not in those from unadapted cells. Our observations indicate that plant cells possess cell-matrix adhesion complexes similar to animal cells, and these adhesion complexes accumulate in growth-limited cells adapted to saline stress.     

Adaptation of Tobacco Cells to NaCl

Cell lines of tobacco (Nicotiana tabacum L. var Wisconsin 38) were obtained which are adapted to grow in media with varying concentrations of NaCl, up to 35 grams per liter (599 millimolar). Salt-adapted cells exhibited enhanced abilities to gain both fresh and dry weight in the presence of NaCl compared to cells which were growing in medium without NaCl (unadapted cells). Tolerance of unadapted cells and cells adapted to 10 grams per liter NaCl was influenced by the stage of growth, with the highest degree of tolerance exhibited by cells in the exponential phase. Cell osmotic potential and turgor varied through the growth cycle of unadapted cells and cells at all levels of adaptation, with maximum turgor occurring at approximately the onset of exponential fresh weight accumulation.

Adaptation to NaCl led to reduced cell expansion and fresh weight gain, while dry weight gain remained unaffected. This reduction in cell expansion was not due to failure of the cells to maintain turgor since cells adapted to NaCl underwent osmotic adjustment in excess of the change in water potential caused by the addition of NaCl to the medium. Tolerance of the adapted cells, as indicated by fresh or dry weight gain, did not increase proportionately with the increase in turgor. Adaptation of these glycophytic cells to NaCl appears to involve mechanisms which result in an altered relationship between turgor and cell expansion.

     

Carbon Use Efficiency and Cell Expansion of NaCl-Adapted Tobacco Cells

Carbon use efficiencies (gram cell organic dry weight accumulated per gram sugar assimilated from the medium) of unadapted and NaCl-adapted (428 millimolar) cells of tobacco (Nicotiana tabacum L. var Wisconsin 38) were determined to evaluate metabolic costs associated with growth and survival in a saline environment. No net increase in carbon costs was associated with salt adaptation. At low substrate levels, carbon use efficiencies of unadapted and NaCl-adapted cells were not appreciably different (0.495 and 0.422, respectively) and at higher substrate levels carbon use efficiency of NaCl-adapted cells was clearly higher than that of unadapted cells. These results indicate that a homeostasis of metabolic efficiency is established after cells have adapted to NaCl. Altered carbon availability does not cause the reduced cell volume that results from adaptation to NaCl. This does not preclude, however, the possibility that altered intracellular partitioning of carbon affects cell expansion.