Electrophoretic and immunological studies on ribosomal proteins of 100 Escherichia coli revertants from streptomycin dependence

Summary Revertants from streptomycin dependence to independence were isolated as single step mutants from six different streptomycin dependent strains. The ribosomal proteins from 100 such mutants were analyzed by two-dimensional polyacrylamide gel electrophoresis and some of them were also examined by immunological techniques. Altered proteins were found in 40 mutants, 24 in protein S4 and 16 in protein S5. No change in any other protein was detected.Altered S5 proteins migrated into five different positions on the polyacrylamide plate and it can be concluded that the mutant proteins differ from the wild type probably by single amino acid replacements. The altered S4 proteins migrated into 17 different positions on the plate. Extensive changes of length, both shorter and longer than wild type S4 protein, are postulated for many of the mutant S4 proteins.Analysis of the ribosomal proteins of four ram mutants revealed altered S4 protein in two of them. The alterations in these mutant proteins are probably very similar to those found in streptomycin independent mutants.Among the revertants there was no apparent correlation between the protein alteration and the particular response to streptomycin.These studies suggest a strong interaction between protein S12, which confers streptomycin dependence, and protein S4 or S5, which can suppress this dependence.Paper No. 60 on Ribosomal Proteins. Preceding paper is by B. Wittmann-Liebold, Hoppe-Seyler's Z. physiol. Chemie, in press.     

At least seven ribosomal proteins are involved in the control of translational accuracy in a eukaryotic organism

In the filamentous fungus Podospora anserina, ribosomal proteins of 60 mutants impaired in the control of translational fidelity have been submitted to electrophoretic analysis. The "four corners" system combining four different two-dimensional polyacrylamide gel electrophoretic systems has been used. An altered electrophoretic pattern has been observed for 12 mutants. In mutants su3, su12 and su11 (decreased translational fidelity), proteins S1, S7 and S8, respectively, are altered. For AS mutants (increased translational fidelity), proteins S9, S12 and S19, respectively, are altered in AS9, AS1 and AS6 mutants, and protein S29 is lacking in AS3 mutants. The data suggest that five of these genes (at least) are the structural genes for the relevant proteins (su3:S1, su12:S7, AS1:S12, AS6:S19, AS9:S9), while the AS3 gene may code for a modifying enzyme.     

An improved method for two-dimensional gel-electrophoresis: Analysis of mutationally altered ribosomal proteins of Escherichia coli

Summary An improved method for the two-dimensional electrophoretic analysis of ribosomal proteins on acrylamide gel slabs has been developed by combining the procedures for the first dimension of Mets and Bogorad (1974) and for the second dimension of Kaltschmidt and Wittmann (1970) and by introducing several modification. Ribosomal proteins of various Escherichia coli mutants have been analyzed by the new method. Advantages are that (1) it requires only small amounts of protein (100–200 g 70S ribosomal proteins), (2) reproducibility is very high, and (3) it makes it easier to identify mutational alterations in proteins S10, L4, L10, and L21 which hardly migrate out of the sample gel with our previous electrophoresis procedure. Furthermore, the new method can be nicely adapted to analysis of the ribosomal proteins from other organisms, such as Bacilli or yeast.     

Properties of the interaction of ribosomal protein S4 and 16S RNA in Escherichia coli revertants from Streptomycin dependence to independence

Summary The binding properties of altered S4 proteins from E. coli revertants from streptomycin dependence to independence were investigated. Three of the proteins with the same length as the wild type protein, from mutants N424, N428 and N430, exhibited unchanged binding and conformational properties. However, three proteins with an altered length, from mutants N422, N425 and N433, bound more weakly to the 16S RNA, and their conformations were different from that of the wild type S4 protein. In the presence of the other 16S RNA binding proteins, no stimulation of the binding of the latter three proteins could be detected.Paper No. 40 on Ribosomal Proteins. Preceding paper is in press in Molec. gen. Genetics (1972).     

Quinacrine-induced dilation of the rat cecum and degeneration of large granular vesicle-containing neurons in the myenteric plexus

Summary An electrophoretic analysis of the microtubule-containing transport channels, known as nutritive tubes, which link the nutritive cells with the chain of developing oocytes in the telotrophic ovarioles of the hemipteran Notonecta glauca, has been carried out. The major polypeptide components resolved have been identified tentatively as -and -tubulin subunits by their comparable electrophoretic mobility to tubulin subunits from purified mammalian brain microtubule protein. Co-migration of some of the minor components with proteins resolved from insect ribosomes (which are the only other components of the nutritive tubes as seen in ultrastructural studies) indicates that these may be ribosomal proteins. Also characterized by electrophoresis were the nutritive cells, which are the source of synthesis of the components transported via the nutritive tubes, and the oocytes, the sites of their accumulation.     

The herbicide-resistant D1 mutant L275F of Chlamydomonas reinhardtii fails to show the bicarbonate-reversible formate effect on chlorophyll a fluorescence transients

Herbicide-resistant mutants of the eukaryotic green alga Chlamydomonas reinhardtii, that are altered in specific amino acids in their D-1 protein, show differential bicarbonate-reversible formate effects. These results suggest the involvement of D1 protein in the bicarbonate effect. A 25 mM formate treatment of mixotrophically or photoautotrophically grown wild type cells results in a slower rise of chlorophyll a fluorescence transient followed by a dramatically slowed decline during measurements in continuous light. These effects are fully reversed upon addition of 10 mM bicarbonate. The mutant BR-202 [L275F] is, however, highly insensitive to 25 mM formate suggesting that a significant change in formate (bicarbonate) binding has occurred in helix V of the D1 protein near histidine involved in Fe binding. With the exception of DCMU-4 [S264A], which is considerably more sensitive to formate than the wild type, five other different [V219I, A25IV, F255Y, G256D and cell-wall deficient CW-15] mutants display a relatively similar response to formate as wild type. Absence of formate effect on a PS II-lacking [FuD-7] mutant confirms the sole involvement of PS II in the bicarbonate effect.     

Biochemical and genetic studies on two different types of erythromycin resistant mutants of Escherichia coli with altered ribosomal proteins

Summary Ribosomes from nine E. coli mutants with high level resistance to the antibiotic erythromycin were isolated and their proteins were compared with those of the parental strains by two-dimensional polyacrylamide gel electrophoresis, by carboxymethylcellulose column chromatography and by immunological techniques. Two 50S proteins were found to be altered in the mutants: either L 4 or L 22.Ribosomes with an altered L4 protein bound erythromycin rather poorly and the formation of N-acetylphenylalanyl puromycin was drastically decreased. On the other handribosomes with an altered L22 protein bound erythromycin as efficiently as wild type ribosomes and their puromycin reaction was at least as good as that of wild type ribosomes.Transduction experiments showed that the mutations affecting both proteins, L4 and L22, are located very close to the str and spc genes, nearer to the spc than to str gene.Paper No. 61 on Ribosomal Proteins. Preceding paper is by Hasenbank et al., Molec. gen. Genet., 127, 1–18 (1973).Communicated by E. Bautz     

Protein Electrophoretic Pattern of Two Chlorella Mutants with Low and High Content of Sulphur-Amino Acids

Two mutants of Chlorella vulgaris characterized by high (HS) or low (LS) content of sulphur-amino acids were compared to the wild strain with respect to their protein electrophoretic pattern. Three new bands, not present in the LS and wild strains, were found in the HS mutant. In algae grown in the presence of ³⁵S labelled sulphate two of these new bands showed a very high ³⁵S specific activity. Some electrophoretic bands common to LS, HS, and wild strain, were present in different proportions and showed different levels of specific radioactivity for each strain. Therefore, mutational events appear to have affected both the amino acid composition of single proteins and the relative amount of proteins with high and low sulphate content.     

The structural gene for the ribosomal protein S18 in Escherichia coli. II. Chemical studies on the protein S18 having an altered electrophoretic mobility

A mutant of Escherichia coli strain CR341 has an altered 30 S ribosomal protein S18. The alteration involves a change in the electrophoretic mobility of S18. S18 proteins were purified from the mutant and the parent strain, respectively, and their amino acid composition and tryptic peptides were compared. The results have shown that the mutational alteration involves substitution of cysteine for arginine. In addition, we determined the electrophoretic mobility of S18 proteins modified by ethyleneimine. The modification, which involves conversion of cysteine residues to S-(2-aminoethyl)cysteine, causes a greater electrophoretic mobility increase in the mutant protein than in the wild type protein, resulting in identical mobilities for the aminoethylated proteins. This experiment gives further support to the conclusion that the original mobility difference between mutant and wild type proteins is due to the mutational substitution of cysteine for arginine. The S18 obtained from a recombinant was also studied. The recombinant protein was found to have the mobility of the wild type protein and the wild type primary structure, as judged by amino acid composition and tryptic peptide analysis. This recombinant was obtained from the mutant by introducing Hfr strain G10 chromosome segments in the region between 70 and 10 minutes, and not in the str-spc region at 64 minutes, as described in the preceding paper. These results, together with those in the preceding paper, show that the mutation studied here is in the structural gene for S18, and that it maps outside the str-spc region.     

Physiological responses of Lactococcus lactis ML3 to alternating conditions of growth and starvation

Lactococcus lactis species can survive periods of carbohydrate starvation for relatively long periods of time. In the first hours of starvation, however, the maximal glycolytic and arginine deiminase (ADI) pathway activities decline rapidly. The rate of decrease of the pathway activities diminishes as soon as the cells become depleted of energy-rich intermediates. Loss of glycolytic activity is associated with loss of glyceraldehyde 3-phosphate dehydrogenase, phosphoglycerate mutase and pyruvate kinase activities. Upon addition of sugar to starved cultures these enzymatic, and thus the glycolytic, activities can be restored to 100% values. The recovery of enzymatic activities is inhibited by chloramphenicol, indicating that protein synthesis is involved. In contrast, restoration of ADI pathway activity does not require de novo synthesis of proteins. General protein degradation and synthesis have been studied in growing and starving cells using [³⁵S]methionine-labeling of proteins and two-dimensional gel analysis. The breakdown of bulk proteins in exponentially growing cells shows first-order rate kinetics (t1/2 of approximately 5 h). Following an initial breakdown of proteins with a t1/2 of 5 h during the first hour(s) of starvation, bulk proteins are degraded very slowly in starving energy-depleted cells. The breakdown of proteins during starvation appears to be (largely) nonspecific. The rate of synthesis of proteins decreases rapidly in the first hour(s) of starvation. From the onset of starvation on at least 45 proteins are no longer synthesized. During starvation relative induction of fourteen to fifteen proteins can be observed.Abbreviations ADI Arginine deiminase - ATP adenosine triphosphate - PEP phosphoenolpyruvate - membrane potential - pH pH gradient - PTS sugar phosphotransferase system - CDM chemically defined medium - TCA trichloro-acetic acid     

Properties of Mutants of Bacteria Belonging the Genus Erwinia Devoid of Common Components of the Phosphoenolpyruvate-Dependent Phosphotransferase System

Biochemical consequences of mutational damage to common components of the Erwinia phosphoenolpyruvate-dependent phosphotransferase system (the HPr protein and enzyme I) were studied. The transport of glucose, mannose, fructose, and mannitol inErwinia was shown to require a preliminary induction of proteins of the phosphotransferase system. A drastic decrease in the rate of the transport of these carbohydrates was observed in ptsI and ptsH mutants. A disturbance in the common components suppresses the synthesis of inducible enzymes (-galactosidase, complexes of pectolate lyases and cellulases) and renders it resistant to catabolite repression by glucose, but mutants were shown to retain intracellular cAMP content. Erwinia mutants devoid of common components of the system lack phytopathogenic features. The appearance of an intact ptsI allele in the cell completely repaired pleiotropic disturbances in these mutants.     

Analysis of gametophytic development in the moss,Physcomitrella patens,using auxin and cytokinin resistant mutants

Mutants altered in their response to auxins and cytokinins have been isolated in the moss Physcomitrella patens either by screening clones from mutagenized spores for growth on high concentrations of cytokinin or auxin, in which case mutants showing altered sensitivities can be recognized 3–4 weeks later, or by non-selective isolation of morphologically abnormal mutants, some of which are found to have altered sensitivities. Most of the mutants obtained selectively are also morphologically abnormal. The mutants are heterogeneous in their responses to auxin and cytokinin, and the behaviour of some is consistent with their being unable to make auxin, while that of others may be due to their being unable to synthesize cytokinin. Physiological analysis of the mutants has shown that both endogenous auxin and cytokinin are likely to play important and interdependent roles in several steps of gametophytic development. Although their morphological abnormalities lead to sterility, genetic analysis of some of the mutants has been possible by polyethyleneglycol induced protoplast fusion.Abbreviations NTG N-methyl-N-nitro-N-nitrosoguanidine - NAA 1-naphthalene acetic acid - 2,4D 2,4-dichlorophenoxyacetic acid - BAP 6-benzylaminopurine - IAP 6-( ²isopentenyl) aminopurine - NAR NAA resistant mutants - BAR BAP resistant mutants     

Alteration of ribosomal protein S17 by mutation linked to neamine resistance in Escherichia coli: II. Localization of the amino acid replacement in protein S17 from a neaA mutant

A mutant of Escherichia coli strain K12S, nea^R301, resistant to the antibiotic neamine was found to have an altered 30 S ribosomal protein S17. The modification involves a change in the electrophoretic mobility of this protein. S17 proteins wore purified from the mutant and the parental strain, respectively, and the amino acid compositions of all tryptic peptides were compared. The results show that the mutational alteration involves a replacement of histidine by proline in peptide T8 from mutant nea^R301. The amino acid replacement is located at position 30 of the S17 protein chain. We conclude, therefore, that the mutation nea^R301 affects the structural gene for protein S17 (rps Q).     

Reversible modification of 50S ribosomal subunits with dimethylmaleic anhydride

Summary The reversible modification of protein amino groups with dimethylmaleic anhydride, which had already been used to dissociate proteins from the 70S ribosomes of Escherichia coli (Pintor-Toro, J. A., et al. (1979) Biochemistry 18, 3219) was applied to the preparation of protein-deficient particles from the 50S subunits. Three successive cycles of treatment with dimethylmaleic anhydride, separation of dissociated proteins and regeneration of the modified amino groups produce partially inactivated ribosomal cores lacking proteins L7, L11 and L12, and having very small amounts of L1, L6 and L10. Incubation of these cores with the corresponding split proteins is accompanied by complete reactivation of the polypeptide synthesizing activity as compared with control 50S subunits.Abbreviation DMMA 2,3-dimethylmaleic anhydride     

Differential localization of ribosomal proteins S14 and 7/8 in egg chambers of D. melanogaster

Summary The localization of Drosophila melanogaster ribosomal proteins S14, and 7/8 during oogenesis was studied by indirect immune fluorescence microscopy. The acidic proteins S14¹ and 7/8¹ were isolated from D. melanogaster embryonic ribosomal proteins by carboxymethylcellulose chromatography (Chooi 1980). Antibodies raised against each of these proteins were applied to ovariole squashes, and the position of each antibody was localized by fluorescein labeled sheep antirabbit IgGs. Anti-S14 was found predominantly in nurse cell nuclei, follicle cell nuclei, oocytes and, to a much lesser degree, in nurse cell and follicle cell cytoplasm. In contrast, anti-7/8 was found in major quantities in nurse cell and follicle cell cytoplasm, and oocytes. Anti-7/8 in the nurse cell and follicle cell nuclei was either not detectable or at a strikingly lower level than that found in the corresponding cytoplasm. The egg chamber patterns of localization of these two proteins were also found in salivary gland cells. However, in Drosophila tissue culture cells, these patterns were altered; both anti-S14 and anti-7/8 were detected only in the cytoplasm.     

The Heat Shock Protein YbeY Is Required for Optimal Activity of the 30S Ribosomal Subunit

The highly conserved bacterial ybeY gene is a heat shock gene whose function is not fully understood. Previously, we showed that the YbeY protein is involved in protein synthesis, as Escherichia coli mutants with ybeY deleted exhibit severe translational defects in vivo. Here we show that the in vitro activity of the translation machinery of ybeY deletion mutants is significantly lower than that of the wild type. We also show that the lower efficiency of the translation machinery is due to impaired 30S small ribosomal subunits.Many heat shock proteins are chaperones and proteases that constitute the protein quality control system (4, 5, 13, 18). Recent studies demonstrated that beyond protein quality control, the heat shock response includes proteins implemented in the translation machinery (16, 17), such as FtsJ (2, 3) and Hsp15 (11).FtsJ catalyzes methylation of U2552 in 23S rRNA (3). This modification occurs during the final steps of 50S biogenesis and is important for the structural stability of the 50S subunit (2). ftsJ deletion mutants accumulate ribosomal subunits at the expense of polysomes (2). Consequently, crude ribosome extracts prepared from ftsJ deletion mutants are far less active than wild-type preparations (3). Hsp15 recognizes and binds with high affinity to the aberrant state of the 50S subunit in complex with peptidyl tRNA positioned at the A site (10), which is more frequent at high temperatures (10). It has been proposed that Hsp15 participates in releasing the bound peptide and thereby helps recycle the 50S subunit (8, 10). Thus, heat shock proteins play a significant role both in the biogenesis of ribosomes and in the translation process.YbeY is a 17-kDa heat shock protein, highly conserved among bacteria, that belongs to the UPF0054 family of metal-dependent hydrolases, suggesting that it may have a potential hydrolytic function (14, 21). In Aquifex aeolicus, analysis of YbeY structure homology showed similarity to eukaryotic extracellular proteinases such as collagenase and gelatinase. However, in vitro experiments could not detect collagenase, gelatinase, or other hydrolase activity in YbeY (14).Recently, we showed that ybeY deletion mutants exhibit severe translational defects manifested by a very low level of polysomes and accumulation of free ribosomes and ribosomal subunits, indicating that most ribosomes in the cell are not engaged in translation. This translational defect intensifies at elevated temperatures (42°C) and results in growth arrest (17).Here we present in vitro studies indicating that the activity of the translation machinery prepared from ybeY deletion mutants is lower than in the wild type. In addition, we show that this lower activity stems specifically from a defective 30S ribosomal subunit.     

Isolation and characterization of prototrophic relaxed mutants of Klebsiella pneumoniae

Summary A new selection procedure has been developed for isolating prototrophic relaxed mutants of Klebsiella pneumoniae. Two mutants were isolated. One of them showed a fully relaxed phenotype, while the other one behaved in a semi-relaxed way.The wild-type strain, as well as the rel mutants exerted similar patterns to their E. coli counterparts in RNA, protein, ppGpp and pppGpp accumulation during amino starvation, carbon source shift-down and nitrogen starvation. Both mutants became stringent after introducing an F-factor carrying the relA ⁺ allele from Escherichia coli. The relaxed phenotype could be recovered by curing the F-factor. Some of the pleiotropic consequences of rel mutations found in E. coli are present in the Klebsiella mutants also while some of them are absent.The mutants are defective in dinitrogen fixation after the exhaustion of limiting ammonium from the culture medium. However, their merodiploid derivatives, carrying the E. coli relA ^- allele, showed the wild-type level of nitrogenase activity under the same conditions.Fellow of the 6th International Training Course jointly sponsored by UNDP/UNESCO Hungarian Academy of Sciences. Present address: Akademie der Wissenschaften der DDR, Forschungszentrum für Molekularbiologie und Medizin, Zentralinstitut für Mikrobiologie und Experimentelle Therapie Jena, Beuthenberg Str. 11, DDR-69 Jena     

The Sinorhizobium meliloti LpxXL and AcpXL Proteins Play Important Roles in Bacteroid Development within Alfalfa

Free-living Sinorhizobium meliloti lpxXL and acpXL mutants lack lipid A very-long-chain fatty acids (VLCFAs) and have reduced competitiveness in alfalfa. We demonstrate that LpxXL and AcpXL play important but distinct roles in bacteroid development and that LpxXL is essential for the modification of S. meliloti bacteroid lipid A with VLCFAs.Sinorhizobium meliloti and Brucella abortus form chronic intracellular infections within legumes and mammalian hosts, respectively (3, 20), and their BacA proteins play essential roles in these processes (8, 12). The precise function(s) of the BacA proteins has not been resolved, but free-living S. meliloti and B. abortus mutants lacking BacA have increased resistance to the glycopeptide bleomycin (9, 12) and there are ∼50% decreases in their lipid A very-long-chain fatty acid (VLCFA) contents (4, 7). It has also been determined that the increased resistance of an S. meliloti bacA null mutant to bleomycin and a truncated eukaryotic peptide, Bac7_1-16, is independent of its lipid A VLCFA alteration (6, 15). Together, these findings support a model in which BacA could have multiple nonoverlapping functions which lead to lipid A VLCFA modification and peptide uptake. The fact that two symbiotically defective S. meliloti BacA site-directed mutants (Q193G and R389G) (13) show defects in BacA-mediated lipid A VLCFA modification (4) but are still capable of peptide uptake (15) suggests that the S. meliloti lipid A VLCFA modification could play a key role in the symbiosis of this organism with alfalfa.Since the mechanism by which BacA leads to the lipid A VLCFA modification has not been resolved (4), S. meliloti mutants were constructed with mutations in the lpxXL and acpXL genes, which encode a lipid A VLCFA acyl transferase and a VLCFA acyl carrier protein directly involved in the biosynthesis of VLCFA-modified lipid A (5, 23). The S. meliloti lpxXL and acpXL mutants completely lack the lipid A VLCFA modification in their free-living states, but, unlike the S. meliloti bacA null mutant, these mutants can still form a successful symbiosis with alfalfa (5, 8, 23). However, the fact that the S. meliloti acpXL and lpxXL mutants are substantially less competitive in the alfalfa symbiosis than the parent strain (5, 23) indicates that the AcpXL and LpxXL proteins play important roles in at least one of the stages of the alfalfa symbiosis. Although the free-living S. meliloti acpXL and lpxXL mutants completely lack the lipid A VLCFA, they produce different species of lipid A (5). For example, in the absence of AcpXL, S. meliloti is able to modify lipid A with either C16:0 or C18:0 in the position normally modified with the VLCFA in the parent strain lipid A. This process is LpxXL dependent, as it does not occur in either an S. meliloti lpxXL single mutant or an S. meliloti acpXL lpxXL double mutant. In addition, since a Rhizobium leguminosarum acpXL mutant completely lacks the lipid A VLCFA modification in its free-living state but its lipid A is partially modified with the VLCFA to ∼58% of the amount in the parent strain lipid A during passage through peas (25), it is also possible that the S. meliloti acpXL mutant and possibly the S. meliloti lpxXL mutant undergo further lipid A changes during the interaction with alfalfa.In this study, we found that LpxXL and AcpXL play important but distinct roles in S. meliloti bacteroid development during alfalfa symbiosis. Additionally, we demonstrated that there is a minor host-induced AcpXL-independent mechanism by which S. meliloti bacteroid lipopolysaccharide (LPS) can be modified with the VLCFA. In contrast, we found that the LpxXL protein plays an essential role in the modification of S. meliloti bacteroids with VLCFAs.     

Asparagine metabolism and nitrogen distribution during protein degradation in sugar-starved maize root tips

Excised maize (Zea mays L.) root tips were used to monitor the effects of prolonged glucose starvation on nitrogen metabolism. Following root-tip excision, sugar content was rapidly exhausted, and protein content declined to 40 and 8% of its initial value after 96 and 192 h, respectively. During starvation the contents of free amino acids changed. Amino acids that belonged to the same synthetic family showed a similar pattern of changes, indicating that their content, during starvation, is controlled mainly at the level of their common biosynthetic steps. Asparagine, which is a good marker of protein and amino-acid degradation under stress conditions, accumulated considerably until 45 h of starvation and accounted for 50% of the nitrogen released by protein degradation at that time. After 45 h of starvation, nitrogen ceased to be stored in asparagine and was excreted from the cell, first as ammonia until 90–100 h and then, when starvation had become irreversible, as amino acids and aminated compounds. The study of asparagine metabolism and nitrogen-assimilation pathways throughout starvation showed that: (i) asparagine synthesis occurred via asparagine synthetase (EC 6.3.1.1) rather than asparagine aminotransferase (EC 2.6.1.14) or the -cyanoalanine pathway, and asparagine degradation occurred via asparaginase (EC 3.5.1.1); and (ii) the enzymic activities related to nitrogen reduction and assimilation and amino-acid synthesis decreased continuously, whereas glutamate dehydrogenase (EC 1.4.1.2–4) activities increased during the reversible period of starvation. Considered together, metabolite analysis and enzymic-activity measurements showed that starvation may be divided into three phases: (i) the acclimation phase (0 to 30–35 h) in which the root tips adapt to transient sugar deprivation and partly store the nitrogen released by protein degradation, (ii) the survival phase (30–35 to 90–100 h) in which the root tips expel the nitrogen released by protein degradation and starvation may be reversed by sugar addition and (iii) the cell-disorganization phase (beyond 100 h) in which all metabolites and enzymic activities decrease and the root tips die.Abbreviations AlaAT alanine aminotransferase - AspAT aspartate aminotransferase - AS asparagine synthetase - Asnase asparaginase - AsnAT asparagine aminotransferase - -CS -cyanoalanine synthase - GDH glutamate dehydrogenase - Glnase glutaminase - GOGAT glutamate synthase - GS glutamine synthetase - NiR nitrite reductase - NR nitrate reductase