Mutation in the lysA gene impairs the symbiotic properties of Mesorhizobium ciceri

A Tn5-induced mutant of Mesorhizobium ciceri, TL28, requiring the amino acid lysine for growth on minimal medium was isolated and characterized. The Tn5 insertion in the mutant strain TL28 was located on a 6.8-kb EcoRI fragment of the chromosomal DNA. Complementation analysis with cloned DNA indicated that 1.269 kb of DNA of the 6.8-kb EcoRI fragment restored the wild-type phenotype of the lysine-requiring mutant. This region was further characterized by DNA sequence analysis and was shown to contain a coding sequence homologous to lysA gene of different bacteria. The lys ^? mutant TL28 was unable to elicit development of effective nodules on the roots of Cicer arietinum L. There was no detectable level of lysine in the root exudates of chickpea. However, addition of lysine to the plant growth medium restored the ability of the mutant to produce effective nodules with nitrogen fixation ability on the roots of C. arietinum.     

Aspartokinase III repression in a thialysine-resistant mutant of E. coli

A thialysine-resistant mutant of the E. coli KL16 strain was isolated. It can grow equally well in the presence and in the absence of thialysine. The properties of the two lysine transport systems, of the lysyl-tRNA synthetase and of the aspartokinase III (AK III) were studied in the mutant and in the parent strain. AK III is the first enzyme of the lysine biosynthetic pathway and its activity is involved in the regulation of lysine biosynthesis by feed-back and repression mechanism. No difference between the two strains was evidenced as regards 1) the affinity of the transport systems for lysine and thialysine 2) the activity of the lysyl-tRNA synthetase 3) the allosteric inhibition of the AK III by lysine and thialysine. A marked difference between the two strains has been evidenced in the AK III repression: in the mutant the enzyme is much less repressed both by lysine and thialysine. The possible correlation between the activity of AK III and the thialysine-resistance is discussed in this paper.     

Calcium Bridge Triggers Capsid Disassembly in the Cell Entry Process of Simian Virus 40

The calcium bridge between the pentamers of polyoma viruses maintains capsid metastability. It has been shown that viral infection is profoundly inhibited by the substitution of lysine for glutamate in one calcium-binding residue of the SV40 capsid protein, VP1. However, it is unclear how the calcium bridge affects SV40 infectivity. In this in vitro study, we analyzed the influence of host cell components on SV40 capsid stability. We used an SV40 mutant capsid (E330K) in which lysine had been substituted for glutamate 330 in protein VP1. The mutant capsid retained the ability to interact with the SV40 cellular receptor GM1, and the internalized mutant capsid accumulated in caveolin-1-mediated endocytic vesicles and was then translocated to the endoplasmic reticulum (ER) region. However, when placed in ER-rich microsome, the mutant capsid retained its spherical structure in contrast to the wild type, which disassembled. Structural analysis of the mutant capsid with cryo-electron microscopy and image reconstruction revealed altered pentamer coordination, possibly as a result of electrostatic interaction, although its overall structure resembled that of the wild type. These results indicate that the calcium ion serves as a trigger at the pentamer interface, which switches on capsid disassembly, and that the failure of the E330K mutant capsid to disassemble is attributable to an inadequate triggering system. Our data also indicate that calcium depletion-induced SV40 capsid disassembly may occur in the ER region and that this is essential for successful SV40 infection.     

Mutation of a consensus purine nucleotide binding site in the adeno-associated virus rep gene generates a dominant negative phenotype for DNA replication.

Adeno-associated virus (AAV) contains a multifunctional nonstructural gene, rep, which is required for AAV DNA replication and has pleiotropic effects on positive and negative regulation of gene expression. All of the parvovirus nonstructural genes contain a region of highly conserved amino acid homology. Within this conserved region is the consensus sequence for a purine nucleotide binding site. We constructed a mutant AAV having a mutation in this site by converting lysine 340 to histidine. The resulting mutant AAV genome, pNTC23, overproduced the mutant Rep proteins, indicating that these proteins are autoregulated. Furthermore, the mutant gene was unable to replicate but was able to inhibit in trans wild-type AAV DNA replication. Thus, pNTC23 represents a dominant negative mutant of AAV. These results suggest that rep has separate functional domains important for DNA replication.     

Thialysine- and selenalysine-resistance in a E. coli mutant

A thialysine-resistant mutant of E. coli strain KL16 also shows a lower sensitivity to selenalysine, the lysine analog containing selenium. No difference between the mutant and the parental strain has been shown regarding the affinities of the transport systems and the lysyl-tRNA synthetase for selenalysine, thialysine and lysine as well as the inhibitory effects of these three aminoacids on the activity of the lysine biosynthetic pathway. A marked difference between the two strains has been evidenced in the AK III repression: in the mutant the repression by selenalysine, thialysine and lysine is much lower than in the parental strain.     

Endocytosis of the AT1A angiotensin receptor is independent of ubiquitylation of its cytoplasmic serine/threonine-rich region

Agonist-induced internalisation of the rat type 1A (AT(1A)) angiotensin II receptor is associated with phosphorylation of a serine/threonine-rich region in its cytoplasmic tail. In yeast, hyperphosphorylation of the alpha-factor pheromone receptor regulates endocytosis of the receptor by facilitating the monoubiquitylation of its cytoplasmic tail on lysine residues. The role of receptor ubiquitylation in AT(1A) receptor internalisation was evaluated by deletion or replacement of lysine residues in its agonist-sensitive serine/threonine-rich region. Expression of such receptor mutants in CHO cells showed that these modifications had no detectable effect on the angiotensin II-induced endocytosis of the AT(1A) receptor. Furthermore, fusion of ubiquitin in-frame to an internalisation-deficient AT(1A) receptor mutant with a truncated carboxyl-terminal tail did not restore the endocytosis of the resulting chimeric receptor. No impairment of receptor internalisation was observed after substitution of all lysine residues in the serine/threonine-rich region at saturating angiotensin II concentrations, where endocytosis occurs by a beta-arrestin and dynamin independent mechanism. Taken together, these data demonstrate that ubiquitylation of the cytoplasmic serine/threonine-rich region of the AT(1A) receptor on lysine residues is not required for its agonist-induced internalisation, and suggest that endocytosis of mammalian G protein-coupled receptors (GPCRs) occurs by a different mechanism than that of yeast GPCRs.     

Nucleotide substitution in the amino acid acceptor stem of lysine transfer RNA causes missense suppression

Previous results from this laboratory indicated that, in Escherichia coli K12, a new class of missense suppressors, which read the lysine codons AAA and AAG, may be misacylated lysine transfer RNAs. We therefore isolated and determined the nucleotide sequence of the lysine tRNA from two of the suppressor strains. In each case, we found both wild-type and mutant species of lysine tRNA, a result consistent with evidence that there are two genes for lysine tRNA in the E coli genome. The wild-type sequence was essentially identical to that reported for lysine tRNA from E. coli B. The mutant species isolated from each suppressor strain had a U for C70 nucleotide substitution, demonstrating that the AAG suppressor is a mutant lysine tRNA. The nucleotide substitution in the amino acid acceptor stem is consistent with the in vivo evidence that the suppressor corrects AAA and AAG missense mutations by inserting an amino acid other than lysine during polypeptide synthesis. This report represents the first verification of missense suppression caused by misacylation of a mutant tRNA.     

Role of surface lysine residues of adipocyte fatty acid-binding protein in fatty acid transfer to phospholipid vesicles

The tertiary structure of murine adipocyte fatty acid-binding protein (AFABP) is a flattened 10-stranded beta-barrel capped by a helix-turn-helix segment. This helical domain is hypothesized to behave as a "lid" or portal for ligand entry into and exit from the binding cavity. Previously, we demonstrated that anthroyloxy-labeled fatty acid (AOFA) transfer from AFABP to phospholipid membranes occurs by a collisional process, in which ionic interactions between positively charged lysine residues on the protein surface and negatively charged phospholipid headgroups are involved. In the present study, the role of specific lysine residues located in the portal and other regions of AFABP was directly examined using site-directed mutagenesis. The results showed that isoleucine replacement for lysine in the portal region, including the alphaI- and alphaII-helices and the beta C-D turn, resulted in much slower 2-(9-anthroyloxy)palmitate (2AP) transfer rates to acidic membranes than those of native AFABP. An additive effect was found for mutant K22,59I, displaying the slowest rates of FA transfer. Rates of 2AP transfer from "nonportal" mutants on the beta-G and I strands were affected only moderately; however, a lysine --> isoleucine mutation in the nonportal beta-A strand decreased the 2AP transfer rate. These studies suggest that lysines in the helical cap domain are important for governing ionic interactions between AFABP and membranes. Furthermore, it appears that more than one distinct region, including the alphaI-helix, alphaII-helix, beta C-D turn, and the beta-A strand, is involved in these charge-charge interactions.     

Cation permeability and cation-anion interactions in a mutant GABA-gated chloride channel from Drosophila.

To investigate the structural basis of anion selectivity of Drosophila GABA-gated Cl(-) channels, the permeation properties of wild-type and mutant channels were studied in Xenopus oocytes. This work focused on asparagine 319, which by homology is one amino acid away from a putative extracellular ring of charge that regulates cation permeation in nicotinic receptors. Mutation of this residue to aspartate reduced channel conductance, and mutation to lysine or arginine increased channel conductance. These results are consistent with an electrostatic interaction between this site and permeating anions. The lysine mutant, but not the arginine mutant, formed a channel that is permeable to cations, and this cannot be explained in terms of electrostatics. The lysine mutant had a 25-mV reversal potential in solutions with symmetrical Cl(-) and asymmetrical cations. The permeability ratio of K(+) to Cl(-) was determined as 0. 33 from reversal potential measurements in KCl gradients. Experiments with large organic cations and anions showed that cation permeation can only be seen in the presence of Cl(-), but Cl(-) permeation can be seen in the absence of permeant cations. Measurements of permeability ratios of organic anions indicated that the lysine mutant has an increased pore size. The cation permeability of the lysine-containing mutant channel cannot be accounted for by a simple electrostatic interaction with permeating ions. It is likely that lysine substitution causes a structural change that extends beyond this one residue to influence the positions of other channel-forming residues. Thus protein conformation plays an important role in enabling ion channels to distinguish between anions and cations.     

Increasing lysine levels in pigeonpea (<Emphasis Type="Italic">Cajanus cajan</Emphasis> (L.) Millsp) seeds through genetic engineering

In higher plants the essential amino acids lysine, threonine, methionine and isoleucine are synthesised through a branched pathway starting from aspartate. The key enzyme of lysine biosynthesis in this pathway—dihydrodipicolinate synthase (DHDPS)—is feedback-inhibited by lysine. The dhdps-r1 gene from a mutant Nicotiana sylvestris, which encodes a DHDPS enzyme insensitive to feedback inhibition, was used to improve the lysine content in pigeonpea seeds. The dhdps-r1 coding region driven by a phaseolin or an Arabidopsis 2S2 promoter was successfully overexpressed in the seeds of pigeonpea by using Agrobacterium transformation and particle bombardment. In 11 lines analysed, a 2- to 6-fold enhanced DHDPS activity in immature seeds at a late stage of maturation was found in comparison to wild type. The overexpression of dhdps-r1 led to an enhanced content of free lysine in the seeds of pigeonpea from 1.6 to 8.5 times compared with wild type. However, this was not reflected in an increase in total seed lysine content. This might be explained by a temporal discrepancy between maximal expression of dhdps-r1 and the rate of amino acid incorporation into storage proteins. Assays of the lysine degradative enzyme lysine-ketoglutarate reductase in these seeds showed no co-ordinated regulation of lysine biosynthesis and catabolism during seed maturation. All transgenic plants were fertile and produced morphologically normal seeds.     

Comprehensive structural analysis of mutant nucleosomes containing lysine to glutamine (KQ) substitutions in the H3 and H4 histone-fold domains

Post-translational modifications (PTMs) of histones play important roles in regulating the structure and function of chromatin in eukaryotes. Although histone PTMs were considered to mainly occur at the N-terminal tails of histones, recent studies have revealed that PTMs also exist in the histone-fold domains, which are commonly shared among the core histones H2A, H2B, H3, and H4. The lysine residue is a major target for histone PTM, and the lysine to glutamine (KQ) substitution is known to mimic the acetylated states of specific histone lysine residues in vivo. Human histones H3 and H4 contain 11 lysine residues in their histone-fold domains (five for H3 and six for H4), and eight of these lysine residues are known to be targets for acetylation. In the present study, we prepared 11 mutant nucleosomes, in which each of the lysine residues of the H3 and H4 histone-fold domains was replaced by glutamine: H3 K56Q, H3 K64Q, H3 K79Q, H3 K115Q, H3 K122Q, H4 K31Q, H4 K44Q, H4 K59Q, H4 K77Q, H4 K79Q, and H4 K91Q. The crystal structures of these mutant nucleosomes were determined at 2.4-3.5 ? resolutions. Some of these amino acid substitutions altered the local protein-DNA interactions and the interactions between amino acid residues within the nucleosome. Interestingly, the C-terminal region of H2A was significantly disordered in the nucleosome containing H4 K44Q. These results provide an important structural basis for understanding how histone modifications and mutations affect chromatin structure and function.     

Biochemical characterization of a thialysine-resistant clone of CHO cells

The intracellular transport and the activation of lysine, thialysine and selenalysine have been investigated in a thialysine-resistant CHO cell mutant strain in comparison with the parental strain. The cationic amino acid transport system responsible for the transport of these 3 amino acids shows no differences between the 2 strains as regards its affinity for each of these amino acids. On the other hand the Vmax of the transport system in the mutant is about double that in the parental strain. The lysyl-tRNA synthetase, assayed both as ATP = PPi exchange reaction and lysyl-tRNA synthesis, shows a lower affinity for thialysine and selenalysine than for lysine in both strains; in the mutant, however, the difference is even greater. Thus the thialysine resistance of the mutant is mainly due to the properties of its lysyl-tRNA synthetase, which shows a greater difference of the affinities for lysine and thialysine with respect to the parental strain.     

A <Emphasis Type="Italic">Candida guilliermondii</Emphasis> lysine hyperproducer capable of elevated citric acid production

A mutant of the yeast Candida guilliermondii ATCC 9058 exhibiting elevated citric acid production was isolated based upon its ability to overproduce lysine. This method involved the use of a solid medium containing a combination of lysine analogues to identify a mutant that produced a several-fold higher lysine level compared to its parent strain using glucose or glycerol as a carbon source. The mutant strain was also capable of producing more than a fivefold higher citric acid level on glycerol as a carbon source compared to its parent strain. It was concluded that the screening of yeast lysine hyperproducer strains could provide a rapid approach to isolate yeast citric acid hyperproducer strains.     

Isolation of auxotrophic mutants from acetobacter methanolicus MB 58

The lysine content of the biomass of the acidophilic facultatively methylotrophic bacterium Acetobacter methanolicus MB 58 was increased by genetic manipulations. A homoserine auxotroph, MB 58.196, and a threonine auxotroph, MB 58.195, were obtained from Acetobacter methanolicus MB 58 by N-methyl-N′-nitro-N-nitrosoguanidine treatment. Investigations of enzyme activities revealed that the homoserine auxotroph lacks homoserine dehydrogenase activity, and the threonine auxotroph lacks homoserine kinase activity. Concerning the lysine-producing ability, only the homoserine auxotrophic mutant accumulates lysine in the intracellular pool. The intracellular lysine content of this mutant was increased 40-fold. An excretion of amino acids into the medium was not detected. A homoserine resistant mutant, MB 58.196.10, isolated from MB 58.196 by UV-irradiation, was able to excrete lysine. About 95% of free lysine were found in the culture medium. Altogether, the free lysine concentration was increased 800-fold in comparison to the wild-type strain. By these genetic manipulations the total lysine concentration of MB 58.196 was increased to 2.7% and of MB 58.196.10 to 56% in comparison to the wild-type strain.     

SIRT7 regulates the nuclear export of NF-κB p65 by deacetylating Ran

Sirtuin 7 (SIRT7) is an NAD⁺-dependent lysine deacetylase that regulates diverse biological processes. We recently observed that SIRT7 deficiency suppresses the nuclear accumulation of p65, which is a component of nuclear factor kappa B. However, the underlying molecular mechanism remains elusive. In this study, we demonstrated that SIRT7 interacts with a small GTPase, Ras-related nuclear antigen (Ran), and deacetylates Ran at K37. The nuclear export of p65 was facilitated in SIRT7-deficient fibroblast cells, while the nuclear export was inhibited in SIRT7-deficient cells expressing K37R-Ran (deacetylation-mimicking mutant). Additionally, the nuclear export of p65 in wild-type fibroblast cells was promoted by K37Q-Ran (acetylation-mimicking mutant). K37Q-Ran exhibited an increased ability to bind to chromosome region maintenance 1 (CRM1), which is a major nuclear receptor that mediates the export of cargo proteins, and enhanced the binding between p65 and CRM1. These data suggest that SIRT7 is a lysine deacetylase that targets the K37 residue of Ran to suppress the nuclear export of p65.     

Escherichia coli regulatory mutation affecting lysine transport and lysine decarboxylase

A spontaneous thiosine-resistant mutant of Escherichia coli was shown to have the following characteristics: lowered initial rate of lysine uptake and lowered plateau level of accumulation of exogenous lysine by both the lysine-specific and the general basic amino acid transport systems; altered repressibility of these two lysine transport systems; a derepressed level of lysine decarboxylase; normal growth rate; parental levels of lysyl-transfer ribonucleic acid synthetase and the inducible and constitutive arginine and ornithine decarboxylases. Both the mutant (lysP) and its parent (lysP+) feed a lysine auxotroph when they are plated in proximity on solid medium. However, the feeding response was observable after 1 day less of incubation when the mutant was the feeding strain. Despite the derepressed level of lysine decarboxylase in exponential cultures of the mutant extracts of these cultures had no detectable cadaverine pool. Conjugation experiments established the following gene order: gyrA (formerly nalA) lysP metG his. All thiosine-resistant recombinants assayed showed reduced lysine transport. In many of these recombinants the derepression of lysine decarboxylase was not expressed.     

Lysine production byBrevibacterium linens and its mutants: Activities and regulation of enzymes of the lysine biosynthetic pathway

Activity and regulation of key enzymes of the lysine biosynthetic pathway were investigated inBrevibacterium linens, a natural excretor of lysine, its lysine-overproducing homoserine auxotroph (Hom(-1)) and its auxotrophic and multianalogue-resistant high-yielding mutant (AEC NV 20(r)50). The activity of aspartate kinase (AK) and aspartaldehydate dehydrogenase (AD) was maximum during the mid-exponential phase of growth and decreased therafter. The mutants showed 10 and 20% more activity of AK and AD than the wild-type lysine excretor.B. linens (natural excretor) has a single AK and AD repressed and inhibited bivalently by lysine and threonine. Lysine slightly repressed and inhibited dihydrodipicolinate synthase (DS) and diaminopimelate decarboxylase (DD) of the wild type and of the mutant Hom(-1). The mutant AEC NV 20(r)50 showed DS and DD to be insensitive to lysine inhibition and repression. Persistence of a major part of the maximal activity of these enzymes during the late stationary phase of growth allowed prolonged synthesis and excretion of lysine. Stepwise addition of resistance to the different analogues of lysine in the mutant AEC NV20(r)50 resulted in an increase of enzyme activity and reduced repressibilities of enzymes that contributed to the high yield of lysine.     

Regulation of filamentous bacteriophage length by modification of electrostatic interactions between coat protein and DNA

Bacteriophage fd gene VIII, which encodes the major capsid protein, was mutated to convert the serine residue at position 47 to a lysine residue (S47K), thereby increasing the number of positively charged residues in the C-terminal region of the protein from four to five. The S47K coat protein underwent correct membrane insertion and processing but could not encapsidate the viral DNA, nor was it incorporated detectably with wild-type coat proteins into hybrid bacteriophage particles. However, hybrid virions could be constructed from the S47K coat protein and a second mutant coat protein, K48Q, the latter containing only three lysine residues in its C-terminal region. K48Q phage particles are approximately 35% longer than wild-type. Introducing the S47K protein shortened these particles, the S47K/K48Q hybrids exhibiting a range of lengths between those of K48Q and wild-type. These results indicate that filamentous bacteriophage length (and the DNA packaging underlying it) are regulated by unusually flexible electrostatic interactions between the C-terminal domain of the coat protein and the DNA. They strongly suggest that wild-type bacteriophage fd makes optimal use of the minimum number of coat protein subunits to package the DNA compactly.