The ITS region as a target for characterization of fungal communities using emerging sequencing technologies

In a previous work, it was observed that the swarming of polyamine-deficient Proteus mirabilis ( speB :: sm ) was severely inhibited on Luria–Bertani (LB) swarming plates (LBSw) (LB, 0.5% glucose, 0.5% agar), and it was clarified that extracellular putrescine was important as a signaling molecule for the induction of swarming in P. mirabilis . However, a polyamine-deficient strain (delta- speAB delta- speC ) of Escherichia coli swarmed as well as the parental strain on LBSw plates. We report that the swarming phenotype of a polyamine-deficient E. coli strain is dependent on spermidine and PotABCD, a spermidine importer.     

Polyamines are essential for the formation of plague biofilm

We provide the first evidence for a link between polyamines and biofilm levels in Yersinia pestis, the causative agent of plague. Polyamine-deficient mutants of Y. pestis were generated with a single deletion in speA or speC and a double deletion mutant. The genes speA and speC code for the biosynthetic enzymes arginine decarboxylase and ornithine decarboxylase, respectively. The level of the polyamine putrescine compared to the parental speA+ speC+ strain (KIM6+) was depleted progressively, with the highest levels found in the Y. pestis DeltaspeC mutant (55% reduction), followed by the DeltaspeA mutant (95% reduction) and the DeltaspeA DeltaspeC mutant (>99% reduction). Spermidine, on the other hand, remained constant in the single mutants but was undetected in the double mutant. The growth rates of mutants with single deletions were not altered, while the DeltaspeA DeltaspeC mutant grew at 65% of the exponential growth rate of the speA+ speC+ strain. Biofilm levels were assayed by three independent measures: Congo red binding, crystal violet staining, and confocal laser scanning microscopy. The level of biofilm correlated to the level of putrescine as measured by high-performance liquid chromatography-mass spectrometry and as observed in a chemical complementation curve. Complementation of the DeltaspeA DeltaspeC mutant with speA showed nearly full recovery of biofilm to levels observed in the speA+ speC+ strain. Chemical complementation of the double mutant and recovery of the biofilm defect were only observed with the polyamine putrescine.     

Mutants of Escherichia coli that do not contain 1,4-diaminobutane (putrescine) or spermidine.

Strains of Escherichia coli K12 have been constructed which do not contain any of the polyamines normally present in a wild type strain, namely, 1,4-diaminobutane (putrescine) and spermidine. This phenotype arises as a consequence of the assembly into these strains of deletion mutations in speA (arginine decarboxylase), speB (agmatine ureohydrolase), speC (ornithine decarboxylase), and speD (adenosylmethionine decarboxylase). The polyamine-deficient strains grow indefinitely in the absence of polyamines but with a growth rate one-third of that found in the presence of polyamines. These strains can act as hosts for bacteriophages T4, T7, and f2, although the latter phage is poorly adsorbed; they can also maintain F' factors, ColE1 and P1 plasmids, and lysogeny by bacteriophage lambda. In contrast, the production of bacteriophage lambda in the absence of polyamines is strikingly decreased (greater than 99%) either after infection of a nonlysogen or after induction of a lysogen. A polyamine-deficient Hfr strain can transfer its chromosome to a recipient at a normal rate, but the number of recombinants observed in a cross is decreased approximately 300-fold. No such effect is observed when only the F- recipient strain in a cross is polyamine deficient.     

Construction of an Escherichia coli strain unable to synthesize putrescine, spermidine, or cadaverine: characterization of two genes controlling lysine decarboxylase.

We have previously described a polyamine-deficient strain of Escherichia coli that contained deletions in speA (arginine decarboxylase), speB (agmatine ureohydrolase), speC (ornithine decarboxylase), and speD (adenosylmethionine decarboxylase). Although this strain completely lacked putrescine and spermidine, it was still able to grow at a slow rate indefinitely on amine-deficient media. However, these cells contained some cadaverine (1,5-diaminopentane). To rule out the possibility that the presence of cadaverine permitted the growth of this strain, we isolated a mutant (cadA) that is deficient in cadaverine biosynthesis, namely, a mutant lacking lysine decarboxylase, and transduced this cadA gene into the delta (speA-speB) delta speC delta D strain. The resultant strain had essentially no cadaverine but showed the same phenotypic characteristics as the parent. Thus, these results confirm our previous findings that the polyamines are not essential for the growth of E. coli or for the replication of bacteriophages T4 and T7. We have mapped the cadA gene at 92 min; the gene order is mel cadA groE ampA purA. A regulatory gene for lysine decarboxylase (cadR) was also obtained and mapped at 46 min; the gene order is his cdd cadR fpk gyrA.     

Isolation, characterization, and mapping of Escherichia coli mutants blocked in the synthesis of ornithine decarboxylase.

Several Escherichia coli K-12 mutants blocked in the synthesis of ornithine decarboxylase (OD) were isolated after transduction for serA+ in a strain (MA197) blocked in agmatine ureohydrolase (AUH) with a mutagenized phage lysate of P1. The new double-polyamine mutants were characterized by an unconditional polyamine dependence; either putrescine or spermidine was required for normal growth. The mutational block was varified by the demonstration of a virtual absence of OD activity in cellular extracts. The mutation, designated speC, was mapped by P1 transduction in several strains and was shown to have a cotransduction frequency of 17.2% with serA. Map order was established as serA speB speC metK. A derivative of one of the OD mutants having wild-type levels of AUH and blocked in OD was utilized along with an OD AUH mutant and an OD+ AUH strain to explore the phenomenon of "pathway selection" using growth rate as a parameter. Polyamine pool studies were carried out simultaneously. The results presented here support the hypothesis of pathway selection, implying a preferential utilization of exogenous arginine rather than endogenously produced arginine in polyamine biosynthesis.     

Utilization of putrescine by Streptococcus pneumoniae during growth in choline-limited medium

Polyamines such as putrescine are small, ubiquitous polycationic molecules that are required for optimal growth of eukaryotic and prokaryotic cells. These molecules have diverse effects on cell physiology and their intracellular content is regulated by de novo synthesis and uptake from the environment. The studies presented here examined the structure of a putative polyamine transporter (Pot) operon in Streptococcus pneumoniae (pneumococcus) and growth of pneumococci in medium containing putrescine substituted for choline. RT-PCR experiments demonstrated that the four genes encoding the Pot system are co-transcribed with murB, a gene involved in an intermediary step of peptidoglycan synthesis. Pneumococci grown in chemically-defined media (CDM) containing putrescine without choline enter logarithmic phase growth after 36-48 hs. However, culture density at stationary phase eventually reaches that of choline-containing medium. Cells grown in CDM-putrescine formed abnormally elongated chains in which the daughter cells failed to separate and the choline-binding protein PspA was no longer cell-associated. Experiments with CDM containing radiolabeled putrescine demonstrated that pneumococci concentrate this polyamine in cell walls. These data suggest that pneumococci can replicate without choline if putrescine is available and this polyamine may substitute for aminoalcohols in the cell wall teichoic acids.     

Characteristics of the gene for a spermidine and putrescine transport system that maps at 15 min on the Escherichia coli chromosome

The nucleotide sequence of the gene for the spermidine and putrescine transport system that maps at 15 min on the Escherichia coli chromosome was determined. It contained four open reading frames encoding A, B, C, and D proteins. By making several subclones, we showed that expression of all the four proteins was necessary for maximal spermidine and putrescine transport activity. A single transport system was involved in the transport of both spermidine and putrescine. The A protein (Mr 43K) was found to be associated with membranes, as shown by Western blot analysis of the cell fractions. In addition, it had consensus amino acid sequences for the nucleotide binding site. B (Mr 31K) and C (Mr 29K) proteins consisted of six putative transmembrane spanning segments linked by hydrophilic segments of variable length as shown by cell localization of the proteins synthesized in maxicells and by hydropathy profiles. D protein (Mr 39K) was inferred to be a polyamine binding protein existing in a periplasmic fraction from the results of Western blot analysis of the cell fractions and from measurements of polyamine binding to the protein. These results indicate that the spermidine and putrescine transport system can be defined as a bacterial periplasmic transport system.     

Adjustment of polyamine contents in Escherichia coli.

Adjustment of polyamine contents in Escherichia coli was studied with strains of Escherichia coli producing normal (DR112) and excessive amounts of ornithine decarboxylase [DR112(pODC)] or S-adenosylmethionine decarboxylase [DR112(pSAMDC)]. Although DR112(pODC) produced approximately 70 times more ornithine decarboxylase than DR112 did, the amounts of polyamines in the cells of both strains did not change significantly. The amounts of polyamines in DR112(pODC) were adjusted by excretion of excessive amounts of putrescine to the medium. When ornithine was deficient in cells, polyamine contents in DR112(pODC) were much higher than those in DR112, although polyamine contents were low in both strains. This indicates that large amounts of ornithine decarboxylase increased the utilization of ornithine for putrescine synthesis. During ornithine deficiency, strain DR112 produced 3.4 times more ornithine decarboxylase. Strain DR112(pSAMDC) produced seven times more S-adenosylmethionine decarboxylase than DR112 did. In DR112(pSAMDC) an increase (40%) in spermidine content, a decrease (35%) in putrescine content, and no significant excretion of putrescine and spermidine were observed. The amount of ornithine decarboxylase in DR112(pSAMDC) was approximately 30% less than that in DR112. In addition, S-adenosylmethionine decarboxylase activity was strongly inhibited by spermidine. A possible regulatory mechanism to maintain polyamine contents in Escherichia coli is discussed based on the results.     

Evidence that putrescine modulates the higher plant photosynthetic proton circuit

The light reactions of photosynthesis store energy in the form of an electrochemical gradient of protons, or proton motive force (pmf), comprised of electrical (Δψ) and osmotic (ΔpH) components. Both components can drive the synthesis of ATP at the chloroplast ATP synthase, but the ΔpH component also plays a key role in regulating photosynthesis, down-regulating the efficiency of light capture by photosynthetic antennae via the q(E) mechanism, and governing electron transfer at the cytochrome b(6)f complex. Differential partitioning of pmf into ΔpH and Δψ has been observed under environmental stresses and proposed as a mechanism for fine-tuning photosynthetic regulation, but the mechanism of this tuning is unknown. We show here that putrescine can alter the partitioning of pmf both in vivo (in Arabidopsis mutant lines and in Nicotiana wild type) and in vitro, suggesting that the endogenous titer of weak bases such as putrescine represents an unrecognized mechanism for regulating photosynthetic responses to the environment.     

Regulation of polyamine synthesis in relation to putrescine and spermidine pools in Neurospora crassa.

Polyamine pools were measured under various conditions of high and low concentrations of cytosolic ornithine with the wild-type and mutant strains of Neurospora crassa. In minimal medium, the wild-type strain has 1 to 2 nmol of putrescine and approximately 14 nmol of spermidine per mg (dry weight); no spermine is found in N. crassa. Exogenous ornithine was found to cause a rapid, but quickly damped, increase in the rate of polyamine synthesis. This effect was greater in a mutant (ota) unable to catabolize ornithine. No turnover of polyamines was detected during exponential growth. Exogenous spermidine was not taken up efficiently by N. crassa; thus, the compound could not be used directly in studies of regulation. However, by nutritional manipulation of a mutant strain, aga, lacking arginase, cultures were starved for ornithine and thus ultimately for putrescine and spermidine. During ornithine starvation, the remaining putrescine pool was not converted to spermidine. The pattern of polyamine synthesis after restoration of ornithine to the polyamine-deprived aga strain indicated that, in vivo, spermidine regulates polyamine synthesis at the ornithine decarboxylase reaction. The results suggest that the regulatory process is a form of negative control which becomes highly effective when spermidine exceeds its normal level. The possible relationship between the regulation of polyamine synthesis and the ratio of free to bound spermidine is discussed.     

Effects of Ethyl and Benzyl Analogues of Spermine on Escherichia coli Peptidyltransferase Activity, Polyamine Transport, and Cellular Growth

Various ethyl and benzyl spermine analogues, including the anticancer agent N1,N12-bis(ethyl)spermine, were studied for their ability to affect the growth of cultured Escherichia coli cells, to inhibit [3H]putrescine and [3H]spermine uptake into cells, and to modulate the peptidyltransferase activity (EC 2. 3. 2. 12). Relative to other cell lines, growth of E. coli was uniquely insensitive to these analogues. Nevertheless, these analogues conferred similar modulation of in vitro protein synthesis and inhibition of [3H]putrescine and [3H]spermine uptake, as is seen in other cell types. Thus, both ethyl and benzyl analogues of spermine not only promote the formation and stabilization of the initiator ribosomal ternary complex, but they also have a sparing effect on the Mg2+ requirements. Also, in a complete cell-free protein-synthesizing system, these analogues at low concentrations stimulated peptide bond formation, whereas at higher concentrations, they inhibited the reaction. The ranking order for stimulation of peptide-bond formation by the analogues was N4,N9-dibenzylspermine > N4, N9-bis(ethyl)spermine congruent with N1-ethylspermine > N1, N12-bis(ethyl)spermine, whereas the order of analogue potency regarding the inhibitory effect was inverted, with inhibition constant values of 10, 3.1, 1.5, and 0.98 microM, respectively. Although the above analogues failed to interact with the putrescine-specific uptake system, they exhibited high affinity for the polyamine uptake system encoded by the potABCD operon. Despite this fact, none of the analogues could be internalized by the polyamine transport system, and therefore they could not influence the intracellular polyamine pools and growth of E. coli cells.     

Evidence that putrescine acts as an extracellular signal required for swarming in Proteus mirabilis

In a search for Proteus mirabilis genes that were regulated by cell-to-cell signalling, a lacZ fusion (cmr437::mini-Tn5lacZ) was identified that was repressed 10-fold by a self-produced extracellular signal from wild-type cells. However, the cmr437::mini-Tn5lacZ insertion itself led to a marked reduction in this extracellular repressing signal. The cmr437::mini-Tn5lacZ insertion was mapped to a speA homologue in P. mirabilis. Sequence analysis indicated that a speB homologue was encoded downstream of speA. Products of the SpeA and SpeB enzymes (agmatine and putrescine) were tested for repression of cmr437::lacZ. Agmatine did not have repressing activity. However, putrescine was an effective repressing molecule at concentrations down to 30 microM. A second prominent phenotype of the cmr437 (speA)::mini-Tn5lacZ insertion was a severe defect in swarming motility. This swarming defect was also observed in a strain containing a disruption of the downstream speB gene. Differentiation of the speB mutant to swarmer cells was delayed by two hours relative to wild-type cells. Furthermore, the speB mutant was unable to migrate effectively across agar surfaces and formed very closely spaced swarming rings. Exogenous putrescine restored both the normal timing of swarmer cell differentiation and the ability to migrate to speB mutants.     

Intracellular putrescine and spermidine deprivation induces increased uptake of the natural polyamines and methylglyoxal bis(guanylhydrazone).

Inhibition of polyamine synthesis by alpha-difluoromethylornithine in cultured Ehrlich ascites-carcinoma cells rapidly enhanced the uptake of exogenous putrescine, spermidine and spermine from the culture medium. In tumour cells exposed to the drug for 2 days, the intracellular concentration of spermidine was decreased to less than 10% of that found in untreated cells. However, the strikingly stimulated transport system brought the concentration of spermidine to the control values in less than 2h after supplementation of the cells with micromolar concentrations of the polyamine. In the absence of polyamine deprivation, tumour cells did not accumulate extracellular polyamines to any appreciable extent. Ascites-tumour cells deprived of putrescine and spermidine likewise concentrated methylglyoxal bis(guanylhydrazone) [1,1'-[methylethanedylidine)dinitrilo]diguanidine] at a greatly enhanced rate. A previous "priming of tumour cells with difluoromethylornithine followed by an exposure of the cells to methylglyoxal bis(guanylhydrazone) resulted in a marked and rapid anti-proliferative effect.     

Histatin 5 uptake by Candida albicans utilizes polyamine transporters Dur3 and Dur31 proteins

Histatin 5 (Hst 5) is a salivary gland-secreted cationic peptide with potent fungicidal activity against Candida albicans. Hst 5 kills fungal cells following intracellular translocation, although its selective transport mechanism is unknown. C. albicans cells grown in the presence of polyamines were resistant to Hst 5 due to reduced intracellular uptake, suggesting that this cationic peptide may enter candidal cells through native yeast polyamine transporters. Based upon homology to known Saccharomyces cerevisiae polyamine permeases, we identified six C. albicans Dur polyamine transporter family members and propose a new nomenclature. Gene deletion mutants were constructed for C. albicans polyamine transporters Dur3, Dur31, Dur33, Dur34, and were tested for Hst 5 sensitivity and uptake of spermidine. We found spermidine uptake and Hst 5 mediated killing were decreased significantly in Δdur3, Δdur31, and Δdur3/Δdur31 strains; whereas a DUR3 overexpression strain increased Hst 5 sensitivity and higher spermidine uptake. Treatment of cells with a spermidine synthase inhibitor increased spermidine uptake and Hst 5 killing, whereas protonophores and cold treatment reduced spermidine uptake. Inhibition assays showed that Hst 5 is a competitive analog of spermidine for uptake into C. albicans cells, and that Hst 5 Ki values were increased by 80-fold in Δdur3/Δdur31 cells. Thus, Dur3p and Dur31p are preferential spermidine transporters used by Hst 5 for its entry into candidal cells. Understanding of polyamine transporter-mediated internalization of Hst 5 provides new insights into the uptake mechanism for C. albicans toxicity, and further suggests design for targeted fungal therapeutic agents.     

Weissella halotolerans W22 combines arginine deiminase and ornithine decarboxylation pathways and converts arginine to putrescine

Aims: To demonstrate that the meat food strain Weissella halotolerans combines an ornithine decarboxylation pathway and an arginine deiminase (ADI) pathway and is able to produce putrescine, a biogenic amine. Evidence is shown that these two pathways produce a proton motive force (PMF). Methods and Results: Internal pH in W. halotolerans was measured with the sensitive probe 2′,7′–bis‐(2‐carboxyethyl)‐5(and‐6)‐carboxyfluorescein. Membrane potential was measured with the fluorescent probe 3,3′‐dipropylthiocarbocyanine iodine. Arginine and ornithine transport studies were made under several conditions, using cells loaded or not loaded with the biogenic amine putrescine. ADI pathway caused an increase in ΔpH dependent on the activity of F₀F₁ATPase. Ornithine decarboxylation pathway generates both a ΔpH and a ΔΨ. Both these pathways lead to the generation of a PMF. Conclusions: Weissella halotolerans W22 combines an ADI pathway and an ornithine decarboxylation pathway, conducing to the production of the biogenic amine putrescine and of a PMF. Transport studies suggest the existence of a unique antiporter arginine/putrescine in this lactic acid bacteria strain. Significance and Impact of the Study: The coexistence of two different types of amino acid catabolic pathways, leading to the formation of a PMF, is shown for a Weissella strain for the first time. Moreover, a unique antiport arginine/putrescine is hypothesized to be present in this food strain.     

The role of putrescine and the energy state of Escherichia coli in regulation of DNA topology during adaptation to oxidative stress]

An exponential-phase culture of E. coli responded to the addition of H2O2 by a decrease in DNA supercoiling induced by the lowering of the energy status of cells, potassium leakage, and breaking of polynucleotide chains. Extending the time of exposure of E. coli cells to hydrogen peroxide led to an increase in the intracellular pools of putrescine and potassium, promotion of cellular energy status, and the restoration of DNA supercoiling to values much in excess of the prestress level. The subsequent stabilization of the intracellular putrescine pool was accompanied by a release of this polyamine from the cell. Based on these results and those available in the literature, a mechanism of E. coli adaptation to oxidative stress is suggested that assigns roles to putrescine, potassium, and cellular energy status.