Essential,deadly, enigmatic: Polyamine metabolism and roles in fungal cells

Polyamines are essential metabolites found in all organisms. Intracellular polyamine levels are tightly maintained by biosynthesis, degradation, uptake and excretion processes that involve regulatory mechanisms – such as the antizyme inhibitory protein – that are conserved across the kingdoms of life, indicating that polyamine levels are critical to cell function. Nonetheless, the biochemical roles of polyamines and their involvement in numerous fundamental cellular processes including aging, cell cycle progression and growth only become apparent when polyamine homeostasis is perturbed. Thus, while polyamines are present in most cells and essential for cell growth, their biochemical functions are largely enigmatic. Studies in fungi have contributed to our basic understanding of polyamines, and might continue to bridge knowledge gaps regarding polyamine metabolism and cell function. Moreover, when considering the impact of fungi – directly or indirectly, for good or for ill – on human society, closing gaps in our understanding of polyamine functions in fungal physiology is an important goal in itself that might lead to the discovery of new targets for enhancing beneficial fungal interactions and diminishing those detrimental to crop and human health. To facilitate progress towards this prospect, here we appraise what is known about polyamine metabolism in fungi, how prevalent polyamines impact fungal physiology and metabolism, and how the levels of each polyamine are maintained in the fungal cell – thus pointing to how they might be perturbed.     

Selective regulation of polyamine metabolism with methylated polyamine analogues

Polyamine metabolism is intimately linked to the physiological state of the cell. Low polyamines levels promote growth cessation, while increased concentrations are often associated with rapid proliferation or cancer. Delicately balanced biosynthesis, catabolism, uptake and excretion are very important for maintaining the intracellular polyamine homeostasis, and deregulated polyamine metabolism is associated with imbalanced metabolic red/ox state. Although many cellular targets of polyamines have been described, the precise molecular mechanisms in these interactions are largely unknown. Polyamines are readily interconvertible which complicate studies on the functions of the individual polyamines. Thus, non-metabolizable polyamine analogues, like carbon-methylated analogues, are needed to circumvent that problem. This review focuses on methylated putrescine, spermidine and spermine analogues in which at least one hydrogen atom attached to polyamine carbon backbone has been replaced by a methyl group. These analogues allow the regulation of both metabolic and catabolic fates of the parent molecule. Substituting the natural polyamines with methylated analogue(s) offers means to study either the functions of an individual polyamine or the effects of altered polyamine metabolism on cell physiology. In general, gem-dimethylated analogues are considered to be non-metabolizable by polyamine catabolizing enzymes spermidine/spermine-N ¹-acetyltransferase and acetylpolyamine oxidase and they support short-term cellular proliferation in many experimental models. Monomethylation renders the analogues chiral, offering some advantage over gem-dimethylated analogues in the specific regulation of polyamine metabolism. Thus, methylated polyamine analogues are practical tools to meet existing biological challenges in solving the physiological functions of polyamines.     

Polyamine levels as related to growth,differentiation and senescence in protoplast-derived cultures of Vigna aconitifolia and Avena sativa

We have previously reported that aseptically cultured mesophyll protoplasts of Vigna divide rapidly and regenerate into complete plants, while mesophyll protoplasts of Avena divide only sporadically and senesce rapidly after isolation. We measured polyamine titers in such cultures of Vigna and Avena, to study possible correlations between polyamines and cellular behavior. We also deliberately altered polyamine titer by the use of selective inhibitors of polyamine biosynthesis, noting the effects on internal polyamine titer, cell division activity and regenerative events.In Vigna cultures, levels of free and bound putrescine and spermidine increased dramatically as cell division and differentiation progressed. The increase in bound polyamines was largest in embryoid-forming callus tissue while free polyamine titer was highest in root-forming callus. In Avena cultures, the levels of total polyamines decreased as the protoplast senesced. The presence of the inhibitors -difluoromethyl-arginine (specific inhibitor of arginine decarboxylase) and dicyclohexylamine (inhibitor of spermidine synthase) reduced cell division and organogenesis in Vigna cultures. Addition of low concentration of polyamines to such cultures containing inhibitors or removal of inhibitors from the culture medium restored the progress of growth and differentiation with concomitant increase in polyamine levels.     

Increased urinary polyamine excretion during liver regeneration

Tumor growth is a process associated with both cell proliferation and cell death. The increase in polyamine excretion observed in cancer patients may be partly due to leakage of polyamines from proliferating cells, which all contain an elevated polyamine level. However, the increased polyamine excretion may also be due to a release of polyamines from dead or damaged cells. To determine if actively proliferating cells release polyamines, the urinary polyamine excretion was measured during a proliferative event associated with minimal cell necrosis. Rats subjected to partial hepatectomy were used as an experimental model. Their 24-hr urines were collected during 6 consecutive days following the operation. Rat liver regeneration is characterized by a proliferation wave with a maximum 24 hr after the operation. The 24-hr urinary putrescine excretion reached a maximum 2 days after the operation and then decreased. The 24-hr urinary spermidine excretion increased during the second day following operation and remained essentially unchanged during the rest of the experimental period. Although there is an apparent correlation between elevated urinary polyamine excretion and the proliferative activity, concurrent permeability changes and necrotic events may contribute to the increase in polyamine excretion.     

Antizyme and antizyme inhibitor activities influence cellular responses to polyamine analogs

Summary. Close structural analogs of spermidine and spermine, polyamine mimetics, are potential chemotheraputic agents as they depress cellular polyamines required for tumor growth. Specific mimetic analogs stimulate synthesis of the regulatory protein antizyme (AZ), which not only inactivates the initial enzyme in polyamine biosynthesis but also inhibits cellular uptake of polyamines. The role of AZ induction in influencing cellular uptake of representative analogs was investigated using three analogs produced by Cellgate Inc., CGC-11047, CGC-11102, and CGC-11144, which exhibit markedly distinct AZ-inducing potential. An inverse correlation was noted between the AZ-inducing activity of a compound and the steady-state levels accumulated in cells. As some tumor cells over express AZI as a means of enhancing the polyamines required for aggressive growth, analog sensitivity was examined in transgenic CHO cells expressing exogenous antizyme inhibitor protein (AZI). Although AZI over expression increased cell sensitivity to analogs, the degree of this affect varied with the analog used.     

Comparative role of polyamines division and plastid differentiation of Euglena gracilis

Regulation of polyamine biosynthesis during growth and differentation of Euglena gracilis was investigated. Increased activity of l-ornithine decarboxylase (EC 4.1.1.17), the enzyme which catalyzes the initial step in polyamine synthesis in Euglena, and accumulation of polyamines were observed prior to DNA replication in synchronous cultures of heterotropically or photoautotrophically grown cells. In photoatotrophic cells three maxima of polyamine synthesis were observed during the light period of the cell cycle. The transition from quiescence of active growth was accompanied in heterotrophic Euglena by a very large stimulation of ornithine decaboxylase activity and polyamine synthesis; the decrease in growth potential of these cells was correlated with a decrease in polyamine levels. In contrast, differentiation of Euglena, i.e., a shift from heterotrophic to photoautotrophic mode of living in the absence of division, led only to a minor stimulation of polyamine biosynthesis. α-Methylornithine, an inhibitor of ornithine decarboxylase, blocked the growth of heterotrophic Euglena, and depletion of intracellular polyamines decreased the differentiation rate. Both events could be reversed only by addition of putrescine to the growth medium. This study suggests that Euglena requires a minimal intracellular level of polyamines to grow and differentiate under optimal conditions. This requirement seems to be more stringent for cell division.     

Pattern and concentration of free and acetylated polyamines in urine of cirrhotic patients.

The pattern and concentration of urinary, free, monoacetylated and total polyamines were determined in 31 cirrhotic patients, divided into three classes according to Child's classification, and in 28 healthy subjects. Cirrhotic patients had increased levels of free, monoacetylated and total polyamines. They also showed a significant increase in N1-acetylspermidine to N8-acetylspermidine molar ratio. Urinary polyamine excretion was not related to the severity of liver disease nor to the values of laboratory liver function tests. Furthermore, polyamine excretion was not significantly different in cirrhotics with or without diabetes or IGT, while plasma insulin and glucagon levels were increased in all cirrhotic patients. The results suggest that enhanced polyamine biosynthesis and catabolism, particularly N1-acetylation, occur in cirrhotic patients, probably due to hepatic regeneration and/or increased levels of insulin and glucagon.     

The role of polyamines in animal cell physiology

The ubiquitous distribution of polyamines in nature suggests that they fulfil some fundamental role(s) in living organisms. In animal cells, polyamine content closely parallels changes in the rate of cell proliferation so that the highest content is always observed in rapidly growing cells. The activity of ornithine decarboxylase (which is the first enzyme in the polyamine biosynthetic pathway) has been found to increase significantly in many systems shortly after exposure to hormones. Also, addition of polyamines greatly stimulates cell-free macromolecular synthesis. Observations such as these have suggested that polyamine accumulation stimulates cell growth and is important in the regulation of macromolecular biosynthesis. However, it is also possible to interpret such data as evidence that polyamine accumulation is the result, not the cause, of increased cell growth. This review supports the latter concept and re-examines the significance of the early induction of ornithine decarboxylase activity and of the stimulatory effects of exogenous polyamine on macromolecular synthesis. It is proposed that the polyamines are important only in maintaining cell growth that has already been stimulated by other factors and that their biosynthesis is to a large extent determined by the accumulation of RNA in the cell.     

Inducible expression of antizyme 1 in prostate cancer cell lines after lentivirus mediated gene transfer

The prostate has the highest level of polyamines among all tissues, and it is the only tissue in which polyamines are purposely synthesized for export. It has been suggested that the high local polyamine concentrations suppress cell growth of primary prostatic carcinomas and that this growth control is lost when cancer cells metastasize. It has also been shown that the sensitivity to polyamine-induced growth arrest correlates with antizyme induction in prostate carcinoma cell lines. In this study, we evaluated the sensitivity of poorly metastatic (LNCaP) and highly metastatic (DU145) prostate cancer cell lines to conditional antizyme 1 over-expression. Antizyme 1 induction resulted in a marked loss of ODC activity and polyamine uptake in both cell lines. However, the proliferation of LNCaP cells was repressed by antizyme 1 induction, whereas the proliferation of DU 145 cells was not affected. Neither cell line showed any reduction in polyamine pools after manipulation nor did polyamine addition into the medium save the LNCaP cells from the growth retardation. The growth inhibition of LNCaP cells was accompanied by accumulation of cells in the G1 phase and depletion of cyclin E1 protein. These results confirm that different prostate cancer cell lines show diverse sensitivities to antizyme 1 which may not be directly polyamine related. The high gene transfer capacity of the used lentiviral vector makes the present approach a useful tool to study the therapeutic potential of antizyme 1 both in cell cultures and experimental animals.     

Polyamines are needed for the differentiation of 3T3-L1 fibroblasts into adipose cells

When non-proliferating 3T3-L1 fibroblasts were stimulated to differentiate into adipose cells, there was a dramatic increase in the intracellular level of the polyamine, spermidine. Addition of α-difluoromethylornithine, an inhibitor of polyamine biosynthesis, depleted the cellular polyamines and prevented triglyceride accumulation and differentiation. The inhibitory effect of α-difluoromethylorinithine was completely abolished by provision of spermidine or putrescine. This suggests that polyamines are needed in the processes of differentiation as well as their established requirement for cell growth.     

Legionella pneumophila requires polyamines for optimal intracellular growth

The Gram-negative intracellular pathogen Legionella pneumophila replicates in a membrane-bound compartment known as the Legionella-containing vacuole (LCV), into which it abundantly releases its chaperonin, HtpB. To determine whether HtpB remains within the LCV or reaches the host cell cytoplasm, we infected U937 human macrophages and CHO cells with L. pneumophila expressing a translocation reporter consisting of the Bordetella pertussisa denylate cyclase fused to HtpB. These infections led to increased cyclic AMP levels, suggesting that HtpB reaches the host cell cytoplasm. To identify potential functions of cytoplasmic HtpB, we expressed it in the yeast Saccharomyces cerevisiae, where HtpB induced pseudohyphal growth. A yeast-two-hybrid screen showed that HtpB interacted with S-adenosylmethionine decarboxylase (SAMDC), an essential yeast enzyme (encoded by SPE2) that is required for polyamine biosynthesis. Increasing the copy number of SPE2 induced pseudohyphal growth in S. cerevisiae; thus, we speculated that (i) HtpB induces pseudohyphal growth by activating polyamine synthesis and (ii) L. pneumophila may require exogenous polyamines for growth. A pharmacological inhibitor of SAMDC significantly reduced L. pneumophila replication in L929 mouse cells and U937 macrophages, whereas exogenously added polyamines moderately favored intracellular growth, confirming that polyamines and host SAMDC activity promote L. pneumophila proliferation. Bioinformatic analysis revealed that most known enzymes required for polyamine biosynthesis in bacteria (including SAMDC) are absent in L. pneumophila, further suggesting a need for exogenous polyamines. We hypothesize that HtpB may function to ensure a supply of polyamines in host cells, which are required for the optimal intracellular growth of L. pneumophila.     

AGP2 encodes the major permease for high affinity polyamine import in Saccharomyces cerevisiae

Polyamines play essential functions in many aspects of cell biology. Plasma membrane transport systems for the specific uptake of polyamines exist in most eukaryotic cells but have been very recently identified at the molecular level only in the parasite Leishmania. We now report that the high affinity polyamine permease in Saccharomyces cerevisiae is identical to Agp2p, a member of the yeast amino acid transporter family that was previously identified as a carnitine transporter. Deletion of AGP2 dramatically reduces the initial velocity of spermidine and putrescine uptake and confers strong resistance to the toxicity of exogenous polyamines, and transformation with an AGP2 expression vector restored polyamine transport in agp2delta mutants. Yeast mutants deficient in polyamine biosynthesis required >10-fold higher concentrations of exogenous putrescine to restore cell proliferation upon deletion of the AGP2 gene. Disruption of END3, a gene required for an early step of endocytosis, increased the abundance of Agp2p, an effect that was paralleled by a marked up-regulation of spermidine transport velocity. Thus, AGP2 encodes the first eukaryotic permease that preferentially uses spermidine over putrescine as a high affinity substrate and plays a central role in the uptake of polyamines in yeast.     

Effect of acetylpolyamines on in vitro protein synthesis and on the growth of a polyamine-requiring mutant of Escherichia coli

The functions of acetylpolyamines were examined with respect to stimulation of protein synthesis and cell growth. Unlike polyamines, acetylpolyamines could not lower the optimal Mg2+ concentration of protein synthesis, and the degree of stimulation of protein synthesis by acetylpolyamines was small. The addition of N1-acetylspermine did not stimulate cell growth of a polyamine-requiring mutant of Escherichia coli MA261, although acetylspermine was accumulated in the cells. Acetylspermine did not interfere with polyamine stimulation of protein synthesis and cell growth of E. coli MA261. The binding of acetylpolyamines to RNA was very weak, and the binding of polyamines to RNA was not disturbed significantly by the presence of acetylpolyamines. When the growth of E. coli MA261 was stimulated by addition of polyamines, significant amounts of acetylpolyamines were also formed in the cells. These results suggest that acetylation of polyamines, together with polyamine excretion, may regulate the intracellular level of the parent polyamines when excess amounts of polyamines accumulate intracellularly.     

Polyamines and colon cancer

In colon cancer, the activities of polyamine-synthesizing enzymes and polyamine content are increased 3-4-fold over that found in the equivalent normal colonic mucosa, and polyamines have even been attributed as markers of neoplastic proliferation in the colon. Furthermore, and in contrast with all other cell systems in the body, normal and neoplastic cells in the colon are exposed to high concentrations of putrescine from the lumen, synthesized by colonic microflora. While such a high polyamine supply may be of benefit in non-neoplastic colonic mucosal growth, the role of luminal polyamines in colon cancer is a clear concern. Luminal polyamines are readily taken up by neoplastic colonocytes, they are utilized in full to support neoplastic growth, and their uptake is strongly up-regulated by the mitogens known to play an important role in colonic carcinogenesis. Inhibition of polyamine synthesis and their uptake, impaired utilization of exogenous polyamines, and enhanced catabolism of polyamines in neoplastic colonocytes are therefore logical approaches in the chemoprevention of colorectal cancer.     

Lack of a correlation between polyamine synthesis and DNA synthesis by cultured rat liver cells and fibroblasts

Growth stimulation of either fetal rat liver cells or rat embryo fibroblasts in culture results in considerable increases in intracellular polyamine levels as cells proceed through the cell cycle. Treatment of such cell cultures with appropriate levels of two inhibitors of polyamine synthesis, namely α-hydrazino ornithine and methylglyoxal bis(guanylhydrazone), can essentially completely block these increases in cellular polyamine content. Under such conditions, where the elevation in intracellular polyamine content is prevented, cell cultures are nevertheless able to initiate DNA synthesis and subsequently synthesize DNA at rates comparable to untreated control cultures that have been growth-stimulated. These two cell types therefore contain sufficient polyamines when in a resting state (G₁) to enable them to enter from G₁ into S phase and traverse S phase at normal rates in the absence of further polyamine synthesis. The recruitment of cells into the first cell cycle, through serum stimulation of growth, therefore appears not to be mediated or regulated by the increases in intracellular levels of polyamines that occurs under these conditions. Conversely, the arrest of growth of these cell types resulting from serum deprivation is not mediated by a limitation of intracellular polyamine content.     

Polyamine uptake by DUR3 and SAM3 in Saccharomyces cerevisiae

It has been reported that GAP1 and AGP2 catalyze the uptake of polyamines together with amino acids in Saccharomyces cerevisiae. We have looked for polyamine-preferential uptake proteins in S. cerevisiae. DUR3 catalyzed the uptake of polyamines together with urea, and SAM3 was found to catalyze the uptake of polyamines together with S-adenosylmethionine, glutamic acid, and lysine. Polyamine uptake was greatly decreased in both DUR3- and SAM3-deficient cells. The K(m) values for putrescine and spermidine of DUR3 were 479 and 21.2 mum, respectively, and those of SAM3 were 433 and 20.7 mum, respectively. Polyamine stimulation of cell growth of a polyamine requiring mutant, which is deficient in ornithine decarboxylase, was not influenced by the disruption of GAP1 and AGP2, but it was diminished by the disruption of DUR3 and SAM3. Furthermore, the polyamine stimulation of cell growth of a polyamine-requiring mutant was completely inhibited by the disruption of both DUR3 and SAM3. The results indicate that DUR3 and SAM3 are major polyamine uptake proteins in yeast. We previously reported that polyamine transport protein kinase 2 regulates polyamine transport. It was found that DUR3 (but not SAM3) was activated by phosphorylation of Thr(250), Ser(251), and Thr(684) by polyamine transport protein kinase 2.     

Systemic overexpression of antizyme 1 in mouse reduces ornithine decarboxylase activity without major changes in tissue polyamine homeostasis

Polyamines, spermidine, spermine and their precursor putrescine, are ubiquitous cell components essential for normal cell growth. Increased polyamine levels and enhanced biosynthesis have been associated with malignant transformation and tumor formation, and thus, the polyamines have been considered to be a meaningful target to cancer therapies. However, clinical cancer treatment trials using inhibitors of polyamine synthesis have been unsuccessful probably due to compensatory uptake of polyamines from extracellular sources. The antizyme proteins regulate both polyamine biosynthesis and transport, and thus, the antizymes could provide an efficient approach to control cellular proliferation compared to the mere inhibition of biosynthesis. To define the role of antizymes in proliferative processes associated with the whole animal, we have generated transgenic mice overexpressing mouse antizyme 1 gene under its own regulatory sequences. Antizyme 1 protein was abundantly expressed in various organs and the expressed antizyme protein was functional as ornithine decarboxylase activity was significantly reduced in all tissues analyzed. However, antizyme 1 overexpression caused only minor changes in tissue polyamine levels demonstrating the challenges in using the “antizyme approach” to deplete polyamines in a living animal. Neither were there any changes in cellular proliferation in the proliferative tissues of transgenic animals. Interestingly though, there was occurrence of abnormally high level of apoptosis in the non-proliferating part of the colon epithelia. Otherwise, the transgenic founder mice appeared healthy and out of seven founders six were fertile. However, none of the founders could transmit the transgene suggesting that the antizyme 1 overexpression may be deleterious to transgenic gametes.     

Induction of hypersensitive cell death by hydrogen peroxide produced through polyamine degradation in tobacco plants

Screening immediate-early responding genes during the hypersensitive response (HR) against tobacco mosaic virus infection in tobacco (Nicotiana tabacum) plants, we identified a gene encoding ornithine decarboxylase. Subsequent analyses showed that other genes involved in polyamine biosynthesis were also up-regulated, resulting in the accumulation of polyamines in apoplasts of tobacco mosaic virus-infected leaves. Inhibitors of polyamine biosynthesis, alpha-difluoromethyl-ornithine, however, suppressed accumulation of polyamines, and the rate of HR was reduced. In contrast, polyamine infiltration into a healthy leaf induced the generation of hydrogen peroxide and simultaneously caused HR-like cell death. Polyamine oxidase activity in the apoplast increased up to 3-fold that of the basal level during the HR, and its suppression with a specific inhibitor, guazatine, resulted in reduced HR. Because it is established that hydrogen peroxide is one of the degradation products of polyamines, these results indicate that one of the biochemical events in the HR is production of polyamines, whose degradation induces hydrogen peroxide, eventually resulting in hypersensitive cell death.     

Casein kinase II and polyamines may interact in the response of adrenocortical cells to their trophic hormone

The ubiquitous casein kinase II (CKII) has been shown to accumulate in the cell nuclear compartment, following exposure to extracellular growth stimuli (O. Filhol et al., Biochemistry, 1990, 29, 9928-9936). The aim of the present study was to examine whether intracellular polyamines, whose levels are increased under similar conditions, could be related to this process. It is shown that (i) CKII accumulates in nuclei of adrenocortical cells exposed to their trophic hormone ACTH; (ii) this CKII nuclear translocation is concomitant with an increase in nuclear polyamine content resulting from ACTH-induced polyamine synthesis; (iii) selective inhibition of polyamine biosynthesis by DFMO results in the inhibition of both ACTH-induced cellular polyamine increase and CKII nuclear accumulation. These observations suggest that polyamines may be examined as intracellular messengers in the regulation of CKII activity and subcellular distribution in the cell response to growth factors and trophic hormones.