D-Galactose uptake is nonfunctional in the conidiospores of Aspergillus niger

The majority of black Aspergilli (Aspergillus section Nigri), including Aspergillus niger, as well as many other Ascomycetes fail to germinate on d-galactose as a sole carbon source. Here, we provide evidence that the ability of A. niger to transport D-galactose is growth stage dependent, being absent in the conidiospores but present in the mycelia. Despite earlier claims, we could identify galactokinase activity in growing cells and all genes of the Leloir pathway (responsible for channelling D-galactose into the EMP pathway) are well induced on D-galactose (and also on lactose, D-xylose and L-arabinose) in the mycelial stage. Expression of all Leloir pathway genes was also detectable in conidiospores, although galE (encoding a galactokinase) and galD (encoding a galactose-1-phosphate uridylyl transferase) were expressed poorly. These results suggest that the D-galactose-negative phenotype of A. niger conidiospores may be due to the lack of inducer uptake.     

Primary roles of two dehydrogenases in the mannitol metabolism and multi-stress tolerance of entomopathogenic fungus Beauveria bassiana

Knockout and complement mutants of mannitol-1-phosphate dehydrogenase (MPD) and mannitol dehydrogenase (MTD) were constructed to probe the roles of both enzymes in the mannitol metabolism and multi-stress tolerances of entomopathogenic fungus Beauveria bassiana. Compared with wild-type and complement mutants, ΔBbMPD lost 99.5% MPD activity for reducing fructose-6-phosphate to mannitol-1-phosphate while ΔBbMTD lost 78.9% MTD activity for oxidizing mannitol to fructose. Consequently, mannitol contents in mycelia and conidia decreased 68% and 83% for ΔBbMPD, and 16% and 38% for ΔBbMTD, accompanied by greatly enhanced trehalose accumulations due to 81-87% decrease in their neutral trehalase expression. Mannitol as mere carbon source in a nitrate-based minimal medium suppressed the colony growth of ΔBbMTD instead of ΔBbMPD, and delayed more conidial germination of ΔBbMTD than ΔBbMPD. Based on median lethal responses, conidial tolerances to H(2) O(2) oxidation, UV-B irradiation and heat stress at 45°C decreased 38%, 39% and 22% in ΔBbMPD, and 18%, 16% and 11% in ΔBbMTD respectively. Moreover, ΔBbMPD and ΔBbMTD lost 14% and 7% of their virulence against Spodoptera litura larvae respectively. Our findings highlight the primary roles of MPD and MTD in mannitol metabolism and their significant contributions to multi-stress tolerances and virulence influential on the biocontrol potential of B.bassiana.     

Characteristics of exogenous dormancy of Aspergillus niger conidia]

Aspergillus niger conidia are characterized by exogenous dormancy: the first stage of their germination is accomplished in twice distilled water. However, germ tube formation requires the availability of carbon and nitrogen sources. Exogenous dormancy in A. niger conidia exhibits the following peculiar features: (i) nitrogen-containing substances are active stimulators of germination; (ii) temperature-dependent changes in the lipid bilayer and in the neutral lipid composition of conidia are virtually identical to those occurring in growing mycelium under temperature stress; and (iii) the spore viability threshold does not exceed 45 degrees C; i.e., the spores are more heat-resistant than the mycelium, but they are less heat-resistant than the spores that are in the state of endogenous dormancy. According to the current classification of the types of cell metabolism arrest, the exogenous dormancy of A. niger conidia resembles the pattern of metabolism characteristic of vegetative cells during the idiophase.     

Glucose oxidase synthesis by Aspergillus niger GIV-10 on starch.

The effect of various kinds of starch, as the sole source of organic carbon, on the biosynthesis of glucose oxidase by A. niger GIV-10 was examined. A. niger grown on 6% wheat starch medium provided extracellular and intracellular glucose oxidase with the highest enzymatic activities. A new method of intracellular glucose oxidase extraction (without disruption of mycelium), developed and discussed in this paper, increased 2 to 3.8-times glucose oxidase yield, as compared to that described earlier.     

Spores of Aspergillus niger as reservoir of glucose oxidase synthesized during solid-state fermentation and their use as catalyst in gluconic acid production

AIMS: To exploit conidiospores of Aspergillus niger as a vector for glucose oxidase extraction from solid media, and their direct use as biocatalyst in the bioconversion of glucose to gluconic acid. METHODS AND RESULTS: Spores of A. niger (200 h old) were shown to fully retain all the glucose oxidase synthesized by the mycelium during solid-state fermentation (SSF). They acted as catalyst and carried out the bioconversion reaction effectively, provided they were permeabilized by freezing and thawing. Glucose oxidase activity was found retained in the spores even after repeated washings. Average rate of reaction was 1.5 g l(-1) h(-1) with 102 g l(-1) of gluconic acid produced out of 100 g l(-1) glucose consumed after approx. 100 h reaction, which corresponded to a molar yield close to 93%. These results were obtained with permeabilized spores in the presence of a germination inhibitor, sodium azide. CONCLUSIONS: Spores of A. niger served as efficient catalyst in the model bioconversion reaction after permeabilization. SIGNIFICANCE AND IMPACT OF THE STUDY: To our knowledge, this is the first detailed study on the ability of A. niger spores to act as reservoir of enzyme synthesized during SSF without its release into solid media. Use of this material served as an innovative concept for enzyme extraction and purification from a solid medium. Moreover, this approach could compete efficiently with the conventional use of mycelial form of the fungus in gluconic acid production.     

Regulation of mannitol biosynthesis and degradation by Cryptococcus neoformans.

Cryptococcus neoformans, an encapsulated yeast that is an opportunistic pathogen of AIDS patients, produced and secreted mannitol when incubated with an appropriate carbon source. Glucose, fructose, and mannose were good growth substrates and were converted to mannitol. Maltose and xylose were good growth substrates but were not converted to mannitol. Cells of C. neoformans that were grown on a non-mannitol-generating carbon source, such as peptone or xylose, were able to convert glucose to mannitol only after a prolonged lag period in the presence of glucose. It was concluded that the enzymes of the mannitol biosynthetic pathway were not constitutively expressed but were induced in response to glucose or to a glucose metabolite. Enzymes required to catabolize mannitol, however, were constitutively expressed. The production of mannitol was inhibited by anaerobiosis, by the respiratory poison rotenone, and by polyethylenesulfonate, a specific inhibitor of fungal NADP-dependent dehydrogenases. When cells were incubated with deuterated glucose, the deuterium content of the mannitol produced was much lower than that of the glucose precursor, indicating that the glucose was diluted by an intracellular pool of an intermediate. We had previously shown that C. neoformans contains a large intracellular pool of glucose 6-phosphate, and we now conclude that this pool of glucose 6-phosphate is metabolically active.     

Gas Exchange and Carbon Partitioning in the Leaves of Celery (Apium graveolens L.) at Various Levels of Root Zone Salinity

Both mannitol and sucrose (Suc) are primary photosynthetic products in celery (Apium graveolens L.). In other biological systems mannitol has been shown to serve as a compatible solute or osmoprotectant involved in stress tolerance. Although mannitol, like Suc, is translocated and serves as a reserve carbohydrate in celery, its role in stress tolerance has yet to be resolved. Mature celery plants exposed to low (25 mM NaCl), intermediate (100 mM NaCl), and high (300 mM NaCl) salinities displayed substantial salt tolerance. Shoot fresh weight was increased at low NaCl concentrations when compared with controls, and growth continued, although at slower rates, even after prolonged exposure to high salinities. Gas-exchange analyses showed that low NaCl levels had little or no effect on photosynthetic carbon assimilation (A), but at intermediate levels decreases in stomatal conductance limited A, and at the highest NaCl levels carboxylation capacity (as measured by analyses of the CO2 assimilation response to changing internal CO2 partial pressures) and electron transport (as indicated by fluorescence measurements) were the apparent prevailing limits to A. Increasing salinities up to 300 mM, however, increased mannitol accumulation and decreased Suc and starch pools in leaf tissues, e.g. the ratio of mannitol to Suc increased almost 10-fold. These changes were due in part to shifts in photosynthetic carbon partitioning (as measured by 14C labeling) from Suc into mannitol. Salt treatments increased the activity of mannose-6-phosphate reductase (M6PR), a key enzyme in mannitol biosynthesis, 6-fold in young leaves and 2-fold in fully expanded, mature leaves, but increases in M6PR protein were not apparent in the older leaves. Mannitol biosynthetic capacity (as measured by labeling rates) was maintained despite salt treatment, and relative partitioning into mannitol consequently increased despite decreased photosynthetic capacity. The results support a suggested role for mannitol accumulation in adaptation to and tolerance of salinity stress.     

Mannitol metabolism in the phytopathogenic fungus Alternaria alternata

Mannitol metabolism in fungi is thought to occur through a mannitol cycle first described in 1978. In this cycle, mannitol 1-phosphate 5-dehydrogenase (EC 1.1.1.17) was proposed to reduce fructose 6-phosphate into mannitol 1-phosphate, followed by dephosphorylation by a mannitol 1-phosphatase (EC 3.1.3.22) resulting in inorganic phosphate and mannitol. Mannitol would be converted back to fructose by the enzyme mannitol dehydrogenase (EC 1.1.1.138). Although mannitol 1-phosphate 5-dehydrogenase was proposed as the major biosynthetic enzyme and mannitol dehydrogenase as a degradative enzyme, both enzymes catalyze their respective reverse reactions. To date the cycle has not been confirmed through genetic analysis. We conducted enzyme assays that confirmed the presence of these enzymes in a tobacco isolate of Alternaria alternata. Using a degenerate primer strategy, we isolated the genes encoding the enzymes and used targeted gene disruption to create mutants deficient in mannitol 1-phosphate 5-dehydrogenase, mannitol dehydrogenase, or both. PCR analysis confirmed gene disruption in the mutants, and enzyme assays demonstrated a lack of enzymatic activity for each enzyme. GC-MS experiments showed that a mutant deficient in both enzymes did not produce mannitol. Mutants deficient in mannitol 1-phosphate 5-dehydrogenase or mannitol dehydrogenase alone produced 11.5 and 65.7 %, respectively, of wild type levels. All mutants grew on mannitol as a sole carbon source, however, the double mutant and mutant deficient in mannitol 1-phosphate 5-dehydrogenase grew poorly. Our data demonstrate that mannitol 1-phosphate 5-dehydrogenase and mannitol dehydrogenase are essential enzymes in mannitol metabolism in A. alternata, but do not support mannitol metabolism operating as a cycle.     

Spatial and Developmental Differentiation of Mannitol Dehydrogenase and Mannitol-1-Phosphate Dehydrogenase in Aspergillus niger

The presence of a mannitol cycle in fungi has been subject to discussion for many years. Recent studies have found no evidence for the presence of this cycle and its putative role in regenerating NADPH. However, all enzymes of the cycle could be measured in cultures of Aspergillus niger. In this study we have analyzed the localization of two enzymes from the pathway, mannitol dehydrogenase and mannitol-1-phosphate dehydrogenase, and the expression of their encoding genes in nonsporulating and sporulating cultures of A. niger. Northern analysis demonstrated that mpdA was expressed in both sporulating and nonsporulating mycelia, while expression of mtdA was expressed only in sporulating mycelium. More detailed studies using green fluorescent protein and dTomato fused to the promoters of mtdA and mpdA, respectively, demonstrated that expression of mpdA occurs in vegetative hyphae while mtdA expression occurs in conidiospores. Activity assays for MtdA and MpdA confirmed the expression data, indicating that streaming of these proteins is not likely to occur. These results confirm the absence of the putative mannitol cycle in A. niger as two of the enzymes of the cycle are not present in the same part of A. niger colonies. The results also demonstrate the existence of spore-specific genes and enzymes in A. niger.Mannitol has been described as one of the main compatible solutes in fungi (20) and may play a role as a storage carbon source (3) or a protectant against a variety of stresses (10, 16, 20, 22). Mannitol metabolism in fungi has been the subject of study for decades. It was proposed to exist in the form of a cyclic pathway, the mannitol cycle (9). This cycle consists of four steps enabling the conversion of fructose into mannitol and back to fructose (Fig. 1). The main role proposed for this cycle was regenerating NADPH (9, 10). Subsequently, many studies have questioned the existence of a mannitol cycle (reviewed in reference 20), and it has been shown that a mannitol cycle is not involved in NADPH regeneration in Stagonospora nodorum (19), Aspergillus niger (16), and Alternaria alternata (21). However, all enzymes of the cycle were detected in both sporulating and nonsporulating mycelia in A. niger (16), suggesting that a cycle could operate in this fungus. Fungi are able to use mannitol as a sole carbon source but do so in various ways (7).Open in a separate windowFig. 1.Putative mannitol cycle in fungi as proposed by Hult and Gatenbeck (9). HXK, hexokinase (EC 2.7.1.1); MTD, mannitol dehydrogenase (EC 1.1.1.138); MPD, mannitol-1-phosphate dehydrogenase (EC 1.1.1.17); MPP, mannitol-1-phosphate phosphatase (EC 3.1.3.22).d-Mannitol plays an important role in germination of Aspergillus conidia. In A. niger (23) and Aspergillus oryzae (8), mannitol accumulates in conidiospores and is utilized during the initial stages of germination. Production of mannitol appears to be largely dependent on mannitol-1-phosphate dehydrogenase (MPD) while mannitol dehydrogenase (MTD) contributes to a lesser extent (16, 19, 20).In this study we demonstrate that MTD and MPD as well as the expression of the corresponding genes (mtdA and mpdA) are spatially separated in colonies of A. niger. This demonstrates that a mannitol cycle does not exist in this fungus and shows that spores express specific genes that are involved in germination.     

黑曲霉组成型表面展示南极假丝酵母脂肪酶B及其发酵调控

黑曲霉表面展示南极假丝酵母脂肪酶B(CALB)可有效应用于食品、化妆品、医药等行业。以黑曲霉Aspergillus niger SH-1为宿主细胞构建诱导型糖化酶基因启动子表面展示CALB,在较高浓度葡萄糖碳源的发酵中CALB表达会受到抑制,发酵后期菌体容易出现菌丝断裂和展示酶活力下降等问题。采用组成型3-磷酸甘油醛脱氢酶基因启动子替代诱导型糖化酶基因启动子的细胞表面展示CALB黑曲霉菌株可有效解决上述问题,该菌株不但可以利用葡萄糖,而且还能利用木糖为发酵碳源,以木糖为碳源发酵在144 h展示酶水平达到1 100.28 U/g。文中探讨了甘蔗渣水解液发酵生产黑曲霉表面展示CALB,初步达到预期的结果,为甘蔗渣的综合利用提供了新途径。     

Effect of carbon sources on the biosynthesis of ergot alkaloids and the activity of carbon metabolism enzymes in Penicillium sizovae

The study was aimed at finding out how different carbon sources influenced the growth of Penicillium sizovae, the biosynthesis of epoxyagroclavine-1 and agroclavine-1 as well as the activity of key enzymes involved in the citric acid cycle, the pentose phosphate pathway and the glyoxylate cycle. The fungal growth was shown to depend on the carbohydrate substrate: it had a two-phase profile when P. sizovae was cultivated on mannitol and glucose, but not on sorbitol. The quantitative content and composition of ergoalkaloids depended on the combination of carbohydrate and organic acid substrates. The overall productivity of the mycelium (epoxyagroclavin-1+agroclavin-1) was highest when mannitol and fumarate were used. A medium with sorbitol and fumaric acid was very selective in terms of epoxyagroclavine-1 synthesis. The high level of alkaloid biosynthesis correlated with the active functioning of the pentose phosphate cycle and with the low activity of the CAC.     

Mannitol Metabolism in Celery Stressed by Excess Macronutrients

The effect of excess macronutrients in the root environment on mannitol and sucrose metabolism was investigated in celery (Apium graveolens L. var dulce [Mill.] Pers.). Plant growth was inhibited progressively as macronutrient concentration in the media, as measured by electrical conductivity (E.C.), increased from 1.0 to 11.9 decisiemens m-1. Plants grown for 35 d at higher E.C. had a lower water content but similar dry weight in their roots, leaves, and petioles compared to plants grown at lower E.C. Macronutrient concentrations of leaves, roots, and petioles were not affected by the imposed stress, indicating that the macronutrient stress resulted in a water-deficit stress response rather than a salt-specific response. Mannitol accumulated in sink tissues and was accompanied by a drastic decrease in activity of mannitol-1-oxidoreductase. Sucrose concentration and activities of sucrose-metabolizing enzymes in sink tissues were not affected by the macronutrient stress. Mature leaves exhibited increased concentrations of both mannitol and sucrose, together with increased activity of mannose-6-phosphate reductase and sucrose phosphate synthase, in response to macronutrient stress. Thus, mannitol accumulation in osmotically stressed celery is regulated by diminished catabolism in sink tissues and increased capacity for mannitol biosynthesis in source leaves.     

Characterization of Aspergillus niger phosphoglucose isomerase. Use for quantitative determination of erythrose 4-phosphate.

Phosphoglucose isomerase (PGI) was purified from Aspergillus niger and the in vitro kinetic properties of the enzyme were related to its functioning in vivo. A new assay method was developed to study the forward reaction making use of mannitol 1-P dehydrogenase as the coupling enzyme. In this simple assay system mannitol 1-P dehydrogenase converts fructose 6-P and NADH to mannitol 1-P and NAD+, respectively. At pH 7.5 the Km for glucose 6-P was 0.48 mM, whereas the Km for fructose 6-P was 0.32 mM. The pentose phosphate pathway intermediates 6-phosphogluconate and erythrose 4-P (E4P) were competitive inhibitors of PGI with Ki values of approximately 0.2 mM and 1 microM respectively. In citric acid producing A. niger mycelium inhibition by 6-phosphogluconate is of minor physiological significance (10% inhibition). Since E4P could not be detected by an existing procedure, a novel assay was developed based on the strong inhibition of PGI by E4P. Although the new assay is very sensitive (detection limit 25 pmol), E4P could still not be detected in metabolite extracts indicating that a very low level of E4P is present in the cells. Using in vitro kinetics and concentrations of intracellular metabolites the in vivo activity of PGI was calculated and closely matched the steady state glycolytic flux observed during citric acid production.     

Alginic acid synthesis in Pseudomonas aeruginosa mutants defective in carbohydrate metabolism.

Mutant cells of mucoid Pseudomonas aeruginosa isolated from cystic fibrosis patients were examined for their ability to synthesize alginic acid in resting cell suspensions. Unlike the wild-type strain which synthesizes alginic acid from glycerol, fructose, mannitol, glucose, gluconate, glutamate, or succinate, mutants lacking specific enzymes of carbohydrate metabolism are uniquely impaired. A phosphoglucose isomerase mutant did not synthesize the polysaccharide from mannitol, nor did a glucose 6-phosphate dehydrogenase mutant synthesize the polysaccharide from mannitol or glucose. Mutants lacking the Entner-Doudoroff pathway dehydrase or aldolase failed to produce alginate from mannitol, glucose, or gluconate, as a 3-phosphoglycerate kinase or glyceraldehyde 3-phosphate dehydrogenase mutant failed to produce from glutamate or succinate. These results demonstrate the primary role of the Entner-Doudoroff pathway enzymes in the synthesis of alginate from glucose, mannitol, or gluconate and the role of glyceraldehyde 3-phosphate dehydrogenase reaction for the synthesis from gluconeogenic precursors such as glutamate. The virtual absence of any activity of phosphomannose isomerase in cell extracts of several independent mucoid bacteria and the impairment of alginate synthesis from mannitol in mutants lacking phosphoglucose isomerase or glucose 6-phosphate dehydrogenase rule out free mannose 6-phosphate as an intermediate in alginate biosynthesis.     

黑曲霉S1生淀粉糖化酶生物合成的调节研究

本文对黑曲霉S_1(Aspergillus niger S_1)生淀粉糖化酶生物合成调节进行了初步研究,认为该菌生淀粉糖化酶的合成与菌体生长呈负相关,即酶的合成过程是典型的选择性合成过程。该菌生淀粉糖化酶的合成受降解物阻遏调控,缓慢供给低浓度易利用碳源和添加环腺苷磷酸(cAMP)可使酶的合成消阻遏,通过研究放线菌素C_1(Actinomycin C_1)等抑制剂对酶合成的影响而推断黑曲霉S_1生淀粉糖化酶合成的阻遏调控发生在转录水平上。     

Carbon export from arbuscular mycorrhizal roots involves the translocation of carbohydrate as well as lipid

Arbuscular mycorrhizal (AM) fungi take up photosynthetically fixed carbon from plant roots and translocate it to their external mycelium. Previous experiments have shown that fungal lipid synthesized from carbohydrate in the root is one form of exported carbon. In this study, an analysis of the labeling in storage and structural carbohydrates after (13)C(1) glucose was provided to AM roots shows that this is not the only pathway for the flow of carbon from the intraradical to the extraradical mycelium (ERM). Labeling patterns in glycogen, chitin, and trehalose during the development of the symbiosis are consistent with a significant flux of exported glycogen. The identification, among expressed genes, of putative sequences for glycogen synthase, glycogen branching enzyme, chitin synthase, and for the first enzyme in chitin synthesis (glutamine fructose-6-phosphate aminotransferase) is reported. The results of quantifying glycogen synthase gene expression within mycorrhizal roots, germinating spores, and ERM are consistent with labeling observations using (13)C-labeled acetate and glycerol, both of which indicate that glycogen is synthesized by the fungus in germinating spores and during symbiosis. Implications of the labeling analyses and gene sequences for the regulation of carbohydrate metabolism are discussed, and a 4-fold role for glycogen in the AM symbiosis is proposed: sequestration of hexose taken from the host, long-term storage in spores, translocation from intraradical mycelium to ERM, and buffering of intracellular hexose levels throughout the life cycle.     

Trehalose Phosphorylase Activity and Carbohydrate Levels During Axenic Fruiting in Three Agaricus bisporus Strains

Three strains of Agaricus bisporus (B430, 116, and 155.8), which share the ability to form hyphal aggregates on solid media under axenic conditions, were investigated with respect to carbohydrate levels and activities of enzymes involved in their carbon metabolism. The size and macroscopic appearance of the aggregates, when grown on diluted medium, suggest that substrate limitation plays a role in the process of fruiting body development in A. bisporus. The enzymes trehalose phosphorylase (TP), mannitol dehydrogenase (MD), and glucose-6-phosphate dehydrogenase (G6PD) seem to be developmentally regulated, in contrast to hexokinase (HK). Activities of TP (measured in the direction of trehalose degradation), MD, and G6PD were higher in the hyphal aggregates compared with the mycelium, whereas HK activity varied little. In the period preceding the axenic formation of hyphal aggregates, synthesis of trehalose by TP approximately doubled in the mycelium. The carbohydrate levels, which were measured by HPLC, varied in a way similar to their corresponding enzymes. The results indicate synthesis of trehalose in the mycelium of A. bisporus before the hyphal aggregates arise. Subsequently, translocation of the trehalose takes place from the mycelium to the emerging aggregates. In these small aggregates the trehalose is rapidly broken down to yield glucose and glucose-1-phosphate, serving as carbon and energy sources for further growth of the aggregates and for the synthesis of the osmolyte mannitol. Received: 4 March 1999 / Accepted: 4 June 1999     

Engineering of photosynthetic mannitol biosynthesis from CO2 in a cyanobacterium

d-Mannitol (hereafter denoted mannitol) is used in the medical and food industry and is currently produced commercially by chemical hydrogenation of fructose or by extraction from seaweed. Here, the marine cyanobacterium Synechococcus sp. PCC 7002 was genetically modified to photosynthetically produce mannitol from CO₂ as the sole carbon source. Two codon-optimized genes, mannitol-1-phosphate dehydrogenase (mtlD) from Escherichia coli and mannitol-1-phosphatase (mlp) from the protozoan chicken parasite Eimeria tenella, in combination encoding a biosynthetic pathway from fructose-6-phosphate to mannitol, were expressed in the cyanobacterium resulting in accumulation of mannitol in the cells and in the culture medium. The mannitol biosynthetic genes were expressed from a single synthetic operon inserted into the cyanobacterial chromosome by homologous recombination. The mannitol biosynthesis operon was constructed using a novel uracil-specific excision reagent (USER)-based polycistronic expression system characterized by ligase-independent, directional cloning of the protein-encoding genes such that the insertion site was regenerated after each cloning step. Genetic inactivation of glycogen biosynthesis increased the yield of mannitol presumably by redirecting the metabolic flux to mannitol under conditions where glycogen normally accumulates. A total mannitol yield equivalent to 10% of cell dry weight was obtained in cell cultures synthesizing glycogen while the yield increased to 32% of cell dry weight in cell cultures deficient in glycogen synthesis; in both cases about 75% of the mannitol was released from the cells into the culture medium by an unknown mechanism. The highest productivity was obtained in a glycogen synthase deficient culture that after 12 days showed a mannitol concentration of 1.1 g mannitol L⁻¹ and a production rate of 0.15 g mannitol L⁻¹ day⁻¹. This system may be useful for biosynthesis of valuable sugars and sugar derivatives from CO₂ in cyanobacteria.     

农杆菌介导转化黑曲霉分生孢子及产孢缺陷突变子T-DNA插入位点分析

【目的】利用农杆菌(Agrobacterium tumefaciens)T-DNA系统,建立转化黑曲霉(Aspergillus niger)分生孢子的方法,构建T-DNA插入突变子文库,为黑曲霉基因组功能注释研究打下基础。【方法】采用携带二元质粒载体pCAMBIA1301的农杆菌EHA105,诱导转化黑曲霉分生孢子,筛选具有潮霉素抗性的突变子。分析抗性稳定突变子菌株的表型,采用反向PCR方法分析T-DNA插入位点相邻位置的序列,并推测突变基因可能具有的功能。【结果】实验获得具有稳定潮霉素抗性转化子193株,转化率为5.6×102转化子/108分生孢子。部分转化子表型出现较为明显改变,其中一株不能产孢,对其T-DNA插入位点序列分析比对结果显示,突变基因属于超级转运家族(major facilitator superfamily,MFS)。【结论】本研究建立的农杆菌转化黑曲霉分生孢子平台,结合T-DNA插入突变位点分析,可以为黑曲霉基因组功能注释研究提供一种简便有效的途径。