Preparation, characterization, and biotransformation of the inclusion complex of phytosterols and hydroxypropyl-beta-cyclodextrin by Mycobacterium neoaurum

The inclusion complex of hydroxypropyl-beta-cyclodextrin (HBbetaCD) and phytosterols (PSs) was prepared and characterized by thermogravimetric analysis (TGA) and infrared (IR) spectroscopy. Biotransformation of the inclusion complex of phytosterols and hydroxypropyl-beta-cyclodextrin (PSs-HBbetaCD) by Mycobacterium neoaurum to 1,4-androstadiene-3,17-dione and 4-androstene-3,17-dione [AD(D)] was studied. The TGA and IR results indicated that the thermal stability of PSs was improved in the complex with HBbetaCD. Biotransformation improved the solubility of PSs in the aqueous medium a lot because the AD(D) production was increased remarkably compared with the control, but growth of the bacteria was inhibited in the presence of HBbetaCD. The optimal inclusion ratio, ultrasonic treating time, dosage, and time of addition of PSs-HBbetaCD complexe were found to be 2:1, 10 min, 1.5 g/30 ml medium, and 48 h after incubation, respectively. This inclusion technique not only increased the availability of the substrates for the microorganisms, but also the capability of these microorganisms to produce AD(D) from PSs.     

Identification of a novel phospholipase D gene and effects of carbon sources on its expression in <Emphasis Type="Italic">Bacillus cereus</Emphasis> ZY12

In the present study, a new strain, Bacillus cereus ZY12, producing phospholipase D (PLD) was identified. The expression of PLD in this strain was found to be induced by its substrate, phosphatidylcholine (PC), and completely silenced by other carbon sources, such as glucose, fructose, and maltose, which are generally used in microbial growth cultures, thus presenting a unique expression pattern different from other PLD-producing microorganisms. This study is the first to report on the ability of B. cereus to produce PLD, and successfully clone its PLD-coding gene and identify its function, extending the knowledge on PLD distribution and evolution in microorganisms.     

Microbiology of synthesis gas fermentation for biofuel production

A significant portion of biomass sources like straw and wood is poorly degradable and cannot be converted to biofuels by microorganisms. The gasification of this waste material to produce synthesis gas (or syngas) could offer a solution to this problem, as microorganisms that convert CO and H2) (the essential components of syngas) to multicarbon compounds are available. These are predominantly mesophilic microorganisms that produce short-chain fatty acids and alcohols from CO and H2. Additionally, hydrogen can be produced by carboxydotrophic hydrogenogenic bacteria that convert CO and H2O to H2 and CO2. The production of ethanol through syngas fermentation is already available as a commercial process. The use of thermophilic microorganisms for these processes could offer some advantages; however, to date, few thermophiles are known that grow well on syngas and produce organic compounds. The identification of new isolates that would broaden the product range of syngas fermentations is desirable. Metabolic engineering could be employed to broaden the variety of available products, although genetic tools for such engineering are currently unavailable. Nevertheless, syngas fermenting microorganisms possess advantageous characteristics for biofuel production and hold potential for future engineering efforts.     

The role of microbial interactions in infectious disease

The occurrence of infectious disease is affected by interaction between microorganisms in three ways. The indigenous flora (commensal microorganisms) of some mucous surfaces provide one of the main protective mechanisms against infection by pathogens (disease-producing microbes). The commensal populations interfere with the establishment of pathogens on mucous membranes by evoking anaerobic conditions, by competing for space and nutrients and by producing inhibitors. How, at the beginning of successful infection, pathogens in relatively small numbers overcome this protective activity of the commensal population is unknown. Although not a general phenomenon, some pathogens exacerbate the effects of others. The best examples are the potentiation of bacterial infections by existing viral infections: mucosal adherence and penetration by bacteria are enhanced and phagocytic defences against them weakened. Some microorganisms that are unable to produce significant disease on their own may combine with others to cause serious sickness. The harmful effects of these combinations of microorganisms can be explained by the multifactorial nature of pathogenicity (virulence), i.e. the capacity to produce disease. Although each member of the mixed population cannot alone produce the full complement of factors needed for disease production, the complement can be attained by combining contributions from different members.     

Isolation and characterization of actinomycetes strains that produce phospholipase D having high transphosphatidylation activity

The present study was conducted to screen microorganisms that produce phospholipase D (PLD), and we especially focused on the strains having high transphosphatidylation activity. Eighty bacterial strains were isolated from soil samples by a screening method utilizing a preliminary selection medium with phosphatidylcholine (PC) as the sole carbon source. The culture supernatants were then assayed for PLD activity. The finding of dual PLD activities in cultures revealed that the hydrolytic and transphosphatidylation activities were correlated. Consequently, six strains were selected as stably producing PLD enzyme(s) during continuous subcultures. The culture supernatants of selected strains synthesized phosphatidylglycerol, phosphatidylserine and phosphatidylethanolamine from PC with high conversion rates. These isolated strains will be made available to carry out phospholipid modification through the efficient transphosphatidylation activity of the PLD that they produce.     

The induction of phenylalanine ammonia lyase and phaseollin by 9-aminoacridine and other deoxyribonucleic Acid intercalating compounds

Bean pod tissue (Phaseolus vulgaris L. var. Top Crop) is induced to produce phaseollin when challenged with various microorganisms. The pods react in the same manner when challenged with 9-aminoacridine. This compound also caused an increase in concentrations of phenylalanine ammonia lyase, an enzyme of the phaseollin synthesizing pathway. Both the synthesis of phenylalanine ammonia lyase and phaseollin are subject to inhibition by actinomycin D, cycloheximide, or 6-methylpurine. The results suggest that both phaseollin production and increased phenylalanine ammonia lyase, when induced by 9-aminoacridine, require newly synthesized RNA and protein.     

The non-mevalonate pathway of isoprenoid precursor biosynthesis

The recently discovered non-mevalonate biosynthetic route to isoprenoid precursors is an essential metabolic pathway in plants, apicomplexan parasites, and many species of bacteria. The pathway relies on eight enzymes exploiting different cofactors and metal ions. Structural and mechanistic data now exist for most components of the pathway though there remain some gaps in our knowledge. The individual enzymes represent new, validated targets for broad spectrum antimicrobial drug and herbicide development. Detailed knowledge of the pathway may also be exploited to genetically modify microorganisms and plants to produce compounds of agricultural and medical interest.     

单萜类化合物的微生物合成

单萜类化合物是萜类化合物的一种,一般具有挥发性和较强的香气,部分单萜还具有抗氧化、抗菌、抗炎等生理活性,是医药、食品和化妆品工业的重要原料.近年来,利用微生物异源合成单萜类化合物的研究引起了科研人员的广泛关注,但因产量低、生产成本高等限制了其大规模应用.合成生物学的迅猛发展为微生物生产单萜类化合物提供了新的手段,通过改...     

Microbial production of D-malate from maleate.

To produce D-malate from maleate by a microbial reaction, we screened a number of maleate-utilizing microorganisms for enzyme activity by an intact cell system. The strain which showed the best productivity among the 440 strains tested was identified taxonomically as Arthrobacter sp. strain MCI2612. The optical purity of the malate produced by this strain was 100% D type. The culture and reaction conditions for the production were studied for this strain. Addition of amino acids such as L-proline, L-histidine, and L-arginine to the culture medium promoted the formation of reaction activity as well as cell growth. Under optimum conditions, 87 g of D-malate per liter was produced in 20 h. The yield was 72 mol%.     

厌氧产表面活性剂微生物提高原油采收率的研究进展

微生物强化采油(microbial enhanced oil recovery,MEOR)是近年来在国内外发展迅速的一项提高原油采收率技术。微生物在油藏中高效生产表面活性剂等驱油物质是微生物采油技术成功实施的关键之一。然而,油藏的缺/厌氧环境严重影响好氧表面活性剂产生菌在油藏原位的生存与代谢活性;油藏注空气会增加开采成本,且注入空气的作用时效和范围难以确定。因此,开发厌氧产表面活性剂菌种资源并强化其驱油效率对于提高原油采收率具有重要意义。本文综述了国内外近年来利用厌氧产表面活性剂微生物提高原油采收率的研究进展,简述了微生物厌氧产表面活性剂的相关驱油机理、菌种资源开发现状以及油藏原位驱油应用进展,并对当前的研究提出了一些思考。     

昆虫先天性免疫信号通路研究进展

昆虫体内形成了强大的免疫防御系统,其被各种微生物攻击时能依靠病原相关分子模式识别蛋白对感染进行区分和激活体内信号通路诱导如抗菌肽之类的效应分子.昆虫体内控制先天性免疫的信号通路分别是:Toll通路、IMD通路和JAS/STAT通路,这3条通路在信号传递过程中存在协作,并且,这些通路与脊椎动物体内某些通路存在惊人相似、在免疫调控通路方面存在共同的进化起源.这揭示了先天性免疫在动物体内存在的普遍性和机体抵御病原感染的重要性.     

微生物增产煤层气技术研究进展

微生物增产煤层气技术能够产生新的煤层气,有效缓解能源紧张问题,是煤层气开采、增产的研究热点。微生物增产煤层气技术的核心机理是煤的厌氧生物降解产甲烷。国内外研究学者通过实验室模拟研究了本源和外源微生物的降解煤产甲烷能力及影响因素。部分煤层气公司富集或分离获得了高效产甲烷菌群,并研究了微生物增产煤层气技术的现场实施方法。开发煤的预处理技术、构建新型高效菌群等可进一步提高微生物的增产煤层气能力,促进微生物增产煤层气技术的应用。     

Invasive bark beetle‐associated microbes degrade a host defensive monoterpene

Conifers respond to herbivore attack with defensive chemicals, which are toxic to both insects and their associated microorganisms. Microorganisms associated with insects have been widely reported to metabolize toxic chemicals, which may help both microorganisms and host insects overcome host conifer defense. Dendroctonus valens LeConte, an introduced exotic pest from North America to China, has killed millions of healthy pines. Alpha‐pinene is the most abundant defensive monoterpene in Chinese Pinus tabuliformis. Although microorganisms associated with D. valens have already been investigated, little is known about their bioactivities when encountering host defensive monoterpenes. In this study, we evaluated the influences of different concentrations of α‐pinene to D. valens and the three most frequently isolated yeasts and bacteria of D. valens, and further assayed microorganisms’ capabilities to degrade α‐pinene. Results showed that the gallery lengths and body weight changes of bark beetles were significantly affected by 6 mg/mL and 12 mg/mL of α‐pinene applied in media compared to controls. The tolerance of experimental microorganisms to α‐pinene varied depending on the microbial species. Two out of three yeast strains and all three bacterial strains degraded 20%–50% of α‐pinene compared to controls in 24 h in vitro. The microorganisms capable of α‐pinene degradation in vitro and their tolerance to high levels of α‐pinene suggested that D. valens‐associated microorganisms may help both microorganisms and the bark beetle overcome host α‐pinene defense.     

微生物源挥发性物质防治采后果蔬病害的研究进展

随着化学杀菌剂弊端的日益凸显,生物防治已逐渐成为采后果蔬病害控制的研究和开发热点。其中,很多微生物产生的多种挥发性物质(volatile organic compounds,VOCs),能显著抑制多种病原菌的生长繁殖,有效控制采后果蔬病害。由于微生物源VOCs具有有效、安全、环保、易降解和无残留等优点,越来越受到各国研究者的重视和青睐。本文综述了产生VOCs的微生物的多样性、微生物源VOCs的多样性、微生物源VOCs的抑菌活性、生防效果及其主要作用机制等方面的研究进展,以期为病原菌的绿色安全防治提供基础资料。     

Hydrolytic activity of symbiotic microflora enzymes in pike (<Emphasis Type="Italic">Esox lucius</Emphasis> L.) intestines

This study has revealed the existence of microflora which is, to different degrees, associated with the intestinal mucosa of pike. A total of 82 bacterial strains have been isolated. These microorganisms produce enzymes that hydrolyze the major food substrates (proteins and carbohydrates). These enzymes are produced by the pool of various microorganisms living in the intestines, as well as by separate strains isolated in pure cultures. These strains produce enzymes with different levels of activity. Most of the isolated strains (68%) produce proteases. The calculated values of the C/P factor (the ratio of carbohydrase to protease activity) indirectly testify to the autochthonous nature of the microflora associated with the intestinal mucosa of pike. Presumably, the contribution that the microflora enzymes make to the enzymatic activity of the pike intestine is substantial, but it is difficult to estimate now.     

Bioprospecting of <Emphasis Type="Italic">Diaporthe terebinthifolii</Emphasis> LGMF907 for antimicrobial compounds

Antibiotic-resistant bacteria have been observed with increasing frequency over the past decades, driving the search for new drugs and stimulating the interest in natural products sources. Endophytic fungi from medicinal plants represent a great source of novel bioactive compounds useful to pharmaceutical and agronomical purposes. Diaporthe terebinthifolii is an endophytic species isolated from Schinus terebinthifolius, a plant used in popular medicine for several health problems. The strain D. terebinthifolii LGMF907 was previously reported by our group to produce secondary metabolites with biological activity against phytopathogens. Based on these data, strain LGMF907 was chosen for bioprospecting against microorganisms of clinical importance and for characterization of major secondary metabolites. In this study, different culture conditions were evaluated and the biological activity of this strain was expanded. The crude extracts demonstrated high antibacterial activity against Escherichia coli, Micrococcus luteus, Saccharomyces cerevisiae, methicillin-sensitive Staphylococcus aureus, and methicillin-resistant S. aureus. The compounds diaporthin and orthosporin were characterized and also showed activity against the clinical microorganisms evaluated. This study discloses the first isolation of diaporthin and orthosporin from D. terebinthifolii, and revealed the potential of this endophytic fungus to produce secondary metabolites with antimicrobial activity.     

苏云金芽孢杆菌酪氨酸酶基因的克隆表达及应用初探

酪氨酸酶基因编码的酪氨酸酶是生物体合成黑色素的关键酶。采用比较酪氨酸酶的同源保守结构域氨基酸序列的方法设计引物 ,从苏云金芽胞杆菌 (Bacillusthuringiensis) 4D11中通过PCR扩增得到了包含酪氨酸酶基因的DNA片段。将该片段亚克隆到载体pGEM_7zf上并转入大肠杆菌DH5α ,所得到的转化子在添加了L_酪氨酸的LB培养基中能合成可溶性的黑色素。测定该菌株黑色素的产量和在紫外光照射后的菌体活力 ,结果表明该基因产生的黑色素能在一定程度上保护菌体免受紫外辐射     

Bacteria engineered for fuel ethanol production: current status

The lack of industrially suitable microorganisms for converting biomass into fuel ethanol has traditionally been cited as a major technical roadblock to developing a bioethanol industry. In the last two decades, numerous microorganisms have been engineered to selectively produce ethanol. Lignocellulosic biomass contains complex carbohydrates that necessitate utilizing microorganisms capable of fermenting sugars not fermentable by brewers' yeast. The most significant of these is xylose. The greatest successes have been in the engineering of Gram-negative bacteria: Escherichia coli, Klebsiella oxytoca, and Zymomonas mobilis. E. coli and K. oxytoca are naturally able to use a wide spectrum of sugars, and work has concentrated on engineering these strains to selectively produce ethanol. Z. mobilis produces ethanol at high yields, but ferments only glucose and fructose. Work on this organism has concentrated on introducing pathways for the fermentation of arabinose and xylose. The history of constructing these strains and current progress in refining them are detailed in this review.     

A contribution to the search of general mathematical principles in biology

A somewhat different approach to the principle of biotopological mapping, discussed in previous publications, is given. The organism is considered as a set of properties, each of which is in its turn a set of numerous subproperties which are logically included in the corresponding properties. Topology is introduced by an appropriate definition of neighborhoods, and four postulates are stated which concern the mapping of the spaces corresponding to higher organisms on those of lower ones. A number of conclusions are drawn from the postulates. Some of them correspond to well-known facts. For example, in man and some higher organisms appropriate emotional stimuli should produce gastrointestinal or cardiovascular disturbances; or some microorganisms should produce substances harmful to other microorganisms (antibiotics). Some other conclusions are still awaiting verification. One of them is, for example, that there must exist unicellular organisms which produce antibodies to appropriate antigens.     

红树林样品不经分离的微生物群体培养物生物活性研究

从海南、广西与广东三省的红树林区采集了181个样品,不进行微生物分离而直接作发酵剂接种到发酵培养基进行发酵,取发酵上清液进行抗细菌、抗真菌与肿瘤细胞毒活性的测定。同时对样品进行可培养微生物的分离与生物活性测定。结果显示:不同样品类型的生物活性差异较大。在15个具有强抗活性的样品中,有5个样品分离到的单株菌均无任何生物活性,说明这5个样品的生物活性可能是由微生物的群体作用产生的,也可能是某种没有培养出的微生物产生的。初步表明了探索微生物混合培养获得生物活性代谢产物的可能性。