Development Of Microorganisms Research Articles

Interrelation between <i>Pseudomonas aeruginosa</i> quinolone signal and the level of immunoglobulins in the blood of patients with lung cancer

Introduction. Researchers in the field of oncology have a significant interest in the role of microorganisms in development of malignant neoplasms.Aim. To study the levels of 2-heptyl-3-hydroxy-4-quinolone (PQS) and 2-heptyl-4-quinolone (HHQ) produced by Pseudomonas aeruginosa in the blood of patients with lung cancer and to analyze the relation between their changes and changes in the level of immunoglobulins and vascular endothelial growth factor (VEGF) in the blood of patients with lung cancer.Materials and methods. PQS and HHQ were quantified in the blood of patients using high performance liquid chromatography. The levels of immunoglobulins G (IgG), secretory immunoglobulin A (s-IgA), and VEGF in the blood were determined using ELISA.Results. Analysis have shown that the level of PQS in the blood of patients with lung cancer is 2-fold higher than in the control group. This change is accompanied by a decrease in the level of immunoglobulins IgG, as well as an increase in the content of s-IgA and growth factor VEGF in the blood.Conclusion. PQS level in the blood of patients with lung cancer is elevated creating conditions aggravating the course of the main disease and worsening its prognosis.

Ecofriendly Antimicrobial Dyeing for Cotton Fabric Using Natural Extract of Marigold

The main drawback with microorganism's development on fabrics is associated with the maintenance of hygiene and fabric deterioration. In this present investigation a trial has been made to produce an attractive and vibrant textile with eco-friendly antimicrobial dyeing by marigold, a natural resource. Tagetes erecta universally recognized as Marigold is a remarkable source of carotenoids and lutein, grown as a lawn plant. Now a day, lutein is exploding into an indubitably predominant active fitting, employed as an element of the Drugs, Nutrients and Textile Industry. The prospective application of marigold as a characteristic of antimicrobial activity has not been accustomed fully. It is due to the lack of knowledge about its ability and resemblance in material manner. In this work, we have concentrated on the analysis, which was led to deliberate the use of distillate isolate of marigold as an antimicrobial. The antimicrobial competence of the extract was evaluated by coloring on cotton textiles. Testing of the dye ability, its wash quickness and light fastness was done. Educations have validated that antimicrobial coatings have not affected by laundering and shown enhanced colouring effect comprising of fastness to washing, perspiration and rubbing than conservatively dyed textiles. It revealed that the essence of Marigold flower is habitually employed for cotton fabrics as an antimicrobial finish. The samples show very encouraging ends up in terms of antimicrobial resistivity.

Solid/Gas Biocatalysis.

Solid/gas biocatalysis is a nontraditional reaction system that employs the ability of some enzymes, being in the solid state, to catalyze reactions of substrates in the gas phase. Manipulation of the reaction parameters (temperature and pressure) in the solid/gas system allows precise control over the thermodynamic activity of water and substrate and creation of a controlled microenvironment for the enzyme, making it an appropriate model for enzymology studies. Owing to such advantages as high stability of dry enzymes and cofactors and easy fractionation of gas mixtures, solid/gas biotechnology has already found several industrial applications. Here we review key thermodynamic factors affecting the properties of enzymes, including their activity and stability, in a solid/gas system. Examples of promising enzymes and microorganisms for development and improvement of solid/gas biocatalytic technologies in organic synthesis, biosensors, and green chemistry are discussed.

Clinico-immunological and microbiological features of bronchial asthma in adults (the literature review)

This review represents contemporary scientific knowledge about prevalence of bronchial asthma, key points of pathogenesis and some immunological aspects of this disease. Main attention is given to role of microorganisms in development of bronchial asthma. Moreover, prospects for the therapy of bronchial asthma with due regard for the composition of microflora of upper respiratory airways.

THE ROLE OF NANOTECHNOLOGY IN HORTICULTURAL CROPS POSTHARVEST MANAGEMENT

Horticulture science has been defined as science and art of cultivating and handling of fruits, vegetables, flowers, and ornamental plants. Human population is increasing rapidly, so providing sufficient and healthy food is becoming a very important problem in the near future. Now, increasing production efficiency and decreasing post harvest wastage with using the findings of novel scientific researches such as biotechnology and nanotechnology in products, could be counted as the best solution to this problem. Nanotechnology using particular characteristics of nanoparticles can be a very useful technology in all science and industry branches. Nowadays, a lot of usages of nanotechnology in agricultural sciences have been established. In relation with extension of horticultural products shelf life, nanotechnology can help us in some grounds, e.g. controlling growth and development of micro organisms, introducing a new generation of packaging coverage's (Films) and controlling influence of gases and the harmful rays (UV), increasing strength, quality and packaging beauty, and using the multiple chips (Nanobiosensors) for labeling products that considered as fundamental step to automated control of storages.

Transformation of steroids by actinobacteria: A review

Development of pharmaceutical industry is currently aimed at introducing biotechnological processes on a large-scale and thereby replacing multiple-stage chemical syntheses. Actinobacteria are efficient biocatalysts of many processes involving steroid bioconversion, which hold considerable importance for the synthesis of hormonal drugs. The potential to catalyze the conversion of a broad spectrum of steroid substrates makes it possible to expect efficient utilization of these microorganisms in development of new technologies of manufacturing steroid pharmaceutical substances. The review is a first attempt to systematize data on the potential of actinobacteria to catalyze diverse reactions of steroid transformation (such as hydroxylation, introduction and reduction of double bonds, oxidation of steroid alcohols, reduction of ketones, side chain de-esterification and degradation, etc.), with emphasis on processes of practical biotechnological importance and progress in steroid bioconversion over the last ten years.

Functional, regulatory and indicator features of microorganisms in man-made ecosystems.

Functional, regulatory and indicator features of microorganisms in development and functioning of the systems and sustaining stability of three man-made ecosystem types has been studied. 1) The functional (metabolic) feature was studied in aquatic ecosystems of biological treatment of sewage waters for the reducer component. 2) The regulatory feature of bacteria for plants (producer component) was studied in simple terrestrial systems "wheat plants-rhizospheric microorganisms-artificial soil" where the behavior of the system varied with activity of the microbial component. For example with atmospheric carbon dioxide content elevated microbes promote intensification of photosynthesis processes, without binding the carbon in the plant biomass. 3) The indicator feature for the humans (consumer component) was studied in Life Support Systems (LSS). High sensitivity of human microflora to system conditions allowed its use as an indicator of the state of both system components and the entire ecosystem. Grant numbers: N99-04-96017, N15.

Replication-selective microbiological agents: fighting cancer with targeted germ warfare.

This Perspective series on cancer biotherapy will review the emerging field of tumor-targeted microorganisms. The clinical efficacy of any cancer treatment depends on both its antitumoral potency and the therapeutic index between cancerous cells and normal cells. Most current nonsurgical therapies for solid tumors fail on one or both scores, and it is unlikely that changes in dose or frequency, or even the combination of standard cytotoxic chemo- or radiotherapies, will satisfy both of these standards. Novel therapeutic approaches are required that offer greater potency and selectivity and that act by mechanisms not subject to cross-resistance when combined with standard therapies. Tumor-targeted microorganisms have the potential to fit all of these criteria. Their ability to replicate in tumor tissue allows for a massive amplification of the input “dose” (e.g., 1,000- to 10,000-fold increases) at the tumor site, while their lack of replication in normal tissues allows for efficient clearance and reduced toxicity. Infectious organisms such as viruses and bacteria have evolved to replicate and spread in human tissues. In many cases, infection leads to tissue destruction, either through direct or immune-mediated effects (Table ​(Table1).1). Not long after the discovery and characterization of bacteria and viruses, investigators conceived that the cell-killing potential of these agents could be used to destroy cancer cells (1). Over the last century, diverse viruses — adenovirus, Bunyamwara, coxsackie, dengue, feline panleukemia, Ilheus, mumps, Newcastle disease, vaccinia, and West Nile (2–4) — were injected into cancer patients by various routes, and bacterial agents have also been used as cancer therapies. Since the original description by Coley of tumor regressions following bacterial injection (5, 6), a variety of bacterial agents have been used as immune adjuvants, including Bacillus Calmette-Guerin (BCG) which eventually became the standard of care for superficial recurrent bladder carcinoma (7). Table 1 Replication-selective microbiological agents in clinical trials for cancer patients These studies illustrated both the promise of cancer biotherapy and the hurdles to be overcome. Both bacteria and viruses replicated within tumors and spread to distant tumor sites and many patients benefited from some degree of tumor necrosis, but patients were generally not properly evaluated by objective tumor response criteria. Many of the tumor responses appear to have been transient or incomplete, and while some of these agents were well-tolerated, toxicity occurred in some trials. Since the time of these pioneering but poorly controlled clinical trials, revolutionary advances in molecular biology and genetics established mechanisms for carcinogenesis as well as for microbial replication and pathogenicity. These advances also allowed novel agents to be engineered to improve their safety and/or their antitumoral potency. In recent years, genetically engineered microorganisms in development have included herpesviruses (8) (R. Martuza, in this Perspective series), adenoviruses (9) (C. Heise and D. Kirn, this series), vaccinia (10) (M. Mastrangelo et al., this series) and Salmonella species (11) (M. Sznol et al., this series). In addition, the inherent tumor-selectivity of agents such as reovirus has been characterized at the genetic level (K. Norman and P. Lee, this series). Each of these agents has shown tumor selectivity in vitro and in vivo, and work in murine tumor models has established the efficacy of these treatments. Until recently, detailed biological data from clinical trials was lacking, but now, as described by C. Heise and D. Kirn (this series), reports from ongoing clinical trials show that the engineered adenoviral mutant dl1520 (ONYX-015, now known as CI-1042, Park-Davis Pharmaceuticals, Inc., division of Warner Lambert, Inc. Ann Arbor, Michigan, USA) replicates and induces necrosis selectively in human tumors (12). Neutralizing antibodies to the virus do not demonstrably prevent antitumoral activity following intratumoral injection. The adenovirus can be delivered to tumors through intra-arterial or intravenous administration, as well. These studies also indicate that this novel biotherapy can interact in a potentially synergistic fashion with standard chemotherapeutic agents (13); a phase III randomized trial of cisplatin plus 5-fluorouracil (5-FU) with or without dl1520 is to be initiated in the first half of 2000. Cross-resistance between agents with such radically different mechanisms of action is unlikely, and combinations may be well-tolerated, particularly if the toxicity profiles of each agent are nonoverlapping. For example, dl1520 causes flulike symptoms, whereas 5-FU suppresses hematopoiesis and causes mucositis.

Role of microorganisms in development of geochemical reduction barriers where limonitization bedded zones wedge-out

The observed rise and fall of Eh level is considered due to changes in the composition and activity of the microflora and by corresponding changes in the products of biochemical reactions. Geochemical reduction barriers develop with the participation of microorganisms which influence the redox rates and determine the Eh gradient in the zones where bedded limonitization wedges out Anaerobic activity in infiltrational formation waters results in a negative Eh by the producers of hydrogen and hydrogen sulfide. Depending on the extent of the microbiological production, a hydrogen, a hydrogen sulfide, or a mixed geochemical barrier is created which determines specificities of the cumulative epigenetic mineralization. — IGR Staff.