Preparation and in vitro analysis of microencapsulated genetically engineered E. coli DH5 cells for urea and ammonia removal

This article describes a novel method of urea and ammonia removal using microencapsulated, genetically engineered Escherichia coli DH5 cells. Optimization of bacterial cell encapsulation was carried out. The optimal method consists of alginate 2.00% (w/v) at a flow rate of 0.0724 mL/min and a coaxial air flow rate of 2.00 L/min. This produces spherical, alginate-poly-L-lysine-alginate (APA) microcapsules of an average 500 +/- 45 mum diameter. Increasing the concentration of alginate from 1.00% to 1.75% improves the quality of the microcapsules, while cell viability remains unaffected. The APA microcapsules are mechanically stable up to 210-rpm agitation with no bacterial cell leakage. The in vitro performance of urea and ammonia removal by encapsulated bacteria is assessed. One hundred milligrams of bacterial cells in APA microcapsules, in their log phase state of growth, can lower 87.89 +/- 2.25% of the plasma urea within 20 min and 99.99% in 30 min. The same amount of encapsulated bacteria can also lower ammonia from 975.14 +/- 70.15 muM/L to 81.151 +/- 7.37 muM/L in 30 min. There are no significant differences in depletion profiles by free and encapsulated bacteria for urea and ammonia removal. This novel approach using microencapsulated, genetically engineered E. coli cells is significantly more efficient than presently available methods of urea and ammonia removal. For instance, it is 30 times more efficient than the standard urease-ammonium adsorbent system. (c) 1995 John Wiley & Sons, Inc.     

Probing the role of microenvironment for microencapsulated Sacchromyces cerevisiae under osmotic stress

Cell encapsulation opens a new avenue to the oral delivery of genetically engineered microorganism for therapeutic purpose. Osmotic stress is one of the universal chemical stress factors in the application of microencapsulation technology. In order to understand the effect and mechanism of the encapsulated microenvironment on protecting cells from hyper-osmotic stress, yeast cells of Saccharomyces cerevisiae Y800 were encapsulated in calcium alginate micro-gel beads (MB), alginate-chitosan-alginate (ACA) solid core microcapsules (SCM), and ACA liquid core microcapsules (LCM), respectively. The stress-induced intracellular components and enzyme activity including trehalose, glycerol and super oxide dismutase (SOD) were measured. Free cell culture was used as control. The survival of encapsulated cells and the cells released from MB, SCM and LCM after osmotic shock induced by NaCl solution (1, 2 and 3M) was evaluated. An analysis method was established to probe the effect of encapsulated microenvironment on the cell tolerance to osmotic stress. The results showed that LCM gave rise to the highest level of intracellular trehalose and glycerol, and SOD activity, as well as the highest survival rate of encapsulated cells or cells released from microcapsule. It was demonstrated that LCM was able to induce the highest stress response and stress tolerance of cells, which was adapted during culture, while SCM failed. The theoretical analysis revealed that it was the liquid alginate matrix in microcapsule that played a central role in domesticating the cells to adapt to hyper-osmotic stress. This finding provides a very useful guideline to cell encapsulation.     

Growth of recombinant fibroblasts in alginate microcapsules

To develop a novel strategy of nonautologous somatic gene therapy, we now demonstrate the feasibility of culturing genetically modified fibroblasts within an immunoprotective environment and the optimal conditions required for their continued survival in vitro. When mouse Ltk(-) fibroblasts transfected with the human growth hormone gene were enclosed within permselective microcapsules fabricated from alginate-polylysine-alginate, they continued to secrete human growth hormone at the same rates as the nonencapsulated cells. They also continued to proliferate in vitro for at least 1 month even though their viability gradually declined to about 50%. The viability can be improved by controlling for (a) temperature during encapsulation, (b) duration of treatment with polylysine, (c) duration of liquefying the core alginate with sodium citrate, and (d) cell density at the time of encapsulation. The best conditions leading to improved survival and maximum proliferation of cells within the microcapsules were obtained by encapsulating the cells at 4 to 10 degrees C instead of room temperature, coating the microspheres with polylysine for 6 to 10 min instead of 20 min, liquefying the core alginate by treating with citrate for 20 min instead of 6 to 10 min, and using a concentration of 2 x 10(6) cells/mL of alginate for encapsulation. Under such conditions, normally adherent and genetically engineered mouse fibroblasts survived and proliferated optimally within the microcapsule environment. The encapsulated fibroblasts maintained their level of transgene expression while recombinant gene products such as human growth hormone could diffuse through the microcapsule membrane without impediment. The demonstration that genetically modified fibroblasts can survive and continue to deliver recombinant gene products from within these microcapsules and the optimization for their maximal viability and growth within microcapsules should increase the potential for success in using such microencapsulated recombinant cells for somatic gene therapy. (c) 1994 John Wiley & Sons, Inc.     

Encapsulation of eukaryotic cells in alginate microparticles: cell signaling by TNF-alpha through capsular structure of cystic fibrosis cells

Entrapment of mammalian cells in natural or synthetic biomaterials represents an important tool for both basic and applied research in tissue engineering. For instance, the encapsulation procedures allow to physically isolate cells from the surrounding environment, after their transplantation maintaining the normal cellular physiology. The first part of the current paper describes different microencapsulation techniques including bulk emulsion technique, vibrating-nozzle procedure, gas driven mono-jet device protocol and microfluidic based approach. In the second part, the application of a microencapsulation procedure to the embedding of IB3-1 cells is also described. IB3-1 is a bronchial epithelial cell line, derived from a cystic fibrosis (CF) patient. Different experimental parameters of the encapsulation process were analyzed, including frequency and amplitude of vibration, polymer pumping rate and distance between the nozzle and the gelling bath. We have found that the microencapsulation procedure does not alter the viability of the encapsulated IB3-1 cells. The encapsulated IB3-1 cells were characterized in term of protein secretion, analysing the culture medium by Bio-Plex strategy. The analyzed factors include members of the interleukin family (IL-6), chemokines (IL-8 and MCP-1) and growth factors (G-CSF). The experiments demonstrated that most of the analyzed proteins, were secreted both by the free and encapsulated cells, even if in a different extent.     

Advances in polymer-based cell encapsulation and its applications in tissue repair

Cell microencapsulation is a more widely accepted area of biological encapsulation. In most cases, it involves fixing cells in polymer scaffolds or semi-permeable hydrogel capsules, providing the environment for protecting cells, allowing the exchange of nutrients and oxygen, and protecting cells against the attack of the host immune system by preventing the entry of antibodies and cytotoxic immune cells. Hydrogel encapsulation provides a three-dimensional (3D) environment similar to that experienced in vivo, so it can maintain normal cellular functions to produce tissues similar to those in vivo. Embedded cells can be genetically modified to release specific therapeutic products directly at the target site, thereby eliminating the side effects of systemic treatments. Cellular microcarriers need to meet many extremely high standards regarding their biocompatibility, cytocompatibility, immunoseparation capacity, transport, mechanical, and chemical properties. In this article, we discuss the biopolymer gels used in tissue engineering applications and the brief introduction of cell encapsulation for therapeutic protein production. Also, we review polymer biomaterials and methods for preparing cell microcarriers for biomedical applications. At the same time, in order to improve the application performance of cell microcarriers in vivo, we also summarize the main limitations and improvement strategies of cell encapsulation. Finally, the main applications of polymer cell microcarriers in regenerative medicine are summarized.     

Yeast cells for encapsulation of bioactive compounds in food products: A review

Nowadays bioactive compounds have gained great attention in food and drug industries owing to their health aspects as well as antimicrobial and antioxidant attributes. Nevertheless, their bioavailability, bioactivity, and stability can be affected in different conditions and during storage. In addition, some bioactive compounds have undesirable flavor that restrict their application especially at high dosage in food products. Therefore, food industry needs to find novel techniques to overcome these problems. Microencapsulation is a technique, which can fulfill the mentioned requirements. Also, there are many wall materials for use in encapsulation procedure such as proteins, carbohydrates, lipids, and various kinds of polymers. The utilization of food-grade and safe carriers have attracted great interest for encapsulation of food ingredients. Yeast cells are known as a novel carrier for microencapsulation of bioactive compounds with benefits such as controlled release, protection of core substances without a significant effect on sensory properties of food products. Saccharomyces cerevisiae was abundantly used as a suitable carrier for food ingredients. Whole cells as well as cell particles like cell wall and plasma membrane can act as a wall material in encapsulation process. Compared to other wall materials, yeast cells are biodegradable, have better protection for bioactive compounds and the process of microencapsulation by them is relatively simple. The encapsulation efficiency can be improved by applying some pretreatments of yeast cells. In this article, the potential application of yeast cells as an encapsulating material for encapsulation of bioactive compounds is reviewed.     

Improved activity of streptozotocin-selected insulinoma cells following microencapsulation and transplantation into diabetic mice

We have recently shown that repeated streptozotocin (STZ) treatment induces the selection of insulinoma cells (RINmS) with both improved resistance to diabetogenic toxins and functional activity, compared to parental RINm cells. The aim of the present study was to estimate the potential of RINmS cells to maintain their engineered characteristics during in vivo hyperglycemic conditions. It was found that microencapsulation and transplantation into diabetic mice preserved a three-fold higher level of insulin content in selected RINmS cells when compared to the parental ones. Retrieval of transplanted encapsulated cells from the peritoneal cavity of diabetic mice had a significantly higher insulin content and a more intense insulin response to secretogogues in selected RINmS cells when compared to retrieved RINm cells. In conclusion, our results show that RINmS cells do not lose their improved functional characteristics after encapsulation and transplantation into diabetic mice.     

T-cell dependent collagenous encapsulating response in the mouse liver to Mesocestoides corti (Cestoda)

Pollacco S., Nicholas W.L., Mitchell G.F. and Chaicharn Stewart A. 1978. T-cell dependent collagenous encapsulating response in the mouse liver to Mesocestoides corti (Cestoda). International Journal for Parasitology8: 457–462. Experiments with genetically hypothymic mice show that the tetrathyridial larvae of Mesocestoides corti (Cestoda) multiply much more rapidly in the liver than in normal mice. In the hypothymic mouse, collagen fibres are not laid down and the parasite is not encapsulated as it is in the normal mouse. Encapsulation probably restricts the parasite's multiplication, and it is suggested that the failure to encapsulate the parasite accounts for its more rapid multiplication in the hypothymic mouse. Fibrogenesis and encapsulation is restored to hypothymic mice by transferring syngeneic thymus cells, spleen cells or peritoneal exudate cells. It is concluded that the encapsulation of M. corti is a T-cell dependent process.     

Impact of Alginate Composition: From Bead Mechanical Properties to Encapsulated HepG2/C3A Cell Activities for In Vivo Implantation

Recently, interest has focused on hepatocytes’ implantation to provide end stage liver failure patients with a temporary support until spontaneous recovery or a suitable donor becomes available. To avoid cell damage and use of an immunosuppressive treatment, hepatic cells could be implanted after encapsulation in a porous biomaterial of bead or capsule shape. The aim of this study was to compare the production and the physical properties of the beads, together with some hepatic cell functions, resulting from the use of different material combinations for cell microencapsulation: alginate alone or combined with type I collagen with or without poly-L-lysine and alginate coatings. Collagen and poly-L-lysine increased the bead mechanical resistance but lowered the mass transfer kinetics of vitamin B12. Proliferation of encapsulated HepG2/C3A cells was shown to be improved in alginate-collagen beads. Finally, when the beads were subcutaneously implanted in mice, the inflammatory response was reduced in the case of alginate mixed with collagen. This in vitro and in vivo study clearly outlines, based on a systematic comparison, the necessity of compromising between material physical properties (mechanical stability and porosity) and cell behavior (viability, proliferation, functionalities) to define optima hepatic cell microencapsulation conditions before implantation.     

微囊化干细胞及其应用研究进展

干细胞极强的自我更新能力和多向分化潜能使其可以成为绝佳的种子细胞来源,用于各种疑难疾病的治疗。微胶囊不仅可以为细胞提供三维生长微环境,而且具有良好的免疫隔离性能和生物相容性。微囊化干细胞技术为干细胞大规模、高活性体外培养及长期保存提供了新的技术支持,为细胞移植疗法开辟了新途径。以下首先简述了微囊化技术的发展情况,然后介绍了目前用于微囊化干细胞的材料、制备方法及其免疫隔离作用,重点阐述了近年来微囊化各种不同类型干细胞的研究和应用进展。最后,提出目前微胶囊化干细胞的问题所在并对此技术进行展望。     

Stereotypic culture systems for liver and bone marrow: evidence for the development of functional tissue in vitro and following implantation in vivo

Stromal cell-associated liver cell and bone marrow (BM) culture on three-dimensiional nylon screen or polyglycolic acid (PGA) felt templates conveys certain functional advantages to the parenchyma of these tissues. Hepatic parenchymal cells (PC) manifest long-term ( approximately 2 month) expression of liver-specific activities including cytochrome P450 enzyme activity and the synthesis of albumin, fibrinogen, transferrin, and other proteins. PC also undergo proliferation in association with stromal cells that were pre-established on these templates. PC mitoses are directly proportional to available space within the template for their expansion indication that geometric or sterotypic parameters influence the growth of these cells in vitro. BM cultured on a similar template exhibits long-term multilineage hematopoietic expression and limited expansion of progenitor cell numbers. Progenitor cell concentration within the cultures can be substantially enhanced if these cells are liberated from co-culture and reseeded onto a template containing fresh stromal cells. BM and liver cel cultures established on felt composed of bioresorbable PGA filaments was grafted into various sites in rats. Liver co-cultures generated sinusoids and other liver-like structures in situ; active hematopoietic blasts were observed at sites of BM co-culture grafts. Biodegradable polymer constructs may prove useful for certain clinical applications as vehicles for the delivery of tissues that were engineered in culture.     

Optimization of microencapsulation parameters: Semipermeable microcapsules as a bioartificial pancreas

An improved membrane has been developed for the microencapsulation of islets of Langerhans which protects these cells from the immune system. These requirements were accomplished through the optimization of important microencapsulation parameters and through the improved biocompatibility of a new alginate-poly-l-lysine (PLL)-alginate capsule membrane. Spherical and smooth microcapsules could be formed by utilizing a purer sodium alginate and by keeping the viscosity of the sodium alginate solution above 30 cps. The strength of the capsule membrane was enhanced by increasing the alginate-PLL reaction time as well as the PLL concentration. The permeability of the membrane [4 mum thick, 93% (w/w) water] was a function of the viscosity average molecular weight (Mv) of the PLL (Mv = 4000-4 x 10(5)) used in the encapsulation procedure. Microcapsules prepared with PLL with Mv = 1.7 x 10(4) were the least permeable, being impermeable to normal serum immunoglobulin, albumin, and haemoglobin. The microencapsulation procedure, by protecting transplanted tissue from the components of the immune system, has great clinical potential as a new form of treatment for diseases such as diabetes and liver disease.     

Retinal ganglion cell differentiation in cultured mouse retinal explants

The availability of genetically engineered mice harboring specific mutations in genes affecting one or more retinal cell types affords new opportunities for investigating the genetic regulatory mechanisms of vertebrate retina formation. When identifying critical regulatory genes involved in retina development it is often advantageous to complement in vivo analysis with in vitro characterization. In particular, by combining classical techniques of retinal explant culturing with gene transfer procedures relying on herpes simple virus (HSV) amplicon vectors, gain-of-function analysis with genes of interest can be performed quickly and efficiently. Here, details are provided for isolating and culturing explants containing retinal progenitor cells and for infecting the explants with HSV expression vectors that perturb or rescue retinal ganglion cells, the first cell type to differentiate in the retina. In addition, the availability of sensitive techniques to monitor gene expression, including detection of reporter gene expression using antibodies and detection of endogenous marker gene expression using quantitative RT-PCR, provides an effective means for comparing wild-type and mutant retinas from genetically engineered mice.     

Construction of tracer plasmids for Bacillus sphaericus 1593 utilizing the xylE gene from Pseudomonas putida

Genetically engineered microorganisms (GEMS) released into the environment must be traceable in order to accurately assess their impact on the area of release. Tracer genes other than those that introduce antibiotic resistance are preferred for use in identifying genetically engineered strains. In this study, we describe the construction of a series of tracer plasmids for use in Bacillus sphaericus using the xylE gene from the Pseudomonas putida TOL plasmid. This gene codes for the enzyme catechol 2,3-dioxygenase which converts the colorless substance catechol to 2-hydroxymuconic semialdehyde, a yellow product which is easily detected. Colonies of cells which express the xylE gene turn yellow shortly after being exposed with a solution of catechol.     

Engineered protein nano-compartments for targeted enzyme localization

Compartmentalized co-localization of enzymes and their substrates represents an attractive approach for multi-enzymatic synthesis in engineered cells and biocatalysis. Sequestration of enzymes and substrates would greatly increase reaction efficiency while also protecting engineered host cells from potentially toxic reaction intermediates. Several bacteria form protein-based polyhedral microcompartments which sequester functionally related enzymes and regulate their access to substrates and other small metabolites. Such bacterial microcompartments may be engineered into protein-based nano-bioreactors, provided that they can be assembled in a non-native host cell, and that heterologous enzymes and substrates can be targeted into the engineered compartments. Here, we report that recombinant expression of Salmonella enterica ethanolamine utilization (eut) bacterial microcompartment shell proteins in E. coli results in the formation of polyhedral protein shells. Purified recombinant shells are morphologically similar to the native Eut microcompartments purified from S. enterica. Surprisingly, recombinant expression of only one of the shell proteins (EutS) is sufficient and necessary for creating properly delimited compartments. Co-expression with EutS also facilitates the encapsulation of EGFP fused with a putative Eut shell-targeting signal sequence. We also demonstrate the functional localization of a heterologous enzyme (β-galactosidase) targeted to the recombinant shells. Together our results provide proof-of-concept for the engineering of protein nano-compartments for biosynthesis and biocatalysis.     

Cell growth and hemoglobin synthesis in murine erythroleukemic cells propagated in high density microcapsule culture

Summary A new microencapsulation technology, developed for the encapsulation of living cells, has been demonstrated to be useful for the study of growth and differential gene expression using Friend erythroleukemic cells cultured at high cell densities. Using this technology, cultures of FL Clone 745 cells were encapsulated within semipermeable membranes composed of cross-linked alginic acid and poly-l-lysine. Cell growth studies measuring total cell number demonstrated an average generation time of 8.5 h in 5% (vol/vol) microcapsule cultures vs. 8.0 h in suspension cultures. Similar microcapsule cultures were serially propagated for more than 90 cell generations (13 sequential passages) with no significant change in this growth rate. In addition, final culture densities of greater than 1.0×10⁸ cells/ml of intracapsular volume were attained using a 3% (vol/vol) microcapsule culture in conjunction with a standard refeeding schedule. Comparison of the level of dimethyl sulfoxide-induced hemoglobin production in suspension and microcapsule cultures demonstrated that the total amount of hemoglobin produced on a per cell basis was comparable in both systems. Due to the retention characteristics of the semipermeable membrane, the concentration of detergent-released hemoglobin, relative to other released protein, was approximately twofold higher in microcapsule cultures than in control suspension cultures.     

Synergistic activation by recombinant mouse interferon-gamma and muramyl dipeptide of tumoricidal properties in mouse macrophages

Mouse peritoneal macrophages were activated to become cytotoxic against B16-BL6 melanoma cells by the combination of subthreshold amounts of murine interferon-gamma (IFN-gamma; 0.1 to 10 U/ml) and N-acetylmuramyl-L-alanyl-D-isoglutamine (MDP; 0.001 to 10 micrograms/ml), but not by the combination of pH 2-treated IFN-gamma and MDP, heat-treated IFN-gamma and MDP, or IFN-gamma and the inactive stereoisomer of MDP, N-acetyl-muramyl-D-alanyl-D-isoglutamine (MDP-D). The encapsulation of intact IFN-gamma and MDP within the same liposome preparation was synergistic for macrophage activation. In contrast, the presentation of identical concentrations of IFN-gamma and MDP in separate liposome preparations did not activate macrophages. These data allow us to conclude that the encapsulation of genetically engineered IFN-gamma and synthetically produced MDP within the same liposome is highly efficient in producing synergistic activation of tumoricidal properties in mouse macrophages.     

The molecular pathogenesis of hepatic encephalopathy

Hepatic encephalopathy (HE) incorporates a spectrum of neuropsychiatric abnormalities seen in patients with liver dysfunction with a potential for full reversibility. Distinct syndromes are identified in acute liver failure and cirrhosis. Rapid deterioration in consciousness level and increased intracranial pressure that may result in brain herniation and death are a feature of acute liver failure whereas manifestations of HE in cirrhosis include psychomotor dysfunction, impaired memory, increased reaction time, sensory abnormalities, poor concentration and in severe forms, coma. For over a 100 years ammonia has been considered central to its pathogenesis. In the brain, the astrocyte is the main site for ammonia detoxification, during the conversion of glutamate to glutamine. An increased ammonia level raises the amount of glutamine within astrocytes, causing an osmotic imbalance resulting in cell swelling and ultimately brain oedema. The present review focuses upon the molecular mechanisms involved in the pathogenesis of HE. Therapy of HE is directed primarily at reducing ammonia generation and increasing its detoxification.