Optimizing the formation of in vitro sponge primmorphs from the Chinese sponge Stylotella agminata (Ridley)

The establishment and optimization of in vitro primmorph formation from a Chinese sponge, Stylotella agminata (Ridley), collected from the South China Sea, were investigated. Our aims were to identify the key factors affecting primmorph formation in this species and to optimize the technique for developing an in vitro primmorph culture system. The size of dissociated cells from S. agminata is relatively small, in the range between 5 and 10 microm. Round-shaped primmorphs of less than 100 microm were formed 3 days after transferring the dissociated cells into seawater containing Ca(2+) and Mg(2+). The effect of various cell dissociation conditions, inoculum cell density, concentration of antibiotics, pH, and temperature was further investigated upon the formation of primmorphs. The time required for primmorph formation, primmorph size distribution, and the proliferating capability were microscopically documented. Healthy sponge S. agminata, inoculum cell density and culture temperature play a critical role for the successful formation of primmorphs and that the microbial contamination will have to be controlled.     

繁茂膜海绵原细胞富集细胞团培养过程中的细胞迁移规律

海绵是重要的生物活性物质来源, 近10年来, 从海绵中发现的具有生物活性的新化合物占海洋生物来源的30%以上, 并且大多具有显著的抗肿瘤, 抗艾滋病病毒的活性。但是, 由于海绵生物量不能满足这些活性物质进一步研究和商业化的需求, 目前仅有一种活性物质被成功的商业化, 这不仅是商业开发的损失, 也是提高人类生活质量活动的一种损失。为了解决海绵供给不足的问题, 人们进行了包括化学合成、海绵养殖以及海绵细胞培养在内的多种尝试,目前的研究结果表明, 海绵细胞离体培养技术是最有可能彻底解决海绵供给不足的途径之一。但是由于海绵自身的特殊性, 还没有人成功的建立起海绵细胞系以满足生产需要。人们发现, 海绵细胞的相互接触对于离体海绵细胞长期培养至关重要。经过多年的探索, 大连化物所海洋生物产品工程组建立了开发出了海绵原细胞富集细胞团培养技术, 通过对海绵组织内的原细胞进行富集来获得可长期培养的海绵细胞。海绵原细胞是海绵组织内的“干细胞”, 具有很强的分化、增殖潜力, 同时也是海绵组织内负责消化的主要细胞类型。为了探索海绵原细胞的增殖、分化规律, 本研究基于海绵原细胞富集细胞团培养体系, 构建了海绵细胞培养实时观测平台, 对繁茂膜海绵原细胞、领细胞、上皮细胞3类主要海绵细胞类型在海绵细胞团形成及生长的全过程进行观察, 了解不同类型细胞迁移规律的变化。通过对视频记录进行分析,发现离散的海绵细胞与细胞团内的海绵细胞具有截然相反的运动规律, 海绵细胞的运动具有很强的协同性。伴随原细胞在细胞团内不停息的迁移, 还观察到海绵细胞团内新生骨针的迁移以及细胞间进行颗粒物质的传递。这些信息的获得, 将有助于进一步了解不同细胞的功能与作用, 也有助于在此基础上探索海绵细胞的增殖、分化控制规律。     

Long-Term Cultivation of Primmorphs from Freshwater Baikal Sponges <Emphasis Type="Italic">Lubomirskia baikalensis</Emphasis>

The work was aimed at performing long-term cultivation of primmorphs in vitro from freshwater sponge Lubomirskia baikalensis (Pallas 1776), collected from Lake Baikal, obtaining its long-term primmorph culture in both natural (NBW) and artificial (ABW) Baikal water and at identifying the impact of different environmental factors on formation and growth of primmorphs. The first fine aggregates of L. baikalensis are formed in vitro 10–15 min after dissociation of sponge cells. Epithelization of aggregates begins 4 h later after the dissociation. Young primmorphs are formed 1 or 2 days later. The surface of primmorphs is covered with a layer of exopinacocytes. The primmorphs remain viable for more than 10 months at 3–6°C. Over 50% of primmorphs in NBW and 25% in ABW are attached to the substrate and grow like adult sponges. Thus, the long-term primmorph cultivation in vitro allows the creation of a controlled live model system under experimental conditions. The results of this work will allow the creation of a cell culture collection of Baikal freshwater sponges for studying morphogenesis of primmorphs during cultivation at different stages and transdifferentiation of their cells, physiological functions of sponge cells, processes of spiculogenesis, identification of proteins involved in biomineralization process, decoding of their genes, as well as a spectrum of secondary metabolites.     

Sulfated polysaccharides from marine sponges: conspicuous distribution among different cell types and involvement on formation of in vitro cell aggregates

Marine sponges (Porifera) display an ancestral type of cell-cell adhesion, based on carbohydrate-carbohydrate interaction. The aim of the present work was to investigate further details of this adhesion by using, as a model, the in vitro aggregation of dissociated sponge cells. Our results showed the participation of sulfated polysaccharides in this cell-cell interaction, as based on the following observations: (1) a variety of sponge cells contained similar sulfated polysaccharides as surface-associated molecules and as intracellular inclusions; (2) ³⁵S-sulfate metabolic labeling of dissociated sponge cells revealed that the majority (two thirds) of the total sulfated polysaccharide occurred as a cell-surface-associated molecule; (3) the aggregation process of dissociated sponge cells demanded the active de novo synthesis of sulfated polysaccharides, which ceased as cell aggregation reached a plateau; (4) the typical well-organized aggregates of sponge cells, known as primmorphs, contained three cell types showing sulfated polysaccharides on their cell surface; (5) collagen fibrils were also produced by the primmorphs in order to fill the extracellular spaces of their inner portion and the external layer surrounding their entire surface. Our data have thus clarified the relevance of sulfated polysaccharides in this system of in vitro sponge cell aggregation. The molecular basis of this system has practical relevance, since the culture of sponge cells is necessary for the production of molecules with biotechnological applications.     

Viability and cell cycle analysis of equine fibroblasts cultured in vitro

This experiment aimed to study equine fibroblasts in culture analyzing and the cell cycle and viability of cells pre- and post-freezing. Skin fragments were obtained from 6 horses and cultured in DMEM high glucose + 10% FCS in 5% CO₂ until the beginning of confluence. Two passages were performed before freezing. Cells subjected to serum starvation (0.5% FCS) were analyzed for viability and cell cycle at 24, 48, 72, 96, 120, 144 and 168 h of culture. For the confluent groups, cells were analyzed at the moment they achieved confluence. Cellular viability was assisted with Hoescht 33342 and propidium iodide. The analysis of apoptosis/necrosis and cell cycle was performed using a flow cytometer (FACS Calibur BD^®) after staining the cells with annexin V and propidium iodide. Both optical microscopy and flow cytometry confirmed that cellular viability was similar for serum starvation and confluent groups (average 84%). Similarly, both methods were efficient to synchronize the cell cycle before freezing. However, after thawing, serum starvation, for more than 24 h, was superior to culture for synchronizing cells in G0/G1 (69% × 90%). The results of this experiment indicate that equine fibroblasts can be efficiently cultured after thawing.     

Primmorphs from archaeocytes-dominant cell population of the sponge hymeniacidon perleve: improved cell proliferation and spiculogenesis

Marine sponges (Porifera) possess an extraordinary diversity of bioactive metabolites for new drug discovery and development. In vitro cultivation of sponge cells in a bioreactor system is very attractive for the sustainable production of sponge-derived bioactive metabolites; however, it is still a challenging task. The recent establishment of sponge primmorphs, multicellular aggregates from dissociated mixed-cell population (MCP), has been widely acknowledged to hold great promise for cultivation in vitro. Here we present a new method to establish an in vitro sponge primmorph culture from archaeocyte-dominant cell population (ADCP) enriched by a Ficoll gradient, rather than a mixed-cell population (MCP). Our rationale is based upon the totipotency (the ability of a cell to differentiate into other cell types) of archaeocyte cells and the different biological functions of various sponge cell types. A sponge, Hymeniacidon perleve collected from the China Yellow Sea was used as a model system for this investigation. Distinct dynamics of primmorph formation were observed while significant increases in DNA synthesis, cell proliferation (up to threefold), and cell growth (up to fourfold) were achieved. Furthermore, a time-dependent spiculogenesis was clearly demonstrated in our longterm culture, indicating high metabolic activity of primmorphs from the ADCP. This new method represents an important step forward to advance sponge cell culture in vitro that may lead to commercial exploitation of sponge-derived drugs.     

Cryopreservation of isolated rat hepatocytes: a critical evaluation of freezing and thawing conditions

Various parameters, including the nature and proportion of the constituents of the cryoprotective medium, the cooling rate, and the composition of the thawing medium, were evaluated for the cryopreservation of adult rat hepatocytes. The highest percentage of cells able to survive in culture was obtained by freezing in L15 medium containing 16% dimethyl sulfoxide, at a rate of 3 degrees C/min, and by adding 0.8 M glucose to the thawing medium. More than 50% of hepatocytes capable of attachment just after cell isolation kept this property after freezing and survived in primary culture. Dead cells could be eliminated before seeding by centrifugation on a Percoll layer. In culture, frozen cells exhibited a morphology similar to that of unfrozen cells and after 24 hr their protein secretion rate was reduced by only about 40%.     

Optimization of slow cooling cryopreservation for human pluripotent stem cells

Human pluripotent stem cells (hPSCs) have the potential for unlimited expansion and differentiation into cell types of all three germ layers. Cryopreservation is a key process for successful application of hPSCs. However, the current conventional method leads to poor recovery of hPSCs after thawing. Here, we demonstrate a highly efficient recovery method for hPSC cryopreservation by slow freezing and single‐cell dissociation. After confirming hPSC survivability after freeze‐thawing, we found that hPSCs that were freeze‐thawed as colonies showed markedly decreased survival, whereas freeze‐thawed single hPSCs retained the majority of their viability. These observations indicated that hPSCs should be cryopreserved as single cells. Freeze‐thawed single hPSCs efficiently adhered and survived in the absence of a ROCK inhibitor by optimization of the seeding density. The high recovery rate enabled conventional colony passaging for subculture within 3 days post‐thawing. The improved method was also adapted to a xeno‐free culture system. Moreover, the cell recovery postcryopreservation was highly supported by coating culture surfaces with human laminin‐521 that promotes adhesion of dissociated single hPSCs. This simplified but highly efficient cryopreservation method allows easy handling of cells and bulk storage of high‐quality hPSCs. genesis 52:49–55, 2014. © 2013 Wiley Periodicals, Inc.     

Seasonal production of primmorphs from the marine sponge Petrosia ficiformis (Poiret, 1789) and new culturing approaches

The need to produce bioactive compounds from marine sponges leads several groups of research to the culture of primmorphs from different species, which are generally maintained in aquaria for long time before processing. Here we present a study where the importance of several parameters on primmorphs production from the symbiotic sponge Petrosia ficiformis has been evaluated: (i) the sterility of sea water, (ii) the maintenance in aquarium before processing, (iii) the seasonal cycle. Sterility of sea water does not improve primmorphs production in this species. The maintenance of sponges in aquaria before processing negatively affects cell cultures. Regarding seasonality, it is evident that both the number and the size of primmorphs can deeply change depending on the period of the year the sponge is collected. April and July are the months that lead to the highest number of primmorphs, May and June are the months that lead to their biggest sizes. Possible relationships of these results with the life cycle of P. ficiformis are discussed.     

Protein-bound SH groups in frozen-thawed egg cells of the sea urchin

Unfertilized egg cells of the sea urchin St. intermedius could survive slow freezing to ?15 °C for a short period of time, but at the same freezing temperature extracellular freezing became fatal within a few hours. Such freezing injury resulted in “black” or “white” cytolysis in frozen-thawed cells. “Black” cytolysis took place in the process of both freezing and thawing, while “white” cytolysis occurred only on thawing. Rapid rewarming consistently produced “white” cytolysis in extracellularly frozen cells. The observed behavior of the injured cells during freeze-thawing appeared favorable for the explanation of freezing injury by the SH-SS hypothesis. Protein-bound SH groups were quantitatively determined in both whole cell and cortex with plasma membrane before and after freeze-thawing. However, no significant change in the SH value was observed between freeze-thaw cytolysed materials and unfrozen ones.     

New process to form a silk fibroin porous 3-D structure

A new process to form fibroin spongy porous 3-D structure is reported herein. The process involves freezing and thawing fibroin aqueous solution in the presence of a small amount of an organic solvent. The process requires no freeze-drying, chemical cross-linking, or the aid of other polymeric materials. The solvent concentration, fibroin concentration, freezing temperature, and freezing duration affect the sponge formation, its porous structure, and its mechanical properties. Measurements by XRD and FTIR indicate that silk I and silk II crystalline structures exist in the fibroin sponge and that the secondary structure of fibroin is transformed to a beta-sheet from a random coil during this process. The tensile strength decreased slightly, but the fibroin sponge showed no deformation after autoclaving. Therefore, the fibroin sponge was sterilized using an autoclave. For 3 weeks, MC3T3 cells proliferated in the sterilized fibroin sponge. The fibroin sponge formed by this new process is applicable as a tissue-engineering scaffold because it is formed from biocompatible pure silk fibroin and offers both porous structure and mechanical properties that are suitable for cell growth and handling.     

The significance of culture for successful cryopreservation of isolated pancreatic islets of Langerhans

It was the aim of the present study to investigate the significance of culture before and after freeze-thawing of isolated mouse pancreatic islets. To evaluate the impact of culture before freezing (5 degrees C/min; 2 M dimethyl sulfoxide), islets were frozen either directly after isolation or after 2, 4, or 7 days of culture in medium RPMI 1640. The culture period after thawing was 7 days. Islets immediately frozen exhibited virtually no (pro)insulin biosynthesis and also a severe inhibition of glucose-stimulated insulin release. The precultured (2-7 days), frozen islets synthesized and released insulin at rates comparable to those of nonfrozen, cultured islets. Studies of the effects of culture after freeze-thawing were performed after a 3-day culture period prior to freezing. The (pro)insulin biosynthetic rates did not differ between islets cultured for 0-7 days after thawing. There was an apparent increase of glucose-stimulated insulin release when the islets were cultured for more than 2 days after thawing. It may be that the decreased viability of islets frozen immediately after isolation was due to minor cell damage induced by the collagenase incubation. During culture the islets may recover and become more resistant to freeze-damage. The beneficial effect of culture after thawing may reflect the loss of damaged cells, which otherwise would influence the results of the viability tests.     

Do heat shock proteins provide protection against freezing?

Yeast cells were frozen by plunging directly into liquid nitrogen (LN2) after exposure at 43 degrees C. Both the cells frozen without prior exposure to heat shock and those treated with cycloheximide showed almost 100% loss of viability during freezing and thawing. Heat exposure prior to freezing and thawing significantly increased the cell viability. This increase in cell viability was associated with the induction of heat shock protein synthesis, which was detected by gel electrophoresis. This protein may act by stabilizing the macromolecules and by increasing the hydrophobic interactions.     

Cryopreservation of the coccolithophore, <Emphasis Type="Italic">Emiliania huxleyi</Emphasis> (Haptophyta,Prymnesiophyceae)

We studied the cryopreservation of the most common coccolithophore, Emiliania huxleyi which is considered as one of the main global carbon cycle participants. Both stages of this complex life cycle species were submitted to gradual addition of three distinct cryoprotectants: dimethylsulfoxide (7.5% v/v), methanol (5% v/v) and proline (0.5 M). They were then control-rate cooled (−5 °C min⁻¹) to −50 °C before plunging into liquid nitrogen. Free radical oxygen species have been proposed to occur in cells subjected to pre-freezing manipulation or to cooling. Therefore, catalase (preventing accumulation of hydroxyl radicals) was evaluated for its ability to improve cell viability before and after freezing-thawing challenge. With the exception of proline which induced a decrease in diploid cell proliferation, cryoprotectants had no deleterious effects. On the contrary, growth of the haploid stage was enhanced by each CPA treatment, suggesting mixotrophic growth. Cryopreservation succeeded when dimethylsulfoxide was used, and the late exponential phase was obtained as soon as the 15th post-thawing day. Cell densities were then similar to the unfrozen controls. Catalase had no beneficial effect on the ability of cells to grow, neither prior freezing nor after thawing. In comparison with former attempts to cryopreserve E. huxleyi in other culture collection centers, our protocols allowed faster recovery.     

An improved method for preparing refrozen rethawed human lymphocytes on plates for microcytotoxicity studies.

This report describes simplified methods for the initial freezing and thawing of human lymphocytes and the subsequent use of these cells after refreezing on cytotoxicity plates, storage, and a second thaw. The proposed initial freeze method eliminates some technical inconveniences required previously such as chilling of cells prior to addition of DMSO, preparing cryoprotective mixtures just prior to freezing, controlled rate of freezing and thawing and the washing of cells after thawing. However, pH of the media, blood freshness, type of storage tube used, and constant storage temperature were found to be very important to maintain good cell viability. Most lymphocytes maintain an average viability of 85 to 95% for at least a year when prepared according to the present freezing and thawing technique.When panels of lymphocytes are prepared for refrozen rethawed cytotoxicity test plates, the thaw time between freezes must be brief. Production of test plates on ice, however, was not found to be necessary. As the period of storage of refrozen cells on plates increases, viability of the cells after a second thaw decreases and treatment with DNase to enzymatically remove the dead cells is useful. With this procedure, refrozen rethawed lymphocytes up to a year old can be prepared on microcytotoxicity test plates with average viabilities of 90 ± 1%.     

Cell cycle analysis of primary sponge cell cultures

Proliferation of sponge cells is generally measured via cell counts or viability assays. However, more insight into the proliferative state of a sponge cell population can be obtained from the distribution of the cells over the different phases of the cell cycle. Cell cycle distribution of sponge cells was measured via flow cytometry after staining the DNA with propidium iodide. The five sponges studied in this paper all showed a large fraction of cells in G1/G0 compared to G2/M and S, indicating that cells were not actively dividing. In addition, some sponges also showed a large apoptotic fraction, indicating cell death. Additional apoptosis measurements, based on caspase activity, showed that harvesting and dissociation of sponge tissue to initiate a primary cell culture was directly correlated with an increase in apoptotic cells. This indicates that for the development of cell cultures, more attention should be given to harvesting, dissociation, and quality of starting material. Finally, cultivation conditions used were ineffective for proliferation, since after 2 d of cultivating Haliclona oculata cells, most cells shifted towards the apoptotic fraction, indicating that cells were dying. For development of in vitro sponge cell cultures, flow cytometric cell cycle analysis is a useful method to assess the proliferative state of a sponge cell culture and can be used to validate improvements in harvesting and dissociation, to select sponges with good proliferative capacities and to study the influence of culture conditions for stimulating cell growth.     

Antioxidants increase the cryoresistance of GM-CFC

The influence of antioxidative drugs on the cryopreservation of human bone marrow cells was studied. The viability of bone marrow cells was tested after freezing and thawing from--196 degrees C by the growth of GM-CFC in agar culture. The results suggest the ability of antioxidants to protect stem cells against damage caused by freezing and thawing. Addition of tocopherol or penicillin to a cryoprotective medium increases the number of surviving GM-CFC. From the colony-to-cluster ratio can be concluded that antioxidants especially protect more immature haematopoietic (colony forming) cells.     

Producing drugs from marine sponges

Marine sponges are potential sources of many unique metabolites, including cytotoxic and anticancer compounds. Natural sponge populations are insufficient or inaccessible for producing commercial quantities of metabolites of interest. This review focuses on methods of producing sponge biomass to overcome supply limitations. Production techniques discussed include aquaculture in the sea, the controlled environments of aquariums, and culture of sponge cells and primmorphs. Cultivation in the sea and aquariums are currently the only practicable and relatively inexpensive methods of producing significant quantities of sponge biomass. In the future, metabolite production from cultured sponge cells and primmorphs may become feasible. Obtaining a consistent biomass yield in aquariums requires attention to many factors that are discussed in this work.     

Cryopreservation of human bone marrow‐derived mesenchymal stem cells with reduced dimethylsulfoxide and well‐defined freezing solutions

The aim of this study is to investigate the feasibility of using well defined, serum‐free freezing solutions with a reduced level of dimethylsulfoxide (DMSO) of 7.5, 5, and 2.5% (v/v) in the combination with polyethylene glycol (PEG) or trehalose to cryopreserve human bone marrow‐derived mesenchymal stem cells (hBMSCs), a main source of stem cells for cell therapy and tissue engineering. The standard laboratory freezing protocol of around 1°C/min was used in the experiments. The efficiency of 1,2‐propandiol on cryopreservation of hBMSCs was explored. We measured the post‐thawing cell viability and early apoptotic behaviors, cell metabolic activities, and growth dynamics. Cell morphology and osteogenic, adipogenic and chondrogenic differentiation capability were also tested after cryopreservation. The results showed that post‐thawing viability of hBMSCs in 7.5% DMSO (v/v), 2.5% PEG (w/v), and 2% bovine serum albumin (BSA) (w/v) was comparable with that obtained in conventional 10% DMSO, that is, 82.9 ± 4.3% and 82.7 ± 3.7%, respectively. In addition, 5% DMSO (v/v) with 5% PEG (w/v) and 7.5% 1,2‐propandiol (v/v) with 2.5% PEG (w/v) can provide good protection to hBMSCs when 2% albumin (w/v) is present. Enhanced cell viability was observed with the addition of albumin to all tested freezing solutions. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Growth kinetics of cells following freezing in liquid nitrogen

The growth kinetics of cells frozen to ?196 °C were monitored after thawing by various techniques. Progression through the cell cycle in the exposed generation was observed by monitoring cell growth either via multiplicity counts or by electronic cell counts of trypsinized suspensions. Subsequent generations were followed by time-lapse microcinematography.The division delay in the exposed generation of exponential-phase cells was dependent on cell age at the time of freezing and varied from 4 to 8 hr. The time of the first generation was still prolonged significantly but subsequent generations revealed cell cycle times that are comparable to unfrozen cells. In the case of plateau-phase cells, mitosis was delayed 7 hr in the exposed generation. This is 50% longer than the delay seen for pre-DNA synthetic g₁ cells in exponentially growing cultures.A rather important observation in this study was that frozen-thawed cells which divide once will probably continue dividing whereas eventual nonsurvivors are not likely to divide at all. The latter, however, remain active for more than 35 hr as observed microscopically, hence possibly indicating residual metabolic activity.