Fractal dimensions and porosities of Zoogloea ramigera and Saccharomyces cerevisae aggregates

The fractal nature microbial aggregates is a function of the type of microorganism and mixing conditions used to develop aggregates. We determined fractal dimensions from length-projected area (D(2)) and length-number scaling (D(3)) relationships. Aggregates of Zoogloea ramigera developed in rotating test tubes were both surface and mass fractals, with fractal dimensions of D(2) = 1.69 +/- 0.11 and D(3)= 1.79 +/- 0.28 (+/-standard deviation), respectively. When we grew this bacteria in a bench-top fermentor, aggregates maintained their surface fractal characteristics (D(2) = 1.78 +/- 0.11) but lost their mass fractal characteristics (D(3) = 2.99 +/- 0.36). Yeast aggregates (Saccharomyces cerevisae) grown in rotating tests tubes had higher average fractal dimensions than bacterial aggregates grown under physically identical conditions, and were also considered fractal (D(2) = 1.92 +/- 0.08 and D(3) = 2.66 +/- 0.34). Aggregates porosity can be expressed in term of a fractal dimensions, but average porosities are higher than expected. The porosities of yeast aggregates (0.9250-0.9966) were similar to porosities of bacterial aggregates (0.9250-0.9966) cultured under the same physical conditions, although bacterial aggregates developed in the reactor had higher average porosities (0.9857-0.9980). These results suggest that that scaling relationships based on fractal geometry may be more useful than equations derived from Euclidean geometry for quantifying the effects of different fluid mechanical environments on aggregates morphology and characteristics such as density, porosity, and projected surface area.     

Localization of active form of caspase-8 in mouse L929 cells induced by TNF treatment and polyglutamine aggregates

The relation between activation of caspase-8 and polyglutamine aggregates has been focused. We prepared an antiserum (anti-m8D387) that recognizes the active form but not the proform of mouse caspase-8. We used immunostaining with anti-m8D387 antiserum to compare the localizations of activated mcaspase-8 in L929 (clone 1422) cells induced by TNF and polyglutamine aggregates. Anti-m8D387 was positive throughout cytoplasm of the TUNEL-positive cells induced by TNF treatment, whereas the anti-m8D387 reactivity was not positive throughout cytoplasm of the cells expressing polyglutamine but was restricted to polyglutamine aggregates. In contrast with TNF-treated cells, cells expressing anti-m8D387-positive cytoplasmic polyglutamine aggregates did not undergo TUNEL-positive apoptosis. Thus activated caspase-8 associated with polyglutamine aggregates alone was not sufficient to induce TUNEL-positive apoptosis of L929 (clone 1422) cells. The distribution of activated caspase-8 associated with polyglutamine aggregates may be essential for the polyglutamine-mediated cell death or downstream of caspase-8 may be different in the TNF-treated cells and cells expressing polyglutamine.     

Forms and Functions of Meso and Micro-niches of Carbon within Soil Aggregates

Soil aggregates include sand/silt/clay, water, ion and organic matter contents combined with natural dry/wet (D/W) cycling alters both the formation and function of intra-aggregate pore continuity, connectivity, dead-end storage volumes, and tortuosity. Surface aggregates in the 0-5 cm depths of most soils experience from 34 to 57 D/W cycles that exceed differences in water contents >10%. Both the rates of drying or wetting, (intensity) and the D/W range of soil water contents (severity) alter the transport of water, C and N through micro and mesofaunal habitats among multiple size domains. This report identifies micro-niche locations of accumulating soil C within soil aggregate regions that may affect nematode residence sites and migration pathways. Recent advances in X-ray microtomography enable the examination of intact pore networks within soil aggregates at resolutions as small as 4 microns. Geostatistical and multi-fractal methods provide concise characteristics of pore spatial distributions within the aggregates and are useful for comparing these alterations among soils. Aggregates subjected to multiple D/W cycles developed greater spatial correlations that parallel increases in the (13)C sorption within aggregate interiors were compared with locations of soil microbial communities. Past research indicates microbial activities within the soil aggregate matrix are spatially heterogeneous due to complex pore geometries within aggregates. Illumination of the "blackbox" interiors of soil aggregates includes a discussion of natural and anthropogenic alterations of solution flow and carbon sequestration by soil aggregates containing biophysical gradients.     

Deposition diseases and 3D domain swapping

Protein aggregation is a feature of both normal cellular assemblies and pathological protein depositions. Although the limited order of aggregates has often impeded their structural characterization, 3D domain swapping has been implicated in the formation of several protein aggregates. Here, we review known structures displaying 3D domain swapping in the context of amyloid and related fibrils, prion proteins, and macroscopic aggregates, and we discuss the possible involvement of domain swapping in protein deposition diseases.     

Culture phases,cytotoxicity and protein expressions of agarose hydrogel induced Sp2/0, A549, MCF-7 cell line 3D cultures

Advancements in cell cultures are occurring at a rapid pace, an important direction is culturing cells in 3D conditions. We demonstrate the usefulness of agarose hydrogels in obtaining 3 dimensional aggregates of three cell lines, A549, MCF-7 and Sp2/0. The differences in culture phases, susceptibility to cisplatin-induced cytotoxicity are studied. Also, the 3D aggregates of the three cell lines were reverted into 2D cultures and the protein profile differences among the 2D, 3D and revert cultures were studied. The analysis of protein profile differences using UniProt data base further augment the usefulness of agarose hydrogels for obtaining 3D cell cultures.     

In situ monitoring of 3D in vitro cell aggregation using an optical imaging system

Bioreactor systems that maintain cells and tissues in suspension are increasingly popular for culturing 3D constructs to avoid the loss of in vivo cell function associated with traditional 2D culture methods. There is a need for the online monitoring of such systems to provide better understanding and control of the processes involved and to prevent the disruption of these processes caused by offline sampling and endpoint analysis. We describe a system for the imaging and analysis of cell aggregation, over long periods, within a high aspect rotating vessel (HARV). The system exploits side illumination, using an adjustable beam pattern, to restrict the detected light to that scattered by the cell aggregates, thus eliminating the need for the fluorescent labeling of the cells. The in situ aggregation of mammalian cells (MCF-7 breast carcinoma cells) was monitored over an 8 h period and image sequences showing the growth and motion of the aggregates within the bioreactor were obtained. Detailed size and population data have been derived characterizing the development of the aggregates during this time. We show how the number of resolvable aggregates increases to reach a peak and then declines as these aggregates merge. Once formed, remaining aggregates are found to consolidate to form more tightly packed bodies, typically reducing in cross-sectional area by one third. These results provide the basis for the development of an automated feedback system to control the growth of 3D cell cultures for repeatable, reliable, and quality controlled experimentation.     

Growth and survival signalling in B16F10 melanoma cells in 3D culture

The two‐way communication between the ECM (extracellular matrix) and the cytoplasm via the integrins has many functions in cancer cells, including the suppression of apoptosis. As cells in a 3D (three‐dimensional) architecture resemble the in vivo situation more closely than do cells in more conventional 2D cultures, we have employed a substratum that prevents cell adhesion and induces cell aggregation to determine why highly metastatic B16F10 melanoma cells resist anoikis. We compared the behaviour of B16F10 cells in 2D [on tPS (tissue culture polystyrene)] and 3D culture {on polyHEMA [poly(2‐hydroxyethylmethacrylate)]} configurations. For this, we analysed cell morphology, proliferation, apoptosis and the activation status of several proteins involved in cell proliferation and survival [RhoA, FAK (focal adhesion kinase), Akt, ERK1/2 (extracellular‐signal‐regulated kinase 1/2)]. B16F10 cells in 3D architecture were able to proliferate as cell aggregates for 3 days, after which the number of cells decreased. The normal Swiss 3T3 cells used as an anoikis‐sensitive control did not proliferate on the anti‐adhesive substratum. Rho A was activated in B16F10 aggregates throughout their time in culture, whereas it was not in Swiss 3T3 aggregates. An absence of apoptotic activity was correlated with the proliferation of B16F10 cells in aggregates: caspase 3 was significantly activated only after 3 days in culture on polyHEMA. FAK and Akt were transiently activated, and their inactivation was correlated with the induction of apoptosis. ERK1/2 were activated throughout the 3D culture. No survival protein was activated in Swiss 3T3 aggregates. Data obtained from cells in 3D culture suggest that B16F10 cells are resistant to anoikis through the activation of the FAK and Akt signalling pathways.     

季节性冻融对典型黑土区土壤团聚体特征的影响

以东北典型黑土区耕地土壤为研究对象,通过对不同水分补充条件下、不同频度和程度的冻融交替处理后土壤干筛团聚体和水稳性团聚体组成、破坏率（PAD_0.25、PAD_1.0）、平均质量直径（D_mm）、平均质量比表面积（SA_mm）和分形维数（D）等特征指标的测定与分析,研究季节性冻融对典型黑土区表层土壤团聚体特征的影响.结果表明：无水无冻融及无水冻融显著增加了＞5 mm干筛团聚体和＞0.25 mm水稳性团聚体的含量,干筛和水稳性团聚体的D_mm分别较冻融前增加了7.98%～29.41%和36.11%～44.44%,SA_mm、D的变化规律也表现为促进大团聚体的团聚作用.少水冻融和季节冻融则显著增加了＜2 mm干筛团聚体和0.25～1 mm水稳性团聚体的含量,D_mm、SA_mm、D均表现出加剧风干团聚体拆分的趋势,水稳性团聚体的SA_mm和D分别降低了10.88%～25.52%和1.02%～3.40%（P<0.05）,团聚作用有所增强.季节性冻融后PAD_0.25降低了33.45%（P<0.05）,PAD_1.0无明显变化,典型黑土区季节性冻融增强了土壤团聚体的水稳定性.     

川南坡地不同退耕模式对土壤团粒结构分形特征的影响

运用分形模型,研究了川南坡地及其退耕成慈竹林、杂交竹林、桤木+慈竹混交林和弃耕地5年后土壤团粒结构分形维数,探讨了分形维数与土壤理化性质之间的关系.结果表明：退耕后,不同退耕模式样地＞0.25 mm的土壤团聚体和水稳性团聚体含量均显著增加,团粒结构分形维数介于1.377～2.826,为慈竹林＜杂交竹林＜桤木+慈竹混交林＜弃耕地＜农耕地,并随＞0.25 mm的土壤团聚体及水稳性团聚体含量的增加而降低;土壤自然含水量、毛管孔隙、有机质、全氮、碱解氮、全磷和全钾含量增加,而土壤容重、非毛管孔隙和通气度降低.退耕后的慈竹林、杂交竹林、桤木+慈竹混交林和弃耕地的土壤团粒结构分形维数与土壤理化性质相关性较好.农耕地退耕对增加＞0.25 mm的土壤团聚体及水稳性团聚体含量和提高土壤结构稳定性具有较好的作用;土壤团粒结构分形维数可以作为坡地退耕后土壤肥力变化的理想指标,在研究区坡地退耕种植慈竹具有较好的培肥改土效益.     

Combination of microwell structures and direct oxygenation enables efficient and size‐regulated aggregate formation of an insulin‐secreting pancreatic β‐cell line

Spherical three‐dimensional (3D) cellular aggregates are valuable for various applications such as regenerative medicine or cell‐based assays due to their stable and high functionality. However, previous methods to form aggregates have shown drawbacks, being labor‐intensive, showing low productivity per unit area or volume and difficulty to form homogeneous aggregates. We proposed a novel strategy based on oxygen‐permeable polydimethylsiloxane (PDMS) honeycomb microwell sheets, which can theoretically supply about 80 times as much oxygen as conventional polystyrene culture dishes, to produce recoverable aggregates in controllable sizes using mouse insulinoma cells (MIN6‐m9). In 48 hours of culture, the PDMS sheets produced aggregates whose diameters were strictly controlled (?32, 60, 90, 150 and 280 mm) even at an inoculum density eight times higher (8.0×105 cells/cm²) than that of normal confluent monolayers (1.0×105 cells/cm²). Measurement of the oxygen tension near the cell layer and glucose/lactate analysis clearly showed that cells exhibit aerobic respiration on the PDMS‐based culture system. Glucose‐responsive insulin secretion of the recovered aggregates showed that the aggregates around 90 mm in diameter secreted the largest amounts of insulin. This confirmed the advantages of 3D cellular organization and the existence of a suitable aggregate size, above which excess organization leads to a decreased metabolic response. These results demonstrated that this microwell‐based PDMS culture system provides a promising method to form size‐regulated and better functioning 3D cellular aggregates of various kinds of cells with a high yield per surface area. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 30:178–187, 2014     

Turnover of the aggregates and cross-linked products of the D1 protein generated by acceptor-side photoinhibition of photosystem II.

It is known that the reaction-center binding protein D1 in photosystem (PS) II is degraded significantly during photoinhibition. The D1 protein also cross-links covalently or aggregates non-covalently with the nearby polypeptides in PS II complexes by illumination. In the present study, we detected the adducts between the D1 protein and the other reaction-center binding protein D2 (D1/D2), the alpha-subunit of cyt b(559) (D1/cyt b(559)), and the antenna chlorophyll-binding protein CP43 (D1/CP43) by SDS/urea-polyacrylamide gel electrophoresis and Western blotting with specific antibodies. The adducts were observed by weak and strong illumination (light intensity: 50-5000 microE m(-2) s(-1)) of PS II membranes, thylakoids and intact chloroplasts from spinach, under aerobic conditions. These results indicate that the cross-linking or aggregation of the D1 protein is a general phenomenon which occurs in vivo as well as in vitro with photodamaged D1 proteins. We found that the formation of the D1/D2, D1/cyt b(559) and D1/CP43 adducts is differently dependent on the light intensity; the D1/D2 heterodimers and D1/cyt b(559) were formed even by illumination with weak light, whereas generation of the D1/CP43 aggregates required strong illumination. We also detected that these D1 adducts were efficiently removed by the addition of stromal components, which may contain proteases, molecular chaperones and the associated proteins. By two-dimensional SDS/urea-polyacrylamide gel electrophoresis, we found that several stromal proteins, including a 15-kDa protein are effective in removing the D1/CP43 aggregates, and that their activity is resistant to SDS.     

Cell-cell interaction can influence drug-induced differentiation of murine embryonal carcinoma cells

When cultured in the presence of either retinoic acid (RA) or dimethyl sulfoxide (DMSO), aggregates of the P19 line of mouse embryonal carcinoma (EC) cells differentiate and the spectrum of cell types formed depends on the drug dose. It is shown here the EC cells rapidly lose their colony-forming ability when cultured as aggregates in the presence of DMSO. This loss of plating efficiency (PE) also occurs rapidly following RA treatment. Loss of PE has been used as a quantitative procedure for assessing the rate of drug-induced differentiation. The relationship between drug dose and loss of PE is much steeper for DMSO than for RA, suggesting that these two drugs affect different stages of the differentiation decision-making apparatus. Mutant EC cell lines (D3 and RAC65) do not differentiate in the presence of drug-inducers (DMSO and RA, respectively). Neither differentiation-deficient mutant has an altered ability to form gap junctions. When D3 and P19 cells were mixed within the same DMSO-treated aggregates, the D3 cells remained undifferentiated and the P19 cells differentiated much less efficiently than if they were cultured in the absence of the D3 cells. When RAC65 and P19 cells were mixed in RA-treated aggregates, each cell responded to the drug as though the other were absent. Thus RA behaves as a cell-autonomous inducer of differentiation, whereas DMSO-induced differentiation seems to be mediated by interactions between neighboring cells.     

An alternative structural isoform in amyloid‐like aggregates formed from thermally denatured human γD‐crystallin

The eye lens protein γD‐crystallin contributes to cataract formation in the lens. In vitro experiments show that γD‐crystallin has a high propensity to form amyloid fibers when denatured, and that denaturation by acid or UV‐B photodamage results in its C‐terminal domain forming the β‐sheet core of amyloid fibers. Here, we show that thermal denaturation results in sheet‐like aggregates that contain cross‐linked oligomers of the protein, according to transmission electron microscopy and SDS‐PAGE. We use two‐dimensional infrared spectroscopy to show that these aggregates have an amyloid‐like secondary structure with extended β‐sheets, and use isotope dilution experiments to show that each protein contributes approximately one β‐strand to each β‐sheet in the aggregates. Using segmental ¹³C labeling, we show that the organization of the protein's two domains in thermally induced aggregates results in a previously unobserved structure in which both the N‐terminal and C‐terminal domains contribute to β‐sheets. We propose a model for the structural organization of the aggregates and attribute the recruitment of the N‐terminal domain into the fiber structure to intermolecular cross linking.     

Inhibition of desmosome formation in chick cell aggregates.

Desmosomes (macula adherens) have been associated with the function of adhesion. Their possible role in aggregation and sorting of chick and mouse epithelial cells has been investigated. Treatment of aggregates with 2-5 microgram/ml of actinomycin D which inhibited RNA synthesis also inhibited both desmosome formation and aggregation if administered at the beginning of the aggregation process. In contrast, if the drug was administered at six hours, when the cells had recovered from the process of dissociation, then aggregation over the following six hours appeared normal from observation of living samples. Such aggregates incorporated leucine-3H at roughly 85% of the control level. A quantitative comparison was made of desmosome formation in aggregates treated with actinomycin D for hours 6-12 and those cultured in normal medium. Desmosome formation was inhibited by the drug, although aggregation could proceed. Combinations of chick corneal and mouse skin cells sorted out in the presence of actinomycin D to the same extent as controls. Thus desmosome formation, which normally occurs during aggregation of the epithelial cells studied here, is not coupled with the aggregation or cell sorting process in these cells of stratified epithelia. When cells were treated with cycloheximide (100 muM) both desmosome formation and the progressive rounding up of aggregates was inhibited.     

Immunoglobulin kappa light chain and its amyloidogenic mutants: a molecular dynamics study

AL amyloidosis and LCDD are pathological conditions caused by extracellural deposition of monoclonal Ig light chain variable domains. In the former case, deposits have a form of amyloid fibrils, in the latter, amorphous aggregates. 1REI kappa light chain variable domain and its two point mutants, R61N and D82I, were chosen for the analysis in this work. Wild 1REI does not create deposits in vitro, while R61N aggregates as amyloid fibrils and D82I creates amorphous aggregates. Both mutated residues create a conserved salt bridge; thus, substitution of any of them should decrease V(L) domain stability. For these three proteins, 5 ns MD simulations were conducted in temperatures of 300 K and 400 K, with protonated and unprotonated acidic residues, mimicking acidic and neutral experimental pH conditions (3 sets: N300, N400, and A400). The analysis of trajectories focused on characterization of changes in conformational behavior and stability of Ig kappa light chain variable domain caused by single aminoacid substitutions that were experimentally proved to enhance aggregation propensity, both in the form of amyloid and amorphous aggregates. Residue D82 turns out to be involved not only in R61-D82 but also in K45-D82 interaction, which was not observed in the X-ray structure, but frequently populated simulations of 1REI. The substitution D82I excludes both interactions, resulting in substantial destabilization (i.e., easier aggregation). Examination of behavior of edge regions of V(L) beta-sandwich reveals significant alterations in D82I mutant compared to wild 1REI, while relatively small changes occur in R61N. This suggests that mild and slow destabilization is the reason of the conversion of V(L) to partially folded amyloidogenic intermediate structure.     

Fluorescence Analysis of 7-Aminoactinomycin–Telomeric Oligonucleotide d[AGGG(TTAGGG)<Subscript>3</Subscript>] Complexes

Interactions of 7-aminoactinomycin D (a fluorescent analogue of actinomycin D, an anticancer antibiotic) and two structural forms of the model guanine-rich telomeric oligonucleotide d[AGGG(TTAGGG)₃] have been studied. We have shown that 7-aminoactinomycin D induces fluorescence in two G-quadruplex structures formed with the presence of potassium or sodium ions. The enthalpy of the interaction between the phenoxasone chromophore of the antibiotic and the telomeric oligonucleotide as determined by analysis of excitation spectra is 5.5 kcal/mol. This value differs little from those obtained for complexes with guanine, adenine, or thymine aggregates (6–7 kcal/mol). In the oligonucleotide, the antibiotic is located within dynamic cavities. Therefore, 7-aminoactinomycin D is not released from telomeric structures to the aqueous phase spontaneously or even by photoexcitation, but it is easily released from the surface of aggregates of the respective nucleobases. The entropy term of the interaction energy calculated as a difference between the total energy determined from the binding constant and the enthalpy determined from excitation spectra constitutes approximately 30% for the telomeric oligonucleotide and is virtually null in interactions with nucleobase aggregates.     

Interplay of Sequence,Topology and Termini Charge in Determining the Stability of the Aggregates of GNNQQNY Mutants: A Molecular Dynamics Study

This study explores the stabilities of single sheet parallel systems of three sequence variants of ¹GNNQQNY⁷, N2D, N2S and N6D, with variations in aggregate size (5–8) and termini charge (charged or neutral). The aggregates were simulated at 300 and 330 K. These mutations decrease amyloid formation in the yeast prion protein Sup35. The present study finds that these mutations cause instability even in the peptide context. The protonation status of termini is found to be a key determinant of stabilities; other determinants are sequence, position of mutation and aggregate size. All systems with charged termini are unstable, whereas both stable and unstable systems are found when the termini are neutral. When termini are charged, the largest stable aggregate for the N2S and N6D systems has 3 to 4 peptides whereas N2D mutation supports oligomers of larger size (5-and 6-mers) as well. Mutation at 2^nd position (N2S and N2D) results in fewer H-bonds at the mutated as well as neighboring (Gly1/Gln4) positions. However, no such effect is found if mutation is at 6^th position (N6D). The effect of Asn→Asp mutation depends on the position and termini charge: it is more destabilizing at the 2^nd position than at the 6^th in case of neutral termini, however, the opposite is true in case of charged termini. Appearance of twist in stable systems and in smaller aggregates formed in unstable systems suggests that twist is integral to amyloid arrangement. Disorder, dissociation or rearrangement of peptides, disintegration or collapse of aggregates and formation of amorphous aggregates observed in these simulations are likely to occur during the early stages of aggregation also. The smaller aggregates formed due to such events have a variety of arrangements of peptides. This suggests polymorphic nature of oligomers and presence of a heterogeneous mixture of oligomers during early stages of aggregation.     

The detection of a precartilage, blastema-specific marker

Mesenchymal cell aggregates, termed blastema in vivo, precede cartilage differentiation in vivo and in high-density cell cultures. The galactose specific lectin, peanut agglutinin (PNA), has been shown to be blastema specific (B. Zimmermann and M. Thies, 1984, Histochemistry 81, 353-361). PNA appears to be a marker for precartilage cellular aggregates both in vivo and in vitro. Frozen sections of stage 24 chick wing buds were double stained with PNA-rhodamine and by indirect immunofluorescence with antibody directed against type II collagen. The PNA stained the humeral blastema intensely and extended distal to the level of type II collagen. High-density cultures of stage 24 chick wing buds were also evaluated for the distribution of PNA binding. Sixteen-hour cultures showed the earliest consistent appearance of PNA binding. The PNA-stained areas coincided with hematoxylin-stained cell aggregates. PNA staining was inhibited by 50 mM D(+)-galactose and was not sensitive to 1% testicular hyaluronidase pretreatment. No Alcian blue-staining nodules were present yet at 16 hr. The presence of a precartilage, blastema-specific marker in situ, as well as in precartilage aggregates in cultures, suggests the similarities in chondrogenesis between these two conditions. Stage 19 limb bud cultures did not form nodules but did form aggregates that were PNA positive. Furthermore, single cells that differentiated into chondrocytes on collagen gels or after cytochalasin D treatment lacked PNA-binding material. These results suggest that this material is specific to precartilage aggregates. The PNA-positive material was extracellular in distribution and was removed after brief extraction with 0.5 M guanidine hydrochloride.     

Characterization of Proteins Associated with Polyglutamine Aggregates

The common feature of many neurodegenerative diseases is emergence of protein aggregates. Identifying their composition can provide valuable insights into the cellular mechanisms of protein aggregation and neuronal death. No reliable method for identification of the aggregate-associated proteins has been available. Here we describe a method for characterization of protein aggregates based on sedimentation of immunocomplexes without involvement of a solid support. As a model, we used the aggregates formed in yeast by a polyglutamine-containing segment of mutant huntingtin. Sixteen proteins associated with the isolated aggregates were identified with 2D gel electrophoresis followed by mass spectrometry. We found that the aggregates in cells lacking Rnq1 prion recruited lesser amounts of chaperones than those in the wild type cells. The method can be utilized for characterization of various types of aggregates, prions and very large protein complexes under mild conditions that preserve associated proteins.