The bacterial planktonic growth and the removal of bacterial cells grown on polypropylene surface coated with covalently immobilized proteases (subtilisin Carlsberg or α-chymotrypsin) was investigated for Enterococcus hirae, Staphyloccocus epidermidis and Eschericha coli. Immobilization of both proteases on plasma-treated polypropylene was carried out using as cross-linking agent i) glutaraldehyde or ii) N'-diisopropylcarbodiimide and N-hydroxysuccinimide. In the presence of immobilized proteases a higher bacterial planktonic growth (up to 40 %) was observed. Instead, a different effect was observed on cell removal, and it varied according to the bacteria strain, the immobilized protease and the immobilization procedure. In particular, the presence of subtilisin in the polypropylene coating increased the cell removal of E. hirae by simple washing of the polypropylene surface and both subtilisin and α-chymotrypsin immobilized by N'-diisopropylcarbodiimide and N-hydroxysuccinimide favored the removal of S. epidermidis after sonication. No significant differences compared to the control where observed in all the other cases. In conclusion this study indicates that proteases can be an enhancer of microbial biomass (a phenomena that could be exploited for industrial fermentation) and can affect the strength of cell adhesion for some bacteria.
Cell-wall mechanical properties play an integral part in the growth and form of Saccharomyces cerevisiae. In contrast to the tremendous knowledge on the genetics of S. cerevisiae, almost nothing is known about its mechanical properties. We have developed a micromanipulation technique to measure the force required to burst single cells and have recently established a mathematical model to extract the mechanical properties of the cell wall from such data. Here we determine the average surface modulus of the S. cerevisiae cell wall to be 11.1 ؎ 0.6 N͞m and 12.9 ؎ 0.7 N͞m in exponential and stationary phases, respectively, giving corresponding Young's moduli of 112 ؎ 6 MPa and 107 ؎ 6 MPa. This result demonstrates that yeast cell populations strengthen as they enter stationary phase by increasing wall thickness and hence the surface modulus, without altering the average elastic properties of the cell-wall material. We also determined the average breaking strain of the cell wall to be 82% ؎ 3% in exponential phase and 80% ؎ 3% in stationary phase. This finding provides a failure criterion that can be used to predict when applied stresses (e.g., because of fluid flow) will lead to wall rupture. This work analyzes yeast compression experiments in different growth phases by using engineering methodology.
cDNAs were cloned for the murine and human orthologues of Chlamydomonas PF20, a component of the alga axoneme central apparatus that is required for flagellar motility. The mammalian genes encode transcripts of 1.4 and 2.5 kb that are highly expressed in testis. The two transcripts appear to arise from alternative transcription start sites. The murine Pf20 gene was mapped to chromosome 1, syntenic with the location of the human gene on chromosome 2. An antibody generated against an N-terminal sequence of mouse Pf20 recognized a 71-kDa protein in sperm and testis extracts. Immunocytochemistry localized Pf20 to the tails of permeabilized sperm; electron microscope immunocytochemistry showed that Pf20 was located in the axoneme central apparatus. A murine Pf20-green fluorescent protein fusion protein expressed in Chinese hamster ovary cells accumulated in the cytoplasm. When coexpressed with Spag6, the mammalian orthologue of Chlamydomonas PF16, Pf20 was colocalized with Spag6 on polymerized microtubules. Yeast two-hybrid assays demonstrated interaction of the Pf20 WD repeats with Spag6. Pf20 was markedly reduced in sperm collected from mice lacking Spag6, which are infertile due to a motility defect. Our observations provide the first evidence for an association between mammalian orthologues of two Chlamydomonas proteins known to be critical for axoneme structure and function.The "9 ϩ 2" microtubule architecture of the eukaryote axoneme has remained virtually unchanged over millions of years of evolution. Understanding the function of molecules that make up the axoneme is important for elucidating the assembly and activity of these structures that are essential for cell motility. The distinctive arrangement of nine outer doublet microtubules in a circle around a central pair of microtubules is recognizable in electron micrographs of flagella and cilia from plants, algae, protists, and animals. Attached along specific microtubules at precise locations and intervals are ranks of substructures including dynein arms, radial spokes, and central pair projections (25,26). Axonemal dyneins form the inner and outer arm structures that have different functions; the outer arms add power and adjust beat frequency (3,4,10,15,16,24,33); the inner arms generate the axonemal waveform (4,7,14,17,27). To work together efficiently, the multiple dynein isoforms must be locally activated and inactivated at different points in the beat cycle, both around the axoneme and along its length.Structural and genetic evidence implicated the radial spokecentral pair structures as key regulators of dynein activity. The radial spoke heads make transient contact with structures that project from the central pair microtubules (35). The central pair is composed of two microtubules (designated C1 and C2 in algae) and their associated structures which include the central pair projections, central pair bridges linking the two tubules, and central pair caps which are attached to the distal or plus ends of the microtubules.Mutants of the alga Chlamydomon...
Spermatogenesis can be divided into three stages: spermatogonial mitosis, meiosis of spermatocytes, and spermiogenesis. During spermiogenesis, spermatids undergo dramatic morphological changes including formation of a flagellum and chromosomal packaging and condensation of the nucleus into the sperm head. The genes regulating the latter processes are largely unknown. We previously discovered that a bi-functional gene, Spag16, is essential for spermatogenesis. SPAG16S, the 35 kDa, testis-specific isoform derived from the Spag16 gene, was found to bind to meiosis expressed gene 1 product (MEIG1), a protein originally thought to play a role in meiosis. We inactivated the Meig1 gene and, unexpectedly, found that Meig1 mutant male mice had no obvious defect in meiosis, but were sterile as a result of impaired spermatogenesis at the stage of elongation and condensation. Transmission electron microscopy revealed that the manchette, a microtubular organelle essential for sperm head and flagellar formation was disrupted in spermatids of MEIG1-deficient mice. We also found that MEIG1 associates with the Parkin co-regulated gene (PACRG) protein, and that testicular PACRG protein is reduced in MEIG1-deficient mice. PACRG is thought to play a key role in assembly of the axonemes/flagella and the reproductive phenotype of Pacrg-deficient mice mirrors that of the Meig1 mutant mice. Our findings reveal a critical role for the MEIG1/PARCG partnership in manchette structure and function and the control of spermiogenesis. Spermatogenesis can be divided into three stages: spermatogonial mitosis, meiosis of spermatocytes, and spermiogenesis, the final step of spermatogenesis. During this stage, the haploid round spermatids differentiate into species-specific shaped spermatozoon, with dramatic morphological changes, including elongation and condensation of the nucleus, and formation of the flagellum (1, 2). Even though some genes have been reported to be indispensable for this process (3, 4), the underlying mechanisms remains largely unknown and need to be elucidated.Mouse meiosis expressed gene 1 (Meig1) was originally identified in a search for mammalian genes potentially involved in meiosis. Two Meig1 transcripts, 11a2 and 2a2, were identified previously, both containing three exons. The two transcripts share the same ORF and 3Ј UTR, but differ in their 5Ј UTRs. Each has a unique non-translated exon 1. The 11a2 message was expressed in somatic cells in the testis, including Leydig cells, whereas the predominant 2a2 isoform was reported to be germ cell-specific. The 2a2 transcript begins to accumulate in the testis at day (d)8-9 of postnatal (pn) development, coinciding with the entry of germ cells into meiosis, and is expressed most abundantly at pn d14 and subsequent stages, when spermatocytes enter the pachytene stage. In situ hybridization analysis showed that Meig1 expression level was low in leptotene cells and increased as the cells progressed through zygotene and pachytene stages. In addition, Meig1 message was also detecte...
Effect of formulation of alginate beads on their mechanical behavior and stiffness. AbstractThe aim of this work was to determine the effect of formulation of alginate beads on their mechanical behavior and stiffness when compressed at high speed. The alginate beads were formulated using different types and concentrations of alginate and gelling cations and were produced using an extrusion-dripping method. Single wet beads were compressed at a speed of 40 mm/min, and their elastic limits were investigated, and the corresponding force versus displacement data were obtained. The Young's moduli of the beads were determined from the force versus displacement data using the Hertz's contact mechanics theory. The alginate beads were found to exhibit plastic behavior when they were compressed beyond 50% with the exception of copper-alginate beads for which yield occured at lower deformation. Alginate beads made of higher guluronic acid contents and gelling cations of higher chemical affinity were found to have greater stiffness. Increasing the concentration of alginate and gelling ions also generated a similar effect. At such a compression speed, the values of Young's modulus of the beads were found to be in the range between 250 and 900 kPa depending on the bead formulation.
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