The Sertoli Cell-Spermatid Junctional Complex: A potential avenue for Male contraception

Wolski, Katja Margrit

01 June 2006

The Sertoli cell ectoplasmic specialization is a specialized domain of the calcium-dependent Sertoli-spermatid adherens junction. Structurally abnormal or absent Sertoli ectoplasmic specializations are associated with spermatid sloughing and subsequent oligospermia in conditions associated with reduced fertility potential, although the junctional strength between these cells is not known. Adjudin is a potential male contraceptive agent thought to interrupt testicular binding dynamics of adherens junctions, resulting in controlled spermatid sloughing.It was hypothesized that the mechanism of action of Adjudin, pertinent to its putative contraceptive effect, is the disruption of the Sertoli cell-spermatid junction. This was tested in vitro using primary isolates of germ cells and both primary and immortal Sertoli cells.This dissertation presents the examination of Sertoli-germ cell interactions in three parts, which address the overall aims of this dissertation project: (1) measurement of the junctional strength between Sertoli cells and spermatids in vitro, (2) determination of the efficacy of sk Sertoli cell lines in Sertoli-germ cell binding studies in vitro, and (3) assessment of Adjudin as a potential male contraceptive, by measuring the junctional binding strength between Sertoli cells and spermatids exposed to this chemical in vitro.For the first time, the strength of the Sertoli-spermatid junction has been measured, using a micropipette pressure transducing system (MPTS). Results reported in this dissertation demonstrate that the junctional strength between Sertoli cells and germ cells can be measured in vitro, support long held speculations regarding Sertoli-spermatid junctional interactions, and provide a technology to test proposed mechanisms of junctional binding dynamics between cells of the seminiferous epithelium (Chapter 2). Although the sk cell lines initially expressed mRNA for the FSH receptor, coculture results determined that these cell lines have limited value for investigating Sertoli-germ cell binding dynamics in vitro (Chapter 3). By utilizing the MPTS and primary cell isolates, Adjudin was determined to reduce the junctional strength between Sertoli cells and step-8 spermatids. In conclusion, results support the use of Adjudin as a potential reversible male contraceptive agent by a mechanism which alters the adhesion properties between the step-8 spermatid and the Sertoli cell (Chapter 4).

Ectoplasmic specialization

Cell-cell junction

Cell culture

Micropipette

Adjudin

American Studies

Arts and Humanities

Multiphoton techniques for dynamic manipulation of cellular microenvironments

Hernandez, Derek Scott

10 September 2015

A multitude of biophysical signals, including chemical, mechanical, and contact guidance cues, are embedded within the extracellular matrix (ECM) to dictate cell behavior and determine cell fate. To understand the complexity of the cell-matrix interaction and how changes to the ECM contribute to the development of tissues or diseases, three-dimensional (3D), culture systems that can decouple the effects of these cues on cell behavior are required. This dissertation describes the development and characterization of approaches based on multiphoton excitation (MPE) to control the chemical, mechanical, and topographical presentation of micro-3D-printed (μ-3DP) protein hydrogels independently. Protein hydrogels were chemically functionalized via the MPE-induced conjugation of benzophenone-biotin without altering the physical properties of the matrix. Complex, immobilized patterns and chemical gradients were generated within protein hydrogels with a high degree of spatial resolution in all axes. Hydrogel surfaces were also labeled with adhesive moieties to promote localized Schwann cell adhesion and polarization. Laser shrinking, a method based on MPE to manipulate the topographical and mechanical presentation of protein hydrogels after fabrication, is also presented. Topographical features on an originally flat substrate are created with depths approaching 6 μm. The Young’s modulus of protein hydrogels can also be increased by 6-fold (~15 – ~90 kPa) using laser shrinking, and parameters can be adjusted to create continuous gradient profiles for studying durotaxis. At determined scan conditions, the two properties can be adjusted independently of each other. Most importantly, the physical properties of the hydrogels can be manipulated in situ to study the effects of dynamic changes to the substrates on cells. As a potential tool to monitor cellular responses to presented cues, fluorescent probes that detect nitric oxide are characterized. Collectively, these technologies represent a key advance in hydrogel tunability, as the platforms presented offer independent, dynamic, and spatiotemporal control of the chemical, mechanical, and topographical features of protein hydrogels. The introduced technologies expand the possibilities of protein hydrogels to clarify underlying factors of cell-matrix interactions that drive morphogenesis and pathogenesis, and are broadly applicable to a multitude of physiological systems. / text

Dynamic cell culture

Hydrogels

Biomaterials

Schwann cells

Immobilization

Chemical gradients

Stiffness gradients

Smart Packaging: A Novel Technique For Localized Drug Delivery For Ovarian Cancer

Williams, Eva Christabel

01 January 2012

Localized drug delivery is emerging as an effective technique due to its ability to administer therapeutic concentrations and controlled release of drugs to cancer sites in the body. It also prevents the contact of harsh chemotherapy drugs to healthy regions in the body that otherwise would become exposed to current treatments. This study reports on a model chemotherapy drug delivery system comprising non-ionic surfactant vesicles (niosomes) packaged within a temperature-sensitive chitosan network. This smart packaging, or package-within-a package system, provides two distinct advantages. First, the gel prevents circulation of the niosomes and maintains delivery in the vicinity of a tumor. Secondly, the chitosan network protects the niosomes against fluctuations in tonicity, which affects delivery rates. Tonicity is the sum of the concentrations of the solutes which have the capacity to exert an osmotic force across the membrane. Release rates were monitored from both bare niosomes alone and niosome-embedded, chitosan networks. It was observed that chitosan networks prolonged delivery from 100 hours to 55 days in low ionic strength environment and pH conditions similar to a tumor site. The primary effect of chitosan is to add control on release time and dosage, and stabilize the niosomes through a high ionic strength surrounding that prevents uncontrolled bursting of the niosomes. Secondary factors include cross-link density of the chitosan network, molecular weight of the individual chitosan polymers, dye concentration within the niosomes, and the number density of niosomes packaged within the chitosan network. Each of these factors can be altered to fine-tune release rates. Release rate experiments were conducted with 5,6-carboxyfluorescein, a fluorescent dye and chemotherapeutics paclitaxel and carboplatin. In vitro studies showed a preferential affinity of the smart packaged system to ovarian carcinoma cell line OV2008 as compared to normal epithelial cell lines of Ilow and MCC3. Further, feasibility of the drug delivery system was evaluated in vivo. Toxicity studies revealed that the system was non-toxic and feasible in vivo. The final outcome of this study includes tuning of the variables mentioned above that will contribute to the development of low cost and improved methods for drug delivery with application to intracavitary ovarian cancer treatment and other types of cancer

cell culture

chitosan

confocal microscopy

niosome

thermo-responsive hydrogel

xenogen

American Studies

Arts and Humanities

Chemical Engineering

Collective Migration Models: Dynamic Monitoring of Leader Cells in Migratory/Invasive Disease Processes

Dean, Zachary S.

January 2015

Leader cells are a fundamental biological process that have only been investigated since the early 2000s. These cells have often been observed emerging at the edge of an artificial wound in 2D epithelial cell collective invasion, created with either a mechanical scrape from a pipette tip or from the removal of a plastic, physical blocker. During migration, the moving cells maintain cell-cell contacts, an important quality of collective migration; the leader cells originate from either the first or the second row, they increase in size compared to other cells, and they establish ruffled lamellipodia. Recent studies in 3D have also shown that cells emerging from an invading collective group that also exhibit leader-like properties. Exactly how leader cells influence and interact with follower cells as well as other cells types during collective migration, however, is another matter, and is a subject of intense investigation between many different labs and researchers. The majority of leader cell research to date has involved epithelial cells, but as collective migration is implicated in many different pathogenic diseases, such as cancer and wound healing, a better understanding of leader cells in many cell types and environments will allow significant improvement to therapies and treatments for a wide variety of disease processes. In fact, more recent studies on collective migration and invasion have broadened the field to include other cell types, including mesenchymal cancer cells and fibroblasts. However, the proper technology for picking out dynamic, single cells within a moving and changing cell population over time has severely limited previous investigation into leader cell formation and influence over other cells. In line with these previous studies, we not only bring new technology capable of dynamically monitoring leader cell formation, but we propose that leader cell behavior is more than just an epithelial process, and that it is a critical physiological process in multiple cell types and diseases.

cancer

fluorescence

Leader cell

miRNA

wound healing

Biomedical Engineering

3D cell culture

SELF-ASSEMBLY OF SILK-ELASTINLIKE PROTEIN POLYMERS INTO THREE-DIMENSIONAL SCAFFOLDS FOR BIOMEDICAL APPLICATIONS

Zeng, Like

January 2014

Production of brand new protein-based materials with precise control over the amino acid sequences at single residue level has been made possible by genetic engineering, through which artificial genes can be developed that encode protein-based materials with desired features. As an example, silk-elastinlike protein polymers (SELPs), composed of tandem repeats of amino acid sequence motifs from Bombyx mori (silkworm) silk and mammalian elastin, have been produced in this approach. SELPs have been studied extensively in the past two decades, however, the fundamental mechanism governing the self-assembly process to date still remains largely unresolved. Further, regardless of the unprecedented success when exploited in areas including drug delivery, gene therapy, and tissue augmentation, SELPs scaffolds as a three-dimensional cell culture model system are complicated by the inability of SELPs to provide the embedded tissue cells with appropriate biochemical stimuli essential for cell survival and function. In this dissertation, it is reported that the self-assembly of silk-elastinlike protein polymers (SELPs) into nanofibers in aqueous solutions can be modulated by tuning the curing temperature, the size of the silk blocks, and the charge of the elastin blocks. A core-sheath model was proposed for nanofiber formation, with the silk blocks in the cores and the hydrated elastin blocks in the sheaths. The folding of the silk blocks into stable cores - affected by the size of the silk blocks and the charge of the elastin blocks - plays a critical role in the assembly of silk-elastin nanofibers. The assembled nanofibers further form nanofiber clusters on the microscale, and the nanofiber clusters then coalesce into nanofiber micro-assemblies, interconnection of which eventually leads to the formation of three-dimensional scaffolds with distinct nanoscale and microscale features. SELP-Collagen hybrid scaffolds were also fabricated to enable independent control over the scaffolds' biochemical input and matrix stiffness. It is reported herein that in the hybrid scaffolds, collagen provides essential biochemical cues needed to promote cell attachment and function while SELP imparts matrix stiffness tunability. To obtain tissue-specificity in matrix stiffness that spans over several orders of magnitude covering from soft brain to stiff cartilage, the hybrid SELP-Collagen scaffolds were crosslinked by transglutaminase at physiological conditions compatible for simultaneous cell encapsulation. The effect of the increase in matrix stiffness induced by such enzymatic crosslinking on cellular viability and proliferation was also evaluated using in vitro cell assays.

matrix stiffness

self-assembly

Silk-elastinlike Proteins

Mechanical Engineering

3D cell culture

A cytotoxic evaluation of aflatoxin B1, zearalenone and their epoxide derivatives using human cell lines.

Pillay, Dharmarai.

January 1996

Since the discovery of mycotoxins in food, the thrust of biochemical and toxicological research has been carried out on animals which has proven to be uncoordinated and not easily extrapolated to humans. Over the last decade, there have been increasing pressures to review and reduce the use of animals in experimental toxicological studies. Consequently in this study aflatoxin B1 (AFB1), zearalenone (Zea) and their epoxide derivatives have been evaluated using in vitro assays. The HepG2, A549 and Hela cell lines were used for assessing the cytotoxicity, effects on cellular metabolism and sites of action of AFB1, Zea and their derivatives. The cytotoxicity of these mycotoxins was evaluated using the methylthiazol tetrazolium (MTT) reduction assay. Cells, treated with mycotoxins were prepared for transmission electron mlcroscopy (TEM), immunocytochemistry (ICC), scanning electron microscopy (SEM), confocal and light microscopy. From the cytotoxicity assay it was found that the epoxide derivatives were more toxic than the parent toxin when exposed to HepG2 cells with no significant differences in toxicity levels in A549 and Hela treated cells. Both epoxide derivatives displayed a regression of hepatoma cell proliferation at high doses (25ug/ml) while lower concentrations (<12.5ug/ml) enhanced cell growth. Microscopy analyses showed distinct cellular alterations. When exposed to AFB1 (12.5ug/ml) hepatoma cells showed prominent ultrastructural alterations such as areas of cytoplasmic lysis and increased numbers of secondary lysosomes while cells exposed to Zea (l2.5ug/ml) displayed numerous ovoid mitochondria and proliferation of rough endoplasmic reticulum which is indicative of enhanced protein synthesis. The presence of label in toxin treated cells is suggestive of the effects of these mycotoxins. Such cellular changes may lead to altered metabolism and cell function. / Thesis (M.Med.)-University of Natal, Durban, 1996.

Mycotoxins.

Aflatoxins.

Human cell culture.

Toxicity testing--In vitro.

Theses--Human physiology.

The cytotoxic effects of aflatoxin B1 and fumonisin B1 on cultured human cells.

Van der Stok, Mary Elizabeth.

January 2004

Aflatoxin B1 (AFB1) and Fumonisin B1 (FB1), potentially cytotoxic and carcinogenic mycotoxins are common contaminants of agricultural commodities in South Africa and thus could be detrimental to the human immune system. Many of the cytotoxic effects of AFB1 require its bioactivation to an epoxide, which will bind covalently to macromolecules to form protein and DNA adducts. Fumonisin B1 is a competitive inhibitor of sphingosine and sphinganine N aceyltransferase, which are key components in the pathways for sphingolipid biosynthesis. Accumulation of free sphingoid bases, which are both cytotoxic and mitogenic, could provide a plausible explanation for the toxicity and carcinogenicity of FB1. The cytotoxic effects of AFB1 and FB1 on normal human lymphocytes, individually and in combination were assessed using the methylthiazol tetrazolium (MTT) bioassay. Two different methods of treatment were used, the treatment of isolated normal human lymphocytes for 12, 24, 48, 72 and 96 hours and whole blood treated for 12 hours. Flow cytometry and fluorescent microscopy were used to determine whether AFB1 and FB1 (5uM and 50uM), individually or in combination, were capable of inducing apoptosis, necrosis or nuclear fragmentation in isolated lymphocytes and whole blood treated for 12 hours. DNA damage was evaluated using the comet assay. The results showed that AFB1routinely induced higher levels of cytotoxicity in isolated lymphocytes than FB1. In the combination treatment, the mitogenic properties of FB1 appeared to partially counteract the cytotoxic effect exerted by AFB1. When whole blood was treated with the same concentration and ratio of toxin, FB1 was shown to be more cytotoxic than AFB1. The combination treatment of whole blood was shown to be cytotoxic in a dose dependent manner. The toxins appeared to exert a greater cytotoxic effect, when treated in combination than individually at higher concentrations. Aflatoxin B1 induced increased levels of apoptosis and necrosis in isolated lymphocytes while treatment with the FB1 resulted in increased levels of apoptosis at both concentrations. Treatment with the combination also resulted in increased levels of apoptosis. The levels of apoptosis were reduced in whole blood lymphocytes when compared to isolated lymphocytes. However, treatment with AFB1 and FB1 resulted in increased levels of apoptosis. Both AFB1 and FB1 are capable of inducing nuclear fragmentation. Treatment with FB1 (5uM and 50uM) resulted in greater degree of fragmentation than AFB1. The most nuclear fragmentation was induced by the 5uM combination treatment. The 50uM combination treatment of isolated lymphocytes induced the most DNA damage. As both toxins are common contaminants and have been known to coexist, this could be a potential area of concern for public health. / Thesis (M.Med.)-University of KwaZulu-Natal, 2004.

Fumonisins.

Mycotoxins.

Toxicity testing.

Aflatoxins.

Human cell culture--Effect of chemicals.

Theses--Human physiology.

New Microfluidic Platforms for Cell Studies

Barbulovic-Nad, Irena

07 March 2011

Biological cell manipulation and analysis is one of the most investigated applications of microfluidics. In the last decade, researchers have developed means to handle and sort cells, isolate and study single cells, assay whole and lysed cells, and transfect and electroporate in microchannels. Much of this work was motivated by the observation that many external forces and fields scale favorably in the micro-regime; this is especially the case for the electrical field. This dissertation investigates further integration of electrical forces with microfluidic devices, both channel- and droplet-based, in order to generate new, flexible and more efficient tools for studying cell biology. The first part of the dissertation (Chapter 3) explores a new dielectrophoretic particle separation method in microchannels. Current electrodeless dielectrophoretic (DEP) separation techniques utilize insulating solid obstacles in a direct current (DC) or low-frequency alternating current (AC) field, while this novel method employs an oil droplet acting as an insulating hurdle between two electrodes. Since the size of the droplet can be dynamically changed, the electric field gradient, and hence DEP force, becomes easily controllable and adjustable to various separation parameters. Very effective separation at the low field strength suggests that this method can also be applied to a separation of biological cells that are not sensitive to low electric potential. The second, larger part of the dissertation (Chapters 4 and 5) is focused on digital microfluidics (DMF), which is used to actuate nanoliter droplets of reagents and cells on a planar array of electrodes. It was demonstrated for the first time that DMF can be used as a method for cell culture and analysis. Several cell-based applications were implemented in DMF format including long-term culture, cell passaging, assaying and transfection. The data presented here suggest advanced performance of DMF techniques relative to standard macro-scale techniques. Cell analysis using DMF was found to be advantageous because of greatly reduced reagent and cell use, increased sensitivity, and the potential for multiplexing. Also, DMF technique for cell passaging demonstrated faster and more straightforward manipulation of cells than the standard techniques. In addition, no adverse effects of actuation by DMF were observed in assays for cell viability, proliferation, and biochemistry. The new DMF platform for long-term mammalian cell culture represents the first microfluidic implementation of any kind of all of the steps required for mammalian cell culture – cell seeding, growth, detachment, and re-seeding on a fresh surface. In addition, it is the first demonstration of long-term cell culture in nanoliter droplets. Cells handled in this manner exhibited growth characteristics and morphology comparable to those cultured in standard tissue culture vessels. We anticipate that the DMF cell culture and analysis techniques presented here will be useful in myriad applications that would benefit from automated mammalian cell culture.

microfluidics

digital microfluidics

droplets

dielectrophoresis

cell assays

cell sorting

cell culture

microscale cell subculture

0541

New Microfluidic Platforms for Cell Studies

Barbulovic-Nad, Irena

07 March 2011

Biological cell manipulation and analysis is one of the most investigated applications of microfluidics. In the last decade, researchers have developed means to handle and sort cells, isolate and study single cells, assay whole and lysed cells, and transfect and electroporate in microchannels. Much of this work was motivated by the observation that many external forces and fields scale favorably in the micro-regime; this is especially the case for the electrical field. This dissertation investigates further integration of electrical forces with microfluidic devices, both channel- and droplet-based, in order to generate new, flexible and more efficient tools for studying cell biology. The first part of the dissertation (Chapter 3) explores a new dielectrophoretic particle separation method in microchannels. Current electrodeless dielectrophoretic (DEP) separation techniques utilize insulating solid obstacles in a direct current (DC) or low-frequency alternating current (AC) field, while this novel method employs an oil droplet acting as an insulating hurdle between two electrodes. Since the size of the droplet can be dynamically changed, the electric field gradient, and hence DEP force, becomes easily controllable and adjustable to various separation parameters. Very effective separation at the low field strength suggests that this method can also be applied to a separation of biological cells that are not sensitive to low electric potential. The second, larger part of the dissertation (Chapters 4 and 5) is focused on digital microfluidics (DMF), which is used to actuate nanoliter droplets of reagents and cells on a planar array of electrodes. It was demonstrated for the first time that DMF can be used as a method for cell culture and analysis. Several cell-based applications were implemented in DMF format including long-term culture, cell passaging, assaying and transfection. The data presented here suggest advanced performance of DMF techniques relative to standard macro-scale techniques. Cell analysis using DMF was found to be advantageous because of greatly reduced reagent and cell use, increased sensitivity, and the potential for multiplexing. Also, DMF technique for cell passaging demonstrated faster and more straightforward manipulation of cells than the standard techniques. In addition, no adverse effects of actuation by DMF were observed in assays for cell viability, proliferation, and biochemistry. The new DMF platform for long-term mammalian cell culture represents the first microfluidic implementation of any kind of all of the steps required for mammalian cell culture – cell seeding, growth, detachment, and re-seeding on a fresh surface. In addition, it is the first demonstration of long-term cell culture in nanoliter droplets. Cells handled in this manner exhibited growth characteristics and morphology comparable to those cultured in standard tissue culture vessels. We anticipate that the DMF cell culture and analysis techniques presented here will be useful in myriad applications that would benefit from automated mammalian cell culture.

microfluidics

digital microfluidics

droplets

dielectrophoresis

cell assays

cell sorting

cell culture

microscale cell subculture

0541

The Development of a 3D Piezoelectric Active Microtissue Model for Airway Smooth Muscle

Walker, Matthew

08 April 2013

Although asthma is primarily thought to be an inflammatory disease of the airways, it has recently been hypothesized that the altered mechanical environment of an asthmatic airway may contribute to the development of the disease through changes in cellular phenotype. In regards to this hypothesis, the effects of stretch on airway smooth muscle (ASM) have previously been investigated using 2D cell culture. However, over the last few years there has been an increasing appreciation to the importance of the role of the 3D extracellular matrix in the regulation of cellular response. For this reason, the work presented in this thesis covers the development of a device capable of high-throughput investigations into the effects of acute or chronic, uniaxial, oscillatory mechanical strain on an array of miniature, 3D, multi-cell, tissue-engineered constructs.

Microtisse

Piezoelectric

3D Cell Culture

Airway Smooth Muscle

Stretch

Asthma

Mechanobiology