Roles of Seminolipid and Its Associated Membrane Domain in Male Fertility

Kongmanas, Kessiri

January 2015

Our research aims at understanding the roles of seminolipid (sulfogalactosylglycerolipid or SGG) and its associated membrane domains in male reproduction. SGG is a sulfoglycolipid present selectively and abundantly in mammalian male germ cells. Therefore, information on its properties would be relevant towards the development of male fertility biomarkers and spermicide-based contraceptives. We have shown that SGG has direct affinity for zona pellucida (ZP, egg extracellular matrix) and plays a role in the formation of sperm lipid rafts, the ZP-binding platforms on the sperm anterior head plasma membrane (APM), the initial ZP binding site. For a better understanding of mechanisms underlying sperm-ZP interaction, I performed proteomic characterization of APM vesicles (SGG-associated membrane domains with ZP affinity) isolated from sperm before and after capacitation, a process through which sperm gain maximal ZP affinity. Proteomic results revealed that capacitated APM vesicles contained high-molecular-weight protein complexes, with higher ZP affinity and levels of ZP-binding proteins as compared with those of the non-capacitated samples. ZP-binding proteins known to exist in the acrosome (i.e., zonadhesin, proacrosin/acrosin) were found in these APM protein complexes. Immunofluorescence suggested that a fraction of these proteins trafficked from the acrosome to APM during capacitation. These findings provided a new mechanism on how sperm gain full ZP-binding ability during capacitation. Since SGG is a major component of APM, proper SGG levels at this site would be important for male fertility. Levels of sperm SGG are regulated through the synthesis and degradation. In fact, lack of SGG-synthesis enzymes causes a spermatogenesis disruption, resulting in male infertility. However, significance of SGG degradation remains unknown. SGG can be desulfated in vitro by arylsulfatase A (ARSA), an enzyme existing in the acrosomes of sperm/spermatids and lysosomes of Sertoli cells, testicular somatic cells that nurture developing germ cells. Sertoli cells also phagocytose ~50% of germ cells that become apoptotic during spermatogenesis. To understand physiological importance of SGG degradation, the fertility status and SGG levels of Arsa-/- male mice were determined. We found that Arsa-/- males became subfertile when they were older than 5 months, and when they were 8-month-old (~40-year-old men) they produced sperm at 50% wild type rate. Arsa-/- sperm had minimal in vitro fertilizing ability and a number of them showed abnormal morphology. Quantitative mass spectrometry revealed that SGG levels in Sertoli cells of 8-month-old Arsa-/- mice were increased to ~250% of the wild type level; this SGG accumulation may lead to a decrease in Sertoli cell ability to support spermatogenesis. However, SGG levels in sperm of 8-month-old Arsa-/- mice were ~50% of the wild type value, a result that partly explained the decreased fertilizing ability of these sperm. The reduced SGG level of Arsa-/- sperm was likely due to a lack of SGG’s building-block lipid (palmitylpalmitoylglycerol) putatively generated in Arsa-/- Sertoli cells and recycled to the next generation of primary spermatocytes for SGG synthesis. Hence, levels of sperm SGG are a promising bioindex for male fertility. Since Sertoli cells also regulate SGG homeostasis, their functionality should be now included in male fertility/subfertility diagnosis.

Seminolipid

Zona pellucida

Sperm anterior head plasma membrane

Acrosomal proteins

Capacitation

Arylsulfatase A

Sertoli cells

Male fertility

Lysosomal storage disorder

Mass spectrometry

Nouvelles régulations métaboliques exercées par la signalisation LKB1 dans les cellules polarisées : conséquences pour l’ontogénie tissulaire / Novel metabolic regulations exerted by LKB1 signaling in polarized cells : impact on tissue ontogeny

Radu, Anca Gabriela

18 May 2018

Le suppresseur de tumeur et sérine/thréonine kinase LKB1 est un régulateur clé de la polarité cellulaire et du métabolisme énergétique en partie grâce à l'activation de sa kinase substrat AMPK. Cette protéine est un senseur métabolique pour adapter les apports énergétiques aux besoins nutritionnels des cellules confrontées à un stress. Pour cela, AMPK phosphoryle divers substrats qui activent les réactions cataboliques et inhibent les processus anaboliques dont la kinase mTOR.Au cours de ma thèse, via l’utilisation de modèles murins d’inactivation conditionnelle, j'ai découvert que Lkb1 est crucial pour la formation des cellules de crête neurale (CCN). Ces cellules multipotentes, originaires du tube neural, donnent naissance à divers dérivés, comme les cellules des os et cartilage de la face, les cellules pigmentées de la peau et les cellules gliales et neurales des nerfs périphériques et du système nerveux entérique. J'ai démontré que Lkb1 est essentiel pour la formation de la tête des vertébrés et pour la différenciation et le maintien des dérivés des CCN dans le système nerveux périphérique. J'ai également mis en évidence l’acétylation de LKB1 sur la lysine 48 par l'acétyltransférase GCN5 et son rôle dans l'ontogenèse des CCN céphaliques et la formation de la tête. De plus, j'ai découvert que Lkb1 contrôle la différenciation des cellules gliales en réprimant un programme de biosynthèse d’acides aminés couplé à la transamination du pyruvate en alanine, en amont de la voie de signalisation mTOR.Les phénotypes dus à la perte de Lkb1 dans les CCN récapitulent les caractéristiques cliniques de maladies humaines appelées neurocristopathies. L’activation anormale du suppresseur de tumeur p53 est également associée à certaines neurocristopathies et l’ablation de p53 sauve le phénotype pathologique. Ainsi, j'ai montré que Lkb1 dans les cellules gliales contrôle p53 en limitant les dommages à l’ADN. Lkb1 est aussi essentiel pour maintenir l’homéostasie lysosomale et le recyclage des protéines et ainsi empêcher la formation de granules nommés lipofuscine, chargés en protéines et lipides oxydés. De façon intéressante, les voies mTOR et LKB1/AMPK sont activées à la surface des lysosomes de façon dépendante des niveaux d’acides aminés. Des données récentes de la littérature suggèrent que les lysosomes constitueraient une plateforme de signalisation pour contrôler la protéolyse et le devenir cellulaire. Ainsi, nos données proposent que les signalisations Lkb1 et p53 pourraient réguler l'homéostasie lysosomale et en conséquence le vieillissement cellulaire.De façon intéressante, les cellules de Sertoli, des cellules somatiques épithéliales, localisées dans les tubes séminifères des testicules, et qui régissent la maturation des cellules germinales et l'homéostasie testiculaire, partagent des fonctions métaboliques similaires avec les cellules gliales. En effet, ces cellules sécrètent le lactate et l'alanine qui alimentent les mitochondries des cellules voisines (cellules germinales ou neurones respectivement) contrôlant ainsi leur survie et leur maturation. Au cours de ma thèse, nous avons observé que Lkb1 est requis pour l'homéostasie testiculaire et la spermatogenèse en régulant la polarité des cellules de Sertoli et leur métabolisme énergétique par le cycle pyruvate-alanine. Ces résultats suggèrent une conservation des régulations métaboliques par Lkb1 dans divers tissus.Dans leur ensemble, mes travaux de thèse ont apporté une meilleure connaissance des mécanismes sous-jacents des régulations métaboliques lors du devenir cellulaire. Ces résultats fournissent de nouvelles perspectives sur le développement des CCN et élargissent notre compréhension du contrôle métabolique exercé par LKB1. Enfin, mes projets de doctorat ont mis en évidence l'existence d'une communication entre les voie de signalisation Lkb1 et p53 et suggèrent l’importance de cette communication dans les pathologies humaines dues à des défauts des CCN. / The tumor suppressor LKB1 codes for a serine/threonine kinase. It acts as a key regulator of cell polarity and energy metabolism partly through the activation of the AMP-activated protein kinase (AMPK), a sensor that adapts energy supply to the nutrient demands of cells facing situations of metabolic stress. To achieve metabolic adaptations, AMPK phosphorylates numerous substrates which inhibit anabolic processes while activating catabolic reactions. In particular, AMPK inhibits the mammalian target of rapamycin (mTOR).During my PhD, based on genetically engineered mouse models, I uncovered that Lkb1 signaling is essential for neural crest cells (NCC) formation. NCC are multipotent cells that originate from the neural tube and give rise to various derivatives including bones and cartilage of the face, pigmented cells in the skin and glial and neural cells in peripheral nerves and the enteric nervous system. I demonstrated that Lkb1 is essential for vertebrate head formation and for the differentiation and maintenance of NCC-derivatives in the peripheral nervous system. I also emphasized that LKB1 is acetylated on lysine 48 by the acetyltransferase GCN5 and that this acetylation could regulates cranial NCC ontogeny and head formation. Furthermore, I discovered that Lkb1 controls NCC-derived glial differentiation through metabolic regulations involving amino acid biosynthesis coupled to pyruvate-alanine cycling upstream of mTOR signaling.Phenotypes due to Lkb1 loss in NCC recapitulate clinical features of human disorders called neurocristopathies and therefore suggest that aberrant Lkb1 metabolic signaling underlies the etiology of these pathologies. Abnormal activation of the tumor suppressor p53 has been described in some NCC disorders and p53 inactivation in neurocristopathy mouse models rescues the pathological phenotype. By using a NCC line that can be cultivated as progenitors or differentiated in glial cells in vitro, I demonstrated that Lkb1 expression in NCC-derivatives controls p53 activation by limiting oxidative DNA damage and prevents the formation of lysosomes filled with oxidized proteins and lipids called lipofuscin granules. Interestingly, activation of mTOR and LKB1/AMPK pathways is governed by amino acid sensors and takes place at the lysosome surface. Lysosomes have been proposed as a signaling hub controlling proteolysis and aging. Thus Lkb1 and p53 signaling could converge especially through lysosome homeostasis thereby potentially impacting cellular aging.Strikingly, Sertoli cells, that are epithelial somatic cells, located in seminiferous tubules in testes, and which govern germ cells maturation and whole testis homeostasis, share similar metabolic functions with glial cells. For example, they secrete lactate and alanine to fuel mitochondria of neighboring cells (germ cells or neurons respectively) to control their survival and maturation. During my PhD, we highlighted that Lkb1 is essential for testis homeostasis and spermatogenesis by regulating Sertoli cell polarity and, as observed in glial cells, energy metabolism through pyruvate-alanine cycling. These data suggest that this particular Lkb1 metabolic regulation is conserved in tissues with similar function.Taken together, these studies reveal the underlying molecular mechanisms that coordinately regulate energy metabolism and cell fate. They provide new insights into NCC development and expand our understanding of the role of LKB1 as an energy metabolic regulator. Finally, my PhD projects uncover the existence of a crosstalk between Lkb1 and p53 and underline its importance in NCC disorders.

Crêtes neurales

Cellules de Sertoli

Métabolisme énergétique

Neurocristopathies

LKB1. p53. AMPK. mTOR

Polarité

Neural crest

Sertoli cells

Energy metabolism

Neurocristopathies

LKB1. p53. AMPK. mTOR

Polarity

570

In vitro diferenciace testikulárních somatických buněk Xenopus tropicalis a Mus musculus. / In vitro differentiation of Xenopus tropicalis and Mus musculus testicular somatic cells.

Hlaviznová, Michaela

January 2021

Sertoli cells (SCs) are somatic cells of testicular tissue that are involved in spermatogenesis and maturation of germ cells. They are currently being extensively studied for their immunomodulatory abilities, and recent studies have shown that they share some properties with mesenchymal stromal cells (MSCs). Detailed characterization of SCs and clarification of their role in testicular tissue is crucial for potential use of SCs as a therapeutic tool in regenerative medicine. Cell culture of Xenopus tropicalis immature Sertoli cells (XtiSCs) and Mus musculus (mSCs) Sertoli cells were established in the Laboratories of Developmental Biology and Immunoregulations, Faculty of Science, Charles University. Previous research has characterized XtiSCs and demonstrated their multipotent potential by in vitro differentiation into a mesodermal line. Following this research, one of the goals of the diploma project was the induction of in vitro differentiation of XtiSC into other cell types, which would verify the differentiation potential of XtiSCs. The mSC expression profile confirmed the somatic origin of this culture as well as the transcription of Sertoli cell gene markers. Differentiation of mSCs along the mesodermal line into osteoblasts, chondrocytes and adipocytes has been successfully induced in vitro....

Desreguladores endócrinos versus Ginsenosídeos modulação da via não genômica ativada por GPR30 e estresse oxidativo em células de Sertoli humanas (HSeC) /

Freitas, André Teves Aquino Gonçalves de.

January 2019

Orientador: Wellerson Rodrigo Scarano / Resumo: Citocinas e proteínas quinases são fundamentais para o controle do processo espermatogênico, estando diretamente envolvidas na dinâmica da barreira hematotesticular. Diferentes mecanismos de controle são modulados por receptores como o GPR30, que ativa rapidamente diferentes vias de sinalização, responsáveis pelos processos de proliferação, sobrevivência e morte celular. Os desreguladores endócrinos (DEs) possuem grande afinidade pelo GPR30, além de potencial para ativar vias de estresse oxidativo e a abertura da barreira. Antagonistas funcionais dos DEs, como o Panax ginseng, podem ser protetores contra seus efeitos. Considerando a importância das vias de sinalização que regulam a espermatogênese e a constante exposição ambiental aos DEs a que estamos submetidos, este trabalho objetiva estudar a possível modulação da via não genômica ativada por GPR30 e do estresse oxidativo em células de Sertoli expostas a baixas doses do DE Monobutil Ftalato (MBP) bem como o potencial papel citoprotetor do GIM-1 (metabólito do P. ginseng) sobre essas células. Para tal, as células de Sertoli humanas (HSec) foram mantidas sobre matriz artificial, simulando o ambiente in vivo. A exposição ao MBP e ao GIM-1 foi realizada nos tempos de 30min, 1, 12, e 48 horas, em doses pré-estabelecidas pelo ensaio do MTT (teste de toxicidade) em 4 grupos: controle, MBP, GIM-1 e MBP + GIM-1. A morfologia celular foi avaliada pela coloração com Hematoxilina e Eosina, evidenciando efeitos deletérios do MBP sobre... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Cytokines and kinases protein are essential to control the spermatogenic process, being directly involved in the blood-testis barrier control. Activation of these mechanisms is modulated by receptors such as GPR30, which rapidly activates different signaling pathways responsible for proliferation and cell death processes. Endocrine Disruptors (EDs) have high affinity for GPR30, causing oxidative stress and possible barrier rupture. Functional antagonists of EDs, such as Panax ginseng, may be protective against their effects. Considering the importance of the signaling pathways that regulate spermatogenesis and the constant environmental exposure to the EDs to which we are subject, this work aims to study the possible modulation of the non-genomic pathway activated by GPR30 and oxidative stress in Sertoli cells exposed to low doses of the ED Monobutyl Phthalate (MBP) and the possible cytoprotective role of GIM-1 (P. ginseng metabolite) on these pathways. To this end, HSec human lineage cells were maintained on artificial matrix, simulating in vivo environment. Exposure to MBP and GIM-1 was performed at 30 min, 1, 12 and 48 hours at pre-set MTT (toxicity assay) levels in 4 groups: control, MBP, GIM-1 and MBP + GIM-1. Morphology and cell adhesion were evaluated by staining with Hematoxylin and Eosin, evidencing deleterious effects of MBP above cell distribution and adhesion in basement membrane; GIM-1 group was similar to Control and MBP+GIM-1 showed an intermediate aspect. In o... (Complete abstract click electronic access below) / Doutor

Ginseng.

GIM-1

HSeC

GPR30

Estresse oxidativo.

Sertoli, Células de.

Barreira hematotesticular.

Desreguladores endócrinos.

Monobutil ftalato

Sertoli cells

Blood-testis barrier

Endocrine disruptors

Monobutyl phthalate

Ginseng.

GIM-1

HSec

GPR30

Oxidative stress

Investigations on the in vitro effects of aqueous Eurycoma longifolia Jack extract on male reproductive functions

Erasmus, Nicolete

January 2012

<p>Eurycoma longifolia (Tongkat Ali / TA) is a Malaysian shrub used to treat various illnesses including male infertility. Considering that TA is also used to improve male fertility and no report&nbsp / regarding its safety has been published, this study investigated the effects of a patented, aqueous TA extract on various sperm and testicular functions. Materials and Methods This study&nbsp / encompasses two parts (part 1: on spermatozoa / part 2: on TM3-Leydig and TM4-Sertoli cells). Part 1: Semen samples of 27 patients and 13 fertile donors were divided into two groups,&nbsp / washed and swim-up prepared spermatozoa, and incubated with different concentrations of TA (1, 10, 20, 100, 2000 &mu / g/ml) for 1 hour at 37&deg / C. A sample without addition of TA served as control. After incubation with TA,&nbsp / the following parameters were evaluated: viability (Eosin-Nigrosin test), total and progressive motility (CASA), acrosome reaction (triple stain technique), sperm production of reactive oxygen&nbsp / species (ROS / dihydroethidium test / DHE), sperm DNA fragmentation (TUNEL assay) and mitochondrial membrane potential (&Delta / &psi / m) (Depsipher kit). Part 2: TM3-Leydig and TM4-Sertoli cells&nbsp / incubated with different concentrations of TA (0.4, 0.8, 1.6, 3.125, 6.25, 12.5, 25, 50 &mu / g/ml) and control (without extract) for 48 and 96 hours. After incubation with TA, the following parameters were&nbsp / evaluated: viability (XTT), cell proliferation (protein assay), testosterone (testosterone ELISA test) and pyruvate (pyruvate assay). Results Part 1: For washed spermatozoa, significant&nbsp / dose-dependent trends were found&nbsp / for viability, total motility, acrosome reaction and sperm ROS production. However, these trends were only significant if the highest concentrations were included in the calculation. In the swim-up spermatozoa, ROS production of spermatozoa showed a biphasic relationship with its lowest percentage at 10 &mu / g/ml, yet, no significance could be&nbsp / observed (P=0.9505). No influence of TA could be observed for sperm DNA fragmentation nor &Delta / &psi / m.</p>

Investigations on the in vitro effects of aqueous Eurycoma longifolia Jack extract on male reproductive functions

Erasmus, Nicolete

January 2012

<p>Eurycoma longifolia (Tongkat Ali / TA) is a Malaysian shrub used to treat various illnesses including male infertility. Considering that TA is also used to improve male fertility and no report&nbsp / regarding its safety has been published, this study investigated the effects of a patented, aqueous TA extract on various sperm and testicular functions. Materials and Methods This study&nbsp / encompasses two parts (part 1: on spermatozoa / part 2: on TM3-Leydig and TM4-Sertoli cells). Part 1: Semen samples of 27 patients and 13 fertile donors were divided into two groups,&nbsp / washed and swim-up prepared spermatozoa, and incubated with different concentrations of TA (1, 10, 20, 100, 2000 &mu / g/ml) for 1 hour at 37&deg / C. A sample without addition of TA served as control. After incubation with TA,&nbsp / the following parameters were evaluated: viability (Eosin-Nigrosin test), total and progressive motility (CASA), acrosome reaction (triple stain technique), sperm production of reactive oxygen&nbsp / species (ROS / dihydroethidium test / DHE), sperm DNA fragmentation (TUNEL assay) and mitochondrial membrane potential (&Delta / &psi / m) (Depsipher kit). Part 2: TM3-Leydig and TM4-Sertoli cells&nbsp / incubated with different concentrations of TA (0.4, 0.8, 1.6, 3.125, 6.25, 12.5, 25, 50 &mu / g/ml) and control (without extract) for 48 and 96 hours. After incubation with TA, the following parameters were&nbsp / evaluated: viability (XTT), cell proliferation (protein assay), testosterone (testosterone ELISA test) and pyruvate (pyruvate assay). Results Part 1: For washed spermatozoa, significant&nbsp / dose-dependent trends were found&nbsp / for viability, total motility, acrosome reaction and sperm ROS production. However, these trends were only significant if the highest concentrations were included in the calculation. In the swim-up spermatozoa, ROS production of spermatozoa showed a biphasic relationship with its lowest percentage at 10 &mu / g/ml, yet, no significance could be&nbsp / observed (P=0.9505). No influence of TA could be observed for sperm DNA fragmentation nor &Delta / &psi / m.</p>

Investigations on the in vitro effects of aqueous Eurycoma longifolia Jack extract on male reproductive functions

Erasmus, Nicolete

January 2012

Magister Scientiae (Medical Bioscience) - MSc(MBS) / Introduction: Eurycoma longifolia (Tongkat Ali; TA) is a Malaysian shrub used to treat various illnesses including male infertility. Considering that TA is also used to improve male fertility and no report regarding its safety has been published, this study investigated the effects of a patented, aqueous TA extract on various sperm and testicular functions. Materials and Methods: This study encompasses two parts (part 1: on spermatozoa; part 2: on TM3-Leydig and TM4-Sertoli cells). Part 1: Semen samples of 27 patients and 13 fertile donors were divided into two groups, washed and swim-up prepared spermatozoa, and incubated with different concentrations of TA (1, 10, 20, 100, 2000 μg/ml) for 1 hour at 37°C. A sample without addition of TA served as control. After incubation with TA, the following parameters were evaluated: viability (Eosin-Nigrosin test), total and progressive motility (CASA), acrosome reaction (triple stain technique), sperm production of reactive oxygen species (ROS; dihydroethidium test; DHE), sperm DNA fragmentation (TUNEL assay) and mitochondrial membrane potential (Δψm) (Depsipher kit). Part 2: TM3-Leydig and TM4-Sertoli cells incubated with different concentrations of TA (0.4, 0.8, 1.6, 3.125, 6.25, 12.5, 25, 50 μg/ml) and control (without extract) for 48 and 96 hours. After incubation with TA, the following parameters were evaluated: viability (XTT), cell proliferation (protein assay), testosterone (testosterone ELISA test) and pyruvate (pyruvate assay). Results Part 1: For washed spermatozoa, significant dose-dependent trends were found for viability, total motility, acrosome reaction and sperm ROS production. However, these trends were only significant if the highest concentrations were included in the calculation. In the swim-up spermatozoa, ROS production of spermatozoa showed a biphasic relationship with its lowest percentage at 10 μg/ml, yet, no significance could be observed (P=0.9505). No influence of TA could be observed for sperm DNA fragmentation nor Δψm. Part 2: The viability rates and protein production of TM3-Leydig and TM4-Sertoli cells at 48-hour exposure to TA showed increases whereas at 96-hour incubation periods viability and protein production declined especially as from concentration 25 μg/ml TA. Similar results could be seen for TM4-Sertoli cells pyruvate production. The testosterone production at 48-hour exposure marginally increased (P=0.0580) at the highest (50 μg/ml) concentration of TA. However, at 96-hour exposure to TA the testosterone production significantly (P=0.0065) increased. It is also apparent that after 96 hours the concentration of testosterone has increased [12 x 10-4 ng/ml] when compared to 48-hour exposure [6 x 10-7ng/ml] of Tongkat Ali. Conclusion: Part 1: Results indicate that the Tongkat Ali extract has no deleterious effects on sperm functions at therapeutically used concentrations (<2.5 μg/ml). Part 2: The cytotoxic effect of TA are only presented at higher concentration from 25 μg/ml. TM3-Leydig cells appears to be more resilient than TM4-Sertoli cells in viability and protein production yet at prolonged periods of exposure it is detrimental. Testosterone production only increases after 96 hours exposure to TA.

Eurycoma longifolia Jack (Tongkat Ali)

Spermatozoa

Motility

Viability

Acrosome reaction

Reactive Oxygen Species (ROS)

Mitochondrial membrane potential

DNA fragmentation

TM3-Leydig cells

TM4-Sertoli cells

Cell proliferation

Testosterone

Pyruvate

Cytotoxicity