Regulation of Abscission in Female Drosophila Germ Cells / Régulation de l’abscission dans la lignée germinale femelle de drosophile

Matias, Neuza

22 September 2015

En fin de cytocinèse, le fin pont cytoplasmique qui relie les deux cellules filles est clivé au niveau d’une structure dense en microtubules, le midbody, et permet ainsi la séparation physique de leurs deux cytoplasmes. Les mécanismes cellulaires et moléculaires de ce processus, appelé abscission, sont très étudiés dans des modèles de cellules en culture. Cependant, ils restent encore mal connus dans le contexte d’un organisme en développement. L’ovogenèse de drosophile est un modèle de choix pour l’étude de la régulation développementale de l’abscission. En effet, des cellules à abscission complète (cellules souches germinales) et incomplète (cystes germinaux) sont situées côte à côte au sein de la même unité développementale, le germarium. Les cellules souches se divisent asymétriquement, pour donner une autre cellule souche et un cystoblaste individualisé. Celui-ci entre en alors en différenciation, un programme au cours duquel il réalise quatre cycles cellulaires synchrones au cours desquels la cytocinèse est incomplète. Un cyste germinal de seize cellules interconnectées est ainsi formé. La durée de l’abscission est régulée précisément et dépend du contexte développemental. Notre laboratoire a récemment montré que les kinases Aurora B et Cdk1/ Cyclin B sont des régulateurs de la durée d’abscission dans les cellules germinales de drosophile et en cellules en culture de vertébrés. Mon travail a consisté à explorer la fonction de la protéine Shrub, un membre du complexe ESCRT-III, au cours de l’abscission dans la lignée germinale femelle de drosophile. Nous avons montré que Shrb est localisé au midbody des cellules souches en fin de cytocinèse, et promeut l’abscission. En effet, nous avons montré qu’une réduction du niveau de Shrub dans la lignée germinale provoque un fort délai de l’abscission des cellules souches, supérieur à la durée de leur cycle cellulaire. La cellule souche et son cystoblaste restent donc connecté jusqu’à la mitose suivante, formant ainsi des structures de plusieurs cellules connectées, appelées stem-cyst . L’abscission tardive au sein du stem cyst libère un progéniteur binucléé qui entre en différenciation. En conséquence, des chambres ovariennes à 32 cellules, au lieu de 16, sont formées. De plus, la fonction de Shrub dans l’abscission semble être contrecarrée par Aurora B, puisqu’une réduction des niveaux d’Aurora B dans des hétérozygotes Shrub réduit le nombre de stem-cysts et de chambres à 32 cellules observés. Enfin, nous avons identifié un nouveau facteur impliqué lors de l’abscission, la protéine Lethal giant discs (lgd), dont la perte de fonction induit, comme celle de Shrub, la formation de stem-cysts. En accord avec son rôle dans l’abscission, nous avons montré que Lgd est localisé au midbody. Lgd est requis pour la fonction de Shrub dans la voie endosomale, mais son implication lors de la cytocinèse était inconnue. Nous avons montré qu’un niveau réduit de Lgd augmente le nombre de stem-cysts des hétérozygotes Shrub, indiquant que Lgd et Shrub fonctionnent ensemble pour l’abscission des cellules souches. De façon surprenante, un nombre réduit de chambres à 32 cellules est observé dans ces ovaires, suggérant une fonction antagoniste de Lgd sur Shrub dans les cystes germinaux. Dans ces cystes, une abscission tardive se produit, qui divise en deux cystes de 16 cellules les cystes de 32 cellules, et expliquant ainsi le paradoxe observé (plus de stem-cysts, mais moins de chambres à 32 cellules). / At the end of cytokinesis, a thin cytoplasmic intercellular bridge is cleaved to allow physical separation of the two daughter cells. This process is called abscission, and its cellular and molecular events have been extensively explored in yeast and isolated mammalian cells. However, how abscission is regulated in different cell types or in a developing organism remains poorly understood.Drosophila oogenesis is a great model to study how abscission is regulated developmentally, as within the same developmental unit, the germarium, we find cells undergoing abscission next to others where this process is blocked. Indeed, the germline stem cell (GSC) divides asymmetrically to give rise to another GSC and to an individualized cystoblast. This cell then enters a well-studied process of differentiation, where through four rounds of mitosis with incomplete cytokinesis, gives rives to a cyst of 16 interconnected cells. The duration of abscission, seems to be tightly regulated and dependent on the developmental context. Our lab has recently discovered that AurB and CycB/Cdk1 function as abscission timers in Drosophila GSC and isolated mammalian cells. Thus, my work consisted in exploring how this process is regulated in the Drosophila female germline.We showed that the ESCRT-III protein Shrb localizes to the midbody of the dividing GSC, functioning to promote abscission. Indeed, we found that reduced levels of Shrb resulted in the blockage, or strong delay, of abscission in the GSC and formation of a structure similar to a cyst. In these so called stem-cysts, the GSC keeps dividing while interconnected to its daughter cells. As a consequence, we saw the appearance of egg chambers formed of 32 cells, instead of 16. Furthermore, Shrb function in abscission seems to be counteracted by AurB, as reducing AurB levels in Shrb heterozygous resulted in decreased stem-cysts and 32-cell cysts. Finally, Lethal giant discs (lgd), required for Shrb function in the endosomal pathway, was also seen localizing at the midbody and regulating abscission in GSCs. Removing one copy of Lgd from Shrb heterozygous increased the number of stem-cysts, but surprisingly the number of 32-cell cysts was reduced. This paradoxical result was explained with the observation of late abscission events in mitotic cysts, which divided the 32-cell cysts in the middle, leading to the formation of two cysts of 16 cells.

Abscission

Cellules Souches Germinales

Drosophile

Développement

ESCRT

Cytokinetic abscission

Germline Stem Cell

Drosophila

Development

ESCRT

The study and manipulation of piglet gonocytes

Yang, Yanfei

16 March 2011

The studies in this thesis examined piglet gonocyte identification, isolation, purification, preservation and potential for initiation of spermatogenesis after transplantation into irradiated recipient testes. As a first step, we characterized a previously non-described auto-fluorescence in the piglet testis tissue. This auto-fluorescence mainly originated from granules among the testis interstitial cells, and we found that its interference with immuno-fluorescence can be overcome using Sudan black staining. We also showed that porcine gonocytes can be specifically labelled with the lectin Dolichos biflorus agglutinin (DBA). To optimize gonocyte isolation, we found that ~9-fold more live cells could be harvested by enzymatic digestion of testis tissues than with mechanical methods. However, the proportion of gonocytes (~7%) did not differ between the mechanical and enzymatic methods of testis cell isolation. We then developed a novel three-step strategy for isolation of gonocytes by combining enzymatic digestion and vortexing, resulting in a gonocyte proportion of ~40% (~5-fold more than that from conventional methods). For short-term preservation of testis cells, we found that the survival of testis cells under hypothermic conditions was dependent on the cell type, and affected by storage duration, temperature and medium used. More than 80% of live testis cells survived the 6-day hypothermic preservation period in 20% FBS-L15, without visible changes to the cell culture potential or gonocyte proportion. In another experiment where testis tissues were maintained under hypothermic conditions, we found that ~25% of testis cells could survive for 6 days if preserved in HypoThermosol-FRS solution (HTS-FRS), without morphological changes. To purify gonocytes, we showed that centrifugation of testis cells using 17% Nycodenz can lead to precipitation of gonocytes in pellets (with a purity of > 80%). We also found that pre-coating tissue culture plates with both fibronectin and poly-D-lysine can result in the negative selection of gonocytes (with a purity of up to 85%). We subsequently showed that further purification of gonocytes (to > 90%) could be achieved by combining the two latter approaches. To prepare recipients for germ cell transplantation, we used local irradiation of piglet testes which reduced testis growth, decreased seminiferous tubule diameters and completely eliminated spermatogenesis at 4 months post-irradiation. Compared with the absence of endogenous spermatogenesis in the control testes, spermatogenesis up to elongating spermatids was observed in the irradiated testes after gonocyte transplantation. In summary, we investigated several critical elements in the study and manipulation of gonocytes in a large animal model.

germ cell transplantation

primordial germ cell

male reproduction

germline stem cell

spermatogonial stem cell

The study and manipulation of piglet gonocytes

Yang, Yanfei

16 March 2011

The studies in this thesis examined piglet gonocyte identification, isolation, purification, preservation and potential for initiation of spermatogenesis after transplantation into irradiated recipient testes. As a first step, we characterized a previously non-described auto-fluorescence in the piglet testis tissue. This auto-fluorescence mainly originated from granules among the testis interstitial cells, and we found that its interference with immuno-fluorescence can be overcome using Sudan black staining. We also showed that porcine gonocytes can be specifically labelled with the lectin Dolichos biflorus agglutinin (DBA). To optimize gonocyte isolation, we found that ~9-fold more live cells could be harvested by enzymatic digestion of testis tissues than with mechanical methods. However, the proportion of gonocytes (~7%) did not differ between the mechanical and enzymatic methods of testis cell isolation. We then developed a novel three-step strategy for isolation of gonocytes by combining enzymatic digestion and vortexing, resulting in a gonocyte proportion of ~40% (~5-fold more than that from conventional methods). For short-term preservation of testis cells, we found that the survival of testis cells under hypothermic conditions was dependent on the cell type, and affected by storage duration, temperature and medium used. More than 80% of live testis cells survived the 6-day hypothermic preservation period in 20% FBS-L15, without visible changes to the cell culture potential or gonocyte proportion. In another experiment where testis tissues were maintained under hypothermic conditions, we found that ~25% of testis cells could survive for 6 days if preserved in HypoThermosol-FRS solution (HTS-FRS), without morphological changes. To purify gonocytes, we showed that centrifugation of testis cells using 17% Nycodenz can lead to precipitation of gonocytes in pellets (with a purity of > 80%). We also found that pre-coating tissue culture plates with both fibronectin and poly-D-lysine can result in the negative selection of gonocytes (with a purity of up to 85%). We subsequently showed that further purification of gonocytes (to > 90%) could be achieved by combining the two latter approaches. To prepare recipients for germ cell transplantation, we used local irradiation of piglet testes which reduced testis growth, decreased seminiferous tubule diameters and completely eliminated spermatogenesis at 4 months post-irradiation. Compared with the absence of endogenous spermatogenesis in the control testes, spermatogenesis up to elongating spermatids was observed in the irradiated testes after gonocyte transplantation. In summary, we investigated several critical elements in the study and manipulation of gonocytes in a large animal model.

germ cell transplantation

primordial germ cell

male reproduction

germline stem cell

spermatogonial stem cell

In Vitro Derivation and Propagation of Spermatogonial Stem Cell Activity from Mouse Pluripotent Stem Cells. / 試験管内における多能性幹細胞から精原幹細胞活性の誘導と増幅

Ishikura, Yukiko

23 March 2017

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第20285号 / 医科博第76号 / 新制||医科||5(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 篠原 隆司, 教授 浅野 雅秀, 教授 近藤 玄 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Spermatogonial stem cell

Germline stem cell

Primordial germ cell

Pluripotent stem cell

491

Ecdysone signaling and miRNA let-7 cooperate in regulating the differentiation of the germline stem cell progeny

König, Annekatrin

08 May 2014

No description available.

570

stem cell niche

Drosophila

germarium

miRNA

let-7

ecdysone signaling

germline stem cell

Abrupt

H2Bub1

wingless signaling

histone modifications

differential cell adhesion

Biologie (PPN619462639)

Zur Rolle von Stra8 in pluripotenten Stammzellen / On the role of Stra8 in pluripotent stem cells

Kotzenberg, Linda

25 January 2011

No description available.

610 Medizin, Gesundheit

Medicine

Stra8

Keimzell-spezifisch

Stammzellen

Pluripotenz

Embryonalen Stammzellen

multipotent adult Germline Stem Cells

Stra8

multipotent adult germline stem cell

44

M

Régulation de la division asymétrique chez C. elegans

Rabilotta, Alexia

07 1900

No description available.

division asymétrique

polarité

cycline B

CDK-1

PAR

cellule souche germinale

niche

DTC

GLP-1

Notch

C. elegans

asymmetric division

polarity

cyclin B

germline stem cell