The actin filament network associated to Sertoli cell ectoplasmic specializations

Junctional devices in Sertoli cells conform the blood-testis barrier and play a key role in maturation and differentiation of germ cells. The spacial distribution of ectoplasmic specializations of Sertoli cells was studied by beta-actin immunolabelling, using laser confocal and transmission electron microscopy. For confocal microscopy, beta-actin immunolabelling of ectoplasmic specializations was studied over the background of either prosaposin or glutaredoxin immunolabelling of the Sertoli cytoplasm. Labelling was found near the basal lamina, surrounding early spermatocytes (presumably in leptotene-zygotene) or at one of two levels in the seminiferous epithelium: (1) around deep infoldings of the Sertoli cell cytoplasm, in tubular stages before spermiation, and (2) in the superficial part of the seminiferous epithelium, in tubular stages after or during spermiation. For transmission electron microscopy, beta-actin immunolabelling of ectoplasmic specializations was also used. Ectoplasmic specializations were found at two different levels of the seminiferous epithelium. We also used freeze fracture to analyze the characteristics of tubulo-bulbar complexes, a known component of apical ectoplasmic specializations. Also, these different approaches allowed us to study the complex arrangement of the actin cytoskeleton of Sertoli cells branches, which surround germ cells in different stages of the spermatogenic cycle. Our results show a consistent labelling for beta-actin before, during and after the release of spermatozoa in the tubular lumen (spermiation) suggesting a significant role of the actin network in spermatic cell differentiation. In conclusion, significant interrelations among the beta-actin network, the junctional complexes of the blood-testis barrier and the ectoplasmic specializations were detected at different stages of the seminiferous cycle

The actin filament network associated to Sertoli cell ectoplasmic specializations

Junctional devices in Sertoli cells conform the blood-testis barrier and play a key role in maturation and differentiation of germ cells. The spacial distribution of ectoplasmic specializations of Sertoli cells was studied by beta-actin immunolabelling, using laser confocal and transmission electron microscopy. For confocal microscopy, beta-actin immunolabelling of ectoplasmic specializations was studied over the background of either prosaposin or glutaredoxin immunolabelling of the Sertoli cytoplasm. Labelling was found near the basal lamina, surrounding early spermatocytes (presumably in leptotene-zygotene) or at one of two levels in the seminiferous epithelium: (1) around deep infoldings of the Sertoli cell cytoplasm, in tubular stages before spermiation, and (2) in the superficial part of the seminiferous epithelium, in tubular stages after or during spermiation. For transmission electron microscopy, beta-actin immunolabelling of ectoplasmic specializations was also used. Ectoplasmic specializations were found at two different levels of the seminiferous epithelium. We also used freeze fracture to analyze the characteristics of tubulo-bulbar complexes, a known component of apical ectoplasmic specializations. Also, these different approaches allowed us to study the complex arrangement of the actin cytoskeleton of Sertoli cells branches, which surround germ cells in different stages of the spermatogenic cycle. Our results show a consistent labelling for beta-actin before, during and after the release of spermatozoa in the tubular lumen (spermiation) suggesting a significant role of the actin network in spermatic cell differentiation. In conclusion, significant interrelations among the beta-actin network, the junctional complexes of the blood-testis barrier and the ectoplasmic specializations were detected at different stages of the seminiferous cycle

Excitatory and inhibitory behavioral responses to the pharmacological stimulation of serotonergic function in dorsalis raphe lesioned rats.

Neurotoxin-induced lesions of 5-HT neurons produce supersensitivity of 5-HT1 receptors without affecting 5-HT2 receptor binding in the brain. This model was used in the present work to analyze the role of 5-HT receptor subtypes in the mechanism controlling the excitatory and inhibitory behavioral responses to the pharmacological stimulation of 5-HT systems. Dorsalis raphe (DR) lesions were made by stereotaxic injection of kainic acid. At day 30 after injection DR-and control rats displayed similar baseline behavior in hole board tests. Three days later DR-and control rats received an ip injection of fluoxetine (5 or 10 mg/kg) 30 min before injecting ip 5-HTP(15 or 30 mg/kg). Immediately before and after each ip injection the excitatory response (myoclonic syndrome) was evaluated. DR-and control-group showed similar scores of myoclonus in response to fluoxetine-5-HTP. The inhibitory response was investigated in hole board trials performed 30 min after the second ip injection. The DR lesion potentiated the behavioral depressive effect of fluoxetine-5-HTP. In agreement with data in the literature the DR lesion caused 74.9

loss of forebrain 5-HT and 75

increases of 3H-5HT binding in cortex membranes. Most components of the excitatory response, which remained unchanged in the DR-lesioned rats, might be related to 5-HT2 receptors. The increased inhibitory response to 5-HT stimulation in DR-lesioned rats would be due to the supersensitivity of 5-HT1 receptors.