Ultrastructural features of human sperm cells cryopreserved by different methods

Cryopreservation of human spermatozoa has been recognized as a key strategy for management of male fertility. Nevertheless, current protocols of sperm freezing are neither optimal nor standardized between different labs (1). In this study we compare the ultrastructural features of human normospermic sperm samples (according to WHO parameters 2010) from 5 different freezing techniques in order to identify the best methods of cryopreservation. After informed con- sent, 21 normospermic patients (from the Medically Assisted Procreation PMA Center of the Fondazione IRCCS Policlinico San Matteo in Pavia) were recruited and both traditional and improved analysis of sperm quality were applied, in order to define critical steps of cryopreservation. Cryopreservation of human spermatozoa has been related to decreased motility associated with impaired velocity and viability of sperm pre-freeze and post-thaw. For all applied methods there was a significant reduction of progressive and total motility (P) as a result of freezing. To investigate ultrastructural details, 5 additional cryopreserved samples by the best two freezing methods were analyzed with elec- tron microscopy (TEM). Preliminary data showed the minimal differences between the protocols, with a large number of queues detached and large quantities of cyto- plasmic debris after of the first protocol. Spermatozoa appear to be better preserved in the second analyzed method, despite both procedures induced deteriorations at ultrastructural level (2). Other non-routine analysis will be performed to determine whether the cooling time to +4°C may affect the procedure; Comet Assay (to assess the degree of sperm DNA fragmentation) (3) and flow cytometry (to study light scat- ters patterns and membrane integrity) (4) will be applied

Growth and stratification of epithelial cells in minimal culture conditions.

Biological risk management is required in modern tissue engineering. Particular attention should be paid to the culture medium and the scaffold used. In this perspective, it is important to define minimal culture conditions which allow proper growth and differentiation of epithelial cells in vitro. We propose a simple experimental system which permits the generation of three-dimensional epidermal constructs using a collagen layer as a scaffold mimicking the entire dermal tissue and without the need of any feeder layer. Although showing significant differences compared to natural epidermis, these epidermal constructs appear useful to study keratinocyte differentiation and epidermis histogenesis

Expression of p63 transcription factor in ectoderm-derived oral tissues.

The p63 gene encodes six splice variants expressed with transactivating or dominant-negative activities. Animal studies with p63 -/- mutants have suggested that p63 is important for proper development of several organs, including tooth and salivary gland. Moreover, mutations of p63 have been detected in patients affected by ectrodactyly, ectodermal dysplasia and facial clefts. To clarify the role of p63 in craniofacial development, we have studied the localization of p63 protein in human and rat oral tissues using immunohistochemistry. p63 immunostaining was identified in the enamel organ, oral epithelium and developing salivary glands. All compartments of the enamel organ were immunolabelled, whereas only basal and some suprabasal cells of the oral epithelium were stained. Ectomesenchyme-derived cells, including pulp cells, odontoblasts, bone cells and chondrocytes, were negative. The staining pattern was identical in human and rat tissues. These data lend support to the hypothesis that p63 is involved in growth and differentation of ectoderm-derived oral tissues and may be useful to clarify molecular and developmental aspects observed in animal knockout experiments and human syndromes related to p63 gene alteration

Cell proliferation and differentiation in a model of human skin equivalent

Recent advances in culturing technology has permitted the production of organotypic models that may be referred to as human skin equivalents (HSE). We have studied histochemical, ultrastructural, and kinetic aspects of an HSE composed by an epidermal equivalent and a dermal equivalent separated by a basement membrane. Only keratinocytes and fibroblasts were present in the epidermal and dermal equivalents, respectively; cells of other lineages were lacking. Keratinocyte stratification and differentiation seemed similar to natural skin. Evidence is shown that such an HSE may also release growth factors such as vascular endothelial growth factor that are believed to play a role in skin grafting. The distribution of cycling cells as well as the values of the growth fraction are comparable to those observed in natural skin. Although the absence of several cells populations that reside in natural skin is a remarkable feature of this HSE, the high levels of tissue organization and cell differentiation lead us to believe that such an HSE may be considered a candidate substitute of human skin in biological, pharmacologic, and clinical applications