Stauros Koussoulakos

Cranial and postcranial skeletal variations induced in mouse embryos by mobile phone radiation

This study focuses on foetal development following mild daily exposure of pregnant mice to near field electromagnetic radiation emitted by a mobile phone. The investigation was motivated by the fact that the potentially hazardous electromagnetic radiation emitted by mobile phones is currently of tremendous public interest. Physically comparable pregnant mice were exposed to radiofrequency radiation GSM 900MHz emitted by a mobile phone. Within 5h after birth most cubs were fixed followed by double staining in toto, and conventional paraffin histology. Other cubs remained with their mothers until teeth eruption. Structural development was assessed by examining newborns for the presence of anomalies and/or variations in soft tissues and skeletal anatomy. Electromagnetic radiofrequency exposed newborns, externally examined, displayed a normal phenotype. Histochemical and histological studies, however, revealed variations in the exposed foetuses with respect to control ones concerning the ossification of cranial bones and thoracic cage ribs, as well as displacement of Meckelian cartilage. Littermates examined after teeth eruption displayed normal phenotypes. It is concluded that mild exposure to mobile phone radiation may affect, although transiently, mouse foetal development at the ossification level. The developmental variations observed could be explained by considering the different embryonic origin and mode of ossification of the affected skeletal elements.

Optimizing isolation culture and freezing methods to preserve Wharton's jelly's mesenchymal stem cell (MSC) properties: an MSC banking protocol validation for the Hellenic Cord Blood Bank

Mesenchymal stem or stromal cells (MSCs) are a heterogeneous population that can be isolated from many tissues including umbilical cord Whartons jelly (UC‐WJ). Although initially limited in studies such as a hematopoietic stem cell transplantation adjuvant, an increasing number of clinical trials consider MSCs as a potential anti‐inflammatory or a regenerative medicine agent. It has been proposed that creating a repository of MSCs would increase their availability for clinical applications. The aim of this study was to assess the optimal isolation and cryopreservation procedures to facilitate WJ MSC banking.

Botulinum Neurotoxin: The Ugly Duckling

This review presents a brief account of the most significant biological effects and clinical applications of botulinum neurotoxins, in a way comprehensive even for casual readers who are not familiar with the subject. The most toxic known substances in botulinum neurotoxins are polypeptides naturally synthesized by bacteria of the genus Clostridium. These polypeptides inhibit acetylcholine release at neuromuscular junctions, thus causing muscle paralysis involving both somatic and autonomic innervation. There is substantial evidence that this muscle-paralyzing feature of botulinum neurotoxins is useful for their beneficial influence on more than 50 pathological conditions such as spastic paralysis, cerebral palsy, focal dystonia, essential tremor, headache, incontinence and a variety of cosmetic interventions. Injection of adequate quantities of botulinum toxins in spastic muscles is considered as a highly hopeful procedure for the treatment of people who suffer from dystonia, cerebral palsy or have experienced a stroke. So far, numerous and reliable studies have established the safety and efficacy of botulinum neurotoxins and advocate wider clinical therapeutic and cosmetic applications.

Vertebrate limb development: from Harrison's limb disk transplantations to targeted disruption of Hox genes

Various animal organs have long been used to investigate the cellular and molecular nature of embryonic growth and morphogenesis. Among those organs, the tetrapod limb has been preferentially used as a model system for elucidating general patterning mechanisms. At the appropriate time during the embryonic period, the limb territories are first determined at the right positions along the cephalocaudal axis of the animal body, and soon the limb buds grow out from the flanks as mesenchymal cell masses covered by simple ectoderm. The position, number, and identity of the limbs depend on the expression of specific Hox genes. Limb morphogenesis occurs along three axes, which become gradually fixed: first the anteroposterior axis, then the dorsoventral, and finally the proximodistal axis, along which the bulk of limb growth occurs. Growth of the limb in amniotes depends on the formation of the apical ectodermal ridge, which, by secreting many members of the fibroblast growth factors family, attracts lateral plate and somitic mesodermal cells, keeps these cells in the progress zone proliferating, and prevents their differentiation until an appropriate time period. Mutual interactions between mesoderm and ectoderm are important in the growth process, and signaling regions have been identified, such as the zone of polarizing activity, the dorsal limb ectoderm, and the apical ectodermal ridge. Several molecules have been found to play leading roles in various biological processes relevant to morphogenesis. Besides its intrinsic merit as a model for unraveling the mechanisms of development, the limb deserves considerable clinical interest because defects of limb development are the most common single category of congenital abnormalities.

Antagonists of retinoic acid and BMP4 affect fetal mouse osteogenesis and odontoblast differentiation

Retinoic acid and bone morphogenetic protein (BMP4) are endogenous factors indispensable for the physiological development of vertebrates. The proximate aim of the present study was to investigate whether the natural compound citral (a retinoic acid synthesis inhibitor) and a monoclonal, anti-BMP4 antibody, administered to pregnant mice affect in the fetuses cranial osteogenesis and odontoblast differentiation. The present investigation was motivated by the fact that, retinoic acid inhibitors and BMP4 neutralizers may frequently contact human tissues (both intentional and unintentional, and/or unconsciously) inducing unanticipated effects. Our ultimate goal is the prevention of side effects and, future clinical implementation of the results. To this end, pregnant, white mice (balb-c Mus musculus) were intra-abdominally injected with either citral or anti-BMP4 antibody at the 9th gestational day. Newborns were processed within 5h, postnatal. Results were evaluated (a) macroscopically, (b) stereoscopically, following histochemical double staining of cartilage and osseous tissues and, (c) microscopically after (c(1)) histological staining of paraffin sections, and, (c(2)) immunohistochemical detection of apoptosis. Data indicate that in vivo administration of citral (biomimicking hypovitaminosis A) caused restriction/retardation of cranial chondrogenesis and osteogenesis. Apoptosis was not detected in teeth tissues. In vivo administration of anti-BMP4 antibody resulted in a transitory interference with the normal course of odontoblast differentiation and the production of pre-dentin, whereas, delay in the ossification also included the alveoli. Animals inspected in adulthood displayed a fairly normal phenotype. It is concluded that those two substances, under their concentrations experienced, are quite safe for the public.

Oxytocin Receptor Is Differentially Expressed in Mouse Endometrium and Embryo during Blastocyst Implantation

Abstract:  The oxytocin (OT)‐oxytocin receptor (OTR) system of the mammalian uterus has mainly been studied in relation to its involvement in the onset of labor. The aim of this study was to elucidate the in vivo expression and localization pattern of OTR in the mouse endometrium and embryo during implantation, as well as OTR mRNA expression in the in vitro developing mouse embryo. The expression of OTR or OT was detected immunohistochemically in uterine tissue sections of 5‐ to 8‐week‐old female mice between days 4 and 10 of an established pregnancy. In addition, the expression of OTR mRNA was detected by means of reverse transcription polymerase chain reaction (RT‐PCR) in mouse oocytes and embryos up to the blastocyst stage. The mean ratios of normalized expression levels of OTR gene in all samples were also calculated. The recorded increase in OTR mRNA immediately after fertilization could mean a possible role of OT in this process, as OTR mRNA gradually decreased after the four‐cell stage of pre‐embryonic development. The differential expression of OTR during embryonic apposition and embryonic invasion/placentation in the mouse uterus suggests a potential role of OT in the implantation process of the mouse. It is possible that the interaction of OTR with the hormones included in the ovulation induction regiments utilized today in in vitro fertilization (IVF) could be affecting the receptivity/quality of the implanting endometrium.

Origin of renewed spinal ganglia during tail regeneration in urodeles.

The source of the cells which form the spinal ganglia within the regenerating urodele tail is not yet indisputably known. Classical and modern experimental approaches trace the spinal cord as the most probable source. The aim of the present study was to further investigate this item by conventional histology, counting of mitotic figures, and estimating the labeling index. The main results can be summarized as follows: (a) The regenerated part of the tail contained only two bilaterally asymmetrical pairs of ganglia, with respect to the rostrocaudal (anterior-posterior) axis. (b) The anterior ganglia were slightly differentiated and appropriately localized; therefore, analysis was performed mainly in the posterior, still developing ganglia. (c) An anatomical continuation between the ventrolateral side of the regenerated spinal cord and the laterally forming spinal ganglion was noticed. There was some indication that many cells migrated out from the spinal cord towards the spinal ganglion, through the ventral root. (d) The mitotic and the labeling index along the regenerated spinal cord exhibited individual peaks near the level of each developing ganglion. The last two observations corroborate and reinforce the prevailing view that the progenitors of the spinal ganglion cells which are formed in the regenerating tail are of spinal cord origin.

Constructive Synergism of Regulatory Genes Expressed in the Course of Eye and Muscle Development and Regeneration

The expression patterns of regulatory genes involved in the formation of the eye in Drosophilaand vertebrates during early development were analyzed comparatively. The results demonstrated that, although the compound eyes of invertebrates and the camera eyes of vertebrates markedly differ in their structure and development, they exhibit a striking similarity at the molecular level. This similarity manifests itself in the fact that the homologous regulatory genes ey/Pax, eya/Eya, dac/Dac, and so/Six, which control the early stages of eye development, are expressed in both groups. Not only was synergism shown in the expression of early regulatory genes, but direct interactions of ey/Pax-and so/Six-encoded transcription factors with DNA and protein–protein interactions between nuclear transcription factors encoded by eya/Eyaand dac/Dacwere also revealed. Transcription factors produced by expressing gene cascades—ey/eya/dac/soin invertebrates and Pax/Eya/Dac/Sixin vertebrates—form the transcription complexes that control eye morphogenesis. Paradoxically, the development of muscles in vertebrates proved to involve the expression of genes homologous to the same regulatory genes that control eye morphogenesis in invertebrates and vertebrates.

Allografting of a Nontransmissible, Spontaneous Dermal Melanoma in the Newt Triturus cristatus

Regeneration-competent urodele Amphibia are highly resistant to spontaneous development of neoplasms, in comparison with other vertebrates which do not exhibit great regenerative power. This observation implies that at least one growth parameter of urodele cells might be subject to different developmental mechanisms than the cells of animals incapable of epimorphic regeneration. Therefore, keeping records concerning the incidence of tumors in urodeles and investigating those exceptional cases might prove invaluable in understanding the basic biological principles governing organ regeneration and carcinogenesis, and might therefore help in cancer therapy. The present report depicts a case of two spontaneous, dermal, melanoma-like tumors found in an adult newt Triturus cristatus. Both tumors were located in the pelvic region. Histological examinations and tumor transplantations were conducted. It was found that the tumors were melanomata. When allografted within the body cavity, their mass was progressively eliminated.

Quantitative Estimation of HRP-Labeled Sensory and Motor Neurons during Nerve-Dependent and Nerve-Independent Periods of Urodele Limb Regeneration

The relationship between urodele regeneration and the possibility of regeneration in mammals is unclear, but the idea of possible regeneration of neural elements in man is being studied because of its potential clinical importance. One of the great challenges is to gain sufficient knowledge about the basic biology of animal regeneration and to use it for the betterment of the mankind. It is known that the initial stages of urodele limb regeneration depend on the presence of intact nerve fibers connected to their cell bodies. The nerve fibers severed at the level of limb amputation regrow and penetrate the blastema, providing blastema cells with indispensable factors. These factors are produced in the perikarya of neurons and transported via their axons to the blastema. Numerous studies have been performed to elucidate the quantitative relationships between nerve fibers and limb regeneration. However, there are no reports dealing with the individual nerve cells at work. The aim of this investigation was to analyze the quantitative participation and qualitative distinctions of different nerve cells innervating the regenerating parts of the urodele limb and their possible roles in the nerve-dependent and nerve-independent periods of regeneration. The cells under study are housed in the dorsal ganglia (sensory neurons) and in the ventral part of the spinal cord gray matter (motor neurons). The direct involvement of these neurons in different regeneration periods was visualized by means of horseradish peroxidase (HRP) labeling. A total of 34 animals (21 experimental and 13 control) were used to study fluctuations in the numbers of labeled nerve cells. The results are summarized as follows: (a) the first nerve cells incorporating HRP within 5 days after amputation are found in the dorsal ganglia, whereas motor neurons in the gray matter are labeled within 7 days; (b) the number of labeled perikarya increases during the nerve-dependent regeneration period (0–21 days after amputation), with the percentage of implicated sensory neurons exceeding that found in the control series; and (c) during the next, nerve-independent period, the number of participating labeled neurons decreases gradually. Such fluctuations in the number of labeled neurons might represent the metabolic status of these cells in their effort to provide the blastema cells with the factors needed at the appropriate time. The current findings support previous observations that the periods of dependence and independence of urodele limb regeneration on the integrated control of brachial nerves reflect changes in the metabolism of individual sensory and motor neurons.