Sex determination strategies in 2012: towards a common regulatory model?

Sex determination is a complicated process involving large-scale modifications in gene expression affecting virtually every tissue in the body. Although the evolutionary origin of sex remains controversial, there is little doubt that it has developed as a process of optimizing metabolic control, as well as developmental and reproductive functions within a given setting of limited resources and environmental pressure. Evidence from various model organisms supports the view that sex determination may occur as a result of direct environmental induction or genetic regulation. The first process has been well documented in reptiles and fish, while the second is the classic case for avian species and mammals. Both of the latter have developed a variety of sex-specific/sex-related genes, which ultimately form a complete chromosome pair (sex chromosomes/gonosomes). Interestingly, combinations of environmental and genetic mechanisms have been described among different classes of animals, thus rendering the possibility of a unidirectional continuous evolutionary process from the one type of mechanism to the other unlikely. On the other hand, common elements appear throughout the animal kingdom, with regard to a) conserved key genes and b) a central role of sex steroid control as a prerequisite for ultimately normal sex differentiation. Studies in invertebrates also indicate a role of epigenetic chromatin modification, particularly with regard to alternative splicing options. This review summarizes current evidence from research in this hot field and signifies the need for further study of both normal hormonal regulators of sexual phenotype and patterns of environmental disruption

Molecular patterns of sex determination in the animal kingdom: a comparative study of the biology of reproduction

Determining sexual fate is an integral part of reproduction, used as a means to enrich the genome. A variety of such regulatory mechanisms have been described so far and some of the more extensively studied ones are being discussed. For the insect order of Hymenoptera, the choice lies between uniparental haploid males and biparental diploid females, originating from unfertilized and fertilized eggs accordingly. This mechanism is also known as single-locus complementary sex determination (slCSD). On the other hand, for Dipterans and Drosophila melanogaster, sex is determined by the ratio of X chromosomes to autosomes and the sex switching gene, sxl. Another model organism whose sex depends on the X:A ratio, Caenorhabditis elegans, has furthermore to provide for the brief period of spermatogenesis in hermaphrodites (XX) without the benefit of the "male" genes of the sex determination pathway. Many reptiles have no discernible sex determining genes. Their sexual fate is determined by the temperature of the environment during the thermosensitive period (TSP) of incubation, which regulates aromatase activity. Variable patterns of sex determination apply in fish and amphibians. In birds, while sex chromosomes do exist, females are the heterogametic (ZW) and males the homogametic sex (ZZ). However, we have yet to decipher which of the two (Z or W) is responsible for the choice between males and females. In mammals, sex determination is based on the presence of two identical (XX) or distinct (XY) gonosomes. This is believed to be the result of a lengthy evolutionary process, emerging from a common ancestral autosomal pair. Indeed, X and Y present different levels of homology in various mammals, supporting the argument of a gradual structural differentiation starting around the SRY region. The latter initiates a gene cascade that results in the formation of a male. Regulation of sex steroid production is also a major result of these genetic interactions. Similar observations have been described not only in mammals, but also in other vertebrates, emphasizing the need for further study of both normal hormonal regulators of sexual phenotype and patterns of epigenetic/environmental disruption

Discriminating Between the Roles of Androgens and Estrogens in Cardiovascular Disease

Cardiovascular disease shows a distinct difference in incidence rates between men and women, a fact that has been known for many years. While initial theories supported that this could be attributed to the protective effect of estrogens in women, attempts to correlate endogenous estrogen levels with cardiovascular risk factors and the progression of atherosclerosis-related indexes indicate otherwise. Similarly, endogenous androgen levels seem to correlate with opposite effects in males and females, whereas exogenous treatment with either androgens or estrogens fails to correspond to scientific expectations entirely. A brief discussion of the merits and pitfalls of placing either estrogens or androgens alone at the root of the problem shows that current understanding is inadequate concerning this major anthropological issue, as it refers to the primary global mortality and morbidity cause

Sex Steroids: Beyond Conventional Dimorphism

Sexual dimorphism is a characteristic of a large number of species, ranging from lower invertebrates to mammals and, last but not least, humans. Recognition of the various factors regulating sexual dimorphism initial establishment (i.e. sex determination and differentiation) and subsequent life-long adaptation to distinct functional and behavioural patterns has remained a hot topic for several decades. As our understanding of the various molecular pathways involved in this process increases, the significant role of sex steroids becomes more evident. At the same time, the recognition of new sites of steroid production (e.g. parts of the brain) and aromatization, as well as new target cells (owing to the pro- posed presence of additional receptors to those classically considered as primary steroid receptors) has lead to the need to revisit their spectrum of actions within a novel, multifactorial context. Thus, anthropology and medicine are presented with the challenge to unravel a major mystery, i.e. that of sexual orientation and differentiation and its potential contri- bution in human evolution and civilization development, taking advantage of the high-tech research tools provided by modern biotechnology. This short review summarizes the basic principles of sex determination and sex steroid function as they have been classically described in the literature and then proceeds to present examples of how modern research methods have started to offer a new insight on the more subtle details of this process, stressing that it is extending to virtually every single part and system of the body

Sex Determinants in the Genome – Lessons from the Animal Kingdom

The immense value of sex differentiation as a means of enriching and evolving the genome has been proven by the vast variety of sex determining mechanisms to which organisms of all kinds resort. From single gene switching pathways found in lower level organisms to haplodiploid reproduction in hymenoptera, temperature-determined sex in reptiles and sex chromosomes in mammals and avians, nature and evolution have designated an impressive amount of effort to ensure that sex-specific variations remain under well-regulated control. Therefore enhancing our efforts to study some of the strategies recruited for the above may also lead to a better understanding of the inherent complexity of sexual dimorphism in general

Establishing Sexual Dimorphism in Human

Sexual dimorphism, i.e. the distinct recognition of only two sexes per species, is the phenotypic expression of a multistage procedure at chromosomal, gonadal, hormonal and behavioral level. Chromosomal – genetic sexual dimorphism refers to the presence of two identical (XX) or two different (XY) gonosomes in females and males, respectively. This is due to the distinct content of the X and Y-chromosomes in both genes and regulatory sequences, SRY being the key regulator. Hormones (AMH, testosterone, Insl3) secreted by the foetal testis (gonadal sexual dimorphism), impede Müller duct development, masculinize Wolff duct derivatives and are involved in testicular descent (hormonal sexual dimorphism). Steroid hormone receptors detected in the nervous system, link androgens with behavioral sexual dimorphism. Furthermore, sex chromosome genes directly affect brain sexual dimorphism and this may precede gonadal differentiation

Fertility in the Áging Male: Molecular Pathways in the Anthropology of Aging

The aging process is a normal stage in development characterized by the gradual deterioration of all life functions. As far as reproduction is concerned, aging is characterized by a significant limitation of fertility in both sexes. This process is, at least partially, attributed to the action (or loss of action) of sex steroids, coinciding with low activity of the pituitary-gonad axis. From an anthropological point of view, the study of reproductive aging is a unique opportunity to investigate various environmental and endogenous factors influencing sexual behavior and, thus, playing a significant role in human biology. Various techniques are now widely available to allow the detailed examination of reproductive hazards using only minor samples of genetic material. These methods are highly sensitive and specific and allow the characterization of distortions at subcellular and even molecular level. This short review briefly summarizes the current understanding of reproductive aging, as well as its potential clinical and anthropological impact

Assessment of Sperm Nucleus Integrity in Infertile Men: A Novel Research Field for Anthropology in the Molecular Era

Anthropology has always been particularly interested in the origin of human life and the development towards adult- hood. Although originally working with skeletal measurements and bio-morphological markers in modern populations, it has now entered the growing field of applied molecular biology. This relatively recent advance allows the detailed study of major events in human development and senescence. For instance, sperm DNA integrity and chromatin re-orga- nization are crucial factors for fertilization and embryo development. Clinical researchers have developed improved methods for the evaluation of DNA integrity and protaminosis in sperm nuclei, such as the TUNEL and the CMA3 assays. DNA damage in spermatozoal nuclei is detected using the TUNEL assay which depends on the specific enzy- matic reaction of TdT with the end strand breaks of DNA. Protaminosis in spermatozoal nucleus is evaluated using CMA3 assay, which is based on the in situ competition between CMA3 and protamines. Such measurements may provide useful data on human reproductive health, aiding the explanation of demographic differences across the world

Hormonal and Meta-Hormonal Determinants of Sexual Dimorphism

The role of hormones in the determination of sexual characteristics has been known for several decades. It has been shown, for example, that several products, including sex steroids, may influence the body development pattern, metabolic pathways, fat and muscle distribution and vocal cord anatomy, thus producing an overall outcome consistent with a masculine or feminine phenotypic pattern. These qualities are usually described as secondary sexual traits, so as to be distinguished from primary sex traits, usually referring to the gonads and external genitalia. However, it must be noted that hormonal regulation may not explain the full range of the sexual phenotype, since the central nervous system retains a significant role in the establishment of sexual identity, thus giving rise to a higher sex determination stage exclusively described in humans, namely behavioral or psychological sex. Recently, it has been suggested that differences among the sexes are not limited to brain function but they may also refer to anatomical differences and different biochemical profiles, including a distinct pattern of AR and ER distribution. This new aspect of sexual dimorphism suggests a whole system of meta-hormonal regulation, recently described as the sexual brain model. The role of local androgen and/or estrogen concentrations in the initial establishment of brain sexual dimorphism is still under evaluation, since the first results are relatively inconclusive and no direct cause and effect relationship has been proven so far. On the other hand, sex hormones have recently been found to participate in processes well beyond their initially suggested spectrum of action. For instance, ER interacts with EGFR in a number of ways, affecting development of a number of epithelial structures. Estrogen receptors have also been detected in a number of non-classic targets of steroids, such as the brain and the lungs. This observation may imply that sexual dimorphism goes a lot deeper than previously estimated, affecting virtually every organic system, suggesting, in essence, the existence of two different functional models for the whole human body, formulated and conserved throughout the evolutionary progress

Gonadal Cell Proliferation Dimorphism

Dimorphism between testis and ovary in germ cells proliferative behavior, shows remarkable differences in foetal and neonatal period 14.5 days post conception (dpc) – 7 days post partum (dpp). Immunostaining of the foetal testis, with the PCNA and Ki-67 antibodies estimation of Labeling Index (LI), reveals increasing germ cells population until birth. Afterwards, a sharp decline in the first 3 days of postnatal life and a transient increase, between 3 and 5 dpp, is observed. Then, the mitotic activity of germ cells ceases. In the foetal ovary, germ cells proliferation reaches a peak value before birth, decreasing thereafter. Somatic (Sertoli or follicular) cells behave similarly in both sexes. Increased mitotic activity is observed throughout the examined period. Thus, the gonadal dimorphism in proliferative behavior, concerns only germ cell lineage and is established during the foetal and neonatal period