New concepts in the study of the sexual differentiation and activation of reproductive behavior, a personal view.

Since the beginning of this century, research methods in neuroendocrinology enjoyed extensive refinements and innovation. These advances allowed collection of huge amounts of new data and the development of new ideas but have not led to this point, with a few exceptions, to the development of new conceptual advances. Conceptual advances that took place largely resulted from the ingenious insights of several investigators. I summarize here some of these new ideas as they relate to the sexual differentiation and activation by sex steroids of reproductive behaviors and I discuss how our research contributed to the general picture. This selective review clearly demonstrates the importance of conceptual changes that have taken place in this field since beginning of the 21st century. The recent technological advances suggest that our understanding of hormones, brain and behavior relationships will continue to improve in a very fundamental manner over the coming years.

The behavioral neuroendocrinology of maternal behavior: Past accomplishments and future directions.

Research on the neuroendocrine-endocrine-neural regulation of maternal behavior has made significant progress the past 50 years. In this mini-review progress during this period has been divided into five stages. These stages consist of advances in the identification of endocrine factors that mediate maternal care, the characterization of the neural basis of maternal behavior with reference to endocrine actions, the impact of developmental and experiential states on maternal care, the dynamic neuroplastic maternal brain, and genes and motherhood. A final section concludes with a discussion of future directions in the field of the neurobiology/neuroendocrinology of motherhood.

Hormones and Behavior: An emergent journal.

Hormones and Behavior was founded in 1969 by Frank A. Beach and members of his laboratory. Prior to the founding there was no journal specifically devoted to hormones and behavior. This paper explores how the editorship of the journal has developed over the first 50 years, going from the initial three male editors to the current female editor-in-chief, five associate editors (four men and one women), and a 98 member editorial board consisting of 46 men and 52 women. Early concerns that a specialty journal of hormones and behavior might ghettoize the field did not come to pass and the visibility and impact of the journal has helped to expand the spread of the field, now called Behavioral Neuroendocrinology. This growth accelerated with the creation of the Society for Behavioral Neuroendocrinology in 1996 and the adoption of Hormones and Behavior as the Society's official journal. The growth has been striking with total annual citations going from 1321 per year in 1997 to the current 10,874 annual citations. The journal's impact factor (JIF), 1.42 in 1997, has increased to the current (2018) JIF of 3.95. Over the 50 years of Hormones and Behavior's existence it has emerged as a principle voice of the Hormones and Behavior community. It will be intriguing to see what the next 50 years reveals.

Sexual differentiation of brain and other tissues: Five questions for the next 50 years.

This paper is part of the celebration of the 50th anniversary of founding of the journal Hormones and Behavior, the official journal of the Society for Behavioral Neuroendocrinology. All sex differences in phenotypic development stem from the sexual imbalance in X and Y chromosomes, which are the only known differences in XX and XY zygotes. The sex chromosome genes act within cells to cause differences in phenotypes of XX and XY cells throughout the body. In the gonad, they determine the type of gonad, leading to differences in secretion of testicular vs. ovarian hormones, which cause further sex differences in tissue function. These current ideas of sexual differentiation are briefly contrasted with a hormones-only view of sexual differentiation of the last century. The multiple, independent action of diverse sex-biasing agents means that sex-biased factors can be synergistic, increasing sex differences, or compensatory, making the two sexes more equal. Several animal models have been fruitful in demonstrating sex chromosome effects, and interactions with gonadal hormones. MRI studies of human brains demonstrate variation in brain structure associated with both differences in gonadal hormones, and in the number of X and Y chromosomes. Five unanswered questions are posed as a challenge to future investigators to improve understanding of sexual differentiation throughout the body.

Testosterone administration in human social neuroendocrinology: Past, present, and future.

Over the past 20 years, social neuroendocrinology researchers have developed pharmacological challenge paradigms to assess the extent to which testosterone plays a causal role in human psychological and behavioural processes. The current paper provides a brief summary of this research and offers recommendations for future research examining the neuroendocrine mechanisms underlying human behaviour.

How technical progress reshaped behavioral neuroendocrinology during the last 50 years and some methodological remarks.

The first issue of Hormones and Behavior was published 50 years ago in 1969, a time when most of the techniques we currently use in Behavioral Endocrinology were not available. Researchers have during the last 5 decades developed techniques that allow measuring hormones in small volumes of biological samples, identify the sites where steroids act in the brain to activate sexual behavior, characterize and quantify gene expression correlated with behavior expression, modify this expression in a specific manner, and manipulate the activity of selected neuronal populations by chemogenetic and optogenetic techniques. This technical progress has considerably transformed the field and has been very beneficial for our understanding of the endocrine controls of behavior in general, but it did also come with some caveats. The facilitation of scientific investigations came with some relaxation of methodological exigency. Some critical controls are no longer performed on a regular basis and complex techniques supplied as ready to use kits are implemented without precise knowledge of their limitations. We present here a selective review of the most important of these new techniques, their potential problems and how they changed our view of the hormonal control of behavior. Fortunately, the scientific endeavor is a self-correcting process. The problems have been identified and corrections have been proposed. The next decades will obviously be filled with exciting discoveries in behavioral neuroendocrinology.

Estrogenic regulation of memory: The first 50 years.

This review highlights fifty years of progress in research on estradiol's role in regulating behavior(s). It was initially thought that estradiol was only involved in regulating estrus/menstrual cycles and concomitant sexual behavior, but it is now clear that estradiol also influences the higher order neural function of cognition. We provide a brief overview of estradiol's regulation of memory and some mechanisms which underlie its effects. Given systemically or directly into the hippocampus, to ovariectomized female rodents, estradiol or specific agonists, enhance learning and/or memory in a variety of rodent cognitive tasks. Acute (within minutes) or chronic (days) treatments enhance cognitive functions. Under the same treatment conditions, dendritic spine density on pyramidal neurons in the CA1 area of the hippocampus and medial prefrontal cortex increase which suggests that these changes are an important component of estrogen's ability to impact memory processes. Noradrenergic, dopaminergic and serotoninergic activity are also altered in these areas following estrogen treatments. Memory enhancements and increased spine density by estrogens are not limited to females but are also present in castrate males. In the next fifty years, neuroscientists need to determine how currently described neural changes mediate improved memory, how interactions among areas important for memory promote memory and the potential significance of neurally derived estrogens in normal cognitive processing. Answering these questions may provide significant advances for treatment of dementias as well as age and neuro-degenerative disease related memory loss.

Infundibulo-tuberal syndrome: the origins of clinical neuroendocrinology in France.

The birth of clinical neuroendocrinology can be dated to the year 1900, when the French neurologist Joseph Babinski (1857-1932) described a particular syndrome of adiposity and sexual infantilism in an adolescent with a craniopharyngioma expanding at the base of the brain. This condition of adipose-genital dystrophy, also known as Babinski-Fröhlich syndrome, represented the first clinical evidence that the brain controlled endocrine functions. Adipose-genital dystrophy forms part of infundibulo-tuberal syndrome, which groups the endocrine, metabolic and behavioral disturbances caused by lesions involving the upper neurohypophysis (median eminence) and the adjacent basal hypothalamus (tuber cinereum). This syndrome was originally described by the French neuropsychiatrists Henri Claude (1869-1946) and Jean Lhermitte (1877-1959) in 1917, also in a patient with a craniopharyngioma. This type of tumor involves specifically the infundibulo-tuberal region of the hypothalamus, providing a clinical model to conceptualize the separation of hypophyseal and hypothalamic functions. The French School of Neurology analyzed and reported the symptoms associated with dysfunction of the basal hypothalamus by craniopharyngiomas and other types of tumors, influencing significantly the development of clinical neuroendocrinology. Experimental lesions performed in the tuber cinereum by the French physiologists Jean Camus (1872-1924) and Gustave Roussy (1874-1948) demonstrated unmistakably the anatomical origin of infundibulo-tuberal syndrome in the basal hypothalamus. This article reviews the original findings on infundibulo-tuberal syndrome reported by the French School of Neurology in the first decades of the twentieth century and the great influence this school had on modern conceptions of hypothalamic control over endocrine functions and behavior.

OLD AND NEW NEUROENDOCRINE MOLECULES: SOMATOSTATIN, CYSTEAMINE, PANTETHINE AND KYNURENINE.

The aim of this review is to commemorate Hans Selye, endocrinologist, the most famous researchers of stress and to briefly summarize the major features of somatostatin (SST), cysteamine (CysA) and patethine (PAN) in neuroendocrinological aspect, which are closely related to his scientific work. In addition, some metabolites of kynurenine pathway (KP) were also mentioned in this paper, as new, possible target molecules in neuroendocrinology. R. Guillemin and A. V. Schally were the main pioneers of the discovery of SST in the 1970's. SST primarily is known as an inhibitor of growth hormone secretion and additionally reduces the gastric acid and pepsin release and also the gastroduodenal mucosal blood flow. These effects are very important in the pathophysiology of peptic ulcer bleeding, which is related to the CysA-evoked perforating duodenal ulcer experimental stress model in rats developed by Selye and Szabo. CysA is a naturally occurring duodenal ulcerogen, which depletes SST in the gastric mucosa and certain brain regions. Furthermore, in addition to depleting SST, CysA also causes adrenocortical necrosis, suggesting an interaction between the central/peripheral nervous system and the neuroendocrine system. The antioxidant PAN, formulated besides the CysA, has similar effects: it attenuates the levels of SST and prolactin in the cerebral cortex and hypothalamus through the accumulation of CysA within cells throughout the body. As new perspectives the KP may be involved in the modulation of neuroendrocrine processes: different agonists and antagonists of glutamate receptors regulate the hypothalamic-pituitary-adrenal axis and kynurenic acid augments the anxiolytic stress responses in neonatal chicks. The pro-inflammatory cytokine-induced and the toxic heavy oil contaminations-evoked alterations in the KP indirectly contribute to the development of neuroendocrine disorders. In summary, there have been highly important developments in neuroendocrinology since the early findings of Selye. Although there are as yet relatively few data about the potential role of kynurenines in neuroendocrinology, the results already achieved are extremely noteworthy and immensely promising.

Tribute to Roger Guillemin, a pioneer in neuroendocrinology (1924-2024), Nobel Prize in Physiology or Medicine.

Roger Guillemin discovered and characterized the hypothalamic factors that control anterior pituitary functions. He consequently demonstrated that these brain peptides regulate a large number of major body activities through neuroendocrine mechanisms. This especially include growth, fertility and reproduction, endocrine gland functions and stress. These seminal works paved the way to major applications in many fields of physiology and medicine for diagnosis, pharmacology and therapy, far beyond the initial discovery and properties of these molecules, including in cancerology, immunology, inflammation, drug addiction and behavior.

Roger Guillemin a mis en évidence et caractérisé les facteurs hypothalamiques qui contrôlent les fonctions de l'adénohypophyse. Cette découverte majeure a permis de démontrer que ces peptides du cerveau régulent par voie neuroendocrine un grand nombre de fonctions importantes de l'organisme. C'est le cas de la croissance, de la fertilité et de la reproduction, des fonctions des glandes endocriniennes et du stress. Ces travaux pionniers ont ouvert la voie à des applications innovantes dans de nombreux domaines de la physiologie et de la médecine pour le diagnostic, la pharmacologie et la thérapie, bien au-delà de la découverte initiale et des propriétés de ces molécules. Ces domaines comprennent en particulier la cancérologie, l'immunologie, les problèmes inflammatoires, les addictions et le comportement.

Historical and cultural aspects of the pineal gland: comparison between the theories provided by Spiritism in the 1940s and the current scientific evidence.

Significance has been attached to the pineal gland in numerous different cultures and beliefs. One religion that has advanced the role of the pineal gland is Spiritism. The objective of the present study was to compile information on the pineal gland drawing on the books of Francisco Cândido Xavier written through psychography and to carry out a critical analysis of their scientific bases by comparing against evidence in the current scientific literature. A systematic search using the terms "pineal gland" and "epiphysis" was conducted of 12 works allegedly dictated by the spirit "André Luiz". All information on the pineal having potential correlation with the field of medicine and current studies was included. Specialists in the area were recruited to compile the information and draw parallels with the scientific literature. The themes related to the pineal gland were: mental health, reproductive function, endocrinology, relationship with physical activity, spiritual connection, criticism of the theory that the organ exerts no function, and description of a hormone secreted by the gland (reference alluding to melatonin, isolated 13 years later). The historical background for each theme was outlined, together with the theories present in the Spiritist books and in the relevant scientific literature. The present article provides an analysis of the knowledge the scientific community can acquire from the history of humanity and from science itself. The process of formulating hypotheses and scientific theories can benefit by drawing on the cultural aspects of civilization, taking into account so-called non-traditional reports and theories.

The Pioneer Neuropharmacologist Alfred Fröhlich (1871-1953) and the Origins of Neuroendocrinology: A Sesquicentennial Remembrance.

The birth of neuroendocrinology as a scientific discipline is traced back to 1900-1901, when Joseph Babinski, Alfred Fröhlich, and Harvey Cushing independently identified adiposogenital dystrophy (Fröhlich syndrome), and related gonadal underdevelopment and obesity to a tumor near the pituitary gland. This discovery prompted decades of research into the brain mechanisms responsible for the control of peripheral metabolism and endocrine functions. On the occasion of the 150th anniversary of Fröhlich's birth, this study traces the origins of his intellectual formation and his association with renowned contemporaries in Austria, England, Italy, and finally Cincinnati, Ohio, where he sought refuge after Austria's annexation by Nazi Germany. Fröhlich interacted with seminal figures in biomedicine, including Lothar von Frankl-Hochwart, Hans Horst Meyer, Ernst Peter Pick, Harvey Cushing, John Newport Langley, and the Nobel laureates Charles Scott Sherrington and Otto Loewi. Alfred Fröhlich, one of the 20th century's most emblematic physicians, left his mark on neurophysiology and neuropharmacology with important works, and published authoritative manuals of drug dispensing and clinical therapy. He confronted the calamities of two World Wars with remarkable resilience like many of his Viennese colleagues who, overcoming the constraints of National Socialism, settled overseas to fulfil their calling as physicians, researchers, and teachers.

The eyes have it: A brief history of crustacean neuroendocrinology.

To help celebrate the 50th anniversary of General and Comparative Endocrinology, the history of only a small portion of crustacean endocrinology is presented here. The field of crustacean endocrinology dates back to the decades prior to the establishment of General and Comparative Endocrinology and the first article about crustacean endocrinology published in this journal was concerned with the anatomy of neurosecretory and neurohemal structures in brachyuran crabs. This review looks at the history of neuroendocrinology in crustaceans during that time and tries to put perspective on the future of this field.

Teratology on the crossroads: historical aspects and modern approaches.

Teratology is the science of congenital developmental disorders (CDDs), overt or latent defects of the organism resulting from the effect of internal and external factors on developmental processes. In this article the significance and position of present-day teratology is discussed in the context of development of this branch of science and related disciplines. The authors present an updated overview of the most important milestones and stages of the development of teratology. Based on the analysis of the historical development of theses and theories that represent a decisive contribution to this field, we present a survey of the fundamental principles of experimental and clinical teratology. The aim of observing these principles is to get insight into developmental relations and to understand mechanisms of action on the level of cell populations (elementary morphogenetic processes), tissues and organs. It is important to realize that any negative intervention into the normal course of these processes, either on genetic or non-genetic basis, inevitably leads to a sequence of subsequent changes resulting in the development of congenital developmental disorders. Despite modern approaches of molecular biology and genetics, along with top diagnostic techniques, we are still not able to identify the actual cause in more than 50% of all congenital defects. One-half of the unidentified cases are referred to as "multifactorial", a term that is rather ambiguous. It either means that some of the basic principles of teratogenesis still escape our attention, or the interpretation of some of the well known principles might be misleading. A third possibility is rather pessimistic. The development of the individual is so sophisticated and dependent on a delicate network of a multitude of factors mutually affecting each other that it is extremely prone to give rise to a plethora of spontaneous errors which are unpredictable and impossible to prevent. Nevertheless, the long and complicated history of scientific endeavour has yielded considerable present-day knowledge on causes and mechanisms of CDDs, a history whose beginnings date back to antiquity.

Laudatio for centenary of the birth of Luigi Di Bella, MD, PhD.

On the centennial of the birth of Luigi Di Bella, the desire to memorialise, at least in part, his thoughts has prompted us to write this tribute, in the hope that one day his dreams may come true. Throughout his research for a treatment of cancer, he deemed it necessary to employ a complex array of substances that, by acting centripetally on neoplastic cells, could in turn be capable of affecting, either simultaneously or sequentially, the myriad of biological reactions supporting their lives. Hence, not a substance but a method (Di Bella Method, DBM). These brief hints at some aspects of Prof. Di Bella's multifaceted scientific vision are aimed not only at reasserting the truth, but also at giving a modest contribution to a novel and free direction in experimental and clinical science.

[From neuroendocrinology to cell biology: Andrée Tixier-Vidal]. / De la neuroendocrinologie à la biologie cellulaire : Andrée Tixier-Vidal (1923­2021).

This article relates the life, career and main scientific achievements of a pioneer in neuroendocrinology and French cell biology research, Mrs Andrée Tixier-Vidal, who passed away in December 2021. After her first works on hypophyseal-thyroid neuroendocrine axis, in birds then in mammals, Andrée Tixier-Vidal devoted herself then her group at the College of France to the histophysiological study of adenohypophysis and namely of prolactin (PRL) cells. Using in vitro models of organotypic cultures and cultures of GH3 cells, she described up to ultrastructural level the secretory process of PRL and its regulation by TRH. Furthermore, she extended her study to the TRH neurons themselves thanks to original models of in vitro cultures of hypothalamic neurons. Her fundamental and methodological achievements have largely contributed to major knowledge advances in cell biology of the secretion during the last century.

Title: De la neuroendocrinologie à la biologie cellulaire : Andrée Tixier-Vidal (1923­2021). Abstract: Cet article relate la vie, la carrière et l'œuvre scientifique de Mme Andrée Tixier-Vidal, disparue en décembre 2021. Il montre comment, après avoir développé une approche histophysiologique originale de la neuroendocrinologie et tout particulièrement de l'axe hypophyso-thyroïdien, elle a réalisé des travaux pionniers qui ont complètement renouvelé les connaissances sur les neurones hypothalamiques à thyréolibérine (TRH) qui interviennent dans la régulation des cellules à thyréostimuline (TSH), mais également de celles à prolactine (PRL). Le fil conducteur de ses recherches a été la biologie cellulaire de la sécrétion abordée par les techniques morphologiques et cytochimiques sur des modèles originaux de cultures organotypiques d'hypophyse mais aussi de cellules tumorales GH3 et enfin de neurones hypothalamiques. Le rayonnement scientifique de Mme Tixier-Vidal et de son équipe se prolonge encore à travers les multiples générations de chercheurs qui ont eu le privilège de profiter de son dynamisme intellectuel et de son enthousiasme pour la recherche en biologie.

History of hypothalamic research: "The spring of primitive existence".

The central brain region of interest for neuroendocrinology is the hypothalamus, a name coined by Wilhelm His in 1893. Neuroendocrinology is the discipline that studies hormone production by neurons, the sensitivity of neurons for hormones, as well as the dynamic, bidirectional interactions between neurons and endocrine glands. These interactions do not only occur through hormones, but are also partly accomplished by the autonomic nervous system that is regulated by the hypothalamus and that innervates the endocrine glands. A special characteristic of the hypothalamus is that it contains neuroendocrine neurons projecting either to the neurohypophysis or to the portal vessels of the anterior lobe of the pituitary in the median eminence, where they release their neuropeptides or other neuroactive compounds into the bloodstream, which subsequently act as neurohormones. In the 1970s it was found that vasopressin and oxytocin not only are released as hormones in the circulation but that their neurons project to other neurons within and outside the hypothalamus and function as neurotransmitters or neuromodulators that regulate central functions, including the autonomic innervation of all our body organs. Recently magnocellular oxytocin neurons were shown to send not only an axon to the neurohypophysis, but also axon collaterals of the same neuroendocrine neuron to a multitude of brain areas. In this way, the hypothalamus acts as a central integrator for endocrine, autonomic, and higher brain functions. The history of neuroendocrinology is described in this chapter from the descriptions in De humani corporis fabrica by Vesalius (1537) to the present, with a timeline of the scientists and their findings.