[Dr. Voronoff's curious glandular xeno-implants]. / Os curiosos xenoimplantes glandulares do doutor Voronoff.

Dr. Serge Voronoff visited Brazil during the Jornadas Médicas of 1928, where he demonstrated his xenotransplantation technique to the local medical community. The present article uses newspaper clippings from that time to illustrate how this controversial surgery and Voronoff's alleged miraculous preservation of good health and longevity was viewed in the popular imagination. Voronoff's initiative paved the way for other health professionals to report on their surgical experiences with xenotransplantation and also popularized the topic, which became the subject of Carnival songs and sardonic jokes in the press. An analysis is offered, based on current scientific parameters, along with a suggestion concerning the possible involvement of xenotransplantation in HIV epidemiology.

Inhibitory effects of the androgenic gland on ovarian development in the mud crab Scylla paramamosain.

Isolation and characterization of androgenic hormone in decapod crustaceans depend on an effective bioassay of its action. In the present study, the effect of androgenic gland on ovarian development in the mud crab Scylla paramamosain was investigated with a view to develop a bioassay for androgenic hormone. Ovarian regression with degeneration of oocytes occurred in some female crabs implanted with androgenic gland in vivo. In vitro incubation of ovarian tissues at secondary vitellogenesis in extract of androgenic gland resulted in a significant decrease in amino acid uptake by the tissues. We propose that this inhibitory effect could be established as an effective bioassay for the isolation of androgenic hormone in the mud crab.

Male-like behavioral patterns and physiological alterations induced by androgenic gland implantation in female crayfish.

The androgenic gland (AG) has been shown to regulate male sexual differentiation and secondary male characteristics in Crustacea. This study presents for the first time in crustaceans evidence for masculinization effects of the AG on reproductive behavior, in addition to morpho-anatomical and physiological effects. AG implantation into immature female red claw crayfish Cherax quadricarinatus inhibited secondary vitellogenesis and development of the ovaries, as well as morphological traits that facilitate maternal egg brooding; it also caused the appearance of secondary male characteristics. However, primary male characteristics and a masculine reproductive system were not developed. In pair encounters, aggression was substantially lower in interactions between AG-implanted and intact females than in interactions within AG-implanted or intact pairs. Moreover, elements of mating behavior, i.e. male courtship displays and false copulations, were exhibited by AG-implanted females in several encounters with intact females. In addition to known morpho-anatomical and physiological effects of the AG in crustaceans, the present study suggests that the AG has novel effects on the neural network that generates social behavior.

The basis of immunogenicity of endocrine allografts.

Two signals are required for optimal T-cell activation: the engagement of the antigen-specific receptor and the provision of a second non-antigen-specific inductive signal, or costimulator (CoS). Regarding allograft immunity, two primary pathways of donor antigen presentation can fulfill this two-signal requirement, resulting in cellular immunity to a transplant: (1) "direct" (donor MHC-restricted) presentation in which the antigen-presenting cells (APCs) resident within the transplant directly activate host T lymphocytes and (2) "indirect" (host MHC-restricted) presentation in which host-derived APCs acquire donor antigens that are then presented to host T lymphocytes. It appears that endocrine allografts, such as pancreatic islets and thyroid, are highly dependent on donor-derived APCs, or "passenger leukocytes," to trigger acute graft rejection. Tissue pretreatment aimed at selectively eliminating APCs within endocrine tissues can result in indefinite allograft survival in immune-competent recipients. Although such results implicate the "direct" pathway as the predominant route of host sensitization, the role of donor APCs in rejection appears to be more complex. Recently, we have found that indirect, CD4 T-cell-dependent reactivity can contribute to islet allograft rejection. However, such indirect recognition nevertheless requires donor-derived APCs as a source of antigen. Thus, whereas the donor-type APC is a critical limiting step for initiating islet allograft rejection, such cells can trigger both direct and indirect forms of immune responses that can result in graft rejection. That is, donor hematopoietic cells, rather than tissue parenchymal cells, probably play a major role in providing antigens that stimulate cellular immunity.

Effects of implantation of hypertrophied androgenic glands on sexual characters and physiology of the reproductive system in the female red claw crayfish, Cherax quadricarinatus.

The role of the androgenic gland (AG), an organ unique to male Crustacea, in the development of sex characters and physiology of the reproductive system has not been fully documented in the red claw crayfish, Cherax quadricarinatus. To investigate the role of the AG in this species, the effect of implanting hypertrophied AGs into immature female animals was followed. Of the female animals with AG implants, 91.6% developed male-like propodi, including the red patch characteristic of males of this species. The development of female secondary sex characteristics such as a wider abdomen, a wider endopod, and simple setation was inhibited. At the end of the experiment, the ovaries of the AG-implanted females contained mostly lipid-stage oocytes, with a small number of oocytes at the early yolk stage. The gonadosomatic index of the AG-implanted females was significantly lower than that of the control (sperm duct-implanted or sham-operated) females, which had mature oocytes with a well-defined perinuclear zone and yolk globules. An immunohistochemical test using an antibody developed against a 106-kDa secondary vitellogenic polypeptide showed only slight immunoreactivity in the oocytes of AG-implanted females compared with abundant immunoreactivity in control ovaries. In the polypeptide profile of the high-density lipoprotein (HDL) from the hemolymph of AG-implanted females, the 206- and 79-kDa secondary vitellogenesis-specific polypeptides were not found, whereas they were present in the profile of control females. In contrast, the female-specific 177-kDa polypeptide was present in the polypeptide profile of hemolymph HDL of both AG-implanted females and control females. It seems therefore that while secondary sex characters were masculinized under the influence of the implanted AG, the process of vitellogenesis was suppressed but not fully eliminated in the AG-implanted females.

Tissue engineering from Adam to the zygote: historical reflections.

Tissue engineering, long a matter of myth and dream throughout the history of medicine, is now a practical reality. A wide spectrum of biological materials are used in the field of urology to treat disease and to overcome human disabilities, including tissue grafts and organ transplantation. Laboratory-engineered bioproducts for the off-the-shelf replacement and reconstruction of tissue is now almost at hand. This article presents a glimpse into the past by highlighting a number of early pioneering works in the field of tissue transplantation and cell culture technologies.

Sex reversal by implantations of ethanol-treated androgenic glands of female isopods, Armadillidium vulgare (Malacostraca, crustacea).

The androgenic glands (AGs) of malacostracan crustaceans are responsible for differentiation of male sexual characteristics, and sex reversal is readily obtained by implantation of AGs in female crustaceans. In order to induce sex reversal, we implanted inactive AGs (dead cells) into young females of Armadillidium vulgare. Before implantation fresh AGs (living cells) were treated twice with 80% ethanol for 3 min and kept in crustacean physiological saline for 30 s. We refer to these AGs as ethanol-treated AGs (t-AGs). Stage 6 females were used as recipients of t-AG implantation. They received an implant of three t-AGs (3 t-AGs) three times, once each week. Testis formation in recipients was used as an indicator of the masculinized levels of female gonads. Female sexual characteristics were masculinized in proportion to the number of 3 t-AG implantations. Three implantations (total number of t-AGs, nine glands) induced development of testes, penes, and male copulatory organs in the recipient females. Furthermore, they could produce progeny. These results show that t-AG implantations are capable of inducing masculinization of female sexual characteristics. The procedure of three implantations with 3 t-AGs at stage 6 is enough to transform the sex from a genetic female into a functional male. If t-AGs are used to implant instead of fresh AGs, we can detect the effects induced by newly formed AGs of recipient females, not by implanted donor's AGs. The present method may be useful for examining the regulatory mechanism of sex differentiation of female A. vulgare.

Major histocompatibility complex restriction and transplantation immunity. A possible solution to the allograft problem.

Studies of the survival of weakly histoincompatible skin grafts in which the Langerhans' cells (LC)5 have been replaced with major histocompatibility complex (MHC)-compatible or incompatible LC, as well as studies of the fate of cultured endocrine allografts in MHC-compatible and incompatible mice and rats, indicate that allografts are only recognized as foreign if they possess donor macrophages (or cells of this family), or if antigen presenting cells MHC-compatible with the graft can be provided by the host.

[Masculinization of prepubertal and pubertal females of Sphaeroma serratum Fabr., (Crustacea Isopoda Flabellifera) by implantation of an androgenic gland of pubertal male]. / Masculinisation des femelles prépubères et pubères de Sphaeroma serratum Fabr., (Crustacé Isopode Flabellifère) par implantation d'une glande androgène de mâle pubère.

In Sphaeroma serratum, the differentiation of the male external sexual characteristics, as a result of an androgenic gland implant, proceeds more easily in females in vitellogenesis than in immature females. On the contrary, the transformation of the gonads is quicker and more obvious in immature females than in mature ones. This transformation which leads, in all cases, to an inversion of the ovary to a functional testicle able to produce spermatozoa, always occurs without any differentiation of an androgenic gland, contrary to what can be observed with Oniscoïds. The details of the external sexual differentiation of the grafted females can be related to the functioning of a protocerebral neurosecretory center having, as in males, an androinhibitory effect on the androgenic gland implant; the activity of this center, which seems to correspond to the center secreting VIH, would be particularly high with immature females and would become very low--or nonexistent--in females in vitellogenesis.

[Transplantation of organs and tissues. The idea and practise in the course of time (author's transl)]. / Transplantation von Geweben und Organen. Idee und Praxis im Laufe der Zeit.

The idea of organ transplantation is old and can be traced back to mythology. Even the practice of skin grafting is already over two thousand years old. Nevertheless, today we are perhaps only at the beginning of the phase of broad clinical realization of transplantation surgery. It became possible by accurate scientific working out of the basic immunological problems in this century. At the present time, between the possible organ and tissue transplantations a wide range from a high probability of success (eg cornea) to extensive lack of success (eg lung, small intestine) is to be seen. This is due particularly to the still unsolved immunological problems. Among the organ transplantations in the strict sense only renal transplants can be said to be the fully recognized clinical method of treatment today.

The brain and subarachnoid space as possible sites for endocrine tissue transplantation.

Immunological rejection has been the major problem limiting the successful transplantation of tissue from one animal to another. Recent technological developments, combined with the use of the central nervous system as an immunologically privileged site, suggest that it might be possible to achieve long-term survival of hormone-secreting tissues, between two gentically dissimilar animals, if these tissues are transplanted to the brain and subarachnoid space of the host. The physiological parameters that should be considered in the clinical application of a transplant of this type are discussed.

Optic gland implants and their effects on the gonads of Octopus.

1. Optic glands transplanted from one Octopus vulgaris into another cause enlargement of the gonads and ducts of the recipient. 2. Enlargement occurs whether or not the gland was secreting when implanted and regardless of the sex of the donor or recipient. 3. Glands derived from Eledone moschata or Octopus macropus implanted into O. vulgaris are as effective as glands derived from O. vulgaris. 4. Implants derived from Sepia officinalis or Loligo vulgaris appear to be ineffective.