Transplantation of porcine adrenal spheroids for the treatment of adrenal insufficiency.

Primary adrenal insufficiency is a life-threatening disorder, which requires lifelong hormone replacement therapy. Transplantation of xenogeneic adrenal cells is a potential alternative approach for the treatment of adrenal insufficiency. For a successful outcome of this replacement therapy, transplanted cells should provide adequate hormone secretion and respond to adrenal physiological stimuli. Here, we describe the generation and characterization of primary porcine adrenal spheroids capable of replacing the function of adrenal glands in vivo. Cells within the spheroids morphologically resembled adult adrenocortical cells and synthesized and secreted adrenal steroid hormones in a regulated manner. Moreover, the embedding of the spheroids in alginate led to the formation of cellular elongations of steroidogenic cells migrating centripetally towards the inner part of the slab, similar to zona Fasciculata cells in the intact organ. Finally, transplantation of adrenal spheroids in adrenalectomized SCID mice reversed the adrenal insufficiency phenotype, which significantly improved animals' survival. Overall, such adrenal models could be employed for disease modeling and drug testing, and represent the first step toward potential clinical trials in the future.

Autogenous transplants of adrenal fragments in an animal model.

Introduction Adrenal insufficiency is a typical complication after surgical treatment of adrenal tumors, especially after the removal of both adrenal glands. Human beings are not able to survive without adrenal glands and without proper hormonal substitution. Autotransplantation of a fragment of the adrenal gland may prevent this complication. This can be done by transplanting the entire adrenal glands or its fragment, such as the adrenal cortex cells. In the case of adrenal tumors, the entire adrenal gland can not be transplanted. However, it is possible to transplant cells from the tumor-free part. Succesful adrenal autografts may result in a new treatment of adrenal insufficiency. MATERIALS AND METHODS: Autograft transplantation was performed on 3 groups of Sprague Dawley rats. In the first group, physiological corticosterone concentrations were determined. These animals were not operated. In the second group, both adrenal glands were removed. Corticosterone concentrations were determined after bilateral adrenalectomy. The third group was divided into two parts. In the first subgroup, bilateral adrenalectomy was performed simultaneosly with adrenal transplant into the omentum. In the second subgroup, right adrenalectomy was performed simultaneosly with and adrenal transplant into the omentum followed a month later by left adrenalectomy. During the experiment, corticosterone concentrations were measured at 4 time points. RESULTS: The statistical difference between corticosterone concentrations in rats after two timed adrenalectomies and rats after bilateral adrenalectomy was statistically different, but these results were far from physiological concentrations.

Hypothalamo­hypophysial system in rats with autotransplantation of the adrenal cortex.

Patients with bilateral pheochromocytoma often require an adrenalectomy. Autotransplantation of the adrenal cortex is an alternative therapy that could potentially be performed instead of receiving glucocorticoid replacement following adrenalectomy. Adrenal cortex autotransplantation aims to avoid the side effects of long­term steroid treatment and adrenal insufficiency. Although the function of the hypothalamo­hypophysial system is critical for patients who have undergone adrenal cortex autotransplantation, the details of that system, with the exception of adrenocorticotropic hormone in the subjects with adrenal autotransplantation, have been overlooked for a long time. To clarify the precise effect of adrenal autotransplantation on the pituitary gland and hypothalamus, the current study examined the gene expression of hormones produced from the hypothalamus and pituitary gland. Bilateral adrenalectomy and adrenal autotransplantation were performed in 8 to 9­week­old male rats. The hypothalamus and pituitary tissues were collected at 4 weeks after surgery. Transcriptional regulation of hypothalamic and pituitary hormones was subsequently examined by reverse transcription­quantitative polymerase chain reaction. Proopiomelanocortin, glycoprotein hormone α polypeptide, and thyroid stimulating hormone ß were significantly elevated in the pituitary gland of autotransplanted rats when compared with sham­operated rats. In addition, there were significant differences in the levels of corticotropin releasing hormone receptor 1 (Crhr1), Crhr2, nuclear receptor subfamily 3 group C member 1 and thyrotropin releasing hormone receptor between the sham­operated rats and autotransplanted rats in the pituitary gland. In the hypothalamus, corticotropin releasing hormone and urocortin 2 mRNA was significantly upregulated in autotransplanted rats compared with sham­operated rats. The authors identified significant alterations in the function of not only the hypothalamus­pituitary­adrenal axis, but also the adenohypophysis thyrotropes in autotransplanted rats. In the future, it will be important to examine other tissues affected by glucocorticoids following adrenal cortex autotransplantation.

Transplantation of bovine adrenocortical cells encapsulated in alginate.

Current treatment options for adrenal insufficiency are limited to corticosteroid replacement therapies. However, hormone therapy does not replicate circadian rhythms and has unpleasant side effects especially due to the failure to restore normal function of the hypothalamic-pituitary-adrenal (HPA) axis. Adrenal cell transplantation and the restoration of HPA axis function would be a feasible and useful therapeutic strategy for patients with adrenal insufficiency. We created a bioartificial adrenal with 3D cell culture conditions by encapsulation of bovine adrenocortical cells (BACs) in alginate (enBACs). We found that, compared with BACs in monolayer culture, encapsulation in alginate significantly increased the life span of BACs. Encapsulation also improved significantly both the capacity of adrenal cells for stable, long-term basal hormone release as well as the response to pituitary adrenocorticotropic hormone (ACTH) and hypothalamic luteinizing hormone-releasing hormone (LHRH) agonist, [D-Trp6]LHRH. The enBACs were transplanted into adrenalectomized, immunodeficient, and immunocompetent rats. Animals received enBACs intraperitoneally, under the kidney capsule (free cells or cells encapsulated in alginate slabs) or s.c. enclosed in oxygenating and immunoisolating ßAir devices. Graft function was confirmed by the presence of cortisol in the plasma of rats. Both types of grafted encapsulated cells, explanted after 21-25 d, preserved their morphology and functional response to ACTH stimulation. In conclusion, transplantation of a bioartificial adrenal with xenogeneic cells may be a treatment option for patients with adrenocortical insufficiency and other stress-related disorders. Furthermore, this model provides a microenvironment that ensures 3D cell-cell interactions as a unique tool to investigate new insights into cell biology, differentiation, tissue organization, and homeostasis.

Non-invasive assessment of adrenocortical function in captive Nile crocodiles (Crocodylus niloticus).

The occurrence of stress-inducing factors in captive crocodilians is a concern, since chronic stress can negatively affect animal health and reproduction, and hence production. Monitoring stress in wild crocodiles could also be beneficial for assessing the state of health in populations which are potentially threatened by environmental pollution. In both cases, a non-invasive approach to assess adrenocortical function as a measure of stress would be preferable, as animals are not disturbed during sample collection, and therefore sampling is feedback-free. So far, however, such a non-invasive method has not been established for any crocodilian species. As an initial step, we therefore examined the suitability of two enzyme-immunoassays, detecting faecal glucocorticoid metabolites (FGMs) with a 11ß,21-diol-20-one and 5ß-3α-ol-11-one structure, respectively, for monitoring stress-related physiological responses in captive Nile crocodiles (Crocodylus niloticus). An adrenocorticotropic hormone (ACTH) challenge was performed on 10 sub-adult crocodiles, resulting in an overall increase in serum corticosterone levels of 272% above the pre-injection levels 5h post-injection. Saline-treated control animals (n=8) showed an overall increase of 156% in serum corticosterone levels 5h post-administration. Faecal samples pre- and post-injection could be obtained from three of the six individually housed crocodiles, resulting in FGM concentrations 136-380% above pre-injection levels, always detected in the first sample collected post-treatment (7-15 days post-injection). FGM concentrations seem comparatively stable at ambient temperatures for up to 72 h post-defaecation. In conclusion, non-invasive hormone monitoring can be used for assessing adrenocortical function in captive Nile crocodiles based on FGM analysis.

[Function-preserving adrenalectomy for adrenal tumors]. / Funktionserhaltende Adrenalektomie bei Nebennierentumoren.

Organ preserving resection (subtotal adrenalectomy) or adrenocortical autotransplantation can preserve adrenocortical stress capacity in bilateral adrenal surgery. After adrenocortical autotransplantation approximately 30% of patients do not need exogenous steroids. Organ preserving surgery avoids steroid supplementation in more than 80% of cases. After organ preserving resections in secondary or familial diseases, however, there is a relevant risk of recurrent disease: the rate of ipsilateral recurrence in familial pheochromocytoma is approximately 20% during a follow-up of 20 years. Routine administration of exogenous steroids should be avoided after subtotal adrenalectomy as functional restitution of the residual tissue might be disturbed. Approximately 80% of patients, however, present with impaired adrenocortical stress capacity directly after surgery. Within a few weeks some 80% of patients show a sufficient functional restitution of the adrenocortical stress capacity. Organ preserving adrenal surgery should be performed endoscopically. The adrenal remnant should not be devascularized; the adrenal vein, however, can be divided without functional consequences. About one third of a normal adrenal gland usually provides sufficient adrenocortical function.

Ectopic expression of the gastric inhibitory polypeptide receptor gene is a sufficient genetic event to induce benign adrenocortical tumor in a xenotransplantation model.

Aberrant expression of ectopic G protein-coupled receptors (GPCRs) in adrenal cortex tissue has been observed in several cases of ACTH-independent macronodular adrenal hyperplasias and adenomas associated with Cushing's syndrome. Although there is clear clinical evidence for the implication of these ectopic receptors in abnormal regulation of cortisol production, whether this aberrant GPCR expression is the cause or the consequence of the development of an adrenal hyperplasia is still an open question. To answer it, we genetically engineered primary bovine adrenocortical cells to have them express the gastric inhibitory polypeptide receptor. After transplantation of these modified cells under the renal capsule of adrenalectomized immunodeficient mice, tissues formed had their functional and histological characteristics analyzed. We observed the formation of an enlarged and hyperproliferative adenomatous adrenocortical tissue that secreted cortisol in a gastric inhibitory polypeptide-dependent manner and induced a mild Cushing's syndrome with hyperglycemia. Moreover, we show that tumor development was ACTH independent. Thus, a single genetic event, inappropriate expression of a nonmutated GPCR gene, is sufficient to initiate the complete phenotypic alterations that ultimately lead to the formation of a benign adrenocortical tumor.

The role of corticosterone in the metabolic recovery after intrasplenic adrenal autotransplantation in rats.

Transplantation of adrenal cortical tissue may represent an alternative treatment to reestablish glucocorticoid secretion in adrenal insufficiency. In the present work, performed in adrenalectomized rats and adrenalectomized rats with a complete autotransplanted adrenal into the spleen, several hormones and biochemical parameters were measured and compared to control animals, in order to examine hormone interactions. Rats were sacrificed three weeks after surgery, and plasma and tissue samples were obtained for hormone and biochemical measurements. In adrenalectomized animals, plasma corticosterone, aldosterone and insulin levels were profoundly decreased, whereas in autotransplanted rats plasma corticosterone levels showed a partial recovery, aldosterone plasma concentrations remained low, and plasma insulin levels increased to values close to those of the controls. Both groups showed a marked elevation of plasma ACTH levels, as well as significantly increased plasma glucagon concentrations. In autotransplanted animals, most of the biochemical parameters, which were altered in adrenalectomized rats, returned to normal levels. These results suggest that increased glucagon levels in adrenalectomized and autotransplanted animals, may contribute to the marked increase of plasma ACTH, and could also be important in the recovery of plasma glucose and hepatic glycogen observed in autografted rats. Since high glucagon concentrations alone were unable to normalize carbohydrate levels in adrenalectomized animals, it appears that glucagon can act only in the presence of corticosterone.

Expression of vascular endothelial growth factor and its receptors Flk-1 and Flt-1 during the regeneration of autotransplanted adrenal cortex in the adrenalectomized rat.

PURPOSE: Autotransplantation of the adrenal cortex may be a therapeutic alternative in the future. For successful adrenal transplantation revascularization is necessary. It is possible that vascular endothelial growth factor (VEGF), which is a potent angiogenic peptide, may have some roles in adrenal transplantation through 2 its receptors, kinase insert domain-containing region (Flk-1) and fms-like tyrosine kinase (Flt-1). Therefore, we studied sequential changes in expression of VEGF, Flk-1 and Flt-1 in regenerated adrenal. MATERIALS AND METHODS: Eight to 9-week-old male Wistar rats underwent bilateral adrenalectomy and immediate adrenal capsular autotransplantation. The expression of VEGF, Flk-1 and Flt-1 was analyzed by immunohistochemistry and reverse-transcriptase-polymerase chain reaction. RESULTS: Angiogenesis was observed in the remodeling of adrenal sinusoidal endothelium during adrenal regeneration. Reverse transcriptase-polymerase chain reaction and immunohistochemistry showed that VEGF expression increased in grafted tissue with time after transplantation and its Flk-1 receptor, which localized to endothelial cells, increased transiently during the regeneration process. Immunostaining for Flt-1 receptor was identified in adrenocortical cells and its intensity gradually increased during adrenal regeneration. CONCLUSIONS: During adrenal gland regeneration VEGF and its receptors Flk-1 and Flt-1 are thought to be involved in neovascularization.

Adrenocortical cell transplantation in scid mice: the role of the host animals' adrenal glands.

Adrenocortical cell transplantation is a powerful technique for the investigation of the regulation of adrenocortical structure and function. Some classical organ and tissue transplantation experiments suggest that the success of transplantation depends on the activity of the pituitary gland and other endocrine systems, and is therefore influenced by the host animals' own adrenal glands. For this reason, our experiments have usually been performed on adrenalectomized animals. However, we show here that cell transplantation experiments, involving the introduction of bovine adrenocortical cells into scid mice, do produce transplant tissues in the presence of the host animals' adrenal glands. However, the tissue that forms is small and its cells also smaller than usual. When the adrenals of such animals are removed in a second surgical procedure, the transplants show a rapid increase in steroidogenic function and a slower increase in size, over several weeks. We conclude that the initial process by which transplanted adrenocortical cells organize into a tissue structure is not affected by the presence of the host animals' adrenal glands, but the growth of the transplants is limited until the adrenal glands are removed.

Using cell transplantation to investigate genes involved in aging.

Cell transplantation provides a way to study genes that may be important in human tissue aging. Studies on gene action in human cells are usually restricted to cell culture investigations and clinical observations. Differences in human and rodent cellular biology, particularly with respect to telomere dynamics, show the need for new systems for investigating aging that use human cells or cells of other large, long-lived mammals, such as bovine cells. The system we describe uses human and bovine adrenocortical cells transplanted into scid (severe combined immunodeficiency) mice. They form a vascularized tissue structure that can replace the essential functions of the animals' own adrenal glands. The cells may be genetically modified before introduction into the animal. Using hTERT (telomerase reverse transcriptase) and oncoproteins, we show the potential for investigating gene action in genetically modified tissues created by cell transplantation.

Allogeneic adrenocortical transplantation: glucocorticosteroid-independent immunomodulatory properties of adrenal cortex cells.

BACKGROUND: Hormone substitution for the treatment of adrenocortical insufficiency does not adequately substitute the physiologic circadian secretion of corticosteroids and leads to long-term sequelae and reduced quality of life. The lack of adaptation to physical and psychologic stress situations may lead to life-threatening Addison's crises. Allogeneic transplantation of adrenal cortex could offer an intriguing alternative. Adrenocortical grafts were demonstrated to proliferate and produce corticosteroids in physiologic concentrations after transplantation. METHODS: K -transgenic murine lymphocytes and allogeneic adrenal cortex cells were cocultured in mixed lymphocyte reactions to examine the alloimmune response; lymphocytes from T-cell receptor transgenic mice and normal mice, respectively, served as responder cells. The effects of corticosteroids secreted by adrenocortical cells were antagonized by the steroid receptor antagonist mifepristone, whereas the impact of cell-cell interactions was differentiated with transwell culture systems. RESULTS: Coculture of adrenal cortex cells in mixed lymphocyte reactions markedly suppressed lymphocyte proliferation. Transwell cultures demonstrated that adrenocortical cells exerted their effects by a soluble factor that was only partially antagonized by mifepristone. CONCLUSION: In vitro, the presence of adrenocortical cells potently suppressed allogeneic immune responses. This effect was not exclusively the result of the secretion of corticosteroids, indicating an additional immunomodulatory property of adrenocortical cells.

Cooperation of hTERT, SV40 T antigen and oncogenic Ras in tumorigenesis: a cell transplantation model using bovine adrenocortical cells.

Expression of TERT, the reverse transcriptase component of telomerase, is necessary to convert normal human cells to cancer cells. Despite this, "telomerization" by hTERT does not appear to alter the normal properties of cells. In a cell transplantation model in which bovine adrenocortical cells form vascularized tissue structures beneath the kidney capsule in scid mice, telomerization does not perturb the functional tissue-forming capacity of the cells. This cell transplantation model was used to study the cooperation of hTERT with SV40 T antigen (SV40 TAg) and oncogenic Ras in tumorigenesis. Only cells expressing all three genes were tumorigenic; this required large T, but not small t, antigen. These cells produced a continuously expanding tissue mass; they were invasive with respect to adjacent organs and eventually destroyed the kidney. Cells expressing only hTERT or only Ras produced minimally altered tissues. In contrast, SV40 TAg alone produced noninvasive nodules beneath the kidney capsule that had high proliferation rates balanced by high rates of apoptosis. The use of cell transplantation techniques in a cell type that is able to form tissue structures with or without full neoplastic conversion allows the phenotypes produced by individual cooperating oncogenes to be observed.

Intradermal cell transplantation in soluble collagen.

Intradermal, as opposed to subcutaneous, cell transplantation was previously shown to be advantageous for tumor cell growth, but this site has not been used for transplantation of normal nonneoplastic cells. In preliminary experiments we found that it was difficult to control the size and shape of transplants when we injected dissociated cells intradermally. This problem was solved by placing cells in nongelled, pepsin-solubilized collagen prior to injection. This technique permitted the successful transplantation of normal bovine adrenocortical cells and of neoplastic cells (3T3 cells secreting FGF) in scid mice. Primary bovine adrenocortical cells formed functional vascularized tissue and the transplants rescued the animals from the lethal effects of adrenalectomy. The histological structure of transplant tissues resembled that previously observed when cells were transplanted in the subrenal capsule space. We also used a line of 3T3 cells that has been genetically modified to secrete a form of acidic FGF. When transplanted intradermally in collagen, they formed rapidly enlarging masses of cells that could easily be palpated beneath the skin of the animal. Intradermal injection of cells in pepsin-solubilized collagen is a simple and reliable technique for transplanting normal primary cells and preneoplastic cells. The ability to grow both types of cells in an easily accessible site allows less invasive monitoring of growth, angiogenesis, and other features of the transplant.

Human adrenocortical cell xenotransplantation: model of cotransplantation of human adrenocortical cells and 3T3 cells in scid mice to form vascularized functional tissue and prevent adrenal insufficiency.

To establish an experimental model for replacement of endocrine organ function by xenotransplantation, human adrenocortical cells from postnatal donors were transplanted beneath the kidney capsule of adrenalectomized scidmice together with mitomycin C-treated 3T3 cells that secrete FGF. Adrenocortical cells from seven donors, male and female, ranging from 6-50 years of age, were used. 12 of 13 animals survived > 16 days following surgery. After 50 days they were sacrified to allow assessment of the histology and ultrastructure of tissue formed from the transplanted cells. Only 1 of 23 adrenalectomized sham-operated animals survived > 16 days. In all surviving animals, vascularized adrenocortical tissue formed at the site of transplantation. Cortisol, the normal human glucocorticoid, was present in the plasma of these animals, replacing corticosterone, the mouse glucocorticoid. Some animals, but not most, had measurable aldosterone. The tissue formed from the transplanted cells showed histological and ultrastructural features of normal adrenal cortex. Mitochondria had tubulo-vesicular cristae and there were prominent microvilli between cells. Tissues had a well-developed vasculature, sometimes with large sinusoidal vessels. Proliferation in the transplant tissues was very low. These results show that tissue formed from transplanted human adrenocortical cells is able to replace the essential functions of the adrenal gland in scid mice. This demonstrates that transplanted human endocrine cells can functionally replace a surgically removed endocrine organ in a host animal.

Simultaneous bilateral laparoscopic adrenalectomy in ACTH-independent macronodular adrenal hyperplasia.

Laparoscopic surgery for urological conditions has now become popular worldwide. The case is reported of a 56-year-old woman who underwent simultaneous bilateral laparoscopic adrenalectomy for adrenocorticotropic hormone-independent macronodular adrenocortical hyperplasia (AIMAH), followed by autotransplantation of resected adrenal gland fragments. Simultaneous laparoscopic adrenalectomies seem feasible for a patient with AIMAH because of its minimally invasive nature. However, autotransplantation of adrenal fragments failed in this patient with AIMAH.

Contrasting roles of p57(KIP2) and p21(WAF1/CIP1/SDI1) in transplanted human and bovine adrenocortical cells.

Cell transplantation provides a way to compare the regulation of cell proliferation in the same cell type in cell culture and in a vascularized tissue structure in a host animal. The cyclin-dependent kinase inhibitors p57(KIP2), p21(WAF1/CIP1/SDI1) and p27(KIP1) have been extensively studied in cell culture but their role in growth control in tissues is less well understood. In the present experiments we compared the behavior of cell cycle inhibitors in human and bovine adrenocortical cells in culture and following cell transplantation in scid mice. p57 was expressed in the majority of cells in the intact human adrenal cortex. However, double immunofluorescence showed that cells that are in the cell cycle are p57(-) adrenocortical cells, p57 and p27 levels were not affected by inhibition of growth at high cell density, whereas p21 was higher in dividing than growth-inhibited cells. However, p21 was also high in senescent adrenocortical cells. After transplantation of human adrenocortical cells in scid mice, p57 and p27 were observed in most cells in the transplant tissue. Over time the number of p21(+) cells decreased greatly in human adrenocortical cells, but not in bovine adrenocortical cells. This difference correlated with lower levels of cell division (assessed by Ki-67 or incorporation of bromodeoxyuridine) in the human cells in transplant tissues in comparison to bovine cells. The differences between human and bovine cells were observed both when cells were transplanted beneath the kidney capsule and when cells were injected subcutaneously in collagen gel. We conclude that the behavior of p57, but not p21, is consistent with a role as a physiological mediator of proliferative quiescence in the adrenal cortex. The high level of p21 in dividing adrenocortical cells in culture, and in bovine adrenocortical cells in transplant tissues, may be a response to conflicting positive and negative growth influences. Cells may enter the cell cycle under the influence of a strong positive mitogenic signal, but coexisting negative growth stimuli trigger a p21-dependent block to further progression through the cell cycle. This model suggests that bovine adrenocortical cells respond to positive growth stimuli in transplant tissues but human cells lack this response.

Regeneration of adrenal cortical tissue after adrenal autotransplantation.

This study tested the possibility of adrenal autotransplantation in rats. Since the cortex and the medulla of the adrenal gland were from different origin embryologically, either whole adrenal glands (ADR), or capsule and cortex (CAP) or medulla (MED) were autotransplanted in the subcutaneous tissue. The functions of regenerated adrenal nodules were tested by measuring plasma corticosterone levels every fortnight. At the end of 9 weeks the rats were exposed to hypovolemic shock followed by naloxone injection to reverse the shock response. Results showed that rats transplanted with either cortex or whole adrenal started secreting corticosterone at 5 weeks post-transplantation (107.73 +/- 21.98 ng/ml, 126.04 +/- 48.41 ng/ml, respectively). Corticosterone levels increased to the value which were not significantly different from control by 9 weeks post-transplantation. However, rats transplanted with adrenal medulla showed very low corticosterone levels. Nine weeks post-transplantation, the mean blood pressure (MBP) of the CAP group was 135 +/- 13 mmHg and was not significantly different from sham-operated controls, whereas MBP of MED group was significantly lower than sham-operated animals (99 +/- 11 mmHg versus 141 +/- 9 mmHg). The MBP of the ADR group was also lower compared to sham-operated controls (112 +/- 17 mmHg P < 0.05). The MBP of the adrenal group was not statistically significant compared to the CAP group. After 1% body weight haemorrhage, the MBP decreased significantly in ADR (45 +/- 5 mmHg, P < 0.05) and MED group (36 +/- 9 mmHg, P < 0.001) compared to sham-operated rats (78 +/- 11 mmHg) but not in the CAP (56 +/- 9 mmHg). It was concluded that autotransplanted whole adrenal or adrenocortical tissues survived subcutaneously and produced sufficient corticosterone to alleviate haemorrhagic shock. Adrenal medullary tissue failed to regenerate subcutaneously and the presence of adrenal medullary tissue may suppressed the growth of transplanted adrenal gland.