Jean A. Laissue

Somatostatin receptor sst1-sst5 expression in normal and neoplastic human tissues using receptor autoradiography with subtype-selective ligands.

Somatostatin receptors are known to be expressed in a large number of human tumours and represent the basis for in vivo tumour targeting. Stable somatostatin derivatives such as octreotide or lanreotide are the most frequently used radiopharmaceuticals acting through specific binding to somatostatin receptors; however, they do not bind with high affinity to all five receptor subtypes. Whereas the mRNAs for most receptor subtypes have been detected in tumours, it is in most cases unclear which of the receptor subtype proteins are expressed. Since in vitro receptor binding methods are close correlates and predictors of in vivo peptide receptor targeting, we took advantage of the recently developed subtype-selective analogues and evaluated approximately 200 tumours for their receptor subtype protein expression in specific binding assays using autoradiography with 125I-[Leu8, D-Trp22, Tyr25]-somatostatin-28 and displacement by subtype-selective analogues. The majority of the tested neuroblastomas, meningiomas, medulloblastomas, breast carcinomas, lymphomas, renal cell carcinomas, paragangliomas, small cell lung carcinomas and hepatocellular carcinomas predominantly expressed sst2. The prostate carcinomas and sarcomas preferentially expressed sst1, while a majority of inactive pituitary adenomas displayed sst3 and, to a lesser extent, sst2. Growth hormone-secreting pituitary adenomas preferentially expressed sst2 and sst5; gastroenteropancreatic tumours and phaeochromocytomas frequently displayed sst2 and/or sst1. Non-neoplastic human tissues such as vessels, nerve plexus, pancreatic islets, prostatic stroma, adrenal medulla, spleen and germinal centres of the lymphoid tissues preferentially expressed sst2. However, the human gastric mucosa predominantly expressed sst1 while colonic mucosa displayed sst2. Interestingly, a minority of tumours showed a strong 125I-[Leu8, D-Trp22, Tyr25]-somatostatin-28 binding, of which less than 50% could be displaced by the sum of the five subtype-selective analogues. This observation suggests the existence of an as yet unknown subtype in selected tumours. This study is the first report to analyse the somatostatin receptor subtype expression in tumours with binding methods. We conclude that sst2, with high affinity for current radiopharmaceuticals such as Octreoscan, is predominantly expressed in a majority of tumours. Fewer tumour types (sarcomas, prostate cancers, inactive pituitary adenomas) preferentially express another subtype. This information is of importance with regard to the clinical applications and development of somatostatin analogues with distinct receptor subtype selectivities.

BCA-1 is highly expressed in Helicobacter pylori–induced mucosa-associated lymphoid tissue and gastric lymphoma

Infection with Helicobacter pylori (Hp) induces the formation of lymphoid tissue in the stomach and the occasional development of primary gastric B-cell lymphomas. We have studied the expression of 2 chemokines that attract B lymphocytes, BCA-1 and SLC, in gastric tissue samples obtained from patients with chronic gastritis induced by Hp infection or nonsteroidal anti-inflammatory drugs, as well as from patients with Hp-associated low-grade and high-grade gastric lymphomas. High-level expression of BCA-1 and its receptor, CXCR5, was observed in all mucosal lymphoid aggregates and in the mantle zone of all secondary lymphoid follicles in Hp-induced gastric mucosa-associated lymphoid tissue (MALT). Follicular dendritic cells and B lymphocytes are possible sources of BCA-1, which is not expressed by T lymphocytes, macrophages, or CD1a(+) dendritic cells. Strong expression of BCA-1 and CXCR5 was also detected in the transformed B cells of gastric MALT lymphomas. By contrast, SLC was confined almost exclusively to endothelial cells in and outside the lymphoid tissue. Only scant, occasional SLC expression was observed in the marginal zone of MALT follicles. Our findings indicate that BCA-1, which functions as a homing chemokine in normal lymphoid tissue, is induced in chronic Hp gastritis and is involved in the formation of lymphoid follicles and gastric lymphomas of the MALT type.

Neuropathology of ablation of rat gliosarcomas and contiguous brain tissues using a microplanar beam of synchrotron-wiggler-generated X rays

Adult‐rat‐brain tissues display an unusually high resistance to necrosis when serially irradiated with parallel, thin slices of a microplanar (i.e., microscopically thin and macroscopically broad) beam of synchrotron‐wiggler‐generated, approx. 35–120 keV (median approx. 50 keV) Gd‐filtered X rays at skin‐entrance absorbed doses of 312 to 5000 Gy per slice. Such microplanar beams were used to irradiate young adult rats bearing right frontocerebral 9L gliosarcomas (approx. 4 mm diameter), through a volume of tissue containing the tumor and contiguous brain tissue, either in a single array or in 2 orthogonally crossed arrays of tissue slices. Each array included 101 parallel microplanar slices, 100 μm center‐to‐center distance, each slice being approx. 25 μm wide and 12 mm high, with skin‐entrance absorbed doses of 312.5 Gy or 625 Gy per slice. Compared with unirradiated controls with a median survival time of 20 days after tumor initiation, the median survival time was extended in irradiated rats by 139 days (625 Gy, crossed arrays), 96 days (312.Gy, crossed arrays) or 24 days (625 Gy, single array). The tumors disappeared in 22 of the 36 irradiated rats, 4/ 11 even after unidirectional microbeam irradiation. The extent and severity of radiation damage to the normal brain in rats with or without tumor was graded histopathologically. Correlation of those grades with radiation doses shows that loss of tissue structure was confined to beam‐crossing regions and that only minor damage was done to zones of the brain irradiated unidirectionally. Int. J. Cancer 78:654–660, 1998.

DIFFERENTIAL IN SITU EXPRESSION OF THE GENES ENCODING THE CHEMOKINES MCP-1 AND RANTES IN HUMAN INFLAMMATORY BOWEL DISEASE

Two chemotactic cytokines, monocyte chemoattractant protein‐1 (MCP‐1) and RANTES, possibly contribute to the recruitment and activation of leukocytes in inflamed tissues. The expression of these cytokine genes was evaluated in tissue sections from resected bowel segments of 14 patients with inflammatory bowel disease (IBD) and seven control patients by use of 35S‐labelled antisense RNA probes. MCP‐1 and RANTES transcripts were generally increased in the intestinal mucosa of patients with IBD, compared with controls. Whereas MCP‐1 gene expression in the mucosa was restricted to the lamina propria, the gene coding for RANTES was expressed in intraepithelial lymphocytes and in the subepithelial lamina propria. Furthermore, MCP‐1 mRNA, but not RANTES mRNA, was abundant in vessel‐associated cells, such as endothelial cells, medial smooth muscle cells, and intraluminal cells; in smooth muscle cells of the intestinal tunica muscularis; and in cells of the myenteric plexus. Compared with controls, a significant increase of MCP‐1‐expressing cells was observed in tissue specimens from patients with IBD, in endothelial cells of venules, and in cells present in the lumen of intestinal vessels. Conversely, the expression of MCP‐1 mRNA in smooth muscle cells and myenteric plexus cells appeared to be comparable in control and diseased intestines. The increased number of MCP‐1 and RANTES mRNA‐expressing cells in mucosa from patients with IBD suggests that these cytokines play a role in the pathogenesis of mucosal inflammation. Furthermore, the expression of the MCP‐1 gene in vessel‐associated cells may indicate its involvement in mechanisms regulating the adhesion of blood monocytes to endothelial cells.

Effects of pulsed, spatially fractionated, microscopic synchrotron X-ray beams on normal and tumoral brain tissue

Microbeam radiation therapy (MRT) uses highly collimated, quasi-parallel arrays of X-ray microbeams of 50-600keV, produced by third generation synchrotron sources, such as the European Synchrotron Radiation Facility (ESRF), in France. The main advantages of highly brilliant synchrotron sources are an extremely high dose rate and very small beam divergence. High dose rates are necessary to deliver therapeutic doses in microscopic volumes, to avoid spreading of the microbeams by cardiosynchronous movement of the tissues. The minimal beam divergence results in the advantage of steeper dose gradients delivered to a tumor target, thus achieving a higher dose deposition in the target volume in fractions of seconds, with a sharper penumbra than that produced in conventional radiotherapy. MRT research over the past 20 years has yielded many results from preclinical trials based on different animal models, including mice, rats, piglets and rabbits. Typically, MRT uses arrays of narrow ( approximately 25-100 microm wide) microplanar beams separated by wider (100-400 microm centre-to-centre) microplanar spaces. The height of these microbeams typically varies from 1 to 100 mm, depending on the target and the desired preselected field size to be irradiated. Peak entrance doses of several hundreds of Gy are surprisingly well tolerated by normal tissues, up to approximately 2 yr after irradiation, and at the same time show a preferential damage of malignant tumor tissues; these effects of MRT have now been extensively studied over nearly two decades. More recently, some biological in vivo effects of synchrotron X-ray beams in the millimeter range (0.68-0.95 mm, centre-to-centre distances 1.2-4 mm), which may differ to some extent from those of microscopic beams, have been followed up to approximately 7 months after irradiation. Comparisons between broad-beam irradiation and MRT indicate a higher tumor control for the same sparing of normal tissue in the latter, even if a substantial fraction of tumor cells are not receiving a radiotoxic level of radiation. The hypothesis of a selective radiovulnerability of the tumor vasculature versus normal blood vessels by MRT, and of the cellular and molecular mechanisms involved remains under investigation. The paper highlights the history of MRT including salient biological findings after microbeam irradiation with emphasis on the vascular components and the tolerance of the central nervous system. Details on experimental and theoretical dosimetry of microbeams, core issues and possible therapeutic applications of MRT are presented.

Weanling piglet cerebellum: a surrogate for tolerance to MRT (microbeam radiation therapy) in pediatric neuro-oncology

The cerebellum of the weanling piglet (Yorkshire) was used as a surrogate for the radiosensitive human infant cerebellum in a Swiss-led program of experimental microbeam radiation therapy (MRT) at the ESRF. Five weanlings in a 47 day old litter of seven, and eight weanlings in a 40 day old litter of eleven were irradiated in November, 1999 and June, 2000, respectively. A 1.5 cm-wide x 1.5 xm-high array of equally space approximately equals 20-30 micrometers wide, upright microbeams spaced at 210 micrometers intervals was propagated horizontally, left to right, through the cerebella of the prone, anesthetized piglets. Skin-entrance intra-microbeam peak adsorbed doses were uniform, either 150, 300, 425, or 600 gray (Gy). Peak and inter-microbeam (valley) absorbed doses in the cerebellum were computed with the PSI version of the Monte Carlo code GEANT and benchmarked using Gafchromic and radiochromic film microdosimetry. For approximately equals 66 weeks [first litter; until euthanasia], or approximately equals 57 weeks [second litter; until July 30, 2001] after irradiation, the littermates were developmentally, behaviorally, neurologically and radiologically normal as observed and tested by experienced farmers and veterinary scientists unaware of which piglets were irradiated or sham-irradiated. Morever, MRT implemented at the ESRF with a similar array of microbeams and a uniform skin-entrance peak dose of 625 Gy, followed by immunoprophylaxis, was shown to be palliative or curative in young adult rats bearing intracerebral gliosarcomas. These observations give further credence to MRTs potential as an adjunct therapy for brain tumors in infancy, when seamless therapeutic irradiation of the brain is hazardous.

Multiple actions of somatostatin in neoplastic disease

The role played by the neuropeptide somatostatin, also known as somatotropin release inhibitory factor (SRIF), in human cancer is not well understood. Recent investigations involving somatostatin receptors in normal and neoplastic human tissues suggest that the action is complex and involves both direct and indirect mechanisms. In this article, Jean-Claude Reubi and Jean Laissue describe the variety of biological mechanisms involved in neoplasia that are associated with somatostatin, and illustrate the therapeutic potential and present limitations of somatostatin analogues.

Somatostatin receptors and their subtypes in human tumors and in peritumoral vessels

Somatostatin receptors are expressed by a large variety of human tumors. In vitro receptor autoradiographic studies have shown that these tumors can express more than one somatostatin receptor subtype. Whereas the majority of tumors bind octreotide with high affinity, some, i.e., prostate tumors, bind octreotide with low affinity only. The discovery of five somatostatin receptor subtypes, sst1-5, by gene cloning has increased our understanding of somatostatin receptor structure and function. Using in situ hybridization techniques, we found that various human tumors, identified as somatostatin receptor-positive in binding studies, expressed sst2 mRNA in the majority of cases, whereas sst1 and sst3 were less frequent. Often, all three sst were expressed simultaneously. In another recent in situ hybridization study, primary prostate cancers were shown to preferentially express sst1, rather than sst2 or sst3. Moreover, a high incidence of sst5 was found in growth hormone (GH)-producing pituitary adenomas and, to a lesser extent, in active pituitary adenomas; gastroenteropancreatic (GEP) tumors showed all possible combinations, but with a predominance of sst2. Overall, the presence of sst2 mRNA and/or sst5 generally correlated with the presence of octreotide-binding sites, but with exceptions. These results indicate the highly variable abundance of sst mRNAs in individual somatostatin receptor-containing tumors. Somatostatin receptors were not only found in tumoural tissue, but also in the peritumoral vascular system. This was particularly well studied in colorectal carcinomas, where the peritumoral veins were shown to express in all cases a high density of somatostatin receptors, probably of the sst2 type, binding octreotide with high affinity. Therefore, the host peritumoral vascular system may be a possible target of somatostatin action in tumor development. Somatostatin may act locally on tumor growth through two different mechanisms dependent on local somatostatin receptor expression: through direct action on tumor cells or through action on peritumoral vessels, which may alter the hemodynamics of the tumoral blood circulation.

The value of octreotide scintigraphy in patients with lung cancer.

We evaluated octreotide scintigraphy in 81 untreated patients who were suspected of having bronchial carcinoma. Octreotide scintigraphy visualized the primary tumour in all of 40 patients with non-smallcell lung carcinoma (non-SCLC), and all of 26 patients with SCLC. In the remaining patients, other bronchial disease and metastases from extrapulmonary carcinomas were also visualized. Mediastinal lymph node involvement and distant metastases were recognized in 5 of 15 and 1 of 7 patients with non-SCLC, respectively. In vitro, none of the non-SCLCs were shown to bear somatostatin receptors. We postulate that the visualization of non-SCLC during octreotide scintigraphy is caused by binding of labelled octreotide to activated leucocytes or to proliferating neuroendocrine cells around the tumours. In patients with SCLC, radiologically suspected lymph node involvement was visualized for 21 of 25 sites. Distant metastases, especially to the liver and abdomen, were missed for 14 of 20 sites, most probably because no laxatives were administered and single photon emission tomography of the abdomen was not performed. The failure to recognize liver metastases is most probably due to a comparable uptake of radioactivity by the surrounding normal liver tissue. In 15 of 26 patients, previously unrecognized tumour sites were suggested during octreotide scintigraphy, leading to a downstaging of 5 of 14 patients with limited disease. Unexpected cerebral metastases were suggested in five patients with either limited or extensive disease. In all four of these for whom follow-up was available, cerebral metastases became manifest 5–8 months after octreotide scintigraphy. We conclude (1) that octreotide scintigraphy is of no use to differentiate SCLC from other lung disease, and (2) that octreotide scintigraphy should be included in the staging procedure of SCLC because it may allow early detection of metastases, especially to the brain.

Expression of Somatostatin Receptors in Normal, Inflamed, and Neoplastic Human Gastrointestinal Tissues

The multiple actions of somatostatin are mediated by specific membrane-bound receptors present in all somatostatin target tissues, such as brain, pituitary, pancreas, gastrointestinal tract, and kidney. For instance, in the human gastrointestinal tract, three different types of tissue compartments express somatostatin receptors: the gastrointestinal mucosa, the peripheral nervous system, and the gut-associated lymphoid tissue, where the receptors are preferentially located in germinal centers. In all these cases, somatostatin binding is of high affinity and specific for bioactive somatostatin analogues. Somatostatin receptors are also expressed in pathological states, such as cancers. A particular abundance is found in neuroendocrine tumors of the gastrointestinal tract. Ninety percent of the carcinoids and a majority of islet cell carcinomas, including their metastases, usually have a high density of somatostatin receptors. Several different somatostatin-receptor subtypes can be expressed by these tumors, the SSTR2 subtype being the most frequently and abundantly expressed. The somatostatin receptors in tumors are identified with in vitro-binding methods, molecular biology techniques, or in vivo-imaging techniques; the latter allow the precise localization of the tumors and their metastases in the patients. Because somatostatin receptors in human gastroenteropancreatic tumors are functional, their identification can be used to predict the therapeutical efficacy of octreotide to inhibit excessive hormone release. Of differential diagnostic importance is the fact that other pathological processes in the gastrointestinal tract may be associated with a high density of somatostatin receptors. Ninety percent of lymphomas, including those with intestinal involvement express somatostatin receptors. Furthermore, a moderate number of colorectal carcinomas contain somatostatin receptors, whereas exocrine pancreatic carcinomas do not. Finally, an increased expression of SS receptors in nonneoplastic conditions, such as in intestinal veins in inflammatory bowel disease, has been recently observed. These observations demonstrate the ability of the human body to regulate SS receptors in a wide number of tissues and conditions.