Modulation of the feeding system by a radular mechanosensory neuron in the terrestrial slug,Incilaria fruhstorferi

We investigated the modulatory role of a radular mechanoreceptor (RM) in the feeding system of Incilaria. RM spiking induced by current injection evoked several cycles of rhythmic buccal motor activity in quiescent preparations, and this effect was also observed in preparations lacking the cerebral ganglia. The evoked rhythmic activity included sequential activation of the inframedian radular tensor, the supramedian radular tensor, and the buccal sphincter muscles in that order.In addition to the generation of rhythmic motor activity, RM spiking enhanced tonic activities in buccal nerve 1 as well as in the cerebrobuccal connective, showing a wide excitatory effect on buccal neurons. The excitatory effect was further examined in the supramedian radular tensor motoneuron. RM spiking evoked biphasic depolarization in the tensor motoneuron consisting of fast excitatory postsynaptic potentials and prolonged depolarization lasting after termination of RM spiking. These depolarizations also occurred in high divalent cation saline, suggesting that they were both monosynaptic.When RM spiking was evoked in the fictive rasp phase during food-induced buccal motor rhythm, the activity of the supramedian radular tensor muscle showed the greatest enhancement of the three muscles tested, while the rate of ongoing rhythmic motor activity showed no increase.Abbreviations CPG central pattern generator - EPSP excitatory postsynaptic potential - RBMA rhythmic buccal motor activity - RM radular mechanosensory neuron - SMT supramedian radular tensor neuron     

Histochemical and Ultrastructural Analyses of the Epithelial Cells of the Body Surface Skin from the Terrestrial Slug, Incilaria fruhstorferi

Dorsal and ventral epithelium of the terrestrial slug, Incilaria fruhstorferi, is simple and consists of five cell types: microvillous, ciliated, round mucous, tubular mucous and channel. Microvillous cells were similar to human intestinal epithelial cells morphologically and functionally. At the base of microvilli, pinocytic vesicles which ultimately fused to form larger vacuoles, or multivesicular bodies were present. At the edge of tail or mouth, ciliated epithelial cells possessed the typical axonemes (9 plus 2 arrangement of microtubles). Mucous secretory cells were either tubular or round and their granules were membrane-bound and secreted by exocytosis. Granules of round mucous cells were proteinaceous but those of tubular cells were acidic mucopolysaccharides. Channel cells were elongate U-shaped and the central lumen was filled with a large amount of fluid (hemolymph). The function of channel cells is thought to remove hemolymph accumulated during hyperhydration. Our experiments of some markers-injection revealed that the fluid containing large molecules passed transcellularly from the hemolymph, across the basal or side region of the cell and into the central lumen. These results suggest that channel cell of the slug skin and vertebrate nephron showed some parallels in structure and function.     

The channel cell of the terrestrial slug Ariolimax columbianus (Stylommatophora,Arionidae)

Summary Studies were carried out to identify the route by which macromolecules and large volumes of fluid traverse the skin of terrestrial gastropods. Electron micrographs of the skin of the banana slug Ariolimax columbianus demonstrated that carbon particles can enter large, specialized cells and pass thence to the exterior. These cells, which are termed channel cells, range up to 500 m in length; they reach from the external surface of the skin to deep within the subepithelial interstitium. At the light-microscope level they show a large central channel or reservoir apparently filled with homogeneous fluid; after injection of ink into the body cavity this central channel becomes ink-filled. Electron micrographs show cisternae of the smooth endoplasmic reticulum, opening from the cell surface and occasionally traversing the entire cytoplasmic layer. The neurohormone arginine vasotocin stimulates fluid and particle movement through the channel cell; this response is inhibited by norepinephrine. Fluid output is dependent on the presence of a transwall hydrostatic pressure gradient of about 7 torr or above, as well as on activation of the channel cells.     

T cell receptor beta-chain selection in human allograft rejection

We have analyzed a series of T cell lines established from renal needle biopsies taken from renal allograft recipients with clinical signs of rejection. These T cells show strong cytotoxicity directed against donor HLA and their proliferative capacity in vitro is highly correlated with irreversible graft rejection. A total of 10 of 12 lines examined by Southern blot analysis using a J beta C beta DNA probe show predominant beta-chain rearrangements. In one instance DNA was isolated from cell lines generated from sequential biopsies taken from the same patient at different times of rejection. These lines show the same predominant beta-chain rearrangements. To determine whether these predominant rearrangements are due to expansion of a single clone or different T cell clones rearranging similar beta-chains, the same blots were analyzed with a J gamma probe. Cell line MH3 shows two predominant beta-chain rearrangements and at least seven of eight possible rearranged gamma-chain bands, implying that multiple clones share similar beta-chains. In contrast, the cell line King shows a single beta-chain and a single gamma-chain rearrangement. Many of the other cell lines fall between these two extremes, indicating that both beta-chain selection and clonal dominance are operating during graft rejection, resulting in the appearance of predominant beta-chain rearrangements.     

Odor-evoked responses in the olfactory center neurons in the terrestrial slug

The procerebrum (PC) of the terrestrial mollusk Limax is a highly developed second-order olfactory center consisting of two electrophysiologically distinct populations of neurons: nonbursting (NB) and bursting (B). NB neurons are by far the more numerous of the two cell types. They receive direct synaptic inputs from afferent fibers from the tentacle ganglion, the primary olfactory center, and also receive periodic inhibitory postsynaptic potentials (IPSPs) from B neurons. Odor-evoked activity in the NB neurons was examined using perforated patch recordings. Stimulation of the superior tentacle with odorants resulted in inhibitory responses in 45% of NB neurons, while 11% of NB neurons showed an excitatory response. The specific response was reproducible in each neuron to the same odorant, suggesting the possibility that activity of NB neurons may encode odor identity. Analysis of the cycle-averaged membrane potential of NB neurons revealed a correlation between the firing rate and the membrane potential at the plateau phase between IPSPs. Also, the firing rate of NB neurons was affected by the frequency of the IPSPs. These results indicate the existence of two distinct mechanisms for the regulation of NB neuron activity.     

T cell subsets in allograft rejection. In situ characterization of T cell subsets in human skin allografts by the use of monoclonal antibodies

We have provided evidence that both major T cell subsets, T4-positive (helper/inducer) and T8-positive (cytotoxic/suppressor), infiltrate human skin allografts. Overall, and in the graft dermis and graft bed, T4-positive cells were predominant (1.5 to 3 times more numerous than T8-positive cells). In contrast, T8-positive cells were relatively more numerous in the epidermis and hair follicles. Rejection probably proceeded by two apparently independent pathways: 1) direct contact killing of graft epithelial cells, presumably by immunologically specific T8-positive cytotoxic cells, and 2) injury of microvascular endothelium of both the graft and graft bed with secondary graft infarction. Although important in first set skin allograft rejection, the mechanism of the second type of killing is uncertain. T4-positive cells were probably involved, as evidenced by their greater numbers; furthermore, studies in mice have shown that transfused helper/inducer cells are able to effect first-set skin graft rejection. It remains to be determined whether T4-positive cells act alone or cooperate with other cells to destroy vessels and bring about graft rejection. Langerhans cells were recognized in epithelial and dermal compartments of both allografts and autografts by their reactivity with anti-T6 and anti-Ia antibodies. We could not determine whether such cells in allografts were of host or donor origin.     

Role of the L3T4+ T cell in allograft rejection

Pancreatic islet and fetal pancreas allotransplantation has been used to examine the role of the L3T4+ T cell in allograft rejection. Tissues were grafted into recipient animals depleted of peripheral L3T4+ T cells by in vivo administration of GK1.5 (anti-L3T4) monoclonal antibody to ask the question: is there a requirement for the L3T4+ T cell in graft rejection? Data show that the requirement for the L3T4+ T cell depends on either the type of tissue transplanted or type of the antigenic disparity between donor and recipient. Data also indicate that islet allograft acceptance achieved after GK1.5 treatment of the recipient is not due to tolerance induction. We therefore conclude that the cellular requirements for allograft rejection are determined by the type of tissue transplanted and the genetic disparity between donor and recipient.     

Expression of Asn-d-Trp-Phe-NH2 in the brain of the terrestrial slug Limax valentianus

The tripeptide Asn-d-Trp-Phe-NH(2) (NdWFamide) is a D-amino acid-containing cardioexcitatory peptide initially isolated from Aplysia. Previously we detected NdWFamide immunoreactivity in the visceral giant cells, the largest neurons in the brain of the terrestrial slug Limax located at the dorsal surface of the visceral ganglia. In the present study, we further analyzed the morphological features of these neurons by an intracellular injection of Lucifer yellow, and found that these neurons extend neurites out of the brain through at least 5 nerve bundles. We then isolated a gene and a cDNA clone potentially encoding a NdWFamide precursor, and investigated expression at the levels of mRNA and protein in Limax. The NdWFamide gene consists of 5 exons spanning at least 17 kb of the genome, and its open reading frame extends over 3 exons. The spatial expression pattern of NdWFamide mRNA was almost identical to that of the NdWFamide peptide, with some minor discrepancies in between. Although the most remarkable expression was evident in the visceral giant cells, we also found the expression of NdWFamide mRNA and peptide in the cerebral and pedal ganglia. These results suggest the involvement of NdWFamide in the regulation of a broad area of the slug's body.     

Vigorous allograft rejection in the absence of danger

Tolerance to self is a necessary attribute of the immune system. It is thought that most autoreactive T cells are deleted in the thymus during the process of negative selection. However, peripheral tolerance mechanisms also exist to prevent development of autoimmune diseases against peripheral self-Ags. It has been proposed that T cells develop tolerance to peripheral self-Ags encountered in the absence of inflammation or "danger" signals. We have used immunodeficient Rag 1-/- mice to study the response of T cells to neo-self peripheral Ags in the form of well-healed skin and vascularized cardiac allografts. In this paper we report that skin and cardiac allografts without evidence of inflammation are vigorously rejected by transferred T cells or when recipients are reconstituted with T cells at a physiologic rate by nude bone graft transplantation. These results provide new insights into the role of inflammation or "danger" in the initiation of T cell-dependent immune responses. These findings also have profound implications in organ transplantation and suggest that in the absence of central deletional tolerance, peripheral tolerance mechanisms are not sufficient to inhibit alloimmune responses even in the absence of inflammation or danger.     

Inhibition of NF-kappaB-dependent T cell activation abrogates acute allograft rejection.

Using a heterotopic model of transplantation, we investigated the role of T cell activation in vivo during allograft rejection in I-kappaB(DeltaN)-transgenic mice that express a transdominant inhibitor of NF-kappaB in T cells. Our results show indefinite prolongation of graft survival in the I-kappaB(DeltaN)-transgenic recipients. Interestingly, at the time of rejection of grafts in wild-type recipients, histology of grafts in the I-kappaB(DeltaN)-transgenic recipients showed moderate rejection; nevertheless, grafts in the I-kappaB(DeltaN) recipients survived >100 days. Analysis of acute phase cytokines, chemokine, chemokine receptors, and immune responses shows that the blockade of NF-kappaB activation in T cells inhibits up-regulation of many of these parameters. Interestingly, our data also suggest that the T cell component of the immune response exerted positive feedback regulation on the expression of multiple chemokines that are produced predominantly by non-T cells. In conclusion, our studies indicate NF-kappaB activation in T cells is necessary for acute allograft rejection.     

Genomic structure of nitric oxide synthase in the terrestrial slug is highly conserved

Nitric oxide (NO) is a key molecule in olfactory information processing across animal species. To gain insight into the genetic basis of NO generation, we investigated the genomic structure of nitric oxide synthase (NOS) in the terrestrial slug Limax because slugs use olfaction as their primary food detection system. The full length cDNA of limNOS encodes a protein consisting of 1632 amino acids that has a PSD-95/discs-large/ZO-1 (PDZ) domain in its N-terminus and 6 other cofactor-binding domains. The limNOS gene consists of 33 exons and spans at least 107 kb of the genome. Almost all the exon-intron boundaries are conserved in Limax and human nNOS and the organization of the Limax genome is more similar to that of humans than to Drosophila, indicating that there was an accelerated evolution of the Drosophila genome during evolution. These results imply that there was a highly conservative selective pressure imposed on NOS gene structure during the evolution of mollusks and vertebrates.     

Analysis of DNA endoreplication in the brain neurons in the terrestrial slug, Limax valentianus

DNA endoreplication is the DNA synthesis without cell division, resulting in the generation of a nucleus containing a larger amount of genomic DNA compared to a normal diploid genome. There are many such giant neurons in the molluscan brain that are generated as a result of repeated endoreplication. However, it has been controversial whether the endoreplication is the whole genome replication (polyploidy) or the local amplification of the genes that are necessary for the neuron's function (polyteny/polysomy). Here in this study, we investigated these two possibilities by (1) immunohistochemical analysis of the distribution of 5'-bromodeoxyuridine incorporated into the nuclei of the brain neurons, and by (2) quantitative genomic PCR directed to two different genes expressed in specific brain regions. Our data supported the view that the DNA endoreplication is the whole genome replication rather than the local amplification of a specific genomic region.     

Cellular immunity in allograft rejection: role of lymphocyte subpopulations and T-cell subsets in rat cardiac allograft rejection

In this study, cellular requirements for rejection are examined by the use of adoptive transfer assays in the ACI to Lewis cardiac allograft model. The findings show that adoptive transfer of 1 x 10(8) spleen cells (SpL), 5 x 10(7) T-cells, and 2 x 10(7) helper T-cells (W3/25+) obtained from normal, nonsensitized donors restores acute ACI graft rejection in sublethally irradiated (750 rad) Lewis recipients. In contrast, reconstitution with 2 x 10(7) cytotoxic T-cells (0X8+) does not restore first-set graft rejection. Reconstitution of the irradiated recipients with either W3/25+ or 0X8+ T-cells obtained from specifically sensitized syngeneic donors resulted in acute rejection. The W3/25+ T-cell subset was significantly more potent (P less than 0.01) in effecting rejection on a per-cell basis. Adoptive transfer of SpL, T-cells, and 0X8+ T-cells obtained from sensitized rats led to accelerated cardiac allograft rejection in the naive secondary recipients while W3/25+ T-cells did not. This study suggests that although the W3/25+ T-cells alone have the capacity to initiate first-set graft rejection, both W3/25+ and 0X8+ subsets appear to be critical to the completion of rejection of heart allografts. We also examined the capacity of adoptively transferred B-cells from sensitized donors to influence graft rejection. Our findings suggest that while B-cells fail to restore the capacity for graft rejection in irradiated recipients, they can, however, present MHC antigens to the secondary naive host thus causing allosensitization which results in accelerated rejection of a subsequent graft.     

Mechanism of thyroid allograft rejection.

Balb/c thyroids, held in organ culture for 26 days, survive and function as well as isografts for greater than 100 days in CBA recipients. Uncultured allografts are totally rejected by 20 days after transplantation. Prolonged allograft survival can also be achieved by the treatment of donor animals with cyclophosphamide prior to harvesting tissues for transplantation. These allografts do not survive as well as 26 day cultured allografts, but cyclophosphamide pretreatment reduces the culture time required to achieve indefinite survival to 7 days. The provision of an allogeneic (LD) stimulus by thyroid tissue that is I-region incompatible with the host does not facilitate the rejection of a tolerated cultured allograft. However, activation of the host immune system by an uncultured graft syngeneic to a tolerated cultured allograft leads to the chronic rejection of the cultured transplant. The transfer of a tolerated cultured allograft back to its strain of origin induces an acute inflammatory reaction that causes tissue damage within the transplant but does not lead to the total destruction of the tissue.     

Modification of cardiac activity in response to dehydration in the terrestrial slug, Limax maximus

The level of body hydration in the terrestrial slug Limax maximus modifies several aspects of behavior such as pneumostome activity, feeding responsiveness, huddling, and contact-rehydration. The relationship between water balance and pneumostome activity and respiratory function suggested that cardiac activity might also be affected. To pursue this possibility, intact slugs and isolated heart-central nervous system (CNS) preparations were used to investigate cardiac responses to the increase in hemolymph osmolality which occurs during dehydration. In intact animals, heart rate increased in response to progressive air-dehydration and to increases in hemolymph osmolality resulting from injections of hyperosmotic solutions of mannitol or NaCl. In isolated preparations, the heart or CNS were separately exposed to hyperosmotic saline. Exposure of the heart alone to hyperosmotic saline resulted in decreased heart rate while exposure of only the CNS resulted in an increase in heart rate. These observations suggest that the increase in heart rate that is observed in intact air-dehydrated slugs is primarily mediated by the CNS.