蛇毒合成的信号通路

蛇毒液产生的周期分为活跃期和静息期两个阶段,在这两个阶段中毒腺分泌细胞的形态学和生物化学方面存在着许多不同。蛇咬物排毒或人工取毒后其释放的去甲肾上腺素(noradrenaline,NE)是分泌细胞中合成毒液所必需的,其中分泌细胞的α肾上腺素能受体(α-adrenoceptor,α-AR)和β肾上腺素能受体(β-adrenoceptor,β-AR)参与了这个过程。本文简要介绍在毒液产生周期的不同阶段中分泌细胞的变化,重点阐述了刺激α-AR和β-AR在引起毒液合成开始时所介导的相关细胞信号通路。最后简单探讨了其它刺激蛇毒腺引起毒液产生的可能因素及其调控机制。     

Asynchrony in the synthesis of secretory proteins in the venom gland of the snake Vipera palaestinae.

1. Venom of Vipera palastinae was subjected to isoelectrofocusing on polyacrylamide gel. The protein separation profiles were similar for different venom samples; more than 25 protein bands with a wide range of pI values could be demonstrated by this technique. 2. Labelled venom was obtained 8h after an intracardial injection of [3H]leucine. The relative radioactivities of four out of 12 main protein bands were significantly different in the venom synthesized during the 2nd day of the venom regeneration cycle as compared with the venom of the 4th day. The comparison was made in venom samples obtained from the two glands of the same snake at two different secretory stages. 3. It is concluded that the asynchronous synthesis of exportable proteins after the initiation of a new venom regeneration cycle is responsible for the non-parallel secretion of some venom proteins by the venom gland of Vipera palaestinae during the first few days after milking.     

Activation of the ryanodine receptor Ca2+ release channel of sarcoplasmic reticulum by a novel scorpion venom.

We identified a peptide fraction from the venom of the scorpion Buthotus hottentota that stimulated binding of [3H]ryanodine to ryanodine receptors of skeletal and cardiac sarcoplasmic reticulum and brain microsomes in a highly specific manner. Activity was concentrated in a peptide fraction of Mr 5,000-8,000. Assuming a single active peptide in this fraction, we estimated a dissociation constant of 20-30 nM for the interaction of the peptide with the ryanodine receptor. The whole venom and the purified fraction activated skeletal ryanodine receptor Ca2+ release channels incorporated into planar lipid bilayers. The venom produced a 10-fold increase in the mean open time and induced the appearance of a long lasting subconductance state not seen in controls. Changes were reversible and could be induced by the partially purified venom fraction. This novel scorpion venom should be helpful in establishing the role of ryanodine receptors in the initiation of intracellular Ca2+ release in striated muscle and in nonmuscle cells containing functional ryanodine receptors such as neurons and secretory cells.     

Localization of some enzymes in the main venom glands of viperid snakes

Several secretory and nonsecretory enzymes were localized histochemically in the main venom gland of 13 viperid snakes. All secretory cells show the intracellular oxidative enzymes succinate dehydrogenase and monoamine oxidase. The granular reactions obtained for both enzymes resemble mitochondria in distribution. Distinctive cells with a very high succinate dehydrogenase activity are dispersed among the secretory cells of all species except Atractaspis. Nonspecific acid phosphatase activity is found in the supranuclear region of the secretory cells in species that do not secrete this enzyme and throughout the cytoplasm in snakes that secrete the enzyme. Nonspecific alkaline phosphatase activity occurs in the secretory cells of those snakes whose venom shows this activity. Leucine amino peptidase (aryl amidase) activity is found in the venom and in the secretory cells of all the species. In Vipera palaestinae both the venom and the secretory cells of the main venom gland contain nonspecific esterase, L-amino acid oxidase and phosphodiesterase activities. The localization of phosphodiesterase and L-amino acid oxidase do not show major differences between glands at different intervals from an initial milking. Adenosine-monophosphate phosphatase activity is localized in the supranuclear region of the secretory cells in the glands of Vipera palaestinae and Aspis cerastes. Its activity is found in the venom of Aspis only.     

管氏肿腿蜂毒液器官超微结构观察

应用透射电镜技术,观察了管氏肿腿蜂Scleroderma guani毒液器官的超微结构.毒腺由基膜层、分泌细胞层、导管细胞层和内膜层构成,分泌细胞内含内质网、末端附器、分泌囊泡、分泌颗粒、液泡等细胞器,其内合成的毒液由末端附器输送至毒腺的腔体.毒囊由肌肉鞘层、上皮细胞层和内膜层组成,肌肉鞘内的肌纤丝规则排列不交错,上皮细胞层内细胞器稀少,内膜层呈波浪状均匀加厚.     

Characterization of beta-adrenoceptors responsible for venom production in the venom gland of the snake Bothrops jararaca

We have shown that the stimulation of beta-adrenoceptors is an important step in venom production in the Bothrops jararaca venom gland. In the present study, the pharmacological profile of the beta-adrenoceptor present in Bothrops jararaca venom gland was characterized by radioligand binding assay and by the ability of isoprenaline to promote accumulation of cyclic AMP in dispersed secretory cells. In both cases, the venom glands were obtained from non-extracted snakes (quiescent stage) or from snakes which venom was extracted 4 days before sacrifice (venom production stimulated stage). [125I]-iodocyanopindolol ([125I]-ICYP) bound to extracted gland membranes in a concentration-dependent and saturable manner, but with low affinity. Propranolol, beta1- or beta2-selective adrenoceptors ligands displaced the [125I]-ICYP binding with low affinity, while selective beta3-adrenoceptor ligands did not displace the [125I]-ICYP binding. The displacement of [125I]-ICYP by propranolol was similar in non-extracted and extracted glands, showing the presence of beta-adrenoceptors in both stages. In dispersed secretory cells of non-extracted glands, isoprenaline (1 microM) increased the cyclic AMP production and propranolol (10 microM) was able to block this effect. On the other hand, in extracted glands, isoprenaline had no effect. The results suggest that the beta-adrenoceptors present in the Bothrops jararaca venom glands are different from those (beta1, beta2 or beta3) described in mammals, but are coupled to the Gs protein, like the known beta-adrenoceptor subtypes. Moreover, previous in vivo stimulation of venom production desensitizes the beta-adrenoceptors system and, although the receptors could be detected by binding studies, they are not coupled to the Gs protein, indicating that beta-adrenoceptors stimulation contributes to the initial steps of venom synthesis.     

Further observations on the B-type neurosecretory cells in the thoracic ganglion of the crab, Potamon magnum magnum (Pretzman).

Only four types of the secretory neurones were observed in the thoracic ganglion of the fresh water crab, Potamon magnum magnum (Pretzman). These cells are classified as A, A', B and C types. Our results also confirmed that the B and B' types of cells (BAID et al. 1968) are one and the same type, the B cells. The B cells are of two forms, with and without the axons. They clearly showed sequential histological patterns pointing out to their phases. The secretory material is discharged either through the periphery or through the axon and periphery both. The vacuoles were observed in both the forms of the B cells. The remarkable sign of the activity of the nuclear membrane especially at the beginning of the secretory cycle and the appearance of the first secretory granules around the nucleus strongly support the vital role of the nucleus in the initiation of the secretory cycle.     

腰带长体茧蜂毒液器官和卵巢的形态学及其超微结构

应用超薄切片和电镜技术,观察内寄生蜂腰带长体茧蜂Macrocentrus cingulum Brischke毒液器官和卵巢的形态结构。腰带长体茧蜂毒液器官由1个毒囊和2条毒腺组成,毒腺接于毒囊的顶端。毒腺由单层分泌细胞、退化的外胚层细胞和环腔的内膜构成,分泌细胞主要由1个明显的细胞核和1个较大囊状细胞器构成,囊状细胞器的功能是分泌毒液。毒囊由肌肉鞘和扁平细胞层构成,但没有分泌细胞。腰带长体茧蜂卵巢1对,每个卵巢由10条左右卵巢小管组成,与侧输卵管相接处略微膨大形成卵巢萼区。2条侧输卵管在产卵管基部会合形成1条总输卵管与产卵管相接。毒液器官通过毒囊的毒液导管附着在总输卵管上。对寄生蜂毒液器官的生物学、细胞学及在分类进化上的意义进行研究。     

Alpha1-adrenoceptors trigger the snake venom production cycle in secretory cells by activating phosphatidylinositol 4,5-bisphosphate hydrolysis and ERK signaling pathway

Loss of venom from the venom gland after biting or manual extraction leads to morphological changes in venom secreting cells and the start of a cycle of production of new venom. We have previously shown that stimulation of both α- and β-adrenoceptors in the secretory cells of the venom gland is essential for the onset of the venom production cycle in Bothrops jararaca. We investigated the signaling pathway by which the α-adrenoceptor initiates the venom production cycle. Our results show that the α₁-adrenoceptor subtype is present in venom gland of the snake. In quiescent cells, stimulation of α₁-adrenoceptor with phenylephrine increased the total inositol phosphate concentration, and this effect was blocked by the phospholipase C inhibitor U73122. Phenylephrine mobilized Ca²⁺ from thapsigargin-sensitive stores and increased protein kinase C activity. In addition, α₁-adrenoceptor stimulation increased the activity of ERK 1/2, partially via protein kinase C. Using RT-PCR approach we obtained a partial sequence of a snake α₁-adrenoceptor (260 bp) with higher identity with α_1D and α_1B-adrenoceptors from different species. These results suggest that α₁-adrenoceptors in the venom secreting cells are probably coupled to a G_q protein and trigger the venom production cycle by activating the phosphatidylinositol 4,5-bisphosphate and ERK signaling pathway.     

Ultrastructural modifications in the venom glands of workers of Apis mellifera L. (Hymenoptera: Apidae) promoted by topical application of juvenile hormone

The present study analyzed, the influence of the treatment with juvenile hormone on the ultrastructure of Apis mellifera L. workers' venom glands. Newly emerged workers received topical application of 1 microl of juvenile hormone diluted in hexane, in the concentration of 2 microg/pl. Two controls were used; one control received no treatment (group C1) and other received topical application of 1 microl of hexane (group C2). The aspect of the glandular cells, in not treated newly emerged workers, showed that they are not yet secreting actively. Cellular modifications happened according to the worker age and to the glandular area considered. The most active phase of the gland happened from the emergence to the 14th day. At the 25th day the cells had already lost their secretory characteristic, being the distal area the first to suffer degeneration. The treatment with juvenile hormone and hexane altered the temporal sequence of the glandular cycle, forwarding the secretory cycle and degeneration of the venom gland.     

Long-term primary culture of secretory cells of Bothrops jararaca venom gland for venom production in vitro

This protocol details the optimal conditions to establish a long-term primary culture of secretory cells from the venom gland of the Bothrops jararaca snake. Furthermore, these conditions allow the production and secretion of venom into the culture medium. Snake venom is a rich source of active molecules and has been used for bioprospection studies. However, obtaining enough venom from snakes is a major obstacle. Secretory cells of venom glands are capable of producing active toxins. Therefore, a culture of secretory cells is a good in vitro system to acquire the venom of snakes without capturing the animal from the wild. The protocol described here provides a rapid (approximately 4 h) and reproducible means of producing sufficient amounts of snake venom for biological investigations.     

Ultrastructural and histochemical study of collagen fibres types I and III in the venom gland of Bothrops jararaca during secretory cycle

Fragments of snake (Bothrops jararaca) venom gland were analysed by light and transmission electron microscopy in order to characterize the changes in collagen fibres types I and III in the intertubular gland septa during the secretory cycle. The snakes were sacrificed at 45 days (unmilked group), 6 h, 4 and 8 days after manual extraction of the venom. The fragments were fixed, processed according to standard histologic technique for embedding in paraffin, and stained with haematoxylin-eosin and Gomori's trichrome and submitted to Gomori's silver impregnation technique and picrosirius-polarization method. For transmission electron microscopy the fragments were fixed and processed for embedding in Spurr's medium. At the 45th day (the gland at rest), when the secretory activity was at a minimum, the septa were narrow and filled with densely packed collagen fibrils. At 6 h, the septa were enlarged and exhibited wide spaces filled with finely granular Alcian Blue-positive material. Until the 8th day, the septa were narrower and the histologic aspect resembled that of the gland at rest. The results demonstrated structural modifications in the glandular septa according to the different periods of the secretory cycle. These modifications can be associated with the transformation in the secretory epithelium during the venom synthesis cycle.     

Intracellular transport of proteins in active and resting secretory cells of the venom gland of Vipera palaestinae

The intracellular transport of venom proteins has been studied in active and resting venom glands of the snake Vipera palaestinae by electron microscope radioautography after an intra-arterial injection of [3H]leucine. In the active gland, most of the label is initially (10 min) found over the RER. By 30 min, the relative grain density of the Golgi complex reaches its maximum, with concomitant increase in the labeling of the condensing vacuoles. Later on, a steep increase in radioactivity of the secretory granules is observed. At 3 h, these granules, which comprise about 2% of the cell volume, contain 22% of the total grains. At the following hour, their labeling declines and at the same time the radioactivity of the secreted venom is increased. It is concluded that, in the active cell, venom proteins are transported via the Golgi apparatus into membrane-bounded granules which are the immediate source of the secreted venom. An alternative pathway, which involves the RER cisternae as a storage compartment, seems unlikely, since incorporated label does not accumulate in this compartment after prolonged postpulse intervals. The route of intracellular transport of proteins in the resting glands is similar to that of the active ones, but the rate of synthesis and transport is much slower. The present results and earlier data, thus, show that the increase in the rate of secretion after initiation of a new venom regeneration cycle is the result of accelerated rates of both synthesis and transport.     

Morphology and ultrastructure of a secretory region enclosed by the venom reservoir in social wasps (Insecta,Hymenoptera)

The morphology and ultrastructure of the convoluted gland inside the venom reservoir of four species of social Vespidae are described. The cells of the venom gland (including the convoluted gland) can be divided into six groups: (1) epithelial cells, (2) glandular cells with the end apparatus secreting into the tubule inside the convoluted gland (internal or embedded tubule), (3) a continuous arrangement of glandular cells with the end apparatus secreting directly into the venom reservoir, (4) glandular cells that are loosely dispersed along the tubule lumen between the free tubules and the embedded tubule of the convoluted gland, (5) secretory cells of the free tubules and (6) duct cells. One kind of secretory cell, hitherto unknown and described in this paper (group 3), is characterized by the presence of a well-developed end apparatus, usually with enlarged extracellular spaces, but lacking the normally associated duct cells. The secretory cells contain several stacks of granular endoplasmic reticulum, but these are mainly concentrated in the middle of the cell. The basal half of the cells contains many lipid droplets. Although the function of the convoluted gland is not yet understood, an hypothesis is related to what is known of the function of reservoir secretory cells in solitary wasps. All wasp species studied showed the same organization of the convoluted gland, which clearly distinguishes their venom gland from that of Sphecidae.     

Ultrastructure of the venom gland of the scorpion,Centruroides sculpturatus (Ewing)

The venom apparatus of the scorpion, C. sculpturatus (Ewing) was studied with light and electron microscopy. Each of the paired glands is lined by secretory epithelium made up of a single layer of columnar cells. Extensive folding in the epithelial layer creates a primitive acinar gland. The secretory products are either membrane-bound or unbound vesicles with discrete morphologies and are observed in the extruded venom, within the lumen of the gland, and within single secretory cells. The venom apparatus, including connective tissues, nerve cells, and muscle tunic is described and correlations are made with observations in other Athropods.     

Morphology and ultrastructure of the venom glands of the northern pacific rattlesnake Crotalus viridis oreganus

The venom gland of Crotalus viridis oreganus is composed of two discrete secretory regions: a small anterior portion, the accessory gland, and a much larger main gland. These two glands are joined by a short primary duct consisting of simple columnar secretory cells and basal horizontal cells. The main gland has at least four morphologically distinct cell types: secretory cells, the dominant cell of the gland, mitochondria-rich cells, horizontal cells, and “dark” cells. Scanning electron microscopy shows that the mitochondria-rich cells are recessed into pits of varying depth; these cells do not secrete. Horizontal cells may serve as secretory stem cells, and “dark” cells may be myoepithelial cells. The accessory gland contains at least six distinct cell types: mucosecretory cells with large mucous granules, mitochondria-rich cells with apical vesicles, mitochondria-rich cells with electron-dense secretory granules, mitochondria-rich cells with numerous cilia, horizontal cells, and “dark” cells. Mitochondria-rich cells with apical vesicles or cilia cover much of the apical surface of mucosecretory cells and these three cell types are found in the anterior distal tubules of the accessory gland. The posterior regions of the accessory gland lack mucosecretory cells and do not appear to secrete. Ciliated cells have not been noted previously in snake venom glands. Release of secretory products (venom) into the lumen of the main gland is by exocytosis of granules and by release of intact membrane-bound vesicles. Following venom extraction, main gland secretory and mitochondria-rich cells increase in height, and protein synthesis (as suggested by rough endoplasmic reticulum proliferation) increases dramatically. No new cell types or alterations in morphology were noted among glands taken from either adult or juvenile snakes, even though the venom of each is quite distinct. In general, the glands of C. v. oreganus share structural similarities with those of crotalids and viperids previously described.     

Comparing the secretory pathway in honeybee venom and hypopharyngeal glands

We provide insights into the secretory pathway of arthropod gland systems by comparing the royal jelly-producing hypopharyngeal glands and the venom-producing glands of the honeybee, Apis mellifera. These glands have different functions and different product release characteristics, but both belong to the class 3 types of insect glands, each being composed of two cells, a secretory cell and a microduct-forming cell. The hypopharyngeal secretory cells possess an extremely elongate tubular invagination that is filled with a cuticular structure, the end-apparatus, anchored against the cell membrane by a conspicuous series of actin rings. In contrast, venom glands have no actin rings, but instead have an actin-rich brush border surrounding the comparatively short and narrow end-apparatus. We relate these cytoskeletal differences to the production system and utilisation of secretions; venom is stored in a reservoir whereas royal jelly and enzymes are produced on demand. Fluorescence-based characterisation of the actin cytoskeleton combined with scanning electron microscopy of the end-apparatus allows for detailed characterisation of the point of secretion release in insect class 3 glands.     

Venom apparatus of the Brazilian tarantula <Emphasis Type="Italic">Vitalius dubius</Emphasis> Mello-Leitão 1923 (Theraphosidae)

Tarantula venoms are a cocktail of proteins and peptides that have been increasingly studied in recent years. In contrast, less attention has been given to analyzing the structure of the paired cephalic glands that produce the venom. We have used light, electron, and confocal microscopy to study the organization and structure of the venom gland of the Brazilian tarantula Vitalius dubius. The chelicerae are hairy chitinous structures, each with a single curved hollow fang that opens via an orifice on the anterior surface. Internally, each chelicera contains striated muscle fiber bundles that control fang extension and retraction, and a cylindrical conical venom gland surrounded by a thick well-developed layer of obliquely arranged muscle fibers. Light microscopy of longitudinal and transverse sections showed that the gland secretory epithelium consists of a sponge-like network of slender epithelial cell processes with numerous bridges and interconnections that form lacunae containing secretion. This secretory epithelium is supported by a basement membrane containing elastic fibers. The entire epithelial structure of the venom-secreting cells is reinforced by a dense network of F-actin intermediate filaments, as shown by staining with phalloidin. Neural elements (axons and acetylcholinesterase activity) are also associated with the venom gland. Transmission electron microscopy of the epithelium revealed an ultrastructure typical of secretory cells, including abundant rough and smooth endoplasmic reticulum, an extensive Golgi apparatus, and numerous mitochondria.     

Venom gland of the digger wasp Liris niger: morphology, ultrastructure, age-related changes and biochemical aspects

Females of the parasitoid digger wasp species Liris niger hunt crickets as food for their future brood. The wasps paralyse the prey by injecting their venom directly into the CNS. The venom is produced in a gland consisting of two ramified glandular tubules terminating in a common reservoir. The reservoir contents enter the sting bulb via a ductus venatus. Secretory units of dermal gland type III line the two free gland tubules, the afferent ducts to the reservoir and the cap region within the reservoir. Secretion products of tubules reach the reservoir through the cuticle-lined central funnel. Secretory cells in the distal and middle parts of the tubules contain extensive rough endoplasmic reticulum and numerous electron-dense vesicles, whereas secretory cells of the afferent ducts and the cap region of the reservoir lack electron-dense vesicles and the endoplasmic reticulum is poorly developed. The secretory apparatus undergoes age-related changes. The secretory units in the venom gland tubules and inside the reservoir complete differentiation 1 day after imaginal ecdysis. After 30 days, massive autolytic processes occur in the secretory cells and in the epithelial cells of the reservoir. Analysis of the polypeptide composition demonstrates that the venom reservoir contains numerous proteins ranging from 3.4 to 200 kDa. A dominant component is a glycoprotein of about 90 kDa. In contrast the polypeptide composition of Dufour's gland is completely different and contains no glycoproteins. Comparison of the venom reservoir contents with the polypeptide pattern of venom droplets reveals that all of the major proteinaceous constituents become secreted. Thus the secreted venom contains exclusively proteins present in the soluble contents of the venom gland.     

Cytochemical analysis of acid phosphatase activity in the venom secretory cells of Bothrops jararaca

A study of the histochemical reaction for acid phosphatase (AcPase) in venom gland secretory cells from Bothrops jararaca was done to investigate the distribution of lysosomes and related structures in stages of high- and low-protein synthesis. From this analysis, it was expected to gain insight into the cellular pathway by which AcPase is secreted into the venom. Two subtypes of AcPase reactivities were detected in the venom gland secretory cells: one was found in lysosomes and related structures and in some trans-Golgi network (TGN) elements and reacts with beta-glycerophosphate (betaGP) as substrate; the other was found in secretory vesicles, apical plasmalemma, lysosomes and related structures, and in some TGN elements, and reacts with cytidine monophosphate (CMP). The results are compatible with the possibility that there is a secretory via for AcPase in the venom gland of B. jararaca and that the elements composing this pathway are noted only when CMP is used as substrate. Large autophagosomes reactive to both betaGP and to CMP were commonly observed in the basal region of the secretory cells, and they were more abundant in the glands during the stage of low activity of protein synthesis.