动物唾液腺的机能结构

凡腺体排空于消化管前的即为唾液腺。按此定义,无脊椎动物与脊椎动物中都有着结构和功能各异的唾液腺。 (一)无脊椎动物的唾液腺在环节动物、软体动物(除双壳纲)、节肢动物等都有唾液腺。如蚯蚓咽部背、腹侧有软的、白的小叶片,乃由很多嗜铬细胞构成,细胞间有小沟(管)。其分泌液为粘液性,也含有纤维消化酶。节肢动物生活方式多种多样,而蜚蠊、蟑螂唾液中含淀粉酶,PH为6.9。松藻虫在每侧有一主腺和一副腺(图1和图2,)。主腺小的为     

捕食性蝽类唾液腺解剖方法—以叉角厉蝽为例

唾液腺的解剖是研究捕食性蝽类唾液成分及功能的关键。以叉角厉蝽Eocanthecona furcellata为例,报道了解剖获得其完整唾液腺的方法。该方法与其他解剖方法相比明显不同之处在于使用镊子固定虫体,更有利于唾液腺的解剖与收集。通过拍照观察,叉角厉蝽的唾液腺由主腺、副腺、肺门和导管组成。主腺可分为主腺前叶和主腺后叶,它们之间通过肺门相连。主腺肺门处着生有两根导管,其中一根导管与口器相连,而另一根导管与副腺连接。本文描述的解剖方法以及叉角厉蝽唾液腺形态结构可用于指导解剖获得其它捕食性蝽类的唾液腺,进而提取唾液开展成分鉴定和功能研究。     

石磺消化系统的组织学观察

对石磺消化系统各部分结构进行组织学观察.石磺的消化系统由消化道和消化腺两部分组成.消化道包括口、食道、贲门胃、幽门胃、中肠和后肠,不具吻;消化腺包括肝胰腺、唾液腺和肛门腺.在光学显微镜下,消化道由粘膜层、粘膜下层、肌层和外膜4层组成;肌层主要为环肌,粘膜层主要为柱状细胞.肝胰腺甚为发达,组织结构显示肝胰腺由很多分支的腺管组成,腺管由腺细胞、分泌细胞等组成.唾液腺和肛门腺发达.     

香菇多糖对小鼠骨髓树突状细胞表型和功能的影响

通过研究香菇多糖(Lentinan,LNT)对小鼠骨髓源树突状细胞(bone marrow dendritic cells,BMDCs)功能调节的机制,进一步阐明香菇多糖的免疫活性。本实验将BMDCs分成脂多糖(LPS)阳性对照组、LNT处理组和RPMI1640空白对照组,应用酸性磷酸酶活性检测、流式细胞仪检测技术、吞噬实验、酶联免疫吸附试验检测各组BMDCs表型和功能的各种指标。结果显示,LNT(50μg/mL)处理组BMDCs酸性磷酸酶活性降低;BMDCs吞噬能力比RPMI1640空白对照组明显下降;BMDCs表面MHCⅡ、CD40、CD83、CD80、CD86和DEC205的表达增加;BMDCs白细胞介素12(IL-12)、白细胞介素10(IL-10)和肿瘤坏死因子-α(TNF-α)的表达增加。证明了适宜浓度的LNT可以促进BMDCs表型及功能的成熟。     

O型谷胱甘肽转移酶1通过抑制泛素化促进MHCII表达

目的 研究谷胱甘肽转移酶omega1 (GSTO1)如何调控骨髓来源的树突状细胞（BMDCs）的功能。方法 利用流式细胞仪和共聚焦显微镜检测GSTO1缺陷及GSTO1抑制剂处理的BMDCs表面MHCII分子的表达。将BMDCs与来自OTII小鼠的CD4 T细胞在OVA存在下共培养，并检测IFN-γ的产生。利用流式细胞仪检测GSTO1抑制剂处理的BMDCs中MHCII分子的循环和内化。实时定量PCR检测GSTO1抑制剂处理的BMDCs中MHCII分子的转录水平。Western blot检测GSTO1抑制剂处理的BMDCs中MHCII分子的总蛋白质水平。免疫共沉淀技术检测GSTO1抑制剂处理后MHCII分子的泛素化水平。结果 GSTO1缺陷或GSTO1抑制剂不影响BMDCs的增殖和凋亡，但会降低细胞膜上抗原递呈分子MHCII分子的表达。GSTO1缺陷或GSTO1抑制剂处理的BMDCs活化CD4 T细胞的能力受损。在GSTO1抑制剂处理的BMDCs中，MHCII分子的循环和内化过程正常。GSTO1抑制剂不影响MHCII分子的转录，但会降低其总蛋白质水平。另外，在GSTO1抑制剂处理的BMDC...     

利用假型反转录病毒对大部分胰腺切除后再生细胞的世系追踪

胰腺是一个重要的内外分泌混合腺, 胰腺发生损伤后能够再生。为了探讨胰腺活体细胞世系追踪的方法和胰腺损伤后再生细胞的来源,分别通过胰腺伤口涂抹并胰内注射、尾静脉注射及腹腔注射三种方法, 利用假型反转录病毒对成体小鼠大部分切除后胰腺的细胞进行世系追踪。结果发现在活体条件下, 与尾静脉注射及腹腔注射法相比, 胰腺伤口涂抹并胰腺内注射反转录病毒的方法能够更有效的标记胰腺细胞; 而且, 通过对标记细胞的世系追踪研究证明, 在胰腺损伤后, 胰腺腺泡细胞能够接受损伤信号刺激发生再生。为今后进一步利用反转录假病毒对活体胰腺进行细胞命运追踪研究奠定基础, 为利用反转录病毒载体进行胰腺疾病的基因治疗提供线索。     

利用假型反转录病毒对大部分胰腺切除后再生细胞的世系追踪

胰腺是一个重要的内外分泌混合腺, 胰腺发生损伤后能够再生。为了探讨胰腺活体细胞世系追踪的方法和胰腺损伤后再生细胞的来源,分别通过胰腺伤口涂抹并胰内注射、尾静脉注射及腹腔注射三种方法, 利用假型反转录病毒对成体小鼠大部分切除后胰腺的细胞进行世系追踪。结果发现在活体条件下, 与尾静脉注射及腹腔注射法相比, 胰腺伤口涂抹并胰腺内注射反转录病毒的方法能够更有效的标记胰腺细胞; 而且, 通过对标记细胞的世系追踪研究证明, 在胰腺损伤后, 胰腺腺泡细胞能够接受损伤信号刺激发生再生。为今后进一步利用反转录假病毒对活体胰腺进行细胞命运追踪研究奠定基础, 为利用反转录病毒载体进行胰腺疾病的基因治疗提供线索。     

SD大鼠和Beagle犬大唾液腺的形态学观察

目的-研究及观察SD大鼠和Beagle犬大唾液腺正常比较组织学.方法-SD大鼠和Beagle犬三对大唾液腺剖取后进行石蜡切片、HE染色和PAS染色,光学显微镜观察.结果-SD大鼠腮腺是纯浆液腺,Beagle犬腮腺属混合腺,以浆液性腺泡为主,偶见小的粘液细胞群.SD大鼠的下颌下腺属于以浆液腺泡为主的混合腺,Beagle犬的下颌下腺属于以粘液腺泡为主的混合腺.SD大鼠与Beagle犬的舌下腺均为粘液性腺泡为主的混合腺.Beagle犬的眶腺亦是以纯粘液性腺泡为主的混合腺结构.     

敲除PKCδ引起舍格伦综合征样的颌下腺功能低下

舍格伦综合征(Sjgren's syndrome)是一种自身免疫性疾病,主要特征为淋巴细胞浸润唾液腺和泪腺,表现为眼干和口干等外分泌腺功能障碍。T细胞是浸润唾液腺的主要淋巴细胞,其介导的自身免疫反应在舍格伦综合征的发病机制中起关键作用。然而新近的研究表明,B细胞的功能异常在舍格伦综合征的发病过程中也起重要的作用。PKCδ在体内广泛表达,对于B细胞耐受的建立至关重要,是调控细胞凋亡的关键分子。但是,抑制PKCδ对唾液腺结构与功能的影响尚不清楚。     

水包油佐剂对小鼠骨髓来源树突状细胞蛋白表达的影响

目的 探索未成熟的小鼠骨髓来源树突状细胞(bone marrow derived dendritic cells,BMDCs)的分离诱导培养方法,并研究水包油佐剂对BMDCs蛋白表达的影响.方法 解剖小鼠获得小鼠骨髓细胞,分析在骨髓细胞诱导培养获得未成熟的BMDCs的过程中,红细胞裂解液(red blood cell ...     

Bone marrow-derived cells: A potential approach for the treatment of xerostomia

Transplantations of bone marrow-derived cells (BMDCs) are traditionally used for hematologic diseases, but there are increasing numbers of clinical trials using BMDC treatments for non-hematologic disorders, including autoimmune diseases. BMDCs are recently reported to improve organ functions. This paper will review available reports supporting the role of BMDCs in reducing xerostomia (i.e. re-establishing salivary gland functions) due to head and neck irradiation for cancer therapies and in Sj?gren's syndrome. There are reports that BMDCs provide a beneficial effect on the saliva production. BMDCs positively affect blood vessels stability and regeneration in irradiated salivary glands. Also, BMDCs provide an immunomodulatory activity in mice with Sj?gren's-like disease. While the exact mechanisms by which BMDCs improve organ functions remain controversial, there is preliminary evidence that a combination of them (such as cell transdifferentiation, vasculogenesis, and paracrine effect) occur in salivary glands.     

SPM Receptor Expression and Localization in Irradiated Salivary Glands

Radiation therapy–mediated salivary gland destruction is characterized by increased inflammatory cell infiltration and fibrosis, both of which ultimately lead to salivary gland hypofunction. However, current treatments (e.g., artificial saliva and sialagogues) only promote temporary relief of symptoms. As such, developing alternative measures against radiation damage is critical for restoring salivary gland structure and function. One promising option for managing radiation therapy–mediated damage in salivary glands is by activation of specialized proresolving lipid mediator receptors due to their demonstrated role in resolution of inflammation and fibrosis in many tissues. Nonetheless, little is known about the presence and function of these receptors in healthy and/or irradiated salivary glands. Therefore, the goal of this study was to detect whether these specialized proresolving lipid mediator receptors are expressed in healthy salivary glands and, if so, if they are maintained after radiation therapy–mediated damage. Our results indicate that specialized proresolving lipid mediator receptors are heterogeneously expressed in inflammatory as well as in acinar and ductal cells within human submandibular glands and that their expression persists after radiation therapy. These findings suggest that epithelial cells as well as resident immune cells represent potential targets for modulation of resolution of inflammation and fibrosis in irradiated salivary glands.     

Bone marrow-derived cells rescue salivary gland function in mice with head and neck irradiation

Treatment for most patients with head and neck cancers includes ionizing radiation. A consequence of this treatment is irreversible damage to salivary glands (SGs), which is accompanied by a loss of fluid-secreting acinar-cells and a considerable decrease of saliva output. While there are currently no adequate conventional treatments for this condition, cell-based therapies are receiving increasing attention to regenerate SGs. In this study, we investigated whether bone marrow-derived cells (BMDCs) can differentiate into salivary epithelial cells and restore SG function in head and neck irradiated mice. BMDCs from male mice were transplanted into the tail-vein of 18Gy-irradiated female mice. Salivary output was increased in mice that received BMDCs transplantation at week 8 and 24 post-irradiation. At 24 weeks after irradiation (IR), harvested SGs (submandibular and parotid glands) of BMDC-treated mice had greater weights than those of non-treated mice. Histological analysis shows that SGs of treated mice demonstrated an increased level of tissue regenerative activity such as blood vessel formation and cell proliferation, while apoptotic activity was increased in non-transplanted mice. The expression of stem cell markers (Sca-1 or c-kit) was detected in BMDC-treated SGs. Finally, we detected an increased ratio of acinar-cell area and approximately 9% of Y-chromosome-positive (donor-derived) salivary epithelial cells in BMDC-treated mice. We propose here that cell therapy using BMDCs can rescue the functional damage of irradiated SGs by direct differentiation of donor BMDCs into salivary epithelial cells.     

Pharmacological Activation of the EDA/EDAR Signaling Pathway Restores Salivary Gland Function following Radiation-Induced Damage

Radiotherapy of head and neck cancers often results in collateral damage to adjacent salivary glands associated with clinically significant hyposalivation and xerostomia. Due to the reduced capacity of salivary glands to regenerate, hyposalivation is treated by substitution with artificial saliva, rather than through functional restoration of the glands. During embryogenesis, the ectodysplasin/ectodysplasin receptor (EDA/EDAR) signaling pathway is a critical element in the development and growth of salivary glands. We have assessed the effects of pharmacological activation of this pathway in a mouse model of radiation-induced salivary gland dysfunction. We report that post-irradiation administration of an EDAR-agonist monoclonal antibody (mAbEDAR1) normalizes function of radiation damaged adult salivary glands as determined by stimulated salivary flow rates. In addition, salivary gland structure and homeostasis is restored to pre-irradiation levels. These results suggest that transient activation of pathways involved in salivary gland development could facilitate regeneration and restoration of function following damage.     

Sox9+ cells are required for salivary gland regeneration after radiation damage via the Wnt/β-catenin pathway

Radiotherapy for head and neck cancer can cause serious side effects, including severe damage to the salivary glands, resulting in symptoms such as xerostomia, dental caries, and oral infection. Because of the lack of long-term treatment for the symptoms of xerostomia, current research has focused on finding endogenous stem cells that can differentiate into various cell lineages to replace lost tissues and restore functions. Here, we report that Sox9⁺ cells can differentiate into various salivary epithelial cell lineages under homeostatic conditions. After ablating Sox9⁺ cells, the salivary glands of irradiated mice showed more severe phenotypes and the reduced proliferative capacity. Analysis of online single-cell RNA-sequencing data reveals the enrichment of the Wnt/β-catenin pathway in the Sox9⁺ cell population. Furthermore, treatment with a Wnt/β-catenin inhibitor in irradiated mice inhibits the regenerative capability of Sox9⁺ cells. Finally, we show that Sox9⁺ cells are capable of forming organoids in vitro and that transplanting these organoids into salivary glands after radiation partially restored salivary gland functions. These results suggest that regenerative therapy targeting Sox9⁺ cells is a promising approach to treat radiation-induced salivary gland injury.     

Pro-apoptotic gene knockdown mediated by nanocomplexed siRNA reduces radiation damage in primary salivary gland cultures

A critical issue in the management of head and neck tumors is radioprotection of the salivary glands. We have investigated whether siRNA-mediated gene knock down of pro-apoptotic mediators can reduce radiation-induced cellular apoptosis in salivary gland cells in vitro. We used novel, pH-responsive nanoparticles to deliver functionally active siRNAs into cultures of salivary gland cells. The nanoparticle molecules are comprised of cationic micelles that electrostatically interact with the siRNA, protecting it from nuclease attack, and also include pH-responsive endosomolytic constituents that promote release of the siRNA into the target cell cytoplasm. Transfection controls with Cy3-tagged siRNA/nanoparticle complexes showed efficiently internalized siRNAs in more than 70% of the submandibular gland cells. We found that introduction of siRNAs specifically targeting the Pkcδ or Bax genes significantly blocked the induction of these pro-apoptotic proteins that normally occurs after radiation in cultured salivary gland cells. Furthermore, the level of cell death from subsequent radiation, as measured by caspase-3, TUNEL, and mitochondrial disruption assays, was significantly decreased. Thus, we have successfully demonstrated that the siRNA/nanoparticle-mediated knock down of pro-apoptotic genes can prevent radiation-induced damage in submandibular gland primary cell cultures.     

On approaches to the functional restoration of salivary glands damaged by radiation therapy for head and neck cancer,with a review of related aspects of salivary gland morphology and development

Radiation therapy for cancer of the head and neck can devastate the salivary glands and partially devitalize the mandible and maxilla. As a result, saliva production is drastically reduced and its quality adversely altered. Without diligent home and professional care, the teeth are subject to rapid destruction by caries, necessitating extractions with attendant high risk of necrosis of the supporting bone. Innovative techniques in delivery of radiation therapy and administration of drugs that selectively protect normal tissues can reduce significantly the radiation effects on salivary glands. Nonetheless, many patients still suffer severe oral dryness. I review here the functional morphology and development of salivary glands as these relate to approaches to preventing and restoring radiation-induced loss of salivary function. The acinar cells are responsible for most of the fluid and organic material in saliva, while the larger ducts influence the inorganic content. A central theme of this review is the extent to which the several types of epithelial cells in salivary glands may be pluripotential and the circumstances that may influence their ability to replace cells that have been lost or functionally inactivated due to the effects of radiation. The evidence suggests that the highly differentiated cells of the acini and large ducts of mature glands can replace themselves except when the respective pools of available cells are greatly diminished via apoptosis or necrosis owing to severely stressful events. Under the latter circumstances, relatively undifferentiated cells in the intercalated ducts proliferate and redifferentiate as may be required to replenish the depleted pools. It is likely that some, if not many, acinar cells may de-differentiate into intercalated duct-like cells and thus add to the pool of progenitor cells in such situations. If the stress is heavy doses of radiation, however, the result is not only the death of acinar cells, but also a marked decline in functional differentiation and proliferative capacity of all of the surviving cells, including those with progenitor capability. Restoration of gland function, therefore, seems to require increasing the secretory capacity of the surviving cells, or replacing the acinar cells and their progenitors either in the existing gland remnants or with artificial glands.     

Gene Expression Analysis Reveals Inhibition of Radiation-Induced TGFβ-Signaling by Hyperbaric Oxygen Therapy in Mouse Salivary Glands

A side effect of radiation therapy in the head and neck region is injury to surrounding healthy tissues such as irreversible impaired function of the salivary glands. Hyperbaric oxygen therapy (HBOT) is clinically used to treat radiation-induced damage but its mechanism of action is largely unknown. In this study, we investigated the molecular pathways that are affected by HBOT in mouse salivary glands two weeks after radiation therapy by microarray analysis. Interestingly, HBOT led to significant attenuation of the radiation-induced expression of a set of genes and upstream regulators that are involved in processes such as fibrosis and tissue regeneration. Our data suggest that the TGFβ-pathway, which is involved in radiation-induced fibrosis and chronic loss of function after radiation therapy, is affected by HBOT. On the longer term, HBOT reduced the expression of the fibrosis-associated factor α-smooth muscle actin in irradiated salivary glands. This study highlights the potential of HBOT to inhibit the TGFβ-pathway in irradiated salivary glands and to restrain consequential radiation induced tissue injury.     

Rescue of salivary gland function after stem cell transplantation in irradiated glands

Head and neck cancer is the fifth most common malignancy and accounts for 3% of all new cancer cases each year. Despite relatively high survival rates, the quality of life of these patients is severely compromised because of radiation-induced impairment of salivary gland function and consequential xerostomia (dry mouth syndrome). In this study, a clinically applicable method for the restoration of radiation-impaired salivary gland function using salivary gland stem cell transplantation was developed. Salivary gland cells were isolated from murine submandibular glands and cultured in vitro as salispheres, which contained cells expressing the stem cell markers Sca-1, c-Kit and Musashi-1. In vitro, the cells differentiated into salivary gland duct cells and mucin and amylase producing acinar cells. Stem cell enrichment was performed by flow cytrometric selection using c-Kit as a marker. In vitro, the cells differentiated into amylase producing acinar cells. In vivo, intra-glandular transplantation of a small number of c-Kit(+) cells resulted in long-term restoration of salivary gland morphology and function. Moreover, donor-derived stem cells could be isolated from primary recipients, cultured as secondary spheres and after re-transplantation ameliorate radiation damage. Our approach is the first proof for the potential use of stem cell transplantation to functionally rescue salivary gland deficiency.     

Possible role of nitric oxide in radiation-induced salivary gland dysfunction

In this study, we developed a murine model of xerostomia to elucidate the mechanism of radiation-induced salivary gland dysfunction and determined the levels of nitric oxide (NO) in the salivary glands to assess its involvement in the salivary dysfunction induced by radiation. In addition, an inhibitor of NO synthesis was administered to the model in vivo, and its effect on saliva secretion was investigated. Salivary gland irradiation at a dose of 15 Gy caused a significant decrease in secretion compared to unirradiated salivary glands. There were no marked differences between the irradiated mice and unirradiated mice in water or food consumption or in body weight changes. The NO levels in the cultured salivary gland epithelial cells were increased by treatment with a combination of interferon gamma (Ifng), interleukin 1-beta (Il1b), and tumor necrosis factor alpha (Tnfa). Irradiation increased the NO level in the salivary gland tissue. The presence of N(G)-monomethyl-l-arginine acetate (l-NMMA), an inhibitor of NO synthesis, caused a decrease in the NO level in cultured salivary gland tissues after irradiation. Administration of l-NMMA to irradiated mice improved saliva secretion. These results suggest that excessive production of NO induced by radiation is involved in the formation of radiation-induced xerostomia. The finding that administration of an inhibitor of NO synthesis ameliorated the dysfunction of irradiated salivary glands indicates that NO plays a role as a mediator of the dry mouth symptoms that occur after irradiation.