群体感应(QS)在牙菌斑形成中的研究进展

形成牙菌斑的生物膜中存在大量微生物,各种微生物通过高丝氨酸内酯(AHL)或寡肽等不同的信号分子产生群体感应(QS),形成的群体感应使各种微生物建立了区系平衡,对龋齿及牙周炎等口腔疾病的治疗产生严重影响。因组成生物膜的各种微生物对抗生素的敏感性和耐受性有显著差异,因此在治疗中增加了对宿主免疫的相应要求。为进一步探讨QS系统在牙菌斑形成中的作用特点,本文就牙菌斑的形成与抗药机制、群体感应系统及其信号分子、群体感应系统的抑制因子和研究展望进行综述。     

口腔乳酸杆菌的分离及其益生特性

[目的]从口腔环境中筛选具有潜在益生特性的乳酸杆菌,用于防治口腔疾病的益生菌疗法.[方法]利用选择性培养基从健康志愿者的唾液和牙菌斑样品中筛选得到乳酸杆菌,然后验证他们对龋齿致病菌变异链球菌生长的抑制作用.同时考察分离得到的微生物是否具有可以定植或在口腔环境中生存的特性.[结果]本研究从牙菌斑样品中分离得到一株发酵乳杆菌Y29.该菌能够抑制变异链球菌的生长,并有自聚集和与其他口腔微生物共聚集形成生物膜的能力.此外,发酵乳杆菌Y29可耐受1.0 mg/mL溶菌酶和140μg/g过氧化氢,有利于其在可能含有多种抑菌物质的口腔动态环境中生存.[结论]发酵乳杆菌Y29在防治龋齿和保证口腔健康方面具有潜在的益生特性.     

益生菌与口腔微生态调控的研究进展

口腔疾病的发生和发展与口腔微生物群落的失衡密切相关。益生菌是一类对人体健康有益的活的微生物,主要通过分泌抗菌物质、与致病菌竞争性定殖、调节毒力相关基因表达、调节宿主免疫反应、调节氧化应激反应、参与硝酸盐—亚硝酸盐—一氧化氮代谢循环通路、调整生物膜pH值等过程发挥其益生效能。研究发现,益生菌疗法能够降低龋齿的风险、改善牙周状况、提高口腔黏膜病的治疗效果,有望成为防治口腔疾病的潜在途径。本文就近年来益生菌与口腔微生态调控相关的研究情况做一综述。     

链球菌-韦荣菌共生对系统性疾病的诊断价值研究

口腔是人体生理功能的窗口,也是种类和数量繁多的微生物库.口腔微生态变化能够反映宿主与环境因素的相互作用,进而影响机体健康和疾病的进展.其中,链球菌属(Streptococcus)和韦荣菌属(Veillonella)是口腔最早的定殖菌和典型共生菌,共同参与口腔早期生物膜形成.大量研究显示,链球菌和韦荣菌共生失调不仅与龋病...     

大蒜素抗变异链球菌的致龋效果

目的研究大蒜素对口腔变异链球菌生长及其菌斑生物膜粘附的抑制作用。方法二倍稀释法梯度稀释测最小抑菌浓度(minimum inhibitory concentration,MIC),将MIC以上2个梯度浓度对应的培养物涂布于BHI培养基上进行次代培养获得最低杀菌浓度(minimum bactericidal concentration,MBC);酶标仪测A值观察不同浓度大蒜素抑菌效应;抑制产酸试验观察抑制细菌产酸效应;结晶紫法研究亚抑菌浓度提取物对变异链球菌粘附能力及生物膜总量的影响;采用激光共聚焦荧光显微镜(laser scanning confocal microscopy,LSCM)观察常态牙菌斑生物膜生长过程中及药物处理后牙菌斑生物膜中死菌和活菌的构成,研究其对牙菌斑生物膜结构和活性的影响。结果抑菌试验中,得到大蒜素MIC为12.8 mg/L,MBC为25.8 mg/L。MIC及亚抑菌浓度抑菌试验显示均有一定的抑菌性,抑制率为2.17%～67.12%,并且抑菌性与浓度梯度成正相关。产酸试验显示24 h内大蒜素明显抑制细菌产酸(P0.01),细菌粘附试验结果显示大蒜素在MIC时生物膜的生成速度最慢,生物膜的总量最低(P0.01)。共聚焦荧光显微镜可见大蒜素组随药物浓度增加,菌斑生物膜较薄,绿色的活菌及团块明显减少,抑制生物膜的生长。结论大蒜素对变异链球菌生长、产酸与粘附有一定抑制作用。     

口腔种植材料表面特性与生物膜形成研究进展

人类口腔环境为微生物提供了适宜生存的条件,多种微生物在牙齿表面形成了由基质包裹相互粘附的口腔生物膜,口腔生物膜是口腔微生物生存、代谢和致病的基础。随着1965年Brnemark种植体在临床上的成功应用,种植相关材料周围致病菌导致的种植体周围炎成为种植修复最常见的并发症之一,影响种植修复的远期效果。种植体周围炎引起了许多关注,并且口腔种植材料表面的特性和口腔生物膜的形成密切相关。本文就种植材料及天然牙齿表面的生物膜形成、种植材料表面特性对口腔生物膜及细菌粘附的影响因素、增强种植材料抗菌性能的方法以及未来的研究方向等作一综述。     

细菌生物膜与龋齿相关性的研究进展

牙菌斑是由多种微生物在牙面上沉积,有机基质互相集聚、交联而形成的生物膜结构,生物膜中微生物相互依存、相互竞争,构成了复杂的微生态关系。牙菌斑生物膜的形成是导致龋齿重要过程。本文综述了细菌生物膜与龋齿发生的关系,以期为龋齿的预防与治疗提供新的思路。     

低龄儿童龋病牙菌斑的菌群结构分析

目的通过低龄龋齿儿童与口腔健康儿童的微生物组检测,探讨低龄儿童龋病牙菌斑的菌群组成特征。方法在深圳地区招募轻度龋齿、重度龋齿及口腔健康儿童共100名,采集其牙菌斑或健康牙齿表面微生物样本,采用MiSeq测序平台进行16S V4-V5区域的高通量测序。同时,通过生物信息分析方法,对低龄龋齿儿童的牙菌斑的微生物组成的特征进行挖掘分析。结果相对口腔健康儿童,重度龋齿患儿的牙菌斑微生物多样性增加,轻度龋齿患儿则减少,但变化不显著。门水平的优势菌主要为放线菌门、变形菌门及拟杆菌门,虽有相对丰度变化但差异无统计学意义。前10位的优势菌属中,轻度及重度龋齿儿童的最高丰度优势菌属为棒状杆菌属,重度龋齿儿童与健康儿童中的棒状杆菌丰度差异有统计学意义(t=-2.195 5, P=0.028 1)。健康儿童口腔的优势菌属包含了卟啉单胞菌属,但在轻度及重度龋齿儿童的优势菌属则替换为月形单胞菌属。种水平的菌群结构分析显示,前10位的优势菌丰度变化差异无统计学意义,而低丰度的致病菌如变异链球菌(H=27.302 1, P<0.000 1)、Atopobium parvulum(H=17.418 2, P=0.000 2)、栖牙普氏菌(H=10.598 9, P=0.005 0)、唾液普氏菌(H=10.035 0, P=0.006 6)等则在重度龋齿儿童中显著富集。结论低龄龋齿儿童的牙菌斑微生物结构发生了改变,部分口腔有害菌的丰度显著增加与龋病严重程度密切相关。     

微生物生物膜研究的新进展

微生物在生长过程中为适应生存环境而形成了生物膜,Dr.Costerton JW在生物膜方面的研究为我们开拓了微生物学的新领域。微生物生物膜是由微生物群体及其包被的细胞外多聚物和基质网组成,它们彼此黏附或者黏附到组织或物体的表面。微生物生物膜与微生物的耐药性形成、基因的转移以及引起机体的持续性感染等都密切相关。目前对生物膜的研究重点已经深入到微生物相互间的信号传递、致病基因的转移以及如何干预微生物生物膜的形成等方面。此外,在治理污水和环境保护工程、生物材料工程和食品工业等方面,微生物生物膜技术已经得到了应用。     

荧光假单胞菌2P24中gidA基因对PcoI/PcoR群体感应系统的影响

【目的】荧光假单胞菌(Pseudomonas fluorescens)2P24中PcoI/PcoR群体感应系统是调控生物膜形成与植物根部定殖能力的重要元件,同时该系统也受到多种上游因子的调控。利用遗传学方法研究P.fluorescens 2P24中gidA基因对群体感应系统的调控作用。【方法】将群体感应信号合成基因pcoI的转录报告质粒p970km-pcoIp转入菌株2P24和gidA基因突变体中以检测gidA对pcoI基因表达的影响,并利用报告菌Agrobacterium tumefaciens NTL4(pZLR4)测定菌株2P24及其衍生菌的信号N-乙酰高丝氨酸内酯(AHL)产量。【结果】gidA基因突变后pcoI基因的转录表达和AHL产量与野生型2P24相比显著降低。gidA基因突变体的游动能力没有受到明显的影响,但生物膜的形成显著低于野生型和互补菌株。小麦根部定殖实验表明,温室条件下gidA突变菌株在灭菌土和自然土中对小麦根尖和根围的定殖量较野生型和互补菌显著减少。此外,突变gidA基因并不影响菌株在LB培养基中的生长,但以葡萄糖、蔗糖、果糖、甘油、半乳糖、阿拉伯糖、甘露糖、木糖或山梨醇为唯一碳源时,gidA突变体的生长受到明显的抑制。【结论】GidA对假单胞菌2P24中的PcoI/PcoR群体感应系统、生物膜形成、定殖和碳源利用具有显著的正调控作用。     

Die Mundhöhle als Ökosystem

Biomimetic approaches for the dental plaque control Tooth and gum diseases are widespread and are primarily based on the presence of bacterial biofilms. The characterization of biofilms can be carried out by means of state‐of‐the‐art microbiome analysis that can provide information on bacterial composition and diversity. Modern oral care products mostly contain different antimicrobial agents for biofilm control. These include chlorhexidine, metal salts, and quaternary ammonium compounds, which, however, often kill harmful (dysbiotic) and useful bacteria (homeostatic) (unspecific antimicrobial effect). Recent developments show that innovative concepts shift the ecological balance of plaque in the oral cavity to “physiological commensal bacteria” (homeostasis) or minimize the bacterial colonization on enamel surfaces without having pronounced antimicrobial properties. Examples are biomimetic approaches, i.e. based on selected salivary enzymes or hydroxyapatite.     

Comparison of the Phenotypes and Genotypes of Biofilm and Solitary Epiphytic Bacterial Populations on Broad-Leaved Endive

The discovery that biofilms are ubiquitous among the epiphytic microflora of leaves has prompted research about the impact of biofilms on the ecology of epiphytic microorganisms and on the efficiency of strategies to manage these populations for disease control and to ensure food safety. Biofilms are likely to influence the microenvironment and phenotype of the microorganisms they harbor. However, it is also important to determine whether there are differences in the types of bacteria within biofilms compared to those outside of biofilms so as to better target microorganisms via disease control strategies. Broad-leaved endive (Cichorium endivia var. latifolia) harbors biofilms containing fluorescent pseudomonads. These bacteria can cause considerable post-harvest losses when this plant is used for manufacturing minimally processed salads. To determine whether the population structure of the fluorescent pseudomonads in biofilms is different from that outside of biofilms on the same leaves, bacteria were isolated quantitatively from the biofilm and solitary components of the epiphytic population on leaves of field-grown broad-leaved endive. Population structure was determined in terms of taxonomic identities of the bacteria isolated, in terms of genotypic profiles, and in terms of phenotypic traits related to surface colonization and biofilm formation. The results illustrate that there are no systematic differences in the composition and structure of biofilm and solitary populations of fluorescent pseudomonads, in terms of either genotypic profiles or phenotypic profiles of the strains. However, Gram-positive bacteria tended to occur more frequently within biofilms than outside of biofilms. We suggest that leaf colonization by fluorescent pseudomonads involves a flux of cells between biofilm and solitary states. This would allow bacteria to exploit the advantages of these two types of existence; biofilms would favor resistance to stressful conditions, whereas solitary cells could foster spread of bacteria to newly colonizable sites on leaves as environmental conditions fluctuate.     

Tobacco smoke augments Porphyromonas gingivalis-Streptococcus gordonii biofilm formation

Smoking is responsible for the majority of periodontitis cases in the US and smokers are more susceptible than non-smokers to infection by the periodontal pathogen Porphyromonas gingivalis. P. gingivalis colonization of the oral cavity is dependent upon its interaction with other plaque bacteria, including Streptococcus gordonii. Microarray analysis suggested that exposure of P. gingivalis to cigarette smoke extract (CSE) increased the expression of the major fimbrial antigen (FimA), but not the minor fimbrial antigen (Mfa1). Therefore, we hypothesized that CSE promotes P. gingivalis-S. gordonii biofilm formation in a FimA-dependent manner. FimA total protein and cell surface expression were increased upon exposure to CSE whereas Mfa1 was unaffected. CSE exposure did not induce P. gingivalis auto-aggregation but did promote dual species biofilm formation, monitored by microcolony numbers and depth (both, p<0.05). Interestingly, P. gingivalis biofilms grown in the presence of CSE exhibited a lower pro-inflammatory capacity (TNF-α, IL-6) than control biofilms (both, p<0.01). CSE-exposed P. gingivalis bound more strongly to immobilized rGAPDH, the cognate FimA ligand on S. gordonii, than control biofilms (p<0.001) and did so in a dose-dependent manner. Nevertheless, a peptide representing the Mfa1 binding site on S. gordonii, SspB, completely inhibited dual species biofilm formation. Thus, CSE likely augments P. gingivalis biofilm formation by increasing FimA avidity which, in turn, supports initial interspecies interactions and promotes subsequent high affinity Mfa1-SspB interactions driving biofilm growth. CSE induction of P. gingivalis biofilms of limited pro-inflammatory potential may explain the increased persistence of this pathogen in smokers. These findings may also be relevant to other biofilm-induced infectious diseases and conditions.     

基于微流控的生物被膜研究进展及口腔微生态系统应用展望

口腔是人体最重要的微生物储藏库之一,这些微生物通常以生物被膜的形式稳定地黏附于口腔内粘膜及牙齿表面,在病理条件下则可以深入髓腔及牙槽骨内,成为龋病、根尖周炎、牙周病等常见口腔疾病的主要病因,甚至与许多全身性疾病密切相关。在人类口腔微生态系统中,微生物种类繁多,生物被膜的构成及相互作用关系复杂,目前对其认识还十分有限;此外,在宿主免疫、口腔内外多种理化因素的调控下,生物被膜还可以出现不同的表型及生物特性,因此对其致病机制的研究也具有挑战性。微流控技术作为一种能够灵活操控微尺度流体的技术,不仅能够精准模拟理化微环境,还能够进行高通量可视化的分析,在生命分析化学及生物被膜的研究方面已经展现出显著优势,在口腔微生态系统研究中具有广阔的应用前景。本文将回顾近期微流控技术在生物被膜方面的研究进展,并结合口腔微生态系统中生物被膜研究的关键问题对微流控技术的应用做系统阐述和展望。     

Taking the Starch out of Oral Biofilm Formation: Molecular Basis and Functional Significance of Salivary α-Amylase Binding to Oral Streptococci

α-Amylase-binding streptococci (ABS) are a heterogeneous group of commensal oral bacterial species that comprise a significant proportion of dental plaque microfloras. Salivary α-amylase, one of the most abundant proteins in human saliva, binds to the surface of these bacteria via specific surface-exposed α-amylase-binding proteins. The functional significance of α-amylase-binding proteins in oral colonization by streptococci is important for understanding how salivary components influence oral biofilm formation by these important dental plaque species. This review summarizes the results of an extensive series of studies that have sought to define the molecular basis for α-amylase binding to the surface of the bacterium as well as the biological significance of this phenomenon in dental plaque biofilm formation.     

益生元对口腔健康促进作用和机制研究进展

口腔微生物群落的动态平衡是维持口腔健康的关键因素。益生元是一类具有选择性、能够促进体内有益菌代谢增殖从而改善宿主健康的有机物质,主要通过调节口腔微生物生长代谢、抑制口腔菌斑生物膜形成、调节宿主免疫反应、参与硝酸盐-亚硝酸盐-一氧化氮代谢循环通路、调节氧化应激反应等途径调控口腔微生态,从而对口腔常见疾病,如龋齿、牙周病、口腔黏膜病的防治起到积极作用。本文主要就近年来益生元在口腔健康中的作用及相关机制的研究情况进行综述。     

Antimicrobial Peptides and their Potential as Oral Therapeutic Agents

Dental caries (tooth decay) and periodontal diseases are the most prevalent bacterial infectious diseases of mankind, together affecting almost the entire population of the world. Both diseases are caused by oral bacteria that exist as components of a polymicrobial biofilm, known as dental plaque, on the tooth surface. The control of specific types of bacteria and/or total numbers of bacteria in dental plaque could lead to prevention or resolution of disease. Antimicrobial peptides isolated from a wide range of natural sources have been known for over 30 years yet little progress had been made in the therapeutic application of these peptides. This is due in part to the characteristics, including susceptibility to proteolysis, of the cationic amphipathic antimicrobial peptides that form the majority of peptides discovered to date. Bovine milk is a readily available source of a range of bioactive peptides. We have isolated and characterized a novel anionic antimicrobial peptide, Kappacin, from bovine milk. Antibacterial activity of the peptide is increased when it is complexed with zinc ions. We have demonstrated that a Kappacin:Zn²⁺ preparation is able to suppress the growth of oral cariogenic bacteria in a biofilm. The Kappacin:Zn²⁺ antibacterial complex may have potential as an additive to oral care products and other delivery vehicles for the control of oral disease.     

Extracellular Glycoside Hydrolase Activities in the Human Oral Cavity

Carbohydrate availability shifts when bacteria attach to a surface and form biofilm. When salivary planktonic bacteria form an oral biofilm, a variety of polysaccharides and glycoproteins are the primary carbon sources; however, simple sugar availabilities are limited due to low diffusion from saliva to biofilm. We hypothesized that bacterial glycoside hydrolase (GH) activities would be higher in a biofilm than in saliva in order to maintain metabolism in a low-sugar, high-glycoprotein environment. Salivary bacteria from 13 healthy individuals were used to grow in vitro biofilm using two separate media, one with sucrose and the other limiting carbon sources to a complex carbohydrate. All six GHs measured were higher in vitro when grown in the medium with complex carbohydrate as the sole carbon source. We then collected saliva and overnight dental plaque samples from the same individuals and measured ex vivo activities for the same six enzymes to determine how oral microbial utilization of glycoconjugates shifts between the planktonic phase in saliva and the biofilm phase in overnight dental plaque. Overall higher GH activities were observed in plaque samples, in agreement with in vitro observation. A similar pattern was observed in GH activity profiles between in vitro and ex vivo data. 16S rRNA gene analysis showed that plaque samples had a higher abundance of microorganisms with larger number of GH gene sequences. These results suggest differences in sugar catabolism between the oral bacteria located in the biofilm and those in saliva.     

Three‐dimensional visualization of mixed species biofilm formation together with its substratum

Biofilms, such as dental plaque, are aggregates of microorganisms attached to a surface. Thus, visualization of biofilms together with their attached substrata is important in order to understand details of the interaction between them. However, so far there is limited availability of such techniques. Here, non‐invasive visualization of biofilm formation with its attached substratum by applying the previously reported technique of continuous‐optimizing confocal reflection microscopy (COCRM) is reported. The process of development of oral biofilm together with its substratum was sequentially visualized with COCRM. This study describes a convenient method for visualizing biofilm and its attached surface.