健康人人关心的话题分享 http://blog.sciencenet.cn/u/qpzeng 写“正能量”博客,做“富营养”科普

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可恶的牙病与牙周细菌 精选

已有 18027 次阅读 2014-6-12 14:15 |个人分类:期刊论文|系统分类:论文交流| 牙病

在中文里,“炎”字是由两个“火”字部首组成的,真是太形象、太贴切了。通常中医所说的“上火”,多数情况都是指局部“发炎”,而口腔“上火”多半是牙龈炎、牙周炎在作怪。

从小就听人说:牙痛不是病!其实,这句话谬种流传,严重误导国人,让很多人对牙病不重视、不治疗。殊不知牙痛不仅会发展成蛀齿,而且引起牙痛的细菌会经食道、气管向全身扩散,从而引起许多严重的慢性疾病,如肠炎、肠癌、心脏病、类风湿性关节炎

因此,我们必须正视牙痛,而且有了牙病一定要去牙科诊治,决不可掉以轻心,放任不管。那么,牙周疾病是由什么细菌引起的呢?为什么人的免疫系统不能清除这种细菌呢?刚刚在《细胞——宿主与微生物》杂志发表的一篇最新论文做出了圆满解答。

牙龈卟啉单胞菌(Porphyromonas gingivalis)是最常见的牙周炎和牙龈炎致病细菌之一,被称为“关键病原菌”(keystone pathogen),它的可恶之处在于能“瘫痪”中性粒细胞的杀菌能力,这就如同“解除”战士的“武装”令其失去“战斗”能力一样

人体对口腔及肠道细菌通常具有耐受性,也就是不会诱发强烈的免疫反应,但其前提条件就是整体微生物群落的基本平衡。可是,由于牙病发作后牙周细菌大量繁殖,结果是中性粒细胞的杀菌性被钝化而使免疫系统“不作为”,导致各种微生物群落在无控状态下疯狂繁殖而失去平衡,最终引起多种急慢性炎症性疾病。

对牙周细菌作用的详细机理研究表明,它能使C5aR和TLR2两个结合病原菌的受体蛋白质交联,结果导致清除病原菌的MyD88降解。同时,还通过C5aR-TLR2激活PI3K启动炎症通路。这样,牙周细菌不仅让中性粒细胞失去吞噬细菌的能力,而且促进Mal与PI3K诱导的炎症加剧及免疫逃逸。牙周细菌也许本身致病性不强,但它能与其他致病菌“狼狈为奸”、“助纣为虐”。因此,这个研究解释了为何牙病在全身性疾病上表现较强的“放大”效应。

如此看来,口腔卫生对于健康是何等重要啊,正如我所说 口腔不卫生,风湿惹上身!今天介绍的最新研究,还让我们了解到,牙周细菌不仅仅引起类风湿性关节炎,还会引起包括癌症在内的多种严重疾病。为了健康,你还能放任牙痛不管吗?以下是对该研究结果的基本介绍,感兴趣者可按提示查找全文。


Gum disease bacteria selectively disarm immune system, study finds

Date:
June 11, 2014
Source:
University of Pennsylvania
Summary:
Bacteria responsible for many cases of periodontitis cause an imbalance in the microbial community in the gums, with a sophisticated, two-prong manipulation of the human immune system, research shows. Not only does the team's discovery open up new targets for periodontitis treatment, it also suggests a bacterial strategy that could be at play in other diseases involving dysbiosis.


Periodontal bacteria hamper the killing action of neutrophils while still allowing them to promote inflammation in the gums.
Credit: Image courtesy of University of Pennsylvania

The human body is comprised of roughly 10 times more bacterial cells than human cells. In healthy people, these bacteria are typically harmless and often helpful, keeping disease-causing microbes at bay. But, when disturbances knock these bacterial populations out of balance, illnesses can arise. Periodontitis, a severe form of gum disease, is one example.

In a new study, University of Pennsylvania researchers show that bacteria responsible for many cases of periodontitis cause this imbalance, known as dysbiosis, with a sophisticated, two-prong manipulation of the human immune system.

Their findings, reported in the journal Cell Host & Microbe, lay out the mechanism, revealing that the periodontal bacterium Porphyromonas gingivalis acts on two molecular pathways to simultaneously block immune cells' killing ability while preserving the cells' ability to cause inflammation. The selective strategy protects "bystander" gum bacteria from immune system clearance, promoting dysbiosis and leading to the bone loss and inflammation that characterizes periodontitis. At the same time, breakdown products produced by inflammation provide essential nutrients that "feed" the dysbiotic microbial community. The result is a vicious cycle in which inflammation and dysbiosis reinforce one another, exacerbating periodontitis.

George Hajishengallis, a professor in the Penn School of Dental Medicine's Department of Microbiology, was the senior author on the paper, collaborating with co-senior author John Lambris, the Dr. Ralph and Sallie Weaver Professor of Research Medicine in the Department of Pathology and Laboratory Medicine in Penn's Perelman School of Medicine. Collaborators included Tomoki Maekawa and Toshiharu Abe of Penn Dental Medicine.

Work by Hajishengallis's group and collaborators had previously identified P. gingivalisas a "keystone pathogen." Drawing an analogy from the field of ecology, in which a species such as a grizzly bear is thought of as a keystone species because of the influence it has over a number of other species in the community, the idea suggests that, although P. gingivalis may be relatively few in number in the mouth, their presence exerts an outsized pull on the overall microbial ecosystem. Indeed, the team has shown that, although P. gingivalis is responsible for instigating the process that leads to periodontitis, it can't cause the disease by itself.

"Scientists are beginning to suspect that keystone pathogens might be playing a role in irritable bowel disease, colon cancer and other inflammatory diseases," Hajishengallis said. "They're bugs that can't mediate the disease on their own; they need other, normally non-pathogenic bacteria to cause the inflammation."

In this study, they wanted to more fully understand the molecules involved in the process by which P. gingivalis caused disease.

"We asked the question, how could bacteria evade killing without shutting off inflammation, which they need to obtain their food," Hajishengallis said.

The researchers focused on neutrophils, which shoulder the bulk of responsibility of responding to periodontal insults. Based on the findings of previous studies, they examined the role of two protein receptors: C5aR and Toll-like receptor-2, or TLR2.

Inoculating mice with P. gingivalis, they found that animals that lacked either of these receptors as well as animals that were treated with drugs that blocked these receptors had lower levels of bacteria than untreated, normal mice. Blocking either of these receptors on human neutrophils in culture also significantly enhanced the cells' ability to kill the bacteria. Microscopy revealed that P. gingivalis causes TLR2 and C5aR to physically come together.

"These findings suggest that there is some crosstalk between TLR2 and C5aR," Hajishengallis said. "Without either one, the bacteria weren't as effective at colonizing the gums."

Further experiments in mice and in cultured human neutrophils helped the researchers identify additional elements of how P. gingivalis operates to subvert the immune system. They found that the TLR2-C5aR crosstalk leads to degradation of the protein MyD88, which normally helps clear infection. And in a separate pathway from MyD88, they discovered that P. gingivalis activates the enzyme PI3K through C5aR-TLR2 crosstalk, promoting inflammation and inhibiting neutrophils' ability to phagocytose, or "eat," invading bacteria.

Inhibiting the activity of either PI3K or a molecule that acted upstream of PI3K called Mal restored the neutrophils' ability to clear P. gingivalis from the gums.

"P. gingivalis uses this connection between C5aR and TLR2 to disarm and dissociate the MyD88 pathway, which normally protects the host from infection, from the proinflammatory and immune-evasive pathway mediated by Mal and PI3K," Hajishengallis said.

Not only does the team's discovery open up new targets for periodontitis treatment, it also suggests a bacterial strategy that could be at play in other diseases involving dysbiosis.

Story Source:

The above story is based on materials provided by University of Pennsylvania. Note: Materials may be edited for content and length.

Journal Reference:

  1. Tomoki Maekawa, Jennifer L. Krauss, Toshiharu Abe, Ravi Jotwani, Martha Triantafilou, Kathy Triantafilou, Ahmed Hashim, Shifra Hoch, Michael A. Curtis, Gabriel Nussbaum, John D. Lambris, George Hajishengallis. Porphyromonas gingivalis Manipulates Complement and TLR Signaling to Uncouple Bacterial Clearance from Inflammation and Promote Dysbiosis. Cell Host & Microbe, 2014; 15 (6): 768 DOI: 10.1016/j.chom.2014.05.012


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