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健康新闻(10)用噬菌体绞杀“超级细菌” 精选

已有 5244 次阅读 2014-9-22 17:28 |个人分类:期刊论文|系统分类:论文交流| 噬菌体, 超级细菌

抗生素在控制细菌性传染病上立下了汗马功劳,但它们同时也是催生“超级细菌”(superbug)的催化剂。所谓超级细菌,就是那些生长繁殖不受特定抗生素抑制的特殊细菌,这些细菌中要么含有某种抗生素抗性基因编码质粒,如甲氧西林抗性金黄色葡萄球菌(MRSA)的NDM-1以及碳青霉烯抗性肠杆菌科细菌(CRE)要么携带某种抗生素抗性突变基因,如喹诺啉(沙星类)抗性的出血性大肠杆菌SHV-18基因。

对于上述超级细菌,最有效的抑杀方式是避免使用同类抗生素,而换用其他抗生素。最近,美国麻省理工学院的科学家想出了一条妙计,他们不用任何抗生素,而是以细菌的天敌——噬菌体来绞杀超级细菌,这正如农业上利用白僵菌防治玉米螟那样。

细菌中普遍存在“成簇规律间隔的短回文重复”(CRISPR)编辑系统,可以用来抵御噬菌体的入侵和寄生,因而被形象地称为细菌的“免疫系统”。由于CRISPR与噬菌体DNA同源,因而可以互补配对,从而被细菌的“手术刀”——Cas9蛋白识别并被切割,结果使噬菌体不能感染细菌。

为了利用CRISPR-Cas9系统,研究人员设计了两种载运体,一种是携带CRISPR质粒的基因工程细菌,还有一个是可以感染细菌并注入CRISPR的噬菌体颗粒。当他们把两种运载体分别导入含NDM-1基因的超级细菌后,可以通过碱基互补找到NDM-1基因所在的未知,从而让细菌的Cas9切割NDM-1基因,结果发现该法杀菌率高达99%!

聪明的读者大概想到了,这个方法并不是让天然噬菌体来杀死细菌,而是利用细菌抑制噬菌体感染的原理让细菌“自杀”,只不过是利用基因工程细菌和噬菌体把CRISPR引入到部分菌体中,并传播至整个细菌群体。目前已在大蜡螟中完成了活体杀菌试验,下一步将在小鼠中评价其杀菌效果。不过,这种技术何时用于人体还有待时日,可能的方式是通过益生菌引入肠道。


Battling superbugs: Two new technologies could enable novel strategies for combating drug-resistant bacteria

Date:
September 21, 2014
Source:
Massachusetts Institute of Technology
Summary:
Two new technologies could enable novel strategies for combating drug-resistant bacteria, scientists report. Most antibiotics work by interfering with crucial functions such as cell division or protein synthesis. However, some bacteria have evolved to become virtually untreatable with existing drugs. In the new study, researchers target specific genes that allow bacteria to survive antibiotic treatment. The CRISPR genome-editing system presented the perfect strategy to go after those genes, they report.


A scanning electron micrograph depicts numerous clumps of methicillin-resistant Staphylococcus aureus bacteria, commonly referred to by the acronym MRSA.
Credit: Janice Haney Carr/Centers for Disease Control and Prevention

In recent years, new strains of bacteria have emerged that resist even the most powerful antibiotics. Each year, these superbugs, including drug-resistant forms of tuberculosis and staphylococcus, infect more than 2 million people nationwide, and kill at least 23,000. Despite the urgent need for new treatments, scientists have discovered very few new classes of antibiotics in the past decade.

MIT engineers have now turned a powerful new weapon on these superbugs. Using a gene-editing system that can disable any target gene, they have shown that they can selectively kill bacteria carrying harmful genes that confer antibiotic resistance or cause disease.

Led by Timothy Lu, an associate professor of biological engineering and electrical engineering and computer science, the researchers described their findings in the Sept. 21 issue of Nature Biotechnology. Last month, Lu's lab reported a different approach to combating resistant bacteria by identifying combinations of genes that work together to make bacteria more susceptible to antibiotics.

Lu hopes that both technologies will lead to new drugs to help fight the growing crisis posed by drug-resistant bacteria.

"This is a pretty crucial moment when there are fewer and fewer new antibiotics available, but more and more antibiotic resistance evolving," he says. "We've been interested in finding new ways to combat antibiotic resistance, and these papers offer two different strategies for doing that."

Cutting out resistance

Most antibiotics work by interfering with crucial functions such as cell division or protein synthesis. However, some bacteria, including the formidable MRSA (methicillin-resistant Staphylococcus aureus) and CRE (carbapenem-resistant Enterobacteriaceae) organisms, have evolved to become virtually untreatable with existing drugs.

In the new Nature Biotechnology study, graduate students Robert Citorik and Mark Mimee worked with Lu to target specific genes that allow bacteria to survive antibiotic treatment. The CRISPR genome-editing system presented the perfect strategy to go after those genes.

CRISPR, originally discovered by biologists studying the bacterial immune system, involves a set of proteins that bacteria use to defend themselves against bacteriophages (viruses that infect bacteria). One of these proteins, a DNA-cutting enzyme called Cas9, binds to short RNA guide strands that target specific sequences, telling Cas9 where to make its cuts.

Lu and colleagues decided to turn bacteria's own weapons against them. They designed their RNA guide strands to target genes for antibiotic resistance, including the enzyme NDM-1, which allows bacteria to resist a broad range of beta-lactam antibiotics, including carbapenems. The genes encoding NDM-1 and other antibiotic resistance factors are usually carried on plasmids -- circular strands of DNA separate from the bacterial genome -- making it easier for them to spread through populations.

When the researchers turned the CRISPR system against NDM-1, they were able to specifically kill more than 99 percent of NDM-1-carrying bacteria, while antibiotics to which the bacteria were resistant did not induce any significant killing. They also successfully targeted another antibiotic resistance gene encoding SHV-18, a mutation in the bacterial chromosome providing resistance to quinolone antibiotics, and a virulence factor in enterohemorrhagic E. coli.

In addition, the researchers showed that the CRISPR system could be used to selectively remove specific bacteria from diverse bacterial communities based on their genetic signatures, thus opening up the potential for "microbiome editing" beyond antimicrobial applications.

To get the CRISPR components into bacteria, the researchers created two delivery vehicles -- engineered bacteria that carry CRISPR genes on plasmids, and bacteriophage particles that bind to the bacteria and inject the genes. Both of these carriers successfully spread the CRISPR genes through the population of drug-resistant bacteria. Delivery of the CRISPR system into waxworm larvae infected with a harmful form of E. coli resulted in increased survival of the larvae.

The researchers are now testing this approach in mice, and they envision that eventually the technology could be adapted to deliver the CRISPR components to treat infections or remove other unwanted bacteria in human patients.

High-speed genetic screens

Another tool Lu has developed to fight antibiotic resistance is a technology called CombiGEM. This system, described in the Proceedings of the National Academy of Sciences the week of Aug. 11, allows scientists to rapidly and systematically search for genetic combinations that sensitize bacteria to different antibiotics.

To test the system, Lu and his graduate student, Allen Cheng, created a library of 34,000 pairs of bacterial genes. All of these genes code for transcription factors, which are proteins that control the expression of other genes. Each gene pair is contained on a single piece of DNA that also includes a six-base-pair barcode for each gene. These barcodes allow the researchers to rapidly identify the genes in each pair without having to sequence the entire strand of DNA.

"You can take advantage of really high-throughput sequencing technologies that allow you, in a single shot, to assess millions of genetic combinations simultaneously and pick out the ones that are successful," Lu says.

The researchers then delivered the gene pairs into drug-resistant bacteria and treated them with different antibiotics. For each antibiotic, they identified gene combinations that enhanced the killing of target bacteria by 10,000- to 1,000,000-fold. The researchers are now investigating how these genes exert their effects.

"This platform allows you to discover the combinations that are really interesting, but it doesn't necessarily tell you why they work well," Lu says. "This is a high-throughput technology for uncovering genetic combinations that look really interesting, and then you have to go downstream and figure out the mechanisms."

Once scientists understand how these genes influence antibiotic resistance, they could try to design new drugs that mimic the effects, Lu says. It is also possible that the genes themselves could be used as a treatment, if researchers can find a safe and effective way to deliver them.

CombiGEM also enables the generation of combinations of three or four genes in a more powerful way than previously existing methods. "We're excited about the application of CombiGEM to probe complex multifactorial phenotypes, such as stem cell differentiation, cancer biology, and synthetic circuits," Lu says.

Story Source:

The above story is based on materials provided by Massachusetts Institute of Technology. The original article was written by Anne Trafton. Note: Materials may be edited for content and length.

Journal Reference:

  1. Robert J Citorik, Mark Mimee, Timothy K Lu. Sequence-specific antimicrobials using efficiently delivered RNA-guided nucleases. Nature Biotechnology, 2014; DOI: 10.1038/nbt.3011





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