先天性肌无力研究的最新进展----Nick Willcox教授

                                                  译者：一位病友的丈夫

如大家所知，David Beeson教授，与我们的校长 John Newsom- Davis 和牛津的Jackie Palace 博士，是先天性肌无力研究方面的世界知名权威。先天性疾病几乎是随机发生的，并可能影响到我们的任何基因。显而易见，对于像肌肉营养不良一类的疾病，准确地认定疾病根源将有助于阐明在不同患者群所存在的细微差异，诸如发病的年龄、病情的严重程度、最合适的治疗方案和结果，等。

在MGA和MDC过去20年的大力支持下，David已经确认了约有三分之二的"先天性"肌无力患者的基因变异（最近已经设立了对其进行常规检查的诊断服务机制）。大部分的"变异"影响到MG患者的致命之处----乙酰胆碱受体（AChR），这是典型MG患者的免疫系统要攻击的目标。

正如David和他在美国梅佑诊所的竞争对手们所发现的，部分"自然试验"可以有助于解释机体什么地方不正常，譬如 Slow Channel 综合症，以及正常的机体应该如何工作。其它的发现也将让我们了解更多东西。例如，Burke博士和David最近通过另一个患者群，确认了他们的疾病根源在一个被称为Rapsyn的蛋白质附近。令人诧异的是，虽然疾病根源看上去都一样，但是在部分此类患者中，肌无力症状发生在他们出生时，而其他的患者在20岁甚至40岁时才发病，而且症状不那么严重。是否那些比较幸运的患者有一些特殊变异的基因在保护他们？其答案可能会为那些不太幸运的患者提供新治疗的线索。

在另一患者群的幸运突破

我们正处于这样一个阶段，很多研究小组都采用人类基因组图去寻找过去没有发现的新基因。东京的一个小组（在 Yuji Yamanashi教授领导下）正在认真研究Dok蛋白质的一族（链），他们注意到其中一个链（Dok-7）仅仅在神经肌肉接头处激活。他们请神经科Masa医生参与研究。Masa医生是牛津研究小组的老朋友，与Lang博士在10年前就合作过，他开发了一个优秀的血液试验至今还在LEMS诊断上使用。

Masa医生很快就确认了Dok-7蛋白质的确在交接处存在。而它全部潜存于肌肉细胞内部，因此它们似乎不应该是抗体呈阴性的MG患者的免疫抗体所攻击的目标。或者说，这意味着它可能是受了肌无力遗传因素的某些影响。因此，去年夏天他要求David检查其50个未分组患者的DNA样板。与 Spearman和Maxwell合作（由MDC/MGA设立），David很快去寻找Dok-7基因的病源，他们一起合作，检查50个病人中的25个，包括一些从70年代就进入的老病友。

当John和Jackie把这些基因有变异的患者名字放到一起时，他们开始意识到这些病人都属于一种特殊的肌无力患者群，"limbgirdle"型肌无力，即肌无力症状多发生在其肩部和臀部，较少影响于眼睛，脸和延髓部位。他们组织这些特殊病人进行了2-3轮的临床聚会。由此了解到，这些患者不像其他的先天性肌无力患者，他们的无力症状通常在出生时表现不明显，特别典型的是，他们都首先出现行走困难，或者会在2-5岁时出现意外的跌倒现象。这种隐性的遗传意味着病人的父母通常不受影响，而且病源的基因缺少某些部分，而不像Slow Channels 那样非常有害的活跃着。事实上，在60年代的首个这样的家庭已被报告过（见 Deborah Cavel-Greant的著作"你、我和重症肌无力"，第146-153 页）。

什么是此类患者的疾病根源？

随着人体发育，其神经和肌肉接口形成初时，神经末梢送出信号，告知肌肉产生一个受体。与MuSK一起，Dok-7 帮助Rapsyn蛋白质激活，然后组合AChR成为密集的群体。David认为不正常的Dok-7无法吸引足够多的AChR到受体上，受体无法形成足够的尺寸，因此无法有效地激活肌肉。

这有什么意义？

这一新发现对诊断先天性的肌无力患者有明显的帮助。在某些其它患者群，类似的进展将引导病人采取更合适的治疗。例如，斯的明对很多病人非常有效，但对于某些病人，它可能起相反的作用，特别是对那些Slow Channels的病人来说，Prozac可能会更好一些。大部分Dok-7病人似乎对长期服用斯的明反映不好。我们需要进一步的研究去发现神经肌肉接头的问题，从而找到更合适的药物。

                      2006年英国重症肌无力协会秋季新闻

sairicai整理，有不当之处，发现的请指出。

［此帖子已被 sairicai 在 2007-7-17 15:26:56 编辑过］

这是西医在单纯全身型方面的突破吧。

从中医的角度讲，大概属于，先天不足吧。

原文如下：

Recent Progress in Congenital Myasthenias

Professor Nick Willcox

As most of you know, Prof David Beeson, together with our President John Newsom- Davis and Dr Jackie Palace (at Oxford), are world authorities on these uncommon inherited myasthenias. You will also remember that inherited faults occur almost randomly and can affect any of our genes. Very often, in such diseases as the muscular dystrophies, identifying the exact fault helps to explain subtle differences between subsets of patients, eg, in the age at onset, the severity, the most suitable treatment and the outcome.

With loyal support from the MGA and MDC over the last 20 years, David has identified the exact faults in around two thirds of our 'congenital' myasthenia patients (and has recently set up a diagnostic service for routine testing). Many of these 'mutations' affect your old friend the acetyl-choline receptor (AChR), the target of the immune attack in typical MG patients.

As David and the rival team at the Mayo Clinic (USA) find, some of these 'experiments of nature' help to explain both what goes wrong, eg, in the Slow Channel Syndrome, and how things work normally. Others will surely teach us further lessons. For example, with David, Dr Georgina Burke recently identified another patient subgroup with faults in a nearby 'scaffolding' protein called Rapsyn. Curiously, the myasthenia is obvious at birth in some of these patients, whereas, in others, it only starts in the 20s or even 40s and is much milder – even though the faults seem identical. Do the lucky ones have some other special modifying gene(s) that protect them? The answer to that might hold clues to better treatments for the unlucky ones.

A lucky break in another subset

We are in a phase where many research groups are using the human genome map to track down interesting new genes that haven't previously been recognised. One such team in Tokyo (with Prof Yuji Yamanashi) has focussed on a family of 'Dok' proteins; they noticed that one of them (Dok-7) is turned on only at the nerve->muscle junction. Because of his expertise on muscle, they got in touch with a Neurologist, Dr Masakatsu Motomura. He is an old friend of the Oxford team's; working here with Dr Bethan Lang about 10 years ago, 'Masa' helped to develop the excellent blood test she still uses for diagnosing the LEMS.

Masa soon confirmed that the Dok-7 protein really is present at the junction. It is entirely inside the muscle cells, so it seemed an unlikely target for the mystery (immune) antibodies in the puzzling 'antibody-negative' MG patients. Instead, he suggested that it just might be affected in some of the inherited myasthenias. So, in the summer of last year, he asked David to try to check that out in his panel of DNA samples from around 50 'un-mapped' patients.

With Hayley Spearman (funded by MDC/MGA) and Susan Maxwell, David soon began to find faults in the Dok-7 gene; together, they now account for around 25 of those 50 patients, including some very old friends known to us (and maybe to you) since the 1970s.

When John and Jackie started putting names to those mutations, they began to realise that they were picking out a subgroup with 'limbgirdle' myasthenia – ie affecting movements around the shoulders and hips more than the eyes, face or throat. They organised 2 or 3 reunions in the clinic where they reviewed as many of these particular patients as they could. That told them that, unlike in many other inherited myasthenias, their weakness is usually not obvious at birth; typically, the first signs are difficulties in walking and/or unexpected falls from the age of 2-5 years. The 'recessive' inheritance means that the patient's parents are not usually affected; also that the faulty genes have something 'missing' rather than anything actively harmful (like Slow Channels are). In fact, there is an excellent description of the very first family to be reported (in the 1960s), on pages 146-153 of "You, Me and Myasthenia Gravis" by Deborah Cavel-Greant (the book we reviewed in the Summer Edition).

What's going wrong in these patients?

When the nerve->muscle junction is first put together in developing babies, the nerve endings send signals across that tell the muscle to form an 'endplate'. Acting with our new friend MuSK, Dok-7 helps to switch on the scaffolding protein Rapsyn that then assembles the AChRs into densely packed clusters. David thinks that the faulty Dok-7 just doesn't attract enough AChRs to the endplates, which never reach the correct size and don't trigger the muscles efficiently.

What use is it all?

This new finding will obviously help in diagnosing more congenital myasthenia patients. In some other subgroups, similar progress has, in turn, pointed patients towards more suitable treatments. For example, many of them find Mestinon® a big help, but, in some others, it can actually make things worse, especially in those with Slow Channels, who may benefit from Prozac® instead. Most Dok-7 patients seem not to respond very well to long-term Mestinon®. Further studies are needed to understand exactly what is going wrong at the nerve->muscle junction and so find more clues about which other drugs to try.                           MGA NEWS Autumn 2006

辛苦了！

辛苦了！

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