PNAS：造血干细胞老化可能解释老年人较高的白血病发病率

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" a& J6 o: j, n+ |PNAS：造血干细胞老化可能解释老年人较高的白血病发病率
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美国研究人员发现相比于来自20到25岁健康人的造血干细胞(hematopoietic stem cells, HSCs)，来自65岁以上健康人的造血干细胞制造较少的淋巴细胞，相反有倾向偏好产生另一种类型白血细胞，称作骨髓细胞(myeloid cell)。这种偏好可能解释了为什么较老的人们要比较年轻的人们更容易患上髓系肿瘤(myeloid malignancy)。0 f. a8 H  Z( f& X

% L& o+ V- A8 Q1 b( R! [Aging Stem Cells May Explain Higher Prevalence of Leukemia, Infections Among Elderly
0 p( N$ D/ ]/ H/ p* }ScienceDaily (Nov. 28, 2011) — Human stem cells aren't immune to the aging process, according to scientists at the Stanford University School of Medicine. The researchers studied hematopoietic stem cells, which create the cells that comprise the blood and immune system. Understanding when and how these stem cells begin to falter as the years pass may explain why some diseases, such as acute myeloid leukemia, increase in prevalence with age, and also why elderly people tend to be more vulnerable to infections such as colds and the flu.4 I3 g# n8 q! G. Z+ s, K

! g6 R* H  m) n  T"We know that immune system function seems to decline with increasing age," said Wendy Pang, MD. "This is the first study comparing the function and gene expression profiles of young and old purified, human hematopoietic stem cells, and it tells us that these clinical changes can be traced back to stem cell function."
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$ c! j7 q; n+ I' f5 m, r) b2 sSpecifically, the researchers found that hematopoietic stem cells from healthy people over age 65 make fewer lymphocytes -- cells responsible for mounting an immune response to viruses and bacteria -- than stem cells from healthy people between ages 20 and 35. (The cells were isolated from bone marrow samples.) Instead, elderly hematopoietic stem cells, or HSCs, have a tendency to be biased in their production of another type of white blood cell called a myeloid cell. This bias may explain why older people are more likely than younger people to develop myeloid malignancies.9 I( O6 o( e0 K" }! q# p- B

2 ?7 q( E/ E" a9 a( mThe study was published online Nov. 28 in the Proceedings of the National Academy of Sciences. Pang, who is in the Medical Science Training Program at Stanford, is the first author of the research; professor of pathology Irving Weissman, MD, is the senior author. Weissman is also the director of Stanford's Institute for Stem Cell Biology and Regenerative Medicine.; ~( n# r1 h5 f6 r

2 K6 w- H1 M5 CPang began the study to understand whether human HSCs aged like mouse HSCs. Previous studies had shown that mouse HSCs change in number and function as a laboratory mouse grows older. She obtained HSCs from 15 healthy elderly people and 28 healthy young people and compared their prevalence, distribution and cell cycle profile.$ a8 [; ~4 f1 x3 i# T
She found that HSCs comprised a greater proportion of bone marrow cells in older people than in younger people. They were also more likely to be actively dividing than younger HSCs. But their greater numbers and increased proliferation didn't translate into greater efficiency; like a top wobbling out of control as its rotation slows, the aging HSCs instead appear to be unsuccessfully trying to keep up with the demands of everyday life.
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When Pang purified the HSCs and grew them in laboratory dishes, she found that HSCs from older people were less able to differentiate into B lymphocytes and more likely to become myeloid cells. Furthermore, immune-deficient laboratory mice given transplants of older, human HSCs exhibited a higher proportion of myeloid to lymphoid cells in their bone marrow in the weeks to months after the transplant.
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Finally, Pang examined the gene expression profile of the two sets of human HSCs, as well as five samples of HSCs from people ages 42 to 61. She found that HSCs from elderly donors express comparatively higher levels of several age-related genes associated with the cell cycle, proliferation and development, as well as genes associated with DNA repair and cell death. The higher levels of these genes suggests the cells are less likely to wait quietly on the sidelines until new blood or immune cells are needed and are instead entering the cell cycle inappropriately.
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. T: \8 U. s/ F8 y0 `, o/ `( EOverall, the results mirror those seen in studies of HSCs from laboratory mice of varying ages. They suggest that human HSCs struggle as a person ages, and that this struggle can sometimes lead not only to inadequate immune responses, but also to inappropriate growth and specific types of blood cancers, such as acute myeloid leukemia. They also contribute valuable information for the study of many other conditions.4 k# Q! k* x& z- C% a, C1 @3 F9 N4 X, g
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"In both mice and humans, the puzzle has been how the system ages," said Weissman, who is also the Virginia & D.K. Ludwig Professor for Clinical Investigation in Cancer Research and a member of Stanford's Cancer Institute. "Because HSCs in old mice and humans are derived from the HSCs they had in their youth, there are two possibilities to describe how these differences occur. Either individual, young HSCs change their gene expression patterns as they age, undergoing heritable adaptations that favor the myeloid lineage, or each young HSC already has a specific lineage bias and is battling for precious niches through the natural selection of aging, which favors those biased toward myeloid cells." Understanding which possibility is true could help clinicians of the future encourage the survival of HSCs with more-appropriate properties in patients with age-related diseases, Weissman believes.  ?+ {& d. \) a% I
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"These findings will also serve as an important baseline for future studies of age-related diseases, such as myeloid dysplastic syndrome, anemia and leukemia," said Pang. "Now that we know how HSCs change and function in elderly individuals who are not ill, we should be able to tease out disease-associated changes from normal age-associated phenomena."! I. }% J: i) w  G" p6 [
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In addition to Pang and Weissman, other Stanford researchers involved in the study include assistant professor of medicine Elizabeth Price, MD; instructor of pathology Debashis Sahoo, PhD; professor of orthopedic surgery William Maloney, MD; and professor of medicine Stanley Schrier, MD./ U+ n# [# e  B% H0 h/ V
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The research was supported by the Stanford Medical Scientist Training Program, the Siebel Stem Cell Institute, the Thomas and Stacey Siebel Foundation and the National Institutes of Health. Information about Stanford's Department of Pathology.! f6 U' F+ d) ]' a
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http://www.sciencedaily.com/releases/2011/11/111128152414.htm

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% ^1 q. J) a' T* t2 v# l+ c* {, _+ b原文信息：
+ U9 Q% p; R/ W$ a8 UHuman bone marrow hematopoietic stem cells are increased in frequency and myeloid-biased with age
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: P8 U5 D8 S5 g$ `4 B& A+ e" Jdoi: 10.1073/pnas.1116110108
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http://www.pnas.org/content/early/2011/11/23/1116110108.abstract

细胞海洋

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% L0 ?6 y9 q; Z" ?2 i' W% I文章编译自：ScienceDaily  Aging Stem Cells May Explain Higher Prevalence of Leukemia, Infections Among Elderly
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6 ^' k& t' N" ?& A文献标题：Human bone marrow hematopoieticstem cells are increased in frequency and myeloid-biased with age) j& P/ `7 z) |8 t) k
文献出处：PNAS ,28, 2011, doi:10.10736 X: B8 n/ B* A
期刊影响因子：9.432
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       据美国斯坦福大学医学院的科学家称，人类干细胞也不能幸免与细胞衰老。研究人员对可生成血液和免疫系统细胞的造血干细胞进行了研究。了解随着时间的流逝这些干细胞何时以及如何开始衰老可能解释为什么一些疾病（如急性髓细胞性白血病）患病率随着年龄的增加而升高，以及为什么老年人往往更容易感染，如感冒和流感。2 K9 u0 O0 O2 I
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       Wendy Pang博士说，“我们知道，免疫系统功能似乎随着年龄的增加而下降。” “这是对年轻人和老年人提纯的造血干细胞功能和基因表达谱进行比较的首次研究，该研究告诉我们，这些临床变化可以追溯到与干细胞功能。”
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! o# K' }, u7 g       具体来说，研究人员发现，与20岁-35岁的健康人相比，65岁以上的健康人的造血干细胞生成淋巴细胞较少，而淋巴细胞可调节对病毒和细菌的免疫应答逐渐增加（细胞分离自骨髓标本）。相反，老年人的造血干细胞，更易于生成另一种称之为骨髓细胞的白细胞。这种倾向也许可以解释为什么老年人比年轻人更易生成骨髓恶性肿瘤。
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, q  L# d" K/ o0 T& B1 w       这项研究结果在线发表在11月28日的《国家科学院院刊》上。参与了斯坦福大学医学科学的培训计划的Pang，是本研究的第一作者;病理学教授Irving Weissman博士为通讯作者。Weissman还是斯坦福大学干细胞生物学和再生医学研究所主任。
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       Pang开始进行研究以了解人造血干细胞的老化是否像小鼠造血干细胞一样。以往的研究表明，随着实验室老鼠衰老，小鼠造血干细胞在数量和功能发生改变。Pang 采集了15名健康老人和28位健康年轻人的造血干细胞并对他们的患病率，分布及细胞周期谱进行了比较。
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       她发现，老年人的造血干细胞中饿骨髓细胞比例比年轻人高。老年人的造血干细胞分裂比年轻人更活跃。但其数量更多，且增殖速度加快并不能转化为更大的效益;就如同顶部旋转减慢后顶部出现摇摆而失去控制一样，老化的造血干细胞在尝试保持与日常生活的需求上出现失控。/ H! O+ ?  m$ c# U4 K
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& C. v  o8 K0 ^( {       当Pang在实验室培养皿中纯化并增殖造血干细胞时发现，老年人的造血干细胞分化成B淋巴细胞较少，而更易分化成髓细胞。此外，免疫缺陷的实验室小鼠移植老年人造血干细胞后数周到数月，其骨髓中的人造血干细胞分化为较大比例的骨髓至淋巴样细胞。
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, m9 `8 I  \% o5 s2 p# P       最后，Pang对两组人造血干细胞基因表达谱，以及5份42-61岁人类造血干细胞样本进行了研究。她发现，老人捐助者的造血干细胞表达几种与细胞周期，增殖和发展有关的年龄相关基因，以及与DNA修复和细胞死亡相关的基因。上述基因表达水平较高，表明这些细胞在新的血液或免疫细胞需要，而非适时的进入细胞周期前不太可能寂然无声。+ s5 Q/ W! p/ ~# g+ u( b
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$ j1 E$ H) b/ |& X       总体来说，结果反映了不同年龄的实验室小鼠造血干细胞的研究结果。他们认为，人造血干细胞的功能随着一个人的年龄变化而改变，就是说有时会不但会导致免疫应答不足，而且还会引起不适当的增殖和特定类型的血液癌症如急性髓细胞性白血病。他们还为许多其他条件下的研究贡献了有价值的信息。5 Q4 P" {5 y3 ~+ [% r! b

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8 i7 ~2 V8 G* w* K% g! \4 q5 q( J       弗吉尼亚和D.K. Ludwig临床癌症研究中心的教授，斯坦福大学癌症研究所的成员Weissman说，“在小鼠和人类中，体系老化的机制一直是难题”。 “因为年龄较大的小鼠和人的造血干细胞来自于早期的造血干细胞，有两种可能可解释这些差异是如何发生的，一是随着衰老，早期的造血干细胞的基因表达模式发生改变，出现遗传性改变，从而向髓系发展，二是每个早期造血干细胞已经有了一个特异性谱系，并通过年龄自然选择争取宝贵的微环境，而向髓细胞方向发展。”Weissman认为，理解这种可能正确的理论能够帮助未来的医生保证与年龄相关疾病患者的更合适的造血干细胞存活。
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( f! Q  |% z7 A/ l. f5 b       Pang说，“这些调查结果也将作为未来与年龄有关的疾病研究如髓细胞发育不良综合征，贫血和白血病的重要的基线数据，现在我们知道了未生病的老年个体的造血干细胞如何变化以及其功能，我们应该能够从正常年龄有关的疾病中梳理出与疾病相关的变化。”
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2 e+ U. b- k4 ]8 Q（转帖自医脉通）