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2010 Some Hot Research & Report Papers [复制链接]

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发表于 2011-5-5 23:53 |只看该作者 |倒序浏览 |打印
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本帖最后由 细胞海洋 于 2011-5-6 00:17 编辑 ' y% @  q& r3 Z
" @$ `7 Y( K1 l8 O4 H; M  l2 }; F
个人觉得搞干细胞还是应该关注一下其他领域的发展,所以在此上传一些2010年比较新比较火的领域的文献给大家分享。
* h7 b6 j  G: O! X( r( G这里有基础研究,临床研究,有结构生物学研究,希望对大家打开科研思维有所帮助。2 ]- c8 X8 v+ J
目录:
/ V/ u0 h! e  t6 t1.[2010 Research]A Septin Diffusion Barrier at the Base of the Primary Cilium Maintains Ciliary Membrane Protein Distribution
" x; g, b1 {. V' Q' w9 y& `Qicong Hu,1 Ljiljana Milenkovic,2,3 Hua Jin,4 Matthew P. Scott,2,3,5–8
; k) @9 D( z, G8 e+ k9 NMaxence V. Nachury,4 Elias T. Spiliotis,9* W. James Nelson1,4*9 n! W9 q0 \, u' p1 ~; I

$ y) ?- J9 \+ y* PIn animal cells, the primary cilium transduces extracellular signals through signaling receptors
1 j; J2 Z* V) Y, hlocalized in the ciliary membrane, but how these ciliary membrane proteins are retained in the5 [- r4 b- l( v/ f1 P" {/ y
cilium is unknown. We found that ciliary membrane proteins were highly mobile, but their
  G$ D* ?/ Q8 n5 d* _0 J8 E4 ndiffusion was impeded at the base of the cilium by a diffusion barrier. Septin 2 (SEPT2), a member
4 B. k1 C3 b$ T# nof the septin family of guanosine triphosphatases that form a diffusion barrier in budding yeast,
4 ~1 }* S3 n% V6 {9 L) `  c- x- g" olocalized at the base of the ciliary membrane. SEPT2 depletion resulted in loss of ciliary membrane
% f& o+ Z: O4 xprotein localization and Sonic hedgehog signal transduction, and inhibited ciliogenesis. Thus,- n, [# s, z# x
SEPT2 is part of a diffusion barrier at the base of the ciliary membrane and is essential for6 @# ?  {; @. v
retaining receptor-signaling pathways in the primary cilium.
" ?/ R0 d3 P7 T- A2 a0 b( K/ T3 h2. [2010 Research]Cancer Statistics$ L) G; A. H/ r  _
3. [2010 Research]Dendritic Cells in Systemic Lupus Erythematosus& a% q9 a" q' W% g$ f1 A
Heather M. Seitz0 O: n) Z' R2 n3 z0 H
Johnson County Community College, Science Division, Overland Park,) d9 c% g$ L" U6 s* _$ E# q
Kansas, USA
+ G! d5 b& b( M; L. m2 HGlenn K. Matsushima2 ^6 f  x( \+ Z0 J$ ~. [5 m
UNC Neuroscience Center, Department of Microbiology & Immunology,: I" Q. E, B& C1 m8 Y
Program for Molecular Biology & Biotechnology, University of North: R) Z* ?" L5 h0 I
Carolina at Chapel Hill, Chapel Hill, North Carolina, USA
. f5 U7 W5 r1 @: `! V+ K% }+ e  `0 b+ o: Q% W. T2 S. t2 L& N4 J
Systemic lupus erythematosus (SLE) persists as a chronic inflammatory autoimmune
0 @+ p$ a% B! r3 ~3 d7 ~: O! f7 Adisease and is characterized by the production of autoantibodies. D- |) u2 a) P  G; y- m
and immune complexes that affect multiple organs. The underlying mechanism; g" R) Y  b4 W! @. J0 r8 L
that triggers and sustains disease are complex and involve certain: i) G- h" F2 _0 ~0 `
susceptibility genes and environmental factors. There have been several immune
5 j( J$ H( i" }; f3 L0 {! [5 Bmediators linked to SLE including cytokines and chemokines that have4 b2 n/ l" D5 E6 _
been reviewed elsewhere [1–3]. A number of articles have reviewed the role
7 m. V$ c% ~  r+ b* p3 m6 Gof B cells and T cells in SLE [4–10]. Here, we focus on the role of dendritic$ M  G) Y4 h2 q
cells (DC) and innate immune factors that may regulate autoreactive B cells.
4 }" b. k! R. c( }8 G4. [2010 Research]Differential immunophenotypic analysis of dendritic cell tumours1 f& |: g$ ~  f* L8 k
Tomohiko Orii,1,2 Hiroaki Takeda,2 Sumio Kawata,2 Kunihiko Maeda,1
) `# D; H2 v- o) O+ zMitsunori Yamakawa1/ z% G4 }. n, k2 W1 o

) ~& _! T: c8 G4 p0 @ABSTRACT* O4 Q; o: B$ a' e1 B
Aims The phenotypic and biological characteristics of+ g) y' E0 q! E7 y3 E" t5 c
dendritic cell (DC) tumours have not been fully
0 r# Q! }( X$ W) v; y4 o6 felucidated. The aim of this study was to compare the6 ^1 |3 p2 i: m) }
immunophenotypic characteristics of DC-related markers4 \6 [, q4 q9 j' \: l# A
and cell-cycle-associated markers among DC tumours
  e5 ?4 f2 Y( N/ Y; S9 L6 `and finally to utilise them for differential diagnosis of DC( _* Q( e* f4 }  P1 K! K
tumours.
3 I( Y7 ]$ M; i1 c6 ^5 i5 r4 H' eMethods Tissue sections from 28 patients with DC) q! X/ X3 S2 S8 A! }! H. C
tumours were immunohistochemically examined using
, o% X6 D) t% mDC-related and cell-cycle-associated markers.
. J; u) ]; N" Q- M4 h  eResults The Langerhans cell histiocytosis (LCH) and
2 ], D5 @' P1 `$ F/ u: _Langerhans cell sarcoma (LCS) samples were positive for
: p3 U$ i7 q" Z9 Y+ jS-100 protein, CD1a, Langerin, fascin, DEC-205 and DCSIGN.7 N  {' y9 b2 ^- d$ Y
Interdigitating dendritic cell sarcoma (IDCS) was
5 w6 q3 h7 Z) K4 _  M7 vpositive for S-100 protein and fascin and negative for4 ~& s$ ]- s  |0 q8 [8 J
Langerin. In addition, two IDCS samples were positive for
( a- B" }; W4 ^6 M, H" Q+ u6 \CD1a, DEC-205 and DC-SIGN. The labelling indices of
3 @* a$ K0 z" `  L: W" QKi-67, cyclin A, cyclin B1 and acetylated histone H3 on the
$ h* w/ w, T0 JLCS and IDCS specimens were significantly higher than, s. J8 a9 x8 f3 ^- H! I9 ^$ }
those on the LCH specimens. The expression of p53 was+ X( F& Q4 E* v3 t( n9 f0 Z
also significantly higher in the LCS specimens than in the0 [$ ?  e$ O2 ?, Z- d* Z2 L
LCH specimens. The numbers of infiltrating CD123+ and, p2 N1 I/ [( y# O
FOXP3+ cells were also significantly higher in the LCS
# ]$ n) G. ~( e' ^7 Rsamples than in the LCH and IDCS samples. Follicular/ B2 o# [( {. o6 A8 O# d  |
dendritic cell sarcoma was distinguished from other DC+ T  `5 X4 \6 @6 o/ F# \
tumours by the lack of DC-SIGN, Langerin and DCE-205./ N% E* Q( H% C$ H- T" R( }# ~
Conclusions These results suggest that Langerin can be
4 {3 ^. x3 |& T- P! |; f5 Gused to distinguish LCS from IDCS, and DC-SIGN and
; ?' N) Q' S  F& `* I$ _& {DEC-205 can be used to identify DC tumour cells. The: H* m4 k2 B( v/ l7 j4 x+ |# `
frequency of cell-cycle-associated markers can be used
4 t6 w; E2 k3 n- q" L& ~for the differential diagnosis of malignant and benign DC tumours.
6 g+ P+ e7 }  ]: w5. [2010 Research]Gut inflammation provides a respiratory electron acceptor for Salmonella( V- B4 v& }$ l  E
Sebastian E. Winter1, Parameth Thiennimitr1,2, Maria G. Winter1, Brian P. Butler1, Douglas L. Huseby3, Robert W. Crawford1,) ~6 {" Q2 `% @% ^% E% e
Joseph M. Russell1, Charles L. Bevins1, L. Garry Adams4, Rene′e M. Tsolis1, John R. Roth3 & Andreas J. Ba¨umler1* U8 R5 `2 U- i$ ^5 `, N) u4 S" J2 H
0 O5 U( D3 y. x
Salmonella enterica serotype Typhimurium (S. Typhimurium) causes acute gut inflammation by using its virulence
8 E- J1 D( W" C9 S1 c7 c+ _4 Ifactors to invade the intestinal epithelium and survive in mucosal macrophages. The inflammatory response
9 y0 n* H3 T( |+ `$ I- _enhances the transmission success of S. Typhimurium by promoting its outgrowth in the gut lumen through' f: \; Z! Q2 f4 o0 N2 O
unknown mechanisms. Here we show that reactive oxygen species generated during inflammation react with
! k, \% h- \" Y7 U6 v" zendogenous, luminal sulphur compounds (thiosulphate) to form a new respiratory electron acceptor, tetrathionate.8 A( ]7 y, I! z1 M4 v: V8 i
The genes conferring the ability to use tetrathionate as an electron acceptor produce a growth advantage for S.
2 N+ ]/ U0 V. b& e' t8 d8 cTyphimurium over the competing microbiota in the lumen of the inflamed gut. We conclude that S. Typhimurium
  j4 z- S- \  H3 m6 _" k- G( gvirulence factors induce host-driven production of a new electron acceptor that allows the pathogen to use
5 z* V: `/ p& ~$ w1 Crespiration to compete with fermenting gut microbes. Thus the ability to trigger intestinal inflammation is crucial for
. D  D% T* `, H% G. f# V, ithe biology of this diarrhoeal pathogen.
1 f) D/ M/ F/ f5 ^; a# L% W8 @6 L6. [2010 Research]Piezo1 and Piezo2 Are Essential Components of Distinct Mechanically Activated Cation Channels+ b' _) H' s/ b; P( `
Bertrand Coste,1 Jayanti Mathur,2 Manuela Schmidt,1 Taryn J. Earley,1 Sanjeev Ranade,1
, Q4 W8 B/ H& A; n/ Q- dMatt J. Petrus,2 Adrienne E. Dubin,1 Ardem Patapoutian1,2*
3 ?3 H. @. ^3 v1 I: r
- p5 E5 Y% G& m/ [, U# WMechanical stimuli drive many physiological processes, including touch and pain sensation,; E5 r* B& F! \' a7 L
hearing, and blood pressure regulation. Mechanically activated (MA) cation channel activities
: A. q* u7 P% A1 t- Khave been recorded in many cells, but the responsible molecules have not been identified.$ Z- i8 l8 w% R+ B8 Q8 N5 s
We characterized a rapidly adapting MA current in a mouse neuroblastoma cell line. Expression2 R: S7 P/ M6 l' B, ?/ c
profiling and RNA interference knockdown of candidate genes identified Piezo1 (Fam38A) to be( s; M/ n, H, o
required for MA currents in these cells. Piezo1 and related Piezo2 (Fam38B) are vertebrate
9 Z) i1 U5 {1 @( U: wmultipass transmembrane proteins with homologs in invertebrates, plants, and protozoa.9 \  b) C$ w$ X. ?
Overexpression of mouse Piezo1 or Piezo2 induced two kinetically distinct MA currents. Piezos4 E/ d# j. K4 o, A: T7 ]+ }4 d3 A; _
are expressed in several tissues, and knockdown of Piezo2 in dorsal root ganglia neurons
8 O- O+ i* r' K' jspecifically reduced rapidly adapting MA currents. We propose that Piezos are components of
" n3 c# m4 P8 \7 J8 r. \, X0 b6 LMA cation channels.; T+ h9 @6 D/ \& e9 c4 [
7. [2010 Research]Platelets Amplify Inflammation in Arthritis via Collagen-Dependent Microparticle Production
; G( z* t- w; C: m( bEric Boilard,1 Peter A. Nigrovic,1,2 Katherine Larabee,1 Gerald F. M. Watts,1
7 x3 p6 C9 l% q' i4 l# _; q; MJonathan S. Coblyn,1 Michael E. Weinblatt,1 Elena M. Massarotti,1
3 Q8 L0 m% G3 G" o8 P$ U/ zEileen Remold-O’Donnell,3 Richard W. Farndale,4 Jerry Ware,5 David M. Lee1*; C' J" T* r7 @# y$ R

% M! g3 h% q8 p6 z: lIn addition to their pivotal role in thrombosis and wound repair, platelets participate in* L0 C9 F+ [4 Q/ r' m$ `6 r# ?' k
inflammatory responses. We investigated the role of platelets in the autoimmune disease9 ]# f  \/ C' S2 h: t% ^2 d
rheumatoid arthritis. We identified platelet microparticles—submicrometer vesicles elaborated by5 |- O  y! j- T$ n: m  P
activated platelets—in joint fluid from patients with rheumatoid arthritis and other forms of
# \- d: }: e. ~inflammatory arthritis, but not in joint fluid from patients with osteoarthritis. Platelet, \3 E$ d3 v" Q+ @1 M3 w
microparticles were proinflammatory, eliciting cytokine responses from synovial fibroblasts via1 \/ e8 V# h3 g2 ]/ z
interleukin-1. Consistent with these findings, depletion of platelets attenuated murine
0 Q9 m; X+ v$ Einflammatory arthritis. Using both pharmacologic and genetic approaches, we identified the8 f" V7 y8 H, b3 r
collagen receptor glycoprotein VI as a key trigger for platelet microparticle generation in arthritis9 S3 L% L( S1 S0 H
pathophysiology. Thus, these findings demonstrate a previously unappreciated role for platelets
# ^+ R) i3 X$ \. v: j  O% Xand their activation-induced microparticles in inflammatory joint diseases.$ n! G7 R7 [) p+ o1 b
8. [2010 Research]The architecture of respiratory complex I
* b+ ~3 K1 l5 k- }( s2 wRouslan G. Efremov*, Rozbeh Baradaran* & Leonid A. Sazanov
2 H2 B6 l2 y  S' n- o) h) l" O/ N1 G
Complex I is the first enzyme of the respiratory chain and has a central role in cellular energy production, coupling electron
1 q. T1 o; f+ R- M5 b" P1 mtransfer between NADH and quinone to proton translocation by an unknown mechanism. Dysfunction of complex I has been1 ^0 b* n! Z* E. h
implicated in many human neurodegenerative diseases. We have determined the structure of its hydrophilic domain
3 J* f+ b7 p/ Epreviously. Here, we report the a-helical structure of the membrane domain of complex I from Escherichia coli at 3.9A°0 s! a4 B3 ^, X# I6 T! B% v
resolution. The antiporter-like subunits NuoL/M/Neach contain 14 conserved transmembrane (TM) helices. Two of them are
/ N3 M7 S5 m3 N% l* K! a5 y: Pdiscontinuous, as in some transporters. Unexpectedly, subunit NuoL also contains a 110-A° long amphipathic a-helix, spanning6 ~7 h9 v8 p! i
almost the entire length of the domain. Furthermore, we have determined the structure of the entire complex I from Thermus
4 U6 a4 ]6 H" ]% E2 p. c, u$ Fthermophilus at 4.5A°
4 s  `: X0 U8 y. D) H! u7 p$ wresolution. The L-shaped assembly consists of the a-helicalmodel for themembrane domain, with 63TM
0 t0 h1 t* |- a* g, T) G& Zhelices, and the known structure of the hydrophilic domain. The architecture of the complex provides strong clues about the
& y( y8 B$ j. h0 Xcoupling mechanism: the conformational changes at the interface of the two main domains may drive the long amphipathic
6 S6 r4 h- _2 J# R4 _. q1 y- ja-helix of NuoL in a piston-like motion, tilting nearby discontinuous TM helices, resulting in proton translocation., r8 R! w% E" x4 `3 ^2 M
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发表于 2011-5-6 00:58 |只看该作者
看看啊

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发表于 2011-5-6 02:14 |只看该作者
Thanks for sharing

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积极份子 热心会员 帅哥研究员 优秀会员 小小研究员

报纸
发表于 2011-5-6 10:11 |只看该作者
谢谢

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地板
发表于 2015-5-22 18:43 |只看该作者
老大,我好崇拜你哟  

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发表于 2015-5-27 08:36 |只看该作者
彪悍的人生不需要解释。  

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发表于 2015-7-20 21:35 |只看该作者
不错不错.,..我喜欢  

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发表于 2015-8-4 19:31 |只看该作者
回复一下  

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发表于 2015-8-13 10:43 |只看该作者
一个子 没看懂  
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