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本帖最后由 细胞海洋 于 2011-5-6 00:17 编辑
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# {9 f& s/ x; o+ s" R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。. W& z5 r5 ^+ P& u K, i
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。; q6 B5 Q& L, |# s' d" @. Z
目录:
( w. V% B# G3 w5 p' s3 x% A1.[2010 Research]A Septin Diffusion Barrier at the Base of the Primary Cilium Maintains Ciliary Membrane Protein Distribution 6 [; ~+ J( J# [) P. ? ~
Qicong Hu,1 Ljiljana Milenkovic,2,3 Hua Jin,4 Matthew P. Scott,2,3,5–80 t7 L0 P# I$ m) f
Maxence V. Nachury,4 Elias T. Spiliotis,9* W. James Nelson1,4*9 |" j; n" z, d$ i/ ]
, B0 k+ W* c' }& w* P
In animal cells, the primary cilium transduces extracellular signals through signaling receptors
: ~/ ]. @( Q. `6 m& I7 ulocalized in the ciliary membrane, but how these ciliary membrane proteins are retained in the
/ k e7 H3 c/ h' U8 p* Hcilium is unknown. We found that ciliary membrane proteins were highly mobile, but their
; }# q0 U" I9 x* j3 Mdiffusion was impeded at the base of the cilium by a diffusion barrier. Septin 2 (SEPT2), a member
' u" A: U, j) z ]) R( [8 Cof the septin family of guanosine triphosphatases that form a diffusion barrier in budding yeast,
9 Z/ d2 v4 O* E/ y- \* f, A' A7 Clocalized at the base of the ciliary membrane. SEPT2 depletion resulted in loss of ciliary membrane
$ ~6 q) R; y4 i' n' r$ U* L% _: ]protein localization and Sonic hedgehog signal transduction, and inhibited ciliogenesis. Thus,
: k2 _9 y2 L) j6 Q3 ~2 w' y+ aSEPT2 is part of a diffusion barrier at the base of the ciliary membrane and is essential for
( e/ c- F7 ^! T7 Nretaining receptor-signaling pathways in the primary cilium.) q* i8 o4 M/ X( I4 s) d% e
2. [2010 Research]Cancer Statistics
! u* x5 s: U" S' ]2 _: A3. [2010 Research]Dendritic Cells in Systemic Lupus Erythematosus
' E2 Q: [0 }2 b9 f4 BHeather M. Seitz
! O9 D' h9 w6 h$ N8 T% rJohnson County Community College, Science Division, Overland Park,
& E) D+ [% u b6 ]Kansas, USA8 u2 s; z) x; j( ~/ O1 D2 u$ G
Glenn K. Matsushima# c* h# O# D9 {0 U0 Y
UNC Neuroscience Center, Department of Microbiology & Immunology,
' \& q" C" H4 }7 |Program for Molecular Biology & Biotechnology, University of North0 P% P0 k3 r* y' Y4 @ }/ `
Carolina at Chapel Hill, Chapel Hill, North Carolina, USA4 ^/ ?4 z% T+ ]4 t
* G4 Q4 y9 G7 a# U& u; sSystemic lupus erythematosus (SLE) persists as a chronic inflammatory autoimmune. X; ]* r7 t, }: ~, B, y0 F+ ^- d
disease and is characterized by the production of autoantibodies
1 l I0 Y( O& R5 Nand immune complexes that affect multiple organs. The underlying mechanism8 U* S, b3 a4 A C" z* }
that triggers and sustains disease are complex and involve certain
5 F1 W; Q; v# i4 Lsusceptibility genes and environmental factors. There have been several immune
S' U/ S6 s+ w S& _8 Wmediators linked to SLE including cytokines and chemokines that have
- e3 b. _( R5 d; ~& r6 t9 p9 vbeen reviewed elsewhere [1–3]. A number of articles have reviewed the role
. V; w& M; z8 r1 W( x R6 pof B cells and T cells in SLE [4–10]. Here, we focus on the role of dendritic8 @- D! B" f2 k+ R$ O
cells (DC) and innate immune factors that may regulate autoreactive B cells.& {* v( ^8 V6 p' L' G3 C# U
4. [2010 Research]Differential immunophenotypic analysis of dendritic cell tumours; k& }# ?2 q- d6 t4 y9 K# G' E$ b& V# w. `
Tomohiko Orii,1,2 Hiroaki Takeda,2 Sumio Kawata,2 Kunihiko Maeda,10 I/ e g2 }5 M; j
Mitsunori Yamakawa1
( P- @: R4 {# h* N- x% P# o" `# E* Q. d; z. L+ @
ABSTRACT0 m9 C. ~4 R7 {4 a: F% J" a
Aims The phenotypic and biological characteristics of
' ^1 |( p, q( y7 C8 {4 d6 Z) ?dendritic cell (DC) tumours have not been fully+ C3 O4 x! u$ I+ J7 I" G, z
elucidated. The aim of this study was to compare the
8 s- H: u9 F3 f; l& fimmunophenotypic characteristics of DC-related markers
# z% `, r7 ~1 Fand cell-cycle-associated markers among DC tumours
5 y/ e0 C# t6 b2 c: oand finally to utilise them for differential diagnosis of DC+ n+ v$ t0 G; O z; ^7 J4 f
tumours.! D3 N4 l. \* m0 J0 R8 U
Methods Tissue sections from 28 patients with DC0 Y- M) _2 H5 S& P! r0 a
tumours were immunohistochemically examined using
- j/ Y1 v6 U: g7 I7 |DC-related and cell-cycle-associated markers.0 {. e1 H1 K8 d7 m- I8 E% d
Results The Langerhans cell histiocytosis (LCH) and. j$ `1 M( J6 K5 x4 g) a& R( }% n
Langerhans cell sarcoma (LCS) samples were positive for
# d9 P( Q4 G5 {6 CS-100 protein, CD1a, Langerin, fascin, DEC-205 and DCSIGN.
~! D% A4 b( [4 }9 d* DInterdigitating dendritic cell sarcoma (IDCS) was5 l7 ?! b0 Z$ {. l3 @9 }& n9 ~
positive for S-100 protein and fascin and negative for0 S+ D2 a+ L; i# }$ a
Langerin. In addition, two IDCS samples were positive for
5 Y) i) i2 D/ E1 n# n# rCD1a, DEC-205 and DC-SIGN. The labelling indices of
; e, ]- ` R" BKi-67, cyclin A, cyclin B1 and acetylated histone H3 on the* |" W P1 m) M) H
LCS and IDCS specimens were significantly higher than
) `% u* |2 {! @9 ?# n9 m+ n8 Wthose on the LCH specimens. The expression of p53 was
" w2 z9 y0 @( Jalso significantly higher in the LCS specimens than in the3 e. y! e: v( p) [3 h4 w. @7 |
LCH specimens. The numbers of infiltrating CD123+ and( |$ @! {4 u$ _5 Z* V# k+ \
FOXP3+ cells were also significantly higher in the LCS+ }9 g) _2 B, F" x/ d
samples than in the LCH and IDCS samples. Follicular, u1 Q/ N2 u/ V6 j
dendritic cell sarcoma was distinguished from other DC
4 g/ O# p& f2 T1 otumours by the lack of DC-SIGN, Langerin and DCE-205.
* a( @0 L% ]" [% `# A2 WConclusions These results suggest that Langerin can be: ]' H- ^ }! a4 `2 l9 E
used to distinguish LCS from IDCS, and DC-SIGN and) {1 s7 {0 n0 J6 r$ ~" Q* q6 c
DEC-205 can be used to identify DC tumour cells. The+ L6 \0 y3 p2 B0 v8 I
frequency of cell-cycle-associated markers can be used
8 `% o9 z* `4 r2 k" E4 p0 hfor the differential diagnosis of malignant and benign DC tumours." ^6 Y6 q( A d @# x- e6 Y3 ]
5. [2010 Research]Gut inflammation provides a respiratory electron acceptor for Salmonella
" Z- h( {- k/ h. s3 Y" mSebastian E. Winter1, Parameth Thiennimitr1,2, Maria G. Winter1, Brian P. Butler1, Douglas L. Huseby3, Robert W. Crawford1,
2 I; ]' Y2 X/ Y w. w8 K+ DJoseph M. Russell1, Charles L. Bevins1, L. Garry Adams4, Rene′e M. Tsolis1, John R. Roth3 & Andreas J. Ba¨umler1
+ ]6 D/ t, v6 i) [- A
" R) d9 r* e; L2 r6 }7 TSalmonella enterica serotype Typhimurium (S. Typhimurium) causes acute gut inflammation by using its virulence! U$ Z" a) K$ ^, e- h" D
factors to invade the intestinal epithelium and survive in mucosal macrophages. The inflammatory response
. M2 L! U7 n% z* L& B; zenhances the transmission success of S. Typhimurium by promoting its outgrowth in the gut lumen through
# U2 f+ b6 n- }0 s$ F+ d. zunknown mechanisms. Here we show that reactive oxygen species generated during inflammation react with; Q# y: ~5 a+ @) U- Y W
endogenous, luminal sulphur compounds (thiosulphate) to form a new respiratory electron acceptor, tetrathionate.
9 V, M; {, A/ t7 S5 mThe genes conferring the ability to use tetrathionate as an electron acceptor produce a growth advantage for S.
& _. H( a1 |1 n# W1 V! K. E7 HTyphimurium over the competing microbiota in the lumen of the inflamed gut. We conclude that S. Typhimurium
* K7 D& q9 M* [& [virulence factors induce host-driven production of a new electron acceptor that allows the pathogen to use( ~+ ]. m: d- ~( s
respiration to compete with fermenting gut microbes. Thus the ability to trigger intestinal inflammation is crucial for" v% C4 n8 K, [4 q# l
the biology of this diarrhoeal pathogen.
! t. s8 w/ e" G, ~2 ~2 p7 R6. [2010 Research]Piezo1 and Piezo2 Are Essential Components of Distinct Mechanically Activated Cation Channels. ]- n+ S" g( @ J% n7 G
Bertrand Coste,1 Jayanti Mathur,2 Manuela Schmidt,1 Taryn J. Earley,1 Sanjeev Ranade,17 O: u7 K+ {& a0 Z7 J& M! P4 o
Matt J. Petrus,2 Adrienne E. Dubin,1 Ardem Patapoutian1,2*" D4 B C1 u# {9 L- m
& W+ h* n. P1 D3 T* _$ H
Mechanical stimuli drive many physiological processes, including touch and pain sensation,
0 h5 K* }; m' b, w7 v' m1 V7 lhearing, and blood pressure regulation. Mechanically activated (MA) cation channel activities
4 S* X: k& e/ ~3 [, @* g* ihave been recorded in many cells, but the responsible molecules have not been identified.# [! k b# Z9 {& E. z9 n; y& Y' k
We characterized a rapidly adapting MA current in a mouse neuroblastoma cell line. Expression# B7 O, ]3 g( `) J! b# w( c
profiling and RNA interference knockdown of candidate genes identified Piezo1 (Fam38A) to be
9 D5 T! Y0 {# F2 l4 q5 c; qrequired for MA currents in these cells. Piezo1 and related Piezo2 (Fam38B) are vertebrate" l# j) Y6 Z, V4 H* {/ f
multipass transmembrane proteins with homologs in invertebrates, plants, and protozoa./ B9 i8 @6 q( w" L
Overexpression of mouse Piezo1 or Piezo2 induced two kinetically distinct MA currents. Piezos8 C5 e4 e. e c N l- H; y/ D! W
are expressed in several tissues, and knockdown of Piezo2 in dorsal root ganglia neurons
* N* @2 ^2 y: H# I6 f h% V) ospecifically reduced rapidly adapting MA currents. We propose that Piezos are components of( @: y3 k2 j4 n8 ^
MA cation channels.% ?$ W3 G' k5 U; X! o* F7 g
7. [2010 Research]Platelets Amplify Inflammation in Arthritis via Collagen-Dependent Microparticle Production
6 V2 L* b$ \5 x3 A$ GEric Boilard,1 Peter A. Nigrovic,1,2 Katherine Larabee,1 Gerald F. M. Watts,1: y( I; R! N& `: l" _# b; }5 I
Jonathan S. Coblyn,1 Michael E. Weinblatt,1 Elena M. Massarotti,15 ^* G# R" F! I1 i
Eileen Remold-O’Donnell,3 Richard W. Farndale,4 Jerry Ware,5 David M. Lee1*; k0 E& F7 D; C% R
" C. r' P5 W. Y. M. ]- ^8 k) C! f' b
In addition to their pivotal role in thrombosis and wound repair, platelets participate in& O5 n) I& \, Q' B" E' }
inflammatory responses. We investigated the role of platelets in the autoimmune disease
7 ~ \6 ]6 k( @9 b7 Yrheumatoid arthritis. We identified platelet microparticles—submicrometer vesicles elaborated by
2 `- _8 o0 h, U Bactivated platelets—in joint fluid from patients with rheumatoid arthritis and other forms of
* z5 D1 q" D% b. I6 |5 M# C! K4 N: Ginflammatory arthritis, but not in joint fluid from patients with osteoarthritis. Platelet
. Q: q- L# Z; }3 m! T) _- Cmicroparticles were proinflammatory, eliciting cytokine responses from synovial fibroblasts via
2 ~. v! {0 S% Binterleukin-1. Consistent with these findings, depletion of platelets attenuated murine% L$ ^, _* } a8 D8 }
inflammatory arthritis. Using both pharmacologic and genetic approaches, we identified the8 p0 w) r5 K! @& s% i7 Z
collagen receptor glycoprotein VI as a key trigger for platelet microparticle generation in arthritis
9 i8 o9 ]: c" p: E9 A9 B5 T8 {pathophysiology. Thus, these findings demonstrate a previously unappreciated role for platelets1 W5 ^: `, Q4 x, F! B( h0 ?
and their activation-induced microparticles in inflammatory joint diseases.4 [; @* G# o: h7 L
8. [2010 Research]The architecture of respiratory complex I3 U1 F# ?) P/ C; ^
Rouslan G. Efremov*, Rozbeh Baradaran* & Leonid A. Sazanov
+ O7 s5 f$ ~9 M6 E7 b
! r% Z. E; d8 Y% A/ hComplex I is the first enzyme of the respiratory chain and has a central role in cellular energy production, coupling electron4 Q: S/ g6 \6 L( N7 C! z. z
transfer between NADH and quinone to proton translocation by an unknown mechanism. Dysfunction of complex I has been/ E1 v2 B }2 d* E
implicated in many human neurodegenerative diseases. We have determined the structure of its hydrophilic domain
3 ^: K y0 c2 @4 p. u: f: @% S, H' opreviously. Here, we report the a-helical structure of the membrane domain of complex I from Escherichia coli at 3.9A°. T) o& u" P" f; E
resolution. The antiporter-like subunits NuoL/M/Neach contain 14 conserved transmembrane (TM) helices. Two of them are# ]& W6 R+ M, k# q, Q) h
discontinuous, as in some transporters. Unexpectedly, subunit NuoL also contains a 110-A° long amphipathic a-helix, spanning
+ \) A. Q6 i' b }) i Ealmost the entire length of the domain. Furthermore, we have determined the structure of the entire complex I from Thermus: z6 [5 n* B( R2 U
thermophilus at 4.5A°
* ^- U" H5 W# [4 {6 |4 ^resolution. The L-shaped assembly consists of the a-helicalmodel for themembrane domain, with 63TM2 _+ T. F5 c$ i7 w& v4 j
helices, and the known structure of the hydrophilic domain. The architecture of the complex provides strong clues about the
! Z V/ z+ {6 E4 }) Q5 @coupling mechanism: the conformational changes at the interface of the two main domains may drive the long amphipathic8 n3 Z4 V; G7 I3 A- N
a-helix of NuoL in a piston-like motion, tilting nearby discontinuous TM helices, resulting in proton translocation." }5 u$ \4 Y9 ~6 v7 |" q$ n. Z$ g
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