<p align="center"><span><font face="Times New Roman">Postdoctoral Positions<p></p></font></span></p><p></p><p></p><p align="center"><span><font face="Times New Roman">in neurodevelopment and synaptic plasticity<p></p></font></span></p><p></p><p></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Postdoctoral positions are available to investigate molecular mechanisms of how synapses form and how their structure and function change under physiological as well as pathological conditions. Representative papers of the laboratory include N<span>euron</span> 26:443, 2000; <span>Neuron</span> 35:489, 2002; <span>Nature Neurosci. </span>7:1250, 2004; <span>Nature Cell Biol.</span>
<span>7:1124, 2005; </span><personname wst="on"></personname><givenname wst="on"></givenname><span>J.</span><givenname></givenname><span>
<sn wst="on"></sn>Neurosci<sn></sn></span><personname></personname><span>. </span>27:3968, 2007; <span>Neuron </span>54:599, 2007; and <span>Neuron </span>54:583, 2007 (for more information, please visit </font><a href="http://www.mcg.edu/institutes/immag/meilab/index.htm"><font face="Times New Roman">http://www.mcg.edu/institutes/immag/meilab/index.htm</font></a><font face="Times New Roman">). The positions require PhD in life sciences. Successful candidates are high-motivated and self-driven individuals and will have the opportunity to develop and carry out exciting projects using multidisciplinary approaches including <span lang="EN-GB">molecular biology, electrophysiology, and behavioural analysis. Immediate projects focus on pathophysiological mechanisms of neurological and psychiatric disorders including schizophrenia, epilepsy, ALS, and muscular dystrophy. The</span> Medical College of Georgia is located in <city wst="on"></city>Augusta<city></city>, <country-region wst="on"></country-region>Georgia<country-region></country-region>, a small city on the <place wst="on"></place>Savannah River<place></place> famous for the Masters gold tournament and enriched life. Interested candidates should send <span lang="EN-GB">CV, statement of research interests, and contact information of three references to Dr. </span>Lin Mei at </font><a href="mailto:lmei@mcg.edu"><font face="Times New Roman">lmei@mcg.edu</font></a><font face="Times New Roman">. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p>
<font face="Verdana" size="2">Ron Yu, a postdoc from Axel lab, now run his own lab at Stowers Institute, have a postdoc position avariable (see details in the website </font><a href="http://www.stowers-institute.org/labs/YuLab.asp" target="_blank"><font face="Verdana" color="#800080" size="2">http://www.stowers-institute.org/labs/YuLab.asp</font></a><font face="Verdana" size="2">). </font>
<p><b><span><font face="Times">Postdoctoral Fellow positions at <place wst="on"></place><placename wst="on"></placename>Duke<placename></placename>
<placetype wst="on"></placetype>University<placetype></placetype><place></place>
<p></p></font></span></b></p><p></p><p></p><p></p><p><font face="Times"></font></p><p></p><p><span><font face="Times">We are looking for postdoctoral fellows to join our team to study the function of HDAC members and reversible protein acetylation in cell signaling and human disease. Our current focus is to elucidate the functional intersection of HDAC members with <i>autophagy machinery in neurodegeneration</i>, <i>mitochondria in cancer metabolism</i>, and <i>skeletal muscle remodeling in neuromuscular disease and muscle atrophy</i> (see <city wst="on"></city><place wst="on"></place>Kawaguchi<place></place><city></city> et. al. <b>Cell. </b>115. 727-738, (2003), Kovacs et. al <b>Molecular Cell</b> 18 601-607 (2005), <sn wst="on"></sn>Bolger<sn></sn>, et. <b>J. Neuroscience</b>
<span>25(41):9544-53 (2005)</span>, Pandey et. <sn wst="on"></sn>al<b> Nature</b><sn></sn><b>. </b><span>447:859-63 (2007), and</span>
<sn wst="on"></sn>Cohen<sn></sn> et. al,<span> </span><b>J. Biol. Chem.</b> 282(46):3375 (2008)). Individuals with experience working with mouse models are particularly encouraged to apply. Interested candidates should send curriculum vitae to: yao00001@mc.duke.edu<p></p></font></span></p><p></p><p></p><p><span><p><font face="Times"></font></p></span></p><p><font face="Times"></font></p><p></p><p><span><font face="Times">Tso-Pang <city wst="on"></city><place wst="on"></place>Yao<place></place><city></city>,<span> </span>Ph.D.<p></p></font></span></p><p></p><p></p><p><span><font face="Times">Associate Professor<p></p></font></span></p><p></p><p></p><p><span><font face="Times">Department of Pharmacology and Cancer Biology<p></p></font></span></p><p></p><p></p><p><font face="Times"><place wst="on"></place><placename wst="on"></placename><span>Duke</span><placename></placename><span>
<placetype wst="on"></placetype>University<placetype></placetype></span><place></place><span><p></p></span></font></p><p></p><p></p><p><place wst="on"></place><font face="Times"><city wst="on"></city><span>Durham</span><city></city><span>, <state wst="on"></state>North Carolina<state></state>, <country-region wst="on"></country-region>USA<country-region></country-region></span></font><place></place><span><p></p></span></p><p></p><p></p>
<p>"it is ok to ask some outstanding candidates from <br/>other labs - just find out if they are indeed technically excellent, <br/>has at least 1 first author paper in a good journal , and preferably can speak English some. The projects here <br/>will be Katp channels, using primary cells (islet beta cells, maybe <br/>cardiac myocytes) and cell lines, whole cell and inside-out <br/>congiruation (for cell lines - COS, HEK). We are also doing <br/>pancreatic slice - like braine slice, to patch on intact islets )- so brain slice patch clampers are also <br/>welcome."</p><p>This lab is in Medicine and Physiology University of Toronto, The boss is very nice and their lab has published several >10 papers. someone interested in this could send email to <a href="mailto:wybiophysics@yahoo.com.cn">wybiophysics@yahoo.com.cn</a></p>
Please suggest the lab to your classmates if any of them are looking for<br/>postdoc in US and have interest in neurodegeneration area. The lab am<br/>particulary interested in students with electrophysiological training.<br/><br/>The lab of Dr. Ilya Bezprozvanny is focused on studies of neuronal calcium<br/>signaling in connection with neurodegenerative disorders (HD and AD).<br/><br/> Please take a look at discription of our projects, papers and people on<br/>the lab's website:<br/><br/> <a href="http://www4.utsouthwestern.edu/ilya">http://www4.utsouthwestern.edu/ilya</a><br/><br/> If you are interested in doing postdoc in the lab, please contact Dr.<br/>Ilya Bezprozvanny<br/><br/> Dr. Ilya Bezprozvanny<br/> Professor of Physiology, Carla Cocke Francis Professor in Alzheimer's<br/> Research<br/> Dept of Physiology, ND12.502B<br/> UT Southwestern Medical Center at Dallas<br/> 5323 Harry Hines Blvd.<br/> (for FedEx: 6001 Forest Park)<br/> Dallas, TX 75390-9040<br/> USA<br/><br/> tel: (214) 645-6017<br/> fax: (214) 645-6018<br/> E-mail: <a href="mailto:%20Ilya.Bezprozvanny@UTSouthwestern.edu">Ilya.Bezprozvanny@UTSouthwestern.edu</a><br/> Web: <a href="http://www4.utsouthwestern.edu/ilya">http://www4.utsouthwestern.edu/ilya</a><br/>
POSTDOCTORAL OPPORTUNITY<br/>Christopher Pittenger, MD, Ph.D.<br/>Department of Psychiatry<br/>Yale University<br/>We are exploring the striatal mechanisms of normal and pathological habit learning.<br/>Automated, relatively inflexible execution of habit-like patterns of behavior and thought<br/>constitute a large percentage of an organism’s behavioral repertoire, especially in a<br/>familiar environment. Significant evidence suggests that the dorsal striatum – the input<br/>nucleus of the basal ganglia – plays a substantial role in both the forming and the<br/>execution of such behavioral patterns. Dysregulated habits contribute to many<br/>psychiatric disorders, including Tourette syndrome, obsessive-compulsive disorder, and<br/>drug addiction. However, the molecular, cellular, and network mechanisms underlying<br/>habit learning remain poorly understood, in part because analyses in genetically modified<br/>mice have only very recently been brought to bear on this class of behaviors (see, for<br/>example, Pittenger et al, J. Neurosci. 2006).<br/>The laboratory uses a combination of pharmacological, transgenic and virus-delivered<br/>molecular manipulations to dissect the mechanisms of habit learning, and both<br/>established and novel behavioral analyses to parse the consequences of such<br/>manipulations. A theme is maximum spatial and cell-type specificity of such<br/>manipulations; we are developing methods to target manipulations to defined populations<br/>of striatal interneurons, examining their role in the orchestration of striatal network<br/>activity and information processing. Another theme is systems-level interactions; recent<br/>behavioral work highlights the sometimes competitive interactions between striatumdependent<br/>and hippocampus-dependent learning. Finally, we have a strong interest in<br/>psychiatric disorders in which striatal function and habit learning are disrupted; we are<br/>actively pursuing to distinct models of Tourette syndrome.<br/>The Division of Molecular Psychiatry is an unusually collaborative group of laboratories,<br/>with expertise ranging from proteomics to behavioral analysis. The Pittenger laboratory<br/>is funded by the National Institute of Mental Health, NARSAD, the American Psychiatric<br/>Association, and the Tourette Syndrome Association of America. We will be moving<br/>into large, brand new laboratory space in the fall of 2008.<br/><a href="http://info.med.yale.edu/psych/faculty/pittenger.htm">http://info.med.yale.edu/psych/faculty/pittenger.htm</a><br/><a href="http://info.med.yale.edu/neurosci/faculty/pittenger_research_statement.pdf">http://info.med.yale.edu/neurosci/faculty/pittenger_research_statement.pdf</a><br/>203-974-7675<br/><a href="mailto:Christopher.pittenger@yale.edu">Christopher.pittenger@yale.edu</a>
Stanford University<br/>POSTDOCTORAL POSITION<br/>A postdoctoral position will be available in my group starting in the fall of 2008 to<br/>work on problems at the interface of physics, chemistry and neurobiology.<br/>Research will employ quantitative tools including single molecule imaging and<br/>microfluidic technologies to quantify biological events inside neurons. Current<br/>topics of interest are axonal transport, neurotrophin signaling and neuronal<br/>network topology. A Ph.D. degree in physics, chemistry, or neuroscience is<br/>preferred. Candidates with both biophysics and neuroscience backgrounds are<br/>strongly encouraged to apply.<br/>Interested applicants should send curriculum vitae, and arrange for references<br/>sent to (e-mail preferred):<br/>Bianxiao Cui, Assistant Professor of Chemistry<br/>URL: <a href="http://www.stanford.edu/dept/chemistry/faculty/cui/index.html">http://www.stanford.edu/dept/chemistry/faculty/cui/index.html</a><br/>Email: <a href="mailto:bcui@stanford.edu">bcui@stanford.edu</a>
<p><font face="Times New Roman">A Postdoctoral position is available for an electrophysiologist with interest in molecular biology in Dr. Zhengping Jia’s laboratory, Department of Physiology, University of Toronto; Neurosciences & Mental Health, The Hospital for Sick Children; Toronto, Canada. The primary assignment of this postdoctoral position would be studies of hippocampal synaptic plasticity on various strains of transgenic mice. Techniques include whole-cell recordings and molecular manipulations such as viral vector-mediated gene expression.</font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><a href="http://www.sickkids.ca/HSCdirectory/personalprofile.asp?pID=3715&s=Research+Programs&sID=1104&ss=Neurosciences+%26+Mental+Health&ssID=378&sss=&sssID"><font face="Times New Roman">http://www.sickkids.ca/HSCdirectory/personalprofile.asp?pID=3715&s=Research+Programs&sID=1104&ss=Neurosciences+%26+Mental+Health&ssID=378&sss=&sssID</font></a><font face="Times New Roman">=</font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><a href="http://www.uoftphysiology.com/faculty/members/facultyDetails.cfm?faculty=39&from=facultyList"><font face="Times New Roman">http://www.uoftphysiology.com/faculty/members/facultyDetails.cfm?faculty=39&from=facultyList</font></a></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><u><font face="Times New Roman">Select publications:<p></p></font></u></p><p></p><p></p><p></p><p></p><p><font face="Times New Roman">Meng J, Meng Y, Hanna A, Janus C, Jia Z. <b>Abnormal long-lasting synaptic plasticity and cognition in mice lacking the mental retardation gene Pak3. </b>J Neurosci. 2005 Jul 13;25(28):6641-50.</font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Meng Y, Zhang Y, Tregoubov V, Falls DL, Jia Z. <b>Regulation of spine morphology and synaptic function by LIMK and the actin cytoskeleton. </b>Rev Neurosci. 2003;14(3):233-40. Review.</font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Meng Y, Zhang Y, Jia Z. <b>Synaptic transmission and plasticity in the absence of AMPA glutamate receptor GluR2 and GluR3. </b>Neuron. 2003 Jul 3;39(1):163-76.</font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Meng YH, Zhang Y, Tregoubov V, Janus C, Cruz L, Jackson M, Lu WY, MacDonald JF, Wang J, Falls DL, Jia ZP. <b>Abnormal spine morphology and enhanced LTP in LIMK-1 knockout mice.</b> Neuron. 35: 121-133, 2002. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Peng X, Jia ZP, Zhang Y, Ware J, Trimble, W. <b>The septin CDCrel-1 is dispensable for normal development and neurotransmitter release.</b> Molecular and Cellular Biology. 22 (1): 378-387, 2002. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Henderson J, Georgiou J, Jia ZP, Robertson J, Elowe S, Roder J, Pawson T. <b>The receptor tyrosine kinase EphB2 regulates NMDA-dependent synaptic function.</b> Neuron. 32: 1041-1056, 2001. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Lei S, Jackson M, Jia ZP, Roder J, Bai D, Orser BA, MacDoanld JF. <b>Cyclic GMP-dependent feedback inhibition of AMPA receptors is independent of PKG.</b> Nature Neuroscience. 3(6):559-565, 2000. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Gerlai R, Henderson J, Roder J, Jia ZP. <b>Multiple behavioral anomalies in GluR2 mutant mice exhibiting enhanced LTP.</b> Behav. Brain Res. 95(1):37-45, 1999. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Jia ZP, Lu Y-M, Henderson J, Taverna F, Romano C, Abramow-Newerly W, Wojtowicz M, Roder J. <b>Selective abolition of the NMDA component of long term potentiation in mice lacking mGluR5.</b> Learning & Memory. 5: 331-343, 1998. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Mainen ZF, Jia ZP, Roder J, Malinow R. <b>Use-dependent AMPA receptor block in mice lacking GluR2 suggests postsynaptic site for LTP expression.</b> Nature Neuroscience. 1(7):579-586, 1998. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Jia ZP, Agopyan N, Miu P, Xiong Z, Henderson J, Gerlai R, Taverna F, Velumian A, MacDonald J, Carlen P, Abramow-Newerly W, Roder J, <b>Enhanced LTP in mice deficient in the AMPA receptor GluR2.</b> Neuron. 17:945-956, 1996. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Hahnenberger KM, Jia ZP, Young PG. <b>Functional expression of the Schizosaccharomyces pombe Na+/H+ antiporter gene, sod2, in saccharomyces cerevisiae.</b> PNAS <place wst="on"></place><place></place><country-region wst="on"></country-region><country-region></country-region>USA<country-region></country-region><country-region></country-region><place></place><place></place>. 93, 5031-5036, 1996. </font></p><p></p><p><font face="Times New Roman"></font></p><p></p><p><font face="Times New Roman">Jia ZP, McCullough N, Martel R, Hemmingsen S, Young PG. <b>Gene amplification at a locus encoding a putative Na+/H+ antiporter confers sodium and lithium tolerance in fission yeast.</b> EMBO J. 11: 1631-1640, 1992.</font></p>
<div><font face="Verdana" color="#222222" size="-4"><b>Postdoctoral Position-A Gap Junction-Dependent Cell Network Establishes Left-Right Neuronal Asymmetry</b></font></div><div><br/></div><div><font face="Verdana" color="#222222" size="-4">Gap junctions are prominent features that link immature cells in the nervous system of both invertebrates and vertebrates. However, little is known about the functional consequences of these interactions. We recently showed for the first time that signaling through gap junctions coordinates a network of cells to establish left-right asymmetry in the nervous system of C. elegans that is reflected in olfactory gene expression and function (Chuang et. al., Cell 2007). We are interested in understanding the molecular mechanisms of left-right neuronal asymmetry by this gap junction-dependent cell network. To learn more about the lab, please visit</font></div><div><font face="Verdana" color="#222222" size="-4"><br/></font><font face="Verdana" color="#cc3333" size="-4"><u>http://www.cincinnatichildrens.org/research/div/dev-biology/fac-labs<span></span>/chuang/</u></font><font face="Verdana" color="#222222" size="-4"><br/></font><font face="Verdana" color="#cc3333" size="-4"><u>http://neuroscience.uc.edu/faculty/person.cfm?NeuroID=180</u></font></div><div><font face="Verdana" color="#222222" size="-4"><br/>Applicants should have a Ph.D. degree (for less than three years) in genetics, cell biology, molecular biology, neurobiology, biochemistry or similar with experience in molecular biology techniques. Candidates with prior experience in electrophysiological recordings or calcium imaging or microarray are encouraged to apply. Interested and qualified candidates please send a brief cover letter describing research experience and interest, CV, pdf files of first-author publications from peer-reviewed journals, and names and contact information of at least two references to Dr. Chiou-Fen Chuang at</font><font face="Verdana" color="#cc3333" size="-4"><u> Chiou-Fen.Chuang@cchmc.org</u></font><font face="Verdana" color="#222222" size="-4">.</font></div><div><font face="Verdana" color="#222222" size="-4"><br/>References:<br/>Gabel, C. V., Antonie, F., Chuang, C.-F., Samuel, A. D., and Chang, C. (2008). Distinct cellular and molecular mechanisms mediate initial axon development and adult-stage axon regeneration in C. elegans. Development 135, 1129-1136.</font></div><div><font face="Verdana" color="#222222" size="-4"><br/></font></div><div><font face="Verdana" color="#222222" size="-4">Chuang, C.-F., VanHoven, M. K., Fetter, R. D., Verselis, V. K., and Bargmann, C. I. (2007). An innexin-dependent cell network establishes left-right neuronal asymmetry in C. elegans. Cell 129, 787-799.</font></div><div><font face="Verdana" color="#222222" size="-4"><br/></font></div><div><font face="Verdana" color="#222222" size="-4">Chuang, C.-F. and Bargmann, C. I. (2005). A Toll-interleukin 1 repeat protein at the synapse specifies asymmetric odorant receptor expression via ASK1 MAPKKK signaling. Genes & Dev. 19, 270-281.</font></div><div><br/></div>
Electrophysiology<br/>Postdoctoral Position<br/>Department of Neuroscience<br/>Howard Hughes Medical<br/>Institute at Johns Hopkins<br/>University<br/>Postdoctoral Position in Neuroscience<br/>A Postdoctoral Fellow position is available to study the mechanisms<br/>controlling synaptic transmission and synaptic plasticity. Our<br/>laboratory uses molecular, cellular and electrophysiological approaches<br/>to study the regulation of synaptic transmission and synaptic structure<br/>that underlie synaptic plasticity. An electrophysiologist trained in whole<br/>cell recording techniques is needed for studies to analyze synaptic<br/>function combining electrophysiology, two-photon uncaging and live<br/>imaging techniques. Applicants should have experience in whole cell<br/>electrophysiological techniques. Applicants should send a CV and the<br/>names of three references to the address listed below.<br/>Richard L. Huganir<br/>Department of Neuroscience<br/>Howard Hughes Medical Institute<br/>Johns Hopkins University School of Medicine<br/>Baltimore, MD 21205<br/>rhuganir@jhmi.edu