Insulin from the β-cells of the pancreatic islets of Langerhans controls energy homeostasis in vertebrates, and its deficiency causes diabetes mellitus. During embryonic development, the transcription factor Neurogenin3 initiates the differentiation of the β-cells and other islet cell types from pancreatic endoderm, but the genetic program that subsequently completes this differentiation remains incompletely understood. Here we show that the transcription factor Rfx6 directs islet cell differentiation downstream of Neurogenin3. Mice lacking Rfx6 failed to generate any of the normal islet cell types except for pancreatic-polypeptide-producing cells. In human infants with a similar autosomal recessive syndrome of neonatal diabetes, genetic mapping and subsequent sequencing identified mutations in the human RFX6 gene. These studies demonstrate a unique position for Rfx6 in the hierarchy of factors that coordinate pancreatic islet development in both mice and humans. Rfx6 could prove useful in efforts to generate β-cells for patients with diabetes.
Summary Episodic memory retrieval is thought to involve reinstatement of the neurocognitive processes engaged when an episode was encoded. Prior fMRI studies and computational models have suggested that reinstatement is limited to instances in which specific episodic details are recollected. We used multi-voxel pattern-classification analyses of fMRI data to investigate how reinstatement is associated with different memory judgments, particularly those accompanied by recollection versus a feeling of familiarity (when recollection is absent). Classifiers were trained to distinguish between brain activity patterns associated with different encoding tasks, and were subsequently applied to recognition-related fMRI data to determine the degree to which patterns were reinstated. Reinstatement was evident during both recollection- and familiarity-based judgments, providing clear evidence that reinstatement is not sufficient for eliciting a recollective experience. The findings are interpreted as support for a continuous, recollection-related neural signal that has been central to recent debate over the nature of recognition memory processes.
The re-use of previously validated designs is critical to the evolution of synthetic biology from a research discipline to an engineering practice. Here we describe the Synthetic Biology Open Language (SBOL), a proposed data standard for exchanging designs within the synthetic biology community. SBOL represents synthetic biology designs in a communitydriven, formalized format for exchange between software tools, research groups and commercial service providers. The SBOL Developers Group has implemented SBOL as an XML/RDF serialization and provides software libraries and specification documentation to help developers implement SBOL in their own software. We describe early successes, including a demonstration of the utility of SBOL for information exchange between several different software tools and repositories from both academic and industrial partners. As a community-driven standard, SBOL will be updated as synthetic biology evolves to provide specific capabilities for different aspects of the synthetic biology workflow.Synthetic biology treats biological organisms as a new technological medium with a unique set of characteristics, such as the ability to self-repair, evolve and replicate. These characteristics create their own engineering challenges, but offer a rich and largely untapped source of potential applications across a broad range of sectors 1,2 . Applications such as biomolecular computing 3 , metabolic engineering 4 , or reconstruction and exploration of natural cell biology 5,6 commonly require the design of new genetically encoded systems. As engineers, synthetic biologists most often base their designs on previously described 'DNA segments' (see Supplementary Table 1 for definitions of selected terms) to meet their design requirements. Reuse of the DNA sequence for these segments involves their exchange between laboratories and their hierarchical composition to form devices and systems with higher level function.Every engineering field relies on a set of 'standards' 7 that practitioners follow to enable the exchange and reuse of designs for 'systems' , 'devices' and 'components' . Similarly, the representation of synthetic biology designs using computer-readable 'data standards' has the potential to facilitate the forward engineering of novel biological systems from previously characterized devices and components. For example, such standards could enable synthetic biology companies to offer catalogs of devices and components by means of computerreadable data sheets, just as modern semiconductor companies do for electronics. Such standards could also enable a synthetic biologist to develop portions of a design using one software tool, refine the design using another tool, and finally transmit it electronically to a colleague or commercial fabrication company.In order for synthetic biology designs to scale up in complexity, researchers will need to make greater use of specialized design tools and parts repositories. Seamless inter-tool communication would, for example, allow the separation of gene...
The neural correlates of episodic memory retrieval ("recollection") differ according to the type of information contained in the recollected episode. Such content-specific recollection effects have been hypothesized to reflect the reinstatement of processes or representations active during encoding. Using event-related functional magnetic resonance imaging, we evaluated this hypothesis by directly contrasting the neural activity elicited during the encoding and subsequent recollection of words studied with one of 2 encoding tasks. Study words appearing on pictures of scenes required imagining the word's referent at any location within the scene, whereas words appearing on a blank background required generating a sentence that incorporated the word. On a later memory test, the neural correlates of recollection were operationalized by contrasting the activity elicited during correct "remember" versus "know" responses. Recollected words from the "scene" task elicited activity in regions of left occipital cortex and anterior fusiform gyrus that overlapped regions where encoding-related activity was greater for the scene than sentence task. Conversely, activity elicited by words recollected from the "sentence" task overlapped with a region of ventromedial frontal cortex where encoding-related activity was greater for the sentence task. These content-specific associations between encoding- and recollection-related neural activity strongly support the reinstatement hypothesis of episodic retrieval.
Like expression of other cell-type-specific genes, expression of the insulin gene depends on the actions of a unique set of nuclear activators. These activators cooperate synergistically in building a transcriptional activation complex that binds to the regulatory domains of the gene and activates the basal RNA polymerase machinery (reviewed in reference 7). The complexity and specificity of the interactions among these activators limit the cell types capable of building a functional activation complex. Dissection of these interactions provides insight into the mechanism by which insulin expression is limited to the correct cell type.In adult mammals, activation of the insulin gene is tightly restricted to the  cells in the pancreatic islets of Langerhans, where it is expressed at high levels. This specificity is reflected in the restricted function of the insulin promoter, the proximal few hundred base pairs of which can replicate the specificity of the intact gene (19,50). Because of the complexity of the intact promoter (9, 13, 24), a short portion of the rat insulin I promoter between bp Ϫ247 and Ϫ197 upstream from the transcription initiation site has been used as a model of the types of synergistic interactions that combine to give the characteristic activity of the full promoter (15). This 50-bp fragment contains at least three distinct DNA-binding sites named E2, A3, and A4 (13). The E and A elements synergize: neither has significant activity on its own, but in combination E and A elements produce -cell specific transcriptional activation (15,23).The E2 element functions as a recognition site for dimers of basic helix-loop-helix (bHLH) proteins, including a heterodimer of the ubiquitous bHLH protein E47/Pan1 and the neuroendocrine specific bHLH protein BETA2/NeuroD1 (35). The A elements each contain the sequence TAAT and have been shown to bind to several homeodomain proteins found in -cell nuclei (12,16,22, 32,37 (16,38,40).The LIM homeodomain protein Lmx1.1 contains two LIM domains that form zinc-binding structures in the amino end of the molecule. The second of these two LIM domains (LIM2) directly binds to the bHLH domain of E47/Pan1 and mediates the synergy between Lmx1.1 and E47/Pan1. This interaction is specific, since analogous domains from other LIM proteins and bHLH proteins cannot substitute for the LIM2 domain of Lmx1.1 or the bHLH domain of E47/Pan1, respectively (20).PDX-1 plays an important role both in the development of the pancreas and in maintaining -cell function. Mice with a targeted disruption of the pdx1 gene selectively lack a pancreas (2, 21, 36). Similar pancreatic agenesis has been found in a human patient with a single nucleotide deletion in the pdx1 gene (46). If the pancreas is allowed to develop with an intact pdx1 gene, and the pdx1 gene is disrupted only in mature  cells, diabetes ensues due to impaired -cell function (3). This
Functional magnetic resonance imaging (fMRI) was used to investigate whether age-related differences in episodic memory performance are accompanied by a reduction in the specificity of recollected information. We addressed this question by comparing recollection-related cortical reinstatement in young and older adults. At study, subjects viewed objects and concrete words, making 1 of 2 different semantic judgments depending on the study material. Test items were words that corresponded to studied words or the names of studied objects. Subjects indicated whether each test item was recollected, familiar, or novel. Reinstatement of information differentiating the encoding tasks was quantified both with a univariate analysis of the fMRI signal and with a multivoxel pattern analysis, using a classifier that had been trained to discriminate between the 2 classes of study episode. The results of these analyses converged to suggest that reinstatement did not differ according to age. Thus, there was no evidence that specificity of recollected information was reduced in older individuals. Additionally, there were no age effects in the magnitude of recollection-related modulations in regional activity or in the neural correlates of post-retrieval monitoring. Taken together, the findings suggest that the neural mechanisms engaged during successful episodic retrieval can remain stable with advancing age.
We have identified a breast carcinoma tyrosine phosphoprotein, discoidin domain receptor (DDR), that defines an unusual class of receptor tyrosine kinases. The DDR cDNA predicts a C-terminal tyrosine kinase domain and an N-terminal domain similar to the Dictyostelium discoideum lectin discoidin I. These domains are connected by an extraordinary hydrophilic proline/glycine-rich domain, which is interrupted by a predicted transmembrane sequence. This extended proline/glycine-rich region may be required for an unusual geometry of interaction with ligand or substrates. Discoidin I domains are also found in other proteins, including coagulation factors V and VIII, and may represent a class of domains that interact with specific cell surface molecules.
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