Crystallization in Confinement

Many crystallization processes of great importance, including frost heave, biomineralization, the synthesis of nanomaterials, and scale formation, occur in small volumes rather than bulk solution. Here, the influence of confinement on crystallization processes is described, drawing together information from fields as diverse as bioinspired mineralization, templating, pharmaceuticals, colloidal crystallization, and geochemistry. Experiments are principally conducted within confining systems that offer well-defined environments, varying from droplets in microfluidic devices, to cylindrical pores in filtration membranes, to nanoporous glasses and carbon nanotubes. Dramatic effects are observed, including a stabilization of metastable polymorphs, a depression of freezing points, and the formation of crystals with preferred orientations, modified morphologies, and even structures not seen in bulk. Confinement is also shown to influence crystallization processes over length scales ranging from the atomic to hundreds of micrometers, and to originate from a wide range of mechanisms. The development of an enhanced understanding of the influence of confinement on crystal nucleation and growth will not only provide superior insight into crystallization processes in many real-world environments, but will also enable this phenomenon to be used to control crystallization in applications including nanomaterial synthesis, heavy metal remediation, and the prevention of weathering.     

Productivity and mobility in academic research: evidence from mathematicians

Using an exhaustive database on academic publications in mathematics all over the world, we study the patterns of productivity by mathematicians over the period 1984–2006. We uncover some surprising facts, such as the weakness of age related decline in productivity and the relative symmetry of international movements, rejecting the presumption of a massive “brain drain” towards the US. We also analyze the determinants of success by top US departments. In conformity with recent studies in other fields, we find that selection effects are much stronger than local interaction effects: the best departments are most successful in hiring the most promising mathematicians, but not necessarily at stimulating positive externalities among them. Finally we analyze the impact of career choices by mathematicians: mobility almost always pays, but early specialization does not.     

Early G1 growth arrest of hybridoma B cells by DMSO involves cyclin D2 inhibition and p21[CIP1] induction

Dimethylsulfoxide (DMSO) was shown to inhibit the proliferation of several B cell lines including Raji, Daudi, and SKW6-CL4 but the mechanisms involved in this growth arrest are still unclear. We show that in 7TD1 mouse hybridoma cells a DMSO-induced reversible G1 arrest involves inactivation of Rb kinases, cyclin D2/CDK4 and cyclin E/CDK2. This occurs by at least three distinct mechanisms. Inhibition of cyclin D2 neosynthesis leads to a dramatic decrease of cyclinD2/CDK4 complexes. This in turn enables the redistribution of p27[KIP1] from cyclin D2/CDK4 to cyclin E/CDK2 complexes. In addition, the simultaneous accumulation of p21[CIP1] entails increasing association with cyclin D3/CDK4 and cyclin E/CDK2. Thus, p21[CIP1] and p27[KIP1], act in concert to inhibit cyclin E/CDK2 activity which, together with CDK4 inactivation, confers a G1-phase arrest.     

Sequence analysis of two cosmids from Schizosaccharomyces pombe chromosome III

We report the complete sequence of two cosmids, SPCC895 (38457 bp insert, EMBL Accession No. AL035247) and SPCC1322 (42068 bp insert, EMBL Accession No. AL035259), localized on chromosome III of the Schizosaccharomyces pombe genome. Fourteen Coding DNA sequences (CDSs) were identified in SPCC895 and 17 in SPCC1322. Two known genes were found in each cosmid: map2 and gms1 on SPCC895, encoding the mating type P-factor precursor and an UDP-galactose transporter, respectively, and bub1 and ade6 in SPCC1322, encoding a protein kinase and a phosphoribosylaminoimidazole carboxylase, respectively. The fission yeast K RNA gene has been localized to SPCC895. Three ribosomal proteins have been predicted among these two cosmids. Nine CDSs similar to known proteins were found on SPCC895, and seven on SPCC1322. They include putative genes for an uridylate kinase, a proteasome catalytic component, an ion transporter, a checkpoint protein, a translation initiation protein, a SNARE complex protein, a protein involved in cytoskeletal organization, a spindle pole body-associating protein, pre-mRNA splicing factor RNA helicase, a 3'-5' exonuclease for RNA 3' ss-tail, an UTP-glucose-1-phosphate uridylyltransferase, a leukotriene A(4) hydrolase, a member of the RanBP7-importin beta-Cse1p superfamily, a Ca(++)-calmodulin-dependent serine/threonine protein kinase and a prohibitin antiproliferative protein. One CDS is predicted to be an integral membrane protein. One CDS from SPCC895 is similar to a CDS of unknown function from Saccharomyces cerevisiae and three from SPCC1322 are similar to CDSs of unknown function from Candida albicans, S. cerevisiae and Sz. pombe, respectively. Finally, one CDS of SPCC895 and three of SPCC1322 correspond to orphan genes.