The Biotechnology Facility for International Space Station

The primary mission of the Cellular Biotechnology Program is to advance microgravity as a tool in basic and applied cell biology. The microgravity environment can be used to study fundamental principles of cell biology and to achieve specific applications such as tissue engineering. The Biotechnology Facility (BTF) will provide a state-of-the-art facility to perform cellular biotechnology research onboard the International Space Station (ISS). The BTF will support continuous operation, which will allow performance of long-duration experiments and will significantly increase the on-orbit science throughput.     

NXF-2, REF-1, and REF-2 affect the choice of nuclear export pathway for tra-2 mRNA in C. elegans

In C. elegans, tra-2 mRNA nuclear export is controlled by a 3'UTR element, the TRE. In the absence of TRA-1, the TRE retains tra-2 mRNA in the nucleus. The binding of TRA-1 to the 3'UTR overcomes this retention resulting in export of a TRA-1/tra-2 mRNA complex. Here, we find that, unlike most mRNAs, tra-2 mRNA exits the nucleus via an alternative pathway to NXF-1 that requires CRM1 activity. Inhibition of export by NXF-1 depends upon the TRE, CeNXF-2, CeREF-1, and CeREF-2. Removal of the TRE or any one of these factors results in export of tra-2 by NXF-1. NXF-2 and REF-1 specifically bind the TRE, suggesting that they directly control tra-2 mRNA export. Furthermore, choice of proper export pathway affects tra-2 translational control. Therefore, tra-2 mRNA export is highly regulated and plays an important role in development by regulating the activity of tra-2 mRNA in the cytoplasm.     

Calcium oscillations in gingival epithelial cells infected with Porphyromonas gingivalis

The periodontal pathogen Porphyromonas gingivalis modulates epithelial cell signal transduction pathways including Ca2+ signaling, and internalizes within the host cell cytoplasm. Since nuclear and cytoplasmic [Ca2+] increases can induce different host cell responses, P. gingivalis-related [Ca2+] changes in these compartments were measured by digital fluorescent imaging microscopy. Non-deconvolved and deconvolved fura-2 images showed that P. gingivalis exposure caused human gingival epithelial cells cultured in physiologic [Ca2+] levels to undergo sustained oscillations of [Ca2+] in nuclear and cytoplasmic spaces. However, P. gingivalis invasion was not tightly correlated with intracellular [Ca2+] oscillations, since invasion could significantly precede, or even occur in the absence of, oscillations. [Ca2+] oscillations required a Ca2+ influx, which was completely inhibited by La3+ or 2-APB (2-aminoethoxydiphenyl borate), indicating Ca2+ entry was via a Ca(2+)-permeable channel. Ca2+ entry was likely not via a store-operated channel, since Ca2+ release from intracellular stores was not observed during cellular uptake of P. gingivalis. Hence, uptake of P. gingivalis in gingival epithelial cells induces oscillations in nuclear and cytoplasmic spaces by activating a Ca2+ influx through Ca2+ channels.     

Strand-specific fluorescence in situ hybridization: the CO-FISH family

The ability to prepare single-stranded chromosomal target DNA allows innovative uses of FISH technology for studies of chromosome organization. Standard FISH methodologies require functionally single-stranded DNAs in order to facilitate hybridization between the probe and the complementary chromosomal target sequence. This usually involves denaturation of double-stranded probes to induce temporary separation of the DNA strands. Strand-specific FISH (CO-FISH; Chromosome Orientation-FISH) involves selective removal of newly replicated strands from DNA of metaphase chromosomes which results in single-stranded target DNA. When single-stranded probes are then hybridized to such targets, the resulting strand-specific hybridization is capable of revealing a level of information previously unattainable at the cytogenetic level. Mammalian telomeric DNA consists of tandem repeats of the (TTAGGG) sequence, oriented 5'-->3' towards the termini of all vertebrate chromosomes. Based on this conserved structural organization, CO-FISH with a telomere probe reveals the absolute 5'-->3' orientation of DNA sequences with respect to the pter-->qter direction of chromosomes. Development and various applications of CO-FISH will be discussed: detection of cryptic inversions, discrimination between telomeres produced by leading- versus lagging-strand synthesis, and replication timing of mammalian telomeres.     

DNA and telomeres: beginnings and endings

How a cell deals with its DNA ends is a question that returns us to the very beginnings of modern telomere biology. It is also a question we are still asking today because it is absolutely essential that a cell correctly distinguishes between natural chromosomal DNA ends and broken DNA ends, then processes each appropriately - preserving the one, rejoining the other. Effective end-capping of mammalian telomeres has a seemingly paradoxical requirement for proteins more commonly associated with DNA double strand break (DSB) repair. Ku70, Ku80, DNA-PKcs (the catalytic subunit of DNA-dependent protein kinase), Xrcc4 and Artemis all participate in DSB repair through nonhomologous end-joining (NHEJ). Somewhat surprisingly, mutations in any of these genes cause spontaneous chromosomal end-to-end fusions that maintain large blocks of telomeric sequence at the points of fusion, suggesting loss or failure of a critical terminal structure, rather than telomere shortening, is at fault. Nascent telomeres produced via leading-strand DNA synthesis are especially susceptible to these end-to-end fusions, suggesting a crucial difference in the postreplicative processing of telomeres that is linked to their mode of replication. Here we will examine the dual roles played by DNA repair proteins. Our review of this rapidly advancing field primarily will focus on mammalian cells, and cannot include even all of this. Despite these limitations, we hope the review will serve as a useful gateway to the literature, and will help to frame the major issues in this exciting and rapidly progressing field. Our apologies to those whose work we are unable to include.     

Poly(hydroxyalkanoic acid) Biosynthesis in Ectothiorhodospirashaposhnikovii: Characterization and Reactivity of a Type III PHA Synthase

Ectothiorhodospira shaposhnikovii is able to accumulate polyhydroxybutyrate (PHB) photoautotrophically during nitrogen-limited growth. The activity of polyhydroxyalkanoate (PHA) synthase in the cells correlates with PHB accumulation. PHA synthase samples collected during the light period do not show a lag phase during in vitro polymerization. Synthase samples collected in the dark period displays a significant lag phase during in vitro polymerization. The lag phase can be eliminated by reacting the PHA synthase with the monomer, 3-hydroxybutyryl-CoA (3HBCoA). The PHA synthase genes (phaC and phaE) were cloned by screening a genomic library for PHA accumulation in E. coli cells. The PHA synthase expressed in the recombinant E. coli cells was purified to homogeneity. Both sequence analysis and biochemical studies indicated that this PHA synthase consists of two subunits, PhaE and PhaC and, therefore, belongs to the type III PHA synthases. Two major complexes were identified in preparations of purified PHA synthase. The large complex appears to be composed of 12 PhaC subunits and 12 PhaE subunits (dodecamer), whereas the small complex appears to be composed of 6 PhaC and 6 PhaE subunits (hexamer). In dilute aqueous solution, the synthase is predominantly composed of hexamer and has low activity accompanied with a significant lag period at the initial stage of reaction. The percentage of dodecameric complex increases with increasing salt concentration. The dodecameric complex has a greatly increased specific activity for the polymerization of 3HBCoA and a negligible lag period. The results from in vitro polymerizations of 3HBCoA suggest that the PHA synthase from E. shaposhnikovii may catalyze a living polymerization and demonstrate that two PhaC and two PhaE subunits comprise a single catalytic site in the synthase complex.     

Distinguishing plant and fungal sequences in ESTs from infected plant tissues

Expressed sequence tags (ESTs) from fungal-infected plant tissues are composed of a mixture of plant and fungal sequences. Using freely available software and tools, a novel procedure is described for distinguishing plant and fungal DNA sequences. Although the GenBank non-redundant (NR) database is larger and therefore one would presume that BLASTX analysis of it would be more accurate, superior resolution of 700 randomly selected fungal ESTs was found with Standalone TBLASTX analyses with a local matching database composed of a plant and a fungal genome. Standalone TBLASTX analyses of 3,983 ESTs from nine different fungal-infected plant EST libraries also proved to be superior in identifying the origin of sequences as either plant or fungal compared to GenBank BLASTX analysis. Standalone TBLASTX with a matching database comprised of a single plant and a single fungal genome appears to be a faster and more accurate method than BLASTX searches of the GenBank non-redundant database to distinguish fungal and plant sequences in mixed EST collections.     

Experimental evidence for multiple assembled states of Sc3 from Schizophyllum commune

The hydrophobin Sc3 from the fungus Schizophyllum commune assembles from the aqueous phase into ordered structures with substantially different characteristics depending upon experimental conditions. Under the first condition, a vortexing procedure widely reported in the literature, interfacial assembly yields highly ordered, stacked beta-sheets. We have also observed a previously unreported assembly of Sc3 under a second condition, which occurs in a time-dependent manner from quiescent solution. The resulting types of assembled states have been compared utilizing fluorescence techniques, sodium dodecyl sulfate polyacrylamide gel electrophoresis, immunoblotting, density gradient centrifugation, and phase contrast and atomic force microscopy. A model based on this study and previous literature is proposed that suggests three distinct states of Sc3: (1) soluble Sc3 consisting of unimers or multimers in micelle-like association, (2) interfacially assembled I-Sc3 with highly ordered, stacked beta-sheets, presumably formed in a templated manner at the air/water interface of microscopic bubbles generated by vortexing, and (3) solution-assembled S-Sc3, a less-ordered structure formed in a time-dependent manner in the absence of an interface.