Structural basis for myopathic defects engendered by alterations in the myosin rod

While mutations in the myosin subfragment 1 motor domain can directly disrupt the generation and transmission of force along myofibrils and lead to myopathy, the mechanism whereby mutations in the myosin rod influences mechanical function is less clear. Here, we used a combination of various imaging techniques and molecular dynamics simulations to test the hypothesis that perturbations in the myosin rod can disturb normal sarcomeric uniformity and, like motor domain lesions, would influence force production and propagation. We show that disrupting the rod can alter its nanomechanical properties and, in vivo, can drive asymmetric myofilament and sarcomere formation. Our imaging results indicate that myosin rod mutations likely disturb production and/or propagation of contractile force. This provides a unifying theory where common pathological cascades accompany both myosin motor and specific rod domain mutations. Finally, we suggest that sarcomeric inhomogeneity, caused by asymmetric thick filaments, could be a useful index of myopathic dysfunction.     

Micropropagation by tissue culture triggers differential expression of infectious endogenous Banana streak virus sequences (eBSV) present in the B genome of natural and synthetic interspecific banana plantains

The genome of Musa balbisiana spp. contains several infectious endogenous sequences of Banana streak virus (eBSV). We have shown previously that in vitro micropropagation triggers the activation of infectious eBSOLV (endogenous sequences of Banana streak Obino l'Ewai virus ) in the synthetic tetraploid interspecific hybrid FHIA21 (AAAB). In this work, we show that another synthetic tetraploid (AAAB) hybrid and two natural triploid (AAB) plantains are equally prone to the activation of infectious eBSOLV during tissue culture. These results are a strong indication that such activation is a general phenomenon in interspecific Musa cultivars, whether synthetic or natural. We also report the first in-depth study of the correlation between the duration of tissue culture and the level of activation of infectious eBSOLV, and show that specific and common activation patterns exist in these banana plants. We hypothesize that these patterns result from the concomitant activation of infectious eBSOLV and a decrease in the virus titre in neoformed plantlets, resulting from cell multiplication outcompeting virus replication. We provide experimental data supporting this hypothesis. No activation of infectious eBSGFV (endogenous sequences of Banana streak Goldfinger virus) by tissue culture was observed in the two natural AAB plantain cultivars studied here, whereas such activation occurred in the AAAB synthetic hybrid studied. We demonstrate that this differential activation does not result from differences in the structure of eBSGFV, as all banana genomes harbour eaBSGFV-7.     

Homologous and illegitimate recombination in developing Xenopus oocytes and eggs.

Exogenous DNA is efficiently recombined when injected into the nuclei of Xenopus laevis oocytes. This reaction proceeds by a homologous resection-annealing mechanism which depends on the activity of a 5'-->3' exonuclease. Two possible functions for this recombination activity have been proposed: it may be a remnant of an early process in oogenesis, such as meiotic recombination or amplification of genes coding for rRNA, or it may reflect materials stored for embryogenesis. To test these hypotheses, recombination capabilities were examined with oocytes at various developmental stages. Late-stage oocytes performed only homologous recombination, whereas the smallest oocytes ligated the restriction ends of the injected DNA but supported no homologous recombination. This transition from ligation to recombination activity was also seen in nuclear extracts from these same stages. Exonuclease activity was measured in the nuclear extracts and found to be low in early stages and then to increase in parallel with recombination capacity in later stages. The accumulation of exonuclease and recombination activities during oogenesis suggests that they are stored for embryogenesis and are not present for oocyte-specific functions. Eggs were also tested and found to catalyze homologous recombination, ligation, and illegitimate recombination. Retention of homologous recombination in eggs is consistent with an embryonic function for the resection-annealing mechanism. The observation of all three reactions in eggs suggests that multiple pathways are available for the repair of double-strand breaks during the extremely rapid cleavage stages after fertilization.     

Microbial development in distillers wet grains produced during fuel ethanol production from corn (Zea mays)

Distillers grains are coproduced with ethanol and carbon dioxide during the production of fuel ethanol from the dry milling and fermentation of corn grain, yet there is little basic microbiological information on these materials. We undertook a replicated field study of the microbiology of distillers wet grains (DWG) over a 9 day period following their production at an industrial fuel ethanol plant. Freshly produced DWG had a pH of about 4.4, a moisture content of about 53.5% (wet mass basis), and 4 x 10(5) total yeast cells/g dry mass, of which about 0.1% were viable. Total bacterial cells were initially below detection limits (ca. 10(6) cells/g dry mass) and then were estimated to be approximately 5 x 10(7) cells/g dry mass during the first 4 days following production. Culturable aerobic heterotrophic organisms (fungi plus bacteria) ranged between 10(4) and 10(5) CFU/g dry mass during the initial 4 day period, and lactic acid bacteria increased from 36 to 10(3) CFU/g dry mass over this same period. At 9 days, total viable bacteria and yeasts and (or) molds topped 10(8) CFU/g dry mass and lactic acid bacteria approached 10(6) CFU/g dry mass. Community phospholipid fatty acid analysis indicated a stable microbial community over the first 4 days of storage. Thirteen morphologically distinct isolates were recovered, of which 10 were yeasts and molds from 6 different genera, 2 were strains of the lactic-acid-producing Pediococcus pentosaceus and only one was an aerobic heterotrophic bacteria, Micrococcus luteus. The microbiology of DWG is fundamental to the assessment of spoilage, deleterious effects (e.g., toxins), or beneficial effects (e.g., probiotics) in its use as feed or in alternative applications.     

Molecular evolution: Please release me, genetic code

The genetic code is no longer universal, even in non-mitochondrial genomes. Recent studies have implicated the eukaryotic release factor eRF1 in mediating coding changes that are not as inconceivable as once thought. Specific residues in eRF1 proteins can be correlated with specific code changes in a wide variety of taxa.     

Importance of homodimerization for the in vivo function of yeast RNA triphosphatase

Saccharomyces cerevisiae RNA triphosphatase Cet1 is an essential component of the yeast mRNA capping apparatus. The active site of Cet1 resides within a topologically closed hydrophilic beta-barrel (the triphosphate tunnel) that is supported by a globular hydrophobic core. The homodimeric quaternary structure of Cet1 is formed by a network of contacts between the partner protomers. By studying the effects of alanine-cluster mutations, we highlight the contributions of two separate facets of the crystallographic dimer interface to Cet1 function in vivo. One essential facet of the interface entails hydrophobic cross-dimer interactions of Cys(330) and Val(331) and a cross-dimer hydrogen bond of Asp(280) with the backbone amide of Gln(329). The second functionally relevant dimer interface involves hydrophobic side-chain interactions of Phe(272) and Leu(273). Ala-cluster mutations involving these residues elicited lethal or severe temperature-sensitive phenotypes that were suppressed completely by fusion of the mutated triphosphatases to the guanylyltransferase domain of mammalian capping enzyme. The recombinant D279A-D280A and F272A-L273A proteins retained phosphohydrolase activity but sedimented as monomers. These results indicate that a disruption of the dimer interface is uniquely deleterious when the yeast RNA triphosphatase must function in concert with the endogenous yeast guanylyltransferase. We also identify key residue pairs in the hydrophobic core of the Cet1 protomer that support the active site tunnel and stabilize the triphosphatase in vivo.     

Lumenal transmission of decapentaplegic in Drosophila imaginal discs

Drosophila imaginal discs are sac-like appendage primordia comprising apposed peripodial and columnar cell layers. Cell survival in disc columnar epithelia requires the secreted signal Decapentaplegic (DPP), which also acts as a gradient morphogen during pattern formation. The distribution mechanism by which secreted DPP mediates global cell survival and graded patterning is poorly understood. Here we report detection of DPP in the lumenal cavity between apposed peripodial and columnar cell layers of both wing and eye discs. We show that peripodial cell survival hinges upon DPP signal reception and implicate DPP-dependent viability of the peripodial epithelium in growth of the entire disc. These results are consistent with lumenal transmission of the DPP survival signal during imaginal disc development.