Chinese hamster ovary (CHO) host cell engineering to increase sialylation of recombinant therapeutic proteins by modulating sialyltransferase expression

N‐Glycans of human proteins possess both α2,6‐ and α2,3‐linked terminal sialic acid (SA). Recombinant glycoproteins produced in Chinese hamster overy (CHO) only have α2,3‐linkage due to the absence of α2,6‐sialyltransferase (St6gal1) expression. The Chinese hamster ST6GAL1 was successfully overexpressed using a plasmid expression vector in three recombinant immunoglobulin G (IgG)‐producing CHO cell lines. The stably transfected cell lines were enriched for ST6GAL1 overexpression using FITC‐Sambucus nigra (SNA) lectin that preferentially binds α2,6‐linked SA. The presence of α2,6‐linked SA was confirmed using a novel LTQ Linear Ion Trap Mass Spectrometry (LTQ MS) method including MSn fragmentation in the enriched ST6GAL1 Clone 27. Furthermore, the total SA (mol/mol) in IgG produced by the enriched ST6GAL1 Clone 27 increased by 2‐fold compared to the control. For host cell engineering, the CHOZN^® GS host cell line was transfected and enriched for ST6GAL1 overexpression. Single‐cell clones were derived from the enriched population and selected based on FITC‐SNA staining and St6gal1 expression. Two clones (“ST6GAL1 OE Clone 31 and 32”) were confirmed for the presence of α2,6‐linked SA in total host cell protein extracts. ST6GAL1 OE Clone 32 was subsequently used to express SAFC human IgG1. The recombinant IgG expressed in this host cell line was confirmed to have α2,6‐linked SA and increased total SA content. In conclusion, overexpression of St6gal1 is sufficient to produce recombinant proteins with increased sialylation and more human‐like glycoprofiles without combinatorial engineering of other sialylation pathway genes. This work represents our ongoing effort of glycoengineering in CHO host cell lines for the development of “bio‐better” protein therapeutics and cell culture vaccine production. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:334–346, 2015     

Intra and Inter-Spore Variability in Rhizophagus irregularis AOX Gene

Arbuscular mycorrhizal fungi (AMF) are root-inhabiting fungi that form mutualistic symbioses with their host plants. AMF symbiosis improves nutrient uptake and buffers the plant against a diversity of stresses. Rhizophagus irregularis is one of the most widespread AMF species in the world, and its application in agricultural systems for yield improvement has increased over the last years. Still, from the inoculum production perspective, a lack of consistency of inoculum quality is referred to, which partially may be due to a high genetic variability of the fungus. The alternative oxidase (AOX) is an enzyme of the alternative respiratory chain already described in different taxa, including various fungi, which decreases the damage caused by oxidative stress. Nevertheless, virtually nothing is known on the involvement of AMF AOX on symbiosis establishment, as well on the existence of AOX variability that could affect AMF effectiveness and consequently plant performance. Here, we report the isolation and characterisation of the AOX gene of R. irregularis (RiAOX), and show that it is highly expressed during early phases of the symbiosis with plant roots. Phylogenetic analysis clustered RiAOX sequence with ancient fungi, and multiple sequence alignment revealed the lack of several regulatory motifs which are present in plant AOX. The analysis of RiAOX polymorphisms in single spores of three different isolates showed a reduced variability in one spore relatively to a group of spores. A high number of polymorphisms occurred in introns; nevertheless, some putative amino acid changes resulting from non-synonymous variants were found, offering a basis for selective pressure to occur within the populations. Given the AOX relatedness with stress responses, differences in gene variants amongst R. irregularis isolates are likely to be related with its origin and environmental constraints and might have a potential impact on inoculum production.     

Effects of clipping and N fertilization on insect herbivory and infestation by pathogenic fungi on bilberry

Interactions among herbivores or between herbivores and other plant natural enemies, such as fungal pathogens, range from competition to facilitation. Moreover, the outcome of these interactions depends on the ecological context where they occur. In this study we examined the effects of clipping, as a surrogate of herbivory by ungulates, on the damage caused by two types of natural enemies (herbivorous insects and foliar fungal pathogens) on bilberry, Vaccinium myrtillus, in combination with nitrogen (N) fertilization representing current N atmospheric deposition. To examine whether the responses of both these natural enemies were mediated by changes in the plant, we estimated the effects of the treatments on bilberry growth and branching and on chlorophyll content as proxy of N content in leaves. Clipping increased the proportion of leaves damaged by herbivorous insects regardless of whether it was combined with N fertilization or not in 2008. In 2007 and 2009 repeated damage to the shrub also facilitated insect herbivory but only under N applications. Regarding fungal infestation incidence, clipping decreased the proportion of infected leaves in all the years considered but only in fertilized plots. Our results suggest that vertebrate herbivores facilitate insect herbivory and reduce fungal infestation but that these effects are dependent on nutritional conditions. Moreover, we found a negative residual correlation between insect herbivory and fungal infestation on bilberry leaves. Therefore, interactions between insect herbivores and fungal pathogens could be implicated in the final outcome of interactions between browsing ungulates and both bilberry natural enemies.     

A global review of the impacts of invasive cats on island endangered vertebrates

Cats are generalist predators that have been widely introduced to the world's ~179 000 islands. Once introduced to islands, cats prey on a variety of native species many of which lack evolved defenses against mammalian predators and can suffer severe population declines and even extinction. As islands house a disproportionate share of terrestrial biodiversity, the impacts of invasive cats on islands may have significant biodiversity impacts. Much of this threatened biodiversity can be protected by eradicating cats from islands. Information on the relative impacts of cats on different native species in different types of island ecosystems can increase the efficiency of this conservation tool. We reviewed feral cat impacts on native island vertebrates. Impacts of feral cats on vertebrates have been reported from at least 120 different islands on at least 175 vertebrates (25 reptiles, 123 birds, and 27 mammals), many of which are listed by the International Union for the Conservation of Nature. A meta‐analysis suggests that cat impacts were greatest on endemic species, particularly mammals and greater when non‐native prey species were also introduced. Feral cats on islands are responsible for at least 14% global bird, mammal, and reptile extinctions and are the principal threat to almost 8% of critically endangered birds, mammals, and reptiles.     

Integration of invasive <Emphasis Type="Italic">Opuntia</Emphasis> spp. by native and alien seed dispersers in the Mediterranean area and the Canary Islands

The success of many alien plant species depends on mutualistic relationships with other species. We describe the assemblage of seed dispersers on three species of alien Opuntia invading Mediterranean and Macaronesian habitats, and examine the quality of such plant-animal interactions. We identified vertebrates consuming O. maxima, O. dillenii and O. stricta fruits by direct observation and collecting droppings and pellets. Phenology of the alien species, as well as that of coexisting native species, was monitored for an entire year. Germination tests of ingested and non-ingested seeds were performed both in the greenhouse and in the field. Seed coat thickness and viability were also measured for all treatments. A great variety of taxa, including reptiles, birds and mammals actively participate in the seed dispersal of Opuntia. Phenology of Opuntia fruits in Menorca and Tenerife overlaps with only a few native fleshy-fruited plants present in the study areas, which suggests an advantage for the invader. Most seeds germinated during the second year of the experiment, independently of the effect produced by the dispersers’ guts. We found great variation in the germination percentage of Opuntia after gut passage and in the effects of ingestion on seed coat thickness. Seed viability was somewhat reduced after gut passage compared to manually depulped seeds. Our results show how different Opuntia species are integrated into native communities by means of mutualistic interactions, with both native and alien dispersers. Although with heterogeneous effects, either type of disperser potentially contributes to the spread of these alien cacti in the recipient areas.     

Simulated ungulate herbivory affects differently two herbivorous arthropod guilds in bilberry

Dense ungulate populations, both domestic and wild, accompanied by high grazing intensities, are known to have effects on the abundance and diversity of the community of arthropods hosted by plants. However, research combining ungulate herbivory with nutrient addition effects is scarce. By means of a nitrogen (N) addition and clipping experiment, we investigated the effects of both factors on the diversity, abundance and trophic structure of the arthropod community hosted by the bilberry, Vaccinium myrtillus, focusing on the response of herbivorous arthropods by considering leaf-chewers and sap-feeders separately. In addition, we assessed altitudinal variation on the arthropod community and also specifically on herbivores. Neither of the variables estimated for the arthropod community (total abundance, richness and biomass) were affected by simulated ungulate herbivory. However, clipping reduced the abundance of sap-feeders although had no significant effect on leaf-chewer insects. We therefore suggest that ungulates can compete with sap-feeders by reducing suitable food resources, or via changing plant nutritional state. Moreover, the lack of response on leaf-chewers could correspond with the absence of chemical defence in bilberry after repeated damage. Despite this effect on sap-feeder abundance, clipping did not cause a cascade effect on the trophic structure of the arthropod community associated with bilberry, at least in the short term. In turn, N fertilization at levels close to atmospheric N deposition did not cause any significant effect on the invertebrate community. Finally, the number of arthropod morphospecies and biomass decreased with altitude.