Forest Landscape Restoration: increasing the positive impacts of forest restoration or simply the area under tree cover?

Restoring forest landscapes is critical in the face of continued global forest loss and degradation. In this article, we explore some challenges underlying the delivery of global commitments to restore forest landscapes. We propose that three fundamental questions need to be resolved upfront for the effective implementation of Forest Landscape Restoration and related commitments: (1) What social and ecological landscape objectives are being sought through Forest Landscape Restoration? (2) How are specific areas being selected for restoration? (3) How is success measured when restoring forest landscapes? We believe that there is an urgent need to adequately answer these questions to successfully implement political commitments for large‐scale forest restoration.     

The complete nucleotide sequence of Chinese hamster (Cricetulus griseus) mitochondrial DNA.

Mammalian mitochondria contain their own approximately 16.5 kb circular genome. Mitochondrial DNA (mtDNA) encodes for a subset of the proteins involved in the electron transport chain and depletion or mutation of the sequence is implicated in a number of human disease processes. The recent finding is that mitochondrial damage mediates genotoxicity after exposure to chemical carcinogens has focused attention on the role of mtDNA mutations in the development of cancer. Although the entire genome has been sequenced for a number of mammals, only a small fraction of the mtDNA sequence is available for hamsters. We have obtained here the entire 16,284 bp sequence of the Chinese hamster mitochondrial genome, which will enable detailed analysis of mtDNA mutations caused by exposure to mutagens in hamster-derived cell lines.     

Propagated fixed-bed mixed-acid fermentation: Part I: Effect of volatile solid loading rate and agitation at high pH

Countercurrent fermentation is a high performing process design for mixed-acid fermentation. However, there are high operating costs associated with moving solids, which is an integral component of this configuration. This study investigated the effect of volatile solid loading rate (VSLR) and agitation in propagated fixed-bed fermentation, a configuration which may be more commercially viable. To evaluate the role of agitation on fixed-bed configuration performance, continuous mixing was compared with periodic mixing. VSLR was also varied and not found to affect acid yields. However, increased VSLR and liquid retention time did result in higher conversions, productivity, acid concentrations, but lower selectivities. Agitation was demonstrated to be important for this fermentor configuration, the periodically-mixed fermentation had the lowest conversion and yields. Operating at a high pH (～9) contributed to the high selectivity to acetic acid, which might be industrially desirable but at the cost of lower yield compared to a neutral pH.     

Genetic and physiological analysis of iron biofortification in maize kernels

Background

Maize is a major cereal crop widely consumed in developing countries, which have a high prevalence of iron (Fe) deficiency anemia. The major cause of Fe deficiency in these countries is inadequate intake of bioavailable Fe, where poverty is a major factor. Therefore, biofortification of maize by increasing Fe concentration and or bioavailability has great potential to alleviate this deficiency. Maize is also a model system for genomic research and thus allows the opportunity for gene discovery. Here we describe an integrated genetic and physiological analysis of Fe nutrition in maize kernels, to identify loci that influence grain Fe concentration and bioavailability.

Methodology

Quantitative trait locus (QTL) analysis was used to dissect grain Fe concentration (FeGC) and Fe bioavailability (FeGB) from the Intermated B73 × Mo17 (IBM) recombinant inbred (RI) population. FeGC was determined by ion coupled argon plasma emission spectroscopy (ICP). FeGB was determined by an in vitro digestion/Caco-2 cell line bioassay.

Conclusions

Three modest QTL for FeGC were detected, in spite of high heritability. This suggests that FeGC is controlled by many small QTL, which may make it a challenging trait to improve by marker assisted breeding. Ten QTL for FeGB were identified and explained 54% of the variance observed in samples from a single year/location. Three of the largest FeGB QTL were isolated in sister derived lines and their effect was observed in three subsequent seasons in New York. Single season evaluations were also made at six other sites around North America, suggesting the enhancement of FeGB was not specific to our farm site. FeGB was not correlated with FeGC or phytic acid, suggesting that novel regulators of Fe nutrition are responsible for the differences observed. Our results indicate that iron biofortification of maize grain is achievable using specialized phenotyping tools and conventional plant breeding techniques.     

Subcellular targeting of an evolutionarily conserved plant defensin MtDef4.2 determines the outcome of plant–pathogen interaction in transgenic Arabidopsis

The Medicago truncatula gene encoding an evolutionarily conserved antifungal defensin MtDef4.2 was cloned and characterized. In silico expression analysis indicated that MtDef4.2 is expressed in many tissues during the normal growth and development of M. truncatula. MtDef4.2 exhibits potent broad‐spectrum antifungal activity against various Fusarium spp. Transgenic Arabidopsis thaliana lines in which MtDef4.2 was targeted to three different subcellular compartments were generated. These lines were tested for resistance to the obligate biotrophic oomycete Hyaloperonospora arabidopsidis Noco2 and the hemibiotrophic fungal pathogen Fusarium graminearum PH‐1. MtDef4.2 directed to the extracellular space, but not to the vacuole or retained in the endoplasmic reticulum, conferred robust resistance to H. arabidopsidis. Siliques of transgenic Arabidopsis lines expressing either extracellularly or intracellularly targeted MtDef4.2 displayed low levels of resistance to F. graminearum, but accumulated substantially reduced levels of the mycotoxin deoxynivalenol. The data presented here suggest that extracellularly targeted MtDef4.2 is sufficient to provide strong resistance to the biotrophic oomycete, consistent with the extracellular lifestyle of this pathogen. However, the co‐expression of extracellular and intracellular MtDef4.2 is probably required to achieve strong resistance to the hemibiotrophic pathogen F. graminearum which grows extracellularly and intracellularly.     

In vitro production of adventitious roots containing asiaticoside from leaf tissues of Centella asiatica L.

Centella asiatica (Apiaceae) is an important medicinal herb used in a variety of herbal medicines worldwide. Although the whole plant contains important triterpenoids, a significant quantity of pharmacologically important phytochemicals collectively known as centellosides can be extracted from leaf tissues and not from other parts of this plant. Asiaticoside is one of the major centellosides and is used in holistic medicine for treating a variety of human ailments. Genotypes of C. asiatica of Indian origin accumulate significant quantities of asiaticoside in their roots, while genotypes from other continents contain insignificant quantities of this chemical. The main purpose of this study was to manipulate the leaf-derived callus of C. asiatica using a combination of plant growth regulators to generate a large quantity of adventitious roots. The presence of asiaticoside in callus and regenerated roots of C. asiatica was detected by thin layer chromatography as well as by high-performance liquid chromatography, and the accumulation of a significant quantity of asiaticoside was demonstrated by spectrophotometric analysis. The protocol developed for the regeneration of roots was simple, reproducible, and reliable for the possible commercial production of root biomass enriched for asiaticoside.     

Antibodies Covalently Immobilized on Actin Filaments for Fast Myosin Driven Analyte Transport

Biosensors would benefit from further miniaturization, increased detection rate and independence from external pumps and other bulky equipment. Whereas transportation systems built around molecular motors and cytoskeletal filaments hold significant promise in the latter regard, recent proof-of-principle devices based on the microtubule-kinesin motor system have not matched the speed of existing methods. An attractive solution to overcome this limitation would be the use of myosin driven propulsion of actin filaments which offers motility one order of magnitude faster than the kinesin-microtubule system. Here, we realized a necessary requirement for the use of the actomyosin system in biosensing devices, namely covalent attachment of antibodies to actin filaments using heterobifunctional cross-linkers. We also demonstrated consistent and rapid myosin II driven transport where velocity and the fraction of motile actin filaments was negligibly affected by the presence of antibody-antigen complexes at rather high density (>20 µm⁻¹). The results, however, also demonstrated that it was challenging to consistently achieve high density of functional antibodies along the actin filament, and optimization of the covalent coupling procedure to increase labeling density should be a major focus for future work. Despite the remaining challenges, the reported advances are important steps towards considerably faster nanoseparation than shown for previous molecular motor based devices, and enhanced miniaturization because of high bending flexibility of actin filaments.