Tytti Sarjala

Promoting human health through forests: overview and major challenges.

This review aims to contribute to the ongoing discussion about human health, global change, and biodiversity by concentrating on the relationships between forests and human health. This review gives a short overview of the most important health benefits that forests provide to humans, and the risks that forests may pose to human health. Furthermore, it discusses the future challenges for the research on the links between forests and human health, and for delivering health through forests in practice. Forests provide enormous possibilities to improve human health conditions. The results of a vast amount of research show that forest visits promote both physical and mental health by reducing stress. Forests represent rich natural pharmacies by virtue of being enormous sources of plant and microbial material with known or potential medicinal or nutritional value. Forest food offers a safety net for the most vulnerable population groups in developing countries, and healthy forest ecosystems may also help in regulation of infectious diseases. Utilizing forests effectively in health promotion could reduce public health care budgets and create new sources of income. Main challenges to delivering health through forests are due to ecosystem and biodiversity degradation, deforestation, and climate change. In addition, major implementation of research results into practice is still lacking. Inadequate implementation is partly caused by insufficient evidence base and partly due to the lack of policy-makers’ and practitioners’ awareness of the potential of forests for improving human health. This calls for strong cooperation among researchers, policy-makers, and practitioners as well as between different sectors, especially between health and environmental professionals.

Consistency of Polyamine Profiles and Expression of Arginine Decarboxylase in Mitosis during Zygotic Embryogenesis of Scots Pine

In this study, we show that both arginine decarboxylase (ADC) protein and mRNA transcript are present at different phases of mitosis in Scots pine (Pinus sylvestris) zygotic embryogenesis. We also examined the consistency of polyamine (PA) profiles with the effective temperature sum, the latter indicating the developmental stage of the embryos. PA metabolism was analyzed by fitting statistical regression models to the data of free and soluble conjugated PAs, to the enzyme activities of ADC and ornithine decarboxylase (ODC), as well as to the gene expression of ADC. According to the fitted models, PAs typically had the tendency to increase at the early stages but decrease at the late stages of embryogenesis. Only the free putrescine fraction remained stable during embryo development. The PA biosynthesis strongly preferred the ADC pathway. Both ADC gene expression and ADC enzyme activity were substantially higher than putative ODC gene expression or ODC enzyme activity, respectively. ADC gene expression and enzyme activity increased during embryogenesis, which suggests the involvement of transcriptional regulation in the expression of ADC. Both ADC mRNA and ADC protein localized in dividing cells of embryo meristems and more specifically within the mitotic spindle apparatus and close to the chromosomes, respectively. The results suggest the essential role of ADC in the mitosis of plant cells.

In vivo Chlorophyll fluorescence is not always a good indicator of cold hardiness

Summary This paper demonstrates that Chlorophyll fluorescence in vivo is not always a true indicator of plant cold hardiness. In this experiment, frost resistance and chlorophyll fluorescence of needles of Scots pine seedlings were followed under natural and controlled phytotron conditions during the most active cold hardening period.

Advancing the use of minirhizotrons in wetlands

BackgroundWetlands store a substantial amount of carbon (C) in deep soil organic matter deposits, and play an important role in global fluxes of carbon dioxide and methane. Fine roots (i.e., ephemeral roots that are active in water and nutrient uptake) are recognized as important components of biogeochemical cycles in nutrient-limited wetland ecosystems. However, quantification of fine-root dynamics in wetlands has generally been limited to destructive approaches, possibly because of methodological difficulties associated with the unique environmental, soil, and plant community characteristics of these systems. Non-destructive minirhizotron technology has rarely been used in wetland ecosystems.ScopeOur goal was to develop a consensus on, and a methodological framework for, the appropriate installation and use of minirhizotron technology in wetland ecosystems. Here, we discuss a number of potential solutions for the challenges associated with the deployment of minirhizotron technology in wetlands, including minirhizotron installation and anchorage, capture and analysis of minirhizotron images, and upscaling of minirhizotron data for analysis of biogeochemical pools and parameterization of land surface models.ConclusionsThe appropriate use of minirhizotron technology to examine relatively understudied fine-root dynamics in wetlands will advance our knowledge of ecosystem C and nutrient cycling in these globally important ecosystems.

Defoliation-induced responses in peroxidases, phenolics, and polyamines in scots pine (Pinus sylvestris L.) needles

Effects of artificial defoliation on defensive needle chemistry in Scots pine (Pinus sylvestris L.) were evaluated with particular emphasis on peroxidases, phenolic compounds, soluble sugars, polyamines, and foliar nitrogen levels. The study was carried out on a nutrient-poor Scots pine stand with 8- to 25-year-old trees. Defoliation treatment consisted of repeated defoliation in two successive years with respective control trees. Defoliation was done before needle flushing by removing all mature needles. Guaiacol peroxidase activity increased in the needles after the first defoliation. The difference between treatments diminished towards autumn, and disappeared before the second defoliation in the next summer. After the second defoliation, the activities showed a similar trend. Apparently, peroxidases are involved in inducible chemical changes and recovery reactions that occur in the intact needles shortly after defoliation. After the second defoliation, total nitrogen concentration in the current year needles was about 20% lower, and free putrescine (a polyamine) concentration was 40% lower in the defoliated trees than in control needles. These changes indicate a loss of nitrogen due to defoliation. Specific phenolic compounds such as quercitrin, (+)-catechin, and two catechin derivatives increased in current year needles in response to defoliation. Accumulation of starch and sucrose in the current year needles of repeatedly defoliated trees may imply decreased assimilate transport. The results are indicative that changes in needle phytochemistry in response to defoliation accompany changes in needle nitrogen metabolism.

Effect of exogenous polyamines and inhibitors of polyamine biosynthesis on growth and free polyamine contents of embryogenic scots pine callus

Summary Effects of the exogenously added polyamines putrescine, spermidine and spermine and the inhibitors of polyamine biosynthesis, methylglyoxal bis(guanylhydrazone) (MGBG) and dicyclohexylamine (DCHA), in the DCR medium on the endogenous polyamine levels and growth of embryogenic callus of Scots pine ( Pinus sylvestris L.) were studied. With polyamine treatments the endogenous putrescine level was signifi-candy affected only by 10 umol/L spermidine, which decreased the putrescine. Other polyamine treatments did not have an effect on the putrescine level. Endogenous spermidine or spermine levels were not significantly affected by exogenous polyamines, although lower spermine concentrations were found in callus tissues with all polyamine supplements. DCHA significantly reduced the endogenous putrescine level but not the spermidine or spermine levels. The highest concentration of MGBG (5 mmol/L), but not the lower ones (0.1 and 1 mmol/L), reduced putrescine, spermidine and spermine levels. The callus tissues cultured with exogenous polyamines or inhibitors showed a positive correlation between endogenous putrescine and the relative growth rate (R G ). The correlation was also positive between the endogenous spermidine and R G , but no correlation was found between the endogenous spermine and R G . Exogenous polyamines did not affect the growth of the callus tissues. All DCHA treatments (0.1, 1.0 and 5 mmol/L) inhibited the growth of the calli, whereas MGBG inhibited the growth only with the highest concentration (5 mmol/L).

Effects of defoliation and symbiosis on polyamine levels in pine and birch

Abstract We report the effect of ectomycorrhizal fungi (Suillus variegatus, Paxillus involutus) and defoliation on polyamine concentrations in pine (Pinus silvestris) and birch (Betula pendula) foliage and roots. Symbiotic root tips showed consistently higher concentrations of putrescine than non-symbiotic roots. Partial defoliation had no effect on the polyamine levels in mycorrhizal pine or birch roots. The foliage of mycorrhizal pine seedlings had lower putrescine concentrations and higher spermidine than foliage of non-mycorrhizal plants, and defoliation reversed this pattern. The response to partial defoliation differed in birch foliage: mycorrhizal status had no effect and all new growth after defoliation had higher spermidine levels than in non-defoliated birch. The potential role of polyamines in mycorrhizal symbiosis is discussed.

Spermidine and methylglyoxal bis(guanylhydrazone) affect maturation and endogenous polyamine content of Scots pine embryogenic cultures

Summary Exogenous spermidine (Spd) and methylglyoxal bis(guanylhydrazone) (MGBG), a putative inhibitor of Spd synthesis, improved somatic embryo formation of Scots pine ( Pinus sylvestris L.). The induced maturation due to MGBG and Spd was accompanied by significantly retarded proliferation growth and by reduction in the concentration of free polyamines compared to the control cultures. The action of MGBG revealed that it has a non-specific effect on the whole polyamine metabolism of Scots pine. Furthermore, at certain concentrations it may induce plant differentiation as well.

The structure and hardening status of Scots pine needles at different potassium availability levels

Abstract Scots pine (Pinus sylvestris L.) seedlings were exposed to three levels of potassium (low, medium and high) and their needle morphology, the cellular structure of the mesophyll and transfusion parenchyma, and the hardening status of the mesophyll cells were examined by light and transmission electron microscopy. The higher the potassium level the greater was the growth of the needles. The area of the mesophyll tissue increased slightly and those of the phloem, xylem and resin ducts decreased in the needles of the seedlings grown at the high K level. Cellular studies revealed that swelling of the chloroplast thylakoids, accumulation of starch in the chloroplasts, translucency of the cytoplasm and plasmolysis in the mesophyll cells were related to a low K level. The hardening status of the mesophyll cells was enhanced after 5 weeks of hardening treatment at high K as seen in changes in chloroplast shape and position and the structure of the endoplasmic reticulum, but the pines showed no major differences in the hardening status of their mesophyll cells between K levels at the end of the experiment, after 9 weeks of hardening. Frost resistance, as shown by the electrolyte leakage test, was nevertheless highest at low K, being related to the increase in the concentration of polyamine putrescine at this potassium level.

Ectomycorrhization of Tricholoma matsutake and two major conifers in Finland—an assessment of in vitro mycorrhiza formation

This study aimed to test the ability of Tricholoma matsutake isolates to form mycorrhizas with aseptic seedlings of Pinus sylvestris L. and Picea abies (L.) Karst. Germinated seedlings of Scots pine and Norway spruce were separately inoculated with either isolates originating from Finland or Japan. Eight months after inoculation, the Finnish isolate had formed a sheath and Hartig net on both host species. Ectomycorrhizal Scots pine seedlings inoculated with the Finnish isolate showed the same shoot height and dry mass as the controls. Ectomycorrhizal Norway spruce seedlings inoculated with the Finnish isolate had similar shoot height but slightly less dry mass than the control seedlings. For both tree species, inoculation with the Finnish isolate resulted in reduced total nitrogen content per seedling, but carbon content was unaffected. Inoculation with the Japanese isolate resulted in an initial Hartig net-like structure in pine but not in spruce. No typical Hartig net was observed on either tree species. Furthermore, seedlings of both species inoculated with the Japanese isolate showed significantly reduced growth, dry mass, nitrogen, and carbon content per seedling and shoot height (in spruce) compared to the controls. This study documents and describes the in vitro ectomycorrhization between T. matsutake and Scots pine or Norway spruce and the variable mycorrhizal structures that matsutake isolates can form.