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Forest certification has been used as a tool to promote forestry responsibility towards sustainable forest management. Forest Stewardship Council (FSC) is one of the certification systems that is well recognised in Europe. Nevertheless, compared to other European countries, the number of FSC chain of custody (CoC) certifications in Finland is relatively low. Semi-structured interviews were conducted with six FSC CoC certified companies to explore their experiences towards implementing and maintaining the system in their companies. The sample group was comprised of wood and paper product industries in manufacturing and trading sectors. Thematic analysis of the interviews revealed the challenges companies encountered. The results indicated that there were eight types of challenges, including three internal and five external ones, hindering the development of FSC CoC certification in Finland. Internal challenges included competence, financial resources, and a lack of motivation to change. External challenges included insufficient marketing and demand, uncertain cost benefit, keen competitor programmes, limited supply, and long trademark approval time. Meanwhile, the relevant solutions these companies adopted to deal with the challenges were discussed. Since external challenges out-numbered internal ones, it seemed that certified companies are not able to tackle the existing challenges alone. Joint-effort among other actors in the forestry sector, for instance, the national authority, FSC national office, certification bodies are essential to influence the rate of certification uptake. Furthermore, participants discussed about the future development of FSC CoC certification system in Finland. Interviewees believed that the enactment of the EU Timber Regulation (EUTR) and the introduction of forest certification into national public procurement policy could positively impact the development of the system. The results of this study could be used as a reference for potential certificate users to prepare themselves for implementing FSC CoC certification system. In addition, the study could shed a light on the development of FSC in Finland in the future.

The changes in lake diatom assemblages as a response to climate warming over the past three decades were examined in 26 lakes across Northwestern Finnish Lapland using multivariate statistical techniques. The lakes are distributed along a steep climatic and vegetational gradient, covering three distinct vegetation zones spanning boreal coniferous forest, mountain birch woodland, and treeless tundra. Lakes were selected following a study realised by Weckström and Korhola in 2001, who had sampled the same lakes for surface-sediment diatom assemblages, physical, and chemical limnological variables. Climate data from the past 30 years was retrieved, showing a slow and steady yearly increase in temperature, with strong seasonal fluctuation and fall months experiencing the strongest warming. Surface sediment samples were taken from the lakes and their diatom communities analysed. A total of 185 diatom taxa representing 27 genera were recorded. Ordination techniques (DCA, CCA) at the genus and species level were performed to identify the main patterns of variation between diatom data from the original data set and the current study, and their relationship to environmental variables. Strong changes were recorded in four of the lakes with major shifts in dominant diatom species. Moderate changes were recorded in eight lakes, where dominance changes were recorded for a few species while the majority remained unchanged. The remaining 14 lakes did not show noticeable changes over the 30-year period. Changes observed in the studied lakes did not follow a widely observed pattern in northern Hemisphere lakes. The results indicate that while climate change is a driving factor behind changing lake dynamics with increasing temperatures and decreasing lake ice cover duration, it cannot be the only force responsible.

Mobility, the somewhat regular and recurring physical movement of people from place to place, is a very important part of a broader transition to sustainability. In Finland the transport sector accounts for 20 % of total greenhouse gas emissions and while emissions have been steadily declining, the pace is not sufficient to meet current emission cut targets. When looking at household generated greenhouse gas emissions, mobility is the single largest contributor. Previous research has focused a lot on technological advancements and individuals’ choices as causes and solutions to sustainable mobility. These approaches have been criticized for underemphasizing the importance of social conditions. Practice theories have been presented as an alternative way of understanding mobility behaviors, challenging the mainstream individualistic explanations. Practices are routinized human behaviors that are made of several elements of materials, meanings, and competences. This thesis adopts a practice theoretical view in analyzing people’s mobility before and during the COVID-19 pandemic. The aim is to learn what practice theory can teach us about sustainable mobility, and how the pandemic has affected people’s mobility in Finland. Nine semi-structured interviews were conducted, asking the participants about their mobility practices before and during the COVID-19 pandemic, forming a comprehensive picture of their daily lives from a mobility point of view. The results were analyzed using qualitative theory-based content analysis. The results indicated that people’s mobility is a complex system which was largely affected by the COVID-19 pandemic. Various elements either enabling or hindering the use of different transport modes were identified, as were important connections between different mobility practices. Practice theory has been often used to research one mobility practice at a time and the broader look of this study, focusing on multiple mobility practices, is potentially the most important contribution this thesis makes to previous mobility research. While not providing direct answers to how people’s mobility could be made more sustainable, this thesis makes an important contribution to practice theoretical mobility research which in a Finnish context is very scarce.

Background– The BCL-2 protein family members are major regulators of apoptosis, and the anti-apoptotic (pro-survival) members of the family is commonly targeted with BH3 mimetic drugs in haematological cancers. However, these treatments have not been very impactful when administered as single agents and they have long been investigated for combination therapy with other agents. Acute myeloid leukaemia (AML) is one of the difficult-to-cure haematological malignancies. A recently approved therapy for AML consists of the combinatorial administration of venetoclax (a selective BCL-2 inhibitor) and a DNA methyltransferase (DNMT) inhibitor such as azacitidine or decitabine. Although this novel therapy has shown promising clinical results, the majority of the patients still relapse under this treatment. These relapsed patients typically become highly resistant to treatment and have poor prognosis, emphasising the need for new effective drug combinations. Apart from BCL-2, other family members like BCL-xL and MCL1 are also common targets of BH3-mimetic drugs. This project thus aims to understand and characterise the resistance against BH3-mimetics and investigate new therapeutic approaches to overcome the challenges of resistance. Aims– This study aims (i) to characterise BH3-resistant AML cell lines for uncovering the mechanisms of drug resistance, and (ii) to identify possible combination treatment options for overcoming drug-resistance. Methods– Viability assays with Cell Titer Glo® (CTG) and Drug Sensitivity and Resistance Testing (DSRT). The long-term effectiveness of venetoclax, azacitidine and talazoparib (a PARP inhibitor) as single agents, double combinations and triple combination were investigated with Time-to-Progression (TTP) assay. For the resistant cell line models, underlying resistance mechanisms were assessed by checking protein expression of pro- and/or anti-apoptotic members of the BCL-2 family members with western blot (WB). Real-time quantitative PCR (RT-qPCR) and WB were carried out for transcriptional and translational expression analyses of certain DNA damage-associated genes in PARP inhibitor-resistant cell lines. Results– Drug screening with DSRT has revealed promising results for two combination treatments of a BCL-xL inhibitor (A-1331852) (i) with an Aurora kinase A inhibitor (alisertib) and (ii) with an MCL1 inhibitor (S63845) for BCL-xL inhibitor-resistant cells. WB analyses of BCL-2 family members showed translational upregulation of un-inhibited members of the anti-apoptotic proteins in BH3-mimetic-resistant cell lines. A venetoclax-resistant AML cell line showed increased levels of the DNA damage marker P-γ-H2Ax upon treatments containing venetoclax, as well as increased levels of cleaved-PARP1, indicating induction of apoptosis. RT-qPCR analyses revealed increased mRNA expression of PARP1 in two resistant cell lines, whereas no significant expression changes in other DNA repair mechanism genes on the transcriptional level. Conclusions– In BH3-mimetic-resistant AML cell lines, apoptosis is avoided through translational upregulation of un-inhibited anti-apoptotic members of the BCL-2 family, and this resistance can be countered by combination treatment for additional inhibition of the compensatory anti-apoptotic proteins. Venetoclax is still effective on cells resistant to it, by inducing DNA damage and sensitising these cells against inhibitors of the members of DNA repair pathway. The transcriptional upregulation of PARP1 and the increase in its auto-catalytic activity suggests the DNA damage-inducing effects of the triple combination treatment [Ven + Aza + Tal].

Over the past years sugar consumption has seen great increases worldwide, together with a rise in the prevalence of metabolic diseases. There is a growing need for a comprehensive characterisation of the genes involved in sugar metabolism, yet the mechanisms by which cells sense and respond to sugars in vivo have remained incompletely understood. Here, I analyse members of a protein family best known for their regulation of differentiation during development with regards to their role in sugar metabolism. The Hairy and Enhancer of Split (HES) protein family are a group of basic helix-loop-helix (bHLH) transcription factors that function as major downstream effectors of the Notch signalling pathway. In mammals, the HES proteins have mostly been studied for their role in cell differentiation, but HES1 has been implicated in metabolic control. Drosophila has several transcription factors belonging to the HES family, including Hairy and seven bHLH transcription factors located in the Enhancer of split complex (E(spl)-C). The E(spl)-C bHLH transcription factors display high homology and are considered to be genetically redundant, and therefore little is known about their individual functions. The other HES family members in Drosophila have not previously been linked to metabolic regulation, but Hairy has been shown to repress the tricarboxylic acid cycle. In light of the findings implicating HES1 and Hairy in the regulation of metabolism, I systematically investigated the role of the HES transcription factors in sugar metabolism. By using the GAL4/UAS system in Drosophila melanogaster, I knocked down gene expression of each of the family members, and raised the flies on diets varying in sugar content to identify possible sugar intolerance phenotypes. Here, I show that knockdown of one of the E(spl)-C bHLH genes led to severe sugar intolerance that affected both survival and organismal growth, but did not alter the levels of circulating carbohydrates and storage lipids as measured with colorimetric assays and lipid staining. Furthermore, I identify the tissues in which this transcription factor functions to provide sugar tolerance. Using analysis of publically available chromatin-immunoprecipitation sequencing data coupled with quantitative RT-PCR, I uncover mTOR target Thor/4E-BP as a putative target gene. Additionally, I show that Hairy is similarly required for complete sugar tolerance, but that the mechanism differs from the E(spl)-C bHLH transcription factor. Hairy binds to and positively regulates expression of genes involved in glycolysis and the pentose phosphate pathway, suggestive of a cooperation with earlier known regulators of sugar sensing. In conclusion, I have shown that only two HES family members are involved in the regulation of sugar metabolism and that their regulatory mechanisms are distinct, implying that the HES family members have more diverse roles than previously assumed.

The degree of neurogenesis in the adult hippocampal dentate gyrus (DG) is the center of the discussion in the field of adult neurogenesis. Although there is an on-going controversy, accumulating evidence suggests that the neural stem cells (NSCs) in the adult human DG are very few. The question remains open as to why there are so few NSCs in the adult human DG when compared with the rodent DG. In order to address these questions, it seems necessary to understand the developmental process of the NSCs in the adult human DG. In this thesis, the neural stem and progenitor cells in the fetal human DG are characterized. In addition to these findings, a semi-automatic method for counting and categorizing cells in their expressions of immunochemistry markers is developed.

Charcot-Marie-Tooth disease (CMT) is a collective name for inherited neuropathies affecting the peripheral nerves. CMT affects 1:2500 children and adults worldwide. The disease is genetically highly heterogeneous, and the pathogenic mechanisms are largely unknown. Thus far, there is no cure known for the Charcot-Marie-Tooth disease. Therefore, the study of the genetic factors involved in the disease and the understanding of the underlying molecular mechanisms will benefit the development of strategies to prevent or treat these diseases. In this thesis, a new candidate gene for CMT was investigated in patient fibroblasts. The novel gene variant was originally found at University of Helsinki in a pair of Finnish brothers with CMT; and in later examinations, in their affected family members. The gene encodes an ER calcium channel receptor that is responsible for Ca2+ release from the endoplasmic reticulum (ER) and plays an important role in the regulation of various cellular processes. In this thesis, I studied the effect of the variant in patient fibroblasts by Western blotting, quantitative reverse transcriptase PCR (RT-qPCR) and calcium imaging. I also knocked down the gene using siRNA in healthy fibroblasts to investigate if the loss of the receptor has a similar effect on calcium signaling as the patient variant. My results showed that siRNA treatment significantly decreased the targeted protein levels and delayed the ATP-evoked Ca2+ release from ER without profound effect on the amplitude of the release. Similar effects of the studied mutation were observed in one patient cell line, but not in the other. Patient cell line, which did not have alterations in the levels of the protein and Ca2+ release, had elevated levels of mRNA of the affected gene. The results suggest that the gene variant does not impair the total volume of the ATP-evoked Ca2+ release from ER. The possible effect of the studied mutation may be related to the decreased levels of the mutated protein, which at the functional level may affect the timing of total Ca2+ release from ER. However, the functional effect of the variant could not be confirmed with the fibroblast cells; further experiments are needed to clearly confirm the variant’s effect on calcium signaling.

Cerebral dopamine neurotrophic factor (CDNF) belongs to the the family of neurotrophic factors that are evolutionary conserved, having a unique structure, with two domains: C-terminal domain and the N-terminal domain, and a cysteine bridge. It is known to be involved in the repair of the dopaminergic neurons when studied in the animal models of PD, which shows their different mode of action as compared to other neurotrophic factors, highlighting their therapeutic potential. Analysis of the crystal structure shows that CDNF and MANF consist of two domains: the saposin-like N-terminal domain with five α-helices stabilized by three disulphide bridges, and presumably unstructured C-terminal domain with a disulphide bridge. Characteristic feature of saposin-like proteins is their ability to interact with membranes or lipids. The lipid interaction may be crucial for the activity of CDNF and MANF proteins. In the first part of this project, the binding of CDNF was tested with several oxidized lipids, using two methods; Co-sedementation assay and lipid fluorescence assay;with two different types of probes. According to the results, CDNF seemed to show binding with POVPC. The second part of the project involved testing the binding and internalization of CDNF to mouse myoblast cells in the presence of oxidized lipid; POVPC. It was observed that CDNF seemed to show binding to the cell surface of the mouse myoblast cells (C2C12) and is also observed to be internalized to the cells as well. However, as these are the preliminary results, so we need to further test the binding between the protein and other lipids and devise more precise protocols for the testing the internalization to the cells.

Puberty is a process of physiological changes, through which an immature individual becomes sexually mature. In humans, timing of puberty is highly variable within and between sexes and populations. Timing of puberty represents a complex trait, which is controlled both genetically and environmentally. Precocious pubertal timing is associated with development of metabolic diseases later in life, such as obesity and diabetes, and other disorders as ovarian and testicular cancer. Despite the estimated high heritability (50-80%) of pubertal timing, its genetic background is still poorly understood. Recently, the genome-wide association studies (GWASs) revealed many novel pubertal timing associated loci. Nevertheless, molecular mechanisms behind these associations remain elusive. This thesis focused on gene vestigial-like family member 3 (VGLL3), which is associated with pubertal timing in humans and maturation in Atlantic salmon (Salmo salar). Since the main physical structures, such as the hypothalamus and the pituitary gland, needed in reaching puberty are evolutionary conserved and start to develop in vertebrates during embryogenesis, the aim was to study the expression pat-terns and role of vgll3 in zebrafish (Danio rerio) during this period. In order to localize expression patterns of the vgll3 gene in zebrafish embryos, a whole-mount in situ RNA hybridization (ISH) was performed. mRNA overexpression and morpholino oligonucleotide (MO) knockdown techniques were used to alter the vgll3 gene expression levels in 0-5 dpf zebrafish. The combined injections of both mRNA and MO were performed to validate MO specificity. The ISH experiment showed the expression patterns in 0-1 dpf embryos. The expression was ubiquitous up to 6 hours post fertilization becoming more localized to specific regions in the head and trunk of the embryos during the later stages. Altering vgll3 expression with high concentrations of synthetic mRNA or MO lead to phenotypical abnormalities such as shortened and curved body axis, pericardial and yolk sack edemas, deformed heads and eyes. However, it remained unclear if these malformations appear only due to the alteration of vgll3 expression levels. The results suggest that vgll3 may play an important role in the embryonic development. However, the study does not show that vgll3 has impacts on the pubertal timing in vertebrates by affecting the development of the structures required for sexual maturation.

The human cerebral cortex is characteristically large and folded, which can be majorly attributed to the high number and variety of neural progenitors during embryonic development. Radial glial cells are essential neural progenitors during neurogenesis. In addition to giving rise to new cell types, they also provide scaffold for migrating newborn neurons. Radial glia are known to portray peculiar characteristics in their cell division process, including unique migratory behavior as well as specifically regulated cleavage furrow orientation. While these processes of radial glial division have been studied extensively, the underlying molecular mechanisms are still largely unknown. ABBA (actin-bundling protein with BAIAP2 homology) and NEDD9 (neural precursor cell expressed, developmentally downregulated 9) are proteins, which are both known to be expressed in certain radial glia progenitors during embryonic development, while they are mainly absent in neurons. ABBA has a defined role of regulating plasma membrane deformation and actin polymerization in radial glia, while NEDD9 expression levels are a known factor in the correct progression from mitosis to cytokinesis. An interaction between ABBA and NEDD9 has previously been identified in a yeast two-hybrid screen done for the embryonic mouse brain. The aim of this thesis was to validate the interaction between ABBA and NEDD9 biochemically. First, their interaction was evaluated by doing co-immunoprecipitation assays on the endogenous proteins from C6 cells. The second approach was to test, whether their interaction is directly mediated by the N-terminal SH3-domain of NEDD9 and the proline-rich C-terminal portion of ABBA. This was done by doing biochemical binding assays using purified proteins and domains of interest. While co-immunoprecipitation of the two proteins gave results indicating an interaction, I could show that there is no direct binding between NEDD9 SH3-domain and ABBA, suggesting that the interaction might require other domains or be indirect. Together, these results provide valuable information that will help characterize what roles of ABBA and NEDD9 play in cortical development and beyond.