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Fungal nitrogen metabolism plays a fundamental role in function of mycorrhizal symbiosis and consequently in nutrient cycling of terrestrial ecosystems. Despite its global ecological relevance the information on control and molecular regulation of nitrogen utilization in mycorrhizal fungi is very limited. We have extended the nitrate utilization RNA silencing studies of the model mycorrhizal basidiomycete, Laccaria bicolor, by altering the expression of LbNrt, the sole nitrate transporter-encoding gene of the fungus. Here we report the first nutrient transporter mutants for mycorrhizal fungi. Silencing of LbNrt results in fungal strains with minimal detectable LbNrt transcript levels, significantly reduced growth capacity on nitrate and altered symbiotic interaction with poplar. Transporter silencing also creates marked co-downregulation of whole Laccaria fHANT-AC (fungal high-affinity nitrate assimilation cluster). Most importantly, this effect on the nitrate utilization pathway appears independent of extracellular nitrate or nitrogen status of the fungus. Our results indicate a novel and central nitrate uptake-independent regulatory role for a eukaryotic nitrate transporter. The possible cellular mechanisms behind this regulation mode are discussed in the light of current knowledge on NRT2-type nitrate transporters in different eukaryotes.

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Most boreal and temperate forest trees form a mutualistic symbiosis with soil borne fungi called ectomycorrhiza (ECM). In this association both partners benefit due to nutrient exchange at the symbiotic interface. Laccaria bicolor is the first mycorrhizal fungus with its genome sequenced thus making possible for the first time to analyze genome scale gene expression profiles of a mutualistic fungus. However, in order to be able to take full advantage of the genome sequence, reverse genetic tools are needed. Among them a high throughput transformation system is crucial. Herein we present a detailed protocol for genetic transformation of L. bicolor by means of Agrobacterium tumefaciens with emphasis on critical steps affecting the success and efficiency of the approach.

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In boreal and temperate forest ectomycorrhizal fungi play a crucial role in nitrogen cycling by assimilating nitrogenous compounds from soil and transferring them to tree hosts. The expression profile of fHANT-AC genes, nitrate transporter (Lbnrt), nitrate reductase (Lbnr) and nitrite reductase (Lbnir), responsible for nitrate utilization in the ectomycorrhizal fungus Laccaria bicolor, was studied on variable N regimens. The three genes were shown to be under a common regulation: repressed in the presence of ammonium while growth on nitrate resulted in high transcripts accumulation. The presence of nitrate was shown not to be indispensable for activation of Laccaria fHANT-AC as also N starvation and growth on urea and l-asparagine resulted in high transcript levels. Equally high expression of Laccaria fHANT-AC genes was detected in mycelia grown on variable concentrations of l-glutamine. This finding shows that in L. bicolor N metabolite repression of fHANT-AC is not signalled via l-glutamine like described in ascomycetes. The expression patterns of Lbnrt and Lbnir were also studied in an Lbnr RNA-silenced Laccaria strain. No differences were observed on the N source regulation or the degree of transcript accumulation of these genes, indicating that the presence of high nitrate reductase activity is not a core regulator of L. bicolor fHANT-AC expression. The simultaneous utilization of nitrate and organic N sources, already suggested by high transcript levels of Laccaria fHANT-AC genes on organic N, was supported by the increase of culture medium pH as a result of nitrate transporter activity. The possible ecological and evolutionary significance of the herein reported high regulatory flexibility of Laccaria nitrate utilization pathway for ectomycorrizal fungi and the ectomycorrhizal symbiosis is discussed.

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pSILBAγ silencing vector was constructed for efficient RNA silencing triggering in the model mycorrhizal fungus Laccaria bicolor. This cloning vector carries the Agaricus bisporus gpdII promoter, two multiple cloning sites separated by a L. bicolor nitrate reductase intron and the Aspergillus nidulans trpC terminator. pSILBAγ allows an easy oriented two-step PCR cloning of hairpin sequences to be expressed in basidiomycetes. With one further cloning step into pHg, a pCAMBIA1300-based binary vector carrying a hygromycin resistance cassette, the pHg/pSILBAγ plasmid is used for Agrobacterium-mediated transformation. The pHg/pSILBAγ system results in predominantly single integrations of RNA silencing triggering T-DNAs in the fungal genome and the integration sites of the transgenes can be resolved by plasmid rescue. pSILBAγ construct and two other pSILBA plasmid variants (pSILBA and pSILBAα) were evaluated for their capacity to silence Laccaria nitrate reductase gene. While all pSILBA variants tested resulted in up to 65-76% of transformants with reduced growth on nitrate, pSILBAγ produced the highest number (65%) of strongly affected fungal strains. The strongly silenced phenotype was shown to correlate with T-DNA integration in transcriptionally active genomic sites. pHg/pSILBAγ was shown to produce T-DNAs with minimum CpG methylation in transgene promoter regions which assures the maximum silencing trigger production in Laccaria. Methylation of the target endogene was only slight in RNA silencing triggered with constructs carrying an intronic spacer hairpin sequence. The silencing capacity of the pHg/pSILBAγ was further tested with Laccaria inositol-1,4,5-triphosphate 5-phosphatase gene. Besides its use in silencing triggering, the herein described plasmid system can also be used for transgene expression in Laccaria. pHg/pSILBAγ silencing system is optimized for L. bicolor but it should be highly useful also for other homobasidiomycetes, group of fungi currently lacking molecular tools for RNA silencing.

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Ectomycorrhiza (ECM) is a mutualistic association between fungi and the roots of the vast majority of trees. These include numerous ecologically and economically relevant species and the participating fungal symbionts are predominantly filamentous basidiomycetes. In natural ecosystems the plant nutrient uptake from soil takes place via the extraradical mycelia of these ECM mycosimbionts as a trade for plant photosyntates. The symbiotic phase in the life cycle of ECM basidiomycetes is the dikaryotic hyphae. Therefore, studies on symbiotic relevant gene functions require the inactivation of both gene copies in these dikaryotic fungi. RNA silencing is a eukaryotic sequence homology-dependent degradation of target RNAs which is believed to have evolved as a protection mechanism against invading nucleic acids. In different eukaryotic organisms, including fungi, the RNA silencing pathway can be artificially triggered to target and degrade gene transcripts of interest, resulting in gene knock-down. Most importantly, RNA silencing can act at the cytosolic level affecting mRNAs originating from several gene copies and different nuclei thus offering an efficient means of altering gene expression in dikaryotic organisms. Therefore, the pHg/pSILBAγ silencing vector was constructed for efficient RNA silencing triggering in the model mycorrhizal fungus Laccaria bicolor. This cloning vector carries the Agaricus bisporus gpdII-promoter, two multiple cloning sites separated by a L. bicolor nitrate reductase intron and the Aspergillus nidulans trpC terminator. pSILBAγ allows an easy two-step PCR-cloning of hairpin sequences to be expressed in basidiomycetes. With one further cloning step into pHg, a pCAMBIA1300-based binary vector carrying a hygromycin resistance cassette, makes the pHg/pSILBAγ plasmid compatible with Agrobacterium-mediated transformation. The pHg/pSILBAγ-system results in predominantly single integrations of RNA silencing triggering T-DNAs in the fungal genome and the integration sites of the transgenes can be resolved by plasmid rescue. Besides the optimized use in L. bicolor, general consideration was taken to build a vector system with maximum compatibility with other homobasidiomycetes and different transformation techniques.

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A large number of countries worldwide have legalized homosexual rights. But for 147 years, since when India was a British colony, Section 377 of the Indian Penal Code defines homosexuality as a crime, punishable by imprisonment. This outdated law violates the fundamental rights of homosexuals in India. Despite the fact that literature drawn from Hindu, Buddhist, Muslim, and modern fiction testify to the presence of same-sex love in various forms, homosexuality is still considered a taboo subject in India, by both the society and the government. In the present article, the continuation of the outdated colonial-era homosexuality law and its impact on the underprivileged homosexual society in India is discussed, as well as consequences to this group's health in relation to HIV infection.

Muitos países têm legalizado os direitos homossexuais. Mas há 147 anos, desde quando a índia ainda era colônia britânica, a Seção 377 do Código Penal indiano define a homossexualidade como crime passível de prisão. Esta lei antiga viola os direitos fundamentais de homossexuais na índia. Embora as literaturas hindu, budista, muçulmana, e a ficção moderna confirmem a presença de sentimento de amor entre pessoas do mesmo sexo, a homossexualidade ainda é considerada um tabu na índia, tanto pela sociedade como pelo governo. No presente artigo, discute-se a continuidade dessa lei da época colonial sobre homossexualidade e seu impacto na sociedade indiana desfavorecida, bem como as conseqüências para a saúde desse grupo quanto à infecção pelo HIV.

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A large number of countries worldwide have legalized homosexual rights. But for 147 years, since when India was a British colony, Section 377 of the Indian Penal Code defines homosexuality as a crime, punishable by imprisonment. This outdated law violates the fundamental rights of homosexuals in India. Despite the fact that literature drawn from Hindu, Buddhist, Muslim, and modern fiction testify to the presence of same-sex love in various forms, homosexuality is still considered a taboo subject in India, by both the society and the government. In the present article, the continuation of the outdated colonial-era homosexuality law and its impact on the underprivileged homosexual society in India is discussed, as well as consequences to this group's health in relation to HIV infection.

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Our recent genome-wide allelotyping analysis of gallbladder carcinoma identified 3p, 8p, 9q and 22q as chromosomal regions with frequent loss of heterozygosity. The present study was undertaken to more precisely identify the presence and location of regions of frequent allele loss involving those chromosomes in gallbladder carcinoma. Microdissected tissue from 24 gallbladder carcinoma were analysed for PCR-based loss of heterozygosity using 81 microsatellite markers spanning chromosome 3p (n=26), 8p (n=14), 9q (n=29) and 22q (n=12) regions. We also studied the role of those allele losses in gallbladder carcinoma pathogenesis by examining 45 microdissected normal and dysplastic gallbladder epithelia accompanying gallbladder carcinoma, using 17 microsatellite markers. Overall frequencies of loss of heterozygosity at 3p (100%), 8p (100%), 9q (88%), and 22q (92%) sites were very high in gallbladder carcinoma, and we identified 13 distinct regions undergoing frequent loss of heterozygosity in tumours. Allele losses were frequently detected in normal and dysplastic gallbladder epithelia. There was a progressive increase of the overall loss of heterozygosity frequency with increasing severity of histopathological changes. Allele losses were not random and followed a sequence. This study refines several distinct chromosome 3p, 8p, 9q and 22q regions undergoing frequent allele loss in gallbladder carcinoma that will aid in the positional identification of tumour suppressor genes involved in gallbladder carcinoma pathogenesis.

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The etiology of small cell lung cancer (SCLC) is strongly tied to cigarette smoking, and now there is considerable information concerning molecular abnormalities involved in the pathogenesis of SCLC. Autocrine growth factors such as neuroendocrine regulatory peptides (eg, bombesin/gastrin-releasing peptide) are prominent in SCLC. Dominant oncogenes of the Myc family are frequently overexpressed in both SCLC and non-small cell lung cancer (NSCLC), while the K-RAS oncogene is never mutated in SCLC but it is in 30% of NSCLCs. The most frequent genetic abnormalities involve tumor suppressor genes (TSGs). The TSG p53 is mutated in more than 90% of SCLCs and more than 50% of NSCLCs; the retinoblastoma TSG is inactivated in over 90% of SCLC but only 15% of NSCLCs, and p16, the other component of the retinoblastoma/p16 pathway, is almost never abnormal in SCLC but is inactivated in more than 50% of NSCLCs. The FHIT TSG is inactivated in 50% to 70% of all lung cancers. Recently, we completed a genome-wide allelotyping study using approximately 400 polymorphic markers distributed at around 10 cM resolution across the human genome comparing SCLCs and NSCLCs, looking for all possible TSG sites by loss of heterozygosity. We found that, on average, 17 loci showed loss of heterozygosity in individual SCLCs and 22 for NSCLC, with an average size of loss of 50 to 60 cM, and an average frequency of microsatellite abnormalities of five per tumor. There were 22 different "hot spots" for loss of heterozygosity, 13 with a preference for SCLC, seven for NSCLC, and two affecting both. This provides clear evidence on a genome-wide scale that SCLC and NSCLC differ significantly in the TSGs that are inactivated during their pathogenesis. Acquired hypermethylation of the promoter region of key genes has become one of the most common mechanisms that tumors use to inactivate the function of tumor suppressor and other genes. We recently completed a study of tumor-acquired promoter hypermethylation for nine genes (p16, DAPK, MGMT, GSTP1, RAR beta, FHIT, ECAD, p14ARF, and TIMP1). We found differences in the frequency of RAR beta methylation (70% for SCLC and 40% for NSCLCs). Finally, we looked at the bronchial epithelium accompanying SCLC and NSCLC for the occurrence of clonal alterations using precise laser capture microdissection with subsequent allelotyping for polymorphic markers. In NSCLC, we frequently find clones of cells with molecular abnormalities in histologically affected epithelium (eg, carcinoma in situ, dysplasia, hyperplasia) and occasionally in normal-appearing epithelium in the cases of current or former smokers. In SCLC these histologic preneoplastic changes were minimal. However, in studies of histologically normal respiratory epithelium, we found a several-fold increased rate of allele loss in SCLC compared with NSCLC patients. Thus, the smoking-damaged histologically normal epithelium associated with SCLC appeared genetically scrambled and has incurred significantly more damage than the epithelium accompanying NSCLCs. We conclude that SCLC and NSCLCs do not differ significantly in the number of genetic alterations that occur. However, SCLCs do differ significantly from NSCLCs in the specific genetic alterations that occur. In addition, smoking-damaged bronchial epithelium accompanying SCLCs appears to have undergone significantly more acquired genetic damage than that accompanying NSCLCs. Future studies need to identify the specific genes involved at these multiple sites and determine if these provide new tools for early molecular detection and monitoring of chemoprevention efforts, and serve as specific targets for developing new therapies. Semin Oncol 28 (suppl 4):3-13.

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