Landscape Initiative for Far-Eastern Himalayas (Hi-LIFE)

Mountain farming systems rely on both empirical and academic knowledge. Their sustainability depends on how effectively diverse knowledge is used for solution-oriented decision making. For mountains, decisions must be conducive to rural farmers whose livelihoods depend on agriculture and related activities. Adopting transdisciplinary research approach, we define a composite Sustainability Space indicator that will help decision makers better understand the ingredients for sustainability, and formulate policy and management decisions to reinforce on-the-ground sustainability. Sustainability Space was derived through analysis of the positive and negative impact factors co-defined by community and disciplinary experts, and visualized through a radar diagram. We used Principal Component Analysis to understand relationships between factors. The results on Sustainability Spaces for eight cases of farming systems from the far-Eastern Himalayas indicated that the sustainability of farming systems is strengthened if decisions holistically cater to (i) geophysical pre-requisites, (ii) ecological foundations, (iii) integrated processes and practices, (iv) resources, knowledge, and value systems, (v) stakeholders’ development and economic aspirations, (vi) well-being of farming communities, and (vii) government support mechanisms. More equitable the attention to these seven components, the higher the sustainability of farming systems in this region could be.

Download Full-text

Detection of ‘relict’ western lineage of citrus tristeza virus virulent genotype in declining Arunachal Wakro orange

10.1101/2020.08.18.255943 ◽

2020 ◽

Author(s):

Sibnarayan Datta ◽

Bidisha Das ◽

Raghvendra Budhauliya ◽

Reji Gopalakrishnan ◽

Vanlalh Muaka ◽

...

Keyword(s):

Climatic Conditions ◽

Rapid Decline ◽

Eastern Himalayas ◽

Eastern State ◽

State Economy ◽

Himalayan Foothills ◽

Decline Disease ◽

The Government ◽

Far Eastern ◽

Tristeza Virus

ABSTRACTEastern Himalayan foothills are known to have optimal agro-climatic conditions for production of quality citrus fruits including oranges. Among the citrus growing regions of eastern Himalayas, Wakro in the far eastern state of Arunachal Pradesh is known for its superior quality oranges, popular as the Wakro orange or the Arunachal orange, which has been included in Geographical Indication Registry by the Government of India. However, during last few years, Arunachal orange orchards have been experiencing severe infestation of aphid associated with rapid decline disease, causing catastrophe to the farmers as well as state economy. Therefore, in 2015, an intensive survey of severely affected orange orchards was carried out to investigate the aetiological factors of citrus decline. RNA samples extracted from leaf and aphid specimens collected from Wakro orchards were subjected to CTV detection through 3’-UTR specific RT-PCR. Subsequently, ORF1 and CP genetic regions were amplified and clonal-sequencing was performed. Although, BLAST search showed close homology of the present sequences with other virulent genotype VT sequences, detailed phylogenetic analysis demonstrated affinity and clustering of present sequences with VT sequences belonging to the ‘western’ lineage. This finding is considerably distinct from CTV sequences reported from citrus growing orchards in India and other neighbouring countries. Additionally, low diversity of CP gene sequences, recombination patterns and presence of sequence segments identical to the present ones in other CTV genotypes was also revealed. Collectively, these observations indicate pristine and primeval nature of present CTV sequences, corroborating well with the proposed origin of CTV in this part of the globe. We here report our finding of western lineage of CTV virulent genotype VT, which is distinct from CTV molecular epidemiology in other parts of India and discuss the implications of these findings.

Download Full-text

Integrating geospatial tools and species for conservation planning in a data-poor region of the Far Eastern Himalayas

Geology Ecology and Landscapes ◽

10.1080/24749508.2019.1610840 ◽

2019 ◽

Vol 4 (3) ◽

pp. 187-202 ◽

Cited By ~ 3

Author(s):

Kabir Uddin ◽

Nakul Chettri ◽

Yongping Yang ◽

Mahendra Singh Lodhi ◽

Naing Zaw Htun ◽

...

Keyword(s):

Conservation Planning ◽

Eastern Himalayas ◽

Poor Region ◽

Geospatial Tools ◽

Far Eastern

Download Full-text

Researches in Far Eastern Seasonal Correlations

Scientific American ◽

10.1038/scientificamerican09211918-192bsupp ◽

1918 ◽

Vol 86 (2229supp) ◽

pp. 192-192

Keyword(s):

Far Eastern

Download Full-text

Resource Constituent of Russian Regional Economy

Voprosy Ekonomiki ◽

10.32609/0042-8736-2007-6-116-132 ◽

2007 ◽

pp. 116-132 ◽

Cited By ~ 1

Author(s):

S. Kimelman ◽

S. Andyushin

Keyword(s):

Economic Policy ◽

Economic Development ◽

Russian Federation ◽

Regional Economy ◽

Federal District ◽

Economic Potential ◽

Resource Model ◽

The Social ◽

Regional Economic Policy ◽

Far Eastern

The article basing upon estimation of the social and economic potential of Russian Federation subjects shows that the resource model of economic development is suitable for nearly half of them. The advantages of this model are described using the example of the Far Eastern Federal District subjects that could be the proof of the necessity of "resource correction" of regional economic policy in Russia.

Download Full-text

Economic efficiency of using photo-diesel stations in the far eastern region

Problems of Economics and Management of Oil and Gas Complex ◽

10.33285/1999-6942-2020-7(187)-18-23 ◽

2020 ◽

pp. 18-23

Author(s):

A.B. Motigullin ◽

◽

A.S. Lopatin ◽

V.G. Kutcherov ◽

◽

...

Keyword(s):

Economic Efficiency ◽

Eastern Region ◽

Far Eastern

Download Full-text

TBE in China

Tick-borne encephalitis - The Book ◽

10.33442/26613980_12b6-3 ◽

2020 ◽

Keyword(s):

Western China ◽

Ixodes Persulcatus ◽

West China ◽

North West ◽

Haemaphysalis Concinna ◽

Viral Subtype ◽

Japanese Military ◽

Natural Foci ◽

Far Eastern ◽

The Brain

The first TBE patients in China were reported in 1943, and the TBEV was isolated from the brain tissues of 2 patients in 1944 by Japanese military scientists,1 and from patients and ticks (Ixodes persulcatus and Haemaphysalis concinna) in 1952 by Chinese researchers.2 The Far Eastern viral subtype (TBEV-FE) is the endemic subtype that has been isolated from all 3 known natural foci (northeastern China, western China, and southwestern China).14 Recently a new “Himalayan subtype” of the TBEV (TBEV-HIM) was isolated from wild rodent Marmoata himalayana in the Qinghai-Tibet Plateau15. The main vector of the TBEV in China is I. persulcatus.3 One recent report suggests that the TBEV-SIB is prevalent in the Uygur region (North West China)13 but epidemiological modelling indicates that the TBEV may occur even widely all over China (Figure 3).4 Likely, the disease is often missed by clinicians due to a lack of the availability of specific diagnostic assays16.

Download Full-text

Chapter 11: General epidemiology of TBE

Tick-borne encephalitis - The Book ◽

10.33442/26613980_11-3 ◽

2020 ◽

Keyword(s):

Eastern Siberia ◽

Genetic Lineages ◽

Phylogenetic Studies ◽

Tick Borne Encephalitis ◽

Natural Foci ◽

Genetic Sequences ◽

Tick Borne Encephalitis Virus ◽

Almost All ◽

Far Eastern ◽

Reservoir Hosts

Tick-borne encephalitis virus (TBEV) exists in natural foci, which are areas where TBEV is circulating among its vectors (ticks of different species and genera) and reservoir hosts (usually rodents and small mammals). Based on phylogenetic studies, four TBEV subtypes (Far-Eastern, Siberian, European, Baikalian) and two putative subtypes (Himalayan and “178-79” group) are known. Within each subtype, some genetic lineages are described. The European subtype (TBEV-EU) (formerly known also as the “Western subtype”) of TBEV is prevalent in Europe, but it was also isolated in Western and Eastern Siberia in Russia and South Korea. The Far-Eastern subtype (TBEV-FE) was preferably found in the territory of the far-eastern part of Eurasia, but some strains were isolated in other regions of Eurasia. The Siberian (TBEV-SIB) subtype is the most common and has been found in almost all TBEV habitat areas. The Baikalian subtype is prevalent around Lake Baikal and was isolated several times from ticks and rodents. In addition to the four TBEV subtypes, one single isolate of TBEV (178-79) and two genetic sequences (Himalayan) supposed to be new TBEV subtypes were described in Eastern Siberia and China. The data on TBEV seroprevalence in humans and animals can serve as an indication for the presence or absence of TBEV in studied area.

Download Full-text