Capacity building of Multi-Stakeholder Innovation Platform (PIMA) actors in members in community governance, crop calendar construction, and implementation of nature-based solutions

Conversion of dry season pasture to potato and vegetable fields in inland valleys is resulting in biodiversity loss, water resources degradation, pastoral marginalization, and increasing conflicts between herders and farmers. The AICCRA project established multi-stakeholders platforms (MSP) at three inland valleys (Finkolo Ganadougou, Blendio, and Loutana) in Mali and strengthened MSP members' capacity in community governance, crop calendar construction, and implementation of nature-based solutions, resulting in enhanced connections between the stakeholders actors, but also better access to input, information and water governance of inland valleys resources

Breakpoint structure of the Anopheles gambiae 2Rb chromosomal inversion

<p>Abstract</p> <p>Background</p> <p>Alternative arrangements of chromosome 2 inversions in <it>Anopheles gambiae </it>are important sources of population structure, and are associated with adaptation to environmental heterogeneity. The forces responsible for their origin and maintenance are incompletely understood. Molecular characterization of inversion breakpoints provides insight into how they arose, and provides the basis for development of molecular karyotyping methods useful in future studies.</p> <p>Methods</p> <p>Sequence comparison of regions near the cytological breakpoints of 2Rb allowed the molecular delineation of breakpoint boundaries. Comparisons were made between the standard 2R<it>+</it>^{<it>b </it>}arrangement in the <it>An. gambiae </it>PEST reference genome and the inverted 2R<it>b </it>arrangements in the <it>An. gambiae </it>M and S genome assemblies. Sequence differences between alternative 2R<it>b </it>arrangements were exploited in the design of a PCR diagnostic assay, which was evaluated against the known chromosomal banding pattern of laboratory colonies and field-collected samples from Mali and Cameroon.</p> <p>Results</p> <p>The breakpoints of the 7.55 Mb 2R<it>b </it>inversion are flanked by extensive runs of the same short (72 bp) tandemly organized sequence, which was likely responsible for chromosomal breakage and rearrangement. Application of the molecular diagnostic assay suggested that 2R<it>b </it>has a single common origin in <it>An. gambiae </it>and its sibling species, <it>Anopheles arabiensis</it>, and also that the standard arrangement (2R<it>+</it>^<it>b</it>) may have arisen twice through breakpoint reuse. The molecular diagnostic was reliable when applied to laboratory colonies, but its accuracy was lower in natural populations.</p> <p>Conclusions</p> <p>The complex repetitive sequence flanking the 2R<it>b </it>breakpoint region may be prone to structural and sequence-level instability. The 2R<it>b </it>molecular diagnostic has immediate application in studies based on laboratory colonies, but its usefulness in natural populations awaits development of complementary molecular tools.</p

Satellite DNA From the Y Chromosome of the Malaria Vector Anopheles gambiae

Satellite DNA is an enigmatic component of genomic DNA with unclear function that has been regarded as “junk.” Yet, persistence of these tandem highly repetitive sequences in heterochromatic regions of most eukaryotic chromosomes attests to their importance in the genome. We explored the Anopheles gambiae genome for the presence of satellite repeats and identified 12 novel satellite DNA families. Certain families were found in close juxtaposition within the genome. Six satellites, falling into two evolutionarily linked groups, were investigated in detail. Four of them were experimentally confirmed to be linked to the Y chromosome, whereas their relatives occupy centromeric regions of either the X chromosome or the autosomes. A complex evolutionary pattern was revealed among the AgY477-like satellites, suggesting their rapid turnover in the A. gambiae complex and, potentially, recombination between sex chromosomes. The substitution pattern suggested rolling circle replication as an array expansion mechanism in the Y-linked 53-bp satellite families. Despite residing in different portions of the genome, the 53-bp satellites share the same monomer lengths, apparently maintained by molecular drive or structural constraints. Potential functional centromeric DNA structures, consisting of twofold dyad symmetries flanked by a common sequence motif, have been identified in both satellite groups