The complete mitochondrial genome of Trigonisca nataliae (Hymenoptera, Apidae) assemblage reveals heteroplasmy in the control region.

The evolution of mitochondrial genomes in the stingless bees is surprisingly dynamic, making them a model system to understand mitogenome structure, function, and evolution. Out of the seven mitogenomes available in this group, five exhibit atypical characteristics, including extreme rearrangements, rapid evolution and complete mitogenome duplication. To further explore the mitogenome diversity in these bees, we utilized isolated mtDNA and Illumina sequencing to assemble the complete mitogenome of Trigonisca nataliae, a species found in Northern Brazil. The mitogenome of T. nataliae was highly conserved in gene content and structure when compared to Melipona species but diverged in the control region (CR). Using PCR amplification, cloning and Sanger sequencing, six different CR haplotypes, varying in size and content, were recovery. These findings indicate that heteroplasmy, where different mitochondrial haplotypes coexist within individuals, occurs in T. nataliae. Consequently, we argue that heteroplasmy might indeed be a common phenomenon in bees that could be associated with variations in mitogenome size and challenges encountered during the assembly process.

Rapid evolution, rearrangements and whole mitogenome duplication in the Australian stingless bees Tetragonula (Hymenoptera: Apidae): A steppingstone towards understanding mitochondrial function and evolution.

The extreme conservation of mitochondrial genomes in metazoans poses a significant challenge to understanding mitogenome evolution. However, the presence of variation in gene order or genome structure, found in a small number of taxa, can provide unique insights into this evolution. Previous work on two stingless bees in the genus Tetragonula (T. carbonaria and T. hockingsi) revealed highly divergent CO1 regions between them and when compared to the bees from the same tribe (Meliponini), indicating rapid evolution. Using mtDNA isolation and Illumina sequencing, we elucidated the mitogenomes of both species. In both species, there has been a duplication of the whole mitogenome to give a total genome size of 30,666 bp in T. carbonaria; and 30,662 bp in T. hockingsi. These duplicated genomes present a circular structure with two identical and mirrored copies of all 13 protein coding genes and 22 tRNAs, with the exception of a few tRNAs that are present as single copies. In addition, the mitogenomes are characterized by rearrangements of two block of genes. We believe that rapid evolution is present in the whole Indo-Malay/Australasian group of Meliponini but is extraordinarily elevated in T. carbonaria and T. hockingsi, probably due to founder effect, low effective population size and the mitogenome duplication. All these features - rapid evolution, rearrangements, and duplication - deviate significantly from the vast majority of the mitogenomes described so far, making the mitogenomes of Tetragonula unique opportunities to address fundamental questions of mitogenome function and evolution.

Regulatory mechanisms behind the phenotypic plasticity associated with Setaria italica water deficit tolerance.

Drought is one of the main environmental stresses that negatively impacts vegetative and reproductive yield. Water deficit responses are determined by the duration and intensity of the stress, which, together with plant genotype, will define the chances of plant survival. The metabolic adjustments in response to water deficit are complex and involve gene expression modulation regulated by DNA-binding proteins and epigenetic modifications. This last mechanism may also regulate the activity of transposable elements, which in turn impact the expression of nearby loci. Setaria italica plants submitted to five water deficit regimes were analyzed through a phenotypical approach, including growth, physiological, RNA-seq and sRNA-seq analyses. The results showed a progressive reduction in yield as a function of water deficit intensity associated with signaling pathway modulation and metabolic adjustments. We identified a group of loci that were consistently associated with drought responses, some of which were related to water deficit perception, signaling and regulation. Finally, an analysis of the transcriptome and sRNAome allowed us to identify genes putatively regulated by TE- and sRNA-related mechanisms and an intriguing positive correlation between transcript levels and sRNA accumulation in gene body regions. These findings shed light on the processes that allow S. italica to overcome drought and survive under water restrictive conditions.

Conserved numts mask a highly divergent mitochondrial-COI gene in a species complex of Australian stingless bees Tetragonula (Hymenoptera: Apidae).

Tetragonula carbonaria, Tetragonula davenporti, Tetragonula hockingsi and Tetragonula mellipes comprise a species complex of Australian stingless bee species known as the 'Carbonaria' group. The species are difficult to distinguish morphologically and the major species-defining characters relate to comb architecture and nest entrance ornamentation. The taxonomy of the group is further complicated by likely nuclear mitochondrial pseudogenes (numts) and inter-specific hybrids. Here we demonstrate the existence of COI numts and isolate and characterize the 'true' mt-COI gene in T. carbonaria and T. hockingsi. Numts were isolated from enriched-nuclear DNA extraction followed by PCR amplification and Sanger sequencing, and were recognized by the presence of deletions and/or premature stop codons in the translated sequences. The mt-COI sequences were obtained from NGS sequencing using purified mtDNA. In T. carbonaria, two numts (numt1 and numt2) were identified and a third (numt3) was identified in T. hockingsi. Numt2 and numt3 are similar (1.2% sequence divergence), indicating a recent common origin. The genetic distance between the mt-COI of the two Tetragonula species was higher than might be expected for closely related species, 16.5%, corroborating previous studies in which T. carbonaria and T. hockingsi were regarded as separate species. The three numts are more similar to the COI of other stingless bee species, including Australian Austroplebia australis and South American Melipona bicolor (81.7-83.9%) than to the mt-COI of their own species (70-71.4%). This is because the mt-COI of T. carbonaria and T. hockingsi differ greatly from other Meliponinae. Our findings explain some formerly puzzling aspects of Carbonaria biogeography, and misinterpreted amplifications.