South Cushitic

The South Cushitic or West Rift Cushitic languages split into two branches: Southern vs. Northern. While the Southern branch continues in Burunge, the Northern branch comprises Alagwa and Iraqwoid, which includes the dialects Gorwaa and Iraqw. Internal convergence of Alagwa towards the Southern branch produced bundles of Burunge/Alagwa lexical isoglosses which could easily be wrongly taken to reflect genetic inheritance. Languages such as Qw’adza, Aasáx, Ma’a/Mbugu, and Dahalo must be excluded from an internal classification of South Cushitic for various methodological considerations. Dahalo’s genetic position between South and East Cushitic has not been determined beyond doubt. Ma’a/Mbugu rather represents an extreme case of intertwining of Bantu and Cushitic, involving language shift and deliberate creation of an ethnolinguistic register. Finally, for both Qw’adza and Aasáx, poor overall documentary coverage and the contexts of data acquisition do not allow for reliable integration into an adequate internal classification.

Language Contact in Warlpiri and Light Warlpiri

The Australian Pama-Nyungan language, Warlpiri, is spoken by about 4,000 people mostly in small remote communities in the Northern Territory, and also in a sizable diaspora. Australia has long been a site of extensive language contact, and there is considerable work on Warlpiri and its historical relationships to neighboring languages, including language contact effects. This chapter reviews work on language contact with regard to Warlpiri from historical and contemporary perspectives, situating the work within that about Australian languages more generally. There is clear evidence of the genetic position of Warlpiri, and also of transfer of lexical items between Warlpiri and neighboring languages, including diffusion of a subsection kinship system. More recently, dramatic contact effects have been seen in the emergence of a mixed language, Light Warlpiri.

Conservation genomics of an Australian orchid complex with implications for the taxonomic and conservation status of Corybas dowlingii

This study assessed genomic diversity in an Australian species complex in the helmet orchids to clarify taxonomic delimitation and conservation status of the threatened species Corybas dowlingii, a narrow endemic from southeast Australia. Taxonomic delimitation between the three closely related species C. aconitiflorus, C. barbarae, and C. dowlingii has been mainly based on floral traits which exhibit varying degrees of overlap, rendering species delimitation in the complex difficult. Genomic data for the species complex was generated using double-digest restriction-site associated DNA (ddRAD) sequencing. Maximum likelihood, NeighborNet, and Bayesian structure analyses showed genetic differentiation within the species complex and retrieved genomic signatures consistent with hybridisation and introgression between C. aconitiflorus and C. barbarae, and an intermediate genetic position of C. dowlingii indicating a hybrid origin of the species. The genetic structure analysis showed varying levels of genetic admixture for several C. aconitiflorus, C. barbarae, and C. dowlingii samples, thus further corroborating the presence of hybridisation and introgression within the species complex. The taxonomic status of C. dowlingii D.L.Jones was revised to C. × dowlingii D.L.Jones stat. nov. to reflect its hybrid origin. The conservation status of C. × dowlingii was assessed based on key ecological and ethical aspects, and recommendations made regarding its conservation status in Australian conservation legislation.

Evolution of Yin and Yang isoforms of a chromatin remodeling subunit precedes the creation of two genes

Genes can encode multiple isoforms, broadening their functions and providing a molecular substrate to evolve phenotypic diversity. Evolution of isoform function is a potential route to adapt to new environments. Here we show that de novo, beneficial alleles in the nurf-1 gene became fixed in two laboratory lineages of C. elegans after isolation from the wild in 1951, before methods of cryopreservation were developed. nurf-1 encodes an ortholog of BPTF, a large (>300 kD) multidomain subunit of the NURF chromatin remodeling complex. Using CRISPR-Cas9 genome editing and transgenic rescue, we demonstrate that in C. elegans, nurf-1 has split into two, largely non-overlapping isoforms (NURF-1.D and NURF-1.B, which we call Yin and Yang, respectively) that share only two of 26 exons. Both isoforms are essential for normal gametogenesis but have opposite effects on male/female gamete differentiation. Reproduction in hermaphrodites, which involves production of both sperm and oocytes, requires a balance of these opposing Yin and Yang isoforms. Transgenic rescue and genetic position of the fixed mutations suggest that different isoforms are modified in each laboratory strain. In a related clade of Caenorhabditis nematodes, the shared exons have duplicated, resulting in the split of the Yin and Yang isoforms into separate genes, each containing approximately 200 amino acids of duplicated sequence that has undergone accelerated protein evolution following the duplication. Associated with this duplication event is the loss of two additional nurf-1 transcripts, including the long-form transcript and a newly identified, highly expressed transcript encoded by the duplicated exons. We propose these lost transcripts are non-functional side products necessary to transcribe the Yin and Yang transcripts in the same cells. Our work demonstrates how gene sharing, through the production of multiple isoforms, can precede the creation of new, independent genes.

Evolution of Yin and Yang isoforms of a chromatin remodeling subunit results in the creation of two genes

Genes can encode multiple isoforms, broadening their functions and providing a molecular substrate to evolve phenotypic diversity. Evolution of isoform function is a potential route to adapt to new environments. Here we show that de novo, beneficial alleles in the nurf-1 gene fixed in two laboratory strains of C. elegans after isolation from the wild in 1951, before methods of cryopreservation were developed. nurf-1 encodes an ortholog of BPTF, a large (>300kD) multidomain subunit of the NURF chromatin remodeling complex. Using CRISPR-Cas9 genome editing and transgenic rescue, we demonstrate that in C. elegans, nurf-1 has split into two, largely non-overlapping isoforms (NURF-1.B and NURF-1.D, which we call Yin and Yang) that share only two of 26 exons. Both isoforms are essential for normal gametogenesis but have opposite effects on male/female gamete differentiation. Reproduction in hermaphrodites, which involves production of both sperm and oocytes, requires a balance of these opposing Yin and Yang isoforms. Transgenic rescue and genetic position of the fixed mutations suggest that different isoforms are modified in each laboratory strain. In a related clade of Caenorhabditis nematodes, the shared exons have duplicated, resulting in the split of the Yin and Yang isoforms into separate genes, each containing approximately 200 amino acids of duplicated sequence that has undergone accelerated protein evolution following the duplication. Associated with this duplication event is the loss of two additional nurf-1 transcripts, including the long-form transcript and a newly identified, highly expressed transcript encoded by the duplicated exons. We propose these lost transcripts are non-functional biproducts necessary to transcribe the Yin and Yang transcripts in the same cells. Our work suggests that evolution of nurf-1 isoforms in nematodes creates adaptive conflict that can be resolved by the creation of new, independent genes.