Comparative study of movement patterns of Mastomys natalensis in irrigated rice and fallow fields in eastern Tanzania

A 2‐year capture–mark–recapture study was conducted to estimate home ranges and weekly travel distance of Mastomys natalensis (Smith 1834) in an irrigated rice ecosystem and fallow fields. We found that adults have larger home ranges than subadults in fallow fields but not in rice fields, indicating that fallow fields are more suitable for breeding. Travel distances were larger in rice fields, especially in the transplanting stage, during which rice fields are flooded and provide less food, causing movements into neighbouring fallow fields that then temporarily experience higher population density. A decrease in travel distance was observed in rice fields during the maturity stage, which can be explained by higher food availability and a more suitable, nonflooded situation. Movement of M. natalensis in rice‐fallow mosaic landscapes thus seems to be driven by food availability and flooding status of the rice fields, which can be attributed to land use practices.     

Cytogenetics of the genus Arvicanthis (Rodentia,Muridae). 3. Comparative cytogenetics of A. neumanni and A. nairobae from Tanzania

The African rats of the genus Arvicanthis have been widely studied during recent years to clarify species boundaries and phylogenetic relationships. The wide chromosomal variability of the genus has been highlighted in several studies, with each accepted species characterised by its individual karyotypes and others being revealed as cryptic species. In the present paper we report the karyotype and the C- and G-banding patterns of the two species A. nairobae and A. neumanni from seven localities of Tanzania, an area of the range poorly studied. The two karyotypes were compared to that of A. niloticus, which is considered to be primitive. The karyotype of A. neumanni is characterised by 2n = 53–54 and NFa = 62. This karyotypic variability depends on a widespread Robertsonian polymorphism. The karyotype of A. nairobae shows 2n = 62 and NFa = 78; it diverges from that of A. niloticus through one reciprocal translocation, five inversions and three heterochromatic additions. The comparison with the karyotypes of other species of the genus showed that A. neumanni belongs to the east African lineage (with A. abyssinicus, A. blicki, A. niloticus), while A. nairobae is closer to the central and the west African representatives which were all previously under the name of A. niloticus (ANI-2, ANI-3, ANI-4). The distribution of A. nairobae in east Africa opens new scenarios in the biogeographical pattern of evolution of the genus.     

Genetic insights into Map3k-dependent proliferative expansion of T cells

Mapks are important regulators of T cell proliferative expansion and cell cycle progression. Detailed genetic analysis of unconventional iNKT cells in both Map3k1^ΔKD and Lck^Cre/+Map3k1^f/f mice demonstrated that Mekk1 (encoded by Map3k1) signaling activates Mapks to regulate Cdkn1b (encoding p27^Kip1) expression and p27^Kip1-dependent proliferative expansion in response to antigen. Mekk1 signaling and activation of E3 ubiquitin ligase Itch, by a phosphorylation-dependent conformational change, is also an important regulatory mechanism for the control of T helper cell cytokine production. Cdkn1b expression is regulated by Mekk1-dependent signaling in differentiated Th17 cells. Mekk1 is one of the 19 Ste11-like Map3ks, and Mekk1 signaling regulates iNKT cell proliferative expansion in response to glycolipid antigens and T cell homeostasis in the liver. Tak1 (encoded by Map3k7), a related Map3k to Mekk1, similarly regulates the proliferative expansion and homeostasis of T cells in the liver, and this illustrates the importance of multiple Map3ks for mammalian Mapk signaling.     

A RING to rule them all? Insights into the Map3k1 PHD motif provide a new mechanistic understanding into the diverse roles of Map3k1

Despite the sizable number of components that comprise Mapk cascades, Map3k1 is the only element that contains both a kinase domain and a plant homeodomain (PHD) motif, allowing Map3k1 to regulate the protein phosphorylation and ubiquitin proteasome systems. As such, Map3k1 has complex roles in the regulation of cell death, survival, migration and differentiation. Numerous mouse and human genetic analyses have demonstrated that Map3k1 is of critical importance for the immune system, cardiac tissue, testis, wound healing, tumorigenesis and cancer. Recent gene knockin of Map3k1 to mutate the E2 binding site within the Map3k1 PHD motif and high throughput ubiquitin protein array screening for Map3k1 PHD motif substrates provide critical novel insights into Map3k1 PHD motif signal transduction and bring a brand-new understanding to Map3k1 signaling in mammalian biology.