SummaryThe spindle checkpoint acts as a mitotic surveillance system, monitoring interactions between kinetochores and spindle microtubules and ensuring high-fidelity chromosome segregation [1, 2, 3]. The checkpoint is activated by unattached kinetochores, and Mps1 kinase phosphorylates KNL1 on conserved MELT motifs to generate a binding site for the Bub3-Bub1 complex [4, 5, 6, 7]. This leads to dynamic kinetochore recruitment of Mad proteins [8, 9], a conformational change in Mad2 [10, 11, 12], and formation of the mitotic checkpoint complex (MCC: Cdc20-Mad3-Mad2 [13, 14, 15]). MCC formation inhibits the anaphase-promoting complex/cyclosome (Cdc20-APC/C), thereby preventing the proteolytic destruction of securin and cyclin and delaying anaphase onset. What happens at kinetochores after Mps1-dependent Bub3-Bub1 recruitment remains mechanistically unclear, and it is not known whether kinetochore proteins other than KNL1 have significant roles to play in checkpoint signaling and MCC generation. Here, we take a reductionist approach, avoiding the complexities of kinetochores, and demonstrate that co-recruitment of KNL1Spc7 and Mps1Mph1 is sufficient to generate a robust checkpoint signal and prolonged mitotic arrest. We demonstrate that a Mad1-Bub1 complex is formed during synthetic checkpoint signaling. Analysis of bub3Δ mutants demonstrates that Bub3 acts to suppress premature checkpoint signaling. This synthetic system will enable detailed, mechanistic dissection of MCC generation and checkpoint silencing. After analyzing several mutants that affect localization of checkpoint complexes, we conclude that spindle checkpoint arrest can be independent of their kinetochore, spindle pole, and nuclear envelope localization.
The quality of indoor air in terms of its bioaerosol composition with microorganisms is important due to its potential aetiological role in development of conditions such as Sick Building Syndrome. Hence, laboratory identification of bacteriological components in any bioaerosol from buildings may help elucidate the role of such organisms in disease states, particularly allergy-related conditions. A molecular method was developed employing universal or "broad-range" eubacterial PCR to help identify environmental culturable bacteria from domestic household air. In a "proof of concept" experiment, 16S rDNA PCR was performed on a collection of bacterial isolates originating from indoor air in the domestic home. 16S rDNA PCR was performed using a set of universal primers to successfully generate an amplicon of approximately 1400 bp, which was sequenced to obtain each isolate's identity. Sequence analysis was able to identify 12/13 of the isolates, whereby the majority were Gram-positive (12/13). Nine different genera were identified from the 13 isolates examined, of which, 12/13 were Gram-positive, with the exception being Moraxella osloensis, which was Gram-negative, as well as a novel species of Exiguobacterium. The closest phylogenetic neighbour of the wildtype isolate to a named species within this genus was E. aestuarii (1364/1384 bases; 98.4% homology), followed by E. marinum (97.5%) and with E. acetylicum being the most distantly related of all the described species. On account of this divergence within the 16S rDNA gene operon of the unknown Exiguobacterium isolate, we believe this isolate to represent a novel species of Exiguobacterium, which we have tentatively named Exiguobacterium belfastensis. Although from this study, these organisms are usually unlikely to be clinically significant to healthy individuals with a competent immune system, we recommend that molecular identification methods are used, if considered necessary, as an adjunct to first line phenotypic identification schemes, where a definitive identification is required. When the use of molecular identification methods is justified, employment of partial 16S rDNA PCR and sequencing provides a valuable and reliable method of identification of environmental bacteria in the home. This study demonstrates the usefulness of such methods and a full and comprehensive study is now required to examine the diversity of bacteria in indoor air in the home, with particular emphasis on the risk of such environmental organisms to immunosurpressed patients, such as those with haematological malignancies and who are neutropenic.
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