Patterns of roost site selection and use by Southern Ground-Hornbills in north-eastern South Africa

Different habitats may be used for the needs of various aspects of an animal’s life. Southern Ground-Hornbill Bucorvus leadbeateri groups announce their presence within year-round territories by calling at dawn from their overnight roost sites. Knowledge on ground-hornbill roosting habits is limited. Groups roost in large trees, apparently close to where they end up after daily foraging. We investigated patterns of roost site selection and use for four Southern Ground-Hornbill groups in the Associated Private Nature Reserves, north-eastern South Africa, based on data from GPS-satellite transmitters. The number of roost sites used per month averaged 15.4 ± 4.7 across all groups, indicating little evidence of strong preferences for specific sites. This number was least when groups were breeding, decreasing throughout the early wet season (October–December) and was lowest during the late wet season (January–March) when actively breeding groups frequently roosted close to the nest (54–83% of roosts <1 000 m of the nest). As might be expected, the mean monthly number of nights per roost peaked during the breeding season (December–January). Riparian habitats were preferred for roosting during the breeding season, whereas disturbed areas, as well as Combretumand mopane-dominated habitats were preferred during the dry non-breeding season. Adequate large trees not only for nesting, but also for roosting, particularly in riparian habitats, may therefore be an important and potentially limiting factor for the successful reproduction of Southern Ground-Hornbills.     

Are there multiple circadian clocks in plants?

We have reported that Arabidopsis might have genetically distinct circadian oscillators in multiple cell-types.¹ Rhythms of CHLOROPHYLL A/B BINDING PROTEIN2 (CAB2) promoter activity are 2.5 h longer in phytochromeB mutants in constant red light and in cryptocrome1 cry2 double mutant (hy4-1 fha-1) in constant blue light than the wild-type.² However, we found that cytosolic free Ca²⁺ ([Ca²⁺]_cyt) oscillations were undetectable in these mutants in the same light conditions.¹ Furthermore, mutants of CIRCADIAN CLOCK ASSOCIATED1 (CCA1) have short period rhythms of leaf movement but have arrhythmic [Ca²⁺]_cyt oscillations. More important, the timing of cab1-1 (toc1-1) mutant has short period rhythms of CAB2 promoter activity (∼21 h) but, surprisingly, has a wild-type period for circadian [Ca²⁺]_cyt oscillations (∼24 h). In contrast, toc1-2, a TOC1 loss-of-function mutant, has a short period of both CAB2 and [Ca²⁺]_cyt rhythms (∼21 h). Here we discuss the difference between the phenotypes of toc1-1 and toc1-2 and how rhythms of CAB2 promoter activity and circadian [Ca²⁺]_cyt oscillations might be regulated differently.Key words: circadian rhythms, TOC1, multiple oscillators, CAB2, Ca²⁺ signalling, arabidopsis, circadian [Ca²⁺]_cyt oscillations, aequorin, luciferase, central oscillatorThe plant circadian clock controls a multitude of physiological processes such as photosynthesis, organ and stomatal movements and transition to reproductive growth. A plant clock that is correctly matched to the rhythms in the environment brings about a photosynthetic advantage that results in more chlorophyll, more carbon assimilation and faster growth.³ One of the first circadian clock mutants to be described in plants was the short period timing of cab1-1 (toc1-1), which was identified using the rhythms of luciferase under a CHLOROPHYLL A/B BINDING PROTEIN2 (CAB2) promoter as a marker for circadian period.⁴Circadian rhythms of both CAB2 promoter activity and cytosolic-free Ca²⁺ ([Ca²⁺]_cyt) oscillations depend on the function of a TOC1, CIRCADIAN CLOCK ASSOCIATED1 and LATE ELONGATED HYPOCOTYL (TOC1/CCA1/LHY) negative feedback loop.⁵ In tobacco seedlings, CAB2:luciferase (CAB2:luc) rhythms and circadian [Ca²⁺]_cyt oscillations can be uncoupled in undifferentiated calli.⁶ In Arabidopsis, we reported that toc1-1 has different periods of rhythms of CAB2 promoter activity (∼21 h) and circadian [Ca²⁺]_cyt oscillations (∼24 h). The mutant allele toc1-1 has a base pair change that leads to a full protein that has an amino acid change from Ala to Val in the CCT domain (CONSTANS, CONSTANS-LIKE and TOC1).⁷ On the other hand, the mutant toc1-2 has short period of both rhythms of CAB2 promoter activity and circadian [Ca²⁺]_cyt oscillations (∼21 h).^1,7 This allele has a base pair change that results in changes to preferential mRNA splicing, resulting in a truncated protein with only 59 residues.⁷ Thus, the mutated CCT domain in toc1-1 might lead to the uncoupling of rhythms of CAB2 promoter activity and circadian [Ca²⁺]_cyt oscillations while the absence of TOC1 in toc1-2 causes the shortening of the period of both rhythms. Indeed, zeitlupe-1 (ztl-1) mutants, that have higher levels of TOC1, have long periods of both rhythms of CAB2 promoter activity and circadian [Ca²⁺]_cyt oscillations.¹ The biochemical function of the CCT domain is unknown but it is predicted to play an important role in protein-protein interactions⁸ and nuclear localization.⁹One model to explain the period difference of CAB2:luc expression and circadian [Ca²⁺]_cyt oscillation is that the toc1-1 mutation has uncoupled two oscillators in the same cell. Uncoupled oscillators are a predicted outcome of certain mutations in the recently described three-loop mathematical model.^10–11 However, both rhythms of TOC1 and CCA1/LHY expression, which would be in uncoupled oscillators accordingly to the model, are described as short-period in toc1-1.⁵ Thus, we have favored the model in which CAB2:luc expression and circadian [Ca²⁺]_cyt oscillation are reporting cell-types with different oscillators that are affected differently by toc1-1.It is possible that TOC1 could interact with a family of cell-type specific proteins. The interaction of TOC1 with each member of the family could be affected differently by the mutation in the CCT domain (Fig. 1). Two-hybrid assays have shown that TOC1 interacts with PIF proteins (PHYTOCHROME INTERACTING FACTOR3 and PIF4) and related PIL proteins (PIF3-LIKE PROTEIN 1, PIL2, PIL5 and PIL6).⁸ In fact, TOC1 interaction with both PIF3 and PIL1 is stronger when the N-terminus receiver domain is taken out and the CCT domain is left intact.⁸ Thus, it is possible that TOC1 and different PIF/PIL proteins interact to regulate the central oscillator. This interaction could be impaired by the Ala to Val change in the toc1-1 mutation, leading to the period shortening. However, lines misexpressing PIF3, PIL1 and PIL6 showed no changes in their circadian rhythms.^12–16Open in a separate windowFigure 1Models of how the toc1-1 mutation might differently affect cell-type specific circadian oscillators. The single mutant toc1-1 have 21 h rhythms of CAB2 promoter activity and 24 h-rhythms of [Ca²⁺]_cyt oscillations. The toc1-1 mutation is a single amino acid change in the CCT domain. The CCT domain is involved in protein-protein interaction and/or nuclear localization. We have proposed that circadian oscillators with different periods are present in different cell-types. The luminescence generated by CAB2 promoter-drived luciferase (from the CAB2:luc) is probably originated in the epidermis and mesophyll cells. In this model, we propose that the mutation on the CCT domain impairs the mutated TOC1 interaction with the hypothetical protein Z in these cells-types. In contrast, in other cell-types, the mutated TOC1 still interacts with other hypothetical proteins (W), despite the mutation in the CCT domain. In those cell-types, the circadian oscillator could still run with a 24 h period for [Ca²⁺]_cyt rhythms (from the 35S:AEQ construct). One possible identity for Z and W are the members of the PHYTOCHROME INTERACTING FACTOR (PIF) related PIF3-LIKE (PIL) family.One possible explanation for the absence of alterations in the period of circadian rhythms in lines misexpressing PIF/PIL is that they only have roles in certain cell-types. As an example, PIL6 and PIF3 are involved with flowering time and hypocotyl growth in red light^12–15 while PIL1 and PIL2 are involved with hypocotyl elongation in shade-avoidance responses.¹⁶ Both hypocotyl growth and flowering time require cell-type specific regulation: vascular bundle cells in the case of the flowering time¹⁷ and the cells in the shoot in the case of the hypocotyl elongation.¹⁶ If TOC1 interaction with certain PIF/PIL is indeed cell-type specific, the mutated CCT domain found in the toc1-1 mutant could affect the clock in different ways, depending on the type of PIF/PIL protein expressed in each cell-type. Therefore, a question that arises is: which cell-types are sensitive to the toc1-1 mutation?There is evidence that CAB2 and CATALASE3 (CAT3) are regulated by two oscillators that respond differently to temperature signals.¹⁸ These genes might be regulated by two distinct circadian oscillators within the same tissues or a single cell.¹⁸ Interestingly, the spatial patterns of expression of CAB2 and CATALASE3 overlap in the mesophyll of the cotyledons.¹⁸ Furthermore, rhythms of CAB2 and CHALCONE SYNTHASE (CHS) promoter activity have different periods and they are equally affected by toc1-1 mutation.¹⁹ Whereas CAB2 is mainly expressed in the mesophyll cells, CHS is mainly expressed in epidermis and root cells.¹⁹ However, rhythms of AEQUORIN luminescence, which reports [Ca²⁺]_cyt oscillation, were insensitive to toc1-1 mutation and appear to come from the whole cotyledon.²⁰ One cell-type which is found in the whole cotyledon but is distinct from either mesophyll or epidermis cells is the vascular tissue and associated cells.Another approach to determine which cell-types are insensitive to toc1-1 mutation is to compare the toc1-1 and toc1-2 phenotypes. The period of circadian [Ca²⁺]_cyt oscillations is not the only phenotype that is different in toc1-1 and toc1-2 mutants. Rhythms in CAB2 promoter activity in constant red light are short period in toc1-1 but arrhythmic in toc1-2.^21,22 COLD, CIRCADIAN RHYTHM AND RNA BINDING 2/GLYCINE-RICH RNA BINDING PROTEIN 7 (CCR2/GRP7) is also arrhythmic in toc1-2 but short period in toc1-1 in constant darkness.^7,22 When the length of the hypocotyl was measured for both toc1-1 and toc1-2 plants exposed to various intensities of red light, only toc1-2 had a clear reduction in sensitivity to red light. Therefore, toc1-2 has long hypocotyl when maintained in constant red light while hypocotyl length in toc1-1 is nearly identical to that in the wild-type.²² These differences may allow us to separate which cell-types are sensitive to the toc1-1 mutation and which not.Hypocotyl growth is regulated by a large number of factors such as light, gravity, auxin, cytokinins, ethylene, gibberellins and brassinosteroids.²³ There is also a correlation between the size of the hypocotyl in red light and defects in the circadian signaling network.^24,25 The fact that toc1-1 has different hypocotyl sizes from toc1-2 suggests that circadian [Ca²⁺]_cyt oscillations could be involved in the light-dependent control of hypocotyl growth. Circadian [Ca²⁺]_cyt oscillations might encode temporal information to control cell expansion and hypocotyl growth.^26–28 toc1-1 have short-period rhythms of hypocotyl elongation, which indicates that the cells in the hypocotyl have a 21 h oscillator.²⁹ However, toc1-1 might also have a wild-type hypocotyl length in continuous red light because cells which generate the signal to regulate hypocotyl growth might have 24 h oscillators.The toc1-1 mutation was the first to be directly associated with the plant circadian clock, revitalizing the field of study.⁴ Now, by either uncoupling two feedback loops or by distinct TOC1 protein-protein interaction in different cell-types, toc1-1 has shown new properties of the circadian clock that may deepen our understanding of this system.     

Anxiety- and depression-like behavior are correlated with leptin and leptin receptor expression in prefrontal cortex of streptozotocin-induced diabetic rats

Anxiety and depression are common in diabetics. Diabetes also may cause reduced leptin levels in the blood. We investigated the relation between diabetes induced anxiety- and depression-like behavior, and leptin and leptin receptor expression levels in diabetic rats. The anxiety- and depression-like behaviors of rats were assessed 4 weeks after intraperitoneal injection of streptozotocin. Diabetic rats exhibited greater anxiety-like behavior; they spent more time in closed branches of the elevated plus maze test and less time in the center cells of the open field arena. Increased depression-like behavior was observed in diabetic rats using the Porsolt swim test. Prefrontal cortex (PFC), blood leptin levels and PFC neuron numbers were decreased, and leptin receptor expression and apoptosis were increased in diabetic rats. Blood corticosterone levels also were increased in diabetic rats. These results indicate that reduction of leptin up-regulates leptin receptor expression and may affect PFC neurons, which eventually triggers anxiety- and depression-like behaviors in diabetic rats.     

Effects of exercise and poor indoor air quality on learning,memory and blood IGF-1 in adolescent mice

It is known that regular aerobic exercise enhances cognitive functions and increases blood insulin-like growth factor 1 (IGF-1) levels. People living in urban areas spend most of their time indoors and indoor air quality can affect health. We investigated the effects of aerobic exercise in poor and good air quality environments on hippocampus and prefrontal cortex (PFC) neurons, anxiety, and spatial learning and memory in adolescent mice. Poor air quality impaired spatial learning and memory; exercise did not affect learning or memory impairment. Exercise in a good air quality environment improved spatial learning and memory. Poor air quality increased apoptosis in the hippocampus and PFC. Both exercised and sedentary groups living in a poor air quality environment had lower serum IGF-1 levels than those living in a good air quality environment. Living in a poor air quality environment has negative effects on the hippocampus, PFC and blood IGF-1 levels in adolescent mice, but exercise did not alter the negative effects of poor air quality.     

Whole Grain Intakes in the Diets Of Malaysian Children and Adolescents – Findings from the MyBreakfast Study

Background

Diets rich in whole grain are associated with several health benefits. Little is known however, about whole grain consumption patterns in Malaysia. The aim of this study was to assess whole grain intakes and dietary source in Malaysian children and adolescents.

Methods

This analysis is from the MyBreakfast study, a national cross sectional study investigating eating habits among primary and secondary school children throughout Malaysia, conducted in 2013. Children (n = 5,165) and adolescents (n = 2,947) who completed two days of dietary assessment using a food record or recall respectively were included. The whole grain content of foods was estimated mainly through the use of quantitative ingredient declarations on food labels. All wholegrain foods were considered irrespective of the amount of whole grain they contained.

Results

Overall, only 25% of children and 19% of adolescents were wholegrain consumers. Mean daily intakes in the total sample were 2.3g/d (SD 5.8g/d) in children and 1.7g/d (SD 4.7g/d) in adolescents and in the consumer’s only sample, mean intakes reached 9.1g/d (SD 8.6) and 9.2g/d (SD 7.1g/d) respectively. Wheat was the main grain source of whole grain while ready to eat breakfast cereals and hot cereals were the main food contributors. Less than 3% of the children and adolescents reached the US quantitative whole grain recommendation of 48g/day.

Conclusion

Whole grain is consumed by only a minority of Malaysian children and adolescents and even among consumers, intakes are well below recommendations. Efforts are needed to firstly understand the barriers to whole grain consumption among Malaysian children in order to design effective health promotion initiatives to promote an increase in whole grain consumption.     

Towards Harmonisation of Critical Laboratory Result Management - Review of the Literature and Survey of Australasian Practices

Timely release and communication of critical test results may have significant impact on medical decisions and subsequent patient outcomes. Laboratories therefore have an important responsibility and contribution to patient safety. Certification, accreditation and regulatory bodies also require that laboratories follow procedures to ensure patient safety, but there is limited guidance on best practices. In Australasia, no specific requirements exist in this area and critical result reporting practices have been demonstrated to be heterogeneous worldwide.Recognising the need for agreed standards and critical limits, the AACB started a quality initiative to harmonise critical result management throughout Australasia. The first step toward harmonisation is to understand current laboratory practices. Fifty eight Australasian laboratories responded to a survey and 36 laboratories shared their critical limits. Findings from this survey are compared to international practices reviewed in various surveys conducted elsewhere. For the successful operation of a critical result management system, critical tests and critical limits must be defined in collaboration with clinicians. Reporting procedures must include how critical results are identified; who can report and who can receive critical results; what is an acceptable timeframe within which results must be delivered or, if reporting fails, what escalation procedures should follow; what communication channels or systems should be used; what should be recorded and how; and how critical result procedures should be maintained and evaluated to assess impact on outcomes.In this paper we review the literature of current standards and recommendations for critical result management. Key elements of critical result reporting are discussed in view of the findings of various national surveys on existing laboratory practices, including data from our own survey in Australasia. Best practice recommendations are made that laboratories are expected to follow in order to provide high quality and safe service to patients.     

Mitochondrial mismatch analysis is insensitive to the mutational process

Mismatch distributions are histograms showing the pattern of nucleotide (or restriction) site differences between pairs of individuals in a sample. They can be used to test hypotheses about the history of population size and subdivision (if selective neutrality is assumed) or about selection (if a constant population size is assumed). Previous work has assumed that mutations never strike the same site twice, an assumption that is called the model of infinite sites. Fortunately, the results are surprisingly robust even when this assumption is violated. We show here that (1) confidence regions inferred using the infinite- sites model differ little from those inferred using a model of finite sites with uniform site-specific mutation rates, and (2) even when site- specific mutation rates follow a gamma distribution, confidence regions are little changed until the gamma shape parameter falls well below its plausible range, to roughly 0.01. In addition, we evaluate and reject the proposition that mismatch waves are produced by pooling data from several subdivisions of a structured population.      

Developmental and wound-, cold-, desiccation-, ultraviolet-B-stress-induced modulations in the expression of the petunia zinc finger transcription factor gene ZPT2-2

The ZPT2-2 gene belongs to the EPF gene family in petunia (Petunia hybrida), which encodes proteins with TFIIIA-type zinc-finger DNA-binding motifs. To elucidate a possible function for ZPT2-2, we analyzed its pattern of expression in relation to different developmental and physiological stress signals. The activity of the ZPT2-2 promoter was analyzed using a firefly luciferase (LUC) reporter gene, allowing for continuous measurements of transgene activity in planta. We show that ZPT2-2::LUC is active in all plant tissues, but is strongly modulated in cotyledons upon germination, in leaves in response to desiccation, cold treatment, wounding, or ultraviolet-B light, and in petal tissue in response to pollination of the stigma. Analysis of mRNA levels indicated that the modulations in ZPT2-2::LUC expression reflect modulations in endogenous ZPT2-2 gene expression. The change in ZPT2-2::LUC activity by cold treatment, wounding, desiccation, and ultraviolet-B light suggest that the phytohormones ethylene and jasmonic acid are involved in regulating the expression of ZPT2-2. Although up-regulation of expression of ZPT2-2 can be blocked by inhibitors of ethylene perception, expression in plants is not induced by exogenously applied ethylene. The application of jasmonic acid does result in an up-regulation of gene activity and, thus, ZPT2-2 may play a role in the realization of the jasmonic acid hormonal responses in petunia.