Brain responses to violet, blue, and green monochromatic light exposures in humans: prominent role of blue light and the brainstem

Background

Relatively long duration retinal light exposure elicits nonvisual responses in humans, including modulation of alertness and cognition. These responses are thought to be mediated in part by melanopsin-expressing retinal ganglion cells which are more sensitive to blue light than violet or green light. The contribution of the melanopsin system and the brain mechanisms involved in the establishment of such responses to light remain to be established.

Methodology/Principal Findings

We exposed 15 participants to short duration (50 s) monochromatic violet (430 nm), blue (473 nm), and green (527 nm) light exposures of equal photon flux (10¹³ph/cm²/s) while they were performing a working memory task in fMRI. At light onset, blue light, as compared to green light, increased activity in the left hippocampus, left thalamus, and right amygdala. During the task, blue light, as compared to violet light, increased activity in the left middle frontal gyrus, left thalamus and a bilateral area of the brainstem consistent with activation of the locus coeruleus.

Conclusion/Significance

These results support a prominent contribution of melanopsin-expressing retinal ganglion cells to brain responses to light within the very first seconds of an exposure. The results also demonstrate the implication of the brainstem in mediating these responses in humans and speak for a broad involvement of light in the regulation of brain function.     

Tuning of the enzyme ratio in a neutral redox convergent cascade: A key approach for an efficient one-pot/two-step biocatalytic whole-cell system

The efficiency of a versatile in vivo cascade involving a promiscuous alcohol dehydrogenase, obtained from a biodiversity search, and a Baeyer–Villiger monooxygenase was enhanced by the independent control of the production level of each enzyme to produce ε-caprolactone and 3,4-dihydrocoumarin. This goal was achieved by adjusting the copy number per cell of Escherichia coli plasmids. We started from the observation that this number generally correlates with the amount of produced enzyme and demonstrated that an in vivo multi-enzymatic system can be improved by the judicious choice of plasmid, the lower activity of the enzyme that drives the limiting step being counter-balanced by a higher concentration. Using a preconception-free approach to the choice of the plasmid type, we observed positive and negative synergetic effects, sometimes unexpected and depending on the enzyme and plasmid combinations. Experimental optimization of the culture conditions allowed us to obtain the complete conversion of cyclohexanol (16 mM) and 1-indanol (7.5 mM) at a 0.5-L scale. The yield for the conversion of cyclohexanol was 80% (0.7 g ε-caprolactone, for the productivity of 244 mg·L ⁻¹·h ⁻¹) and that for 1-indanol 60% (0.3 g 3,4-dihydrocoumarin, for the productivity of 140 mg·L ⁻¹·h ⁻¹).     

Strigo-D2—a bio-sensor for monitoring spatio-temporal strigolactone signaling patterns in intact plants

Strigolactones (SLs) are a class of plant hormones that mediate biotic interactions and modulate developmental programs in response to endogenous and exogenous stimuli. However, a comprehensive view on the spatio-temporal pattern of SL signaling has not been established, and tools for a systematic in planta analysis do not exist. Here, we present Strigo-D2, a genetically encoded ratiometric SL signaling sensor that enables the examination of SL signaling distribution at cellular resolution and is capable of rapid response to altered SL levels in intact Arabidopsis (Arabidopsis thaliana) plants. By monitoring the abundance of a truncated and fluorescently labeled SUPPRESSOR OF MAX2 1-LIKE 6 (SMXL6) protein, a proteolytic target of the SL signaling machinery, we show that all cell types investigated have the capacity to respond to changes in SL levels but with very different dynamics. In particular, SL signaling is pronounced in vascular cells but low in guard cells and the meristematic region of the root. We also show that other hormones leave Strigo-D2 activity unchanged, indicating that initial SL signaling steps work in isolation from other hormonal signaling pathways. The specificity and spatio-temporal resolution of Strigo-D2 underline the value of the sensor for monitoring SL signaling in a broad range of biological contexts with highly instructive analytical depth.

Strigo-D2 is a genetically encoded sensor visualizing spatio-temporal patterns of strigolactone signaling levels in intact plants based on the activity ratio of two fluorescent marker proteins.     

Neuronal postdevelopmentally acting SAX-7S/L1CAM can function as cleaved fragments to maintain neuronal architecture in Caenorhabditis elegans

Whereas remarkable advances have uncovered mechanisms that drive nervous system assembly, the processes responsible for the lifelong maintenance of nervous system architecture remain poorly understood. Subsequent to its establishment during embryogenesis, neuronal architecture is maintained throughout life in the face of the animal’s growth, maturation processes, the addition of new neurons, body movements, and aging. The Caenorhabditis elegans protein SAX-7, homologous to the vertebrate L1 protein family of neural adhesion molecules, is required for maintaining the organization of neuronal ganglia and fascicles after their successful initial embryonic development. To dissect the function of sax-7 in neuronal maintenance, we generated a null allele and sax-7S-isoform-specific alleles. We find that the null sax-7(qv30) is, in some contexts, more severe than previously described mutant alleles and that the loss of sax-7S largely phenocopies the null, consistent with sax-7S being the key isoform in neuronal maintenance. Using a sfGFP::SAX-7S knock-in, we observe sax-7S to be predominantly expressed across the nervous system, from embryogenesis to adulthood. Yet, its role in maintaining neuronal organization is ensured by postdevelopmentally acting SAX-7S, as larval transgenic sax-7S(+) expression alone is sufficient to profoundly rescue the null mutants’ neuronal maintenance defects. Moreover, the majority of the protein SAX-7 appears to be cleaved, and we show that these cleaved SAX-7S fragments together, not individually, can fully support neuronal maintenance. These findings contribute to our understanding of the role of the conserved protein SAX-7/L1CAM in long-term neuronal maintenance and may help decipher processes that go awry in some neurodegenerative conditions.     

A directed nucleotide-sequencing approach for single-stranded vectors based on recloning intermediates of a progressive DNA synthesis reaction

A simple method for site-directed nucleotide sequencing is presented that uses a novel procedure for generating nested 'deletions' within inserts of single-stranded clones. In this method, single-stranded template, sequencing primer, and the Klenow fragment of Escherichia coli DNA polymerase I are used to initiate progressive DNA synthesis of the entire insert of the clone. By time-dependent sampling and pooling of intermediates from the synthesis reaction a series of nested double-stranded DNA subfragments of the insert can be created. Nested subclones are then produced by S1-endonuclease treatment and oriented subcloning methods. First, smaller quantities of template DNA can be used, equivalent to a fraction of a small DNA sequencing prep. Second, it works with single-stranded M13 phage DNA rather than requiring the preparation of double-stranded replicative form DNA as in ExoIII-based methods. Third, the 'deletions' it generates can span areas of simple nucleotide sequence or secondary structure that often halt digestion in the single-stranded exonuclease-based method. Last, the method is adaptable to a larger variety of insert cloning sites than the ExoIII-based method. The main disadvantage of the method is that, due to the lower efficiency of subcloning larger DNA fragments, subclone inserts larger than 3 kb are generated only infrequently.     

Neuregulin-heparan-sulfate proteoglycan interactions produce sustained erbB receptor activation required for the induction of acetylcholine receptors in muscle

Neuregulins bind to and activate members of the EGF receptor family of tyrosine kinases that initiate a signaling cascade that induces acetylcholine receptor synthesis in the postsynaptic membrane of neuromuscular synapses. In addition to an EGF-like domain, sufficient for receptor binding and tyrosine auto-phosphorylation, many spliced forms also have an IG-like domain that binds HSPGs and maintains a high concentration of neuregulin at synapses. Here, we show that the IG-like domain functions to keep the EGF-like domain at sufficiently high concentrations for a sufficiently long period of time necessary to induce acetylcholine receptor gene expression in primary chick myotubes. Using recombinant neuregulins with and without the IG-like domain, we found that IG-like domain binding to endogenous HSPGs produces a 4-fold increase in receptor phosphorylation. This enhancement of activity was blocked by soluble heparin or by pretreatment of muscle cells with heparitinase. We show that at least 12-24 h of neuregulin exposure was required to turn on substantial acetylcholine receptor gene expression and that the erbB receptors need to be kept phosphorylated during this time. The need for sustained erbB receptor activation may be the reason why neuregulins are so highly concentrated in the extracellular matrix of synapses.     

The conserved active site motif A of Escherichia coli DNA polymerase I is highly mutable

Escherichia coli DNA polymerase I participates in DNA replication, DNA repair, and genetic recombination; it is the most extensively studied of all DNA polymerases. Motif A in the polymerase active site has a required role in catalysis and is highly conserved. To assess the tolerance of motif A for amino acid substitutions, we determined the mutability of the 13 constituent amino acids Val(700)-Arg(712) by using random mutagenesis and genetic selection. We observed that every residue except the catalytically essential Asp(705) can be mutated while allowing bacterial growth and preserving wild-type DNA polymerase activity. Hence, the primary structure of motif A is plastic. We present evidence that mutability of motif A has been conserved during evolution, supporting the premise that the tolerance for mutation is adaptive. In addition, our work allows identification of refinements in catalytic function that may contribute to preservation of the wild-type motif A sequence. As an example, we established that the naturally occurring Ile(709) has a previously undocumented role in supporting sugar discrimination.