Claes Axäng

Monitoring of lipid storage in Caenorhabditis elegans using coherent anti-Stokes Raman scattering (CARS) microscopy

Better understanding of the fundamental mechanisms behind metabolic diseases requires methods to monitor lipid stores on single-cell level in vivo. We have used Caenorhabditis elegans as a model organism to demonstrate the limitations of fluorescence microscopy for imaging of lipids compared with coherent anti-Stokes Raman scattering (CARS) microscopy, the latter allowing chemically specific and label-free imaging in living organisms. CARS microscopy was used to quantitatively monitor the impact of genetic variations in metabolic pathways on lipid storage in 60 specimens of C. elegans. We found that the feeding-defective mutant pha-3 contained a lipid volume fraction one-third of that found in control worms. In contrast, mutants (daf-2, daf-4 dauer) with deficiencies in the insulin and transforming growth factors (IGF and TGF-β) signaling pathways had lipid volume fractions that were 1.4 and 2 times larger than controls, respectively. This was observed as an accumulation of small-sized lipid droplets in the hypodermal cells, hosting as much as 40% of the total lipid volume in contrast to the 9% for the wild-type larvae. Spectral CARS microscopy measurements indicated that this is accompanied by a shift in the ordering of the lipids from gel to liquid phase. We conclude that the degree of hypodermal lipid storage and the lipid phase can be used as a marker of lipid metabolism shift. This study shows that CARS microscopy has the potential to become a sensitive and important tool for studies of lipid storage mechanisms, improving our understanding of phenomena underlying metabolic disorders.

Developmental genetics of the C. elegans pharyngeal neurons NSML and NSMR

BackgroundWe are interested in understanding how the twenty neurons of the C. elegans pharynx develop in an intricate yet reproducible way within the narrow confines of the embryonic pharyngeal primordium. To complement an earlier study of the pharyngeal M2 motorneurons, we have now examined the effect of almost forty mutations on the morphology of a bilateral pair of pharyngeal neurosecretory-motor neurons, the NSMs.ResultsA careful description of the NSM morphology led to the discovery of a third, hitherto unreported process originating from the NSM cell body and that is likely to play a proprioceptive function. We found that the three NSM processes are differently sensitive to mutations. The major dorsal branch was most sensitive to mutations that affect growth cone guidance and function (e.g. unc-6, unc-34, unc-73), while the major sub-ventral branch was more sensitive to mutations that affect components of the extracellular matrix (e.g. sdn-1). Of the tested mutations, only unc-101, which affects an adaptin, caused the loss of the newly described thin minor process. The major processes developed synaptic branches post-embryonically, and these exhibited activity-dependent plasticity.ConclusionBy studying the effects of nearly forty different mutations we have learned that the different NSM processes require different genes for their proper guidance and use both growth cone dependent and growth cone independent mechanisms for establishing their proper trajectories. The two major NSM processes develop in a growth cone dependent manner, although the sub-ventral process relies more on substrate adhesion. The minor process also uses growth cones but uniquely develops using a mechanism that depends on the clathrin adaptor molecule UNC-101. Together with the guidance of the M2 neuron, this is the second case of a pharyngeal neuron establishing one of its processes using an unexpected mechanism.

A genetic analysis of axon guidance in the C. elegans pharynx

We wish to understand how the trajectories of the twenty pharyngeal neurons of C. elegans are established. In this study we focused on the two bilateral M2 pharyngeal motorneurons, which each have their cell body located in the posterior bulb and send one axon through the isthmus and into the metacorpus. We used a GFP reporter to visualize these neurons in cell-autonomous and cell-non-autonomous axon guidance mutant backgrounds, as well as other mutant classes. Our main findings are: 1). Mutants with impaired growth cone functions, such as unc-6, unc-51, unc-73 and sax-3, often exhibit abnormal terminations and inappropriate trajectories at the distal ends of the M2 axons, i.e. within the metacorpus; and 2). Growth cone function mutants never exhibit abnormalities in the proximal part of the M2 neuron trajectories, i.e. between the cell body and the metacorpus. Our results suggest that the proximal and distal trajectories are established using distinct mechanisms, including a growth cone-independent process to establish the proximal trajectory. We isolated five novel mutants in a screen for worms exhibiting abnormal morphology of the M2 neurons. These mutants define a new gene class designated mnm (M neuron morphology abnormal).

Genetics of Extracellular Matrix Remodeling During Organ Growth Using the Caenorhabditis elegans Pharynx Model

The organs of animal embryos are typically covered with an extracellular matrix (ECM) that must be carefully remodeled as these organs enlarge during post-embryonic growth; otherwise, their shape and functions may be compromised. We previously described the twisting of the Caenorhabditis elegans pharynx (here called the Twp phenotype) as a quantitative mutant phenotype that worsens as that organ enlarges during growth. Mutations previously known to cause pharyngeal twist affect membrane proteins with large extracellular domains (DIG-1 and SAX-7), as well as a C. elegans septin (UNC-61). Here we show that two novel alleles of the C. elegans papilin gene, mig-6(et4) and mig-6(sa580), can also cause the Twp phenotype. We also show that overexpression of the ADAMTS protease gene mig-17 can suppress the pharyngeal twist in mig-6 mutants and identify several alleles of other ECM-related genes that can cause or influence the Twp phenotype, including alleles of fibulin (fbl-1), perlecan (unc-52), collagens (cle-1, dpy-7), laminins (lam-1, lam-3), one ADAM protease (sup-17), and one ADAMTS protease (adt-1). The Twp phenotype in C. elegans is easily monitored using light microscopy, is quantitative via measurements of the torsion angle, and reveals that ECM components, metalloproteinases, and ECM attachment molecules are important for this organ to retain its correct shape during post-embryonic growth. The Twp phenotype is therefore a promising experimental system to study ECM remodeling and diseases.

The twisted pharynx phenotype in C. elegans

BackgroundThe pharynx of C. elegans is an epithelial tube whose development has been compared to that of the embryonic heart and the kidney and hence serves as an interesting model for organ development. Several C. elegans mutants have been reported to exhibit a twisted pharynx phenotype but no careful studies have been made to directly address this phenomenon. In this study, the twisting mutants dig-1, mig-4, mnm-4 and unc-61 are examined in detail and the nature of the twist is investigated.ResultsWe find that the twisting phenotype worsens throughout larval development, that in most mutants the pharynx retains its twist when dissected away from the worm body, and that double mutants between mnm-4 and mutants with thickened pharyngeal domains (pha-2 and sma-1) have less twisting in these regions. We also describe the ultrastructure of pharyngeal tendinous organs that connect the pharyngeal basal lamina to that of the body wall, and show that these are pulled into a spiral orientation by twisted pharynges. Within twisted pharynges, actin filaments also show twisting and are longer than in controls. In a mini screen of adhesionmolecule mutants, we also identified one more twisting pharynx mutant, sax-7.ConclusionDefects in pharyngeal cytoskeleton length or its anchor points to the extracellular matrix are proposed as the actual source of the twisting force. The twisted pharynx is a useful and easy-to-score phenotype for genes required in extracellular adhesion or organ attachment, and perhaps forgenes required for cytoskeleton regulation.

CARS microscopy for the monitoring of lipid storage in C. elegans

After several years of proof-of-principle measurements and focus on technological development, it is timely to make full use of the capabilities of CARS microscopy within the biosciences. We have here identified an urgent biological problem, to which CARS microscopy provides unique insights and consequently may become a widely accepted experimental procedure. In order to improve present understanding of mechanisms underlying dysfunctional metabolism regulation reported for many of our most wide-spread diseases (obesity, diabetes, cardio-vascular diseases etc.), we have monitored genetic and environmental impacts on cellular lipid storage in the model organism C. elegans in vivo in a full-scale biological study. Important advantages of CARS microscopy could be demonstrated compared to present technology, i.e. fluorescence microscopy of labelled lipid stores. The fluorescence signal varies not only with the presence of lipids, but also with the systemic distribution of the fluorophore and the chemical properties of the surrounding medium. By instead probing high-density regions of CH bonds naturally occurring in the sample, the CARS process was shown to provide a consistent representation of the lipid stores. The increased accumulation of lipid stores in mutants with deficiencies in the insulin and transforming growth factor signalling pathways could hereby be visualized and quantified. Furthermore, spectral CARS microscopy measurements in the C-H bond region of 2780-2930 cm-1 provided the interesting observation that this accumulation comes with a shift in the ordering of the lipids from gel- to liquid phase. The present study illustrates that CARS microscopy has a strong potential to become an important instrument for systemic studies of lipid storage mechanisms in living organisms, providing new insights into the phenomena underlying metabolic disorders.

CARS microscopy for the monitoring of fat deposition mechanisms in a living organism

We introduce near-infrared Coherent Anti-Stokes Raman Scattering (CARS) microscopy as a method for the monitoring of fat deposition in a living organism by directly probing the CH2 vibration of the lipids without the need for staining or labeling. This study nicely brings forward all the advantages of the technique: deep probe depth, low excitation powers, high 3-dimensional resolution, and visualization without the interference of exogenous label molecules, or fixation and staining procedures. Differences in fat deposition during the life cycle of the nematode Caenorhabditis elegans were evaluated quantitatively from the CARS microscopy images, showing that the technique can be used to study mechanisms that regulate lipid storage. Beside the wild type nematode, the feeding-deficient mutant pha-3 was studied. It was shown that the embryonal accumulation of energy stores is enough for the development of a full-sized pre-adult larva, being possible also for the mutant. However, the volume density of lipid stores at the fourth and last pre-adult development stage seems to determine its adult body size. Whereas the wild type larva maintains its size when becoming adult, though at the cost of reduced lipid density, the feeding deficient mutant instead has to reduce its body size in order to reach the same volume density of lipid stores. Both strains start off their adult life with a volume fraction of lipid stores corresponding to 6-7%; the wild type with a radius of 24±2 µm and the pha-3 mutant with a significantly smaller radius of 16±3 μm.