Visualization of the composition of the urinary fluorescent metabolome. Why is it important to consider initial urine concentration?

Urine is a highly complex fluorescent system, the fluorescence of which can be affected by many factors, including the often-ignored initial urine concentration in comprehensive fluorescent urine analysis. In this study, a total urine fluorescent metabolome profile (uTFMP) was created as a three-dimensional fluorescence profile of serial synchronous spectra of urine diluted by geometric progression. uTFMP was generated using software designed for this purpose after recalculating the 3D data concerning the initial urine concentration. It can be presented as a contour map (top view) or as a more illustrative and straightforward simple curve, thus usable in various medicinal applications.

The long protostomic-type cytoplasmic intermediate filament (cIF) protein in Branchiostoma supports the phylogenetic transition between the protostomic- and the chordate-type cIFs.

We identified 23 and 20 cytoplasmic IF (cIF) genes in the two Branchiostoma belcheri and Branchiostoma lanceolatum cephalochordates, respectively. Combining these results with earlier data on the related Branchiostoma floridae, the following conclusions can be drawn. First, the Branchiostoma N4 protein with a long lamin-like coil 1B segment is the only protostomic-type cIF found so far in any analysed chordate or vertebrate organism. Second, Branchiostoma is the only organism known so far containing both the long protostomic- and the short chordate-prototypes of cIFs. This finding provides so far missing molecular evidence for the phylogenetic transition between the protostomic- and the chordate-type IF sequences at the base of the cephalochordates and vertebrates. Third, this finding also brings some support for another hypothesis, that the long protostomic-type cIF is subjected to evolutionary constraints in order to preclude inappropriate interactions with lamin and that the latter complexes might be prevented by a several heptad-long rod deletion, which released the selective constraints on it and promoted, at least in part, its expansion in nematodes, cephalochordates, and in vertebrates. Finally, here-presented data confirmed our previous results that cephalochordates do not have any vertebrate type III or type IV IF homolog.

Dilated cardiomyopathy is a part of the ARV1-associated phenotype: a case report.

BACKGROUND: ACAT-related enzyme 2 required for viability 1 (ARV1) encodes a transmembrane lipid transporter of the endoplasmic reticulum, which is presented in all eukaryotes and in plants. Deficiency of ARV1 is clinically presented as autosomal recessive developmental and epileptic encephalopathy 38 (DEE38) in humans and in mice. So far, three different homozygous and two compound heterozygous ARV1 mutations in humans have been reported in 15 children. CASE PRESENTATION: In this case report we present a novel homozygous in-frame ARV1-deletion (c.554_556delTAT, p.L185del) in a 21-year old Caucasian man with developmental delay, intellectual disability, seizures, walking and speech impairments, as well as with a dilated cardiomyopathy (DCM), which has not yet been firmly related to the ARV1-associated phenotype. Interestingly, this novel variant lies in the proximity of the p.G189R mutation, which was previously described in two brothers with DEE38 and dilated cardiomyopathy. CONCLUSION: The finding of dilated cardiomyopathy in the presented as well as in three previously reported patients from two different families indicates that dilated cardiomyopathy is a part of the ARV1-induced DEE38 phenotype. However, more data are needed to make this conclusion definitive.

Promiscuous Dimerization Between the Caenorhabditis elegans IF Proteins and a Hypothesis to Explain How Multiple IFs Persist Over Evolutionary Time.

Our previous calculations of ionic interactions indicated that the Caenorhabditis elegans intermediate filament (IF) IFA proteins, in addition to IFA/IFB-1 heterodimers, may also form homodimers. In order to prove the significance of these calculations, we analysed the dimerization potential of the IFA chains in blot overlays. Unexpectedly, we found here that the dimerization of the IFA-1 protein was of both homotypic and heterotypic nature, and involved all proteins immobilized on the membrane (IFA-1, IFA-2, IFA-4, IFB-1, IFB-2, IFC-1, IFC-2, IFD-1, IFD-2 and IFP-1). A similar interaction profile, though less complex, was observed for two biotinylated proteins (IFA-2 and IFA-4). These and previous results indicate that the IFA proteins are able to form many different heteropolymeric and homopolymeric complexes in the C. elegans tissue, but that only those triggered by the IFA-specific IFB-1 protein result in mature IFs. Moreover, the calculations of the possible ionic interactions between the individual rod sequences as well as their various deletion variants indicated a special role in this process for the middle part of the C. elegans IF coil 1B segment that is deleted in all vertebrate cytoplasmic IFs. We hypothesized here, therefore, that the striking promiscuity of the C. elegans IFs originally involved a nuclear lamin which, due to a two-heptad-long rod deletion, prevented formation of a functional lamin/cIF dimer. This, in concert with an efficient dimerization and a strict tissue-specific co-expression, may allow expansion and maintenance of the multiple Caenorhabditis IFs. A possible implication for evolution of chordate IFs proteins is also discussed.

Analysis of the novel excretory cell expressed ECP-1 protein and its proposed ECP-1/IFC-2 fusion protein EXC-2 in the nematode Caenorhabditis elegans.

The multigene family of cytoplasmic intermediate filament (IF) proteins in C. elegans covers eleven members, of which four (IFA-1 to IFA-3, IFB-1), which form an obligate heteropolymeric IF system, are essential for development. The six other C. elegans IF proteins IFB-2, IFC-1, IFC-2, IFD-1, IFD-2 and IFP-1 are co-expressed in the intestinal terminal web during different developmental stages, reveal various differently penetrant RNAi phenotypes and form another heteropolymeric IFB-2/IFCDP-1 IF system in C. elegans. Interestingly, the alternatively spliced IFC-2 variant, called EXC-2, was recently found also to be needed for a normal excretory system maturation in C. elegans. In order to better understand the IFC-2 function in the nematode tissue, we retrieved from the WormBase its multiple predicted alternatively spliced transcripts and analysed them using the molecular, immunofluorescence and RNAi approaches. We found that the 21-exon long genomic fragment encodes, besides the two different intestinal IFC-2a and IFC-2b IF proteins, also the novel excretory cell/IF unrelated protein ECP-1 and probably also the large ECP-1/IFC-2 fusion protein EXC-2, which all seem to be tissue-specific regulated from different promoters. Our analyses provide a framework for investigating interactions between the novel ECP-1, EXC-2 and some other proteins, including IFs, which show a similar excretory canal phenotype and are essential for development of the C. elegans excretory cells.

Intermediate filament (IF) proteins IFA-1 and IFB-1 represent a basic heteropolymeric IF cytoskeleton of nematodes: A molecular phylogeny of nematode IFs.

Intermediate filaments (IF) belong to major cytoskeletal components of metazoan cells. We have previously determined a tissue specific expression and assembly properties of all eleven cytoplasmic IFs (IFA-1 - IFA-4, IFB-1, IFB-2, IFC-1, IFC-2, IFD-1, IFD-2, IFP-1) in C. elegans and reported an essential function for four (IFA-1, IFA-2, IFA-3 and IFB-1) of them. In this study we continued the characterisation of the IF proteins in C. elegans by searching for in vivo polymerisation partners of the IFA proteins. Using the murine IFA-1 to IFA-3-specific monoclonal Ab MH4 and the immunoprecipitation assay as a tool, we identified the heteropolymeric IFA-1/IFB-1 complexes in the whole nematode protein extract, confirming their existence also in vivo. Moreover, in the present study we also analysed evolutionary aspects of the IF proteins in C. elegans and in nematodes. We found 106 C. elegans IF homologs in different nematode clades. Phylogenetic analyses suggest that all nematode IFs (including the three newly identified IF sequences IFA-5, IFCDP-1 and IFCDP-2) might arose from a AB-type IF ancestor through repeated gene duplications and sequence divergence. Interestingly, the C. elegans IF proteins IFA-1 and IFB-1 represent a heteropolymeric IF cytoskeleton in all investigated nematode clades, in contrast to other sequences restricted to the clade III-V (IFA-2, IFA-4), III (IFA-5) and V (IFB-2, IFCDP) taxa, or even to the Caenorhabditis genus (IFA-3, IFC-1 to IFP-1). These analyses provide an insight into the origin of the multiple IFs in nematodes and also represent a basis for further studies of these sequences in nematodes.

Detection of FLT3 Mutations in Patients from Eastern Slovakia.

BACKGROUND: The study investigated FLT3 gene mutations in patients from eastern Slovakia using a simple molecular method. PATIENTS AND METHODS: We analyzed 141 patients with primary acute myeloid leukemia (AML) and 8 patients with AML that developed from myelodysplastic syndrome (MDS) who were aged 19-81 years. DNA isolated from peripheral blood and/or bone marrow was analyzed by PCR. FLT3 internal tandem duplication (FLT3-ITD) was detected by amplification of exons 14 and 15. Point mutations in the FLT3 tyrosine kinase domain (FLT3-TKD) were detected by digesting the PCR product of exon 20 with the restriction endonuclease EcoRV. Fragments were separated electrophoretically. PCR products of the positive samples were also analyzed using a microchip device (Bioanalyzer 2100). RESULTS: LT3-ITD and point mutations in the FLT-TKD were detected in 19 and 8% of patients, resp. Two patients (1%) harbored both types of mutations. Patients with and without FLT3 mutations were called FLT+ and FLT-, resp. Most FLT3+ patients had no chromosomal aberrations (59%) or harbored the t (15; 17) translocation in PML-RARA (15%). The mortality rate was 33% among FLT3+ patients and 10% among FLT3-patients. Among FLT3+ patients, the mortality rates of patients with FLT3-ITD and point mutations of the FLT-TKD were almost the same. A 77-year-old female patient with both FLT3-ITD and a point mutation in the FLT3-TKD was in remission. The eight patients who developed AML from MDS were assessed separately. Of these, three patients were FLT3+; two patients displayed FLT3-ITD, and one patient harbored a point mutation in the FLT3-TKD. No other genetic aberrations were detected. FLT3+ patients lived for longer than FLT3-patients. These analyses of FLT3 gene mutations in patients from eastern Slovakia are consistent with published data from other databases. CONCLUSION: The applied PCR method is reliable, relatively fast, and affordable, and can be used for routine monitoring of FLT3 gene mutations. FLT3 mutations can be verified using a microchip as an alternative to capillary electrophoresis. Key words: acute myelogenous leukemia - DNA - PCR - mutation - FLT3-ITD - FLT3-TKD The study was supported by the European Regional Development grant OPVaV-2009/2.2/05- -SORO (ITMS code: 26220220143). The authors declare they have no potential conflicts of interest concerning drugs, products, or services used in the study. The Editorial Board declares that the manuscript met the ICMJE recommendation for biomedical paper Submitted: 19. 10. 2017 Accepted: 15. 2. 2018.

Assembly studies of six intestinal intermediate filament (IF) proteins B2, C1, C2, D1, D2, and E1 in the nematode C. elegans.

The dimerisation properties of six intestine-expressed intermediate filament (IF) proteins (B2, C1, C2, D1, D2, E1) were analysed in blot overlay assay on membranes containing all of the eleven recombinant C. elegans IF proteins (A1, A2, A3, A4, B1, B2, C1, C2, D1, D2, and E1). The interactions detected in the blot assays exclusively comprise intestine-expressed IF proteins and the protein A4, which is found in the dauer larva intestine. About 86% of these interactions are heterotypic, while the remaining interactions relate to C1, C2, and D2 homodimers. These multiple modes of interaction were also supported by calculations of the numbers of possible interchain ionic interactions derived from the individual rod sequences. The results predict that the six B2, C1, C2, D1, D2, and E1 IF proteins are able to form as many as eleven different heteropolymeric and three homopolymeric IFs in the C. elegans intestine. This simple model of the intestinal IF meshwork enables us to speculate that our previously reported triple RNAi worms arrested or decreased their growth because of feeding reduction due to morphological defects of the mechanically compromised intestine.

Molecular evolution of the multiple calmodulin-like cal genes in C. elegans and in nematodes.

Calmodulin (CaM) is a major EF hand containing intracellular calcium receptor in animals and plants; however, eukaryotes also express a number of related CaM-like proteins. We have previously characterized an embryonic phenotype of the single Caenorhabditis elegans CaM gene cmd-1, reported no visible RNAi phenotype for the four related cal-1 to cal-4 genes and started tissue-specific expression analyses of these proteins. In the present study, we analyzed evolutionary aspects of the previously reported CAL-1 to CAL-4 proteins, along with the four new CAL-5 to CAL-8 sequences retrieved from the worm database. Phylogenetic analyses suggest that all C. elegans CAL proteins arose from a CaM ancestor through repeated gene duplications, fusions and sequence divergence. The same holds, also, for the variable N-terminal extensions of the CAL-1 to CAL-4 proteins, which have evolved from the CaM-like core domain. We found 97 CAL homologs in different nematode clades and also detected two CAL-7-related sequences outside the nematodes. Moreover, the C. elegans-specific cal-6 gene, representing the most CaM-related sequence found in nematodes so far, harbours many deletions, insertions and sequence substitutions and is predicted, therefore, to be non-functional. These analyses provide an insight into a complex and dynamic origin of the multiple CAL genes in C. elegans and in nematodes and represent also a basis for further functional studies of these CaM-related sequences in nematodes.

A novel way to monitor urine concentration: fluorescent concentration matrices.

BACKGROUND: The amount of water found in urine is important diagnostic information; nevertheless it is not yet directly determined. Indirectly, the water content in urine is expressed by its density (specific gravity). However, without the diuresis value it is not possible to determine whether the increase in density of urine is due to a decrease in water secretion or an increase in the concentration of secreted substances. This problem can be solved by the use of fluorescent concentration 3D-matrices which characterise urine concentration through the pφ (or -logφ) value of the first fluorescence centre. MATERIALS AND METHODS: The urine fluorescent concentration 3D-matrix was created by the alignment of the synchronous spectra of the dilution series of urine starting from undiluted (pφ = 0) to 1000-fold diluted urine (pφ = 3). RESULTS: Using the fluorescence concentration 3D-matrix analysis of the urine samples from healthy individuals, a reference range was established for the value pφ, determining the normal, concentrated or diluted type of urine. The diagnostic potential of this approach was tested on urine samples from two patients with a chronic glomerulonephritis. CONCLUSION: The pφ value of the urine fluorescence concentration 3D-matrix analysis determines whether the urine sample falls within the normal, concentrated or diluted type of urine. This parameter can be directly utilised in sportsmen's hydration state monitoring, as well as in the diagnosis and treatment of serious diseases. An important advantage of this novel diagnostic approach is that a 12/24 h urine collection is not required, which predetermines it for use especially within paediatrics.

Unusual ultrastructures of the Branchiostoma IF protein C2 containing heptads in the tail.

Branchiostoma intermediate filament (IF) protein C2 contains a long tail domain consisting of several degenerate repeats which display a heptad repeat pattern. This unique tail sequence is predicted to constitute a long coiled coil domain in C2, which is separated from the rod by a glycine-rich linker L3. The recombinant IF protein C2 shows, in electron microscopy (EM), parallel rodlike dimers of 66.7 nm decorated by a larger globule on one side and a smaller globule on the other side. In contrast, the length of the tailless C2 dimers, decorated by only one small globule, is about 26 nm shorter. These results indicate that both the rod domain and the newly predicted coiled coil segment 3 participate in the formation of a double-stranded coiled coil dimer. Moreover, the two to four C2 dimers are able to associate via their globular tail domain into multiarm oligomers, an ability not seen by the tailless C2 mutant or the other currently known protostomic and vertebrate IFs.

The cephalochordate Branchiostoma genome contains 26 intermediate filament (IF) genes: implications for evolution of chordate IF proteins.

We analyzed the draft genome of the cephalochordate Branchiostoma floridae (B. floridae) for genes encoding intermediate filament (IF) proteins. From 26 identified IF genes 13 were not reported before. Four of the new IF genes belong to the previously established Branchiostoma IF group A, four to the Branchiostoma IF group B, one is homologous to the type II keratin E2 while the remaining four new IF sequences N1 to N4 could not be readily classified in any of the previously established Branchiostoma IF groups. All eleven identified A and B2-type IF genes are located on the same genomic scaffold and arose due to multiple cephalochordate-specific duplications. Another IF gene cluster, identified in the B. floridae genome, contains three keratins (E1, Y1, D1), two keratin-like IF genes (C2, X1), one new IF gene (N1) and one IF unrelated gene, but does not show any similarities to the well defined vertebrate type I or type II keratin gene clusters. In addition, some type III sequence features were documented in the new IF protein N2, which, however, seems to share a common ancestry with the Branchiostoma keratins D1 and two keratin-related genes C. Thus, a few type I and type II keratin genes existed in a common ancestor of cephalochordates and vertebrates, which after separation of these two lineages gave rise to the known complexities of the vertebrate cytoplasmic type I-IV IF proteins, as well as to the multiple keratin and related IF genes in cephalochordates, due to multiple gene duplications, deletions and sequence divergences.

A rod domain sequence in segment 1B triggers dimerisation of the two small Branchiostoma IF proteins B2 and A3.

Previously, we cloned two Branchiostoma IF proteins A3 and B2 and demonstrated that both can form heteropolymeric IF based on a coiled coil dimer consisting of one B2 and one A3 polypeptide. In this study we continued in the characterisation of the B2/A3 heterodimer by searching for the sequences that play an important role in the triggering of the B2/A3 heterodimer. Using a series of deletion and chimeric B2, A3 and B1 constructs and the overlay assay as a tool, we were able to identify a part of the B2 sequence (segment 1A, linker L1 and the N-terminal part of segment 1B) which retains the ability of the full length protein B2 to specifically recognize A3 in blot overlays. Moreover, inspection of this A3-competent B2 fragment identified a short sequence in segment 1B which shares with the currently known trigger-like motif of cortexillin and other coiled coil proteins potential to form multiple inter-chain ionic interactions. Thus, a common and essential feature of trigger sequences with different primary structures found so far in IF and other coiled coil proteins seems to be their ability to form multiple inter-chain ionic interactions which brings the chains close to one another and allows coiled coil formation to propagate accordingly.

Smad-interacting protein-1 (Zfhx1b) acts upstream of Wnt signaling in the mouse hippocampus and controls its formation.

Smad-interacting protein-1 (Sip1) [Zinc finger homeobox (Zfhx1b)] is a transcription factor implicated in the genesis of Mowat-Wilson syndrome in humans. Sip1 expression in the dorsal telencephalon of mouse embryos was documented from E12.5. We inactivated the gene specifically in cortical precursors. This resulted in the lack of the entire hippocampal formation. Sip1 mutant mice exhibited death of differentiating cells and decreased proliferation in the region of the prospective hippocampus and dentate gyrus. The expression of the Wnt antagonist Sfrp1 was ectopically activated, whereas the activity of the noncanonical Wnt effector, JNK, was down-regulated in the embryonic hippocampus of mutant mice. In cortical cells, Sip1 protein was detected on the promoter of Sfrp1 gene and both genes showed a mutually exclusive pattern of expression suggesting that Sfrp1 expression is negatively regulated by Sip1. Sip1 is therefore essential to the development of the hippocampus and dentate gyrus, and is able to modulate Wnt signaling in these regions.

Most genes encoding cytoplasmic intermediate filament (IF) proteins of the nematode Caenorhabditis elegans are required in late embryogenesis.

Intestinal cells of C. elegans show an unexpectedly high complexity of cytoplasmic intermediate filament (IF) proteins. Of the 11 known IF genes six are coexpressed in the intestine, i.e. genes B2, C1, C2, D1, D2, and E1. Specific antibodies and GFP-promoter constructs show that genes B2, D1, D2, and E1 are exclusively expressed in intestinal cells. Using RNA interference (RNAi) by microinjection at 25 degrees C rather than at 20 degrees C we observe for the first time lethal phenotypes for C1 and D2. RNAi at 25 degrees C also shows that the known A1 phenotype occurs already in the late embryo after microinjection and is also observed by feeding which was not the case at 20 degrees C. Thus, RNAi at 25 degrees C may also be useful for the future analysis of other nematode genes. Finally, we show that triple RNAi at 20 degrees C is necessary for the combinations B2, D1, E1 and B2, D1, D2 to obtain a phenotype. Together with earlier results on genes A1, A2, A3, B1, and C2 RNAi phenotypes are now established for all 11IF genes except for the A4 gene. RNAi phenotypes except for A2 (early larval lethality) and C2 (adult phenotype) relate to the late embryo. We conclude that in C. elegans cytoplasmic IFs are required for tissue integrity including late embryonic stages. This is in strong contrast to the mouse, where ablation of IF genes apparently does not affect the embryo proper.

The genome of the early chordate Ciona intestinalis encodes only five cytoplasmic intermediate filament proteins including a single type I and type II keratin and a unique IF-annexin fusion protein.

We screened the recently established draft genome of the early chordate Ciona intestinalis for genes encoding cytoplasmic intermediate filament (IF) proteins. The draft of the tunicate/urochordate genome contains only the five genes (IF-A, IF-B, IF-C, IF-D and IF-F) previously established by cDNA cloning. Three of these IF proteins (IF-D, IF-C, IF-A) were shown to be orthologs of vertebrate IF subfamilies I to III while two proteins (IF-B, IF-F) seemed tunicate specific. This is now firmly established for protein IF-F since the genomic data show that it arises as a fusion protein with a C-terminal annexin domain, a feature not found before in the very large collection of metazoan IF proteins. The results also confirm the previous proposal that urochordates lack orthologs of vertebrate type IV IF proteins. We discuss the striking increase of IF complexity from 5 tunicate to 65 human genes during chordate evolution. Thus the tunicate has a single keratin pair, which is expressed in the epidermis, while the human genome has at least 25 genes each for keratins I and keratins II. Finally there are four normal Ciona annexin genes in addition to the gene encoding the IF-annexin fusion proteins (IF-F).

In vivo and in vitro evidence that the four essential intermediate filament (IF) proteins A1, A2, A3 and B1 of the nematode Caenorhabditis elegans form an obligate heteropolymeric IF system.

The in vitro polymerization and tissue-specific expression patterns of the four essential intermediate filament (IF) proteins (A1, A2, A3, B1) and the non-essential IF protein A4 were analyzed. Recombinant B1, used as a probe in blot overlay assays of the 11 Caenorhabditis elegans IF proteins, reacted strongly with proteins A1 to A4, indicating a heterotypic interaction. Obligate heteropolymeric filament assembly in vitro was confirmed by electron microscopy. Protein B1 formed long IF when mixed with an equimolar amount of A1, A2 or A3. Developmentally regulated coexpression of B1 and one or more members of the A family was found with GFP-promoter reporters. This coexpression pattern argues for a heteropolymer system in vivo. One or both splice variants of the B1 gene are always coexpressed in a tissue-specific manner with at least one member of the A family in hypodermis, pharynx, pharyngeal-intestinal valve, excretory cells, uterus, vulva and rectum. Interestingly, while the intestine normally lacks a B1/A pair, the dauer larva shows intestinal B1 and A4. These results are in line with similar postembryonic phenotypes of the hypodermis induced by RNA interference (RNAi) of genes B1, A2 and A3. Similarly, defects of the pharynx and its A1-GFP containing tonofilaments observed in the postembryonic B1 RNAi phenotype are consistent with the coexpression of B1 and A1 in the marginal cells. Thus RNAi analyses provide independent evidence for the existence of the B1/A obligate heteropolymer system in vivo. Proteins A1 and B1 have a similar and rather slow turnover rate in photobleaching experiments of the pharynx tonofilaments.

The single nuclear lamin of Caenorhabditis elegans forms in vitro stable intermediate filaments and paracrystals with a reduced axial periodicity.

The lamins of the tunicate Ciona intestinalis and the nematode Caenorhabditis elegans show unusual sequence features when compared to the more than 35 metazoan lamin sequences currently known. We therefore analyzed the in vitro assembly of these two lamins by electron microscopy using chicken lamin B2 as a control. While lamin dimers usually appear as a rod carrying two globules at one end, these globules are absent from Ciona lamin, which lacks the central 105-residue region of the tail domain. The deletion of 14 residues or two heptads from the coiled coil rod domain of the single C.elegans lamin results in a 1.5-nm shortening of the dimer rod. Similarly, the paracrystals assembled from the C.elegans lamin exhibit a 3.1-nm reduction of the true axial repeat compared to that of chicken lamin B2 paracrystals. We speculate that the banding pattern in the C.elegans lamin paracrystals arises from a relative stagger between dimers and/or a positioning of the globular tail domain relative to the central rod that is distinct from that observed in chicken lamin B2 paracrystals. Here we show that a nuclear lamin can assemble in vitro into 10-nm intermediate filaments (IFs). C.elegans lamin in low ionic strength Tris-buffers at a pH of 7.2-7.4 provides a stable population of lamin IFs. Some implications of this filament formation are discussed.

Functional analysis of the single calmodulin gene in the nematode Caenorhabditis elegans by RNA interference and 4-D microscopy.

Calmodulin (CaM), a small calcium-binding protein, is the key mediator of numerous calcium-induced changes in cellular activity. Its ligands include enzymes, cytoskeletal proteins and ion channels, identified in large part by biochemical and cell biological approaches. Thus far it has been difficult to assess the function of CaM genetically, because of the maternal supply in Drosophila and the presence of at least three nonallelic genes in vertebrates. Here we use the unique possibility offered by the C. elegans model system to inactivate the single CaM gene (cmd-1) through RNA interference (RNAi). We show that the RNAi microinjection approach results in a severe embryonic lethal phenotype. Embryos show disturbed morphogenesis, aberrant cell migration patterns, a striking hyperproliferation of cells and multiple defects in apoptosis. Finally, we show that RNAi delivery by the feeding protocol does not allow the efficient silencing of the CaM gene obtained by microinjection. General differences between the two delivery methods are discussed.